View allAll Photos Tagged efficient
An aircraft gas turbine and efficient aerodynamic aluminum body marked out Jean Albert Gregoire as a great designer. The project was shelved due to cost and braking problems ; a turbine does not generate any braking effect upon deceleration.
Turbine
100 ch @ 25.000 rpm
Vmax : 200 km/h
1 ex.
Collection Automobile Club de l'Ouest
Musée Automobile de la Sarthe
Musée des 24 Heures
Le Mans
France
July 2015
By now you should know that the Aria Express CityCenter Tram is the most efficient way to travel between the South Strip and the Central Strip. So when it comes time for you and your lovely lady to get from Mandalay Bay to Caesars Palace for the Celine Dion Show, you will know what to do. Don't you think...
On the 30th October 2017 the Maersk Line E Series Ultra Large Container Ship "Eleonora Maersk" (2007, 156,257DWT) arrives at Hamburg from Rotterdam.
The Maersk E Class comprises eight 14,770 twenty-foot equivalent unit (TEU) container ships. Until 2012, they were the largest container ship ever constructed. The E-class was followed by the Triple-E class, which is even larger and more fuel-efficient.
MAN Lion's Intercity LE
-
Avanza - 1079 | 6307 MNC
-
659 - Majadahonda (Pinar del Plantio) > Madrid (Moncloa)
The Temp
The Unknown Employee
She's a hard worker, efficient, bright and gets the job done. Whatever assignment that is thrown her way, she does it with ease, without complaint. But who is she? Where did she come from? No one seems to know......
None of the Directors or Managers can recall calling the temp agency - yet she just showed up one day at the receptionist's desk AND NEVER LEFT!
Is her name Lisa? Lauren? Lacey? Leanna? No one knows, yet, she'll answer to them all... She doesn't share anything about her personal life and she always stays to herself. Even The Gossip Girls couldn't get anything out of her!
It's a Scooby Doo mystery for sure........ Ideas, anyone?
This brand new i6s Efficient integral is seen here on display at the North West Vehicle Restoration Trust's open & running day, Kirkby, Liverpool, on 04/06/2023. The i6s Efficient is new to the market and has several lightweight features, mirrorcams and a more raked back front. © Peter Steel 2023.
The BMW i8, first introduced as the BMW Concept Vision Efficient Dynamics, is a plug-in hybrid sports car developed by BMW. The 2015 model year BMW i8 has a 7.1 kWh lithium-ion battery pack that delivers an all-electric range of 37 km (23 mi) under the New European Driving Cycle (NEDC).[5] Under the United States Environmental Protection Agency (EPA) cycle, the range in EV mode is 24 km (15 mi) with a small amount of gasoline consumption.
The BMW i8 can go from 0–100 km/h (0 to 60 mph) in 4.4 seconds and has a top speed of 250 km/h (155 mph). The BMW i8 has a fuel efficiency of 2.1 L/100 km (134.5 mpg-imp; 112.0 mpg-US) under the NEDC test with carbon emissions of 49 g/km. EPA rated the i8 combined fuel economy at 76 equivalent (MPG-equivalent) (3.1 L gasoline equivalent/100 km; 91 mpg-imp gasoline equivalent).
The initial turbodiesel concept car was unveiled at the 2009 International Motor Show Germany. The production version of the BMW i8 was unveiled at the 2013 Frankfurt Motor Show. The i8 was released in Germany in June 2014. Deliveries to retail customers in the U.S. began in August 2014. Global cumulative sales totaled almost 4,500 units through June 2015.
History
The i8 is part of BMW's "Project i" and it is being marketed as a new brand, BMW i, sold separately from BMW or Mini. The BMW i3, launched for retail customers in Europe in the fourth quarter of 2013, was the first model of the i brand available in the market, and it was followed by the i8, released in Germany in June 2014 as a 2015 model year. Other i models are expected to follow.
The initial turbodiesel concept car was unveiled at the 2009 International Motor Show Germany, In 2010, BMW announced the mass production of the Concept Vision Efficient Dynamics in Leipzig beginning in 2013 as the BMW i8. The BMW i8 gasoline-powered concept car destined for production was unveiled at the 2011 Frankfurt Motor Show. The production version of the BMW i8 was unveiled at the 2013 International Motor Show Germany. The following are the concept and pre-production models developed by BMW that precedeed the production version.
BMW Vision EfficientDynamics (2009)
BMW Vision EfficientDynamics concept car is a plug-in hybrid with a three cylinder turbodiesel engine. Additionally, there are two electric motors with 139 horsepower. It allows an acceleration to 100 km/h (62 mph) in 4.8 seconds and an electronically limited top speed of 250 km/h (160 mph).
According to BMW, the average fuel consumption in the EU test cycle (KV01) is 3.76 liters/100 kilometers, (75.1 mpg imp), and has a carbon dioxide emission rating of 99 grams per kilometer (1,3 l/100 km and 33g CO2/km ; EU-PHEV ECE-R101). The estimated all-electric range is 50 km (31 mi), and the 24-liter petrol tank extends the total vehicle range to up to 700 km (430 mi). The lightweight chassis is made mainly from aluminum. The windshield, top, doors and fenders are made from polycarbonate glass, with the body having a drag coefficient of 0.26.
The designers in charge of the BMW Vision EfficientDynamics Concept were Mario Majdandzic, Exterior Design and Jochen Paesen, Interior Design.
The vehicle was unveiled in 2009 International Motor Show Germany, followed by Auto China 2010.
BMW i8 Concept (2011)
BMW i8 Concept plug-in hybrid electric vehicle includes an electric motor located in the front axle powering the front wheels rated 96 kW (131 PS; 129 hp) and 250 N·m (184 lb·ft), a turbocharged 1.5-liter 3-cylinder gasoline engine driving rear wheels rated 164 kW (223 PS; 220 hp) and 300 N·m (221 lb·ft) of torque, with combined output of 260 kW (354 PS; 349 hp) and 550 N·m (406 lb·ft), a 7.2 kWh (26 MJ) lithium-ion battery pack that allows an all-electric range of 35 km (22 mi). All four wheels provide regenerative braking. The location of the battery pack in the energy tunnel gives the vehicle a low centre of gravity, enhancing its dynamics. Its top speed is electronically limited to 250 km/h (160 mph) and is expected to go from 0 to 100 km/h (0 to 60 mph) in 4.6 seconds. Under normal driving conditions the i8 is expected to deliver 80 mpg-US (2.9 L/100 km; 96 mpg-imp) under the European cycle. A full charge of the battery will take less than 2 hours using 220V. The positioning of the motor and engine over the axles results in optimum 50/50 weight distribution.
The vehicle was unveiled at the 2011 International Motor Show Germany, followed by CENTER 548 in New York City, 42nd Tokyo Motor Show 2011, 82nd Geneva Motor Show 2012, BMW i Born Electric Tour at the Palazzo delle Esposizioni at Via Nazionale 194 in Rome, Auto Shanghai 2013.
This concept car was featured in the film Mission: Impossible – Ghost Protocol.
BMW i8 Concept Spyder (2012)
The BMW i8 Concept Spyder included a slightly shorter wheelbase and overall length over the BMW i8 Concept, carbon-fibre-reinforced plastic (CFRP) Life module, drive modules made primarily from aluminium components, interlocking of surfaces and lines, 8.8-inch (22.4 cm) screen display, off-white outer layer, orange tone naturally tanned leather upholstery.
The vehicle was unveiled in Auto China 2012 in Beijing and won Concept Car of the Year, followed by 83rd Geneva International Motor Show 2013.
The designer of the BMW i8 Concept Spyder was Richard Kim.
BMW i8 coupe prototype (2013)
The design of the BMW i8 coupe prototype was based on the BMW i8 Concept. The BMW i8 prototype has an average fuel efficiency of less than 2.5 L/100 km (113.0 mpg-imp; 94.1 mpg-US) under the New European Driving Cycle with carbon emissions of less than 59 g/km. The i8 with its carbon-fiber-reinforced plastic (CFRP) passenger cell lightweight, aerodynamically optimized body, and BMW eDrive technology offers the dynamic performance of a sports car, with an expected 0–100 km (0–60 mi) sprint time of less than 4.5 seconds using both power sources. The plug-in hybrid system of the BMW i8 comprises a three-cylinder, 1.5-liter BMW TwinPower turbo gasoline engine combined with BMW eDrive technology used in the BMW i3 and develops maximum power of 170 kW (230 hp). The BMW i8 is the first BMW production model to be powered by a three-cylinder gasoline engine and the resulting specific output of 115 kW (154 hp) per liter of displacement is on a par with high-performance sports car engines and is the highest of any engine produced by the BMW Group.
The BMW i8's second power source is a hybrid synchronous electric motor specially developed and produced by the BMW Group for BMW i. The electric motor develops maximum power of 131 hp (96 kW) and produces its maximum torque of around 320 N·m (240 lbf·ft) from standstill. Typical of an electric motor, responsive power is instantly available when starting and this continues into the higher load ranges. As well as providing a power boost to assist the gasoline engine during acceleration, the electric motor can also power the vehicle by itself. Top speed in electric mode is approximately 120 km/h (75 mph), with a maximum driving range of up to 35 km (22 mi). Linear acceleration is maintained even at higher speeds since the interplay between the two power sources efficiently absorbs any power flow interruptions when shifting gears. The BMW i8 has an electronically controlled top speed of 250 km (160 mi), which can be reached and maintained when the vehicle operates solely on the gasoline engine. The model-specific version of the high-voltage 7.2 lithium-ion battery has a liquid cooling system and can be recharged at a conventional household power socket, at a BMW i Wallbox or at a public charging station. In the US a full recharge takes approximately 3.5 hours from a conventional 120V, 12 amp household circuit or approximately 1.5 hours from a 220V Level 2 charger.
The driver can also select several driving modes: SPORT, COMFORT and ECO PRO. Using the gear selector, the driver can either select position D for automated gear selection or can switch to SPORT mode. SPORT mode offers manual gear selection and at the same time switches to very sporty drive and suspension settings. In SPORT mode, the engine and electric motor deliver extra performance, accelerator response is faster and the power boost from the electric motor is maximized. And to keep the battery topped up, SPORT mode also activates maximum energy recuperation during overrun and braking as the electric motor’s generator function, which recharges the battery using kinetic energy, switches to a more powerful setting. The Driving Experience Control switch on the center console offers a choice of two settings. On starting, COMFORT mode is activated, which offers a balance between sporty performance and fuel efficiency, with unrestricted access to all convenience functions. Alternatively, the ECO PRO mode can be engaged, which, on the BMW i8 as on other models, supports an efficiency-optimized driving style. On this mode the powertrain controller coordinates the cooperation between the gasoline engine and the electric motor for maximum fuel economy. On deceleration, the intelligent energy management system automatically decides, in line with the driving situation and vehicle status, whether to recuperate braking energy or to coast with the powertrain disengaged. At the same time, ECO PRO mode also programs electrical convenience functions such as the air conditioning, seat heating and heated mirrors to operate at minimum power consumption, but without compromising safety. The maximum driving range of the BMW i8 on a full fuel tank and with a fully charged battery is more than 500 km (310 mi) in COMFORT mode, which can be increased by up to 20% in ECO PRO mode. The BMW i8’s ECO PRO mode can also be used during all-electric operation. The vehicle is then powered solely by the electric motor. Only if the battery charge drops below a given level, or under sudden intense throttle application such as kickdown, is the internal combustion engine automatically activated.
The vehicle was unveiled in BMW Group's Miramas test track in France.
Production version
The production BMW i8 was designed by Benoit Jacob. The production version was unveiled at the 2013 International Motor Show Germany, followed by 2013 Les Voiles de Saint-Tropez. It features butterfly doors, head-up display, rear-view cameras and partially false engine noise. Series production of customer vehicles began in April 2014. It is the first production car with laser headlights, reaching further than LED lights.
The i8 has a low vehicle weight of 1,485 kg (3,274 lb) (DIN kerb weight) and a low drag coefficient (Cd) of 0.26. In all-electric mode the BMW i8 has a top speed of 120 km/h (75 mph). In Sport mode the i8 delivers a mid-range acceleration from 80 to 120 km/h (50 to 75 mph) in 2.6 seconds. The electronically controlled top speed is 250 km/h (160 mph).
Range and fuel economy[edit]
The production i8 has a 7.1 kWh lithium-ion battery pack with a usable capacity of 5.2 kWh and intelligent energy management that delivers an all-electric range of 37 km (23 mi) under the NEDC cycle. Under the EPA cycle, the range in EV mode is 15 mi (24 km), with a gasoline consumption of 0.1 gallons per 100 mi, and as a result, EPA's all-electric range is zero. The total range is 330 mi (530 km).
The production version has a fuel efficiency of 2.1 L/100 km (134.5 mpg-imp; 112.0 mpg-US) under the NEDC test with carbon emissions of 49 g/km.[5] Under EPA cycle, the i8 combined fuel economy in EV mode was rated 76 equivalent (MPG-equivalent) (3.1 L gasoline equivalent/100 km; 91 mpg-imp gasoline equivalent), with an energy consumption of 43 kW-hrs/100 mi and gasoline consumption of 0.1 gal-US/100 mi. The combined fuel economy when running only with gasoline is 28 mpg-US (8.4 L/100 km; 34 mpg-imp), 28 mpg-US (8.4 L/100 km; 34 mpg-imp) for city driving, and 29 mpg-US (8.1 L/100 km; 35 mpg-imp) in highway.
The U.S. Environmental Protection Agency's 2014 edition of the "Light-Duty Automotive Technology, Carbon Dioxide Emissions, and Fuel Economy Trends" introduced utility factors for plug-in hybrids to represent the percentage of miles that will be driven using electricity by an average driver, in electric only or blended modes. The BMW i8 has a utility factor in EV mode of 37%, compared with 83% for the BMW i3 REx, 66% for the Chevrolet Volt, 65% for the Cadillac ELR, 45% for the Ford Energi models, 43% for the McLaren P1, 39% for the Porsche Panamera S E-Hybrid, and 29% for the Toyota Prius PHV.
[Text from Wikipedia]
This Lego miniland-scale BMW i8 has been created for Flickr LUGNuts' 94th Build Challenge, - "Appease the Elves Summer Automobile Build-off (Part 2)", - a design challenge combining the resources of LUGNuts, TheLegoCarBlog (TLCB) and Head Turnerz.
🔵⚪️ STAR ⚪️🔵
Rennes 🇫🇷
Réseau 🎫 : STAR
Exploitant 📋 : Keolis Rennes et Transdev CAT 35
Véhicule 🚐 : Mercedes-Benz Citaro C2 G et MAN New Lion’s City GNV Efficient hybrid
Numéro de Parc 🅿️ : 723, 724 et 4025
Ligne 🚦 : C4 Saint Grégoire Grand Quartier <-> Za Saint Sulpice et 11 en direction de Saint Saëns
Photo 📍 : 03/12/2023 à l'arrêt République
Appareil : Canon EOS 250 D
Hashtag #️⃣: #mercedes #mercedesbenz #evobus #citaro #mercedescitaro #citaroc2 #c2G #citaroC2G #MAN #MANbus #lionscity #newlionscity #manlionscity #mantruck #lionscitygnv #manefficienthybrid #rennes #star #transdev #keolis #bus #busspotter #busspotting #busfan #busphotograph #busphotography #likebus #bustransport #transportencommun #publictransport #tcdefrance
When it comes to energy efficient design, Boulder County Housing Authority is a leader in the field.
On Tuesday, February 16th, Norrie Boyd, Erin Ganser, Maggie Crosswy, Angel Bond, Geneva Z. Bailey and Aimee Bruhn, along with our local partners, Blue Valley Energy, Farnsworth Group, and Milender White Construction Company, had an opportunity to showcase our expertise to an impressive 20-member foreign delegation. As part of the U.S. Department of Commerce’s Special American Business Internship Training (SABIT) program, the delegation included representatives from Azerbaijan, Kazakhstan, Moldova, Russia, Tajikistan, Turkmenistan, and Ukraine. These industry specialists were seeking information on trends and innovations in energy efficient construction and renewables.
BCHA and our partners hosted a breakfast and technical presentation followed by a tour of Aspinwall, Josephine Commons, and the Kestrel construction site. The delegation’s hands-on enthusiasm began the moment they looked into the geothermal mechanical room at Josephine Commons and continued as they ventured up to the roof to view the building’s solar array. They were also able to visit an apartment in Josephine Commons and were blown away by the quality design (special thanks to resident Kathy Johnston for opening her doors to the group!). Questions were flying and answered with the help of two Russian translators and our own Angel Bond.
The real fun began when the delegation visited the construction site for Kestrel, BCHA’s future 200-unit affordable housing development in Louisville. Construction was in process on the geothermal installation and the delegates watched as geothermal wells were being drilled 400 feet underground.
One of the biggest sources of pride for BCHA is that the geothermal systems we’re installing are literally paying for themselves very quickly (less than 5 years for Josephine Commons, for example) thanks to the energy savings. Our buildings are also proving themselves to be extremely energy-efficient, which further helps us with the affordability of the developments. And we’re getting better and better, incorporating “lessons learned” from each construction project into the next.
After an information-packed half-day with BHCA and our expert partners, participants are better equipped to apply energy efficiency and green building principles to construction projects in their home countries.
Voici un New MAN LION'S CITY 12 GNC EFFICIENT HYBRIDE des lignes de l'Agglo Métropole Mobilité de Aubagne. Le 1936 est en service sur la ligne 8 en provenance de la Gare d'Aubagne et à destination de Saint-Zarcharie.
Il est pris en photo sur la Route Départementale 560.
The cleanup of streets in New Orleans after Mardi Gras parades is phenomenal- one of the best shows of the season!! Efficient on another level! At the end of each final parade, the streets and neutral ground are CLEAR!
Mardi Gras 2017
New Orleans LA
The BMW i8, first introduced as the BMW Concept Vision Efficient Dynamics, is a plug-in hybrid sports car developed by BMW. The 2015 model year BMW i8 has a 7.1 kWh lithium-ion battery pack that delivers an all-electric range of 37 km (23 mi) under the New European Driving Cycle (NEDC).[5] Under the United States Environmental Protection Agency (EPA) cycle, the range in EV mode is 24 km (15 mi) with a small amount of gasoline consumption.
The BMW i8 can go from 0–100 km/h (0 to 60 mph) in 4.4 seconds and has a top speed of 250 km/h (155 mph). The BMW i8 has a fuel efficiency of 2.1 L/100 km (134.5 mpg-imp; 112.0 mpg-US) under the NEDC test with carbon emissions of 49 g/km. EPA rated the i8 combined fuel economy at 76 equivalent (MPG-equivalent) (3.1 L gasoline equivalent/100 km; 91 mpg-imp gasoline equivalent).
The initial turbodiesel concept car was unveiled at the 2009 International Motor Show Germany. The production version of the BMW i8 was unveiled at the 2013 Frankfurt Motor Show. The i8 was released in Germany in June 2014. Deliveries to retail customers in the U.S. began in August 2014. Global cumulative sales totaled almost 4,500 units through June 2015.
History
The i8 is part of BMW's "Project i" and it is being marketed as a new brand, BMW i, sold separately from BMW or Mini. The BMW i3, launched for retail customers in Europe in the fourth quarter of 2013, was the first model of the i brand available in the market, and it was followed by the i8, released in Germany in June 2014 as a 2015 model year. Other i models are expected to follow.
The initial turbodiesel concept car was unveiled at the 2009 International Motor Show Germany, In 2010, BMW announced the mass production of the Concept Vision Efficient Dynamics in Leipzig beginning in 2013 as the BMW i8. The BMW i8 gasoline-powered concept car destined for production was unveiled at the 2011 Frankfurt Motor Show. The production version of the BMW i8 was unveiled at the 2013 International Motor Show Germany. The following are the concept and pre-production models developed by BMW that precedeed the production version.
BMW Vision EfficientDynamics (2009)
BMW Vision EfficientDynamics concept car is a plug-in hybrid with a three cylinder turbodiesel engine. Additionally, there are two electric motors with 139 horsepower. It allows an acceleration to 100 km/h (62 mph) in 4.8 seconds and an electronically limited top speed of 250 km/h (160 mph).
According to BMW, the average fuel consumption in the EU test cycle (KV01) is 3.76 liters/100 kilometers, (75.1 mpg imp), and has a carbon dioxide emission rating of 99 grams per kilometer (1,3 l/100 km and 33g CO2/km ; EU-PHEV ECE-R101). The estimated all-electric range is 50 km (31 mi), and the 24-liter petrol tank extends the total vehicle range to up to 700 km (430 mi). The lightweight chassis is made mainly from aluminum. The windshield, top, doors and fenders are made from polycarbonate glass, with the body having a drag coefficient of 0.26.
The designers in charge of the BMW Vision EfficientDynamics Concept were Mario Majdandzic, Exterior Design and Jochen Paesen, Interior Design.
The vehicle was unveiled in 2009 International Motor Show Germany, followed by Auto China 2010.
BMW i8 Concept (2011)
BMW i8 Concept plug-in hybrid electric vehicle includes an electric motor located in the front axle powering the front wheels rated 96 kW (131 PS; 129 hp) and 250 N·m (184 lb·ft), a turbocharged 1.5-liter 3-cylinder gasoline engine driving rear wheels rated 164 kW (223 PS; 220 hp) and 300 N·m (221 lb·ft) of torque, with combined output of 260 kW (354 PS; 349 hp) and 550 N·m (406 lb·ft), a 7.2 kWh (26 MJ) lithium-ion battery pack that allows an all-electric range of 35 km (22 mi). All four wheels provide regenerative braking. The location of the battery pack in the energy tunnel gives the vehicle a low centre of gravity, enhancing its dynamics. Its top speed is electronically limited to 250 km/h (160 mph) and is expected to go from 0 to 100 km/h (0 to 60 mph) in 4.6 seconds. Under normal driving conditions the i8 is expected to deliver 80 mpg-US (2.9 L/100 km; 96 mpg-imp) under the European cycle. A full charge of the battery will take less than 2 hours using 220V. The positioning of the motor and engine over the axles results in optimum 50/50 weight distribution.
The vehicle was unveiled at the 2011 International Motor Show Germany, followed by CENTER 548 in New York City, 42nd Tokyo Motor Show 2011, 82nd Geneva Motor Show 2012, BMW i Born Electric Tour at the Palazzo delle Esposizioni at Via Nazionale 194 in Rome, Auto Shanghai 2013.
This concept car was featured in the film Mission: Impossible – Ghost Protocol.
BMW i8 Concept Spyder (2012)
The BMW i8 Concept Spyder included a slightly shorter wheelbase and overall length over the BMW i8 Concept, carbon-fibre-reinforced plastic (CFRP) Life module, drive modules made primarily from aluminium components, interlocking of surfaces and lines, 8.8-inch (22.4 cm) screen display, off-white outer layer, orange tone naturally tanned leather upholstery.
The vehicle was unveiled in Auto China 2012 in Beijing and won Concept Car of the Year, followed by 83rd Geneva International Motor Show 2013.
The designer of the BMW i8 Concept Spyder was Richard Kim.
BMW i8 coupe prototype (2013)
The design of the BMW i8 coupe prototype was based on the BMW i8 Concept. The BMW i8 prototype has an average fuel efficiency of less than 2.5 L/100 km (113.0 mpg-imp; 94.1 mpg-US) under the New European Driving Cycle with carbon emissions of less than 59 g/km. The i8 with its carbon-fiber-reinforced plastic (CFRP) passenger cell lightweight, aerodynamically optimized body, and BMW eDrive technology offers the dynamic performance of a sports car, with an expected 0–100 km (0–60 mi) sprint time of less than 4.5 seconds using both power sources. The plug-in hybrid system of the BMW i8 comprises a three-cylinder, 1.5-liter BMW TwinPower turbo gasoline engine combined with BMW eDrive technology used in the BMW i3 and develops maximum power of 170 kW (230 hp). The BMW i8 is the first BMW production model to be powered by a three-cylinder gasoline engine and the resulting specific output of 115 kW (154 hp) per liter of displacement is on a par with high-performance sports car engines and is the highest of any engine produced by the BMW Group.
The BMW i8's second power source is a hybrid synchronous electric motor specially developed and produced by the BMW Group for BMW i. The electric motor develops maximum power of 131 hp (96 kW) and produces its maximum torque of around 320 N·m (240 lbf·ft) from standstill. Typical of an electric motor, responsive power is instantly available when starting and this continues into the higher load ranges. As well as providing a power boost to assist the gasoline engine during acceleration, the electric motor can also power the vehicle by itself. Top speed in electric mode is approximately 120 km/h (75 mph), with a maximum driving range of up to 35 km (22 mi). Linear acceleration is maintained even at higher speeds since the interplay between the two power sources efficiently absorbs any power flow interruptions when shifting gears. The BMW i8 has an electronically controlled top speed of 250 km (160 mi), which can be reached and maintained when the vehicle operates solely on the gasoline engine. The model-specific version of the high-voltage 7.2 lithium-ion battery has a liquid cooling system and can be recharged at a conventional household power socket, at a BMW i Wallbox or at a public charging station. In the US a full recharge takes approximately 3.5 hours from a conventional 120V, 12 amp household circuit or approximately 1.5 hours from a 220V Level 2 charger.
The driver can also select several driving modes: SPORT, COMFORT and ECO PRO. Using the gear selector, the driver can either select position D for automated gear selection or can switch to SPORT mode. SPORT mode offers manual gear selection and at the same time switches to very sporty drive and suspension settings. In SPORT mode, the engine and electric motor deliver extra performance, accelerator response is faster and the power boost from the electric motor is maximized. And to keep the battery topped up, SPORT mode also activates maximum energy recuperation during overrun and braking as the electric motor’s generator function, which recharges the battery using kinetic energy, switches to a more powerful setting. The Driving Experience Control switch on the center console offers a choice of two settings. On starting, COMFORT mode is activated, which offers a balance between sporty performance and fuel efficiency, with unrestricted access to all convenience functions. Alternatively, the ECO PRO mode can be engaged, which, on the BMW i8 as on other models, supports an efficiency-optimized driving style. On this mode the powertrain controller coordinates the cooperation between the gasoline engine and the electric motor for maximum fuel economy. On deceleration, the intelligent energy management system automatically decides, in line with the driving situation and vehicle status, whether to recuperate braking energy or to coast with the powertrain disengaged. At the same time, ECO PRO mode also programs electrical convenience functions such as the air conditioning, seat heating and heated mirrors to operate at minimum power consumption, but without compromising safety. The maximum driving range of the BMW i8 on a full fuel tank and with a fully charged battery is more than 500 km (310 mi) in COMFORT mode, which can be increased by up to 20% in ECO PRO mode. The BMW i8’s ECO PRO mode can also be used during all-electric operation. The vehicle is then powered solely by the electric motor. Only if the battery charge drops below a given level, or under sudden intense throttle application such as kickdown, is the internal combustion engine automatically activated.
The vehicle was unveiled in BMW Group's Miramas test track in France.
Production version
The production BMW i8 was designed by Benoit Jacob. The production version was unveiled at the 2013 International Motor Show Germany, followed by 2013 Les Voiles de Saint-Tropez. It features butterfly doors, head-up display, rear-view cameras and partially false engine noise. Series production of customer vehicles began in April 2014. It is the first production car with laser headlights, reaching further than LED lights.
The i8 has a low vehicle weight of 1,485 kg (3,274 lb) (DIN kerb weight) and a low drag coefficient (Cd) of 0.26. In all-electric mode the BMW i8 has a top speed of 120 km/h (75 mph). In Sport mode the i8 delivers a mid-range acceleration from 80 to 120 km/h (50 to 75 mph) in 2.6 seconds. The electronically controlled top speed is 250 km/h (160 mph).
Range and fuel economy[edit]
The production i8 has a 7.1 kWh lithium-ion battery pack with a usable capacity of 5.2 kWh and intelligent energy management that delivers an all-electric range of 37 km (23 mi) under the NEDC cycle. Under the EPA cycle, the range in EV mode is 15 mi (24 km), with a gasoline consumption of 0.1 gallons per 100 mi, and as a result, EPA's all-electric range is zero. The total range is 330 mi (530 km).
The production version has a fuel efficiency of 2.1 L/100 km (134.5 mpg-imp; 112.0 mpg-US) under the NEDC test with carbon emissions of 49 g/km.[5] Under EPA cycle, the i8 combined fuel economy in EV mode was rated 76 equivalent (MPG-equivalent) (3.1 L gasoline equivalent/100 km; 91 mpg-imp gasoline equivalent), with an energy consumption of 43 kW-hrs/100 mi and gasoline consumption of 0.1 gal-US/100 mi. The combined fuel economy when running only with gasoline is 28 mpg-US (8.4 L/100 km; 34 mpg-imp), 28 mpg-US (8.4 L/100 km; 34 mpg-imp) for city driving, and 29 mpg-US (8.1 L/100 km; 35 mpg-imp) in highway.
The U.S. Environmental Protection Agency's 2014 edition of the "Light-Duty Automotive Technology, Carbon Dioxide Emissions, and Fuel Economy Trends" introduced utility factors for plug-in hybrids to represent the percentage of miles that will be driven using electricity by an average driver, in electric only or blended modes. The BMW i8 has a utility factor in EV mode of 37%, compared with 83% for the BMW i3 REx, 66% for the Chevrolet Volt, 65% for the Cadillac ELR, 45% for the Ford Energi models, 43% for the McLaren P1, 39% for the Porsche Panamera S E-Hybrid, and 29% for the Toyota Prius PHV.
[Text from Wikipedia]
This Lego miniland-scale BMW i8 has been created for Flickr LUGNuts' 94th Build Challenge, - "Appease the Elves Summer Automobile Build-off (Part 2)", - a design challenge combining the resources of LUGNuts, TheLegoCarBlog (TLCB) and Head Turnerz.
These two Officer of the Chicago Police Mounted Unit have, quite appropriately in my view, parked their mounts in the space reserved for "fuel efficient vehicle parking only!"
2916 W. 47th Street.
The BMW i8, first introduced as the BMW Concept Vision Efficient Dynamics, is a plug-in hybrid sports car developed by BMW. The 2015 model year BMW i8 has a 7.1 kWh lithium-ion battery pack that delivers an all-electric range of 37 km (23 mi) under the New European Driving Cycle (NEDC).[5] Under the United States Environmental Protection Agency (EPA) cycle, the range in EV mode is 24 km (15 mi) with a small amount of gasoline consumption.
The BMW i8 can go from 0–100 km/h (0 to 60 mph) in 4.4 seconds and has a top speed of 250 km/h (155 mph). The BMW i8 has a fuel efficiency of 2.1 L/100 km (134.5 mpg-imp; 112.0 mpg-US) under the NEDC test with carbon emissions of 49 g/km. EPA rated the i8 combined fuel economy at 76 equivalent (MPG-equivalent) (3.1 L gasoline equivalent/100 km; 91 mpg-imp gasoline equivalent).
The initial turbodiesel concept car was unveiled at the 2009 International Motor Show Germany. The production version of the BMW i8 was unveiled at the 2013 Frankfurt Motor Show. The i8 was released in Germany in June 2014. Deliveries to retail customers in the U.S. began in August 2014. Global cumulative sales totaled almost 4,500 units through June 2015.
History
The i8 is part of BMW's "Project i" and it is being marketed as a new brand, BMW i, sold separately from BMW or Mini. The BMW i3, launched for retail customers in Europe in the fourth quarter of 2013, was the first model of the i brand available in the market, and it was followed by the i8, released in Germany in June 2014 as a 2015 model year. Other i models are expected to follow.
The initial turbodiesel concept car was unveiled at the 2009 International Motor Show Germany, In 2010, BMW announced the mass production of the Concept Vision Efficient Dynamics in Leipzig beginning in 2013 as the BMW i8. The BMW i8 gasoline-powered concept car destined for production was unveiled at the 2011 Frankfurt Motor Show. The production version of the BMW i8 was unveiled at the 2013 International Motor Show Germany. The following are the concept and pre-production models developed by BMW that precedeed the production version.
BMW Vision EfficientDynamics (2009)
BMW Vision EfficientDynamics concept car is a plug-in hybrid with a three cylinder turbodiesel engine. Additionally, there are two electric motors with 139 horsepower. It allows an acceleration to 100 km/h (62 mph) in 4.8 seconds and an electronically limited top speed of 250 km/h (160 mph).
According to BMW, the average fuel consumption in the EU test cycle (KV01) is 3.76 liters/100 kilometers, (75.1 mpg imp), and has a carbon dioxide emission rating of 99 grams per kilometer (1,3 l/100 km and 33g CO2/km ; EU-PHEV ECE-R101). The estimated all-electric range is 50 km (31 mi), and the 24-liter petrol tank extends the total vehicle range to up to 700 km (430 mi). The lightweight chassis is made mainly from aluminum. The windshield, top, doors and fenders are made from polycarbonate glass, with the body having a drag coefficient of 0.26.
The designers in charge of the BMW Vision EfficientDynamics Concept were Mario Majdandzic, Exterior Design and Jochen Paesen, Interior Design.
The vehicle was unveiled in 2009 International Motor Show Germany, followed by Auto China 2010.
BMW i8 Concept (2011)
BMW i8 Concept plug-in hybrid electric vehicle includes an electric motor located in the front axle powering the front wheels rated 96 kW (131 PS; 129 hp) and 250 N·m (184 lb·ft), a turbocharged 1.5-liter 3-cylinder gasoline engine driving rear wheels rated 164 kW (223 PS; 220 hp) and 300 N·m (221 lb·ft) of torque, with combined output of 260 kW (354 PS; 349 hp) and 550 N·m (406 lb·ft), a 7.2 kWh (26 MJ) lithium-ion battery pack that allows an all-electric range of 35 km (22 mi). All four wheels provide regenerative braking. The location of the battery pack in the energy tunnel gives the vehicle a low centre of gravity, enhancing its dynamics. Its top speed is electronically limited to 250 km/h (160 mph) and is expected to go from 0 to 100 km/h (0 to 60 mph) in 4.6 seconds. Under normal driving conditions the i8 is expected to deliver 80 mpg-US (2.9 L/100 km; 96 mpg-imp) under the European cycle. A full charge of the battery will take less than 2 hours using 220V. The positioning of the motor and engine over the axles results in optimum 50/50 weight distribution.
The vehicle was unveiled at the 2011 International Motor Show Germany, followed by CENTER 548 in New York City, 42nd Tokyo Motor Show 2011, 82nd Geneva Motor Show 2012, BMW i Born Electric Tour at the Palazzo delle Esposizioni at Via Nazionale 194 in Rome, Auto Shanghai 2013.
This concept car was featured in the film Mission: Impossible – Ghost Protocol.
BMW i8 Concept Spyder (2012)
The BMW i8 Concept Spyder included a slightly shorter wheelbase and overall length over the BMW i8 Concept, carbon-fibre-reinforced plastic (CFRP) Life module, drive modules made primarily from aluminium components, interlocking of surfaces and lines, 8.8-inch (22.4 cm) screen display, off-white outer layer, orange tone naturally tanned leather upholstery.
The vehicle was unveiled in Auto China 2012 in Beijing and won Concept Car of the Year, followed by 83rd Geneva International Motor Show 2013.
The designer of the BMW i8 Concept Spyder was Richard Kim.
BMW i8 coupe prototype (2013)
The design of the BMW i8 coupe prototype was based on the BMW i8 Concept. The BMW i8 prototype has an average fuel efficiency of less than 2.5 L/100 km (113.0 mpg-imp; 94.1 mpg-US) under the New European Driving Cycle with carbon emissions of less than 59 g/km. The i8 with its carbon-fiber-reinforced plastic (CFRP) passenger cell lightweight, aerodynamically optimized body, and BMW eDrive technology offers the dynamic performance of a sports car, with an expected 0–100 km (0–60 mi) sprint time of less than 4.5 seconds using both power sources. The plug-in hybrid system of the BMW i8 comprises a three-cylinder, 1.5-liter BMW TwinPower turbo gasoline engine combined with BMW eDrive technology used in the BMW i3 and develops maximum power of 170 kW (230 hp). The BMW i8 is the first BMW production model to be powered by a three-cylinder gasoline engine and the resulting specific output of 115 kW (154 hp) per liter of displacement is on a par with high-performance sports car engines and is the highest of any engine produced by the BMW Group.
The BMW i8's second power source is a hybrid synchronous electric motor specially developed and produced by the BMW Group for BMW i. The electric motor develops maximum power of 131 hp (96 kW) and produces its maximum torque of around 320 N·m (240 lbf·ft) from standstill. Typical of an electric motor, responsive power is instantly available when starting and this continues into the higher load ranges. As well as providing a power boost to assist the gasoline engine during acceleration, the electric motor can also power the vehicle by itself. Top speed in electric mode is approximately 120 km/h (75 mph), with a maximum driving range of up to 35 km (22 mi). Linear acceleration is maintained even at higher speeds since the interplay between the two power sources efficiently absorbs any power flow interruptions when shifting gears. The BMW i8 has an electronically controlled top speed of 250 km (160 mi), which can be reached and maintained when the vehicle operates solely on the gasoline engine. The model-specific version of the high-voltage 7.2 lithium-ion battery has a liquid cooling system and can be recharged at a conventional household power socket, at a BMW i Wallbox or at a public charging station. In the US a full recharge takes approximately 3.5 hours from a conventional 120V, 12 amp household circuit or approximately 1.5 hours from a 220V Level 2 charger.
The driver can also select several driving modes: SPORT, COMFORT and ECO PRO. Using the gear selector, the driver can either select position D for automated gear selection or can switch to SPORT mode. SPORT mode offers manual gear selection and at the same time switches to very sporty drive and suspension settings. In SPORT mode, the engine and electric motor deliver extra performance, accelerator response is faster and the power boost from the electric motor is maximized. And to keep the battery topped up, SPORT mode also activates maximum energy recuperation during overrun and braking as the electric motor’s generator function, which recharges the battery using kinetic energy, switches to a more powerful setting. The Driving Experience Control switch on the center console offers a choice of two settings. On starting, COMFORT mode is activated, which offers a balance between sporty performance and fuel efficiency, with unrestricted access to all convenience functions. Alternatively, the ECO PRO mode can be engaged, which, on the BMW i8 as on other models, supports an efficiency-optimized driving style. On this mode the powertrain controller coordinates the cooperation between the gasoline engine and the electric motor for maximum fuel economy. On deceleration, the intelligent energy management system automatically decides, in line with the driving situation and vehicle status, whether to recuperate braking energy or to coast with the powertrain disengaged. At the same time, ECO PRO mode also programs electrical convenience functions such as the air conditioning, seat heating and heated mirrors to operate at minimum power consumption, but without compromising safety. The maximum driving range of the BMW i8 on a full fuel tank and with a fully charged battery is more than 500 km (310 mi) in COMFORT mode, which can be increased by up to 20% in ECO PRO mode. The BMW i8’s ECO PRO mode can also be used during all-electric operation. The vehicle is then powered solely by the electric motor. Only if the battery charge drops below a given level, or under sudden intense throttle application such as kickdown, is the internal combustion engine automatically activated.
The vehicle was unveiled in BMW Group's Miramas test track in France.
Production version
The production BMW i8 was designed by Benoit Jacob. The production version was unveiled at the 2013 International Motor Show Germany, followed by 2013 Les Voiles de Saint-Tropez. It features butterfly doors, head-up display, rear-view cameras and partially false engine noise. Series production of customer vehicles began in April 2014. It is the first production car with laser headlights, reaching further than LED lights.
The i8 has a low vehicle weight of 1,485 kg (3,274 lb) (DIN kerb weight) and a low drag coefficient (Cd) of 0.26. In all-electric mode the BMW i8 has a top speed of 120 km/h (75 mph). In Sport mode the i8 delivers a mid-range acceleration from 80 to 120 km/h (50 to 75 mph) in 2.6 seconds. The electronically controlled top speed is 250 km/h (160 mph).
Range and fuel economy[edit]
The production i8 has a 7.1 kWh lithium-ion battery pack with a usable capacity of 5.2 kWh and intelligent energy management that delivers an all-electric range of 37 km (23 mi) under the NEDC cycle. Under the EPA cycle, the range in EV mode is 15 mi (24 km), with a gasoline consumption of 0.1 gallons per 100 mi, and as a result, EPA's all-electric range is zero. The total range is 330 mi (530 km).
The production version has a fuel efficiency of 2.1 L/100 km (134.5 mpg-imp; 112.0 mpg-US) under the NEDC test with carbon emissions of 49 g/km.[5] Under EPA cycle, the i8 combined fuel economy in EV mode was rated 76 equivalent (MPG-equivalent) (3.1 L gasoline equivalent/100 km; 91 mpg-imp gasoline equivalent), with an energy consumption of 43 kW-hrs/100 mi and gasoline consumption of 0.1 gal-US/100 mi. The combined fuel economy when running only with gasoline is 28 mpg-US (8.4 L/100 km; 34 mpg-imp), 28 mpg-US (8.4 L/100 km; 34 mpg-imp) for city driving, and 29 mpg-US (8.1 L/100 km; 35 mpg-imp) in highway.
The U.S. Environmental Protection Agency's 2014 edition of the "Light-Duty Automotive Technology, Carbon Dioxide Emissions, and Fuel Economy Trends" introduced utility factors for plug-in hybrids to represent the percentage of miles that will be driven using electricity by an average driver, in electric only or blended modes. The BMW i8 has a utility factor in EV mode of 37%, compared with 83% for the BMW i3 REx, 66% for the Chevrolet Volt, 65% for the Cadillac ELR, 45% for the Ford Energi models, 43% for the McLaren P1, 39% for the Porsche Panamera S E-Hybrid, and 29% for the Toyota Prius PHV.
[Text from Wikipedia]
This Lego miniland-scale BMW i8 has been created for Flickr LUGNuts' 94th Build Challenge, - "Appease the Elves Summer Automobile Build-off (Part 2)", - a design challenge combining the resources of LUGNuts, TheLegoCarBlog (TLCB) and Head Turnerz.
The BMW i8, first introduced as the BMW Concept Vision Efficient Dynamics, is a plug-in hybrid sports car developed by BMW. The 2015 model year BMW i8 has a 7.1 kWh lithium-ion battery pack that delivers an all-electric range of 37 km (23 mi) under the New European Driving Cycle (NEDC).[5] Under the United States Environmental Protection Agency (EPA) cycle, the range in EV mode is 24 km (15 mi) with a small amount of gasoline consumption.
The BMW i8 can go from 0–100 km/h (0 to 60 mph) in 4.4 seconds and has a top speed of 250 km/h (155 mph). The BMW i8 has a fuel efficiency of 2.1 L/100 km (134.5 mpg-imp; 112.0 mpg-US) under the NEDC test with carbon emissions of 49 g/km. EPA rated the i8 combined fuel economy at 76 equivalent (MPG-equivalent) (3.1 L gasoline equivalent/100 km; 91 mpg-imp gasoline equivalent).
The initial turbodiesel concept car was unveiled at the 2009 International Motor Show Germany. The production version of the BMW i8 was unveiled at the 2013 Frankfurt Motor Show. The i8 was released in Germany in June 2014. Deliveries to retail customers in the U.S. began in August 2014. Global cumulative sales totaled almost 4,500 units through June 2015.
History
The i8 is part of BMW's "Project i" and it is being marketed as a new brand, BMW i, sold separately from BMW or Mini. The BMW i3, launched for retail customers in Europe in the fourth quarter of 2013, was the first model of the i brand available in the market, and it was followed by the i8, released in Germany in June 2014 as a 2015 model year. Other i models are expected to follow.
The initial turbodiesel concept car was unveiled at the 2009 International Motor Show Germany, In 2010, BMW announced the mass production of the Concept Vision Efficient Dynamics in Leipzig beginning in 2013 as the BMW i8. The BMW i8 gasoline-powered concept car destined for production was unveiled at the 2011 Frankfurt Motor Show. The production version of the BMW i8 was unveiled at the 2013 International Motor Show Germany. The following are the concept and pre-production models developed by BMW that precedeed the production version.
BMW Vision EfficientDynamics (2009)
BMW Vision EfficientDynamics concept car is a plug-in hybrid with a three cylinder turbodiesel engine. Additionally, there are two electric motors with 139 horsepower. It allows an acceleration to 100 km/h (62 mph) in 4.8 seconds and an electronically limited top speed of 250 km/h (160 mph).
According to BMW, the average fuel consumption in the EU test cycle (KV01) is 3.76 liters/100 kilometers, (75.1 mpg imp), and has a carbon dioxide emission rating of 99 grams per kilometer (1,3 l/100 km and 33g CO2/km ; EU-PHEV ECE-R101). The estimated all-electric range is 50 km (31 mi), and the 24-liter petrol tank extends the total vehicle range to up to 700 km (430 mi). The lightweight chassis is made mainly from aluminum. The windshield, top, doors and fenders are made from polycarbonate glass, with the body having a drag coefficient of 0.26.
The designers in charge of the BMW Vision EfficientDynamics Concept were Mario Majdandzic, Exterior Design and Jochen Paesen, Interior Design.
The vehicle was unveiled in 2009 International Motor Show Germany, followed by Auto China 2010.
BMW i8 Concept (2011)
BMW i8 Concept plug-in hybrid electric vehicle includes an electric motor located in the front axle powering the front wheels rated 96 kW (131 PS; 129 hp) and 250 N·m (184 lb·ft), a turbocharged 1.5-liter 3-cylinder gasoline engine driving rear wheels rated 164 kW (223 PS; 220 hp) and 300 N·m (221 lb·ft) of torque, with combined output of 260 kW (354 PS; 349 hp) and 550 N·m (406 lb·ft), a 7.2 kWh (26 MJ) lithium-ion battery pack that allows an all-electric range of 35 km (22 mi). All four wheels provide regenerative braking. The location of the battery pack in the energy tunnel gives the vehicle a low centre of gravity, enhancing its dynamics. Its top speed is electronically limited to 250 km/h (160 mph) and is expected to go from 0 to 100 km/h (0 to 60 mph) in 4.6 seconds. Under normal driving conditions the i8 is expected to deliver 80 mpg-US (2.9 L/100 km; 96 mpg-imp) under the European cycle. A full charge of the battery will take less than 2 hours using 220V. The positioning of the motor and engine over the axles results in optimum 50/50 weight distribution.
The vehicle was unveiled at the 2011 International Motor Show Germany, followed by CENTER 548 in New York City, 42nd Tokyo Motor Show 2011, 82nd Geneva Motor Show 2012, BMW i Born Electric Tour at the Palazzo delle Esposizioni at Via Nazionale 194 in Rome, Auto Shanghai 2013.
This concept car was featured in the film Mission: Impossible – Ghost Protocol.
BMW i8 Concept Spyder (2012)
The BMW i8 Concept Spyder included a slightly shorter wheelbase and overall length over the BMW i8 Concept, carbon-fibre-reinforced plastic (CFRP) Life module, drive modules made primarily from aluminium components, interlocking of surfaces and lines, 8.8-inch (22.4 cm) screen display, off-white outer layer, orange tone naturally tanned leather upholstery.
The vehicle was unveiled in Auto China 2012 in Beijing and won Concept Car of the Year, followed by 83rd Geneva International Motor Show 2013.
The designer of the BMW i8 Concept Spyder was Richard Kim.
BMW i8 coupe prototype (2013)
The design of the BMW i8 coupe prototype was based on the BMW i8 Concept. The BMW i8 prototype has an average fuel efficiency of less than 2.5 L/100 km (113.0 mpg-imp; 94.1 mpg-US) under the New European Driving Cycle with carbon emissions of less than 59 g/km. The i8 with its carbon-fiber-reinforced plastic (CFRP) passenger cell lightweight, aerodynamically optimized body, and BMW eDrive technology offers the dynamic performance of a sports car, with an expected 0–100 km (0–60 mi) sprint time of less than 4.5 seconds using both power sources. The plug-in hybrid system of the BMW i8 comprises a three-cylinder, 1.5-liter BMW TwinPower turbo gasoline engine combined with BMW eDrive technology used in the BMW i3 and develops maximum power of 170 kW (230 hp). The BMW i8 is the first BMW production model to be powered by a three-cylinder gasoline engine and the resulting specific output of 115 kW (154 hp) per liter of displacement is on a par with high-performance sports car engines and is the highest of any engine produced by the BMW Group.
The BMW i8's second power source is a hybrid synchronous electric motor specially developed and produced by the BMW Group for BMW i. The electric motor develops maximum power of 131 hp (96 kW) and produces its maximum torque of around 320 N·m (240 lbf·ft) from standstill. Typical of an electric motor, responsive power is instantly available when starting and this continues into the higher load ranges. As well as providing a power boost to assist the gasoline engine during acceleration, the electric motor can also power the vehicle by itself. Top speed in electric mode is approximately 120 km/h (75 mph), with a maximum driving range of up to 35 km (22 mi). Linear acceleration is maintained even at higher speeds since the interplay between the two power sources efficiently absorbs any power flow interruptions when shifting gears. The BMW i8 has an electronically controlled top speed of 250 km (160 mi), which can be reached and maintained when the vehicle operates solely on the gasoline engine. The model-specific version of the high-voltage 7.2 lithium-ion battery has a liquid cooling system and can be recharged at a conventional household power socket, at a BMW i Wallbox or at a public charging station. In the US a full recharge takes approximately 3.5 hours from a conventional 120V, 12 amp household circuit or approximately 1.5 hours from a 220V Level 2 charger.
The driver can also select several driving modes: SPORT, COMFORT and ECO PRO. Using the gear selector, the driver can either select position D for automated gear selection or can switch to SPORT mode. SPORT mode offers manual gear selection and at the same time switches to very sporty drive and suspension settings. In SPORT mode, the engine and electric motor deliver extra performance, accelerator response is faster and the power boost from the electric motor is maximized. And to keep the battery topped up, SPORT mode also activates maximum energy recuperation during overrun and braking as the electric motor’s generator function, which recharges the battery using kinetic energy, switches to a more powerful setting. The Driving Experience Control switch on the center console offers a choice of two settings. On starting, COMFORT mode is activated, which offers a balance between sporty performance and fuel efficiency, with unrestricted access to all convenience functions. Alternatively, the ECO PRO mode can be engaged, which, on the BMW i8 as on other models, supports an efficiency-optimized driving style. On this mode the powertrain controller coordinates the cooperation between the gasoline engine and the electric motor for maximum fuel economy. On deceleration, the intelligent energy management system automatically decides, in line with the driving situation and vehicle status, whether to recuperate braking energy or to coast with the powertrain disengaged. At the same time, ECO PRO mode also programs electrical convenience functions such as the air conditioning, seat heating and heated mirrors to operate at minimum power consumption, but without compromising safety. The maximum driving range of the BMW i8 on a full fuel tank and with a fully charged battery is more than 500 km (310 mi) in COMFORT mode, which can be increased by up to 20% in ECO PRO mode. The BMW i8’s ECO PRO mode can also be used during all-electric operation. The vehicle is then powered solely by the electric motor. Only if the battery charge drops below a given level, or under sudden intense throttle application such as kickdown, is the internal combustion engine automatically activated.
The vehicle was unveiled in BMW Group's Miramas test track in France.
Production version
The production BMW i8 was designed by Benoit Jacob. The production version was unveiled at the 2013 International Motor Show Germany, followed by 2013 Les Voiles de Saint-Tropez. It features butterfly doors, head-up display, rear-view cameras and partially false engine noise. Series production of customer vehicles began in April 2014. It is the first production car with laser headlights, reaching further than LED lights.
The i8 has a low vehicle weight of 1,485 kg (3,274 lb) (DIN kerb weight) and a low drag coefficient (Cd) of 0.26. In all-electric mode the BMW i8 has a top speed of 120 km/h (75 mph). In Sport mode the i8 delivers a mid-range acceleration from 80 to 120 km/h (50 to 75 mph) in 2.6 seconds. The electronically controlled top speed is 250 km/h (160 mph).
Range and fuel economy[edit]
The production i8 has a 7.1 kWh lithium-ion battery pack with a usable capacity of 5.2 kWh and intelligent energy management that delivers an all-electric range of 37 km (23 mi) under the NEDC cycle. Under the EPA cycle, the range in EV mode is 15 mi (24 km), with a gasoline consumption of 0.1 gallons per 100 mi, and as a result, EPA's all-electric range is zero. The total range is 330 mi (530 km).
The production version has a fuel efficiency of 2.1 L/100 km (134.5 mpg-imp; 112.0 mpg-US) under the NEDC test with carbon emissions of 49 g/km.[5] Under EPA cycle, the i8 combined fuel economy in EV mode was rated 76 equivalent (MPG-equivalent) (3.1 L gasoline equivalent/100 km; 91 mpg-imp gasoline equivalent), with an energy consumption of 43 kW-hrs/100 mi and gasoline consumption of 0.1 gal-US/100 mi. The combined fuel economy when running only with gasoline is 28 mpg-US (8.4 L/100 km; 34 mpg-imp), 28 mpg-US (8.4 L/100 km; 34 mpg-imp) for city driving, and 29 mpg-US (8.1 L/100 km; 35 mpg-imp) in highway.
The U.S. Environmental Protection Agency's 2014 edition of the "Light-Duty Automotive Technology, Carbon Dioxide Emissions, and Fuel Economy Trends" introduced utility factors for plug-in hybrids to represent the percentage of miles that will be driven using electricity by an average driver, in electric only or blended modes. The BMW i8 has a utility factor in EV mode of 37%, compared with 83% for the BMW i3 REx, 66% for the Chevrolet Volt, 65% for the Cadillac ELR, 45% for the Ford Energi models, 43% for the McLaren P1, 39% for the Porsche Panamera S E-Hybrid, and 29% for the Toyota Prius PHV.
[Text from Wikipedia]
This Lego miniland-scale BMW i8 has been created for Flickr LUGNuts' 94th Build Challenge, - "Appease the Elves Summer Automobile Build-off (Part 2)", - a design challenge combining the resources of LUGNuts, TheLegoCarBlog (TLCB) and Head Turnerz.
Quick visual representation of the difference between be efficient and be effective.
Efficient: you have managed your time well, but we don't know if you have achieved your purpose. Effective: you have achieved your purpose, but we don't know how you have managed your time.
The future of construction vehicles is here ! This multipurpose mech can work on all terrains thanks to its six legs, and can be twice as efficient as your usual machine with its two independent and fully articulated arms ! Attach the tool of your choosing, and you're ready to work ! You can grab, drill, cut, or dig, with a single machine ! And if you need help on the construction site, the remote controlled crab drone is here !
• With the claws on, the mech measures 39.4 x 33.3 x 18.5 studs / 12.4 x 10.5 x 5.8in / 31.5 x 26.6 x 14.8cm (L x W x H)
• The steel beam measures 36 studs / 11.3in / 28.8cm long and can be split in three sections.
• The drone crab measures 9.7 x 9.1 x 5 studs / 3 x 2.9 x 1.6in / 7.7 x 7.3 x 4cm (L x W x H)
• The model comes with three minifigs : a pilot, a copilot, and a drone operator.
• The mech can use five functional tools : two claws, a bucket, a drill, and a circular saw blade.
• Open the windscreen to access the cockpit, with seats and coffee for the pilot and the copilot.
• The front and back legs can move back and forth, and the arms are fully articulated.
Instructions available on Rebrickable : rebrickable.com/mocs/MOC-216982/Leewan/construction-crab-...
+++ DISCLAIMER +++
Nothing you see here is real, even though the conversion or the presented background story might be based historical facts. BEWARE!
Some background:
The "Entwicklung" tank series (= "development"), more commonly known as the E-Series, was a late-World War II attempt by Germany to produce a standardized series of tank designs. There were to be six standard designs in different weight classes, from which several specialized variants were to be developed. This intended to reverse the trend of extremely complex tank designs that had resulted in poor production rates and mechanical unreliability.
The E-series designs were simpler, cheaper to produce and more efficient than their predecessors; however, their design offered only modest improvements in armor and firepower over the designs they were intended to replace, such as the Jagdpanzer 38(t), Panther Ausf. G or Tiger II. However, the resulting high degree of standardization of German armored vehicles would also have made logistics and maintenance easier. Indeed, nearly all E-series vehicles — up through and including the E-75 — were intended to use what were essentially the Tiger II's 80 cm (31½ in) diameter, steel-rimmed road wheels for their suspension, meant to overlap each other (as on the later production Tiger I-E and Panther designs that also used them), even though in a highly simplified fashion. For instance, while the E-50/75’s running gear resembled outwardly the Tiger II’s, the latter’s torsion bar suspension, which necessitated a complex hull with many openings, was replaced by very compact conical spring coil packages that each held a pair of interleaved road wheels – with the benefit that all suspension elements remained outside of the hull. This considerably simplified production and saved time as well as scarce material.
Focus of initial chassis and combat vehicle development was the E-50/75 Standardpanzer, designed by Adler. These were two mostly identical vehicles and only differed in armor thickness, overall weight and running gear design to cope with the different weights. While the E-50 was the standardized replacement for the medium PzKpfw. V “Panther” and the last operational PzKpfw. VI “Tiger”, with an operational weight of around 50 tons, the E-75 was intended to become the standard heavy tank in the 70 ton class, as a replacement for the Tiger II battle tank and the Jagdtiger SPG. They were to share many components, including the same Maybach HL 234 engine with up to 900 hp output and the drivetrain, as well as running gear elements and almost all peripheral equipment. Both E-50 and E-75 were built on the same production lines for ease of manufacture.
This universal tank chassis would, beyond the primary use for battle tanks, also become the basis for a wide range of specialized support vehicles like self-propelled artillery, assault guns, tank hunters and anti-aircraft weapon carriers, which would gradually replace and standardize the great variety of former support vehicles, dramatically optimizing maintenance and logistics.
The E-50/75 SPAAG sub-family itself was quite diversified and comprised a wide range of vehicles that mainly carried different turrets with the respective weaponry as well as air space surveillance, targeting and command equipment. The range of armament included not only guns of various calibers for short, medium and long range in armored and mostly fully enclosed turrets, there were furthermore armored launch ramps for anti-aircraft missiles, including the guided “Rheintochter”, “Wasserfall” or “Enzian” SAMs as well as batteries with unguided “Taifun” anti-aircraft missiles.
Among this new vehicle family, the heaviest gun that was carried in a fully enclosed turret was the Rheinmetall 8.8 cm Flak 41. This was an improved version of the powerful pre-war 8.8 cm Flak 36/37 that was also developed into an anti-tank gun and became the main armament for Germany’s heavy battle tanks like the Tiger I: the 8.8 cm PaK 43 and KwK 43, respectively.
The 8.8 cm Flak 41 was a mobile field weapon on a new pedestal mounting that lowered its silhouette, and it used a longer barrel and a longer 88 mm cartridge with an increased propellant load. The shells had a weight of 9.4-kilogram (20 lb) and achieved a muzzle velocity of 1,000 m/s (3,280 ft/s), giving the gun an effective ceiling of 11,300 meters (37,100 ft) and a maximum of 14,700 meters (48,200 ft). The barrel initially consisted of three sections and had a length of 74 calibers but was then redesigned to a simpler dual-section barrel with a length of 72 calibers, for easier manufacture. Improvements in reloading raised the manual firing rate, with 20 to 25 rounds a minute being quoted. The Flak 41 could also be used against ground targets and was able to penetrate about 200 mm (7.9 inches) of armor at 1,000 m (3,280 feet), allowing it to defeat the armor of any contemporary tank from a relatively safe distance. Because of the high cost and complexity of this weapon, however, Rheinmetall manufactured relatively few of them, 556 in all. 399 were fielded, the rest went into SPAAG production.
The new pedestal mounting made it easy to adapt the weapon to a vehicle, so that this formidable weapon was immediately earmarked to be combined with a tank chassis to improve its mobility. Since an SPAAG would not need the massive frontal armor of a battle tank, the hull from the lighter E-50 was used (which still had a maximum armor thickness of 60mm at the front at 30°, which was effectively 120 mm vs. the E-75’s 185 mm), but instead of the E-50 MBT’s running gear with six steel wheels per side, the Flak 41 SPAAG used the heavier E-75’s running gear with eight wheels per side and wider tracks, effectively creating a hybrid E-50/75 chassis. This measure was taken to better distribute the vehicle’s overall weight and stabilize the it while moving and firing. In this form the new vehicle received the designation Sd.Kfz. 192/3, also known as “Einheits-Flakpanzer E-50 (88 mm)” or “E-50-41” for short.
The Flak 41 was integrated into Rheinmetall’s standardized SPAAG turret that could carry a wide range of automatic anti-aircraft weapons. It was a spacious, boxy design, optimized for maximum internal space than for effective armor protection, resulting in almost vertical side walls and a high silhouette. However, the level of armor was sufficient to protect the crew and the equipment inside from 20 mm gun shells – the typical armament of Allied fighter bombers of the time like the Hawker Typhoon and Tempest.
A heavy-duty hydraulic gun mount with a reinforced recoil system allowed an elevation of the Flak 41 between +83° and -3°. As a novel feature the weapon received a semi-automatic loading mechanism. This was the attempt to increase the gun’s excellent manual rate of fire even further, and it mimicked the magazine clips of the smaller 37 mm Flak 37 that contained seven rounds for short, continuous bursts of fire. A belt feed for truly continuous fire had been envisioned, but not possible with the long and heavy 88 mm rounds within the turret and chassis limits. A mechanical magazine solution, e. g. a drum with several rounds, was impossible, too. The most practical solution was a spiral-shaped magazine, driven by simple gravitation and directly attached to the Flak 41’s breech. This feeding could – beyond an initial round already in the barrel – hold up to three more rounds, and upon firing and expelling the empty case, a fresh round automatically fell into place. The rounds from the magazine could be fired in a fully automatic mode in a short burst with a rate of 50-55 RPM. The magazine itself had to be filled manually, though, and the gun could alternatively be fed directly, too, so that different types of ammunition could be prepared and the gunner could switch between them on short notice.
To accommodate the weapon’s longer ammunition (the Flak 41’s cartridge was 855 mm long) and a crew of four (commander, gunner and two loaders), the standard Rheinmetall Flak turret had to be extended at the rear. Anti-aircraft aiming was done visually, a stereoscopic rangefinder with a span of 200 cm (78¾ in) was integrated above the gun mount. A secondary ZF.20 scope for ground targets was available, too. Two more crewmen, the driver and a radio operator, sat in the hull in front of the turret, similar to the E-50/75 battle tank’s layout. The radio operator on the right side also acted as a third loader for the ammunition supply stored in the hull’s front.
Initially, no secondary defensive armament was provided since the new SPAAGs were to be operated in specialized anti-aircraft units, the so-called Fla-Züge, in which the SPAAGs’ protection would be taken over by supporting infantry and other dedicated vehicles. However, initial field experience quickly revealed this weak spot in the vehicle’s close-range defense: due to material and personnel shortages the Fla-Züge units could hardly be equipped with everything they needed to operate as planned, so that they were in most cases just an underserved mix of SPAAGs, occasionally augmented by a command vehicle and rarely with the protection these specialized vehicles needed. Most of the time the units’ vehicles had to operate independently and were therefore left to their own devices. As a solution, a commander cupola was soon added to the Sd. Kfz.192/3’s turret that not only improved the field of view around the vehicle to assess the tactical situation and detect approaching infantrymen that tried to attach mines or throw Molotov cocktails, it also featured a remote-controlled MG 42 that could be aimed and fired by the commander from the inside. However, to re-supply the ammunition, the cupola hatch had to be opened and someone had to leave the turret’s cover and manually insert a new box of rounds. Furthermore, a 100 mm grenade launcher, a so-called “Nahverteidigungswaffe”, was mounted into the opposite side of the turret roof, too. It fired SMi 35 leaping mines for close defense against approaching infantry. This made the cramped turret interior even more cluttered, but significantly improved the vehicle’s survivability, especially in a confined, urban combat environment. Updated vehicles reached the frontline units in late 1945 and were immediately thrown into service.
Despite being a powerful weapon, several operational problems with the Sd.Kfz. 192/3 became soon apparent. The complex Flak 41 and its feeding mechanism needed constant proper maintenance and service – otherwise it easily jammed. Spent shell casing also frequently jammed the gun. The high silhouette was an innate tactical problem, but this had already been accepted during the design phase of Rheinmetall’s SPAAG standard turret. However, the tall turret was the source of an additional conceptual weakness of the Sd.Kfz. 192/3: the sheer weight of the large turret with the heavy gun frequently caused imbalances that overstressed the turret bearing and its electric drive (which had been taken over from the E-50/75 battle tanks), resulting in a jammed turret — especially when either fully loaded or when the ammunition supply was depleted. Due to the large and heavy turret, the vehicle’s center of gravity was relatively high, too, so that its off-road handling was limited. Even on paved roads the early Sd.Kfz. 192/3s tended to porpoise in tight corners and upon braking. Stiffer coil springs, introduced during the running production and retrofitted through field kits to existing vehicles, countered this flaw, even though these kits were rare due to material shortages. Sometimes the harder coil springs were distributed between two vehicles, only replacing the suspension on the front and rear pair of wheels.
A different tactical problem was the limited ammunition supply for the Flak 41. While 57 rounds were sufficient for a comparable battle tank, the semi-automatic Flak 41‘s theoretical high rate of fire meant that the Sd.Kfz. 192/3 quickly depleted this supply and could only keep up fire and its position for a very limited period, or it had to save ammunition to a point that its deployment became pointless. After spending its ammunition, the vehicle had to retreat to a safe second line position to re-supply, and this was, due to the vehicle’s limited mobility, size and the heavy and bulky rounds, a risky undertaking and meant tedious manual labor with poor protection for the supply crews. The resulting supply logistics to keep the Sd.Kfz. 192/3 operational and effective were demanding.
Nevertheless, despite these shortcoming, the Sd.Kfz. 192/3 greatly improved the heavy Flak units’ mobility and firepower, and the weapon’s effectiveness was high against both air and ground targets. Until mid-1946, a total of around forty Sd.Kfz. 192/3 were built and put into service, primarily with units that defended vital production sites in Western Germany and Saxonia.
At the time of the Sd.Kfz. 192/3’s introduction, anti-aircraft aiming was already augmented by mobile radar systems like the “Würzburg” device or special command vehicles like the Sd.Kfz. 282 “Basilisk” which combined an autonomous radar system with a powerful visual rangefinder and an integrated analogue range calculator, the Kommandogerät 40. However, fire control development had continued, and at least one Sd.Kfz. 192/3 was used in late 1946 during trials to fully automatize gun aiming and firing remotely through electric drives through “slaving” a turret to an external director. This was a modified Sd.Kfz. 282/1 that successfully controlled the Sd.Kfz. 192/3 via cable from an elevated location 50 m away from the SPAAG’s firing position. The objective of these trials was to connect several anti-aircraft weapons to a single command unit with improved sensors and high accuracy under any weather condition for concentrated and more effective fire and an improved first shot hit probability.
Specifications:
Crew: Sixe (commander, gunner, two loaders, radio operator, driver)
Weight: 64 tonnes (71 short tons)
Length: 7.27 m (23 ft 10 ¾ in) (hull only)
9.57 m (31 ft 4 ½ in) with gun forward
Width: 3.88 m (12 ft 9 in)
Height 3.46 m (11 ft 4 in)
3.81 m (12 ft 6 in) with commander cupola
Ground clearance: 495 to 510 mm (1 ft 7.5 in to 1 ft 8.1 in)
Suspension: Conical spring
Fuel capacity: 720 liters (160 imp gal; 190 US gal)
Armor:
30 – 60 mm (1.2 – 2.4 in)
Performance:
Speed
- Maximum, road: 44 km/h (27.3 mph)
- Sustained, road: 38 km/h (24 mph)
- Cross country: 15 to 20 km/h (9.3 to 12.4 mph)
Operational range: 160 km (99 miles)
Power/weight: 14 PS/tonne (12.5 hp/ton)
Engine:
V-12 Maybach HL 234 gasoline engine with 900 PS (885 hp/650 kW)
Transmission:
ZF AK 7-200 with 7 forward 1 reverse gears
Armament:
1× 8,8 cm Flak 41 L/72 anti-aircraft cannon with 57 rounds in turret and hull
1× 7.92 mm Maschinengewehr 42 with 2.400 rounds, remote-controlled on the commander cupola
The kit and its assembly:
This fictional German SPAAG never existed, not even on the drawing boards. But I wondered, after ModelCollect had released an E-100 SPAAG with a twin 88mm gun some years ago, why there was no lighter vehicle with the powerful 88 mm Flak in a closed turret? There were plans to mount this weapon onto a tracked chassis in real life, but it would have been only lightly armored. Then I recently came across a whiffy aftermarket resin turret with a single 88 mm Flak, based on the Tiger II’s Porsche turret, and I liked the idea – even though the rather MBT-esque aftermarket turret looked rather dubious and too small for my taste – esp. the potential angle of the AA weapon appeared insufficient. From this basis the idea was born to create a personal interpretation of a Flak 41 in a fully enclosed turret on a tank chassis.
The basis became the Trumpeter 1:72 E-75 kit of the twin 55 mm Flak with its boxy turret. While I initially considered a totally different turret shape, I eventually settled on a generic design that would have been used for a variety of weapons. This appeared more realistic to me and so I stuck to the Rheinmetall AA turret. However, due to the heavy weapon its certainly massive mount and bulky recoil system as well as the long rounds and a crew of four, I decided to enlarge the Rheinmetall turret. The turret was cut into a front and rear half and an 8 mm wide plug, made from 1.5 mm styrene sheet, was implanted and PSRed. To keep the turret rotatable, the rear extension had to be raised, so that the “oriel” could move over the air intake fairings on the engine cover.
Due to the longer roof, some details were modified there. The most obvious addition is a commander cupola on the left, taken from an early Panzer IV, together with a MG 42 and a small shield on a swing arm, inspired by the remote-controlled installation on some Jagdpanzer 38(t) Hetzer. A stereoscopic rangefinder was added to the turret flanks and a periscope added to one of the loader’s hatches. A cover for a ventilator was added on the right side of the roof, together with a cover for a vertical grenade launcher underneath.
Using the original turret as base, the model’s movable mount for the twin 55 mm guns was retained and the rear extension would also become a good visual balance for the new main weapon. The armor at barrels’ base was cut off and a 1:72 Flak 41, taken from a Zvezda field gun kit, was glued to it, together with parts of the field gun’s recoil system and styrene bits to blend the new gun into the rest of the turret.
The E-75 chassis was taken OOB, since it would be a standardized vehicle basis. Outwardly the hull did not bear recognizable differences to the lighter E-50, which it is supposed to represent, just with more wheels to better cope with the bulky and heavy new turret.
Thankfully, this Trumpeter kit’s vinyl tracks were molded in black – sometimes they come in a sandy beige, and it’s a PITA to paint them! As another bonus, Trumpeter’s running gear on the 1:72 E-50/75 model is of a more sturdy and simpler construction than the one on the alternative ModelCollect kit(s), making the assembly and esp. the mounting of the tracks much easier. The Trumpeter kit is simpler than the comparable ModelCollect models with the E-50/75 basis, but the result is visually quite similar.
Painting and markings:
The paint scheme uses once more typical German late WWII "Hinterhalt" camouflage colors, namely Dark Yellow, Olive Green and Red Brown. This time, however, to adapt the livery to the boxy hull and the huge turret, the pattern ended up as a kind of a splinter scheme – inspired by a real Panzer V Panther from the Eastern Front in 1943.
The basic colors became Humbrol 57 (Buff) for the RAL 7028 Dunkelgelb, in this case as a rather pale (stretched?) shade, plus large areas of brown (RAL 8017, I used this time Humbrol 98 for a darker and less reddish shade) and Humbrol 86 for the green (RAL 6003), which appears quite pale in contrast to the dark brown. The camouflage was applied over an overall coat of sand brown as a primer coat, with the intention of letting this uniform basis shine through here and there. The distribution of the darker colors is quite unique, concentrating the brown on the vehicle’s edges and the green only to the flanks of hull and turret. However, the pattern works well on the huge E-50/75, and I can imagine that it might have worked well in an urban environment, breaking up the tank’s outlines.
As a match for the upper hull the wheels were painted uniformly in the same standard colors –without any pattern, because this would be very eye-catching while on the move. The many delicate tools on the tank’s hull are molded, and instead of trying to paint them I tried something else: I rubbed over them with graphite, and this worked very well, leaving them with a dark metallic shine. Just some wooden handles were then painted with a reddish brown.
Decals/marking came next, everything was procured from the scrap box. The Balkenkreuze came from a Hasegawa Sd.Kfz. 234/2 “Puma”, the tactical code from a TL-Modellbau sheet and the small unit badges on front and back from an UM Models Bergehetzer. A dry brushing treatment with light grey followed, highlighting surface details and edges, and after painting some details and adding some rust marks with watercolors followed a coat of matt varnish.
The tracks were painted with a cloudy mix of dark grey, red brown and iron acrylic paints, and mounted after hull and running gear had been assembled. The antennae, made from heated spure material, were mounted to the turret and, finally, the tank’s lower areas were dusted with a greyish-brown mineral pigment mix, simulating dust and mud residue.
This project was realized in just two days, made easy through the Trumpeter kit’s simple construction. Most work went into the extended turret and the different main weapon, but all parts mostly fell into place – and the result looks IMHO quite believable. In fact, the E-50/75 with a Flak 41 reminds a bit of the Italian Otomatic 76 mm SPAAG from the late Eighties?
Bodie is a ghost town in the Bodie Hills east of the Sierra Nevada mountain range in Mono County, California, United States. It is about 75 miles (121 km) southeast of Lake Tahoe, and 12 mi (19 km) east-southeast of Bridgeport, at an elevation of 8,379 feet (2554 m). Bodie became a boom town in 1876 (146 years ago) after the discovery of a profitable line of gold; by 1879 it had a population of 7,000–10,000.
The town went into decline in the subsequent decades and came to be described as a ghost town by 1915 (107 years ago). The U.S. Department of the Interior recognizes the designated Bodie Historic District as a National Historic Landmark.
Also registered as a California Historical Landmark, the ghost town officially was established as Bodie State Historic Park in 1962. It receives about 200,000 visitors yearly. Bodie State Historic Park is partly supported by the Bodie Foundation.
Bodie began as a mining camp of little note following the discovery of gold in 1859 by a group of prospectors, including W. S. Bodey. Bodey died in a blizzard the following November while making a supply trip to Monoville (near present-day Mono City), never getting to see the rise of the town that was named after him. According to area pioneer Judge J. G. McClinton, the district's name was changed from "Bodey," "Body," and a few other phonetic variations, to "Bodie," after a painter in the nearby boomtown of Aurora, lettered a sign "Bodie Stables".
Gold discovered at Bodie coincided with the discovery of silver at nearby Aurora (thought to be in California, later found to be Nevada), and the distant Comstock Lode beneath Virginia City, Nevada. But while these two towns boomed, interest in Bodie remained lackluster. By 1868 only two companies had built stamp mills at Bodie, and both had failed.
In 1876, the Standard Company discovered a profitable deposit of gold-bearing ore, which transformed Bodie from an isolated mining camp comprising a few prospectors and company employees to a Wild West boomtown. Rich discoveries in the adjacent Bodie Mine during 1878 attracted even more hopeful people. By 1879, Bodie had a population of approximately 7,000–10,000 people and around 2,000 buildings. One legend says that in 1880, Bodie was California's second or third largest city. but the U.S. Census of that year disproves this. Over the years 1860-1941 Bodie's mines produced gold and silver valued at an estimated US$34 million (in 1986 dollars, or $85 million in 2021).
Bodie boomed from late 1877 through mid– to late 1880. The first newspaper, The Standard Pioneer Journal of Mono County, published its first edition on October 10, 1877. Starting as a weekly, it soon expanded publication to three times a week. It was also during this time that a telegraph line was built which connected Bodie with Bridgeport and Genoa, Nevada. California and Nevada newspapers predicted Bodie would become the next Comstock Lode. Men from both states were lured to Bodie by the prospect of another bonanza.
Gold bullion from the town's nine stamp mills was shipped to Carson City, Nevada, by way of Aurora, Wellington and Gardnerville. Most shipments were accompanied by armed guards. After the bullion reached Carson City, it was delivered to the mint there, or sent by rail to the mint in San Francisco.
As a bustling gold mining center, Bodie had the amenities of larger towns, including a Wells Fargo Bank, four volunteer fire companies, a brass band, railroad, miners' and mechanics' union, several daily newspapers, and a jail. At its peak, 65 saloons lined Main Street, which was a mile long. Murders, shootouts, barroom brawls, and stagecoach holdups were regular occurrences.
As with other remote mining towns, Bodie had a popular, though clandestine, red light district on the north end of town. There is an unsubstantiated story of Rosa May, a prostitute who, in the style of Florence Nightingale, came to the aid of the town menfolk when a serious epidemic struck the town at the height of its boom. She is credited with giving life-saving care to many, but after she died, was buried outside the cemetery fence.
Bodie had a Chinatown, the main street of which ran at a right angle to Bodie's Main Street. At one point it had several hundred Chinese residents and a Taoist temple. Opium dens were plentiful in this area.
Bodie also had a cemetery on the outskirts of town and a nearby mortuary. It is the only building in the town built of red brick three courses thick, most likely for insulation to keep the air temperature steady during the cold winters and hot summers. The cemetery includes a Miners Union section, and a cenotaph erected to honor President James A. Garfield. The Bodie Boot Hill was located outside of the official city cemetery.
On Main Street stands the Miners Union Hall, which was the meeting place for labor unions. It also served as an entertainment center that hosted dances, concerts, plays, and school recitals. It now serves as a museum.
The first signs of decline appeared in 1880 and became obvious toward the end of the year. Promising mining booms in Butte, Montana; Tombstone, Arizona; and Utah lured men away from Bodie. The get-rich-quick, single miners who came to the town in the 1870s moved on to these other booms, and Bodie developed into a family-oriented community. In 1882 residents built the Methodist Church (which still stands) and the Roman Catholic Church (burned 1928). Despite the population decline, the mines were flourishing, and in 1881 Bodie's ore production was recorded at a high of $3.1 million. Also in 1881, a narrow-gauge railroad was built called the Bodie Railway & Lumber Company, bringing lumber, cordwood, and mine timbers to the mining district from Mono Mills south of Mono Lake.
During the early 1890s, Bodie enjoyed a short revival from technological advancements in the mines that continued to support the town. In 1890, the recently invented cyanide process promised to recover gold and silver from discarded mill tailings and from low-grade ore bodies that had been passed over. In 1892, the Standard Company built its own hydroelectric plant approximately 13 miles (20.9 km) away at Dynamo Pond. The plant developed a maximum of 130 horsepower (97 kW) and 3,530 volts alternating current (AC) to power the company's 20-stamp mill. This pioneering installation marked the country's first transmissions of electricity over a long distance.
In 1910, the population was recorded at 698 people, which were predominantly families who decided to stay in Bodie instead of moving on to other prosperous strikes.
The first signs of an official decline occurred in 1912 with the printing of the last Bodie newspaper, The Bodie Miner. In a 1913 book titled California Tourist Guide and Handbook: Authentic Description of Routes of Travel and Points of Interest in California, the authors, Wells and Aubrey Drury, described Bodie as a "mining town, which is the center of a large mineral region". They referred to two hotels and a railroad operating there. In 1913, the Standard Consolidated Mine closed.
Mining profits in 1914 were at a low of $6,821. James S. Cain bought everything from the town lots to the mining claims, and reopened the Standard mill to former employees, which resulted in an over $100,000 profit in 1915. However, this financial growth was not in time to stop the town's decline. In 1917, the Bodie Railway was abandoned and its iron tracks were scrapped.
The last mine closed in 1942, due to War Production Board order L-208, shutting down all non-essential gold mines in the United States during World War II. Mining never resumed after the war.
Bodie was first described as a "ghost town" in 1915. In a time when auto travel was on the rise, many travelers reached Bodie via automobiles. The San Francisco Chronicle published an article in 1919 to dispute the "ghost town" label.
By 1920, Bodie's population was recorded by the US Federal Census at a total of 120 people. Despite the decline and a severe fire in the business district in 1932, Bodie had permanent residents through nearly half of the 20th century. A post office operated at Bodie from 1877 to 1942
In the 1940s, the threat of vandalism faced the ghost town. The Cain family, who owned much of the land, hired caretakers to protect and to maintain the town's structures. Martin Gianettoni, one of the last three people living in Bodie in 1943, was a caretaker.
Bodie is now an authentic Wild West ghost town.
The town was designated a National Historic Landmark in 1961, and in 1962 the state legislature authorized creation of Bodie State Historic Park. A total of 170 buildings remained. Bodie has been named as California's official state gold rush ghost town.
Visitors arrive mainly via SR 270, which runs from US 395 near Bridgeport to the west; the last three miles of it is a dirt road. There is also a road to SR 167 near Mono Lake in the south, but this road is extremely rough, with more than 10 miles of dirt track in a bad state of repair. Due to heavy snowfall, the roads to Bodie are usually closed in winter .
Today, Bodie is preserved in a state of arrested decay. Only a small part of the town survived, with about 110 structures still standing, including one of many once operational gold mills. Visitors can walk the deserted streets of a town that once was a bustling area of activity. Interiors remain as they were left and stocked with goods. Littered throughout the park, one can find small shards of china dishes, square nails and an occasional bottle, but removing these items is against the rules of the park.
The California State Parks' ranger station is located in one of the original homes on Green Street.
In 2009 and again in 2010, Bodie was scheduled to be closed. The California state legislature worked out a budget compromise that enabled the state's Parks Closure Commission to keep it open. As of 2022, the park is still operating, now administered by the Bodie Foundation.
California is a state in the Western United States, located along the Pacific Coast. With nearly 39.2 million residents across a total area of approximately 163,696 square miles (423,970 km2), it is the most populous U.S. state and the 3rd largest by area. It is also the most populated subnational entity in North America and the 34th most populous in the world. The Greater Los Angeles area and the San Francisco Bay Area are the nation's second and fifth most populous urban regions respectively, with the former having more than 18.7 million residents and the latter having over 9.6 million. Sacramento is the state's capital, while Los Angeles is the most populous city in the state and the second most populous city in the country. San Francisco is the second most densely populated major city in the country. Los Angeles County is the country's most populous, while San Bernardino County is the largest county by area in the country. California borders Oregon to the north, Nevada and Arizona to the east, the Mexican state of Baja California to the south; and has a coastline along the Pacific Ocean to the west.
The economy of the state of California is the largest in the United States, with a $3.4 trillion gross state product (GSP) as of 2022. It is the largest sub-national economy in the world. If California were a sovereign nation, it would rank as the world's fifth-largest economy as of 2022, behind Germany and ahead of India, as well as the 37th most populous. The Greater Los Angeles area and the San Francisco Bay Area are the nation's second- and third-largest urban economies ($1.0 trillion and $0.5 trillion respectively as of 2020). The San Francisco Bay Area Combined Statistical Area had the nation's highest gross domestic product per capita ($106,757) among large primary statistical areas in 2018, and is home to five of the world's ten largest companies by market capitalization and four of the world's ten richest people.
Prior to European colonization, California was one of the most culturally and linguistically diverse areas in pre-Columbian North America and contained the highest Native American population density north of what is now Mexico. European exploration in the 16th and 17th centuries led to the colonization of California by the Spanish Empire. In 1804, it was included in Alta California province within the Viceroyalty of New Spain. The area became a part of Mexico in 1821, following its successful war for independence, but was ceded to the United States in 1848 after the Mexican–American War. The California Gold Rush started in 1848 and led to dramatic social and demographic changes, including large-scale immigration into California, a worldwide economic boom, and the California genocide of indigenous people. The western portion of Alta California was then organized and admitted as the 31st state on September 9, 1850, following the Compromise of 1850.
Notable contributions to popular culture, for example in entertainment and sports, have their origins in California. The state also has made noteworthy contributions in the fields of communication, information, innovation, environmentalism, economics, and politics. It is the home of Hollywood, the oldest and one of the largest film industries in the world, which has had a profound influence upon global entertainment. It is considered the origin of the hippie counterculture, beach and car culture, and the personal computer, among other innovations. The San Francisco Bay Area and the Greater Los Angeles Area are widely seen as the centers of the global technology and film industries, respectively. California's economy is very diverse: 58% of it is based on finance, government, real estate services, technology, and professional, scientific, and technical business services. Although it accounts for only 1.5% of the state's economy, California's agriculture industry has the highest output of any U.S. state. California's ports and harbors handle about a third of all U.S. imports, most originating in Pacific Rim international trade.
The state's extremely diverse geography ranges from the Pacific Coast and metropolitan areas in the west to the Sierra Nevada mountains in the east, and from the redwood and Douglas fir forests in the northwest to the Mojave Desert in the southeast. The Central Valley, a major agricultural area, dominates the state's center. California is well known for its warm Mediterranean climate and monsoon seasonal weather. The large size of the state results in climates that vary from moist temperate rainforest in the north to arid desert in the interior, as well as snowy alpine in the mountains.
Settled by successive waves of arrivals during at least the last 13,000 years, California was one of the most culturally and linguistically diverse areas in pre-Columbian North America. Various estimates of the native population have ranged from 100,000 to 300,000. The indigenous peoples of California included more than 70 distinct ethnic groups, inhabiting environments from mountains and deserts to islands and redwood forests. These groups were also diverse in their political organization, with bands, tribes, villages, and on the resource-rich coasts, large chiefdoms, such as the Chumash, Pomo and Salinan. Trade, intermarriage and military alliances fostered social and economic relationships between many groups.
The first Europeans to explore the coast of California were the members of a Spanish maritime expedition led by Portuguese captain Juan Rodríguez Cabrillo in 1542. Cabrillo was commissioned by Antonio de Mendoza, the Viceroy of New Spain, to lead an expedition up the Pacific coast in search of trade opportunities; they entered San Diego Bay on September 28, 1542, and reached at least as far north as San Miguel Island. Privateer and explorer Francis Drake explored and claimed an undefined portion of the California coast in 1579, landing north of the future city of San Francisco. Sebastián Vizcaíno explored and mapped the coast of California in 1602 for New Spain, putting ashore in Monterey. Despite the on-the-ground explorations of California in the 16th century, Rodríguez's idea of California as an island persisted. Such depictions appeared on many European maps well into the 18th century.
The Portolá expedition of 1769-70 was a pivotal event in the Spanish colonization of California, resulting in the establishment of numerous missions, presidios, and pueblos. The military and civil contingent of the expedition was led by Gaspar de Portolá, who traveled over land from Sonora into California, while the religious component was headed by Junípero Serra, who came by sea from Baja California. In 1769, Portolá and Serra established Mission San Diego de Alcalá and the Presidio of San Diego, the first religious and military settlements founded by the Spanish in California. By the end of the expedition in 1770, they would establish the Presidio of Monterey and Mission San Carlos Borromeo de Carmelo on Monterey Bay.
After the Portolà expedition, Spanish missionaries led by Father-President Serra set out to establish 21 Spanish missions of California along El Camino Real ("The Royal Road") and along the Californian coast, 16 sites of which having been chosen during the Portolá expedition. Numerous major cities in California grew out of missions, including San Francisco (Mission San Francisco de Asís), San Diego (Mission San Diego de Alcalá), Ventura (Mission San Buenaventura), or Santa Barbara (Mission Santa Barbara), among others.
Juan Bautista de Anza led a similarly important expedition throughout California in 1775–76, which would extend deeper into the interior and north of California. The Anza expedition selected numerous sites for missions, presidios, and pueblos, which subsequently would be established by settlers. Gabriel Moraga, a member of the expedition, would also christen many of California's prominent rivers with their names in 1775–1776, such as the Sacramento River and the San Joaquin River. After the expedition, Gabriel's son, José Joaquín Moraga, would found the pueblo of San Jose in 1777, making it the first civilian-established city in California.
The Spanish founded Mission San Juan Capistrano in 1776, the third to be established of the Californian missions.
During this same period, sailors from the Russian Empire explored along the northern coast of California. In 1812, the Russian-American Company established a trading post and small fortification at Fort Ross on the North Coast. Fort Ross was primarily used to supply Russia's Alaskan colonies with food supplies. The settlement did not meet much success, failing to attract settlers or establish long term trade viability, and was abandoned by 1841.
During the War of Mexican Independence, Alta California was largely unaffected and uninvolved in the revolution, though many Californios supported independence from Spain, which many believed had neglected California and limited its development. Spain's trade monopoly on California had limited the trade prospects of Californians. Following Mexican independence, Californian ports were freely able to trade with foreign merchants. Governor Pablo Vicente de Solá presided over the transition from Spanish colonial rule to independent.
In 1821, the Mexican War of Independence gave the Mexican Empire (which included California) independence from Spain. For the next 25 years, Alta California remained a remote, sparsely populated, northwestern administrative district of the newly independent country of Mexico, which shortly after independence became a republic. The missions, which controlled most of the best land in the state, were secularized by 1834 and became the property of the Mexican government. The governor granted many square leagues of land to others with political influence. These huge ranchos or cattle ranches emerged as the dominant institutions of Mexican California. The ranchos developed under ownership by Californios (Hispanics native of California) who traded cowhides and tallow with Boston merchants. Beef did not become a commodity until the 1849 California Gold Rush.
From the 1820s, trappers and settlers from the United States and Canada began to arrive in Northern California. These new arrivals used the Siskiyou Trail, California Trail, Oregon Trail and Old Spanish Trail to cross the rugged mountains and harsh deserts in and surrounding California. The early government of the newly independent Mexico was highly unstable, and in a reflection of this, from 1831 onwards, California also experienced a series of armed disputes, both internal and with the central Mexican government. During this tumultuous political period Juan Bautista Alvarado was able to secure the governorship during 1836–1842. The military action which first brought Alvarado to power had momentarily declared California to be an independent state, and had been aided by Anglo-American residents of California, including Isaac Graham. In 1840, one hundred of those residents who did not have passports were arrested, leading to the Graham Affair, which was resolved in part with the intercession of Royal Navy officials.
One of the largest ranchers in California was John Marsh. After failing to obtain justice against squatters on his land from the Mexican courts, he determined that California should become part of the United States. Marsh conducted a letter-writing campaign espousing the California climate, the soil, and other reasons to settle there, as well as the best route to follow, which became known as "Marsh's route". His letters were read, reread, passed around, and printed in newspapers throughout the country, and started the first wagon trains rolling to California. He invited immigrants to stay on his ranch until they could get settled, and assisted in their obtaining passports.
After ushering in the period of organized emigration to California, Marsh became involved in a military battle between the much-hated Mexican general, Manuel Micheltorena and the California governor he had replaced, Juan Bautista Alvarado. The armies of each met at the Battle of Providencia near Los Angeles. Marsh had been forced against his will to join Micheltorena's army. Ignoring his superiors, during the battle, he signaled the other side for a parley. There were many settlers from the United States fighting on both sides. He convinced these men that they had no reason to be fighting each other. As a result of Marsh's actions, they abandoned the fight, Micheltorena was defeated, and California-born Pio Pico was returned to the governorship. This paved the way to California's ultimate acquisition by the United States.
In 1846, a group of American settlers in and around Sonoma rebelled against Mexican rule during the Bear Flag Revolt. Afterward, rebels raised the Bear Flag (featuring a bear, a star, a red stripe and the words "California Republic") at Sonoma. The Republic's only president was William B. Ide,[65] who played a pivotal role during the Bear Flag Revolt. This revolt by American settlers served as a prelude to the later American military invasion of California and was closely coordinated with nearby American military commanders.
The California Republic was short-lived; the same year marked the outbreak of the Mexican–American War (1846–48).
Commodore John D. Sloat of the United States Navy sailed into Monterey Bay in 1846 and began the U.S. military invasion of California, with Northern California capitulating in less than a month to the United States forces. In Southern California, Californios continued to resist American forces. Notable military engagements of the conquest include the Battle of San Pasqual and the Battle of Dominguez Rancho in Southern California, as well as the Battle of Olómpali and the Battle of Santa Clara in Northern California. After a series of defensive battles in the south, the Treaty of Cahuenga was signed by the Californios on January 13, 1847, securing a censure and establishing de facto American control in California.
Following the Treaty of Guadalupe Hidalgo (February 2, 1848) that ended the war, the westernmost portion of the annexed Mexican territory of Alta California soon became the American state of California, and the remainder of the old territory was then subdivided into the new American Territories of Arizona, Nevada, Colorado and Utah. The even more lightly populated and arid lower region of old Baja California remained as a part of Mexico. In 1846, the total settler population of the western part of the old Alta California had been estimated to be no more than 8,000, plus about 100,000 Native Americans, down from about 300,000 before Hispanic settlement in 1769.
In 1848, only one week before the official American annexation of the area, gold was discovered in California, this being an event which was to forever alter both the state's demographics and its finances. Soon afterward, a massive influx of immigration into the area resulted, as prospectors and miners arrived by the thousands. The population burgeoned with United States citizens, Europeans, Chinese and other immigrants during the great California Gold Rush. By the time of California's application for statehood in 1850, the settler population of California had multiplied to 100,000. By 1854, more than 300,000 settlers had come. Between 1847 and 1870, the population of San Francisco increased from 500 to 150,000.
The seat of government for California under Spanish and later Mexican rule had been located in Monterey from 1777 until 1845. Pio Pico, the last Mexican governor of Alta California, had briefly moved the capital to Los Angeles in 1845. The United States consulate had also been located in Monterey, under consul Thomas O. Larkin.
In 1849, a state Constitutional Convention was first held in Monterey. Among the first tasks of the convention was a decision on a location for the new state capital. The first full legislative sessions were held in San Jose (1850–1851). Subsequent locations included Vallejo (1852–1853), and nearby Benicia (1853–1854); these locations eventually proved to be inadequate as well. The capital has been located in Sacramento since 1854 with only a short break in 1862 when legislative sessions were held in San Francisco due to flooding in Sacramento. Once the state's Constitutional Convention had finalized its state constitution, it applied to the U.S. Congress for admission to statehood. On September 9, 1850, as part of the Compromise of 1850, California became a free state and September 9 a state holiday.
During the American Civil War (1861–1865), California sent gold shipments eastward to Washington in support of the Union. However, due to the existence of a large contingent of pro-South sympathizers within the state, the state was not able to muster any full military regiments to send eastwards to officially serve in the Union war effort. Still, several smaller military units within the Union army were unofficially associated with the state of California, such as the "California 100 Company", due to a majority of their members being from California.
At the time of California's admission into the Union, travel between California and the rest of the continental United States had been a time-consuming and dangerous feat. Nineteen years later, and seven years after it was greenlighted by President Lincoln, the First transcontinental railroad was completed in 1869. California was then reachable from the eastern States in a week's time.
Much of the state was extremely well suited to fruit cultivation and agriculture in general. Vast expanses of wheat, other cereal crops, vegetable crops, cotton, and nut and fruit trees were grown (including oranges in Southern California), and the foundation was laid for the state's prodigious agricultural production in the Central Valley and elsewhere.
In the nineteenth century, a large number of migrants from China traveled to the state as part of the Gold Rush or to seek work. Even though the Chinese proved indispensable in building the transcontinental railroad from California to Utah, perceived job competition with the Chinese led to anti-Chinese riots in the state, and eventually the US ended migration from China partially as a response to pressure from California with the 1882 Chinese Exclusion Act.
Under earlier Spanish and Mexican rule, California's original native population had precipitously declined, above all, from Eurasian diseases to which the indigenous people of California had not yet developed a natural immunity. Under its new American administration, California's harsh governmental policies towards its own indigenous people did not improve. As in other American states, many of the native inhabitants were soon forcibly removed from their lands by incoming American settlers such as miners, ranchers, and farmers. Although California had entered the American union as a free state, the "loitering or orphaned Indians" were de facto enslaved by their new Anglo-American masters under the 1853 Act for the Government and Protection of Indians. There were also massacres in which hundreds of indigenous people were killed.
Between 1850 and 1860, the California state government paid around 1.5 million dollars (some 250,000 of which was reimbursed by the federal government) to hire militias whose purpose was to protect settlers from the indigenous populations. In later decades, the native population was placed in reservations and rancherias, which were often small and isolated and without enough natural resources or funding from the government to sustain the populations living on them. As a result, the rise of California was a calamity for the native inhabitants. Several scholars and Native American activists, including Benjamin Madley and Ed Castillo, have described the actions of the California government as a genocide.
In the twentieth century, thousands of Japanese people migrated to the US and California specifically to attempt to purchase and own land in the state. However, the state in 1913 passed the Alien Land Act, excluding Asian immigrants from owning land. During World War II, Japanese Americans in California were interned in concentration camps such as at Tule Lake and Manzanar. In 2020, California officially apologized for this internment.
Migration to California accelerated during the early 20th century with the completion of major transcontinental highways like the Lincoln Highway and Route 66. In the period from 1900 to 1965, the population grew from fewer than one million to the greatest in the Union. In 1940, the Census Bureau reported California's population as 6.0% Hispanic, 2.4% Asian, and 89.5% non-Hispanic white.
To meet the population's needs, major engineering feats like the California and Los Angeles Aqueducts; the Oroville and Shasta Dams; and the Bay and Golden Gate Bridges were built across the state. The state government also adopted the California Master Plan for Higher Education in 1960 to develop a highly efficient system of public education.
Meanwhile, attracted to the mild Mediterranean climate, cheap land, and the state's wide variety of geography, filmmakers established the studio system in Hollywood in the 1920s. California manufactured 8.7 percent of total United States military armaments produced during World War II, ranking third (behind New York and Michigan) among the 48 states. California however easily ranked first in production of military ships during the war (transport, cargo, [merchant ships] such as Liberty ships, Victory ships, and warships) at drydock facilities in San Diego, Los Angeles, and the San Francisco Bay Area. After World War II, California's economy greatly expanded due to strong aerospace and defense industries, whose size decreased following the end of the Cold War. Stanford University and its Dean of Engineering Frederick Terman began encouraging faculty and graduates to stay in California instead of leaving the state, and develop a high-tech region in the area now known as Silicon Valley. As a result of these efforts, California is regarded as a world center of the entertainment and music industries, of technology, engineering, and the aerospace industry, and as the United States center of agricultural production. Just before the Dot Com Bust, California had the fifth-largest economy in the world among nations.
In the mid and late twentieth century, a number of race-related incidents occurred in the state. Tensions between police and African Americans, combined with unemployment and poverty in inner cities, led to violent riots, such as the 1965 Watts riots and 1992 Rodney King riots. California was also the hub of the Black Panther Party, a group known for arming African Americans to defend against racial injustice and for organizing free breakfast programs for schoolchildren. Additionally, Mexican, Filipino, and other migrant farm workers rallied in the state around Cesar Chavez for better pay in the 1960s and 1970s.
During the 20th century, two great disasters happened in California. The 1906 San Francisco earthquake and 1928 St. Francis Dam flood remain the deadliest in U.S. history.
Although air pollution problems have been reduced, health problems associated with pollution have continued. The brown haze known as "smog" has been substantially abated after the passage of federal and state restrictions on automobile exhaust.
An energy crisis in 2001 led to rolling blackouts, soaring power rates, and the importation of electricity from neighboring states. Southern California Edison and Pacific Gas and Electric Company came under heavy criticism.
Housing prices in urban areas continued to increase; a modest home which in the 1960s cost $25,000 would cost half a million dollars or more in urban areas by 2005. More people commuted longer hours to afford a home in more rural areas while earning larger salaries in the urban areas. Speculators bought houses they never intended to live in, expecting to make a huge profit in a matter of months, then rolling it over by buying more properties. Mortgage companies were compliant, as everyone assumed the prices would keep rising. The bubble burst in 2007–8 as housing prices began to crash and the boom years ended. Hundreds of billions in property values vanished and foreclosures soared as many financial institutions and investors were badly hurt.
In the twenty-first century, droughts and frequent wildfires attributed to climate change have occurred in the state. From 2011 to 2017, a persistent drought was the worst in its recorded history. The 2018 wildfire season was the state's deadliest and most destructive, most notably Camp Fire.
Although air pollution problems have been reduced, health problems associated with pollution have continued. The brown haze that is known as "smog" has been substantially abated thanks to federal and state restrictions on automobile exhaust.
One of the first confirmed COVID-19 cases in the United States that occurred in California was first of which was confirmed on January 26, 2020. Meaning, all of the early confirmed cases were persons who had recently travelled to China in Asia, as testing was restricted to this group. On this January 29, 2020, as disease containment protocols were still being developed, the U.S. Department of State evacuated 195 persons from Wuhan, China aboard a chartered flight to March Air Reserve Base in Riverside County, and in this process, it may have granted and conferred to escalated within the land and the US at cosmic. On February 5, 2020, the U.S. evacuated 345 more citizens from Hubei Province to two military bases in California, Travis Air Force Base in Solano County and Marine Corps Air Station Miramar, San Diego, where they were quarantined for 14 days. A state of emergency was largely declared in this state of the nation on March 4, 2020, and as of February 24, 2021, remains in effect. A mandatory statewide stay-at-home order was issued on March 19, 2020, due to increase, which was ended on January 25, 2021, allowing citizens to return to normal life. On April 6, 2021, the state announced plans to fully reopen the economy by June 15, 2021.
Living in London has given me the opportunity to have an open interpretation of society. I found that London was split between modern and older structures which have helped to create the culture that it brings. Older structures such as Big Ben relate to parliament which symbolise authority and age. These scenes are commonly used in TV News production as they give the reporter a sense of authenticity whereby watchers are able to find the information reliable which helps the media create the image that it wants to create. Tower Bridge connotes the idea of connectivity which is common among the efficient transport links that London offers. Its modernised road shows the development of the new generation. Statues play a large role in London’s history and are able to express different emotions and ideas. The 3 lions at Leister square are a significant symbol to English culture and symbolise loyalty and protection as anyone is welcome in London to share the national pride. Horses are also common in London and connote the idea of independence which is seen in businessmen and commuters. More modern structures such as Oxford Street shops help the new generation to merge with the old fashioned culture of London. Modernised structures such as the Shard and Gherkin have common glass textures which symbolise opportunity, proximity and the idea of looking into a future path that we are able to choose. With relevance to the film industry, using the location of London would be useful in a romantic comedy or films where success and drive to a future goal are key as the culture has a range of aspects that can display the emotions these films would need to bring. My mood board showed common colour themes of red, white and blue. This symbolised ideas of English culture and flag but the colour red could also be interpreted as the colour of authority and romance. Authority would relate to the idea of Parliament and Buckingham Palace being at the centre of London. The colour white connotes ideas of delicacy which is common in fantasy films where there is a modernised set and colours are commonly bright in order to focus on new unique aspects. I chose to incorporate the focus on Pride in my mood board as it is a vital aspect of the new generation in London and is also very important to me. As a culture, we are very accepting of different types of personalities and welcome everyone. Gay pride show a wide range of colours to symbolise the LGBTQ+ community which connote ideas of happiness and joy as the colours are bright and welcoming to particularly young ages. This has inspired me to make a documentary style video based to LGBT discrimination and how the media represents this particular group. A vital aspect of my mood board is the use of cranes in the London skyline. I found that London has a fair distribution of symbolic landmarks which add to its iconic skyline. However these are largely blocked with construction works and cranes therefore I decided to place these images on elevated squares in order to highlight their impact to the image of London. I interpreted this idea of construction as a symbolic change in London society and how the generation is changing for the better by becoming more accepting of different cultures in order to allow anyone to have the opportunity to succeed in their future.
Energy efficient ('off the grid') Southern Vermont home features:
Electricity generation
2 turbine windmills
2 kinds of solar panels (rigid and amorphous/strips)
Heating/Water
Russian stove (closed chamber wood stove, thermal mass heating system)
solar water heating panels
gas powered radiant heating in the floor.
Low Energy Lighting & Appliances
Because of careful selection of lighting and appliances, the house is able to run within its energy budget almost all of the time.
After 2 years of running completely off-grid (with backup gasoline generator), we installed electricity (a "grid tie"), mostly used to feed excess capacity back into the grid.
Hints and Links on home energy consumption:
There are 2 ways to decrease home energy use.
1. Reduce power consumption.
2. Install a renewable energy system
The first can be as simple as replacing high usage incandescent bulbs with new compact flourescent bulbs and lighting fixtures. Around here, you can buy these products at a discount thru programs sponsored by the electric company (NStar).
Another good idea is replacing old appliances with newer energy efficient models.
There is a lot of information about energy saving here :
www1.eere.energy.gov/consumer/tips/
If you are interested in solar energy or other sustainable energy generation technologies, I suggest taking a look at www.homepower.com/ a magazine dedicated to "home-scale renewable energy and sustainable living".
This site has an overview article on Renewable Energy which is relatively short and clear. www.homepower.com/files/featured/HP116_pp46-50_Casale.pdf
Contact: For more information about energy efficient living you can write Paul at myerspe@starband.net
File: DSC_5825_ACR
Watch the video here: youtu.be/KE18c9pA3pk
Here is a video I made to explain how to wash ands rub your hands efficiently with a hand sanitizer, step by step visual tutorial. I filmed it at CHU UCL Namur Hospital in Belgium.
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Hand sanitizer is a liquid or gel generally used to decrease infectious agents on the hands. Formulations of the alcohol-based type are preferable to hand washing with soap and water in most situations in the healthcare setting. It is generally more effective at killing microorganisms and better tolerated than soap and water. Hand washing should still be carried out if contamination can be seen or following the use of the toilet. The general use of non-alcohol based versions has no recommendations. Outside the health care setting, evidence to support the use of hand sanitizer over hand washing is poor. They are available as liquids, gels, and foams.
Hand sanitizer that contains at least 60 % alcohol or contains a "persistent antiseptic" should be used. Alcohol rubs kill many different kinds of bacteria, including antibiotic resistant bacteria and TB bacteria. 90% alcohol rubs are highly flammable, but kill many kinds of viruses, including enveloped viruses such as the flu virus, the common cold virus, coronaviruses, and HIV, though is notably ineffective against the rabies virus.
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© Ben Heine
The morning sunrise in Condobolin in far western NSW starts to warm up the town as VL362, VL353 and GL109 shunt 8890 back onto the mainline, having stabled the previous night in the yard after traveling from Broken Hill. The train consisted of CQMY wagons being transferred from Bowmans in South Australia to Bathurst and was operated by Sydney Rail Services.
The engines would travel light engine to Goulburn as D890 after dropping the wagons off the following day.
Please don't use this image on websites, blogs or other media without my explicit permission. © All rights reserved
Using Energy Efficiently
For all the energy required to propel a vehicle, not all of it makes it to the wheels. Some of it is lost to friction and heat. Vehicle inefficiency can be classified into two categories of losses: road-load and energy conversion. At Tesla, careful attention is given to both to achieve the maximum range. The Tesla Roadster leverages both an incredible electric powertrain and an engineer’s obsession with efficiency to be the most efficient production sports car on the market today.
London Drive the Future
In 1982 Mercedes-Benz released the production version of more than a decade's research into developing a compact format, efficient and safe luxury car. The name '190' referred back to the 1950 and 60s versions of 'reduced power output' models of their mainstream saloon car range. The 190E specified a fuel-injected 2.0 litre, four cylinder engine, whilst a 190 model, without the 'E' (for einspritz' appellation, referred to the same engine, but using a carburetor.
This is the version most commonly seen in taxis, along with a 2.0 litre 4-cylinder diesel, with even less power......
Then something strange happened within the halls of Mercedes-Benz....
190E 2.3-16 & 2.5-16 "Cosworth":
In the late 1970s, Mercedes competed in rallying with the big V8-powered Coupés of the R107 Series, mainly the light-weight Mercedes 450 SLC 5.0. Mercedes wished to take the 190 E rallying, and asked British engineering company Cosworth to develop an engine with 320 bhp (239 kW) for the rally car. This project was known as project "WAA' by Cosworth". During this time, the Audi Quattro with its all-wheel drive and turbocharger was launched, making the 2.3-16v appear outclassed. With a continued desire to compete in high-profile motor sport with the 190, and also now an engine to do it with, Mercedes turned to the Deutsche Tourenwagen Meisterschaft (DTM) (German Touring Car Championship) motor sport series instead. Cars racing in this championship, however, had to be based on a roadgoing model. Mercedes therefore had to put into series production a 190 fitted with a detuned version of the Cosworth engine. This high-performance model was known as the 190 E 2.3-16, and debuted at the Frankfurt Auto Show in September 1983, after its reputation had already been established. Three cars, only slightly cosmetically altered, had set three world records in August at the Nardo testing facility in Italy, recording a combined average speed of 154.06 mph (247.94 km/h) over the 50,000 km endurance test, and establishing twelve international endurance records. The Mercedes 190-E Cosworth was also featured on the second episode in series fifteen of the popular car show Top Gear.
Engin:
2.5-16 Cosworth
The Cosworth engine was based on the M102 four cylinder 2.3-litre 8-valve 136 hp (101 kW) unit already fitted to the 190- and E-Class series. Cosworth developed the cylinder head, "applying knowledge we've learnt from the DFV and BDA." It was made from light alloy using Coscast's unique casting process and brought with it dual overhead camshafts and four valves per cylinder, meaning 16 valves total which were developed to be the "largest that could practically be fitted into the combustion chamber".
In roadgoing trim,the 2.3 L 16-valve engine made "185 hp (138 kW) at 6,200 rpm and 174 lb·ft (236 N·m) at 4,500 rpm. The oversquare 95.50 x 80.25 mm bore and stroke dimensions ensuring that it revs easily up to the 7000 rpm redline". Acceleration from 0–100 km/h (62 mph) was less than eight seconds, and the top speed was 230 km/h (143 mph).
US-Specification cars had a slightly reduced compression ratio (9.7:1 instead of 10.5:1), and were rated at 167 hp (125 kW) @ 5800 rpm and 162 lb·ft (220 N·m) @ 4750.
The roadgoing version of the engine was reconfigured with reduced inlet and exhaust port sizes, different camshaft profiles, no dry sump configuration and Bosch K-jetronic replacing the specialised Kugelfischer fuel injection. These changes helped bring power down to the required 185 bhp (138 kW) specification, but still resulted in a "remarkably flexible engine, with a very flat torque curve and a wide power band". The heads for the engines were cast at Cosworth's Coscast foundry in Worcester and sent to Germany to be fitted to the rest of the engine, parts of which were different from the standard 2.3 including light pressed alloy pistons, and rings designed to withstand higher engine speeds, whilst con-rods, bearings and bearing caps were found to be strong enough as standard and left unaltered.
16v differences:
Due to their performance, the 16-valve cars were different from the other 190 models. The body kit on the 2.3-16 and 2.5-16 reduced the drag coefficient to 0.32, one of the lowest CD values on a four-door saloon of the time, whilst also reducing lift at speed. The steering ratio was quicker and the steering wheel smaller than that on other 190s, whilst the fuel tank was enlarged from 55 to 70 L. The Getrag 5-speed manual gearbox was unique to the 16-valve and featured a 'racing' gear pattern with 'dog-leg' first gear, left and down from neutral. This meant that the remaining 2nd, 3rd, 4th and 5th gears were in a simple H pattern allowing fast and easy selection. The gearchange quality was, however, noted as "notchy, baulky", criticisms which weren't levelled at the BMW M3 (E30) which shared the same gearbox. The pattern is also unusual in that the driver engages reverse by shifting left and up from neutral, as for first gear in a conventional pattern. This was demonstrated in a Top Gear episode (S15E02) where James May took a 190E 2.3-16 Cosworth and repeatedly confused reverse and first gear. An oil cooler was fitted to ensure sufficient oil cooling for the inevitable track use many of these cars were destined for.
The strictly four-seater interior had Recaro sports seats with strong side bolsters for front and rear passengers. 3 extra dials - an oil temperature gauge, stopwatch and voltmeter - were included in the centre console. The 190 E 2.3-16 was available in only two colours, Blue-Black metallic (Pearl Black in the US), and Smoke Silver. The 2.5-16 added Almandine Red and Astral Silver.
All 2.3-16-valve 190 models are fitted with a Limited Slip Differential (LSD) as standard. They were also available with Mercedes' ASD system which was standard equipment on the 2.5-16v. The ASD is an electronically controlled, hydraulically locking differential which activates automatically when required. The electronic control allows varied amounts of differential lock from the standard 15% right up to 100%. It is not a traction control system however, and can only maximize traction rather than prevent wheel spin. Activation of the ASD system is indicated by an illuminating amber triangle in the speedometer.
The suspension on 16-valve models is very different from the standard 190 (W201). As well as being lower and stiffer, it has quicker dampers, larger anti-roll bars, harder bushings and hydraulic Self-levelling suspension (SLS) on the rear. This allows the rear ride height to remain constant even when the car is fully loaded.
At the inauguration of the new, shorter Nürburgring in 1984, a race with identical cars was held, with former and current F1 pilots at the wheel. A then unknown Ayrton Senna took first place.
Private Teams such as AMG later entered the 2.3-16 in touring cars races, especially the DTM. In the late 1980s, the 2.5-16 (never released in the United States) raced many times, against the similar BMW M3 and even the turbocharged Ford Sierra RS Cosworth.
Evolution models:
2.5-16 Evolution II
With the debut of the BMW M3 Sport Evolution, Mercedes' direct competitor, it became obvious that the 2.5-16 needed a boost for the circuit. In March 1989, the 190 E 2.5-16 Evolution debuted at the Geneva Auto Show. The Evo I, as it came to be called, had a new spoiler and wider wheel arches. Many changes were made to under-the-skin components such as brakes and suspension. There was a full SLS suspension allowing vehicle ride height to be adjusted from an interior switch. All were intended to allow the Evolution cars to be even more effective round a track.
The Evo I's output is similar to the 202 bhp (151 kW) of the "regular" 2.5-16. However this car had a redesigned engine of similar capacity but, most importantly, a shorter stroke and bigger bore which would allow for a higher rev limit and improved top-end power capabilities. Additional changes stretch to "rotating masses lightened, lubrication improved and cam timing altered". Cosworth also list a project code "WAC" for the development of the short-stroke Evolution engine.
Only 502 units of the Evolution model were produced for homologation in compliance with DTM rules. For those customers desiring even more performance, a PowerPack option engineered by AMG was available for DM 18,000. The PowerPack option included hotter camshafts, a larger diameter throttle body, more aggressive ignition and fuel management as well as optimization of the intake and exhaust systems. The net result was an additional 30 bhp (22 kW).
In March 1990, at the Geneva Auto Show, the 190 E 2.5-16 Evolution II was shown. With the success of the first Evolution model, this model's 502-unit production was already sold before it was unveiled.
The "Evo II" included the AMG PowerPack fitted to the same short-stroke 2.5 engine as the Evolution, as well as a full SLS suspension allowing vehicle ride height to be adjusted from an interior switch. An obvious modification to the Evolution II is a radical body kit (designed by Prof. Richard Eppler from the University of Stuttgart) with a large adjustable rear wing, rear window spoiler, and Evolution II 17-inch wheels. The kit served an aerodynamic purpose — it was wind tunnel tested to reduce drag to 0.29, while at the same time increasing downforce. Period anecdotes tell of a BMW executive who was quoted as saying "if that rear wing works, we'll have to redesign our wind tunnel." The anecdote claims that BMW did.
As mentioned 500 were made in "blauschwarz" blue/black metallic. But the last two, numbers 501 and 502 were made in astral silver.
[Test taken from Wikipedia]
This Lego miniland-scale 190E 2.5-16 Evolution II sedan has been created for Flickr LUGNuts' 84th Build Challenge, our 7th birthday, - "LUGNuts Turns 7…or 49 in Dog Years", - where all the previous challenges are available to build to. In this case Challenge 57, - "From Mild to Wild", for vehicles that have been turned into something special out of the ordinary. And also challenge 33, - "Size Matters", - as a buddy challenge with Sirmanperson, who has produced the same 190E 2.5-16 Evolution II in 1:17 scale.
Fast, efficient and handy the Brass Defender is the new weapon of the brave shock troops of his majesty.
This mechanized armor can withstand a whole squad!
The image showcases Pier 27 in San Francisco, prominently known for its James R. Herman Cruise Terminal. The entrance area is marked with clear signage displaying "Pier 27" and "James R. Herman Cruise Terminal," welcoming visitors and cruise passengers. The modern architecture is evident in the building's large glass windows and clean lines, presenting a sleek, contemporary look. The area is meticulously maintained, with a spacious plaza and steps leading up to the terminal. Street lamps and a bench in the foreground add a touch of everyday charm.
Pier 27 serves as a significant hub for cruise ship activity in San Francisco. The terminal is strategically located to provide easy access to the city's attractions and stunning waterfront views. It's not just a transit point but a starting place for exploring the vibrant culture and history of San Francisco. The architecture and design reflect the city's blend of modernity and tradition, creating a welcoming atmosphere for travelers.
Visitors often appreciate the calm and orderly environment of Pier 27, especially when embarking on or disembarking from their cruise journeys. The terminal's efficient design ensures a smooth flow of passengers, enhancing the overall travel experience. The surrounding area, with its inviting open spaces and thoughtful urban design, offers a pleasant spot for relaxation and photography.
Whether you're setting sail on an exciting adventure or simply exploring the waterfront, Pier 27 stands out as a noteworthy landmark in San Francisco. Its blend of functionality, modern design, and connection to the city's maritime heritage makes it a memorable and essential part of any visit to the area.
Baselland Transport [BLT] Route 10 combination Class Be 4/8 245 and Class Be 4/6 224 were recorded at Münchenstein Dorf. The branding on the leading tram unit is for IWB, a leading provider of renwable energy and energy efficiency.
All images on this site are exclusive property and may not be copied, downloaded, reproduced, transmitted, manipulated or used in any way without expressed written permission of the photographer. All rights reserved – Copyright Don Gatehouse
'Efficient', an Andrew Barclay 0-4-0 saddle tank (W/No.1598 built in 1918) shunting loaded bogie flat wagons at Shelton Steelworks during a photographic charter on 8th April 2000.
© Gordon Edgar - All rights reserved. Please do not use my images without my explicit permission
The loco is now at the Ribble Steam Railway, Preston and their website shows the following information:
'Efficient' was built at the Caledonia works of Andrew Barclay & Sons in Kilmarnock. It is a standard Barclay saddle tank with 14" x 22" cylinders and 3' 5" driving wheels. Painted in the Kilmarnock firms usual green lined livery and lettering, it spent it's entire working life at McKechnie Brothers' copper smelting works at Widnes. It shared the duties here with a smaller Barclay engine named 'Economic', which failed to live up to it's name and was scrapped in 1955. There were also two 100h.p. Sentinels as well.
When no longer required at the copper works 'Efficient' was purchased by the Liverpool Locomotive Preservation Group and moved to Seacombe in July 1969. From here, it worked the two Docker railtours in 1971 and 1972, double-headed with 'Lucy'. 'Efficient' moved to Southport in July 1973, where she had the distinction of being the first steam locomotive to enter the newly formed museum. She was fitted with a new inner firebox in 1981, and was a regular performer at Southport until the late 1990s when the site closed, eventually arriving at Preston on 27th July 1999. Efficient's last public steaming was in April 2000 as she took part in the closing celebrations at Shelton Steelworks in Stoke. A firm favourite amongst the crews at the museum, investigation was carried out during the summer of 2005 to bring the loco back into service.
Unfortunately, due to the extent of the work required on the boiler, she will have to wait her turn. She is on view in the museum in a 'as in industrial use' condition.
Some background:
Simple, efficient and reliable, the Regult (リガード, Rigādo) was the standard mass production mecha of the Zentraedi forces. Produced by Esbeliben at the 4.432.369th Zentraedi Fully Automated Weaponry Development and Production Factory Satellite in staggering numbers to fill the need for an all-purpose mecha, this battle pod accommodated a single Zentraedi soldier in a compact cockpit and was capable of operating in space or on a planet's surface. The Regult saw much use during Space War I in repeated engagements against the forces of the SDF-1 Macross and the U.N. Spacy, but its lack of versatility against superior mecha often resulted in average effectiveness and heavy losses. The vehicle was regarded as expendable and was therefore cheap, simple, but also very effective when fielded in large numbers. Possessing minimal defensive features, the Regult was a simple weapon that performed best in large numbers and when supported by other mecha such as Gnerl Fighter Pods. Total production is said to have exceeded 300 million in total.
The cockpit could be accesses through a hatch on the back of the Regult’s body, which was, however, extremely cramped, with poor habitability and means of survival. The giant Zentraedi that operated it often found themselves crouching, with some complaining that "It would have been easier had they just walked on their own feet". Many parts of the craft relied on being operated on manually, which increased the fatigue of the pilot. On the other hand, the overall structure was extremely simple, with relatively few failures, making operational rate high.
In space, the Regult made use of two booster engines and numerous vernier thrusters to propel itself at very high speeds, capable of engaging and maintaining pace with the U.N. Spacy's VF-1 Valkyrie variable fighter. Within an atmosphere, the Regult was largely limited to ground combat but retained high speed and maneuverability. On land, the Regult was surprisingly fast and agile, too, capable of closing with the VF-1 variable fighter in GERWALK flight (though likely unable to maintain pace at full GERWALK velocity). The Regult was not confined to land operations, though, it was also capable of operating underwater for extended periods of time. Thanks to its boosters, the Regult was capable of high leaping that allowed the pod to cover long distances, surprise enemies and even engage low-flying aircraft.
Armed with a variety of direct-fire energy weapons and anti-personnel/anti-aircraft guns, the Regult offered considerable firepower and was capable of engaging both air and ground units. It was also able to deliver powerful kicks. The armor of the body shell wasn't very strong, though, and could easily be penetrated by a Valkyrie's 55 mm Gatling gun pod. Even bare fist attacks of a VF-1 could crack the Regult’s cockpit or immobilize it. The U.N. Spacy’s MBR-07 Destroid Spartan was, after initial battel experience with the Regult, specifically designed to engage the Zentraedi forces’ primary infantry weapon in close-combat.
The Regult was, despite general shortcomings, a highly successful design and it became the basis for a wide range of specialized versions, including advanced battle pods for commanders, heavy infantry weapon carriers and reconnaissance/command vehicles. The latter included the Regult Tactical Scout (リガード偵察型). manufactured by electronics specialist Ectromelia. The Tactical Scout variant was a deadly addition to the Zentraedi Regult mecha troops. Removing all weaponry, the Tactical Scout was equipped with many additional sensor clusters and long-range detection equipment. Always found operating among other Regult mecha or supporting Glaug command pods, the Scout was capable of early warning enemy detection as well as ECM/ECCM roles (Electronic Countermeasures/Electronic Counter-Countermeasures). In Space War I, the Tactical Scout was utilized to devastating effect, often providing radar jamming, communication relay and superior tactical positioning for the many Zentraedi mecha forces.
At the end of Space War I in January 2012, production of the Regult for potential Earth defensive combat continued when the seizure operation of the Factory Satellite was executed. After the war, Regults were used by both U.N. Spacy and Zentraedi insurgents. Many surviving units were incorporated into the New U.N. Forces and given new model numbers. The normal Regult became the “Zentraedi Battle Pod” ZBP-104 (often just called “Type 104”) and was, for example, used by Al-Shahal's New U.N. Army's Zentraedi garrison. The related ZBP-106 was a modernized version for Zentraedi commanders, with built-in boosters, additional Queadluun-Rhea arms and extra armaments. These primarily replaced the Glaug battle pod, of which only a handful had survived. By 2067, Regult pods of all variants were still in operation among mixed human/Zentraedi units.
General characteristics:
Accommodation: pilot only, in standard cockpit in main body
Overall Height: 18.2 meters
Overall Length: 7.6 meters
Overall Width: 12.6 meters
Max Weight: 39.8 metric tons
Powerplant & propulsion:
1x 1.3 GGV class Ectromelia thermonuclear reaction furnace,
driving 2x main booster Thrusters and 12x vernier thrusters
Performance:
unknown
Armament:
None
Special Equipment and Features:
Standard all-frequency radar antenna
Standard laser long-range sensor
Ectromelia infrared, visible light and ultraviolet frequency sensor cluster
ECM/ECCM suite
The kit and its assembly:
I had this kit stashed away for a couple of years, together with a bunch of other 1:100 Zentraedi pods of all kinds and the plan to build a full platoon one day – but this has naturally not happened so far and the kits were and are still waiting. The “Reconnaissance & Surveillance” group build at whatifmodellers.com in August 2021 was a good occasion and motivation to tackle the Tactical Scout model from the pile, though, as it perfectly fits the GB’s theme and also adds an exotic science fiction/anime twist to the submissions.
The kit is an original ARII boxing from 1983, AFAIK the only edition of this model. One might expect this kit to be a variation of the 1982 standard Regult (sometimes spelled “Reguld”) kit with extra parts, but that’s not the case – it is a new mold with different parts and technical solutions, and it offers optional parts for the standard Regult pod as well as the two missile carrier versions that were published at the same time, too. The Tactical Scout uses the same basis, but it comes with parts exclusive for this variant (hull and a sprue with the many antennae and sensors).
I remembered from a former ARII Regult build in the late Eighties that the legs were a wobbly affair. Careful sprue inspection revealed, however, that this second generation comes with some sensible detail changes, e. g. the feet, which originally consisted of separate toe and heel sections (and these were hollow from behind/below!). To my biggest surprise the knees – a notorious weak spot of the 1st generation Regult kit – were not only held by small and flimsy vinyl caps anymore: These were replaced with much bigger vinyl rings, fitted into sturdy single-piece enclosures made from a tough styrene which can even be tuned with small metal screws(!), which are included in the kit. Interesting!
But the joy is still limited: even though the mold is newer, fit is mediocre at best, PSR is necessary on every seam. However, the good news is that the kit does not fight with you. The whole thing was mostly built OOB, because at 1:100 there's little that makes sense to add to the surface, and the kit comes with anything you'd expect on a Regult Scout pod. I just added some lenses and small stuff behind the large "eye", which is (also to my surprise) a clear part. The stuff might only appear in schemes on the finished model, but that's better than leaving the area blank.
Otherwise, the model was built in sub-sections for easier painting and handling, to be assembled in a final step – made possible by the kit’s design which avoids the early mecha kit’s “onion layer” construction, except for the feet. This is the only area that requires some extra effort, and which is also a bit tricky to assemble.
However, while the knees appear to be a robust construction, the kit showed some material weakness: while handling the leg assembly, one leg suddenly came off under the knees - turned out that the locator that holds the knee joint above (which I expected to be the weak point) completely broke off of the lower leg! Weird damage. I tried to glue the leg into place, but this did not work, and so I inserted a replacement for the broken. This eventually worked.
Painting and markings:
Colorful, but pretty standard and with the attempt to be authentic. However, information concerning the Regults’ paint scheme is somewhat inconsistent. I decided to use a more complex interpretation of the standard blue/grey Regult scheme, with a lighter “face shield” and some other details that make the mecha look more interesting. I used the box art and some screenshots from the Macross TV series as reference; the Tactical Scout pod already appears in episode #2 for the first time, and there are some good views at it, even though the anime version is highly simplified.
Humbrol enamels were used, including 48 (Mediterranean Blue), 196 (RAL 7035, instead of pure white), 40 (Pale Grey) and 27 (Sea Grey). The many optics were created with clear acrylics over a silver base, and the large frontal “eye” is a piece of clear plastic with a coat of clear turquoise paint, too.
The model received a black ink washing to emphasize details, engraved panel lines and recesses, as well as some light post-shading through dry-brushing. Some surface details were created with decal stripes, e. g. on the upper legs, or with a black fineliner, and some color highlights were distributed all over the hull, e. g. the yellowish-beige tips of the wide antenna or the bright blue panels on the upper legs.
The decals were taken OOB, and thanks to a translation chart I was able to decipher some of the markings which I’d interpret as a serial number and a unit code – but who knows?
Finally, the kit received an overall coat of matt acrylic varnish and some weathering/dust traces around the feet with simple watercolors – more would IMHO look out of place, due to the mecha’s sheer size in real life and the fact that the Regult has to be considered a disposable item. Either it’s brand new and shiny, or busted, there’s probably little in between that justifies serious weathering which better suits the tank-like Destroids.
A “normal” build, even though the model and the topic are exotic enough. This 2nd generation Regult kit went together easier than expected, even though it has its weak points, too. However, material ageing turned out to be the biggest challenge (after all, the kit is almost 40 years old!), but all problems could be overcome and the resulting model looks decent – and it has this certain Eighties flavor! :D
Auto rickshaws are a common means of public transportation in many countries in the world. Also known as a three-wheeler, Samosa, tempo, tuk-tuk, trishaw, autorick, bajaj, rick, tricycle, mototaxi, baby taxi or lapa in popular parlance, an auto rickshaw is a usually three-wheeled cabin cycle for private use and as a vehicle for hire. It is a motorized version of the traditional pulled rickshaw or cycle rickshaw. Auto rickshaws are an essential form of urban transport in many developing countries, and a form of novelty transport in many developed countries. However, in some parts of Europe they remain an essential mode of transportation, notably Italy's.
OVERVIEW
ORIGN
Auto rickshaws of Southeast Asia started from the knockdown production of the Daihatsu Midget which had been introduced in 1957.
Japan had been exporting three-wheelers to Thailand since 1934. Moreover, The Ministry of Posts and Telecommunications of Japan donated about 20,000 used three-wheelers to Southeast Asia. In Japan, three-wheelers went out of use in the latter half of the 1960s.
DESIGN
An auto rickshaw is generally characterized by a sheet-metal body or open frame resting on three wheels, a canvas roof with drop-down sides, a small cabin in the front of the vehicle for the driver (sometimes called an auto-wallah), and seating space for up to three passengers in the rear. Newer models are generally fitted with a compressed natural gas (CNG) fuel scooter version of a 200 cc four-stroke engine, with handlebar controls instead of a steering wheel.
REGIONAL VARIATIONS
AFRICA
EASTERN AFRICA
There are tuk-tuks in several Kenyan towns. Using them is somewhat cheaper than ordinary taxis. However, tuk-tuks cannot operate in mountainous towns, which are common in Kenya. Fierce competition with Boda-bodas (bicycle taxis) and Matatus (minibuses) hinders popularity of Tuk-tuks, especially within the interior of Kenya. While they may not be widely found in Kenya, they are numerous in the coastal regions, which are less mountainous. For example, in the town of Malindi they offer an economical and convenient mode of transportation.
Tuk-tuks are also common in Ethiopia and are becoming common in Tanzania, particularly in the outer areas of Dar es Salaam. In Tanzania and Ethiopia they are known as "Bajaj" or "Bajajis", after the Bajaj Auto company which manufactures many of them. Since 2009, tuk-tuks have become common in Maputo, Mozambique.
EGYPT
In Egypt, auto rickshaws are called toktok (Egyptian Arabic: توك توك pronounced [ˈtoktok], plural: تكاتك takātek [tæˈkæːtek]); they are widely used as taxis in poorer neighborhoods of the capital, and have become a popular symbol for lower class Egyptians, although they are banned from the streets of wealthier neighborhoods. Deposed president Mohamed Morsi (June 2012-July 2013) in his opening speech addressed the Tuk-Tuk (toktok) drivers as a symbol of the lower class population, but his political rivals and mass media considered it as a mean of emotional deception for the masses by rendering what could be a promise to legalize their status.
MADAGASCAR
In Madagascar, man-pulled rickshaws are a common form of transportation in a number of cities, especially Antsirabe. They are known as "posy" from pousse-pousse, meaning push-push. Cycle rickshaws never took off, yet Posy are threatened by the auto-rickshaws, introduced in numbers since 2009. Provincial capitals like Toamasina, Mahajanga, Toliara, Antsiranana are taking to them rapidly. They are known as "bajaji" and now licenced to operate as taxis. They are not yet allowed an operating licence in the congested, and more pollution prone national capital, Antananarivo.
NIGERIA
There are keke-marwa's in several Nigerian towns and cities. Although not as popular as the ubiquitous "Okada" in Nigeria, keke-marwa's are embraced as an alternative means of transport by the middle and lower class citizens. Keke-marwa is named after Lagos former military Governor, Buba Marwa in the late 1990s.
SOUTH AFRICA
Tuk-tuks, introduced in Durban in the late 1980s enjoyed growing popularity in recent years, particularly in Gauteng.
SUDAN
Rickshaws are a major means of transport in all parts of Sudan, it's locally known as Raksha.
ASIA
BANGLADESH
Auto rickshaws (locally called "baby taxis" and more recently "CNGs" due to their fuel source) are one of the most popular modes of transport in Bangladesh mainly due to their size and speed. They are best suited to narrow, crowded streets, and are thus the principal means of covering longer distances within urban areas.
Earlier, auto rickshaws were colored black with a yellow canvas topping and ran on gasoline without any meter system. However, due to the vast supplies of natural gas in Bangladesh, the government has since encouraged the development of four-stroke compressed natural gas (CNG)-powered engines rather than the older two-stroke engine petrol-running models. Two-stroke engines had been identified as one of the leading sources of air pollution in Dhaka. Thus, since January 2003, traditional auto rickshaws were banned from the capital; only the new CNG-powered models were permitted to operate within the city limits. The newly manufactured CNG auto rickshaws are more fuel-efficient and have a lower center of gravity, making them safer than older models. All CNGs are painted green to signify that the vehicles are eco-friendly and that each one has a meter built in as standard.
Another version of the auto rickshaw can be seen in rural areas of Bangladesh, where they are called "helicopters". "Helicopters" are auto rickshaws modified to have a large body with which it can carry more than six or seven passengers.
At the end of the 1980s, a local company Atlas designed and built a new version of the auto rickshaw, called mishuk, a name derived from a children's mascot of a local deer. Unlike baby taxis, mishuks have spoke wheels and a green body, and have no meter system. Mishuks have more space than baby taxis or CNGs, which makes it more popular with women. They are commonly found in Dhaka and elsewhere in the country due to its four-stroke engine, which is not listed as a significant source of air pollution.
CAMBODIA
In Cambodia, the term tuk-tuk (Khmer: ទុកទុក) is used to refer to a motorcycle with a cabin attached to the rear. Cambodian cities have a much lower volume of automobile traffic than Thai cities, and tuk-tuks are still the most common form of urban transport. At the temple complex of Angkor, for example, tuk-tuks provide a convenient form of transport around the complex for tourists. One can hire a tuk-tuk and driver by the day.[citation needed]
Siem Reap tuk-tuks are generally of the style of motorcycle and trailer. This version does not have rear brakes.
Phnom Penh tuk-tuks are one piece. The one piece tuk-tuk is the front end of a motorcycle consisting of steering, tank and engine/gearbox with a covered tray mounted at the back. The power is transferred by chain to an axle mounted to the modified rear fork which drives the two rear wheels. Suspended upon the rear fork is an open cabin with an in-line seat on each side. This arrangement can carry 6 people at ease, with their luggage in the leg space. It is not unusual to see these vehicles greatly overloaded, especially in outer suburbs and around markets.
Sihanoukville tuk-tuks are generally a motorcycle and articulated trailer without rear brakes on the trailer. A minority of tuk-tuks are three wheeled. The rear wheel of the motorcycle is removed and the front of the bike is melded with a trailer. Power is supplied to the trailer wheels by a driveshaft and differential. Rear wheel brakes add significantly to the safety of this design, especially when going downhill.
Currently, Tuk Tuk in Cambodia is being developed to be more convenient and safer. It is also becoming a popular form of transportation for Phnom Penh residents.
Gaza
Together with the recent boom of recreational facilities in Gaza for the local residents, donkey carts have all but been displaced by tuk-tuks in 2010. Due to the ban by Israel on the import of most motorised vehicles, the tuk-tuks have had to be smuggled in parts through the tunnel network connecting Gaza with Egypt.
CHINA
Various types of auto rickshaw are used around China, where they are called 三轮 (Sān lún - three wheeler) or 嘟嘟车 (Dū dū chē - beep beep car).
In Hainan, the southernmost province, electric models are used in the capital Haikou. These may be heavy, purpose-built vehicles, or simple bicycles attached to a light chassis, with a small electric motor housed underneath.
In rural areas, a sturdy, petrol-powered, plastic-bodied type is common, similar to the Philippine motorized tricycle.
INDIA
OVERVIEW
Most cities offer auto rickshaw service, although hand-pulled rickshaws do exist in some areas, such as Kolkata.
Auto rickshaws are used in cities and towns for short distances; they are less suited to long distances because they are slow and the carriages are open to air pollution. Auto rickshaws (often called "autos") provide cheap and efficient transportation. Modern auto rickshaws run on compressed natural gas (CNG) and are environmentally friendly compared to full-sized cars.
It is also not uncommon in many parts of India (including major cities like Delhi) to see primary school children crammed into an auto-rickshaw, transporting them between home and school.
To augment speedy movement of traffic, Auto rickshaws are not allowed in the southern part of Mumbai.
DESIGN & MANUFACTURE
There are two types of autorickshaws in India. In older versions the engines were situated below the driver's seat, while in newer versions engines are located in the rear. They normally run on petrol, CNG and diesel. The seating capacity of a normal rickshaw is four, including the driver's seat. Six-seater rickshaws exist in different parts of the country, but the model was officially banned in the city of Pune 10 January 2003 by the Regional Transport Authority (RTA).
CNG autos are distinguishable from the earlier petrol-powered autos by a green and yellow livery, as opposed to the earlier black and yellow appearance. Certain local governments are advocating for four-stroke engines instead of the current two-stroke versions.
Auto rickshaw manufacturers in India include Bajaj Auto, Kumar Motors, Kerala Automobiles Limited, Force Motors (previously Bajaj Tempo), Mahindra & Mahindra, Piaggio Ape and TVS Motors.
LEGISLATION
Generally rickshaw fares are controlled by the government.
INDONESIA
In Indonesia, auto rickshaws are popular in Jakarta, Medan, Java, and Sulawesi. In Jakarta, the auto rickshaws are similar to the ones in India but are colored blue and orange. Outside of Jakarta the bentor-style auto rickshaw is more ubiquitous, with the passenger cabin mounted as a sidecar to a motorcycle. Where these sidecar style auto rickshaws do occur in Jakarta they are not referred to as bentor, but rather as bajaj (bajai). They were also popular in East Java until the end of the 20th century and were known as a bemo.
LAOS
Lao tuk-tuks come as tuk-tuks or jumbo tuk-tuks. Jumbos have a larger 3- or 4-cylinder four-stroke engine, and many are powered by Daihatsu engines. Jumbos' larger engine and cabin size allow for greater loads, up to 12 persons, and higher top speeds. Jumbos are (with few exceptions) only found in Vientiane and Luang Prabang.
NEPAL
Auto rickshaws were the popular mode of transport in Nepal during the 1980s and 1990s, till Nepal Government decided to ban the movement of 600 such vehicles in the early 2000. Earliest model of auto rickshaw running in Kathmandu were manufactured by Bajaj Auto. Nepal has been a popular destination for Rickshaw Run. The 2009 Fall Run took place in Goa, India and concluded in Pokhara, Nepal.
PAKISTAN
Auto rickshaws are a popular mode of transport in Pakistani towns and is mainly used for traveling short distances within cities. One of the major brands of auto rickshaws is Vespa (an Italian Company). Lahore is hub of CNG Auto rikshaws manufacturers in Pakistan.The government of Pakistan is taking measures to convert all the gasoline run auto-rickshaws to more effective CNG rickshaw by 2015 in all the major cities of Pakistan by issuing easy loans through commercial banks. Environment Canada is implementing pilot projects in Lahore, Karachi and Quetta with engine technology developed in Mississauga, Ontario, Canada that uses CNG instead of gasoline in the two-stroke engines, in an effort to combat environmental pollution and noise levels.
In many cities in Pakistan, there are also motorcycle rickshaws, usually called chand gari (moon car) or Chingchi (after the Chinese company Jinan Qingqi Motorcycle Co. Ltd who first introduced these to the market).
Rickshaws are forbidden in the capital, Islamabad.
Auto rickshaws have had a history of displaying political statements. In February 2013, that legacy was modified to promote peace. According to Syed Ali Abbas Zaidi, head of the Pakistan Youth Alliance, "We need to take back this romanticized art form and use it for peace sloganeering and conflict resolution."
Manufacturers There are many companies involving in Rickshaw manufacturing in Pakistan, some of them are, AECO Export Company, STAHLCO Motors, Global Sources, Parhiyar Automobiles, Global Ledsys Technologies, Siwa Industries, Prime Punjab Automobiles, Murshid Farm Industries, Sazgar Automobiles, NTN Enterprises, Imperial Engineering Company
PHILLIPINES
Auto rickshaws are an especially popular form of public transportation in the Philippines, where they are referred to as "tricycles" (Filipino: traysikel; Cebuano: traysikol). In the Philippines, the design and configuration of tricycles varies widely from place to place, but tends towards rough standardization within each municipality. The usual design is a passenger or cargo sidecar fitted to a motorcycle, usually on the right of the motorcycle. It is rare to find one with a left sidecar. Tricycles can carry five passengers or more in the sidecar, one or two pillion passengers behind the motorcycle driver, and even a few on the roof of the sidecar. Tricycles are one of the main contributors to air pollution in the Philippines, since majority of them employ two-stroke motorcycles. However, some local governments are working towards phasing out two-stroke-powered tricycles for ones with cleaner four-stroke motorcycles.
SRI LANKA
Auto rickshaws, commonly known as three-wheelers and more recently tuk-tuk, can be found on all roads in Sri Lanka from the curvy roads through the hill country to the congested roads of Colombo transporting locals, foreigners, or freight about. Sri Lankan three-wheelers are of the style of the light Phnom Penh type. Most of the three-wheelers in Sri Lanka are a slightly modified Indian Bajaj model, imported from India though there are few manufactured locally and increasingly imports from other countries in the region and other brands of three-wheelers such as Piaggio. In 2007 January the Sri Lankan government imposed a ban on all 2-stroke three-wheelers, due to environmental concerns and therefore the ones imported to the island now are the ones with four-stroke engines. Most three-wheelers are available as hiring vehicles, with few being used to haul goods and as private company or advertising vehicles. Bajaj enjoys a virtual monopoly in the island, with its agent being David Pieries Motor Co Ltd. A few three-wheelers in Sri Lanka have distance meters, and in the capital city it is becoming more and more common, however the vast majority of charges are negotiated between the passenger and driver.
THAILAND
The auto rickshaw, called tuk-tuk (Thai: ตุ๊กตุ๊ก, pronounced "took-took") or sam-lor (Thai: สามล้อ) meaning three-wheeler in Thailand, is a widely used form of urban transport in Bangkok and other Thai cities. It is particularly popular where traffic congestion is a major problem, such as in Bangkok and Nakhon Ratchasima. The name is onomatopoeic, mimicking the sound of a small (often two-cycle) engine. An equivalent English term would be "putt-putt."
Bangkok and other cities in Thailand have many tuk-tuks which are a more open variation on the Indian auto-rickshaw. There are no meters, and trip costs are negotiated in advance. Bangkok fares have risen to nearly equal normal taxis due to uninformed foreigners willing to pay the asking price, but leaves passengers more exposed to environmental pollution than taxis. The solid roof is so low that the tuk-tuk is a difficult touring vehicle. Today few locals take one unless they are burdened with packages or travelling in a big group for short distances.
The Thai tuk-tuk is starting to change from the old smoke-spewing vehicle of yesteryear. Many Thai tuk-tuk manufacturers now produce low emission vehicles, and even old ones are having new engines fitted along with LPG conversions. In an early morning of Bangkok, these same passenger vehicles can be seen busily transporting fresh produce around the city. Newer tuk-tuks also have wet weather sides to keep passengers and drivers dry.
The Thai auto-rikshaw manufacturers are, Monika Motors Ltd., TukTuk (Thailand) Co., Ltd., TukTuk Forwerder Co., Ltd. Bangkok and MMW Tuk-Tuks Co.,Ltd. in Hua Hin. Smaller manufacturers are the Chinnaraje Co., Ltd. in Chiang Mai and the Expertise Co., Ltd. in Chonburi which manufactures its models in Komaki, Japan, also.
VIETNAM
Known locally as xe lam, the vernacular pronunciation of the Lambro from the Lambretta line by Innocenti of Italy, these vehicles were very popular in the 1960s and 1970s, especially the urban centers of South Vietnam. Over time the authorities have moved to limit their use.
Xe lam with 1-wheel forward and 2-aft were designed to carry passengers whereas other variants with 2-forward and 1-aft, used mostly to transport goods are known as Xe ba gác máy. The motorized version of cycle rickshaw is the Xích lô máy is of the same design.
EUROPE
FRANCE
A number of Tuk-tuks ( 250 in 2013 according to the Paris Prefecture)are used as an alternative tourist transport system in Paris, some off them being pedal operated with the help of an electric engine. They are not yet fully licenced to operate and await customers on the streets. 'Velos taxis' were common during the Occupation years in Paris due to fuel restrictions.
ITALY
Auto rickshaws have been commonly used in Italy since the late 1940s, providing a low-cost means of transportation in the post-World-War-II years when the country was short of economic resources. The Piaggio Ape, designed by Vespa creator Corradino D'Ascanio and first manufactured in 1948 by the Italian company Piaggio, though primarily designed for carrying freight has also been widely used as an auto rickshaw. It is still extremely popular throughout the country, being particularly useful in the narrow streets found in the center of many little towns in central and southern Italy. Though it no longer has a key role in transportation, Piaggio Ape is still used as a minitaxi in some areas such as the islands of Ischia and Stromboli (on Stromboli no cars are allowed). It has recently been re-launched as a trendy-ecological means of transportation, or, relying on the role the Ape played in the history of Italian design, as a promotional tool. Since 2006 the Ape has been produced under licence in India.
NETHERLANDS
Since 2007, tuk-tuks have been active in the Netherlands, starting with Amsterdam. They now operate in Amersfoort, Amsterdam, The Hague, Zandvoort, Bergen op Zoom, the popular beach resort Renesse and Rotterdam. The tuk-tuks in the Netherlands are imported from India and Thailand. They are fitted with CNG engines and have passed the EURO-4 rules.
UNITED KINGDOM
The first Tuk Tuks to enter service in the United Kingdom were supplied and built by MMW Imports in 1999, under the brand name MMW Tuk Tuks. The very first Private Hire licence was issued to an MMW Tuk Tuk for tours of Bath in the year 2000, MMW also gained full Hackney license in Weston-super-Mare. MMW also now export Tuk Tuks from Thailand to the Netherlands, Germany, Spain, New Zealand and Australia. All the MMW range are built in their own factory in Thailand and are custom made for each customer's needs; hence no two tuk tuks are the same, and they come fully customized as per required spec.
Tukshop of Southampton started the commercial importing of Tuk Tuks into the UK in 2003, which resulted in many people being inspired to set up taxi-type operations in a number of cities including Blackpool, Brighton and Leeds. Tukshop failed to gain a taxi operator license for London after a number of media appearances in 2004. The company, founded by mrsteve, are specialists in experiential marketing using the iconic three-wheelers for street marketing campaigns. Clients of Tukshop include many household names, such as T Mobile, Harrods, Universal Pictures, O2, BBC, Freeview, Price Waterhouse Coopers, Tiger Beer & Grolsch lager. Tukshop have imported and put over one hundred tuk tuks on the roads of the UK and Europe between starting the business and Oct 2010. The company currently stocks models from Piaggio & Bajaj, including the commercial versions such as the TM Van.
A Bajaj tuk tuk is currently operated by Bangwallop of Salcombe, South Devon. Taking just two passengers at a time, the tuk tuk has an operator's licence issued by VOSA and trips can be booked in advance.[citation needed]
Auto rickshaws were introduced to the city of Brighton and Hove on 10 July 2006 by entrepreneur Dominic Ponniah's company Tuctuc Ltd, who had the idea after seeing the vehicles used in India and Sri Lanka. They were CNG-powered, using a four-speed (plus reverse) 175 cc engine. Under the terms of their license, the Bajas ran on a fixed single route, and stopped only at designated stops. They are of the same design as traditional auto rickshaws in other countries.
An investigation was launched into Tuctuc Ltd's operation of the service after complaints were raised, primarily by the city's taxi drivers, that routes, stopping points and timetables were not being adhered to. In November 2006, the company was fined £16,500 – the maximum penalty possible – by the South East Traffic Commissioner. After amendments were made to the timetable to reduce delays and improve reliability, the Commissioner allowed the company to keep its operating license. However, the company announced in January 2008 that it was ceasing operations, citing "archaic legislation" as the reason.
In the Scottish capital, Edinburgh, there is a new street food restaurant called Tuk Tuk Indian Street Food, that has its own branded Tuk Tuks, which are used for marketing around the town and picking up customers on special occasions.
CENTRAL AMERICA
EL SALVADOR
The mototaxi or moto is the El Salvadoran version of the auto rickshaw. These are most commonly made from the front end and engine of a motorcycle attached to a two-wheeled passenger area in back. Commercially produced models, such as the Indian Bajaj brand, are also employed.
GUATEMALA
In Guatemala the commercial vehicles are referred to as tuk-tuks. Tuk-tuks operate, both as taxis and private vehicles, in Guatemala City, Guatemala, around the island town of Flores, Peten, in the mountain city of Antigua Guatemala, and in many small towns in the mountains. In 2005 the tuk-tuks prevalent in the Lago de Atitlán towns of Panajachel and Santiago Atitlán all appeared to be from India (Bajaj Auto).
HONDURAS
Three-wheeled all-in-one tuk-tuks are used in the place of traditional taxis in most rural towns and villages.
NICARAGUA
As of 2011 there were an estimated 5,000 mototaxis, popularly known as "caponeras".
CARIBBEAN
Three-wheeled Coco taxis in Havana, Cuba
CUBA
Three-wheeled Coco taxis, named for their resemblance to a coconut, are used in Havana, Cuba.
SOUTH AMERICA
ECUADOR
The mototaxi is the Ecuatorian version of the auto rickshaw. These are most commonly made from the front end and engine of a motorcycle attached to a two-wheeled passenger area in back.
PERU
It is a common sight in the rural areas, towns and cities of Peru to see auto rickshaws, locally known as "mototaxis," "motokars", "taxi cholo", or "cholotaxi" lining up to pick up passengers as their fares are generally lower than car taxis. They are also in the capital, Lima, but they are usually restricted to the peripheral districts. The "jungle" cities and towns in eastern Peru are famous for their prevalence of auto rickshaws. This vehicle, usually running on regular unleaded gasoline, is the main non-private transport vehicle, and is known as "motocarro", "mototaxi" or "tuk-tuk" (for foreigners).
Many of the jungle areas of eastern Peru can be extremely noisy as a result of poorly maintained auto rickshaws and other 2 or 3-wheel vehicles, especially in high traffic or hilly areas. Auto-rickshaw brands such as the Indian-made Bajaj, which use GLP [a form of liquified petroleum gas which some car taxis also use] are much quieter.
NORTH AMERICA
UNITED STATES
Tuk Tuks were introduced to the United States through Tuk Tuk North America of Swainsboro, Georgia. As early as 2006, Mr. Roy Jordan, the owner of Tuk Tuk North America, began working with both the U.S. federal government and manufacturers in Thailand to configure a tuk tuk that was cost effective but adaptable to meet or exceed U.S. Department of Transportation regulations. He was able to contract a manufacturer who could make imported tuk tuks that could meet all necessary federal regulations in the U.S. Original products were imported from Thailand and were gas propelled. Due to the changing regulations of the Environmental Protection Agency, the introduction of imported gas-propelled tuk tuks was short-lived. Due to such changes, in 2009 Tuk Tuk North America decided to go dormant in its importing of gas propelled tuk tuks into the U.S.
However, with the growing emphasis on sustainable “green” energy and the recognition of the continuing rising oil prices, in 2011 the project's short dormancy was rejuvenated being redirected towards introduction of a complete line of all-electric tuk tuks. The line included eight models of "street legal" tuk tuks including passenger, utility, and delivery vehicles. These were offered under the manufacturer’s new name, Electro Technologies LLC, and marketed and sold exclusively through Tuk Tuk Transport LLC of Lenoir City, Tennessee, under the leadership of C. Phillip Tallant.
Prior to 2013, the greatest obstacle to commercial transportation usage of the electric tuk tuks created by Electro Technologies was addressed in mid 2013 by providing a means by which ET Tuk Tuks could be in service 24/7. With this advancement grew the opportunity for formation of Tuk Tuk of America, a company by which partnering affiliates across the U.S. could begin their own local niche urban mobility transportation company with guaranteed protected territories.
FUEL EFFICIENCY & POLLUTION
In July 1998, the Supreme Court of India ordered the Delhi government to implement CNG or LPG (Autogas) fuel for all autos and for the entire bus fleet in and around the city.[citation needed] Delhi's air quality has improved with the switch to CNG. Initially, auto rickshaw drivers in Delhi had to wait in long queues for CNG refueling, but the situation has improved with the increase of CNG stations. Certain local governments are pushing for four-stroke engines instead of the current two-stroke versions. Typical mileage for an Indian-made auto rickshaw is around 35 kilometers per liter of petrol (about 2.9 L per 100 km, or 82 miles per gallon [United States (wet measure), 100 miles per gallon Imperial (United Kingdom, Canada)]. Pakistan has passed a similar law prohibiting auto rickshaws in certain areas. CNG auto rickshaws have started to appear in huge numbers in many Pakistani cities.
In January 2007 the Sri Lankan government also banned two-stroke trishaws to reduce air pollution. In the Philippines there are projects to convert carburated two-stroke engines to direct-injected via Envirofit technology. Research has shown LPG or CNG gas direct-injection to be retrofit-able to existing engines in similar fashion to the Envirofit system. In Vigan City majority of tricycles-for-hire as of 2008 are powered by motorcycles with four-stroke engines, as tricycles with two-stroke motorcycles are prevented from receiving operating permits. Direct injection is standard equipment on new machines in India.
In March 2009 an international consortium coordinated by the International Centre for Hydrogen Energy Technologies initiated a two-year public-private partnership of local and international stakeholders aiming at operating a fleet of 15 hydrogen-fueled three-wheeled vehicles in New Delhi's Pragati Maidan complex. As of January 2011, the project was upon completion.
In the meantime, in October, 2011, the Department of Transportation for the U.S. approved the complete 2012 series of American made, all-electric tuk tuks by Electro Technologies. Chassis were still being shipped in from Thailand, but now with the inclusion of all electrical components as manufactured only in the U.S. with assembly completed in Chattanooga, Tennessee. The American made electric tuk tuks were unique in that they were charged through common 110v outlets providing a range of 60 to 100(+) miles per charge (depending upon model and conditions) with a recharge time between 4 to 6 hours. The Electro Technologies Tuk Tuks topped out at 40 miles per hour which perfectly addresses the needs of their design; niche urban mobile transportation.
The greatest obstacle to daily usage in niche urban mobile commercial transportation was addressed in 2013 by Electro Technologies when they introduced their quick-release battery pack allowing for restoration of 100% power availability in just a few short minutes. This commercial upgrade allowed niche urban transportation businesses to operate 24/7 with no interruption to business.
TRAFFIC ISSUES
Auto rickshaws have a top-speed of around 50 km/h (about 31 mph) and a cruising speed of around 35 km/h (22 mph), much slower than the automobiles they share the road with. Traffic authorities in big cities try to implement mechanisms to reduce the resulting traffic slowing, but none have proven effective.
The MMW Tuk Tuk has a top speed of around 70 mph and with the introduction of the new turbo will have much improved acceleration, to allow for increased speed these Tuk Tuks have anti-roll bars and are fitted with disc brakes.
The triangular form of the vehicle makes maneuvering easy, with the single front wheel negotiating the available gap, and the rear two wheels forcing a larger space. Care must be taken even at low speeds, however, because of the stability problems of three-wheeler vehicles with a single front wheel. Such a "delta"-configuration three-wheeler can easily roll if the driver turns while braking.
In the Philippines, 2-stroke motor tricycle such as Yamaha RS-100T can give a top speed of 55 km/h (one passenger in the sidecar), or 30–40 km/h (full passengers in the sidecar).
More powerful four-stroke motor tricycles such as Honda TMX & Yamaha STX & Bajaj CT-100 can give a top speed up to 70–85 km/h (special trip/one passenger) or 40–50 km/h (full passengers).
RACING
Due to their relatively low top-speed, auto rickshaws have never lent themselves to conventional road or street racing. However, their modest speed, simple construction and impressive fuel economy has endeared them to the international amateur adventuring community, most notably with the Rickshaw Run and also the Indian Autorickshaw Challenge, and even off-road racing with the Apecar competitions in Italy. A Tuk Tuk built by Art In Motion, LLC competed in the 2008 Fireball Run II – Back to the Track
PORTRAYAL IN MEDIA
Auto rickshaws are often portrayed in Indian films (Auto Shankar, Basha, Aye Auto, Oram Po, Hero Hiralal) as well as some Hollywood and foreign productions such as the James Bond film Octopussy, the Canada-India film Amal and the Indonesian movie Pembalasan Rambu. Auto rickshaws are also prominent in the fuel-poor London of 2027 A.D. depicted in Children of Men. A memorable tuk-tuk chase features in the Thai film Ong-Bak: Muay Thai Warrior, climaxing with many of them driving off the edge of an unfinished elevated expressway. The video games Just Cause 2, Stuntman, Far Cry 4 and Battlefield: Bad Company 2: Vietnam feature Tuk-Tuks as drivable vehicles. James Bond (Pierce Brosnan) rides in a tuk-tuk in a Visa Card commercial.
WIKIPEDIA
I’ve worked so closely with him , he’s such a real man , unlike young guys , he understands , he knows I’m different from other girls , at first he was unkind and rather cold towards me , but I worked hard and so efficiently , dressed nicely , soon he melted under my charm and , yes , flirtatious comments “Your looking so handsome today , Mr Brown “ I’d say , he replies with a smile “ Henry , Jennie , when there’s just the two of us , it’s Henry “ oh the thrill , I’ve finally broken the ice , soon we were sharing sexual glances , I remember the day I deliberately bent over his desk , he stood behind me , gently caressed my pert ass incased in my tight pencil skirt , “”One day Henry , soon I hope “ I say as I turn and smile a warm smile and wiggle my ass , it’s such an erotic moment “ It’s the office party next Saturday , would you , we’ll could we , can I ask you , to be my date” oh he’s so nervous , but finally said it ! “Oh yes please Henry , you won’t be disappointed , that I promise you “ I reply not too eagerly , he’s on the hook mustn’t rush him , scare him off . So here we are , in our own little world , we wined and dined , he’s such a gentleman , oh how his eyes lit up as I sashayed in , a little late , giggle , keeping him waiting , but also making an entrance too , so many envious male , yes , and female eyes on me , I saw the love, yes , and the desire in his eyes , I felt so feminine , so alive , hoping my dress wasn’t tenting , as my silk panties teased and caressed me in their silky folds . Now here we are on the dance floor , I can feel how aroused , oh yes , how big and hard he is as I press my hip into his groin and work him into a state of sexual excitement , he’s mine , I will be his too ! “I’ve taken the liberty of booking us a hotel room “ he nervously whispers “Oh Henry that was a bit presumptuous of you” I reply , just to tease and put him on the back foot , after all it’s our first date “”I’m so sorry , but I just thought………” I cut in , “Just thought I was easy prey , Henry , I’m not that kind of girl………..” I paused , saw the angst in his eyes poor man “ ………But having said that for you I’ll be every dream you ever dreamy and so much more ,I have so much more to offer too “ oh how he blushed , oh how he kissed me , yes that night he was mine and I was his girl !