2019 Xplore Engineering

Workshop: The Manufacturing Process Challenge

Photo: Joseph Xu/Michigan Engineering, Communications & Marketing

Syrup Manufacturing Plant,Liquid Syrup Plant,Manufacturing Plant, Pharmaceutical syrup manufacturing process,Sugar syrup manufacturing plant-Prism Pharma Machinery,Ahmedabad,Gujarat,India.

For more detail visit us at : www.liquidsyrupmanufacturingplant.com

A team of researchers led by Cev Noyan from Columbia University is conducting experiments at VULCAN, SNS beam line 7, as part of an ongoing study of suspension bridge cable design. Shown here are Janelle Mills and Adrian Brügger (left to right), from Columbia University examining a wire bundle they are testing at VULCAN.

Suspension bridge cables are made up of parallel wire strands bundled together. Moisture, local defects in the wire, and contaminants can cause corrosion and cracking in the wire. The team is using neutron diffraction to understand the effects of these breaks on the overall strength of the cable. These experiments will help quantify the effect of mechanical interference of the outer wires with the central wire on the strain transfer to a broken wire. Essentially, they want to find out if there’s a break in one of the hundreds of wires that makes up a cable, at what distance from the break does the wire begin to carry the load due to friction and wire twist.

Using neutron diffraction allows for nondestructive study of the wires, and thus more accurate measurements of the wire strain. Other methods of making these measurements, like adding sensors to the wire, disrupt the contact mechanics of the whole system. Additionally, VULCAN offers a unique environment for their experiment where the team can apply torsion to the wire specimen, twisting it to represent the natural curving that the wires exhibit as a result of coiling the cables during the manufacturing process.

Learn more about this research team: carleton.columbia.edu/suspension-bridge-cable-monitoring

Related Videos:

www.youtube.com/watch?v=UfFXPK-AoaA

www.youtube.com/watch?v=aBGHBXvuXl4#t=18

Image credit: Genevieve Martin/ORNL.

Bursera graveolens, known in Spanish as palo santo ("holy wood") is a tree that inhabits the coast of Ecuador. The tree belongs to the same family (Burseraceae) as frankincense and myrrh. It is widely used in folk medicine. Aged heartwood is rich in terpenes such as limonene and α-terpineol.

The use of Palo santo (or Palo Santo) from Bursera Graveolens is reported to be traditional in South America, especially in Ecuador. According to the local customs, it is used against the "mala energia" (bad energy) ("Palo Santo para limpiar tu casa de la mala energia, Palo Santo para la buena suerte" or "Palo Santo to clean your house of bad energy, Palo Santo for good luck").

The factory was completed in 1923 and inspired by Henry Ford’s Highland Park plant in Detroit, the entire manufacturing process was concentrated on the building’s five floors with raw materials entering on the ground floor and finished vehicles emerging on to the roof with its famous test track.

Built in 1928 in the backyard of the owners' home to replace a barn that had grown too small for demand. At one time the plant manufactured everything needed for a car batter except for the rubber case.

The plant operated until 2019 when it closed. Its unique location in a residential area (that filled in around the plant) led to environmental concerns over the amounts of lead, arsenic and asbestos used in the manufacturing processes over the years. The city of Council Bluffs acquired the property in 2021 and it remains vacant, albeit cleaned of hazardous materials.

The Password:JDM Dry Carbon Fiber Engine Cover for the 2013+ Subaru BRZ / Scion FR-S will clean up the look of your engine bay! Like all of our Dry Carbon parts we manufacture, this engine cover has been precision crafted for a perfect fitment every time. We have used a fade resistant resin during the manufacturing process to ensure this plug cover will always look & function as good as the day you bought it!

Includes all necessary mounting hardware.

Features include:

- Perfect dry carbon fitment with structural integrity

- high-heat, fade resistant resin fabrication process

- two options to choose from, dry carbon fiber and dry carbon kevlar

- Extreme lightweight to strength ratio

- Made in the USA

- Badass looks for your BRZ or FR-S engine bay!

From the planting of the seed to the end of the manufacturing process, Portuguese cork makes for authentic, high quality and eco-efficient cork products that are created with true craftsmanship and care.

Compact walk behind pallet stacker/ pallet truck

This small, yet powerful pedestrian pallet stacker by Atlet features a small frame providing flexible maneuvering in small confined spaces. This pallet stacker/ pallet truck is ideal for "mom and pop" shops, loading and unloading on the delivery docks, and similar small warehousing operations.

- Quickly and easily transport material in small confined spaces

- Ergonomically designed for fast loading and unloading trucks

- Works from ambient to cold store environments (down to -35°C -2°F).

- An environmentally friendly product from an environmentally friendly manufacturing process.

www.atletusa.com

800-351-5525 ext. 6

The new Catholic Health building in Buffalo, NY complete with Hunter Panels XCI Class A and Foil products behind the cladding.

Xci Class A is an exterior wall insulation panel composed of a Class A rigid polyisocyanurate foam core laminated during the manufacturing process to embossed foil facers.

Hunter Xci polyiso products:

- Have the highest R-Value per inch of any insulation

- NFPA 285 TEST - Passed

- Energy Star approved

- Contribute toward LEED certification credits

- HCFC, CFC, zero ODP, and negligable GWP.

XCI Twitter: twitter.com/#!/HunterXCI

XCI Facebook: www.facebook.com/pages/Hunter-Xci-Exterior-Continuous-Ins...

View more: www.hunterxci.com/

(En) Founded in 1906, the Coking Plant of Anderlues was specialized in the production of coke for industrial use.

Coke was obtained by distillation of coal in furnaces and, thanks to its superior fuel coal properties, it was used afterwards to feed the blast furnaces in the steel manufacturing process.

Closed and abandoned since 2002, the site has since undergone many losses and damages, not including an important pollution. While some buildings have now been demolished, there are however still some important parts of the former coking plant.

Among them, the former coal tower, next to the imposing "battery" of 38 furnaces, where the coke was produced. Besides them, we still can see the administrative buildings, the power station with its cooling tower, and buildings for the by-products, which were obtained by recovering the tar and coal gas. There are also a gasometer north side, the coal tip east side and a settling basin south side.

-----------

(Fr) Fondées en 1906, les Cokeries d'Anderlues étaient spécialisées dans la fabrication de coke à usage industriel.

Le coke était obtenu par distillation de la houille dans des fours et, grâce à ses propriétés combustibles supérieures au charbon, il servait par après à alimenter les hauts-fourneaux dans le processus de fabrication de l'acier.

Fermé et laissé à l'abandon depuis 2002, le site a depuis lors subi de nombreuses pertes et dégradations, sans compter la pollution qui y règne. Si certains bâtiments (comme l'ancien lavoir à charbon) ont aujourd'hui été démolis, on retrouve encore toutefois certaines parties importantes de cette ancienne cokerie.

Parmi celles-ci, l'ancienne tour à charbon suivie de près par l'imposante "batterie" de 38 fours, où était produit le coke. A côté d'eux, on découvre également les bâtiments administratifs, la centrale électrique avec sa tour de refroidissement, ainsi que les bâtiments des sous-produits, lesquels étaient obtenus par récupération du goudron et du gaz de houille. Et en périphérie, on retrouve un gazomètre côté nord, le terril à l'est et un bassin de décantation côté sud.

Liquid oral section,Colloid Mill,Fermentation vessels,Stirrer- Agitator, Vacuum Homogenizer Mixer-Prism Pharma Machinery,Ahmedabad,Gujarat,India.

For more detail visit us at : www.liquidsyrupmanufacturingplant.com

From the planting of the seed to the end of the manufacturing process,Portuguese cork makes for authentic, high quality and eco-efficient cork products that are created with true craftsmanship and care.

At the Cup Noodles Museum, you can learn the secret of cup noodle and even have the opportunity to make one-of-a-kind ramen yourself.

Japanese food company Nissin operates this unique museum for Ramen.

The museum shows the 40 year product history as well as the founder, Mr. Ando Momofuku's creativity, by exhibiting 3,000 kinds of cup noodle packages.

They also recreate Mr. Ando Momofuku's humble research facility.

At "My Cup Noodle Factory," you can make your own cup noodle out of 5,460 soup base / topping combinations.

There is also "Cup Noodles Park", a playground for kids where they can experience the manufacturing process of Cup Noodle.

There is a "Chicken Ramen Factory" where you can make Chicken Ramen by hand, starting with kneading, spreading, and steaming the wheat flour and then drying it with the hot oil drying method. After experiencing the process that led to the invention of the world's first instant ramen, you can take your freshly made ramen with you and enjoy its delicious taste at home.

And of course you can enjoy global varieties of noodles in the contemporarily designed museum restaurant!

Contact well-known Guar Gum Manufacturing Process and Micro Crystalline Cellulose Powder Plant

Machineries Manufacturer in India at ww.raj-turnkey.com.

This is a LEGO Ideas project that describes their manufacturing process from start to finish. Here is the link for support: ideas.lego.com/projects/7245b0e6-86e9-47a8-9e07-5e5cd259c...

There is a special booklet that contains the most important details of the building. View or download it through Google Drive in the following short link: kutt.it/thelegofactorybooklet

Armchair (Aluminium chair), design 1942

made by Wim Rietveld (1924-1985) & Egbert Rietveld (1915-1981)

aluminium, 1960

The construction of this experimental armchair reflects Gerrit Rietveld's quest to create a chair from a single piece. With the exception of the conical back legs, the entire chair has been folded from one plate of aluminium. The perforations with narrow, curled back edges make the material stronger and the chair lighter in weight. This specimen was made as a study model for students of architecture in Delft.

Paper Bone Chair

manufactured by Habith Modell- & formenbau GMBH

paper, 2006

The paper study model for the Bone Chair is composed of sheets of paper, joined together layer by layer. Each layer was printed by a computer. A three-dimensional computer model was used as the starting point for this laminated object manufacturing process, which is a form of rapid prototyping.

Bone Chair

made by Phil Verdult

cast aluminium, 2006

Like Rietveld's aluminium Armchair, the Bone Chair is an experimental piece of furniture. Computer software from the automobile industry was used in its design and production. This software is based on growth models for bones and calculates how to achieve the strongest construction with the minimum amount of material. The form of the chair shows how forces can be absorbed in an organic fashion.

www.lcrapid.com/3d-printing/

LC Rapid is a professional 3D printing service company that has advanced 3D printers. We are the expert to help you find suitable 3d printing solutions to make the high-quality SLA rapid prototyping and production components at a very low cost. Our skilled engineering team assists you to start from concept to create cosmetic prototypes or evolve a product with complex structure and intricate geometry.

Introduction of 3D Printing Service

Each 3D printer makes prototypes or high-definition production parts base on the same main principle: a physical three-dimensional solid object is built by adding layer from layer. SLA 3d is the additive manufacturing process, which is a completely different manufacturing method when compared with conventional subtractive methods (CNC machining). Unlike CNC machining requires a cutting tool, Injection Moulding & Die Casting requires the hard toolings, there is no special tools are needed in 3D stereolithography.

Advantages of Precision 3D Printing

Rapid Turnaround

3D Printing process can produce parts in as fast as 1 day.

Complex Geometry

The advantage of 3D printing process is that it allows easy fabrication of parts with complexity. No additional cost is required even with increasing complexity.

High Accuracy

3D Printing is a technology that enables you have a high accurate parts quickly.

Cost Saving

3D printing is inexpensive compared to other conventional manufacturing methods, requiring no toolings as with Injection Molding or Die Casting.

Wide Range of Materials

LC Rapid creates the cost efficient, ultra-fine prototypes and production parts from a large selection of metals and plastics.

Cosmetic Appearance

Quality surface finishes can be easily achieved by using 3D printing process.

3D Printing Process

Stereolithography (SLA)

Selective Laser Sintering (SLS)

Direct Metal Laser Sintering (DMLS)

3D Printing Tolerances

We can meet tolerances of +/- 0.1 mm. We can do the post machining according to customers’ requirement if a finer tolerance is asked.

3D Printing Materials

LC Rapid 3D printing service offers a wide range of materials, from nylon, ABS to Aluminum and steel whether you are making a single or dozens of high accuracy production components.

3D Printing Finishes

Sanding

The sanding process can remove imperfections and prepare a high quality surface for later finishing procedure.

3D Printing Solutions

Consumer Goods

High quality 3D printing service in the consumer goods industry is being used to speed up the testing time, improve product quality, and help get your product launched sooner. From design to manufacturing to sales, fast 3D printing service makes a great contribution to the entire product development stages.

Medical

3D printing prototyping service enables medical device manufacturers to get customized concept models that mimic the production-level quality faster. There are different materials and colors can be selected.

Automotive

The professional 3D printing services in LC Rapid can help clients develop lighter weight, lower cost parts. The quick turnaround ensures you receive physical prototypes with greater strength, shrink your time to launch the production onto market.

Common Applications of 3D Printing

Rapid Prototyping

With the advantage of low cost and good surface quality, 3D Printing can be used to make the visual and functional prototypes.

Production Components

We use 3D Printing to build high volume of custom parts because of the dimension consistency and high accuracy of it.

Toolings

Stereolithography (SLA)- one of the 3D printing service can be used as master models to cast polyurethane vacuum casting patterns.

3D Printing FAQ

Are you able to create the drawing for me if I don’t have a 3D CAD model

We offer the design services, please contact us with your idea. We can also offer reverse engineering service using your legacy parts.

How does LC Rapid set itself apart from the competition.

We are focused on providing the fastest and highest quality prototypes and production parts in the industry.

What 3D printing technologies do you currently offer？

SLA printing service and SLS printing service are two common types of 3d model printing services.

rubber manufacturing process.

040

Friday, December 8th, 2017

Fortune Global Forum 2017

Guangzhou, China

8:00 AM–9:20 AM

SMART MANUFACTURING AND THE INTERNET OF THINGS

Around the world, factory floors and assembly lines are becoming highly automated, combining human ingenuity with data and technology to revolutionize product and productivity outcomes. As the notion of a “factory of the future” continues to evolve, how are companies incorporating “smart” and connected products into their manufacturing process? From sensors and robots to 3D printing and green technology, global companies are experimenting with a variety of methods to streamline, scale, and sustain their business. Here in China, manufacturers have been asked to deliver on the nation’s “Made in China 2025” strategy and are aggressively pursuing their own strategies to become smarter, greener, and more efficient. As these changes take hold, what are the implications for those doing business in China and for supply chains worldwide? And how are companies redeploying and reeducating their workforces as traditional factory jobs become automated and the need for technically proficient talent increases?

Hosted by The City of Guangzhou

Börje Ekholm, President and CEO, Ericsson Group

Till Reuter, Chief Executive Officer, KUKA

Tony Tan, Partner, Shanghai Office, McKinsey & Company

Wang Wenyin, Chairman, Amer International Group

Shoei Yamana, President and CEO, Konica Minolta

Zhang Jing, Founder and Chairman, Cedar Holdings Group

Moderator: Adam Lashinsky, Fortune

Photograph by Vivek Prakash/Fortune

(En) Founded in 1906, the Coking Plant of Anderlues was specialized in the production of coke for industrial use.

Coke was obtained by distillation of coal in furnaces and, thanks to its superior fuel coal properties, it was used afterwards to feed the blast furnaces in the steel manufacturing process.

Closed and abandoned since 2002, the site has since undergone many losses and damages, not including an important pollution. While some buildings have now been demolished, there are however still some important parts of the former coking plant.

Among them, the former coal tower, next to the imposing "battery" of 38 furnaces, where the coke was produced. Besides them, we still can see the administrative buildings, the power station with its cooling tower, and buildings for the by-products, which were obtained by recovering the tar and coal gas. There are also a gasometer north side, the coal tip east side and a settling basin south side.

-----------

(Fr) Fondées en 1906, les Cokeries d'Anderlues étaient spécialisées dans la fabrication de coke à usage industriel.

Le coke était obtenu par distillation de la houille dans des fours et, grâce à ses propriétés combustibles supérieures au charbon, il servait par après à alimenter les hauts-fourneaux dans le processus de fabrication de l'acier.

Fermé et laissé à l'abandon depuis 2002, le site a depuis lors subi de nombreuses pertes et dégradations, sans compter la pollution qui y règne. Si certains bâtiments (comme l'ancien lavoir à charbon) ont aujourd'hui été démolis, on retrouve encore toutefois certaines parties importantes de cette ancienne cokerie.

Parmi celles-ci, l'ancienne tour à charbon suivie de près par l'imposante "batterie" de 38 fours, où était produit le coke. A côté d'eux, on découvre également les bâtiments administratifs, la centrale électrique avec sa tour de refroidissement, ainsi que les bâtiments des sous-produits, lesquels étaient obtenus par récupération du goudron et du gaz de houille. Et en périphérie, on retrouve un gazomètre côté nord, le terril à l'est et un bassin de décantation côté sud.

New Porsche 911 turbo cabs are rare, offering a unique mix of comfort, top-down California style and the heartpounding performance of over 500 horsepower and sophisticated all-wheel-drive. This particular model has been upgraded with a set of HRE custom forged CL40 centerlock wheels, featuring a brushed and clear coated finish sized at 19x8.5 front and 19x11 rear. At HRE we are proud to not only offer the finest Centerlock forged performance wheels on the planet, we can also boast a TUV verified facility, a strict inspection process by German authorities that certifies the quality of the manufacturing process. Every wheel we build is forged for maximum strength and performance, then crafted by artisans who recognize that every Porsche owner demands style, exclusivity and performance.

To learn more about HRE forged wheels for your 911, call (760) 598-1960 or visit the HRE wheels section online.

www.hrewheels.com/blog/featured-rides/2011-911-turbo…re...

As Space Truckers we have to deal with a lot of cargo. Our main contract is with the earth based synth manufacturer Moog Music. We ship analogue synths to the outer rim and haul back the high tolerence silicon wafers essential to Moog's manufacturing process.

Types of Foam Dressing:

Foam dressing types include Adhesive Foam Dressing, Non-adhesive Foam Dressing, Membrane Foam Dressing, Silicone foam dressing without border, Silicone foam lite dressing with border, Silicone Foam Dressing with Border, etc.

Winner medical is the first company that has strong R&D strength and achieves stable mass production of medical-grade foam in China. Our foam is TDI-based hydrophilic polyurethane foam and has good physical properties such as soft, faster absorption, higher absorbency, and excellent retention, and also it has passed the biocompatibility test.

hydrophilic Polyurethane foams offer superior absorbency and comfort making them a perfect choice for e. g. wound dressing. During to their excellent absorption and retention characteristics, these foams can absorb >15 times their own weight in fluid- features that enable them to set high standards in the medical field. Our “pour to thickness” manufacturing process allows us to produce in a wide range of thicknesses, from 1.5 mm to 6.0 mm.

Foaming on the PU film directly brings ultra-soft, high MVTR, and excellent comfort.

Silver or PHMB as antimicrobials are added during the foaming process which allows our customers to convert it into high-quality antimicrobial dressings.

We have developed different types of Medical-grade hydrophilic Polyurethane foam suitable for different purposes, including vertical absorption, good retention, excellent conductivity, fine foam, thick holes foam, high-density foam...

Dimora Silicone Foam Dressing With Border Adhesive Waterproof Wound Dressing 4"X4"(10 Cm*10 Cm) Pack Of 10 Square Dressing For Wound Care

Write Review

Regular price

$23.99

Sale price

$18.00

Vendor : Dimora

Product Type :

Sku : WM-101 079-F

Size

3x3 Inch (Pack of 10) 4x4 Inch (Pack of 10) 6x6 Inch (Pack of 5) 2x5 Inch (Pack of 5) 4x8 Inch (Pack of 5)

Silicone Foam Dressing with Border Specifications:

Brand: Dimora

Material: Foam

Size: 4x4 Inch (Pack of 10)

Item Dimensions: LxWxH 4 x 4 inches

Item Form: Foam

Silicone Foam Dressing with Border Features:

1. Easy to operate, advanced wound moist healing care and treatment method, it can be opened repeatedly to observe the changes of the wound, and the painless dressing change is perfect.

2. The surface layer of TPU film is waterproof, antibacterial, and highly breathable to avoid wound infection. Silicone provides a moist healing environment and promotes wound healing.

3. Foam absorption layer, quickly absorb exudate, soft and comfortable, good elasticity.

4. Non-invasive skin-friendly contact layer, silicone wound contact layer provides gentle adhesion and fixation, which greatly reduces painful trauma and secondary injury when changing dressings, and improves patient comfort

5. Suitable for venous leg ulcers, pressure ulcers, diabetic foot ulcers, abrasion wounds, joints, I-II degree burns, and home acute wound care.

Silicone Foam Dressing with Border Adavantages:

1. Visual dressing: Repeatedly pasted, you can view the wound and squeeze

2. Painless dressing change: no pain to peel off, no adhesion of wound exudate

3. More exudate absorption: moisture balance, providing a moist healing environment for the wound, while ensuring that the wound is not prone to maceration

4. Anti-squeeze dressing: The dressing has its own decompression effect to prevent secondary damage caused by external pressure on the wound

Winner Silicone Sacrum Foam Dressing With Border Adhesive Waterproof Wound Dressing Healing Pads Sterile Sacral Ulcer Patch 5pcs

No review yet.

Write Review

Regular price

$28.99

Sale price

$20.00

Vendor : Dimora

Product Type : 0

Sku : WM-102052-F

Sacral Foam Dressing Specifications:

Brand: Dimora

Material: Silicone Foam

Size: 7.08x7.08 Inch (Pack of 5)

Sacral Foam Dressing Features:

HIGH ABSORBENCY FOR ADVANCED HEALING

5-layer material self-adhesive dressing that can absorb 15 times more wound fluid, contains a polymer absorbent layer, instantly locks fluid, provides a moist healing environment, and promotes wound healing

COMFORT AND PAIN RELIEF

A+ medical grade hypoallergenic silicone as a wound contact layer, it absorbs dead tissue cells, won't stick to wet wounds, and at the same time sticks enough to dry skin, reducing pain and trauma during dressing changes

RELIEVE STRESS

Anti-extrusion layer: Effectively mitigate pressure injuries and prevent pressure ulcers

Sacral Foam Dressing PREVENT INFECTION

The semi-permeable PU membrane layer is waterproof and breathable, allowing oxygen ，water vapor to pass through while providing a liquid barrier to avoid cross infection

www.winnermedicalstore.com/collections/foam-dressing

(En) Founded in 1906, the Coking Plant of Anderlues was specialized in the production of coke for industrial use.

Coke was obtained by distillation of coal in furnaces and, thanks to its superior fuel coal properties, it was used afterwards to feed the blast furnaces in the steel manufacturing process.

Closed and abandoned since 2002, the site has since undergone many losses and damages, not including an important pollution. While some buildings have now been demolished, there are however still some important parts of the former coking plant.

Among them, the former coal tower, next to the imposing "battery" of 38 furnaces, where the coke was produced. Besides them, we still can see the administrative buildings, the power station with its cooling tower, and buildings for the by-products, which were obtained by recovering the tar and coal gas. There are also a gasometer north side, the coal tip east side and a settling basin south side.

-----------

(Fr) Fondées en 1906, les Cokeries d'Anderlues étaient spécialisées dans la fabrication de coke à usage industriel.

Le coke était obtenu par distillation de la houille dans des fours et, grâce à ses propriétés combustibles supérieures au charbon, il servait par après à alimenter les hauts-fourneaux dans le processus de fabrication de l'acier.

Fermé et laissé à l'abandon depuis 2002, le site a depuis lors subi de nombreuses pertes et dégradations, sans compter la pollution qui y règne. Si certains bâtiments (comme l'ancien lavoir à charbon) ont aujourd'hui été démolis, on retrouve encore toutefois certaines parties importantes de cette ancienne cokerie.

Parmi celles-ci, l'ancienne tour à charbon suivie de près par l'imposante "batterie" de 38 fours, où était produit le coke. A côté d'eux, on découvre également les bâtiments administratifs, la centrale électrique avec sa tour de refroidissement, ainsi que les bâtiments des sous-produits, lesquels étaient obtenus par récupération du goudron et du gaz de houille. Et en périphérie, on retrouve un gazomètre côté nord, le terril à l'est et un bassin de décantation côté sud.

Coconut candy refer to various candies made with coconut or coconut flavorings.

In Vietnamese cuisine, kẹo dừa coconut candy is most commonly produced in Bến Tre province, Vietnam with coconut milk and coconut cream.

In the United States, coconut candy was sometimes spelled as cocoanut candy. These included various traditional confections in the United States. Mason Pecan Cocoanut Candy was made in the 1950s in Milprint, Milwaukee. Squirrel Brand made Cocoanut Zippers. There was also a Mason Cherry Cocoanut candy produced in Mineola, New York. Welch's made Cocoanut Candy Bar from Hinde & Dauch. Welch's Cocoanut candy was also produced by the James O. Welch Company.

Sauerkraut candy is made with grated coconut. Grated coconut is often used in various chocolate confections.

VIETNAM

The Bến Tre Province is nicknamed by Vietnamese as the "Land of Coconut" (Xu Dua). The Vietnamese term for coconut candy is "kẹo dừa", with kẹo = candy and dừa = coconut. Coconut candy was originally associated with Mỏ Cày, a small township within the Bến Tre province.

MANUFACTURING PROCESS

The production of Vietnamese coconut candy starts with the grating of fresh coconut flesh. The grated flesh is then pressed to extract coconut milk and coconut cream. The next step is the addition of malt syrup and sugar to this mixture of coconut milk and cream. The ratio of the various ingredients is a closely guarded secret of individual coconut candy manufacturers. The mixing process is often entrusted only to family members of the factory owner. Slight variations in the ingredient ratios can lead to very different texture and taste in the final product.

The mixture is then heated to a very high temperature in large woks over fires generated by the burning of coconut shells. While being heated, the mixture is stirred continuously to ensure even heat distribution. Traditionally, this stirring process was done manually with large wooden paddles. In larger modern manufacturing facilities, these paddles have been replaced by electric motors. The mixture eventually caramelises to a thicker texture. Recognising when the mixture has been cooked to the right level is more of an art than an exact science. While it is still hot and soft, the thickened mixture is then stringed out into moulds and allowed to cool. The final step sees the candy strings cut into rectangular lozenges, then wrapped and packaged.

Traditionally, coconut candy is wrapped in two layers of wrappings. The inner layer is edible rice paper, and the outer layer is paper soaked in vegetable oil. These measures were necessary to stop the candy from sticking to the paper wrapping. Larger manufacturers now use heat-sealed foil paper, which does not stick to the candy.

ECONOMIC IMPORTANCE

Bến Tre currently has over one hundred coconut candy manufacturers, making up thirty percent of local enterprises. However, the market is dominated by a handful of well-known brands, with most manufacturers producing candy under licence for these brands. Coconut candy is sold throughout Vietnam. It is also exported to other Asian countries, Australia, Europe, and North America.

COCONUT CANDY TYPES

Bounty (chocolate bar) contains coconut (it is known as Bounty outside of the U.S.)

Coconut ice

Ferrero Raffaello

Perle de coco

Ounhmangu

WIKIPEDIA

The Password:JDM Dry Carbon Fiber Engine Cover for the 2013+ Subaru BRZ / Scion FR-S will clean up the look of your engine bay! Like all of our Dry Carbon parts we manufacture, this engine cover has been precision crafted for a perfect fitment every time. We have used a fade resistant resin during the manufacturing process to ensure this plug cover will always look & function as good as the day you bought it!

Includes all necessary mounting hardware.

Features include:

- Perfect dry carbon fitment with structural integrity

- high-heat, fade resistant resin fabrication process

- two options to choose from, dry carbon fiber and dry carbon kevlar

- Extreme lightweight to strength ratio

- Made in the USA

- Badass looks for your BRZ or FR-S engine bay!

Ferrari 250 GT Cabriolet, 1957

V-12, 3.0 litre, 240 hp, Chassis no. 0655GT

The 250 GT Cabriolet, designed by Pininfarina, marked Ferrari's increasing ability to build sophisticated road cars as well as single-seat and sports racing cars.

This car was displayed at the Geneva Motor Show in 1957, and was acquired by Peter Collins, one of Ferrari's top drivers. Collins had it repainted at Pininfarina in dark green - a patriotic gesture reflecting the British international racing colour.

[Design Museum]

Ferrari: Under the Skin (November 2017 to April 2018)

In an Italy ravaged by the Second World War, Enzo Ferrari and a small team decided to create the perfect racing machine. The exhibition will explore Ferrari’s powerful personality, the design and manufacturing process, the famous clientele and the future of the luxury car brand.

From the very first Ferrari to Michael Schumacher’s winning Formula One car and the newest hybrid model, the exhibition features rare cars and memorabilia displayed in public for the first time. Discover the Ferrari experience through original hand-drawn sketches, sculpture-like models and engines, alongside films and interviews telling one of the great design stories of all time.

[Design Museum]

In the Design Museum

(En) Founded in 1906, the Coking Plant of Anderlues was specialized in the production of coke for industrial use.

Coke was obtained by distillation of coal in furnaces and, thanks to its superior fuel coal properties, it was used afterwards to feed the blast furnaces in the steel manufacturing process.

Closed and abandoned since 2002, the site has since undergone many losses and damages, not including an important pollution. While some buildings have now been demolished, there are however still some important parts of the former coking plant.

Among them, the former coal tower, next to the imposing "battery" of 38 furnaces, where the coke was produced. Besides them, we still can see the administrative buildings, the power station with its cooling tower, and buildings for the by-products, which were obtained by recovering the tar and coal gas. There are also a gasometer north side, the coal tip east side and a settling basin south side.

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(Fr) Fondées en 1906, les Cokeries d'Anderlues étaient spécialisées dans la fabrication de coke à usage industriel.

Le coke était obtenu par distillation de la houille dans des fours et, grâce à ses propriétés combustibles supérieures au charbon, il servait par après à alimenter les hauts-fourneaux dans le processus de fabrication de l'acier.

Fermé et laissé à l'abandon depuis 2002, le site a depuis lors subi de nombreuses pertes et dégradations, sans compter la pollution qui y règne. Si certains bâtiments (comme l'ancien lavoir à charbon) ont aujourd'hui été démolis, on retrouve encore toutefois certaines parties importantes de cette ancienne cokerie.

Parmi celles-ci, l'ancienne tour à charbon suivie de près par l'imposante "batterie" de 38 fours, où était produit le coke. A côté d'eux, on découvre également les bâtiments administratifs, la centrale électrique avec sa tour de refroidissement, ainsi que les bâtiments des sous-produits, lesquels étaient obtenus par récupération du goudron et du gaz de houille. Et en périphérie, on retrouve un gazomètre côté nord, le terril à l'est et un bassin de décantation côté sud.

info. from wikipedia.

Soju is a distilled beverage native to Korea. Most brands of modern soju are made in South Korea. Though traditionally made from rice, most major brands supplement or even replace the rice with other starches such as potato, wheat, barley, sweet potato, or tapioca (called dangmil in Korean). Soju is clear in color and typically varies in alcohol content from about 20% to about 45% alcohol by volume (ABV), with 20% ABV being most common. Its taste is comparable to vodka, though often slightly sweeter due to the added sugar in the manufacturing process.

(En) Founded in 1906, the Coking Plant of Anderlues was specialized in the production of coke for industrial use.

Coke was obtained by distillation of coal in furnaces and, thanks to its superior fuel coal properties, it was used afterwards to feed the blast furnaces in the steel manufacturing process.

Closed and abandoned since 2002, the site has since undergone many losses and damages, not including an important pollution. While some buildings have now been demolished, there are however still some important parts of the former coking plant.

Among them, the former coal tower, next to the imposing "battery" of 38 furnaces, where the coke was produced. Besides them, we still can see the administrative buildings, the power station with its cooling tower, and buildings for the by-products, which were obtained by recovering the tar and coal gas. There are also a gasometer north side, the coal tip east side and a settling basin south side.

-----------

(Fr) Fondées en 1906, les Cokeries d'Anderlues étaient spécialisées dans la fabrication de coke à usage industriel.

Le coke était obtenu par distillation de la houille dans des fours et, grâce à ses propriétés combustibles supérieures au charbon, il servait par après à alimenter les hauts-fourneaux dans le processus de fabrication de l'acier.

Fermé et laissé à l'abandon depuis 2002, le site a depuis lors subi de nombreuses pertes et dégradations, sans compter la pollution qui y règne. Si certains bâtiments (comme l'ancien lavoir à charbon) ont aujourd'hui été démolis, on retrouve encore toutefois certaines parties importantes de cette ancienne cokerie.

Parmi celles-ci, l'ancienne tour à charbon suivie de près par l'imposante "batterie" de 38 fours, où était produit le coke. A côté d'eux, on découvre également les bâtiments administratifs, la centrale électrique avec sa tour de refroidissement, ainsi que les bâtiments des sous-produits, lesquels étaient obtenus par récupération du goudron et du gaz de houille. Et en périphérie, on retrouve un gazomètre côté nord, le terril à l'est et un bassin de décantation côté sud.

Coconut candy refer to various candies made with coconut or coconut flavorings.

In Vietnamese cuisine, kẹo dừa coconut candy is most commonly produced in Bến Tre province, Vietnam with coconut milk and coconut cream.

In the United States, coconut candy was sometimes spelled as cocoanut candy. These included various traditional confections in the United States. Mason Pecan Cocoanut Candy was made in the 1950s in Milprint, Milwaukee. Squirrel Brand made Cocoanut Zippers. There was also a Mason Cherry Cocoanut candy produced in Mineola, New York. Welch's made Cocoanut Candy Bar from Hinde & Dauch. Welch's Cocoanut candy was also produced by the James O. Welch Company.

Sauerkraut candy is made with grated coconut. Grated coconut is often used in various chocolate confections.

VIETNAM

The Bến Tre Province is nicknamed by Vietnamese as the "Land of Coconut" (Xu Dua). The Vietnamese term for coconut candy is "kẹo dừa", with kẹo = candy and dừa = coconut. Coconut candy was originally associated with Mỏ Cày, a small township within the Bến Tre province.

MANUFACTURING PROCESS

The production of Vietnamese coconut candy starts with the grating of fresh coconut flesh. The grated flesh is then pressed to extract coconut milk and coconut cream. The next step is the addition of malt syrup and sugar to this mixture of coconut milk and cream. The ratio of the various ingredients is a closely guarded secret of individual coconut candy manufacturers. The mixing process is often entrusted only to family members of the factory owner. Slight variations in the ingredient ratios can lead to very different texture and taste in the final product.

The mixture is then heated to a very high temperature in large woks over fires generated by the burning of coconut shells. While being heated, the mixture is stirred continuously to ensure even heat distribution. Traditionally, this stirring process was done manually with large wooden paddles. In larger modern manufacturing facilities, these paddles have been replaced by electric motors. The mixture eventually caramelises to a thicker texture. Recognising when the mixture has been cooked to the right level is more of an art than an exact science. While it is still hot and soft, the thickened mixture is then stringed out into moulds and allowed to cool. The final step sees the candy strings cut into rectangular lozenges, then wrapped and packaged.

Traditionally, coconut candy is wrapped in two layers of wrappings. The inner layer is edible rice paper, and the outer layer is paper soaked in vegetable oil. These measures were necessary to stop the candy from sticking to the paper wrapping. Larger manufacturers now use heat-sealed foil paper, which does not stick to the candy.

ECONOMIC IMPORTANCE

Bến Tre currently has over one hundred coconut candy manufacturers, making up thirty percent of local enterprises. However, the market is dominated by a handful of well-known brands, with most manufacturers producing candy under licence for these brands. Coconut candy is sold throughout Vietnam. It is also exported to other Asian countries, Australia, Europe, and North America.

COCONUT CANDY TYPES

Bounty (chocolate bar) contains coconut (it is known as Bounty outside of the U.S.)

Coconut ice

Ferrero Raffaello

Perle de coco

Ounhmangu

WIKIPEDIA

back of cap is damaged - could have been done during the manufacturing process...

John William Delveaux (b. March 15, 1937 in Chicago, Illinois) was a Canadian football fullback and linebacker who played for the Winnipeg Blue Bombers from 1959 to 1964, a team which won the Grey Cup in 1959, 1961 and 1962.

Delveaux played college football at the University of Illinois at Urbana–Champaign and was their team captain. He joined the Blue Bombers in 1959 and played both offense and defense. In the 1961 Canadian Football League season, he replaced an injured Charlie Shepard as the punter and did a commendable job in the team's Grey Cup victory. In 1962, he became their regular punter up to his final year, averaging 42.1 yards per punt over 5 years. As a linebacker, he intercepted 9 balls in his career, 4 of which in 1962, and recovered 4 fumbles.

Positions - FB / LB / P

Height - 6 ft 1 in

Weight - 220 lbs

Link to his CFL stats - www.justsportsstats.com/footballstatsindex.php?player_id=...

Link to some of his issued football cards - www.footballcardgallery.com/search.php?search=jack+Delveaux

Embossed writing on the back of this coin (type 2 back / dark blue cap) - POTATO CHIPS / NALLEY'S / AND SNACKS * SAVE A COMPLETE SET OF 100 WESTERN CONFERENCE FOOTBALL STARS

jelly bellies aging in between some of the steps of the manufacturing process

Raj Process Equipments And Systems

Pvt. Ltd. are one professional Micro Crystalline Cellulose Powder Plant, Zero

Liquid Discharge Plants Machineries Manufacturer in India.

At the Cup Noodles Museum, you can learn the secret of cup noodle and even have the opportunity to make one-of-a-kind ramen yourself.

Japanese food company Nissin operates this unique museum for Ramen.

The museum shows the 40 year product history as well as the founder, Mr. Ando Momofuku's creativity, by exhibiting 3,000 kinds of cup noodle packages.

They also recreate Mr. Ando Momofuku's humble research facility.

At "My Cup Noodle Factory," you can make your own cup noodle out of 5,460 soup base / topping combinations.

There is also "Cup Noodles Park", a playground for kids where they can experience the manufacturing process of Cup Noodle.

There is a "Chicken Ramen Factory" where you can make Chicken Ramen by hand, starting with kneading, spreading, and steaming the wheat flour and then drying it with the hot oil drying method. After experiencing the process that led to the invention of the world's first instant ramen, you can take your freshly made ramen with you and enjoy its delicious taste at home.

And of course you can enjoy global varieties of noodles in the contemporarily designed museum restaurant!

Montblanc nibs in their manufacturing process.

Governor Kay Ivey participated in the Grand Opening of Winkelmann Flowform Technology, LP. Thursday October 3, 2019 in Auburn, Ala. Winkelmann Flowform Technology, LP. specializes in high-precision, high-strength, thin wall roto-symmetrical parts from metals such as titanium and steel. Through technical engineering and in-house manufacturing processes, the company seeks to provide high-quality, precise, near net shape designs for use in the Aerospace and defense industries. The project involves the creation of 50 new jobs and a $12 million investment in the Auburn metal forming operation. (Governor's Office/Hal Yeager)

The new Catholic Health building in Buffalo, NY complete with Hunter Panels XCI Class A and Foil products behind the cladding.

Xci Class A is an exterior wall insulation panel composed of a Class A rigid polyisocyanurate foam core laminated during the manufacturing process to embossed foil facers.

Hunter Xci polyiso products:

- Have the highest R-Value per inch of any insulation

- NFPA 285 TEST - Passed

- Energy Star approved

- Contribute toward LEED certification credits

- HCFC, CFC, zero ODP, and negligable GWP.

XCI Twitter: twitter.com/#!/HunterXCI

XCI Facebook: www.facebook.com/pages/Hunter-Xci-Exterior-Continuous-Ins...

View more: www.hunterxci.com/

The company was founded by John Dyson who began mining clay and making bricks in the early 1800s. From the very beginning the business was a success. The 1834 Sheffield trade directory lists - “John Dyson - Brick Maker, Stannington” which indicates that he ran the business on his own. However, by 1838 the business was listed as “John Dyson and Son - Black clay miners and firebrick manufacturers, Griffs House, Stannington.

Dyson's were manufacturers of Refractory material, ceramics for the steel industry, they also produce fire backs and other household ceramic bricks for the likes of Aga's etc. They have also been know to sell clay for use in Well Dressings.

Unfortunately Dyson's traditional manufacturing process relied heavily on gas fired kilns. With increased in energy costs the plants was no longer economically viable, despite the very best efforts of the management and staff alike the site closed around 2005.

The high performance niche products in Dyson's range are still available and are the cornerstone in Dyson's progression. The company have a wholly owned manufacturing facility in Tianjin, PRC which produces is high quality products.

Custom Presentation Folder / Pocket Folder with Brochure Insert

Type of Paper: 80# Diamond Gloss Cover - FSC

Printing Process: Offset Printing

Number of Colors: 7/7 Overall Satin Aqueous Coating

Binding: Trim, Score, Fold and Pack

Page Size: 25.5" x 11"

Finished Size: 8.5" x 11"

This presentation folder and brochure had very tricky cross page line ups. We spent the time to make sure all line ups we accounted for in all manufacturing processes.

At the Cup Noodles Museum, you can learn the secret of cup noodle and even have the opportunity to make one-of-a-kind ramen yourself.

Japanese food company Nissin operates this unique museum for Ramen.

The museum shows the 40 year product history as well as the founder, Mr. Ando Momofuku's creativity, by exhibiting 3,000 kinds of cup noodle packages.

They also recreate Mr. Ando Momofuku's humble research facility.

At "My Cup Noodle Factory," you can make your own cup noodle out of 5,460 soup base / topping combinations.

There is also "Cup Noodles Park", a playground for kids where they can experience the manufacturing process of Cup Noodle.

There is a "Chicken Ramen Factory" where you can make Chicken Ramen by hand, starting with kneading, spreading, and steaming the wheat flour and then drying it with the hot oil drying method. After experiencing the process that led to the invention of the world's first instant ramen, you can take your freshly made ramen with you and enjoy its delicious taste at home.

And of course you can enjoy global varieties of noodles in the contemporarily designed museum restaurant!

Oil Filter Elementsis a filter designed to remove contaminants from engine oil, transmission oil, lubricating oil, or hydraulic oil. Oil filters are used in many different types of hydraulic machinery. A chief use of the oil filter is in internal-combustion engines in on- and off-road motor vehicles, light aircraft, and various naval vessels. Other vehicle hydraulic systems, such as those in automatic transmissions and power steering, are often equipped with an oil filter. Gas turbine engines, such as those on jet aircraft, require the use of oil filters. Aside from these uses, oil production, transport, and recycling facilities also employ filters in the manufacturing process.

Features

1.98 percent single-pass filtering efficiency at 25-30 microns for excellent filtering capabilities

Patented cellulose media traps particles 1/3 the width of a human hair to help provide a clean supply of oil to engine components

2.Thermosetting adhesive seals hold filtering media in place for consistent, dependable filtration

3.Designed with five times greater burst strength than most engine oil operating pressures after the oil reaches operating temperatures

4.Application coverage for 97 percent of all cars, light-duty trucks and sport utility vehicles, both foreign and domestic

5.Reduced use of raw materials.

6.Kinder to the environment with less waste during maintenance.

7.Waste disposal problems are eased.

Specification

Filter media: filter element adopts many kinds of materials, such as glass fiber, wood pulp filterpaper , stainless steel sinter fiber web and stainless steel wire woven.

Nominal filtration rating: 0.01μ ~ 1000μ

Operating pressure:21bar-210bar (Hydraulic Liquid Filtration)

O-ring material: Vition, NBR

Application

Because of equipment failure and other reasons, oil pipelines, oil tank, equipment such as lubricating points in material, and metal powder to thoroughly clean, can use Oil Filter Elements quality collected, and slag and repeatedly DuoCi clean strainer, make the system clean.

www.sinteredwiremesh.com

Minton Tiles

The richly patterned and colored Minton tile floors are one of the most striking features of the extensions of the United States Capitol. They were first installed in 1856, when Thomas U. Walter was engaged in the design and construction of vast additions to the Capitol (1851-1865). For the floors in his extensions, Walter chose encaustic tile for its beauty, durability and sophistication.

•Artist: Minton, Hollins and Company

•Date: Installed in 1856

One striking example of the contrast between the interiors of the Old Capitol (finished in 1826) and the extensions (begun in 1851) may be seen in the differences in flooring materials. In the Old Capitol, stone pavers were used in corridors and other public spaces, such as the Rotunda and Crypt, while brick was used to floor committee rooms and offices. These materials, although durable and fireproof, would have looked plain and old-fashioned to the Victorian eye. In the mid-19th century, encaustic tile flooring was considered the most suitable and beautiful material for high-traffic areas. Unlike ordinary glazed tile, the pattern in encaustic tile is made of colored clays inlaid or imbedded in the clay ground. Because the color is part of the fabric of the encaustic tile, it will retain its beauty after years of wear. One observer noted:

“The indestructibility of tiles may be judged from the fact that the excavations at Pompeii have unearthed apartments where painted tiles are just as beautiful, the colors as fresh and bright as... when the fated city was in all its glory.”

Two types of tile were used at the U.S. Capitol: plain and inlaid encaustic tiles in a range of colors. Plain tiles were used as borders for the elaborate inlaid designs or to pave large corridor areas. They were available in seven colors: buff, red, black, drab, chocolate, light blue and white. Additional colors, such as cobalt blue, blue-gray, and light and dark green, appear in the inlaid encaustic tiles that form the elaborate centerpieces and architectural borders. They were made by “filling indentations in the unburnt tile with the desired colors and burning the whole together.”

The patterns and designs formed in the inlaid tiles were limited only by taste and imagination. They include geometric patterns such as the Greek key, guilloche, and basket weave; floral designs such as the fleur-de-lis; and figures such as dolphins and classical heads. Few of the patterns are repeated. Although most of the tiles are six-by-six-inch squares, some are round, triangular or pie-shaped. Approximately 1,000 different tile patterns are used in the corridors of the Capitol alone, and up to 100 different tiles may be needed to create a single design.

The original encaustic tiles in the Capitol extensions were manufactured at Stoke-upon-Trent in Staffordshire, England, by Minton, Hollins and Company. The firm’s patented tiles had won numerous gold medals at international exhibitions and were considered the best tiles made. In 1876, having seen Minton’s large display at the Centennial Exhibition in Philadelphia, one critic wrote, “Messr. Minton shone superior to all exhibits of the sort… and may be cited as showing the highest results in tile-pottery achieved by modern skill and research.”

Beginning in 1856, and continuing for five years, the tile was installed by the import firm of Miller and Coates of New York City. For the journey from New York to Washington, the tiles were packed in wooden casks weighing about 1100 pounds; each cask contained enough tiles to pave about 100 square feet. The cost of the tile ranged from $0.68 to $2.03 per square foot.

Thomas U. Walter had every reason to believe that the encaustic tile floors would last as long as his extensions stood. One visitor noted in 1859 that the tile floors vied with the beauty of marble and surpassed it in durability. While perhaps valid for other installations, however, this prediction proved overly optimistic for the Capitol Building. By 1924, the Minton tile was removed from the corridors in the first and second floors of the House Wing and replaced by “marble tile in patterns of a simple order.” In that day, marble was selected for its superior durability and because suitable replacement tile was difficult to find.

In the 1970s, however, a similar condition prompted a very different response. In 1972, a search was undertaken to determine a source of similar tiles in order to restore the original appearance of the building. Inquiries were made of all major American tile manufacturers, the American Ceramic Tile Manufacturers Association, and even Mexican and Spanish tile suppliers. Although the colors and designs could be reproduced relatively easily, the patterns would quickly wear because they would be applied to the surface. The “inlaid” feature of the encaustic tiles, i.e., the approximately 1/8-inch thickness of the pattern and color, is the characteristic that enables the Minton tiles to be walked upon for over 100 years without signs of wear. It was this technique that formed the basic difficulty of manufacture.

Finally, as a result of the Capitol’s needs becoming generally known, the Architect of the Capitol was placed in contact with H & R Johnson Tiles Ltd., located at Stoke-on-Trent, England. It was discovered that that firm was a successor company to the Minton Tile Co. and had even retained many of the original hand tools and forms in a private museum at the company’s manufacturing site.

Contact was then made with Mr. James Ellis, the Directing Architect of Ancient Monuments and Historic Buildings for the Crown. He had been trying for many years to establish a program for the replacement of the worn Minton tiles at the Houses of Parliament but had more or less given up the attempt because of H & R Johnson’s continued unwillingness to revive the encaustic tile process. However, the restoration work at the Arts and Industries Building of the Smithsonian Institution was in process at about the time the needs of the Capitol became known; it thus appeared that a market for such tiles was developing to the degree that the manufacturer began to reconsider its prior position. The company thus began the experiments that finally led to the present availability, after many decades, of the original Minton-type tiles.

Because the tiles in the Capitol are more decorative and have more complicated designs and color combinations than those in either the Houses of Parliament or the Smithsonian, those institutions were able to obtain replacement tiles sooner than the Capitol. The lessons learned in the manufacture of the simpler tiles served as a basis for filling the later needs.

Color photographs and full-sized drawings of the many required patterns were made and recorded, and many developmental submissions were made as the hand-made manufacturing process was re-developed. Finally, in 1986, the first acceptable tiles were delivered. The installation process was accomplished with modern cement adhesives and has yielded excellent results.

The program enabled the original tiles to be replaced with exact replicas. This project began on the first floor of the Senate wing, where the effects of 130 years of wear and tear were most noticeable. Replacement tile was closely scrutinized to ensure fidelity to the nineteenth-century originals. While difficult and slow, this process is the only fitting response to the history of the Capitol extensions, not only to restore the original beauty and elegance of these unique floors, but also to provide for their continuing attractiveness for the foreseeable future.

From the planting of the seed to the end of the manufacturing process, Portuguese cork makes for authentic, high quality and eco-efficient cork products that are created with true craftsmanship and care.

Io Aircraft - www.ioaircraft.com

Drew Blair

www.linkedin.com/in/drew-b-25485312/

io aircraft, phantom express, phantom works, boeing phantom works, lockheed skunk works, hypersonic weapon, hypersonic missile, scramjet missile, scramjet engineering, scramjet physics, boost glide, tactical glide vehicle, Boeing XS-1, htv, Air-Launched Rapid Response Weapon, (ARRW), hypersonic tactical vehicle, hypersonic plane, hypersonic aircraft, space plane, scramjet, turbine based combined cycle, ramjet, dual mode ramjet, darpa, onr, navair, afrl, air force research lab, defense science, missile defense agency, aerospike,

Advanced Additive Manufacturing for Hypersonic Aircraft

Utilizing new methods of fabrication and construction, make it possible to use additive manufacturing, dramatically reducing the time and costs of producing hypersonic platforms from missiles, aircraft, and space capable craft. Instead of aircraft being produced in piece, then bolted together; small platforms can be produced as a single unit and large platforms can be produces in large section and mated without bolting. These techniques include using exotic materials and advanced assembly processes, with an end result of streamlining the production costs and time for hypersonic aircraft; reducing months of assembly to weeks. Overall, this process greatly reduced the cost for producing hypersonic platforms. Even to such an extent that a Hellfire missile costs apx $100,000 but by utilizing our technologies, replacing it with a Mach 8-10 hypersonic missile of our physics/engineering and that missile would cost roughly $75,000 each delivered.

Materials used for these manufacturing processes are not disclosed, but overall, provides a foundation for extremely high stresses and thermodynamics, ideal for hypersonic platforms. This specific methodology and materials applications is many decades ahead of all known programs. Even to the extend of normalized space flight and re-entry, without concern of thermodynamic failure.

*Note, most entities that are experimenting with additive manufacturing for hypersonic aircraft, this makes it mainstream and standardized processes, which also applies for mass production.

What would normally be measured in years and perhaps a decade to go from drawing board to test flights, is reduced to singular months and ready for production within a year maximum.

Unified Turbine Based Combined Cycle (U-TBCC)

To date, the closest that NASA and industry have achieved for turbine based aircraft to fly at hypersonic velocities is by mounting a turbine into an aircraft and sharing the inlet with a scramjet or rocket based motor. Reaction Engines Sabre is not able to achieve hypersonic velocities and can only transition into a non air breathing rocket for beyond Mach 4.5

However, utilizing Unified Turbine Based Combine Cycle also known as U-TBCC, the two separate platforms are able to share a common inlet and the dual mode ramjet/scramjet is contained within the engine itself, which allows for a much smaller airframe footprint, thus engingeers are able to then design much higher performance aerial platforms for hypersonic flight, including the ability for constructing true single stage to orbit aircraft by utilizing a modification/version that allows for transition to outside atmosphere propulsion without any other propulsion platforms within the aircraft. By transitioning and developing aircraft to use Unified Turbine Based Combined Cycle, this propulsion system opens up new options to replace that airframe deficit for increased fuel capacity and/or payload.

Enhanced Dynamic Cavitation

Dramatically Increasing the efficiency of fuel air mixture for combustion processes at hypersonic velocities within scramjet propulsion platforms. The aspects of these processes are non disclosable.

Dynamic Scramjet Ignition Processes

For optimal scramjet ignition, a process known as Self Start is sought after, but in many cases if the platform becomes out of attitude, the scramjet will ignite. We have already solved this problem which as a result, a scramjet propulsion system can ignite at lower velocities, high velocities, at optimal attitude or not optimal attitude. It doesn't matter, it will ignite anyways at the proper point for maximum thrust capabilities at hypersonic velocities.

Hydrogen vs Kerosene Fuel Sources

Kerosene is an easy fuel to work with, and most western nations developing scramjet platforms use Kerosene for that fact. However, while kerosene has better thermal properties then Hydrogen, Hydrogen is a far superior fuel source in scramjet propulsion flight, do it having a much higher efficiency capability. Because of this aspect, in conjunction with our developments, it allows for a MUCH increased fuel to air mixture, combustion, thrust; and ability for higher speeds; instead of very low hypersonic velocities in the Mach 5-6 range. Instead, Mach 8-10 range, while we have begun developing hypersonic capabilities to exceed 15 in atmosphere within less then 5 years.

Conforming High Pressure Tank Technology for CNG and H2.

As most know in hypersonics, Hydrogen is a superior fuel source, but due to the storage abilities, can only be stored in cylinders thus much less fuel supply. Not anymore, we developed conforming high pressure storage technology for use in aerospace, automotive sectors, maritime, etc; which means any overall shape required for 8,000+ PSI CNG or Hydrogen. For hypersonic platforms, this means the ability to store a much larger volume of hydrogen vs cylinders.

As an example, X-43 flown by Nasa which flew at Mach 9.97. The fuel source was Hydrogen, which is extremely more volatile and combustible then kerosene (JP-7), via a cylinder in the main body. If it had used our technology, that entire section of the airframe would had been an 8,000 PSI H2 tank, which would had yielded 5-6 times the capacity. While the X-43 flew 11 seconds under power at Mach 9.97, at 6 times the fuel capacity would had yielded apx 66 seconds of fuel under power at Mach 9.97. If it had flew slower, around Mach 6, same principles applied would had yielded apx 500 seconds of fuel supply under power (slower speeds required less energy to maintain).

Enhanced Fuel Mixture During Shock Train Interaction

Normally, fuel injection is conducted at the correct insertion point within the shock train for maximum burn/combustion. Our methodologies differ, since almost half the fuel injection is conducted PRE shock train within the isolator, so at the point of isolator injection the fuel enhances the combustion process, which then requires less fuel injection to reach the same level of thrust capabilities.

Improved Bow Shock Interaction

Smoother interaction at hypersonic velocities and mitigating heat/stresses for beyond Mach 6 thermodynamics, which extraordinarily improves Type 3, 4, and 5 shock interaction.

6,000+ Fahrenheit Thermal Resistance

To date, the maximum thermal resistance was tested at AFRL in the spring of 2018, which resulted in a 3,200F thermal resistance for a short duration. This technology, allows for normalized hypersonic thermal resistance of 3,000-3,500F sustained, and up to 6,500F resistance for short endurance, ie 90 seconds or less. 10-20 minute resistance estimate approximately 4,500F +/- 200F.

*** This technology advancement also applies to Aerospike rocket engines, in which it is common for Aerospike's to exceed 4,500-5,000F temperatures, which results in the melting of the reversed bell housing. That melting no longer ocurrs, providing for stable combustion to ocurr for the entire flight envelope

Scramjet Propulsion Side Wall Cooling

With old technologies, side wall cooling is required for hypersonic flight and scramjet propulsion systems, otherwise the isolator and combustion regions of a scramjet would melt, even using advanced ablatives and ceramics, due to their inability to cope with very high temperatures. Using technology we have developed for very high thermodynamics and high stresses, side wall cooling is no longer required, thus removing that variable from the design process and focusing on improved ignition processes and increasing net thrust values.

Lower Threshold for Hypersonic Ignition

Active and adaptive flight dynamics, resulting in the ability for scramjet ignition at a much lower velocity, ie within ramjet envelope, between Mach 2-4, and seamless transition from supersonic to hypersonic flight, ie supersonic ramjet (scramjet). This active and dynamic aspect, has a wide variety of parameters for many flight dynamics, velocities, and altitudes; which means platforms no longer need to be engineered for specific altitude ranges or preset velocities, but those parameters can then be selected during launch configuration and are able to adapt actively in flight.

Dramatically Improved Maneuvering Capabilities at Hypersonic Velocities

Hypersonic vehicles, like their less technologically advanced brethren, use large actuator and the developers hope those controls surfaces do not disintegrate in flight. In reality, it is like rolling the dice, they may or may not survive, hence another reason why the attempt to keep velocities to Mach 6 or below. We have shrunken down control actuators while almost doubling torque and response capabilities specifically for hypersonic dynamics and extreme stresses involved, which makes it possible for maximum input authority for Mach 10 and beyond.

Paradigm Shift in Control Surface Methodologies, Increasing Control Authority (Internal Mechanical Applications)

To date, most control surfaces for hypersonic missile platforms still use fins, similar to lower speed conventional missiles, and some using ducted fins. This is mostly due to lack of comprehension of hypersonic velocities in their own favor. Instead, the body itself incorporates those control surfaces, greatly enhancing the airframe strength, opening up more space for hardware and fuel capacity; while simultaneously enhancing the platforms maneuvering capabilities.

A scramjet missile can then fly like conventional missile platforms, and not straight and level at high altitudes, losing velocity on it's decent trajectory to target. Another added benefit to this aspect, is the ability to extend range greatly, so if anyone elses hypersonic missile platform were developed for 400 mile range, falling out of the sky due to lack of glide capabilities; our platforms can easily reach 600+ miles, with minimal glide deceleration.

(En) Founded in 1906, the Coking Plant of Anderlues was specialized in the production of coke for industrial use.

Coke was obtained by distillation of coal in furnaces and, thanks to its superior fuel coal properties, it was used afterwards to feed the blast furnaces in the steel manufacturing process.

Closed and abandoned since 2002, the site has since undergone many losses and damages, not including an important pollution. While some buildings have now been demolished, there are however still some important parts of the former coking plant.

Among them, the former coal tower, next to the imposing "battery" of 38 furnaces, where the coke was produced. Besides them, we still can see the administrative buildings, the power station with its cooling tower, and buildings for the by-products, which were obtained by recovering the tar and coal gas. There are also a gasometer north side, the coal tip east side and a settling basin south side.

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(Fr) Fondées en 1906, les Cokeries d'Anderlues étaient spécialisées dans la fabrication de coke à usage industriel.

Le coke était obtenu par distillation de la houille dans des fours et, grâce à ses propriétés combustibles supérieures au charbon, il servait par après à alimenter les hauts-fourneaux dans le processus de fabrication de l'acier.

Fermé et laissé à l'abandon depuis 2002, le site a depuis lors subi de nombreuses pertes et dégradations, sans compter la pollution qui y règne. Si certains bâtiments (comme l'ancien lavoir à charbon) ont aujourd'hui été démolis, on retrouve encore toutefois certaines parties importantes de cette ancienne cokerie.

Parmi celles-ci, l'ancienne tour à charbon suivie de près par l'imposante "batterie" de 38 fours, où était produit le coke. A côté d'eux, on découvre également les bâtiments administratifs, la centrale électrique avec sa tour de refroidissement, ainsi que les bâtiments des sous-produits, lesquels étaient obtenus par récupération du goudron et du gaz de houille. Et en périphérie, on retrouve un gazomètre côté nord, le terril à l'est et un bassin de décantation côté sud.

Location: Lichfield District Council

Accession number: 1983.93.3

A wooden boomerang, believed to have been produced in Australia during the 19th Century.

The boomerang is constructed of a single, bent length of wood. It has been worked into two curved planes which terminate in sharp points. The gouge marks created by an axe during the manufacturing process are still visible.

The boomerang is widely associated with the Indigenous people of Australia, being used for both sport and hunting within traditional Australian culture.

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The company was founded by John Dyson who began mining clay and making bricks in the early 1800s. From the very beginning the business was a success. The 1834 Sheffield trade directory lists - “John Dyson - Brick Maker, Stannington” which indicates that he ran the business on his own. However, by 1838 the business was listed as “John Dyson and Son - Black clay miners and firebrick manufacturers, Griffs House, Stannington.

Dyson's were manufacturers of Refractory material, ceramics for the steel industry, they also produce fire backs and other household ceramic bricks for the likes of Aga's etc. They have also been know to sell clay for use in Well Dressings.

Unfortunately Dyson's traditional manufacturing process relied heavily on gas fired kilns. With increased in energy costs the plants was no longer economically viable, despite the very best efforts of the management and staff alike the site closed around 2005.

The high performance niche products in Dyson's range are still available and are the cornerstone in Dyson's progression. The company have a wholly owned manufacturing facility in Tianjin, PRC which produces is high quality products.