Blow Moulding Machine Manufacturer in Ahmedabad | India

Molding
Molding is the procedure of production forming flexible raw content by using a firm frame or model known as a pattern. The maker who creates the pattern is known as Blow Moulding Machine Manufacturer in India. Mold maker use different kinds of device in casting procedure.

Types of Molding Machines
Blow Moulding Machine Manufacturer in Ahmedabad is a production procedure by which empty plastic parts are established. There are main kinds of device use for strike casting. Extrusion strike moulding device assumes top quality components with both air-driven and mechanical systems, and it is suitable for producing PE, PP and PC container items. Blow hypodermic injection casting device are widely used in medicine packaging, the cosmetic packaging, making up chemical market, gifts & toys and so on. Stretch strike casting device three steps in one from raw content to container finish product no more loss in damaged perform. Pet strike casting device is used in bottling procedure of standard water, sodas, delicious oil and farm chemicals.
Mould devices manufacturer creates different kind of device for casting procedure like candle moulding device for create candle lights, pulp moulding device for create egg containers, fruit containers and pallets. In-mold marking device is perfect equipment of many sectors, such as lubricating oil bucket, dressing container, municipal packaging market, etc.

China Molds
China is the largest manufacturer of hypodermic injection pattern devices on the globe and in fact it rated 1st on the globe. In the past several years hypodermic injection pattern device manufacturers have got greatly improved on technological innovation. However compared with those in western Blow Moulding Machine Manufacturer in India suppliers still have a way to catch up on technological innovation and kinds. In detail there is still not little blank on such kinds as super-large or special perfection hypodermic injection pattern machines; meanwhile self-support rate of home-made hypodermic injection pattern devices for items processing, most adopt brought in hypodermic injection pattern devices. Totally research and production of hypodermic injection pattern devices cannot still satisfy demands brought by development of plastic materials market in Chinese suppliers.
http://www.zeelplastmachinery.in/blow-molding-machine.html

Zeel Plast Machinery for HDPE Bottle Machinery Manufacturer In Ahmedabad, Fully Automatic Blow Moulding Machine Manufacturer In Ahmedabad, Plastic Blow Moulding Machine Manufacturer In Ahmedabad, Plastic Container Manufacturer Machine In India, Plastic Pesticide Bottle Manufacturer in Ahmedabad.
Nice Plastic Auto Door Tooling Production photos

Nice Plastic Auto Door Tooling Production photos

A few nice plastic auto door tooling production images I found:

Steven F. Udvar-Hazy Center: Boeing B-29 Superfortress “Enola Gay”, with Lockheed P-38J-10-LO Lightning
plastic auto door tooling production
Image by Chris Devers
Quoting Smithsonian National Air and Space Museum | Lockheed P-38J-10-LO Lightning :

In the P-38 Lockheed engineer Clarence "Kelly" Johnson and his team of designers created one of the most successful twin-engine fighters ever flown by any nation. From 1942 to 1945, U. S. Army Air Forces pilots flew P-38s over Europe, the Mediterranean, and the Pacific, and from the frozen Aleutian Islands to the sun-baked deserts of North Africa. Lightning pilots in the Pacific theater downed more Japanese aircraft than pilots flying any other Allied warplane.

Maj. Richard I. Bong, America’s leading fighter ace, flew this P-38J-10-LO on April 16, 1945, at Wright Field, Ohio, to evaluate an experimental method of interconnecting the movement of the throttle and propeller control levers. However, his right engine exploded in flight before he could conduct the experiment.

Transferred from the United States Air Force.

Manufacturer:
Lockheed Aircraft Company

Date:
1943

Country of Origin:
United States of America

Dimensions:
Overall: 390 x 1170cm, 6345kg, 1580cm (12ft 9 9/16in. x 38ft 4 5/8in., 13988.2lb., 51ft 10 1/16in.)

Materials:
All-metal

Physical Description:
Twin-tail boom and twin-engine fighter; tricycle landing gear.

• • • • •

Quoting Smithsonian National Air and Space Museum | Boeing B-29 Superfortress "Enola Gay":

Boeing’s B-29 Superfortress was the most sophisticated propeller-driven bomber of World War II and the first bomber to house its crew in pressurized compartments. Although designed to fight in the European theater, the B-29 found its niche on the other side of the globe. In the Pacific, B-29s delivered a variety of aerial weapons: conventional bombs, incendiary bombs, mines, and two nuclear weapons.

On August 6, 1945, this Martin-built B-29-45-MO dropped the first atomic weapon used in combat on Hiroshima, Japan. Three days later, Bockscar (on display at the U.S. Air Force Museum near Dayton, Ohio) dropped a second atomic bomb on Nagasaki, Japan. Enola Gay flew as the advance weather reconnaissance aircraft that day. A third B-29, The Great Artiste, flew as an observation aircraft on both missions.

Transferred from the United States Air Force.

Manufacturer:
Boeing Aircraft Co.
Martin Co., Omaha, Nebr.

Date:
1945

Country of Origin:
United States of America

Dimensions:
Overall: 900 x 3020cm, 32580kg, 4300cm (29ft 6 5/16in. x 99ft 1in., 71825.9lb., 141ft 15/16in.)

Materials:
Polished overall aluminum finish

Physical Description:
Four-engine heavy bomber with semi-monoqoque fuselage and high-aspect ratio wings. Polished aluminum finish overall, standard late-World War II Army Air Forces insignia on wings and aft fuselage and serial number on vertical fin; 509th Composite Group markings painted in black; "Enola Gay" in black, block letters on lower left nose.

Steven F. Udvar-Hazy Center: Hawker Hurricane Mk. IIC, with Northrop P-61C Black Widow, B-29 Superfortress “Enola Gay”, and SR-71 Blackbird in the background

Steven F. Udvar-Hazy Center: Hawker Hurricane Mk. IIC, with Northrop P-61C Black Widow, B-29 Superfortress “Enola Gay”, and SR-71 Blackbird in the background

A few nice auto molds factory china images I found:

Steven F. Udvar-Hazy Center: Hawker Hurricane Mk. IIC, with Northrop P-61C Black Widow, B-29 Superfortress “Enola Gay”, and SR-71 Blackbird in the background
auto molds factory china
Image by Chris Devers
See more photos of this, and the Wikipedia article.

Details, quoting from Smithsonian National Air and Space Museum: Steven F. Udvar-Hazy | Hawker Hurricane Mk. IIC:

Hawker Chief Designer Sydney Camm’s Hurricane ranks with the most important aircraft designs in military aviation history. Designed in the late 1930s, when monoplanes were considered unstable and too radical to be successful, the Hurricane was the first British monoplane fighter and the first British fighter to exceed 483 kilometers (300 miles) per hour in level flight. Hurricane pilots fought the Luftwaffe and helped win the Battle of Britain in the summer of 1940.

This Mark IIC was built at the Langley factory, near what is now Heathrow Airport, early in 1944. It served as a training aircraft during the World War II in the Royal Air Force’s 41 OTU.

Donated by the Royal Air Force Museum

Manufacturer:
Hawker Aircraft Ltd.

Date:
1944

Country of Origin:
United Kingdom

Dimensions:
Wingspan: 12.2 m (40 ft)
Length: 9.8 m (32 ft 3 in)
Height: 4 m (13 ft)
Weight, empty: 2,624 kg (5,785 lb)
Weight, gross: 3,951 kg (8,710 lb)
Top speed:538 km/h (334 mph)
Engine:Rolls-Royce Merlin XX, liquid-cooled in-line V, 1,300 hp
Armament:four 20 mm Hispano cannons
Ordnance:two 250-lb or two 500-lb bombs or eight 3-in rockets

Materials:
Fuselage: Steel tube with aircraft spruce forms and fabric, aluminum cowling
Wings: Stressed Skin Aluminum
Horizontal Stablizer: Stress Skin aluminum
Rudder: fabric covered aluminum
Control Surfaces: fabric covered aluminum

Physical Description:
Hawker Hurricane Mk. IIC single seat, low wing monoplane ground attack fighter; enclosed cockpit; steel tube fuselage with aircraft spruce forms and fabric, aluminum cowling, stressed skin aluminum wings and horizontal stablizer, fabric covered aluminum rudder and control surfaces; grey green camoflage top surface paint scheme with dove grey underside; red and blue national roundel on upper wing surface and red, white, and blue roundel lower wing surface; red, white, blue, and yellow roundel fuselage sides; red, white and blue tail flash; Rolls-Royce Merlin XX, liquid cooled V-12, 1,280 horsepower engine; Armament, 4: 20mm Hispano cannons.

• • • • •

See more photos of this, and the Wikipedia article.

Details, quoting from Smithsonian National Air and Space Museum: Steven F. Udvar-Hazy | Northrop P-61C Black Widow:

The P-61 Black Widow was the first U.S. aircraft designed to locate and destroy enemy aircraft at night and in bad weather, a feat made possible by the use of on-board radar. The prototype first flew in 1942. P-61 combat operations began just after D-Day, June 6, 1944, when Black Widows flew deep into German airspace, bombing and strafing trains and road traffic. Operations in the Pacific began at about the same time. By the end of World War II, Black Widows had seen combat in every theater and had destroyed 127 enemy aircraft and 18 German V-1 buzz bombs.

The Museum’s Black Widow, a P-61C-1-NO, was delivered to the Army Air Forces in July 1945. It participated in cold-weather tests, high-altitude drop tests, and in the National Thunderstorm Project, for which the top turret was removed to make room for thunderstorm monitoring equipment.

Transferred from the United States Air Force.

Manufacturer:
Northrop Aircraft Inc.

Date:
1943

Country of Origin:
United States of America

Dimensions:
Overall: 450 x 1500cm, 10637kg, 2000cm (14ft 9 3/16in. x 49ft 2 9/16in., 23450.3lb., 65ft 7 3/8in.)

• • • • •

Quoting Smithsonian National Air and Space Museum | Boeing B-29 Superfortress "Enola Gay":

Boeing’s B-29 Superfortress was the most sophisticated propeller-driven bomber of World War II and the first bomber to house its crew in pressurized compartments. Although designed to fight in the European theater, the B-29 found its niche on the other side of the globe. In the Pacific, B-29s delivered a variety of aerial weapons: conventional bombs, incendiary bombs, mines, and two nuclear weapons.

On August 6, 1945, this Martin-built B-29-45-MO dropped the first atomic weapon used in combat on Hiroshima, Japan. Three days later, Bockscar (on display at the U.S. Air Force Museum near Dayton, Ohio) dropped a second atomic bomb on Nagasaki, Japan. Enola Gay flew as the advance weather reconnaissance aircraft that day. A third B-29, The Great Artiste, flew as an observation aircraft on both missions.

Transferred from the United States Air Force.

Manufacturer:
Boeing Aircraft Co.
Martin Co., Omaha, Nebr.

Date:
1945

Country of Origin:
United States of America

Dimensions:
Overall: 900 x 3020cm, 32580kg, 4300cm (29ft 6 5/16in. x 99ft 1in., 71825.9lb., 141ft 15/16in.)

Materials:
Polished overall aluminum finish

Physical Description:
Four-engine heavy bomber with semi-monoqoque fuselage and high-aspect ratio wings. Polished aluminum finish overall, standard late-World War II Army Air Forces insignia on wings and aft fuselage and serial number on vertical fin; 509th Composite Group markings painted in black; "Enola Gay" in black, block letters on lower left nose.

• • • • •

See more photos of this, and the Wikipedia article.

Details, quoting from Smithsonian National Air and Space Museum | Lockheed SR-71 Blackbird:

No reconnaissance aircraft in history has operated globally in more hostile airspace or with such complete impunity than the SR-71, the world’s fastest jet-propelled aircraft. The Blackbird’s performance and operational achievements placed it at the pinnacle of aviation technology developments during the Cold War.

This Blackbird accrued about 2,800 hours of flight time during 24 years of active service with the U.S. Air Force. On its last flight, March 6, 1990, Lt. Col. Ed Yielding and Lt. Col. Joseph Vida set a speed record by flying from Los Angeles to Washington, D.C., in 1 hour, 4 minutes, and 20 seconds, averaging 3,418 kilometers (2,124 miles) per hour. At the flight’s conclusion, they landed at Washington-Dulles International Airport and turned the airplane over to the Smithsonian.

Transferred from the United States Air Force.

Manufacturer:
Lockheed Aircraft Corporation

Designer:
Clarence L. "Kelly" Johnson

Date:
1964

Country of Origin:
United States of America

Dimensions:
Overall: 18ft 5 15/16in. x 55ft 7in. x 107ft 5in., 169998.5lb. (5.638m x 16.942m x 32.741m, 77110.8kg)
Other: 18ft 5 15/16in. x 107ft 5in. x 55ft 7in. (5.638m x 32.741m x 16.942m)

Materials:
Titanium

Physical Description:
Twin-engine, two-seat, supersonic strategic reconnaissance aircraft; airframe constructed largley of titanium and its alloys; vertical tail fins are constructed of a composite (laminated plastic-type material) to reduce radar cross-section; Pratt and Whitney J58 (JT11D-20B) turbojet engines feature large inlet shock cones.

Steven F. Udvar-Hazy Center: main hall panorama
auto molds factory china
Image by Chris Devers

See more photos of this, and the Wikipedia article.

Details, quoting from Smithsonian National Air and Space Museum | _details_pending_:

Nice Plastic Auto Parts Plastic Mould photos

Nice Plastic Auto Parts Plastic Mould photos

A few nice plastic auto parts plastic mould images I found:

1973 Citroen DS23 Pallas
plastic auto parts plastic mould
Image by DVS1mn
CITROEN DS23 PALLAS
When in 1955 Citroen released its DS19 ‘Goddess’, media commentators reviewed the car in tones previously reserved for objects arriving from the depths of outer space.

Hydro-pneumatic suspension, assistance systems for the steering, brakes and gearshift lever, and inboard front disc brakes were among the advances pioneered by this extraordinary design.

By 1968 the rest of the world had begun adopting aspects of Citroen’s radical package; however, Citroen wasn’t finished exploring the range of quirks it could pack into a medium-sized sedan. One new feature to perplex the home mechanic was a link that would swivel headlights in unison with the front wheels.

The car’s ability to traverse rough terrain was proved in 1969 when a Citroen was set to win the first London-Sydney Marathon, only to be taken out in a serious collision with a spectator vehicle. Five years later, the Australian crew of a DS23 got the job done, dominating a 1974 World Cup Rally that sent competitors from South America to Munich via the Sahara Desert.

Maintaining a DS is work for specialist technicians or perhaps the seriously talented amateur. There is barely room under the bonnet of a Pallas to see engine components, let alone put a spanner on them.

Three-speed automatics were plagued by problems and remain difficult to maintain, so get a five-speed manual if you can. Overseas values are providing a big hint that anyone who wants a really good Pallas needs to act soon. Be prepared to invest the better part of ,000. Of several thousand cars sold new in Britain, fewer than 300 are known to survive and numbers in Australia will be far slimmer.

TRAPS AND TIPS

Packing a mass of electro/mechanical/hydraulic bits plus the complete drivetrain into a small space ahead of the firewall didn’t help Citroen’s reputation for reliability.

Keeping your Citroen cool is vital to engine longevity and that can be costly. One spare parts site was quoting authentic but renovated radiators at more than 00. Replacing the coolant hoses with a set of genuine items will cost more than 0.

Citroen club sites of late have carried requests for help in locating a competent trimmer for DS models. This suggests that finding someone to repair a car with worn seats and compromised head-lining has become challenging.

FROM THE WHEELS ARCHIVES
Words: Paul Blank – January, 2005

The DS was spectacularly bold, wrote Paul Blank…

When the time came to replace the Traction Avant, the resulting car could be expected to be absolutely amazing – and it was.

The new car, launched at the Paris Salon in 1955, was called DS, which, when pronounced in French, is "Day-ess", which translates to Goddess. At the Paris Salon an amazing number of orders were taken for the new car – some 12,000 people signing on the dotted line.

In 1955 Australians were buying new FJ Holdens and the Morris Minor was considered a modern small car in England. The DS might as well have been a spaceship in comparison. It certainly looked like
nothing else.

The car floated along at any speed. Famously, the DS featured Hydropneumatic suspension. It had the cars sitting on suspension units which were steel spheres in place of traditional springs and shock absorbers. The ride in a DS has to be experienced to be believed. Even if a tyre blew, the car would compensate.

Another DS feature was the use of disc brakes. It was Citroen which first fitted them to a mass-production car.

Inside, the DS was as spectacularly bold as the rest of the car. In an era of flat tin or wood dashboards, Citroen used the biggest single piece of moulded plastic in the world. The DS in not a complicated car; just very different.

You know the car’s ready when first the back, then the front of the car lift up to normal ride height. To change gear, you lift off, switch to the next gear and accelerate away again. Then you have to learn about the brakes. Where you might expect a brake pedal, there’s a black rubber mushroom. It works like a valve operating by the "the harder you push, the more you stop" system, with almost no pedal travel available.

The DS isn’t a sports car; it’s a real Grand Tourer and, treated as such, provides a magical experience.

SPECIFICATIONS

Citroen DS23 Pallas

Number built: 582,593 (All ID/DS 1968-75)
Body: All-steel, integrated body/chassis 4-door sedan and station wagon
Engine: 2347cc inline 4-cylinder, OHV, 8v, fuel injection
Power & torque: 105kW @ 5500rpm, 200Nm @ 4000rpm
Performance: 0-97km/h 10.2sec; 0-400m 17.3sec
Transmission: 3-speed automatic, 5-speed manual
Suspension: Independent with wishbones, pneumatic struts and anti-roll bar (f); Independent with trailing arms, pneumatic struts and anti-roll bar (r)
Brakes: Discs, power-assisted
Tyres: 185HR15 radial
Price range: 00-,000
Contact: Citroen Clubs in various states,
www.ds23.co.nz/
Click here for more car pictures at my Flickr site.

Car Bumper Manufacturers in China

Car Bumper Manufacturers in China

China has begun to emerge as the economic force to reckon with in the global market. Its billion strong population has made it possible to break through almost all the markets, and these include the car bumper market. It seems that there is no dearth to car bumper manufacturers in China. Below is a list of some of the more visible Chinese manufacturers who have made their presence felt online, plus an overview of their companies.

Xiamen Kingtom Rubber-Plastic Co., Ltd. Is established and located in the province of Xiamen. This ISO 9001 certified company is 400-strong with 60 production lines. They are specialized in rubber and plastic parts for sanitation, automobiles (which includes car bumpers) and electrical appliances. Their monthly capacity is around 400 tons finished items, so items can be delivered in less than a week. Their vision is to turn their company into a large scale company operating for the international market.

Changshu Jianan FRP Products Co., Ltd. specializes in FRP (or fiber reinforced plastic) technology. They have a comprehensive range of products: from the automobile bumper to the motorcycle casing to the cable jacket, they all have it. Although they have a much lesser number of employees – 120 – they do have a vast factory area of over 12,000 square meters, and their annual production capacity is 10,000 MT. Also, the proximity of their location makes it convenient for them to transport their deliveries on time. They mostly cater to the international market, with their products reaching as far as UK, Australia and America. Their annual sales are US $ 2,200,000 and their main buyers are the Hitachi Medical Corporation and the Import Trenz, among others.

The Haiyan Zhenda Automobile Fittings Factory, established in 1976, has been a leading manufacturer of auto parts, including brake lining, rubber parts such as the car bumper, and engine bolts. They are an OEM supplier to major vehicle assemblers, and they are vouched for by their ISO 9001 and TS-16949 certifications. It is no wonder then that their sales top US $ 10,000,000 annually and that half of the products they make find their way throughout the world.

The L&C Auto Parts is relatively young compared to the abovementioned. It was established only in 19990, although they have been in fact steadily growing over the years. Their annual sales tip $ 8,000,000. Their main products include the car bumper, the guard rail, the solenoid, the armature, the exhaust manifold, et al. Their two main factories specialize in producing hardware car parts for assembly and creating starters and armatures, respectively. They place great stock in the quality of their products as evidenced by the investment they put in their R&D and QC departments.

The Anhui Technology is a large trading company that supplies mostly the US and European markets. They have a variety of product offerings, from appliances to chemicals to machinery. This contributed to their export volume of $ 524, 000,000 last year. Their branch, the Anhui Technology Auto Parts & Accessories, offers automotive break parts, automotive suspension parts and accessories (the car bumper being one of these) and automotive battery terminal/fittings.

The Shanghai Tengkun Consulting Co., Ltd. offer a broad range of products, from auto spare parts (like the car bumper, car mirror, or car tire) to furnishing parts and telecommunication equipment. Their products have proven to be a hit in the Japanese, European and North American markets. They are engaged in the export and import service, and also have a Commission agent for their documentation works agency and inspection agency.

And to think that this is only a drop in the sea that is the car bumper business, and the ocean that is the automobile industry. The plethora of car bumper choices is a boon for consumers who wan the best value their money can buy.

James Monahan is the owner and senior editor of
BumperCenter.com
Mr. McClure’s 1/43 collection- and one of mine. Racing Cars: F1, Le Mans, Can-Am, WRC

Mr. McClure’s 1/43 collection- and one of mine. Racing Cars: F1, Le Mans, Can-Am, WRC

Check out these plastic auto parts injection mould manufacturers images:

Mr. McClure’s 1/43 collection- and one of mine. Racing Cars: F1, Le Mans, Can-Am, WRC
plastic auto parts injection mould manufacturers
Image by wbaiv
Mmmm my kind of racing cars – Old F1 (mostly pre-WWII), 50s and later Le Mans, some Can Am, a WRC Lancia Stratos from the 1970s. This is the good stuff and if you look at the full size picture you can read the info tags on Kent’s models. The green one furthest away, #0, white wheels, is my own Mitsubishi "0" (nyuk nyuk nyuk) No such actual markings were ever carried by a WRC car, and many would find it in poor taste, I suppose. But I thought the classic IJN green over IJN light gray, black around the engine, and metallic blue-green inside would be fun. It used to be a mater of faith among the model building community that the interior of Imperial Japanese Navy planes was a transparent blue-green (Malachite green some said) primer/protectant. Turns out not to be true. Some original finishes aged and faded to look like that, but the factory interior paint was a grey green (surprise!), slightly different for Mitsubishi and Nakajima. Different Japanese Navy bases had different "light gray" standards, no surprise the manufacturers differed.
Anyway, my kit is a Heller injection molded plastic kit, Mr. McClure’s work classic cottage industry stuff- white metal or resin body and chassis, white metal, resin or turned aluminum wheels, perhaps some photoetch, vacuformed clear parts. NON trivial stuff. You can tell he’s good.

From the left, back to front:
Porsche 917-30K, Porsche 908-3, Porsche 934, Porsche 936, Courage, Rondinet or something like that, Porsche 935, Ferrari 330 P3 or P4, McLaren Mk 6, Mitsubishi

Second Row: Porsche 550, Porsche 917/69, Porsche 917/70, Porsche 917? Porsche 917LH/1971 (lang heck) FordGT-40 MkII or possibly Gulf Mirage, McLaren Mk 1, Lancia Stratos.

Third Row: Cistilla? Auto Union? F1, British F1, British F1, Ford GT-40, Porsche 962, not sure.

Fourth row 3 front engine F1s, and what mgith be a Cooper. Shelby Daytona Cobra, Ford P 3.0 (endurance racer with Cosworth DFV 3.0…)

Fifth row (one back from the front row) – Front engine F1- Alfa? (sign) abortive 4WD F1 car, Ferrari sports/racer, furthest right, red March Can Am car.

Front row: F1 car, Jaguar "D" type, Lotus 11 or 19 or something else very small and light. Ford GT-40

DSC_0468

Cool Auto Moulds Factory China images

Cool Auto Moulds Factory China images

Some cool auto moulds factory china images:

Steven F. Udvar-Hazy Center: Lockheed P-38J-10-LO Lightning
auto moulds factory china
Image by Chris Devers
See more photos of this, and the Wikipedia article.

Details, quoting from Smithsonian National Air and Space Museum | Lockheed P-38J-10-LO Lightning

In the P-38 Lockheed engineer Clarence "Kelly" Johnson and his team of designers created one of the most successful twin-engine fighters ever flown by any nation. From 1942 to 1945, U. S. Army Air Forces pilots flew P-38s over Europe, the Mediterranean, and the Pacific, and from the frozen Aleutian Islands to the sun-baked deserts of North Africa. Lightning pilots in the Pacific theater downed more Japanese aircraft than pilots flying any other Allied warplane.

Maj. Richard I. Bong, America’s leading fighter ace, flew this P-38J-10-LO on April 16, 1945, at Wright Field, Ohio, to evaluate an experimental method of interconnecting the movement of the throttle and propeller control levers. However, his right engine exploded in flight before he could conduct the experiment.

Transferred from the United States Air Force.

Manufacturer:
Lockheed Aircraft Company

Date:
1943

Country of Origin:
United States of America

Dimensions:
Overall: 390 x 1170cm, 6345kg, 1580cm (12ft 9 9/16in. x 38ft 4 5/8in., 13988.2lb., 51ft 10 1/16in.)

Materials:
All-metal

Physical Description:
Twin-tail boom and twin-engine fighter; tricycle landing gear.

Long Description:
From 1942 to 1945, the thunder of P-38 Lightnings was heard around the world. U. S. Army pilots flew the P-38 over Europe, the Mediterranean, and the Pacific; from the frozen Aleutian Islands to the sun-baked deserts of North Africa. Measured by success in combat, Lockheed engineer Clarence "Kelly" Johnson and a team of designers created the most successful twin-engine fighter ever flown by any nation. In the Pacific Theater, Lightning pilots downed more Japanese aircraft than pilots flying any other Army Air Forces warplane.

Johnson and his team conceived this twin-engine, single-pilot fighter airplane in 1936 and the Army Air Corps authorized the firm to build it in June 1937. Lockheed finished constructing the prototype XP-38 and delivered it to the Air Corps on New Year’s Day, 1939. Air Corps test pilot and P-38 project officer, Lt. Benjamin S. Kelsey, first flew the aircraft on January 27. Losing this prototype in a crash at Mitchel Field, New York, with Kelsey at the controls, did not deter the Air Corps from ordering 13 YP-38s for service testing on April 27. Kelsey survived the crash and remained an important part of the Lightning program. Before the airplane could be declared ready for combat, Lockheed had to block the effects of high-speed aerodynamic compressibility and tail buffeting, and solve other problems discovered during the service tests.

The most vexing difficulty was the loss of control in a dive caused by aerodynamic compressibility. During late spring 1941, Air Corps Major Signa A. Gilke encountered serious trouble while diving his Lightning at high-speed from an altitude of 9,120 m (30,000 ft). When he reached an indicated airspeed of about 515 kph (320 mph), the airplane’s tail began to shake violently and the nose dropped until the dive was almost vertical. Signa recovered and landed safely and the tail buffet problem was soon resolved after Lockheed installed new fillets to improve airflow where the cockpit gondola joined the wing center section. Seventeen months passed before engineers began to determine what caused the Lightning’s nose to drop. They tested a scale model P-38 in the Ames Laboratory wind tunnel operated by the NACA (National Advisory Committee for Aeronautics) and found that shock waves formed when airflow over the wing leading edges reached transonic speeds. The nose drop and loss of control was never fully remedied but Lockheed installed dive recovery flaps under each wing in 1944. These devices slowed the P-38 enough to allow the pilot to maintain control when diving at high-speed.

Just as the development of the North American P-51 Mustang, Republic P-47 Thunderbolt, and the Vought F4U Corsair (see NASM collection for these aircraft) pushed the limits of aircraft performance into unexplored territory, so too did P-38 development. The type of aircraft envisioned by the Lockheed design team and Air Corps strategists in 1937 did not appear until June 1944. This protracted shakedown period mirrors the tribulations suffered by Vought in sorting out the many technical problems that kept F4U Corsairs off U. S. Navy carrier decks until the end of 1944.

Lockheed’s efforts to trouble-shoot various problems with the design also delayed high-rate, mass production. When Japan attacked Pearl Harbor, the company had delivered only 69 Lightnings to the Army. Production steadily increased and at its peak in 1944, 22 sub-contractors built various Lightning components and shipped them to Burbank, California, for final assembly. Consolidated-Vultee (Convair) subcontracted to build the wing center section and the firm later became prime manufacturer for 2,000 P-38Ls but that company’s Nashville plant completed only 113 examples of this Lightning model before war’s end. Lockheed and Convair finished 10,038 P-38 aircraft including 500 photo-reconnaissance models. They built more L models, 3,923, than any other version.

To ease control and improve stability, particularly at low speeds, Lockheed equipped all Lightnings, except a batch ordered by Britain, with propellers that counter-rotated. The propeller to the pilot’s left turned counter-clockwise and the propeller to his right turned clockwise, so that one propeller countered the torque and airflow effects generated by the other. The airplane also performed well at high speeds and the definitive P-38L model could make better than 676 kph (420 mph) between 7,600 and 9,120 m (25,000 and 30,000 ft). The design was versatile enough to carry various combinations of bombs, air-to-ground rockets, and external fuel tanks. The multi-engine configuration reduced the Lightning loss-rate to anti-aircraft gunfire during ground attack missions. Single-engine airplanes equipped with power plants cooled by pressurized liquid, such as the North American P-51 Mustang (see NASM collection), were particularly vulnerable. Even a small nick in one coolant line could cause the engine to seize in a matter of minutes.

The first P-38s to reach the Pacific combat theater arrived on April 4, 1942, when a version of the Lightning that carried reconnaissance cameras (designated the F-4), joined the 8th Photographic Squadron based in Australia. This unit launched the first P-38 combat missions over New Guinea and New Britain during April. By May 29, the first 25 P-38s had arrived in Anchorage, Alaska. On August 9, pilots of the 343rd Fighter Group, Eleventh Air Force, flying the P-38E, shot down a pair of Japanese flying boats.

Back in the United States, Army Air Forces leaders tried to control a rumor that Lightnings killed their own pilots. On August 10, 1942, Col. Arthur I. Ennis, Chief of U. S. Army Air Forces Public Relations in Washington, told a fellow officer "… Here’s what the 4th Fighter [training] Command is up against… common rumor out there that the whole West Coast was filled with headless bodies of men who jumped out of P-38s and had their heads cut off by the propellers." Novice Lightning pilots unfamiliar with the correct bailout procedures actually had more to fear from the twin-boom tail, if an emergency dictated taking to the parachute but properly executed, Lightning bailouts were as safe as parachuting from any other high-performance fighter of the day. Misinformation and wild speculation about many new aircraft was rampant during the early War period.

Along with U. S. Navy Grumman F4F Wildcats (see NASM collection) and Curtiss P-40 Warhawks (see NASM collection), Lightnings were the first American fighter airplanes capable of consistently defeating Japanese fighter aircraft. On November 18, men of the 339th Fighter Squadron became the first Lightning pilots to attack Japanese fighters. Flying from Henderson Field on Guadalcanal, they claimed three during a mission to escort Boeing B-17 Flying Fortress bombers (see NASM collection).

On April 18, 1943, fourteen P-38 pilots from the 70th and the 339th Fighter Squadrons, 347th Fighter Group, accomplished one of the most important Lightning missions of the war. American ULTRA cryptanalysts had decoded Japanese messages that revealed the timetable for a visit to the front by the commander of the Imperial Japanese Navy, Admiral Isoroku Yamamoto. This charismatic leader had crafted the plan to attack Pearl Harbor and Allied strategists believed his loss would severely cripple Japanese morale. The P-38 pilots flew 700 km (435 miles) at heights from 3-15 m (10-50 feet) above the ocean to avoid detection. Over the coast of Bougainville, they intercepted a formation of two Mitsubishi G4M BETTY bombers (see NASM collection) carrying the Admiral and his staff, and six Mitsubishi A6M Zero fighters (see NASM collection) providing escort. The Lightning pilots downed both bombers but lost Lt. Ray Hine to a Zero.

In Europe, the first Americans to down a Luftwaffe aircraft were Lt. Elza E. Shahan flying a 27th Fighter Squadron P-38E, and Lt. J. K. Shaffer flying a Curtiss P-40 (see NASM collection) in the 33rd Fighter Squadron. The two flyers shared the destruction of a Focke-Wulf Fw 200C-3 Condor maritime strike aircraft over Iceland on August 14, 1942. Later that month, the 1st fighter group accepted Lightnings and began combat operations from bases in England but this unit soon moved to fight in North Africa. More than a year passed before the P-38 reappeared over Western Europe. While the Lightning was absent, U. S. Army Air Forces strategists had relearned a painful lesson: unescorted bombers cannot operate successfully in the face of determined opposition from enemy fighters. When P-38s returned to England, the primary mission had become long-range bomber escort at ranges of about 805 kms (500 miles) and at altitudes above 6,080 m (20,000 ft).

On October 15, 1943, P-38H pilots in the 55th Fighter Group flew their first combat mission over Europe at a time when the need for long-range escorts was acute. Just the day before, German fighter pilots had destroyed 60 of 291 Eighth Air Force B-17 Flying Fortresses (see NASM collection) during a mission to bomb five ball-bearing plants at Schweinfurt, Germany. No air force could sustain a loss-rate of nearly 20 percent for more than a few missions but these targets lay well beyond the range of available escort fighters (Republic P-47 Thunderbolt, see NASM collection). American war planners hoped the long-range capabilities of the P-38 Lightning could halt this deadly trend, but the very high and very cold environment peculiar to the European air war caused severe power plant and cockpit heating difficulties for the Lightning pilots. The long-range escort problem was not completely solved until the North American P-51 Mustang (see NASM collection) began to arrive in large numbers early in 1944.

Poor cockpit heating in the H and J model Lightnings made flying and fighting at altitudes that frequently approached 12,320 m (40,000 ft) nearly impossible. This was a fundamental design flaw that Kelly Johnson and his team never anticipated when they designed the airplane six years earlier. In his seminal work on the Allison V-1710 engine, Daniel Whitney analyzed in detail other factors that made the P-38 a disappointing airplane in combat over Western Europe.

• Many new and inexperienced pilots arrived in England during December 1943, along with the new J model P-38 Lightning.

• J model rated at 1,600 horsepower vs. 1,425 for earlier H model Lightnings. This power setting required better maintenance between flights. It appears this work was not done in many cases.

• During stateside training, Lightning pilots were taught to fly at high rpm settings and low engine manifold pressure during cruise flight. This was very hard on the engines, and not in keeping with technical directives issued by Allison and Lockheed.

• The quality of fuel in England may have been poor, TEL (tetraethyl lead) fuel additive appeared to condense inside engine induction manifolds, causing detonation (destructive explosion of fuel mixture rather than controlled burning).

• Improved turbo supercharger intercoolers appeared on the J model P-38. These devices greatly reduced manifold temperatures but this encouraged TEL condensation in manifolds during cruise flight and increased spark plug fouling.

Using water injection to minimize detonation might have reduced these engine problems. Both the Republic P-47 Thunderbolt and the North American P-51 Mustang (see NASM collection) were fitted with water injection systems but not the P-38. Lightning pilots continued to fly, despite these handicaps.

During November 1942, two all-Lightning fighter groups, the 1st and the 14th, began operating in North Africa. In the Mediterranean Theater, P-38 pilots flew more sorties than Allied pilots flying any other type of fighter. They claimed 608 enemy a/c destroyed in the air, 123 probably destroyed and 343 damaged, against the loss of 131 Lightnings.

In the war against Japan, the P-38 truly excelled. Combat rarely occurred above 6,080 m (20,000 ft) and the engine and cockpit comfort problems common in Europe never plagued pilots in the Pacific Theater. The Lightning’s excellent range was used to full advantage above the vast expanses of water. In early 1945, Lightning pilots of the 12th Fighter Squadron, 18th Fighter Group, flew a mission that lasted 10 ½ hours and covered more than 3,220 km (2,000 miles). In August, P-38 pilots established the world’s long-distance record for a World War II combat fighter when they flew from the Philippines to the Netherlands East Indies, a distance of 3,703 km (2,300 miles). During early 1944, Lightning pilots in the 475th Fighter Group began the ‘race of aces.’ By March, Lieutenant Colonel Thomas J. Lynch had scored 21 victories before he fell to antiaircraft gunfire while strafing enemy ships. Major Thomas B. McGuire downed 38 Japanese aircraft before he was killed when his P-38 crashed at low altitude in early January 1945. Major Richard I. Bong became America’s highest scoring fighter ace (40 victories) but died in the crash of a Lockheed P-80 (see NASM collection) on August 6, 1945.

Museum records show that Lockheed assigned the construction number 422-2273 to the National Air and Space Museum’s P-38. The Army Air Forces accepted this Lightning as a P-38J-l0-LO on November 6, 1943, and the service identified the airplane with the serial number 42-67762. Recent investigations conducted by a team of specialists at the Paul E. Garber Facility, and Herb Brownstein, a volunteer in the Aeronautics Division at the National Air and Space Museum, have revealed many hitherto unknown aspects to the history of this aircraft.

Brownstein examined NASM files and documents at the National Archives. He discovered that a few days after the Army Air Forces (AAF) accepted this airplane, the Engineering Division at Wright Field in Dayton, Ohio, granted Lockheed permission to convert this P-38 into a two-seat trainer. The firm added a seat behind the pilot to accommodate an instructor who would train civilian pilots in instrument flying techniques. Once trained, these test pilots evaluated new Lightnings fresh off the assembly line.

In a teletype sent by the Engineering Division on March 2, 1944, Brownstein also discovered that this P-38 was released to Colonel Benjamin S. Kelsey from March 3 to April 10, 1944, to conduct special tests. This action was confirmed the following day in a cable from the War Department. This same pilot, then a Lieutenant, flew the XP-38 across the United States in 1939 and survived the crash that destroyed this Lightning at Mitchel Field, New York. In early 1944, Kelsey was assigned to the Eighth Air Force in England and he apparently traveled to the Lockheed factory at Burbank to pick up the P-38. Further information about these tests and Kelsey’s involvement remain an intriguing question.

One of Brownstein’s most important discoveries was a small file rich with information about the NASM Lightning. This file contained a cryptic reference to a "Major Bong" who flew the NASM P-38 on April 16, 1945, at Wright Field. Bong had planned to fly for an hour to evaluate an experimental method of interconnecting the movement of the throttle and propeller control levers. His flight ended after twenty-minutes when "the right engine blew up before I had a chance [to conduct the test]." The curator at the Richard I. Bong Heritage Center confirmed that America’s highest scoring ace made this flight in the NASM P-38 Lightning.

Working in Building 10 at the Paul E. Garber Facility, Rob Mawhinney, Dave Wilson, Wil Lee, Bob Weihrauch, Jim Purton, and Heather Hutton spent several months during the spring and summer of 2001 carefully disassembling, inspecting, and cleaning the NASM Lightning. They found every hardware modification consistent with a model J-25 airplane, not the model J-10 painted in the data block beneath the artifact’s left nose. This fact dovetails perfectly with knowledge uncovered by Brownstein. On April 10, the Engineering Division again cabled Lockheed asking the company to prepare 42-67762 for transfer to Wright Field "in standard configuration." The standard P-38 configuration at that time was the P-38J-25. The work took several weeks and the fighter does not appear on Wright Field records until May 15, 1944. On June 9, the Flight Test Section at Wright Field released the fighter for flight trials aimed at collecting pilot comments on how the airplane handled.

Wright Field’s Aeromedical Laboratory was the next organization involved with this P-38. That unit installed a kit on July 26 that probably measured the force required to move the control wheel left and right to actuate the power-boosted ailerons installed in all Lightnings beginning with version J-25. From August 12-16, the Power Plant Laboratory carried out tests to measure the hydraulic pump temperatures on this Lightning. Then beginning September 16 and lasting about ten days, the Bombing Branch, Armament Laboratory, tested type R-3 fragmentation bomb racks. The work appears to have ended early in December. On June 20, 1945, the AAF Aircraft Distribution Office asked that the Air Technical Service Command transfer the Lightning from Wright Field to Altus Air Force Base, Oklahoma, a temporary holding area for Air Force museum aircraft. The P-38 arrived at the Oklahoma City Air Depot on June 27, 1945, and mechanics prepared the fighter for flyable storage.

Airplane Flight Reports for this Lightning also describe the following activities and movements:

6-21-45 Wright Field, Ohio, 5.15 hours of flying.
6-22-45Wright Field, Ohio, .35 minutes of flying by Lt. Col. Wendel [?] J. Kelley and P. Shannon.
6-25-45Altus, Oklahoma, .55 hours flown, pilot P. Shannon.
6-27-45Altus, Oklahoma, #2 engine changed, 1.05 hours flown by Air Corps F/O Ralph F. Coady.
10-5-45 OCATSC-GCAAF (Garden City Army Air Field, Garden City, Kansas), guns removed and ballast added.
10-8-45Adams Field, Little Rock, Arkansas.
10-9-45Nashville, Tennessee,
5-28-46Freeman Field, Indiana, maintenance check by Air Corps Capt. H. M. Chadhowere [sp]?
7-24-46Freeman Field, Indiana, 1 hour local flight by 1st Lt. Charles C. Heckel.
7-31-46 Freeman Field, Indiana, 4120th AAF Base Unit, ferry flight to Orchard Place [Illinois] by 1st Lt. Charles C. Heckel.

On August 5, 1946, the AAF moved the aircraft to another storage site at the former Consolidated B-24 bomber assembly plant at Park Ridge, Illinois. A short time later, the AAF transferred custody of the Lightning and more than sixty other World War II-era airplanes to the Smithsonian National Air Museum. During the early 1950s, the Air Force moved these airplanes from Park Ridge to the Smithsonian storage site at Suitland, Maryland.

• • •

Quoting from Wikipedia | Lockheed P-38 Lightning:

The Lockheed P-38 Lightning was a World War II American fighter aircraft built by Lockheed. Developed to a United States Army Air Corps requirement, the P-38 had distinctive twin booms and a single, central nacelle containing the cockpit and armament. Named "fork-tailed devil" by the Luftwaffe and "two planes, one pilot" by the Japanese, the P-38 was used in a number of roles, including dive bombing, level bombing, ground-attack, photo reconnaissance missions, and extensively as a long-range escort fighter when equipped with drop tanks under its wings.

The P-38 was used most successfully in the Pacific Theater of Operations and the China-Burma-India Theater of Operations as the mount of America’s top aces, Richard Bong (40 victories) and Thomas McGuire (38 victories). In the South West Pacific theater, the P-38 was the primary long-range fighter of United States Army Air Forces until the appearance of large numbers of P-51D Mustangs toward the end of the war. The P-38 was unusually quiet for a fighter, the exhaust muffled by the turbo-superchargers. It was extremely forgiving, and could be mishandled in many ways, but the rate of roll was too slow for it to excel as a dogfighter. The P-38 was the only American fighter aircraft in production throughout American involvement in the war, from Pearl Harbor to Victory over Japan Day.

Variants: Lightning in maturity: P-38J

The P-38J was introduced in August 1943. The turbo-supercharger intercooler system on previous variants had been housed in the leading edges of the wings and had proven vulnerable to combat damage and could burst if the wrong series of controls were mistakenly activated. In the P-38J model, the streamlined engine nacelles of previous Lightnings were changed to fit the intercooler radiator between the oil coolers, forming a "chin" that visually distinguished the J model from its predecessors. While the P-38J used the same V-1710-89/91 engines as the H model, the new core-type intercooler more efficiently lowered intake manifold temperatures and permitted a substantial increase in rated power. The leading edge of the outer wing was fitted with 55 gal (208 l) fuel tanks, filling the space formerly occupied by intercooler tunnels, but these were omitted on early P-38J blocks due to limited availability.

The final 210 J models, designated P-38J-25-LO, alleviated the compressibility problem through the addition of a set of electrically-actuated dive recovery flaps just outboard of the engines on the bottom centerline of the wings. With these improvements, a USAAF pilot reported a dive speed of almost 600 mph (970 km/h), although the indicated air speed was later corrected for compressibility error, and the actual dive speed was lower. Lockheed manufactured over 200 retrofit modification kits to be installed on P-38J-10-LO and J-20-LO already in Europe, but the USAAF C-54 carrying them was shot down by an RAF pilot who mistook the Douglas transport for a German Focke-Wulf Condor. Unfortunately the loss of the kits came during Lockheed test pilot Tony LeVier‘s four-month morale-boosting tour of P-38 bases. Flying a new Lightning named "Snafuperman" modified to full P-38J-25-LO specs at Lockheed’s modification center near Belfast, LeVier captured the pilots’ full attention by routinely performing maneuvers during March 1944 that common Eighth Air Force wisdom held to be suicidal. It proved too little too late because the decision had already been made to re-equip with Mustangs.

The P-38J-25-LO production block also introduced hydraulically-boosted ailerons, one of the first times such a system was fitted to a fighter. This significantly improved the Lightning’s rate of roll and reduced control forces for the pilot. This production block and the following P-38L model are considered the definitive Lightnings, and Lockheed ramped up production, working with subcontractors across the country to produce hundreds of Lightnings each month.

Noted P-38 pilots

Richard Bong and Thomas McGuire

The American ace of aces and his closest competitor both flew Lightnings as they tallied 40 and 38 victories respectively. Majors Richard I. "Dick" Bong and Thomas J. "Tommy" McGuire of the USAAF competed for the top position. Both men were awarded the Medal of Honor.

McGuire was killed in air combat in January 1945 over the Philippines, after racking up 38 confirmed kills, making him the second-ranking American ace. Bong was rotated back to the United States as America’s ace of aces, after making 40 kills, becoming a test pilot. He was killed on 6 August 1945, the day the atomic bomb was dropped on Japan, when his P-80 Shooting Star jet fighter flamed out on takeoff.

Charles Lindbergh

The famed aviator Charles Lindbergh toured the South Pacific as a civilian contractor for United Aircraft Corporation, comparing and evaluating performance of single- and twin-engined fighters for Vought. He worked to improve range and load limits of the F4U Corsair, flying both routine and combat strafing missions in Corsairs alongside Marine pilots. In Hollandia, he attached himself to the 475th FG flying P-38s so that he could investigate the twin-engine fighter. Though new to the machine, he was instrumental in extending the range of the P-38 through improved throttle settings, or engine-leaning techniques, notably by reducing engine speed to 1,600 rpm, setting the carburetors for auto-lean and flying at 185 mph (298 km/h) indicated airspeed which reduced fuel consumption to 70 gal/h, about 2.6 mpg. This combination of settings had been considered dangerous; it was thought it would upset the fuel mixture and cause an explosion. Everywhere Lindbergh went in the South Pacific, he was accorded the normal preferential treatment of a visiting colonel, though he had resigned his Air Corps Reserve colonel’s commission three years before. While with the 475th, he held training classes and took part in a number of Army Air Corps combat missions. On 28 July 1944, Lindbergh shot down a Mitsubishi Ki-51 "Sonia" flown expertly by the veteran commander of 73rd Independent Flying Chutai, Imperial Japanese Army Captain Saburo Shimada. In an extended, twisting dogfight in which many of the participants ran out of ammunition, Shimada turned his aircraft directly toward Lindbergh who was just approaching the combat area. Lindbergh fired in a defensive reaction brought on by Shimada’s apparent head-on ramming attack. Hit by cannon and machine gun fire, the "Sonia’s" propeller visibly slowed, but Shimada held his course. Lindbergh pulled up at the last moment to avoid collision as the damaged "Sonia" went into a steep dive, hit the ocean and sank. Lindbergh’s wingman, ace Joseph E. "Fishkiller" Miller, Jr., had also scored hits on the "Sonia" after it had begun its fatal dive, but Miller was certain the kill credit was Lindbergh’s. The unofficial kill was not entered in the 475th’s war record. On 12 August 1944 Lindbergh left Hollandia to return to the United States.

Charles MacDonald

The seventh-ranking American ace, Charles H. MacDonald, flew a Lightning against the Japanese, scoring 27 kills in his famous aircraft, the Putt Putt Maru.

Robin Olds

Main article: Robin Olds

Robin Olds was the last P-38 ace in the Eighth Air Force and the last in the ETO. Flying a P-38J, he downed five German fighters on two separate missions over France and Germany. He subsequently transitioned to P-51s to make seven more kills. After World War II, he flew F-4 Phantom IIs in Vietnam, ending his career as brigadier general with 16 kills.

Clay Tice

A P-38 piloted by Clay Tice was the first American aircraft to land in Japan after VJ-Day, when he and his wingman set down on Nitagahara because his wingman was low on fuel.

Antoine de Saint-Exupéry

Noted aviation pioneer and writer Antoine de Saint-Exupéry vanished in a F-5B-1-LO, 42-68223, c/n 2734, of Groupe de Chasse II/33, out of Borgo-Porreta, Bastia, Corsica, a reconnaissance variant of the P-38, while on a flight over the Mediterranean, from Corsica to mainland France, on 31 July 1944. His health, both physical and mental (he was said to be intermittently subject to depression), had been deteriorating and there had been talk of taking him off flight status. There have been suggestions (although no proof to date) that this was a suicide rather than an aircraft failure or combat loss. In 2000, a French scuba diver found the wreckage of a Lightning in the Mediterranean off the coast of Marseille, and it was confirmed in April 2004 as Saint-Exupéry’s F-5B. No evidence of air combat was found. In March 2008, a former Luftwaffe pilot, Horst Rippert from Jagdgruppe 200, claimed to have shot down Saint-Exupéry.

Adrian Warburton

The RAF’s legendary photo-recon "ace", Wing Commander Adrian Warburton DSO DFC, was the pilot of a Lockheed P-38 borrowed from the USAAF that took off on 12 April 1944 to photograph targets in Germany. W/C Warburton failed to arrive at the rendezvous point and was never seen again. In 2003, his remains were recovered in Germany from his wrecked USAAF P-38 Lightning.

The Love Muscle

The Love Muscle

A few nice custom automotive mould images I found:

The Love Muscle
custom automotive mould
Image by Studio PCK
Concept for a modern, pro-touring style street custom van.
Sketch scanned and drawn in Illustrator as usual…
Vehicle is a ’72 Tradesman on a custom tube chassis with mid-mounted Viper V-10… Wheels are shoved outboard via widened quarters and fenders, top is chopped, body sectioned, doors lengthened, cargo door removed, wheel openings enlarged, vents added to roof for cooling and air intake… ‘Cuda tail lamps out back in molded panel….

Nomination 42 – Safety – Carbon Fiber Composite Roof Assembly
custom automotive mould
Image by spe.automotive
CARBON FIBER COMPOSITE ROOF ASSEMBLY
•OEM Make & Model: 2013MY Chrysler Group LLC SRT Viper® GTS supercar
•Tier Supplier/Processor: Plasan Carbon Composites
•Material Supplier / Toolmaker: Umeco plc/Cytec Industries (carbon fiber weave prepreg); Toray Carbon Fibers Americas, Inc. (unidirectional carbon fiber prepreg); Dow Automotive (structural adhesive) / Windsor Mold Group
•Material / Process: G83C T700S-24K carbon composite / Vacuum bag, autoclave cure
•Description: This carbon fiber composite roof assembly is a Class A part that is a key structural component of the vehicle. Layup orientation and thickness were custom tuned to meet various structural requirements of both part and vehicle. Complex layup of plies was enabled by a CAD-drive laser placement system, which directs the operator in positioning plies during layup of the prepreg kit. Structural rigidity was increased vs. aluminum or SMC while weight was significantly reduced.

Understanding the Growing Usage of Injection Mold Equipment in Recent Times

Understanding the Growing Usage of Injection Mold Equipment in Recent Times

Mold has been considered one of the most expensive methods to manufacture equipment including metals, glasses, elastomers and confections for the industrial application use. These days molding is a process that is very commonly used to meet the growing requirement of various injection mold equipment that is being used in multi-applications to create many things such as bottle caps, pocket combs, wire spools, parts of numerous musical instruments, chairs and tables etc. The one and only disadvantage of this overall process is the demand of heavy cost equipment investment, potentially high running costs, and the need to design moldable parts.

There are very few injection mold companies, which are majorly putting collective efforts to manufacture high end metallic parts by utilizing injection molding machines consist of a material hopper, an injection ram or screw-type plunger, and a heating unit. These are called presses in which the components are designed or carved. It will be rated by tonnage, which expresses the amount of clamping force that the machine can exert. This force keeps the mold closed during the injection process. In the competitive industry of mold equipments, Acme Disys is the company which is creating a niche by adopting innovative technologies and cost effective methods to carve or design parts for the metallic products. It’s an emerging mold making company which is promoting the use of most recent injection molding technology and systems, which can be integrated seamlessly into the machines. To grow with the industry norms and making products of high utility to create an image around the world with outstanding reliability, universal application and individually adaptable high-end technical solutions. The success story of the Acme Delhi and its products is the result, above all, of a sophisticated, modular design, which enables each user to adapt technology to their own individual requirements.

With repeatedly setting benchmarks by initiating precision in manufacturing systems and solutions for the specialized industry usage in mold making, most of the companies are rendering their key focus on producing extremely innovative quality parts registering superior design capabilities for various purposes. Injection moulding of plastic is also becoming integral with time to help various industries grow and materials such as polystyrene, nylon, polypropylene and polythene, which can be used in a process called injection moulding. These are thermoplastics – this means when they are heated and then pressured in a mould they can be formed into different shapes. For the companies which produce, quality management system is very crucial to produce standard and precise products. Essentially injection molding is used for create a variety of parts, like plastic milk cartons, containers, bottle caps, automotive dashboards, pocket combs, and most other plastic products available today. Injection molding is the most common method of part manufacture. Injection molding is a cyclic process that is an on-going activity for manufacturing parts for a number of purposes.

Acme Disys aims to be the best among the best in Mold manufacturing companies. For more information, visit- www.acmedisys.com