Teqnora Fibre Crafts

Teqnora Fibre Crafts A Re-inforced Plastic Processing Industry All our fibreglass products are custom designed. These are self pigmented and available in wooden finishing too.

Fibreglass-reinforced plastic, or simply referred to as "FRP", is a composite material consisting of glass fibres embedded in a resin matrix. It is used commonly today in a variety of products and structures such as automobiles, airplanes, boats, and buildings. Bring us your ideas / designs / CAD files or talk to us about what you want manufactured. No matter what the situation, interior or exteri

or, Teqnora has the expertise to design, manufacture and install quality fibreglass products....

Our products are meticulously fabricated by keeping in view the latest market fashion and requirements. Due to their unique features they find wide application in wide areas. We combine our understanding of customer needs with our expertise in materials, process and technology to deliver solutions that replace traditional metals and woods. Our composite products offer superior performance characteristics, such as strength, durability and minimal weight....

18/10/2012
Our new textile mannequins base model 6" - 1A
22/09/2012

Our new textile mannequins base model 6" - 1A

NewsMcLaren Automotive launches 12C Spider03 July 201212 months since the MP4-12C first went on sale, McLaren Automotive...
04/07/2012

News
McLaren Automotive launches 12C Spider

03 July 2012

12 months since the MP4-12C first went on sale, McLaren Automotive announces its next high performance sports car, the 12C Spider, which is based on the same carbon fibre MonoCell chassis as the MP4-12C.

More information on this new addition to the McLaren Automotive range will be released in the next few days when ordering commences across the company’s network of retailers.

McLaren Automotive has launched a full range of high performance sports cars manufactured at the new McLaren Production Centre. The first model in the range is the MP4-12C. Other models and derivatives will join the 12C in this range, all of them inheriting the technology and know-how developed in Formula 1, with the main objectives being energy efficiency and high performance.

These aims are partly achieved by the one-piece moulded carbon chassis, using a new manufacturing process. All McLaren models are based on this technology.

http://teqnora.in
03/07/2012

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A Reinforced Plastic Processing Industry....Teqnora Fibre Crafts is an environmentally conscious, responsible company. We ensure that all aspects of the organisation have a minimum effect on the environment by adopting and implementing environmentally sensitive practices in all of our operations.

28/06/2012

News
Tissa and Victrex develop TIXPREF composite fabrics

27 June 2012

Victrex Polymer Solutions and Tissa Glasweberei AG have developed TIXPREF™ prepregs made out of unidirectional tapes formed from S2-glass or carbon fibres that have been impregnated with high performance VICTREX® PEEK polymer.

TIXPREF composite fabrics are claimed to drastically reduce the cycle time by up to 50% (more for thin walled parts) required for press forming the fabrics into composite parts.

TIXPREF, a trademark of Tissa Glasweberei AG, is said to offer numerous advantages, including excellent mechanical properties that result from the high fibre content of up to 65%. Being thermoplastic, TIXPREF fabrics have a higher damage tolerance when compared to thermoset-based fabrics, high fatigue strength and stiffness, and excellent integration of the fibre with the matrix, resulting in a longer lifetime for the composite part, plus a reduction in its structural weight.

The fabrics are also easy and safe to handle, and thus well suited for automated processes and out-of-autoclave manufacturing methods.

"These characteristics exploit the outstanding performance properties of VICTREX PEEK polymer," says Albert Vodermayer, European Composites Market Leader at Victrex Polymer Solutions, which is the sole manufacturer and supplier of VICTREX PEEK (polyether ether ketone) polymer worldwide.

"They include a service temperature of up to 260°C (500°F), high resistance to harsh chemicals and solvents, and exceptional wear resistance, to provide superior mechanical properties under both static and dynamic load conditions. Further, Tissa fabrics are environmentally friendly since VICTREX PEEK polymer is solvent-free and recyclable and being thermoplastic in nature they can be stored at ambient temperature eliminating the need for expensive cooling and storage costs."

Tissa, a weaver of fibreglass textiles, has also developed non-crimp fabrics (NCFs) using VICTREX PEEK polymer.

Tissa's flexible production techniques allow multiple combinations of fibres and matrices. The resulting composite fabrics are tailored for use in aerospace, and in industrial and medical applications that do not have complex shaped parts, such as flat structures and panels. By heating the prepregs and press forming for two to three minutes, a panel thickness of just 2 mm is said to be possible.

27/06/2012

News

Toho Tenax partners with Hindoostan Technical Fabrics to develop carbon fabrics for India

June 2012

Toho Tenax Co Ltd has announced a collaboration with Indian company Hindoostan Technical Fabrics Ltd to develop and market carbon fibre fabrics for India’s composite industry.

Toho Tenax is the core company of Japanese company Teijin Group’s carbon fibres and composites business. Hindoostan Technical Fabrics, Mumbai, is a manufacturer of carbon and aramid textiles, owned by textiles company Hindoostan Mills Ltd, part of the Thackersey Group.

This will be the first time Toho Tenax partners with a textile manufacturer in India’s carbon fibre sector.

Under the partnership, Toho Tenax will supply its Tenax carbon fibre to Hindoostan Technical Fabrics for weaving and processing into textiles. The two companies will jointly market products to manufacturers of composites.

The focus of the collaboration will be on the Indian composites industry, serving various industrial marktes, including transportation (including automotive, aerospace and rail), wind power; sports and leisure, medical equipment, construction and retrofitting, and electronics (such as computer and mobile phone housings).

Toho Tenax, which already supplies chopped carbon fibre in India, sees significant potential in the country's carbon fibre market. It says it is preparing to meet surging demand from various customers for highly valued intermediate material, including prepregs.

“The collaboration between Hindoostan Technical Fabrics, with its advanced textile technology and strong presence in the Indian market, and Toho Tenax, the world’s second largest carbon fibre maker with a proven track record in the global carbon fibre composite market, will enable us to quickly secure a stronger market position in India,” says Norio Kamei, president of Toho Tenax and head of the Teijin group’s carbon fibres and composites business.

“We aim to establish Tenax textile as a mainstream product in the fast-growing Indian composite market.”

India is one of the most strategic markets in Teijin group’s medium- to long-term growth plan.

We believe that India’s carbon fibre composite industry is in its infancy and has substantial growth potential. Our collaboration with Toho Tenax, an industry leader in carbon fibre technology, will play a pivotal role in providing users with high quality, customised and competitive carbon fibre fabrics with reliable supply and strong application support. Our goal is to use our expertise and experience to continuously develop innovative textile solutions in the field of high performance composites.

Sudhir Thackersey, Chairman, Hindoostan Technical Fabrics Ltd

27/06/2012

News
Quickstep opens new manufacturing facility

25 June 2012

Quickstep has opened its new manufacturing facility at Bankstown Airport, Sydney, Australia, which will supply composite components to aerospace companies Northrop Grumman Corporation and Lockheed Martin.

The Bankstown facility is Quickstep's new headquarters and comprises a 4000 m2 hangar with $15 million of the latest manufacturing equipment and infrastructure for the production of carbon fibre components, along with a 1250 m2 office. There is room for further expansion.

Quickstep has already commenced production on the first phase of commercial production of F-35 Lightning II Joint Strike Fighter (JSF) parts. This work is expected to generate up to $700 million over 20 years.

In March 2012, Quickstep was selected by Lockheed Martin to supply composite wing flaps for the C-130J Hercules military transport aircraft. This contract is valued at $75 million to $100 million to Quickstep over five years.

New JSF contract
Quickstep has also announced a second Long Term Agreement (LTA) with Northrop Grumman to manufacture parts for the international F-35 Lightning II Joint Strike Fighter (JSF) programme.

The LTA covers production of 'Group 2' JSF components until 2020, and follows the LTA signed in February 2011 for Group 1 JSF components, for which manufacturing is now underway.

Group 2 parts represent more complex aircraft components, including portions of the main F-35 structure and supports.

The first Purchase Order for Group 2 parts is expected to be received in July 2012.

20/06/2012

Fibersim helps SpaceX manufacture composite parts for Dragon spacecraft

June 2012
Siemens PLM Software

Space launch company SpaceX used Fibersim composites engineering software to reduce the time needed to design and manufacture composite parts for its Dragon spacecraft and Falcon rocket.

SpaceX, headquartered in Hawthorne, California, is a space transport company and developer of the Falcon launch vehicles and Dragon spacecraft. Following the retirement of NASA’s Space Shuttle Program, the Falcon 9 and Dragon system will initially take over delivery of cargo, and later astronauts, to the International Space Station.

In May 2012, the Dragon (unmanned) became the first commercial vehicle to dock with the International Space Station.

Adopting composite materials

For the better part of five decades, commercial access to space has been limited by the high cost of flight operations. However, Space Exploration Technologies Corp (SpaceX) has rewritten the rules of the game by adopting a new business model and cutting edge technologies to enhance reliability and reduce the cost of space access.

SpaceX’s Falcon Heavy (currently under development) will be the world’s most powerful rocket, with more than twice the payload-to-orbit capacity of the space shuttle, but at only one-third the cost. It is expected to be the first rocket to break the US$1000-per-lb-to-orbit barrier, less than a tenth as much as the NASA space shuttle.

One significant way SpaceX decided to enhance the performance of its Falcon rocket and Dragon capsule was by adopting advanced composite materials. As composites have received growing acceptance in a variety of industries, including aerospace, the space industry has taken note. SpaceX was no exception. It recognised that composites could significantly enhance performance by improving the strength-to-weight ratio of the materials used to construct its spacecraft.

Fibersim proves invaluable

Once that decision was made, SpaceX conducted an evaluation of available composites engineering solutions and decided that Siemens PLM Software’s Fibersim™ software was the best fit for its design and manufacturing environment.

“Based on our comparison, there was no question that Fibersim was definitely the best choice on the market for designing and manufacturing composite components to suit our needs,” says Kirk Matthes, SpaceX’s design manager.

SpaceX’s business model is derived from the philosophy that simplicity, low-cost and reliability can go hand in hand. By eliminating the traditional layers of management and subcontractors, the company has reduced costs while speeding decision making and delivery. Likewise, by keeping the vast majority of manufacturing in-house, SpaceX reduced costs, kept tighter control of quality, and ensured a tight feedback loop between the design and manufacturing teams.
And by concentrating on simple, proven designs with a primary focus on reliability, the company has reduced the costs associated with complex systems operating at the margin. Fibersim has proved invaluable within that paradigm.

“Time is always of the essence for us, so Fibersim’s proven ability to take us from art to part so rapidly was a critical consideration in our decision to purchase the software,” says Chris Thompson, vice president of structures engineering for SpaceX.

“But it is about more than just speed. Fibersim improves product quality by providing accurate engineering information to the manufacturing floor, which also helps the repeatability of the manufacturing process. This assures that parts fit when they come off the tool.”

Time savings

SpaceX has used Fibersim to design and manufacture a variety of composite parts on both the Falcon rocket and the Dragon capsule.
Fibersim is being used to develop production fibre placement diagrams and laser projection files. It is also used to assist with actual fibre placement for the spacecraft’s thermal protection system, including the heat shield, exterior panels, insulating layers on the rocket and spacecraft, and several panels around the nose cone and engines.

Fibersim is now being employed from the outset on all new composites projects and has enabled SpaceX to reduce the design-to-manufacturing time on composite parts, such as the 5 m fairing boattail panel by 71%, from seven days to two days.
For other designs, the generation of manufacturing data was reduced by 86%, from seven days to one day with the use of Fibersim.

These dramatic time savings mean that changes are processed more quickly, designs are updated more reliably and the overall process flows more smoothly.

SpaceX has used Fibersim to perform a variety of tasks – including creating designs, making flat patterns and working in conjunctionwith its finite element analysis software – and to create laser data.

“Fibersim enables us to work in parallel between design and manufacturing, which is very important to us since we’re such a fast-paced organisation,” notes Derek Lies, structural designer for composite panels used on the Dragon capsule.
“It definitely helped improve the collaboration between design and manufacturing. And we also found that Fibersim very nicely captured the vocabulary of composites and provided an intuitive workflow, which enables our people who aren’t trained in composites to get up and running very quickly.”

Strong support

As a newcomer to composites, SpaceX was also concerned about finding a software vendor that had significant composites experience so it could receive the necessary guidance and support as it embarked on working with new materials.

“Siemens PLM Software’s support is excellent,” says Matthes.
“Anytime we have a problem, we can send a model to the Siemens PLM Software’s technical consultant and he helps us get through the issue. Again, as a fast-paced organisation, we must continually be moving forward, and Siemens PLM Software’s responsiveness and expertise enables us to do just that.”

Siemens PLM Software also embeds the know-how derived from its years of experience in the composites industry to provide intuitive, easy-to-use features for the design of a variety of composite structures. The fact that this is 'baked in' to the software flattens the learning curve and makes the learning experience for new users fast and easy. This greatly aids in training new users who may not have deep experience in designing with composite materials.

Speeding ply definitions

Since most of the composite parts are not especially complicated, the Fibersim Composites Engineering Environment (CEE) has proven to be sufficient. However, certain sections of the launch vehicle are characterised by complex curvature, so SpaceX opted for Siemens PLM Software’s Advanced Composites Engineering Environment (ACEE) to design those parts.

ACEE exploits the inherent advantages of many different composite design methodologies – including structure-based, zone-based, and ply-based design – to enable efficient engineering of large, complex structural components and highly contoured composite skins.

Most importantly, it helps to address the changes that inevitably occur while developing a composite structure. Based upon inputs from analysis, manufacturing or further iterations of the design, the definition evolves to its final state. This can require frequent updates and changes, which are time-consuming without software created specifically for this process. ACEE is designed to meet this challenge and create a more straightforward process for managing design changes.

“ACEE provided a significant boost to our efforts to define or import laminate specifications and requirements quickly using a zone-based design methodology,” explains Matthes.
“It helped speed ply definition by dynamically generating zone transitions and ply boundaries using an offset profile.”

The ability to accelerate the process and make it more accurate enables SpaceX to proceed with heretofore unheard of speed and quality, setting new standards for designing and manufacturing composite spacecraft. ♦

Fibersim very nicely captured the vocabulary of composites and provided an intuitive workflow, which enables our people who aren’t trained in composites to get up and running very quickly.
Derek Lies, Structural Designer for Composite panels - Dragon Capsule, SpaceX

SpaceX and Fibersim

Business challenges

• Enhance the performance of the Falcon launch vehicle and Dragon capsule
• Leverage the full value of composites
• Increase speed to market of new space vehicles
• Find a software vendor with significant composites expertise to support initiatives
Keys to success
• Enhance speed to market by enabling concurrent workflow between design and manufacturing
• Improve product quality and repeatability by providing accurate information to the manufacturing floor
• Ensure rigorous deadlines are met through immediate access to technical support
Results
• Reduced time needed to design and manufacture composite parts by over 70%
• Measurably improved product quality
• Enhanced manufacturing best practices/process repeatability

20/06/2012

UK project to develop lower cost, lightweight composite vehicle structures

June 2012

A project called ACOMPLICE (Affordable COMPosites for LIghtweight Car StructurEs) aims to manufacture lightweight, lower cost composite automotive structures to meet demand for fuel-efficient vehicles which meet reduced emission targets.
The £1.5 million project is part-funded by the UK Technology Strategy Board's Collaborative Research and Development programme, following an open competition.
The project consortium is led by Umeco, with partners Aston Martin Lagonda, Delta Motorsport Ltd, ABB Robotics and Pentangle Engineering Services Ltd.

Over the next two years, ACOMPLICE aims to significantly reduce the cost of composite body-in-white vehicle structures for the mainstream automotive sector. The partners plan to develop pre-impregnated broad application materials suitable for robotic lamination and fast cure technologies.

ACOMPLICE proposes to demonstrate the developed technologies by manufacturing selected structural automotive parts.
Umeco’s role is to develop fast cure, highly-efficient prepregs, enabling the rapid robotic manipulation and placement of individual plies. Novel materials formatting and moulding techniques will also be developed in order to optimise component output rates.
Umeco’s DForm® prepreg technology will also be used in combination with rapid perform technology in order to facilitate the lamination of complex shaped geometries via automated processes.

Hybrid-electric aircraft has composite structureVolta Volare and its subsidiary Volt Aero Technologies recently launched...
20/06/2012

Hybrid-electric aircraft has composite structure


Volta Volare and its subsidiary Volt Aero Technologies recently launched their GT4 aircraft, which they claim is the world's first hybrid-electric, full-sized high performance private aircraft. It is constructed from carbon composite.

Every structural component of the 4-seat GT4 is constructed from carbon fibe composite. Volta Voltare, headquartered in Portland, Oregon, USA, says this makes the aircraft stable and agile, but also able to withstand tremendous loads, corrosion, weather and UV exposure over many years of service life.

10 Volta Volaré GT4 aircraft remain available for purchase in 2012, and only 36 are scheduled for production in 2013.

Volta Volare claims its EViation Drive System is the world's first hybrid-electric drive system in the field of aviation.

The launch price is US$495,000.

Hot Pressed Panel Tank. Capacity - 328000ltr
15/06/2012

Hot Pressed Panel Tank. Capacity - 328000ltr

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