Copyright © John G. Lidstone, all rights reserved.

It is an offence under law if you remove my copyright marking, or post this image anywhere else without my express written permission.

Surely, with new regulations governing diesel passenger rolling stock and emissions, the class 220/221 'Voyager' family must have a numbered amount of years left...good riddance! With the fumes lingering long after they'd gone, an unidentified Virgin pair race north through Balshaw Lane Jn on 17/02/18.

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]

en.wikipedia.org/wiki/BMW_i8

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]

en.wikipedia.org/wiki/BMW_i8

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.

got flat Honda tire? no problem,. There are "repair shops" on almost every street ..

Saigon, Vietnam

Construction at the new $52 million Urlas townhouses located in Ansbach,Germany is approximately at the half way point. These energy efficient Passivhauser or passive homes are German designed. When complete, each of the 22 homes will use approximately one-fourth the energy demands of a standard German home. To the Soldier living in them, there will be little visual different with the expection of a solar panel on each roof. The real difference is on the walls and in the windows. Extra thick insulation, triple-paned glass and innovative HVAC system makes these townhomes the most energy efficient homes in the Department of the Defense. (U.S. Army Corps of Engineers photo by Carol E. Davis)

Efficient Weight-loss Natural Treatment / therapeutic programs are provided in Czech Health SPA.

The old dishwasher (GE Nautilus) used $58 to operate per year with an electric water heater and $31 per year with a gas water heater (according to the old dishwasher's Energy Guide).

25 per cent more efficient from 2025.

Enhanced with further technologies and innovative high-temperature materials, the Advance core overall pressure ratio is pushed to more than 70:1. UltraFan also features a new geared architecture (introduced between the fan and intermediate pressure compressor),ensuring the fan runs at optimum speed, as does the engine compressor and turbine thanks to the core architecture. The carbon titanium fan system is further developed to allow the removal of the thrust reverser, enabling a truly slim-line nacelle system

Manchester Victoria station was the biggest station, and the headquarters, of the Lancashire & Yorkshire Railway - a complex, efficient and busy railway that is criminally under-studied by historians simply due to its sin of not serving London. It was never glamorous, with its black locomotives carrying coal and cotton, and its passenger trains going to Colne, or Todmorden, or Wigan.

Yet it was fascinating, and its station at Victoria especially so. In British Rail days, Victoria was messy, scruffy, unloved, complicated... and glorious. Even in the 1980s it was worth spending time on platform 11 (once the longest station platform in the world, combined with Exchange's main platform) watching the trains go by hauled by class 40s, 45s and 47s with DMUs beetling to and fro - while the Bury electric units glided in and out regularly from their bay platform.

The eastward route from Victoria consisted of a steep bank, almost from the platform end, to Miles Platting two miles away. Banking engines were always kept ready on this siding next to platform 12, and it was always known as 'the wall side' - strangely, as it was right in the centre of the station with no wall anywhere near it...

On this summer's day, LYR 'coffee pot' 0-6-0 engines 52341 and 52431 awaited their next duty while at platform 12 alongside, a Blackpool (Central) to Manchester express had terminated. The dirt is everywhere - the engines are dirty, there are piles of cinders next to the track, and the timber screen (erected after wartime bomb damage) clearly hadn't seen a lick of paint since it was put there. But it was a wonderful place to stand and watch trains (and the top decks of buses passing over the bridge just visible in the background).

Everything in this photo is long gone. Dirty, scruffy Manchester Victoria was largely replaced by a newer, more functional station with the AO Arena above - although thankfully, the main offices and frontage were retained. The new Victoria is also much smaller, with no need for newspaper loading platforms and no trains to Accrington via Heywood. In fact, it's now generally realised that Voctoria was over-pruned and with the growth in passenger numbers in the last 30 years, a couple more platforms might have been useful.

Victoria also now sees Metrolink, Greater Manchester's modern tramway system, and Victoria is one of its busiest and biggest stops. A new overall roof keeps passengers dry, and if you wander off a tram onto the main station concourse, a fair bit of Victoria's grandeur still remains. It's worth stopping off there for a look around.

If you'd like to know more about the Museum of Transport Greater Manchester and its collection of vintage buses, go to motgm.uk.

© Greater Manchester Transport Society. All rights reserved. Unauthorised reproduction is strictly prohibited and may result in action being taken to protect the intellectual property interests of the Society.

2,000 views on 14th November 2013

1,000 views on 11th October 2013

The "new" Police Station

In compliance with the Police (Scotland) Act of 1857 every County in Scotland (excluding Orkney & Shetland) was required to set up a police force or unite with a neighbour. In most cases what happened was the existing force was reconstituted, albeit with major clearance of existing staff.

Provided the force was deemed efficient, a Government grant of 25 per cent of the annual cost of upkeep of the force (wages and uniforms) was paid. To establish efficiency or otherwise, a new position - Her Majesty’s Inspector for Scotland (“HMI”) – was created and that poor soul travelled the length and breadth of Scotland every year, inspecting every force (including burgh/city ones if they had decided to remain separate from their County neighbours).

In the inaugural Report, produced in May 1859, and which covered the period from 16.3.1858 to 15.3.1859, the original Inspector, Colonel John Kinloch outlined his duty : to 'visit and enquire into the State and Efficiency of the Police appointed for every County and Burgh, and also into the State of the Police Stations, Charge Rooms, Cells, or Lock-ups, and other Premises occupied for the Use of such Police'.

He did however appreciate that “Rome was not built in a day” - and obviously neither were police stations!

In Colonel Kinloch's next Annual Report - covering the period March 1859 to March 1860 – he noted that the Sutherland Force had grown by one to NINE (one man for each district)and that there were also proposals to build a police station in the County Town of Dornoch. Presumably the Force Headquarters at that time was merely a spare room (or two) within the Sheriff Courthouse, or in the old Court building/Jail.

The officer for Dornoch would be the Sergeant (Deputy Chief Constable) by then, although the Chief constable would have been also the local bobby up until then. It would be some time before a Constable was also based in Dornoch. But despite that, there was still a need for a proper police office for the officer(s) to work out of and where the public could attend to make complaints, and also to hold prisoners.

Whichever building was used up until then would have been unsatisfactory, being without suitable accommodation in which to lodge prisoners - brought in from all parts of the county for Court appearance before the Sheriff.

The Commissioners met again on 30 April 1861, when a further increase in the Rogue Money assessment was set, this year being £200. The sum of £350 was to be required as the Police assessment for the year to 15/3/1862, to cover the cost of salaries, uniforms and other matters.

"The meeting do further assess a sum of £400 towards the expense of erecting a Police Station in Dornoch ... in terms of a pledge given (to) Colonel Kinloch, Her Majesty's Inspector of the constabulary force in Scotland, as the condition under which he reported the police force of this County efficient, entitling them to draw the Government allowance of 25 per cent, but this sum was not to be collected before the first day of October next."

The plans of the Station, and all matters relating to it, along with the contracts involved, were delegated to the Police Committee with full powers to take the matter forward to completion.

Mr Kinloch in April 1862 reported that plans (for the new Station at Dornoch) were well advanced. His plan had worked for once. Not all Counties and Burgh Police authorities were prepared to work with him - many stubbornly resisted his proposals!

Then, at the Annual Meeting of the Commissioners held on 30/4/1862, when it came to calculating the Police Assessment: "The Commissioners do therefore assess ... in the sum of £380, with a further sum of £300 to complete the Police Station now in the course of erection in the Burgh of Dornoch."

On 30th April 1863, the Police Assessment came to:"£850 including a balance due to the Bank disbursed on account of erecting the new Police Station."

Value for money was important, and value the people of Sutherland got! That building – in Dornoch Square - would be used as a Police Station for nearly 120 years!

As well as being the local Police Station for the Burgh of Dornoch (the burgh was one of few in Scotland never to have its own police force), it served as the Headquarters for the Sutherland Constabulary until that force merged with the Ross & Cromarty Constabulary in May 1963 – to form Ross & Sutherland Constabulary.. Thereafter it was the Sub Divisional Office for Sutherland throughout the existence of Ross & Sutherland Constabulary - which merged with the other forces of the Scottish Highlands & Islands on 16th May 1975 to form Northern Constabulary.

The original building was clearly by then no longer fit for purpose and plans were already afoot to build a new Station in Dornoch, and this finally opened in the early 1980s. Set on a rise just beyond the Square, it occupied an imposing position overlooking a petrol filling station, affording a good clear view of the Square and right up the main thoroughfare of Dornoch. At least it did, until the filling station went the same way as most urban ones, and closed and became a prime location for the building of flatted dwellings. Now the station no longer has a view, thanks to the new three story structure which now stands in front of it.

The new police station became the new Sub Divisional Station for Sutherland (Part of Central Division, which comprised almost the whole of the former Ross and Sutherland force area) , originally with a Chief Inspector and Inspector in charge. The higher rank was however soon redeployed elsewhere, an early precursor of a rationalisation of ranks.

In due course, in the early 1990s the Divisional structure was dissolved within Northern Constabulary, and 8 Area Commands were set up instead. Sutherland became a Sub Area of Caithness and Sutherland, with the Inspector at Dornoch being in charge of Sutherland Sub Area. More recent changes saw boundary changes result in formation on an enlarged Area Command, retitled Caithness, Sutherland and Easter Ross.

Dornoch was never a 24-hour Station and in 2011, Northern Constabulary announced a number of Station closures. Dornoch, as a larger station, would remain open but the public counter would only be open 0900-1700 Monday-Friday.

These days, it seems few members of the public actually call in person at a police station – most contact is nowadays done by telephone. Such is progress?

In preparation for the merger of all 8 Scottish Police Forces to form the “Police Service of Scotland” on 1st April 2013, signage was de-badged to remove all mention of the former force of origin. Hence removal of the sizeable Northern Constabulary logo from the Police Station sign board has resulted in an over-abundance of white space.

Although the “new” station is not unpleasing to the eye, to my mind the original station is far more impressive – even if was designed more on dwelling-house lines than as a “Police Complex”. It is one of a line of grand structures (all facing the Cathedral) ranked along the main street of Dornoch, including the old Jail (now a large shop), the Sheriff Courthouse (soon scheduled to close in favour of Tain) and the Bishop’s Castle (now a Hotel) - what once comprised a whole line of symbols of Dornoch’s status as an ancient Royal Burgh, Cathedral City and County town.

A light mech designed for speed and hunting. Typically seen in squads with two or three other soldiers. These "Hunting Parties" have proved time and again to be deadly efficient.

The palanquin is a class of wheelless vehicles, a type of human-powered transport, for the transport of persons. Examples of litter vehicles include lectica (ancient Rome), kiệu [轎] (Vietnam), sedan chair (Britain), litera (Spain), palanquin (France, India, Ghana), jiao (China), liteira (Portugal), wo (วอ, Chinese style known as kiao เกี้ยว) (Thailand), gama (Korea), koshi, ren and kago [駕籠] (Japan) and tahtırevan (Turkey).

Smaller litters may take the form of open chairs or beds carried by two or more carriers, some being enclosed for protection from the elements. Larger litters, for example those of the Chinese emperors, may resemble small rooms upon a platform borne upon the shoulders of a dozen or more people. To most efficiently carry a litter, porters will attempt to transfer the load to their shoulders, either by placing the carrying poles upon their shoulders, or the use of a yoke to transfer the load from the carrying poles to the shoulder.

DEFINITIONS

A simple litter, often called a king carrier, consists of a sling attached along its length to poles or stretched inside a frame. The poles or frame are carried by porters in front and behind. Such simple litters are common on battlefields and emergency situations, where terrain prohibits wheeled vehicles from carrying away the dead and wounded.

Litters can also be created by the expedient of the lashing of poles to a chair. Such litters, consisting of a simple cane chair with maybe an umbrella to ward off the elements and two stout bamboo poles, may still be found in Chinese mountain resorts such as the Huangshan Mountains to carry tourists along scenic paths and to viewing positions inaccessible by other means of transport.

A more luxurious version consists of a bed or couch, sometimes enclosed by curtains, for the passenger or passengers to lie on. These are carried by at least two porters in equal numbers in front and behind, using wooden rails that pass through brackets on the sides of the couch. The largest and heaviest types would be carried by draught animals.

Another form, commonly called a sedan chair, consists of a chair or windowed cabin suitable for a single occupant, also carried by at least two porters in front and behind, using wooden rails that pass through brackets on the sides of the chair. These porters were known in London as "chairmen". These have been very rare since the 19th century, but such enclosed portable litters have been used as an elite form of transport for centuries, especially in cultures where women are kept secluded.

Sedan chairs, in use until the 19th century, were accompanied at night by link-boys who carried torches. Where possible, the link boys escorted the fares to the chairmen, the passengers then being delivered to the door of their lodgings. Several houses in Bath, Somerset, England still have the link extinguishers on the exteriors, shaped like outsized candle snuffers. In the 1970s, entrepreneur and Bathwick resident, John Cuningham, revived the sedan chair service business for a brief amount of time.

ANTIQUITY

In pharaonic Egypt and many oriental realms such as China, the ruler and divinities (in the form of an idol) were often transported in a litter in public, frequently in procession, as during state ceremonial or religious festivals.

The ancient Hebrews fashioned the Ark of the Covenant to resemble and function as a litter for the ten commandments and presence of God.

In Ancient Rome, a litter called lectica or "sella" often carried members of the imperial family, as well as other dignitaries and other members of the rich elite, when not mounted on horseback.

The habit must have proven quite persistent, for the Third Council of Braga in 675 AD saw the need to order that bishops, when carrying the relics of martyrs in procession, must walk to the church, and not be carried in a chair, or litter, by deacons clothed in white.

In the Catholic Church, Popes were carried the same way in Sedia gestatoria, which was replaced later by the Popemobile.

IN ASIA

CHINA

In Han China the elite travelled in light bamboo seats supported on a carrier's back like a backpack. In the Northern Wei Dynasty and the Northern and Southern Song Dynasties, wooden carriages on poles appear in painted landscape scrolls.

A commoner used a wooden or bamboo civil litter (Chinese: 民轎; pinyin: min2 jiao4), while the mandarin class used an official litter (Chinese: 官轎; pinyin: guan1 jiao4) enclosed in silk curtains.

The chair with perhaps the greatest importance was the bridal chair. A traditional bride is carried to her wedding ceremony by a "shoulder carriage" (Chinese: 肩輿; pinyin: jiān yú), usually hired. These were lacquered in an auspicious shade of red, richly ornamented and gilded, and were equipped with red silk curtains to screen the bride from onlookers.

Sedan chairs were once the only public conveyance in Hong Kong, filling the role of cabs. Chair stands were found at all hotels, wharves, and major crossroads. Public chairs were licensed, and charged according to tariffs which would be displayed inside. Private chairs were an important marker of a person's status. Civil officers' status was denoted by the number of bearers attached to his chair. Before Hong Kong's Peak Tram went into service in 1888, wealthy residents of The Peak were carried on sedan chairs by coolies up the steep paths to their residence including Sir Richard MacDonnell's (former Governor of Hong Kong) summer home, where they could take advantage of the cooler climate. Since 1975 an annual sedan chair race has been held to benefit the Matilda International Hospital and commemorate the practice of earlier days.

KOREA

In Korea, royalty and aristocrats were carried in wooden litters called gama. Gamas were primarily used by royalty and government officials. There were six types of gama, each assigned to different government official rankings. In traditional weddings, the bride and groom are carried to the ceremony in separate gamas. Because of the difficulties posed by the mountainous terrain of the Korean peninsula and the lack of paved roads, gamas were preferred over wheeled vehicles.

JAPAN

As the population of Japan increased, less and less land was available as grazing for the upkeep of horses. With the availability of horses restricted to martial uses, human powered transport became more important and prevalent.

Kago (Kanji: 駕籠, Hiragana: かご) were often used in Japan to transport the non-samurai citizen. Norimono were used by the warrior class and nobility, most famously during the Tokugawa period when regional samurai were required to spend a part of the year in Edo (Tokyo) with their families, resulting in yearly migrations of the rich and powerful (Sankin-kōtai) to and from the capital along the central backbone road of Japan.

Somewhat similar in appearance to kago are the portable shrines that are used to carry the "god-body" (goshintai), the central totemic core normally found in the most sacred area of Shinto Shrines, on a tour to and from a shrine during some religious festivals.

THAILAND

In Thailand, the royalty were also carried in wooden litters called wo ("พระวอ" Phra Wo, literally, "Royal Sedan") for large ceremonies. Wos were elaborately decorated litters that were delicately carved and colored by gold leaves. Stained glass is also used to decorate the litters. Presently, Royal Wos and carriages are only used for royal ceremonies in Thailand. They are exhibited in the Bangkok National Museum.

INDONESIA

In traditional Javanese society, the generic palanquin or joli was a wicker chair with a canopy, attached to two poles, and borne on men's shoulders, and was available for hire to any paying customer. As a status marker, gilded throne-like palanquins, or jempana, were originally reserved solely for royalty, and later co-opted by the Dutch, as a status marker: the more elaborate the palanquin, the higher the status of the owner. The joli was transported either by hired help, by nobles' peasants, or by slaves.

Historically, the palanquin of a Javanese king (raja), prince (pangeran), lord (raden mas) or other noble (bangsawan) was known as a jempana; a more throne-like version was called a pangkem. It was always part of a large military procession, with a yellow (the Javanese colour for royalty) square canopy. The ceremonial parasol (payung) was held above the palanquin, which was carried by a bearer behind and flanked by the most loyal bodyguards, usually about 12 men, with pikes, sabres, lances, muskets, keris and a variety of disguised blades. In contrast, the canopy of the Sumatran palanquin was oval-shaped and draped in white cloth; this was reflective of greater cultural permeation by Islam. Occasionally, a weapon or heirloom, such as an important keris or tombak, was given its own palanquin. In Hindu culture in Bali today, the tradition of using palanquins for auspicious statues, weapons or heirlooms continues, for funerals especially; in more elaborate rituals, a palanquin is used to bear the body, and is subsequently cremated along with the departed.

INDIA

A palanquin, also known as palkhi, is a covered sedan chair (or litter) carried on four poles. It derives from the Sanskrit word for a bed or couch, pa:lanka.

Palanquins are mentioned in literature as early as the Ramayana (c. 250BC).

Palanquins began to fall out of use after rickshaws (on wheels, more practical) were introduced in the 1930s.

The doli (also transliterated from Hindi as dhooly or dhoolie) is a cot or frame, suspended by the four corners from a bamboo pole. Two or four men would carry it. In the time of the British in India, dhooly-bearers were used to carry the wounded from the battlefield and transport them.

Today in numerous areas of India including at the Hindu pilgrimage site of Amarnath Temple in Kashmir, palanquins can be hired to carry the customer up steep hills.

IN AFRICA

GHANA

In Southern Ghana the Akan and the Ga-Dangme carry their chiefs and kings in palanquins when they appear in their state durbars. When used in such occasions these palanquins may be seen as a substitutes of a state coach in Europe or a horse used in Northern Ghana. The chiefs of the Ga (mantsemei) in the Greater Accra Region (Ghana) use also figurative palanquins which are built after a chief's family symbol or totem. But these day the figurative palanquins are very seldom used. They are related with the figurative coffins which have become very popular among the Ga in the last 50 years. Since these figurative coffins were shown 1989 in the exhibition "Les magicians de la terre" in the Centre Pompidou in Paris they were shown in many art museums around the world.

ANGOLA

From at least the 15th century until the 19th century, litters of varying types known as tipoye were used in the Kingdom of Kongo as a mode of transportation for the elites. Seat-style litters with a single pole along the back of the chair carried by two men (usually slaves) were topped with an umbrella. Lounge-style litters in the shape of a bed were used to move one to two people with porter at each corner. Due to the tropical climate, horse were not native to the area nor could they survive very ong once introduced by the Portuguese. Human portage was the only mode of transportation in the region and became highly adept with missionary accounts claiming the litter transporters could move at speeds 'as fast as post horses at the gallop'.

IN THE WEST

EUROPE

Portuguese and Spanish navigators and colonistics encountered litters of various sorts in India, Mexico, and Peru. They were imported into Spain and spread into France and then Britain. All the names for these devices are ultimately derived from the root sed- in Latin sedere, "sit," which gave rise to seda ("seat") and its diminutive sedula ("little seat"), the latter of which was contracted to sella, the traditional Latin name for a carried chair.The carried chair met instant success in Europe, whose city streets were often a literal mess of mud and refuse: Where cities and towns did not enjoy the presence of sewage systems left over from Imperial Roman days, it was common to empty chamber pots and discard kitchen refuse from windows down into the adjacent streets. Affluent and well-to-do citizens often found it hazardous and impractical to negotiate those avenues, and sedan chairs allowed them to remain prim and spotless while the carrying valets had to contend with the mud and the filth.In Europe, Henry VIII of England was carried around in a sedan chair — it took four strong chairmen to carry him towards the end of his life — but the expression "sedan chair" was not used in print until 1615. It does not seem to take its name from the city of Sedan. Trevor Fawcett notes (see link) that British travellers Fynes Moryson (in 1594) and John Evelyn (in 1644-5) remarked on the seggioli of Naples and Genoa, which were chairs for public hire slung from poles and carried on the shoulders of two porters.From the mid-17th century, visitors taking the waters at Bath would be conveyed in a chair enclosed in baize curtains, especially if they had taken a heated bath and were going straight to bed to sweat. The curtains kept off a possibly fatal draft. These were not the proper sedan chairs "to carry the better sort of people in visits, or if sick or infirmed" (Celia Fiennes). In the 17th and 18th centuries, the chairs stood in the main hall of a well-appointed city residence, where a lady could enter and be carried to her destination without setting foot in a filthy street. The neoclassical sedan chair made for Queen Charlotte remains at Buckingham Palace.

By the mid-17th century, sedans for hire were a common mode of transportation. In London, "chairs" were available for hire in 1634, each assigned a number and the chairmen licensed because the operation was a monopoly of a courtier of Charles I. Sedan chairs could pass in streets too narrow for a carriage and were meant to alleviate the crush of coaches in London streets, an early instance of traffic congestion. A similar system was later used in Scotland. In 1738, a fare system was established for Scottish sedans, and the regulations covering chairmen in Bath are reminiscent of the modern Taxi Commission's rules. A trip within a city cost six pence and a day's rental was four shillings. A sedan was even used as an ambulance in Scotland's Royal Infirmary.

Chairmen moved at a good clip. In Bath they had the right-of-way and pedestrians hearing "By your leave" behind them knew to flatten themselves against walls or railings as the chairmen hustled through. There were often disastrous accidents, upset chairs, and broken glass-paned windows.

Sedan chairs were also used by the wealthy in the cities of colonial America. Benjamin Franklin used a sedan chair late in the 18th century.

COLONIAL PRACTICE

In various colonies, litters of various types were maintained under native traditions, but often adopted by the white colonials as a new ruling and/or socio-economic elite, either for practical reasons (often comfortable modern transport was unavailable, e.g. for lack of decent roads) and/or as a status symbol. During the 17-18th centuries, palanquins (see above) were very popular among European traders in Bengal, so much so that in 1758 an order was issued prohibiting their purchase by certain lower-ranking employees.

THE END OF A TRADITION

In Great Britain, in the early 19th century, the public sedan chair began to fall out of use, perhaps because streets were better paved or perhaps because of the rise of the more comfortable, companionable and affordable hackney carriage. In Glasgow, the decline of the sedan chair is illustrated by licensing records which show twenty-seven sedan chairs in 1800, eighteen in 1817, and ten in 1828. During that same period the number of registered hackney carriages in Glasgow rose to one hundred and fifty.

THE TRAVELING SILLA OF LATIN AMERICA

A similar but simpler palanquin was used by the elite in parts of 18th- and 19th-century Latin America. Often simply called a silla (Spanish for seat or chair), it consisted of a simple wooden chair with an attached tumpline. The occupant sat in the chair, which was then affixed to the back of a single porter, with the tumpline supported by his head. The occupant thus faced backwards during travel. This style of palanquin was probably due to the steep terrain and rough or narrow roads unsuitable to European-style sedan chairs. Travellers by silla usually employed a number of porters, who would alternate carrying the occupant.

A chair borne on the back of a porter, almost identical to the silla, is used in the mountains of China for ferrying older tourists and visitors up and down the mountain paths. One of these mountains where the silla is still used is the Huangshan Mountains of Anhui province in Eastern China.

WIKIPEDIA

Energy Efficient Light

as featured (in violation of license terms) on ridiculous pages like this and this; also featured in a presentation on, of all things, pair programming

A47

Construction on a vehicle maintenance warehouse near the company and battalion operations centers south of U.S. Army Garrison Grafenwoehr's PX/Commissary complex nears completion as one of the final projects in U.S. Army Europe's $700+ million Efficient Basing Grafenwoehr program, which is set to complete in spring 2010. (U.S. Army Corps of Engineers photo by Justin Ward)

Day 25. 120 hours total.

To me, the puzzling is over and has morphed into a fill-in-the-blanks exercise. It's just plugging in pieces, everything carefully arranged by shape on pieces of cardboard. I spend my time scanning through the columns and rows, occasionally trying a piece but usually just a lot of scanning until the correct piece is found. I build off a 'corner' spot where two sides of the connecting piece are known; this narrows down the possible piece shapes: the two adjacent sides could be either knob, knob; knob, hole; or hole, hole.

It's an incredibly boring process and to me, the antithesis of puzzling. There isn't any of the enjoyment of interacting with color, detail, texture and line; pairing up pieces independently and slowly watching pods build. Or the act of touching and moving pieces around, which in and of itself creates serendipitous connections.

But at this point, it is the most efficient way (short of using the pattern) to complete the rest of the puzzle.

To complete the stone work took 5 hrs., 50 mins. The remaining 4:10 has been spent on the shadow of the red dress, which is slow going so far (although, some of that time was spent sorting out deep-reds from deep-blues and then arranging pieces into formation).

Really ready to get this thing done with.

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.

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

Construction on a vehicle maintenance warehouse near the company and battalion operations centers south of U.S. Army Garrison Grafenwoehr's PX/Commissary complex nears completion as one of the final projects in U.S. Army Europe's $700+ million Efficient Basing Grafenwoehr program, which is set to complete in spring 2010. (U.S. Army Corps of Engineers photo by Justin Ward)

efficient line

Construction at the new $52 million Urlas townhouses located in Ansbach,Germany is approximately at the half way point. These energy efficient Passivhauser or passive homes are German designed. When complete, each of the 22 homes will use approximately one-fourth the energy demands of a standard German home. To the Soldier living in them, there will be little visual different with the exception of a solar panel on each roof. The real difference is on the walls and in the windows. Extra thick insulation, triple-paned glass and innovative HVAC system makes these townhomes the most energy efficient homes in the Department of the Defense. (U.S. Army Corps of Engineers photo by Carol E. Davis)

The palaquin is a class of wheelless vehicles, a type of human-powered transport, for the transport of persons. Examples of litter vehicles include lectica (ancient Rome), kiệu [轎] (Vietnam), sedan chair (Britain), litera (Spain), palanquin (France, India, Ghana), jiao (China), liteira (Portugal), wo (วอ, Chinese style known as kiao เกี้ยว) (Thailand), gama (Korea), koshi, ren and kago [駕籠] (Japan) and tahtırevan (Turkey).

Smaller litters may take the form of open chairs or beds carried by two or more carriers, some being enclosed for protection from the elements. Larger litters, for example those of the Chinese emperors, may resemble small rooms upon a platform borne upon the shoulders of a dozen or more people. To most efficiently carry a litter, porters will attempt to transfer the load to their shoulders, either by placing the carrying poles upon their shoulders, or the use of a yoke to transfer the load from the carrying poles to the shoulder.

DEFINITIONS

A simple litter, often called a king carrier, consists of a sling attached along its length to poles or stretched inside a frame. The poles or frame are carried by porters in front and behind. Such simple litters are common on battlefields and emergency situations, where terrain prohibits wheeled vehicles from carrying away the dead and wounded.

Litters can also be created by the expedient of the lashing of poles to a chair. Such litters, consisting of a simple cane chair with maybe an umbrella to ward off the elements and two stout bamboo poles, may still be found in Chinese mountain resorts such as the Huangshan Mountains to carry tourists along scenic paths and to viewing positions inaccessible by other means of transport.

A more luxurious version consists of a bed or couch, sometimes enclosed by curtains, for the passenger or passengers to lie on. These are carried by at least two porters in equal numbers in front and behind, using wooden rails that pass through brackets on the sides of the couch. The largest and heaviest types would be carried by draught animals.

Another form, commonly called a sedan chair, consists of a chair or windowed cabin suitable for a single occupant, also carried by at least two porters in front and behind, using wooden rails that pass through brackets on the sides of the chair. These porters were known in London as "chairmen". These have been very rare since the 19th century, but such enclosed portable litters have been used as an elite form of transport for centuries, especially in cultures where women are kept secluded.

Sedan chairs, in use until the 19th century, were accompanied at night by link-boys who carried torches. Where possible, the link boys escorted the fares to the chairmen, the passengers then being delivered to the door of their lodgings. Several houses in Bath, Somerset, England still have the link extinguishers on the exteriors, shaped like outsized candle snuffers. In the 1970s, entrepreneur and Bathwick resident, John Cuningham, revived the sedan chair service business for a brief amount of time.

ANTIQUITY

In pharaonic Egypt and many oriental realms such as China, the ruler and divinities (in the form of an idol) were often transported in a litter in public, frequently in procession, as during state ceremonial or religious festivals.

The ancient Hebrews fashioned the Ark of the Covenant to resemble and function as a litter for the ten commandments and presence of God.

In Ancient Rome, a litter called lectica or "sella" often carried members of the imperial family, as well as other dignitaries and other members of the rich elite, when not mounted on horseback.

The habit must have proven quite persistent, for the Third Council of Braga in 675 AD saw the need to order that bishops, when carrying the relics of martyrs in procession, must walk to the church, and not be carried in a chair, or litter, by deacons clothed in white.

In the Catholic Church, Popes were carried the same way in Sedia gestatoria, which was replaced later by the Popemobile.

IN ASIA

CHINA

In Han China the elite travelled in light bamboo seats supported on a carrier's back like a backpack. In the Northern Wei Dynasty and the Northern and Southern Song Dynasties, wooden carriages on poles appear in painted landscape scrolls.

A commoner used a wooden or bamboo civil litter (Chinese: 民轎; pinyin: min2 jiao4), while the mandarin class used an official litter (Chinese: 官轎; pinyin: guan1 jiao4) enclosed in silk curtains.

The chair with perhaps the greatest importance was the bridal chair. A traditional bride is carried to her wedding ceremony by a "shoulder carriage" (Chinese: 肩輿; pinyin: jiān yú), usually hired. These were lacquered in an auspicious shade of red, richly ornamented and gilded, and were equipped with red silk curtains to screen the bride from onlookers.

Sedan chairs were once the only public conveyance in Hong Kong, filling the role of cabs. Chair stands were found at all hotels, wharves, and major crossroads. Public chairs were licensed, and charged according to tariffs which would be displayed inside. Private chairs were an important marker of a person's status. Civil officers' status was denoted by the number of bearers attached to his chair. Before Hong Kong's Peak Tram went into service in 1888, wealthy residents of The Peak were carried on sedan chairs by coolies up the steep paths to their residence including Sir Richard MacDonnell's (former Governor of Hong Kong) summer home, where they could take advantage of the cooler climate. Since 1975 an annual sedan chair race has been held to benefit the Matilda International Hospital and commemorate the practice of earlier days.

KOREA

In Korea, royalty and aristocrats were carried in wooden litters called gama. Gamas were primarily used by royalty and government officials. There were six types of gama, each assigned to different government official rankings. In traditional weddings, the bride and groom are carried to the ceremony in separate gamas. Because of the difficulties posed by the mountainous terrain of the Korean peninsula and the lack of paved roads, gamas were preferred over wheeled vehicles.

JAPAN

As the population of Japan increased, less and less land was available as grazing for the upkeep of horses. With the availability of horses restricted to martial uses, human powered transport became more important and prevalent.

Kago (Kanji: 駕籠, Hiragana: かご) were often used in Japan to transport the non-samurai citizen. Norimono were used by the warrior class and nobility, most famously during the Tokugawa period when regional samurai were required to spend a part of the year in Edo (Tokyo) with their families, resulting in yearly migrations of the rich and powerful (Sankin-kōtai) to and from the capital along the central backbone road of Japan.

Somewhat similar in appearance to kago are the portable shrines that are used to carry the "god-body" (goshintai), the central totemic core normally found in the most sacred area of Shinto Shrines, on a tour to and from a shrine during some religious festivals.

THAILAND

In Thailand, the royalty were also carried in wooden litters called wo ("พระวอ" Phra Wo, literally, "Royal Sedan") for large ceremonies. Wos were elaborately decorated litters that were delicately carved and colored by gold leaves. Stained glass is also used to decorate the litters. Presently, Royal Wos and carriages are only used for royal ceremonies in Thailand. They are exhibited in the Bangkok National Museum.

INDONESIA

In traditional Javanese society, the generic palanquin or joli was a wicker chair with a canopy, attached to two poles, and borne on men's shoulders, and was available for hire to any paying customer. As a status marker, gilded throne-like palanquins, or jempana, were originally reserved solely for royalty, and later co-opted by the Dutch, as a status marker: the more elaborate the palanquin, the higher the status of the owner. The joli was transported either by hired help, by nobles' peasants, or by slaves.

Historically, the palanquin of a Javanese king (raja), prince (pangeran), lord (raden mas) or other noble (bangsawan) was known as a jempana; a more throne-like version was called a pangkem. It was always part of a large military procession, with a yellow (the Javanese colour for royalty) square canopy. The ceremonial parasol (payung) was held above the palanquin, which was carried by a bearer behind and flanked by the most loyal bodyguards, usually about 12 men, with pikes, sabres, lances, muskets, keris and a variety of disguised blades. In contrast, the canopy of the Sumatran palanquin was oval-shaped and draped in white cloth; this was reflective of greater cultural permeation by Islam. Occasionally, a weapon or heirloom, such as an important keris or tombak, was given its own palanquin. In Hindu culture in Bali today, the tradition of using palanquins for auspicious statues, weapons or heirlooms continues, for funerals especially; in more elaborate rituals, a palanquin is used to bear the body, and is subsequently cremated along with the departed.

INDIA

A palanquin, also known as palkhi, is a covered sedan chair (or litter) carried on four poles. It derives from the Sanskrit word for a bed or couch, pa:lanka.

Palanquins are mentioned in literature as early as the Ramayana (c. 250BC).

Palanquins began to fall out of use after rickshaws (on wheels, more practical) were introduced in the 1930s.

The doli (also transliterated from Hindi as dhooly or dhoolie) is a cot or frame, suspended by the four corners from a bamboo pole. Two or four men would carry it. In the time of the British in India, dhooly-bearers were used to carry the wounded from the battlefield and transport them.

Today in numerous areas of India including at the Hindu pilgrimage site of Amarnath Temple in Kashmir, palanquins can be hired to carry the customer up steep hills.

IN AFRICA

GHANA

In Southern Ghana the Akan and the Ga-Dangme carry their chiefs and kings in palanquins when they appear in their state durbars. When used in such occasions these palanquins may be seen as a substitutes of a state coach in Europe or a horse used in Northern Ghana. The chiefs of the Ga (mantsemei) in the Greater Accra Region (Ghana) use also figurative palanquins which are built after a chief's family symbol or totem. But these day the figurative palanquins are very seldom used. They are related with the figurative coffins which have become very popular among the Ga in the last 50 years. Since these figurative coffins were shown 1989 in the exhibition "Les magicians de la terre" in the Centre Pompidou in Paris they were shown in many art museums around the world.

ANGOLA

From at least the 15th century until the 19th century, litters of varying types known as tipoye were used in the Kingdom of Kongo as a mode of transportation for the elites. Seat-style litters with a single pole along the back of the chair carried by two men (usually slaves) were topped with an umbrella. Lounge-style litters in the shape of a bed were used to move one to two people with porter at each corner. Due to the tropical climate, horse were not native to the area nor could they survive very ong once introduced by the Portuguese. Human portage was the only mode of transportation in the region and became highly adept with missionary accounts claiming the litter transporters could move at speeds 'as fast as post horses at the gallop'.

IN THE WEST

EUROPE

Portuguese and Spanish navigators and colonistics encountered litters of various sorts in India, Mexico, and Peru. They were imported into Spain and spread into France and then Britain. All the names for these devices are ultimately derived from the root sed- in Latin sedere, "sit," which gave rise to seda ("seat") and its diminutive sedula ("little seat"), the latter of which was contracted to sella, the traditional Latin name for a carried chair.The carried chair met instant success in Europe, whose city streets were often a literal mess of mud and refuse: Where cities and towns did not enjoy the presence of sewage systems left over from Imperial Roman days, it was common to empty chamber pots and discard kitchen refuse from windows down into the adjacent streets. Affluent and well-to-do citizens often found it hazardous and impractical to negotiate those avenues, and sedan chairs allowed them to remain prim and spotless while the carrying valets had to contend with the mud and the filth.In Europe, Henry VIII of England was carried around in a sedan chair — it took four strong chairmen to carry him towards the end of his life — but the expression "sedan chair" was not used in print until 1615. It does not seem to take its name from the city of Sedan. Trevor Fawcett notes (see link) that British travellers Fynes Moryson (in 1594) and John Evelyn (in 1644-5) remarked on the seggioli of Naples and Genoa, which were chairs for public hire slung from poles and carried on the shoulders of two porters.From the mid-17th century, visitors taking the waters at Bath would be conveyed in a chair enclosed in baize curtains, especially if they had taken a heated bath and were going straight to bed to sweat. The curtains kept off a possibly fatal draft. These were not the proper sedan chairs "to carry the better sort of people in visits, or if sick or infirmed" (Celia Fiennes). In the 17th and 18th centuries, the chairs stood in the main hall of a well-appointed city residence, where a lady could enter and be carried to her destination without setting foot in a filthy street. The neoclassical sedan chair made for Queen Charlotte remains at Buckingham Palace.

By the mid-17th century, sedans for hire were a common mode of transportation. In London, "chairs" were available for hire in 1634, each assigned a number and the chairmen licensed because the operation was a monopoly of a courtier of Charles I. Sedan chairs could pass in streets too narrow for a carriage and were meant to alleviate the crush of coaches in London streets, an early instance of traffic congestion. A similar system was later used in Scotland. In 1738, a fare system was established for Scottish sedans, and the regulations covering chairmen in Bath are reminiscent of the modern Taxi Commission's rules. A trip within a city cost six pence and a day's rental was four shillings. A sedan was even used as an ambulance in Scotland's Royal Infirmary.

Chairmen moved at a good clip. In Bath they had the right-of-way and pedestrians hearing "By your leave" behind them knew to flatten themselves against walls or railings as the chairmen hustled through. There were often disastrous accidents, upset chairs, and broken glass-paned windows.

Sedan chairs were also used by the wealthy in the cities of colonial America. Benjamin Franklin used a sedan chair late in the 18th century.

COLONIAL PRACTICE

In various colonies, litters of various types were maintained under native traditions, but often adopted by the white colonials as a new ruling and/or socio-economic elite, either for practical reasons (often comfortable modern transport was unavailable, e.g. for lack of decent roads) and/or as a status symbol. During the 17-18th centuries, palanquins (see above) were very popular among European traders in Bengal, so much so that in 1758 an order was issued prohibiting their purchase by certain lower-ranking employees.

THE END OF A TRADITION

In Great Britain, in the early 19th century, the public sedan chair began to fall out of use, perhaps because streets were better paved or perhaps because of the rise of the more comfortable, companionable and affordable hackney carriage. In Glasgow, the decline of the sedan chair is illustrated by licensing records which show twenty-seven sedan chairs in 1800, eighteen in 1817, and ten in 1828. During that same period the number of registered hackney carriages in Glasgow rose to one hundred and fifty.

THE TRAVELING SILLA OF LATIN AMERICA

A similar but simpler palanquin was used by the elite in parts of 18th- and 19th-century Latin America. Often simply called a silla (Spanish for seat or chair), it consisted of a simple wooden chair with an attached tumpline. The occupant sat in the chair, which was then affixed to the back of a single porter, with the tumpline supported by his head. The occupant thus faced backwards during travel. This style of palanquin was probably due to the steep terrain and rough or narrow roads unsuitable to European-style sedan chairs. Travellers by silla usually employed a number of porters, who would alternate carrying the occupant.

A chair borne on the back of a porter, almost identical to the silla, is used in the mountains of China for ferrying older tourists and visitors up and down the mountain paths. One of these mountains where the silla is still used is the Huangshan Mountains of Anhui province in Eastern China.

WIKIPEDIA

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 "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.

Engine:

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.

[Test taken from Wikipedia]

This Lego miniland-scale 190E 2.3-16 sedan has been created for Flickr LUGNuts' 85th Build Challenge, - "Like, Totally 80's", - for vehicles created during the decade of the 1980s.

Construction at the new $52 million Urlas townhouses located in Ansbach,Germany is approximately at the half way point. These energy efficient Passivhauser or passive homes are German designed. When complete, each of the 22 homes will use approximately one-fourth the energy demands of a standard German home. To the Soldier living in them, there will be little visual different with the expection of a solar panel on each roof. The real difference is on the walls and in the windows. Extra thick insulation, triple-paned glass and innovative HVAC system makes these townhomes the most energy efficient homes in the Department of the Defense. (U.S. Army Corps of Engineers photo by Carol E. Davis)

Construction at the new $52 million Urlas townhouses located in Ansbach,Germany is approximately at the half way point. These energy efficient Passivhauser or passive homes are German designed. When complete, each of the 22 homes will use approximately one-fourth the energy demands of a standard German home. To the Soldier living in them, there will be little visual different with the expection of a solar panel on each roof. The real difference is on the walls and in the windows. Extra thick insulation, triple-paned glass and innovative HVAC system makes these townhomes the most energy efficient homes in the Department of the Defense. (U.S. Army Corps of Engineers photo by Carol E. Davis)

Construction at the new $52 million Urlas townhouses located in Ansbach,Germany is approximately at the half way point. These energy efficient Passivhauser or passive homes are German designed. When complete, each of the 22 homes will use approximately one-fourth the energy demands of a standard German home. To the Soldier living in them, there will be little visual different with the expection of a solar panel on each roof. The real difference is on the walls and in the windows. Extra thick insulation, triple-paned glass and innovative HVAC system makes these townhomes the most energy efficient homes in the Department of the Defense. (U.S. Army Corps of Engineers photo by Carol E. Davis)

Efficient, logical, effective and practical.

Using all resources to the best of our ability

Changing, designing, adapting our mentalities

Improving our abilities for a better way of life

en.wikipedia.org/wiki/Genetic_Engineering_(song)

Image of an en.wikipedia.org/wiki/IBM_Personal_Computer with green monochrome monitor by Ruben de Rijcke

on Wikimedia Commons w.wiki/4MkA

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]

en.wikipedia.org/wiki/BMW_i8

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.

View Large On White

"Murray Building (built in 1969) was designed with its windows meticulously oriented to avoid intrusion of excessive direct sunlight. This design won the Certificate of Merit of the Energy Efficient Building Award in 1994... The building (has already been vacated) will be auctioned off for re-development into a hotel by The Lands Department, after the government bureaus have moved to the Central Government Complex, Tamar." Wikipedia

Murray Building, Garden Road, Hong Kong

Construction at the new $52 million Urlas townhouses located in Ansbach,Germany is approximately at the half way point. These energy efficient Passivhauser or passive homes are German designed. When complete, each of the 22 homes will use approximately one-fourth the energy demands of a standard German home. To the Soldier living in them, there will be little visual different with the expection of a solar panel on each roof. The real difference is on the walls and in the windows. Extra thick insulation, triple-paned glass and innovative HVAC system makes these townhomes the most energy efficient homes in the Department of the Defense. (U.S. Army Corps of Engineers photo by Carol E. Davis)

Construction at the new $52 million Urlas townhouses located in Ansbach,Germany is approximately at the half way point. These energy efficient Passivhauser or passive homes are German designed. When complete, each of the 22 homes will use approximately one-fourth the energy demands of a standard German home. To the Soldier living in them, there will be little visual different with the expection of a solar panel on each roof. The real difference is on the walls and in the windows. Extra thick insulation, triple-paned glass and innovative HVAC system makes these townhomes the most energy efficient homes in the Department of the Defense. (U.S. Army Corps of Engineers photo by Carol E. Davis)

The public learns about energy efficient light bulb options in the exhibit tent at the U.S. Department of Energy Solar Decathlon 2011 at West Potomac Park in Washington, D.C., Thursday, Sept. 29, 2011. (Credit: Stefano Paltera/U.S. Department of Energy Solar Decathlon)

---

About the U.S. Army Installation Management Community:

IMCOM handles the day-to-day operations of U.S. Army installations around the globe - We are the Army's Home. Army installations are communities that provide many of the same types of services expected from any small city. Fire, police, public works, housing, and child-care are just some of the things IMCOM does in Army communities every day. We endeavor to provide a quality of life for Soldiers, Civilians and Families commensurate with their service. Our professional workforce strives to deliver on the commitments of the Army Family Covenant, honor the sacrifices of military Families, and enable the Army Force Generation cycle.

Our Mission: To provide standardized, effective and efficient services, facilities and infrastructure to Soldiers, Civilians and Families for an Army and Nation engaged in persistent conflict.

Our Vision: Army installations are the Department of Defense standard for infrastructure quality and are the provider of consistent, quality services that are a force multiplier in supported organizations' mission accomplishment, and materially enhance Soldier, Civilian and Family well-being and readiness.

To learn more about IMCOM, visit us online:

IMCOM Official Web Site - www.imcom.army.mil/hq/

Flickr Photostream - www.flickr.com/photos/imcom

YouTube - www.youtube.com/installationmgt

Twitter - www.twitter.com/armyimcom

Facebook - www.facebook.com/InstallationManagementCommunity

Scribd - www.scribd.com/IMCOMPubs

CNN iReport - www.ireport.com/people/HQIMCOMPA/

DoD Live Blog - usarmyimcom.armylive.dodlive.mil/

---

Heading for Glasgow on the 926 is West Coast Motors Irizar i6s Efficient YT23 HYN (12311), the last of the first batch of i6s Efficients.

This is the Visitor Center / Nature Center building at the Cave Creek Recreation Area north of the Carefree Highway off of 32nd Street in north Phoenix. I had to stop here to buy my Maricopa County Regional Parks System Annual Pass.

www.maricopa.gov/parks/cave_creek/

Located north of Phoenix, this 2,922-acre park sits in the upper Sonoran Desert. Ranging in elevation from 2,000 feet to 3,060, this desert oasis provides any hiker and equestrian majestic views. The Go John Trail loops around a mountain to provide the illusion of being miles away from civilization. In the 1870s, fever stricken gold seekers staked their dreams on the jasper-studded hills. Guided trails to these sites give visitors an opportunity to travel back in time.

[edit] thanks to sedonakin for pointing out that this is a very special building. It is LEED certified. www.maricopa.gov/parks/naturecenters.aspx

"Before the department began designing the prototype, staff sought Leadership in Energy and Environmental Design (LEED) certification criteria from the U.S. Green Building Council to gain a better understanding as to which types of materials and facilities would work best to preserve the natural environment of the park.

The goal of the project was to design a fully functional, sustainable and energy efficient visitor’s center while minimizing the disturbance to the natural landscape and maximizing the design compatibility with the natural surroundings. Several other factors taken into consideration included the preservation of wildlife corridors, the need to avoid disturbing natural undeveloped land and the possibility of utilizing a site which already had been previously disturbed.

After a lengthy design process with a team of architects and staff, Parks agreed on a prototype that would be aesthetically pleasing to guests as well as energy efficient and functional.

The nature centers contain an entry pathway that welcomes visitors into the park and encourages them to venture into their natural surroundings. The nature centers at Cave Creek Regional Park and Usery Mountain Regional Park are paired with outdoor amphitheaters and are connected to the centers by scenic desert walkways that stem from the back patio. The amphitheaters allow staff to and incorporate interpretive and green educational programming opportunities.

As visitors make their way down the path to the center, they’ll notice a garden roof system that contains native plant species and enables the facility to visually integrate into its surrounding. The desert roof adds a significant insulative value, retains rainwater, and reduces storm water runoff on the site.

Once inside the facility, visitors will see a central skylight that is fully glazed for daylight admission yet is situated behind deep shade canopies to discourage direct sun in the summer. In the winter, when the low sun angle hits it, the skylight absorbs and reradiates the heat into the space. The floors consist of exposed concrete that, along with the 20-inch-thick masonry walls, act as a thermal mass.

The walls, glass and the roof are all designed and insulated to meet or exceed American Society of Heating, Refrigerating and Air-Conditioning Engineers energy standards. For instance, the windows are operable with dual-glazed low-e glass, allowing them to be opened for natural ventilation when the weather permits and to resist heat gain in the summer.

Whenever possible, Parks also took special care in selecting materials that were regional, rapidly renewable and offered high recycled content.For example, the majority of the installed materials were left with a natural finish to reduce the use of paints and varnishes. Exterior materials, such as the corrugated metal roofing panels and the unpainted steel siding, were chosen for their durability and low maintenance needs. The restrooms will use low-flow toilets and waterless urinals. " [end edit]

The standards developed by the U.S. Green Building Council (USGBC). LEED, or Leadership in Energy and Environmental Design, is an internationally recognized green building certification system. It takes into account sustainable sites, water efficiency, energy atmosphere effects, materials and resources, indoor environmental quality, and innovation in design.

IMG_0519 maricopa country regional parks visitor center

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]

en.wikipedia.org/wiki/BMW_i8

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.

Fireplace inserts have become more and more efficient over the years. Recently this Vermont Castings Montpelier fireplace insert with a Georgian surround was installed in our home. This is a medium sized insert that can heat anywhere between 1500 and 1800 square feet, but it will be used mainly as supplmental heat fror our gas furnace.

I will update the performance over time, but see my attached energy blog entry for a short history of improvements in heating stoves.

Update 1. This stove is a real performer. We have it about two months duirng late fall and early winter. The temperatures have been mild, so there have been no really cold days. The insert is used for supplemental heat. The stove does back smoke into the room if you do not start it in a certain way. We leave a bed of ash in the bottom of the insert, put two balls of newspaper at the back, dry kindling over the newspaper, and light it from the very back. This produces an immediate draft with very little smoke entering the room. The stove then requires dry medium split logs (about 2 inches by 2 inches) to really get the temperature in the firbox to rise. After that it is very easy to maintain the fire by simply adding dry split wood and adjusting the airflow. We do not use the included fan (which on low is not as noisy as we thought it would be) as we do not want the room to heat up too much and would rather have the stove heat up and then give off heat after we quit adding wood. So all in all it is a great performer as well as very attractive. More updates coming.

Update 2. We use the Vermont Castings Montpelier fireplace insert every night for supplemental heat and it has performed very well. However, after more experimentation we now start the fire by using fatwood and what has been called a log cabin approach. The old procedure worked fine, but it tends to give off quite a bit of smoke during fire starting because of all the small branches and newspaper. The new approach promotes greater air flow in the firebox, a cleaner burning fire and very little carbon on the glass viewing area of the door. To accomplish this, one oak log is cut in half so the pieces are able to fit front to back in the fireplace, and then each half piece is split into three more pieces to make kindling. Two of the six to 10 inch long split pieces then are placed over the ashes vertical to the fireplace opening to take advantage of the stoves air flow system. Several smaller pieces of branchwood along with one piece of fatwood are placed on top of those pieces and laid across the foundation wood. This square crossing pattern is continued with all six split pieces of oak. If there is enough room we put a normal sized log on the very top of this square structure. The fatwood is lighted and due to its slow initial burn rate it activates a positive airflow up the flue preventing any back-smoking problems. Once things begin to catch the door is left slightly ajar until the fire blazes and becomes hot, usually taking just a few minutes. After this the door is closed and the air control is set to maximum until the firebox becomes hot (about one-half hour). At this point the airflow is turned down to the desired level (medium or low) and wood is added as needed. Once all this burns down to form a bed of coals, we just add wood in the usual manner.

Update 3. I am still impressed with this stove after a year of use and we have just started using it for this heating season. I have refined the method of starting this stove and now do not have any backsmoking into the room. I put two large logs on the bottom parallel to the back wall of the stove. Over these logs I then put two 8 inch long logs perpendicular to stove back wall making a kind of rectangle. Or if they are short enough you can criss-cross normal logs diagonally in the firebox. Between these 8 inch logs I place fatwood and kindling at varous angles. The fatwood is optional if you have very small branched that will light with fireplace matches. Over this I put some small logs just under the air tubes. I can't stress enough the importance of having seasoned wood. We purchased wood (mostly oak) in March and put it in our garage. On purchase the moisture content was in the 30% range for many pieces even though the dealer said it was seasoned. But many wood sellers often do not split the wood until just before delivery. At that time this wood was not usable in the wood stove due to the high moisture content . After 6 months of having this wood in a hot garage over the summer the wood's moisture content is now 20% or below and is ready for use in the wood stove. Good luck.

Update 4. Much has been written about this stove and backsmoking (when airflow reverses direction and smoke comes out of the combustion air entrance for the stove). I have found that for our stove chimney configuration the stove only backsmokes when the stove is very cold and there are unique weather conditions. If you use the stove daily, it is unlikely to backsmoke. You can tell if it will backsmoke if you put your hand under the top front of the stove and feel cold air coming down the chimney into the stove. If this is the case then you have to warm the stove before attemplting to start the fire either by placing a candle or electric light bulb inside the stove to warm it and to create a draft. But this takes quite a bit of time. An alternative method is to use some fatwood or other material placed at the top of the stove to start the draft.

For information on heating stove standards for the USA, see the link from my blog below.

www.energyfordevelopment.com/2011/02/better-stove-standar...

+++ DISCLAIMER +++

Nothing you see here is real, even though the conversion or the presented background story might be based on historical facts. BEWARE!

Some background:

The T-34 was a Soviet medium tank that had a profound and lasting effect on the field of tank design. Although its armor and armament were surpassed later in the war, it has been often credited as the most effective, efficient and influential tank design of the Second World War. Replacing many light and medium tanks in Red Army service, it was the most-produced tank of the war, as well as the second-most-produced tank of all time (after its successor, the T-54/55 series).

Soviet industry would eventually produce over 80,000 T-34s of all variants, allowing steadily greater numbers to be fielded as the war progressed despite the loss of thousands in combat against the German Wehrmacht.

Specifications:

Crew: Five (commander, gunner, 2x loader, driver)

Weight: 32.5 tonnes (35.7 short tons)

Length: 6.12 m (20 ft), hull only

6.77 m (22 ft 2 in) with gun facing forward

Width: 3.00 m (9 ft 10 in)

Height: 3.02 m (10 ft)

Suspension: Christie

Ground clearance: 0.4 m (16 in)

Fuel capacity: 820 l (180 imp gal; 220 US gal)

Armor:

15–47 mm (0.6 – 1.85 in)

Performance:

Maximum road speed: 45.5 km/h (28 mph)

Operational range: 300 km (186 mi)

Power/weight: 15.4 PS/tonne (14 hp/ton)

Engine:

Model V-2-34 38.8 L V12 Diesel engine with 500 PS (493 hp, 368 kW)

Armament:

1× 122 mm (4.803 in) M-30S howitzer with 30 rounds

2× 7.62 mm (0.308 in) DT machine guns (1× co-axial with the main gun, 1× in the front hull)

with 3.000 rounds

The kit and its assembly:

What would a “Soviet Group Build” be without a T-34 submission? And creating a whiffy variant is pretty easy since there are aftermarket conversion sets that allow the build of a fictional variant like the T-34-122/T-34G with relatively little effort.

AFAIK, the T-34G with a 122mm howitzer turret was considered but actually never made it off the drawing boards – the simpler Su-122 was preferred right from the start. But the concept is an interesting idea and the respective tank a nice whif model topic.

There are even conversion sets for this tank project: Sharkit from France offers two sets for this conversion in 1:72, either a cast and a welded turret variant. I had stashed away the latter some time ago, actually for the conversion of a leftover T-34/85 chassis. But for the currently running Group Build at whatifmodelers.com I bought a dedicated new kit for the project – a T-34/76 1943 model from Zvezda, which donated the complete lower hull.

The Zvezda kit is actually a snap-fit model, relatively new and probably aimed at tabletop gamers. Sounds shabby, but it’s actually a very good offering, with crisp detail, very good fit and an interesting mix of full-steel and rubber-padded wheels plus tracks which come in separate IP pieces.

Another good thing: the Sharkit turret fits perfectly onto the adapter that normally holds the OOB T-34/76 snap-on turret in place, so that the conversion is as simple as it could be!

The Sharkit parts themselves appear bleak at first sight, but everything you ask for is there, including separate “Mickey Mouse” twin hatches, which fit well once properly cleaned and trimmed. The only questionable point is the material itself: the walls are thin, and the grey stuff is surprisingly soft – at first, I thought it was injected plastic, but you need super glue to put the few parts together.

Fit is – for a short run production set – surprisingly good, too, only little PSR was necessary to put the howitzer turret together. Anyway, a mini drill (like a Dremel) with a saw blade is highly recommended in order to get the parts off of the sprues and trim them. My only personal mod to the turret is the drilled-open barrel and four lugs on the turret’s roof, made from thin brass wire.

Otherwise, the Zvezda kit was built OOB. I just added two wooden storage boxes to the rear flanks because the T-34 looked OOB a little too “clean” for my taste, despite the two separate towing cables and some tool boxed on the mudguards.

Painting and markings:

Soviet WWII tanks offer little variety, most were finished in an overall dark green (which was not uniform and could differ from olive drab to grass green or even a deep forest green), and I found some specimen in an overall tan/brown. There’s also always the whitewash option, but I wanted a vehicle from the Battle of Kursk in July 1943, so that this was – in this case – not an option.

Some T-34s were finished in a green/brown scheme, and this was eventually the route I chose. For the pattern, though, I referred to an interesting scheme I found on a BA-10 profile from the Battle of Kursk period: a deep brown basis onto which clearly defined, large mottles of grass green had been added. Not certain if that’s authentic or just an over-artistic interpretation, but the concept was transferred to the T-34-122 here.

The basis is an all-over coat of a rich chocolate brown, RAL 8017. This was then painted over with thinned Lederbraun, RAL 8027. On top of that, rich green (RAL 6003) mottles were painted, leaving a spongy, brown net. The wheels were painted in uniform green or brown.

After a dark brown wash, the basic colors were further lightened with French Earth Brown (ModelMaster) and Grass Green (Humbrol 80). After the few decals had been applied, the whole kit received a dry brushing treatment with Ochre (Humbrol 83) and some pure black ink around the cooler grates.

The tracks were painted with a wet-in-wet mix of Black, Iron and Sienna, all acrylics, and once they were in place (as well as the turret), the lower hull received a pigment treatment for simulated dust and mud around the running gear.

A rather simple and subtle whif, but I like the result of this fictional T-34 variant. The changed silhouette through the tall, new turret reminds a lot of the bigger KW-2 tank? A mini KW-2!? The paint scheme did not come out as clearly or bright as originally planned, but I left it that way because the rich brown and the yellow-ish green are still discernable under the weathering and the pigment dust. And it’s IMHO a worthy addition to my range of Group Build submissions.

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]

en.wikipedia.org/wiki/BMW_i8

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.

Energy efficient solar screens offered by Screenmobile block up to ninety percent of the sun's radiant heat before it reaches window glass and can help reduce a homeowner's utility bills up to fifty percent. Lower electric usage, protect furnishings, hall hangings, carpet and yourself from harmful UV rays. You Call, We Screen. Screenmobile.

Efficient marshal at the Historic Race Day - Killarney, Cape Town

Here at Haas Automation, we take full advantage of the capacities and capabilities of every machine in the shop to produce the right number of parts at the right time, in the most efficient way possible. Here, we’re utilizing the high-speed capabilities and large table of a Haas VF-3SSYT VMC to precision chamfer gears for the Haas 40-taper gearbox – 20 gears at a time, in a single setup.

It’s a high-production environment, and we put as much thought and engineering into optimizing our workholding and machining processes as we do into designing high-quality components for Haas machines.

Original Caption: A highly efficient solar greenhouse at a school in Albuquerque, New Mexico. Black barrels contain water and are heated during the day. Plastic panels are double layered with a space in between. At night styrofoam beads are blown in this space as insulation and sucked out during daylight, 04/1974

U.S. National Archives’ Local Identifier: 412-DA-12846

Photographer: Norton, Boyd

Subjects:

Environmental protection

Natural resources

Pollution

Albuquerque (New Mexico, United States) inhabited place

Persistent URL: research.archives.gov/description/555298

Repository: Still Picture Records Section, Special Media Archives Services Division (NWCS-S), National Archives at College Park, 8601 Adelphi Road, College Park, MD, 20740-6001.

For information about ordering reproductions of photographs held by the Still Picture Unit, visit: www.archives.gov/research/order/still-pictures.html

Reproductions may be ordered via an independent vendor. NARA maintains a list of vendors at www.archives.gov/research/order/vendors-photos-maps-dc.html

Access Restrictions: Unrestricted

Use Restrictions: Unrestricted

Cougar Creek TimberFrame, building efficient green built custom homes.

Questions: www.pbssips.com/contact/sales/

Visit us: www.pbssips.com

Paintings by Abdurrahman Öztoprak

Apartment remodeling in Shanghai with active and passive energy efficient concepts.

PUBLICATIONS

www.cityweekend.com.cn/shanghai/articles/home-and-office-...

www.genco-berk-design.com

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]

en.wikipedia.org/wiki/BMW_i8

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.

July 2005 - sleepless night on a business trip to London, this shot taken from the hotel room sometime after midnight.

4 March 2014. Tawilla: A woman fires a fuel-efficient stoves made in the Rwanda camp for internally displaced people (IDP) in Tawila, North Darfur.

More than 8,000 women from the camp are the beneficiaries of the Safe Access to Firewood and Alternative Energy (SAFE) project, run by the World Food Programme (WFP). Since 2011, displaced women receive training on how to make fuel-efficient stoves and fire briquettes from saw dust and dried leaves and household waste. WFP's SAFE project offers a safer, cheaper and greener way to cook food and also helps women to generate income through selling the stoves in the market.

Photo by Albert Gonzalez Farran, UNAMID.