Friday, December 13, 2013

Airbus and MIT look to digital manufacturing to reduce aircraft construction costs

A lego play composite?? Damn cool.... :)

Source : http://www.reinforcedplastics.com/view/36097/airbus-and-mit-look-to-digital-manufacturing-to-reduce-aircraft-construction-costs/

Could composite aerospace structures be assembled much like snap-together building blocks rather than manufactured as large, expensive, one-piece parts? Under a new research agreement Airbus and the Massachusetts Institute of Technology (MIT) will explore the potential of digital manufacturing in aircraft construction.

Aircraft manufacturers are increasingly adopting composite materials to reduce aircraft weight and operating costs. Airbus' latest model, the A350 XWB, is over 50 wt% composite.
Current composite airframe manufacture involves the fabrication of large single-piece parts, an expensive process. (The fuselage of the A350 XWB, for example, is made up of a number of large composite panels which are then joined together.)
The digital material concepts being developed at MIT could lead to lighter weight structures and lower construction and assembly costs.

Composite materials

Airbus will work with MIT’s Center for Bits and Atoms (CBA), which has been developing new methods for manufacturing structures out of carbon fibre reinforced plastic (CFRP). 
CBA Director Neil Gershenfeld and his colleague Kenneth C. Cheung recently published a paper in the journal Science on Reversibly Assembled Cellular Composite Materials. This outlines the assembly of a 3D lattice of mass-produced CFRP parts with integrated mechanical interlocking connections. Cheung produced flat, cross-shaped composite pieces that were clipped into a cubic lattice of octahedral cells, a structure called a 'cuboct.'
The parts form a structure that is 10 times stiffer for a given weight than existing lightweight materials, according to the researchers. The structure can also be disassembled and reassembled easily – such as to repair damage. (The repair of the composite aircraft fuselages now entering service is a challenge facing the aerospace industry).
The individual composite parts can be mass-produced and MIT is developing a robot to assemble them into wings, aircraft fuselages, and other parts. Other applications such as bridge decks are also possible.

Advantages of 'digital composites'

The MIT technique allows much less material to carry a given load. This could reduce the weight of aircraft and other vehicles, which in turn would lower fuel use and operating costs.
The costs of construction and assembly would also be lower.
Unlike conventional composite materials, which tend to fail abruptly and at large scale when stressed to the breaking point, the modular system tends to fail incrementally, the researchers say. This makes it more reliable and easier to repair. 
The possibility of linking a number of parts introduces a new degree of design freedom into composite manufacturing. MIT has shown that by combining different part types, they can make 'morphing' structures with identical geometry but that bend in different ways in response to loads.
This means that instead of moving only at fixed joints, the wing of an aircraft could change shape.

Tuesday, December 10, 2013

Taper Scarf Removal : Not For Real Man


It is not an art at all. Just a lazy man's work. Although this is preferable in MRO industries, but the quality of the repaired structure already been compromised.

A few cons :

Not applicable to repairs of thick structures 
Some risk of damaging “good” structure within and outside the scarf area



The load designed for each layers of plies orientation is not connected perfectly anymore. It is just more or less, which is not up to the standard for aircraft industries.

For a real man out there, let's go for higher standard!





Composite Step Removal : The Forgotten Art


In composite repair, the removal plies process is the most unpleasant situation and could be hazardous due to dust from the removal. The best practice for this process is still the STEP REMOVAL.

Step removal is the standard requirement in aircraft industries especially for manufacturer. But, most of the MRO players prefer the taper scarf removal which is not very good in quality and load transfer designed for the current structure.



It is the race-against-time which in the end determine either step sanding or taper scarf is preferable.

Most probably, the step removal will be the forgotten art.

Video show of simple step removal using grinding process.

The quality different between step removal and taper scarf will vary greatly when the number of plies removed increases.

But, by using grinder for step removal at certain point can be very impossible to handle. This will limit the repair if the competency is not up to the level required.

The keyword here is 'Competency'.

See the example of 16 plies removal using special techniques from aircraft industries;


So, how to remove 16 plies of composite with this complex configuration?

The keywords here is 'Special Techniques'.

The secret of the forgotten art is safe with us.

The Aircraft Composite Repair Getting Harder and Complicated


It is just a matter of time before the composite repair getting more harder and complex. Until that time only a few can still follow the competency level required by the fast changing industries.

Metal type of repair may become obsolete or at least becoming less and less popular in the next 10-20 years  after this.

Most of the MRO's players prefer a simple composite repair techniques like wet layup and trying to avoid the use of advanced materials like prepreg applications due to high cost of MOQ, storage and short storage life issues.

By doing this, they just buying time before they realize they cannot catch the advanced repair techniques standard for high performance composite set by the manufacturer/OEM.

If this was right, in the nearer future, only manufacturer can repair the high performance composite type. The MRO players need to make collaboration with the manufacturer to set up an integrated Composite Repair Center approved eg by Boeing or Airbus in a region like South East Asia.

This smart collaboration will save money on the advanced facilities and materials and also save time in developing the competency of the people.

Compete or collaborate?

You decide.

Read an interesting news on Boeing concern about the composite repairs;

Boeing Dreamliner Composite Repairs Questioned By U.S. Watchdog

Boeing Co. (BA)’s new 787 Dreamliner, set to fly its first paying passengers next week, faces four “safety-related concerns” about repairs to the composites used for the fuselage and wings, a U.S. agency said.
A review of the Dreamliner, the first airliner built with carbon-fiber reinforced composite plastics instead of metal, was released Oct. 20 by the U.S. Government Accountability Office. The GAO identified four concerns: limited information on the behavior of airplane composite structures; technical issues with the materials’ unique properties; standards for repairs; and training and awareness.
The U.S. Federal Aviation Administration certified the 787 in August following 20 months of flight tests, after requiring that Boeing take extra steps to demonstrate its safety. The GAO was asked by three members of Congress to review the FAA’s certification process and planned oversight once the model enters service, and consulted experts on repair and maintenance.
“None of the experts believed these concerns posed extraordinary safety risks or were insurmountable,” the GAO said in its report. Still, while the FAA is taking action to address the matters, “until these composite airplanes enter service, it is unclear if these actions will be sufficient,” the report said.
The 250-seat Dreamliner uses the lighter-weight composites, new engines and the first all-electric system to help it fly farther with less fuel.

Charter Flight

Chicago-based Boeing delivered the plane last month to its first customer, Tokyo-based All Nippon Airways Co., more than three years late after Boeing struggled with the new materials and manufacturing processes. The Dreamliner is scheduled for a charter flight from Tokyo toHong Kong on Oct. 26 and will enter regular service the following week.
“Regardless of the materials we use, Boeing employs the same rigorous methods to deliver products that are safe for the flying public and efficient for airlines,” said Marc Birtel, a Boeing spokesman in Seattle. “Composite materials have been used in commercial airplanes for decades.
‘‘The concerns in the GAO report are limited to support activities,’’ which already are being addressed through an industrywide effort involving regulators, manufacturers, operators and maintenance and repair organizations, Birtel said.
Boeing has used composites for other airliners before, including the 777, though never for the whole fuselage and wings as in the 787.

Repairs Different

The Dreamliner’s fuselage is made of reinforced carbon fibers spun around a barrel mold and baked, so repairs will be handled differently than with traditional aircraft that are built of riveted aluminum panels.
‘‘The FAA conducts a rigorous certification process for every new airplane that ensures it meets the highest levels of safety, and the FAA has certified commercial aircraft that use composite materials for decades,’’ the agency said yesterday in a statement. ‘‘In addition to the extensive certification requirements, the FAA’s robust safety oversight system is designed to detect and correct any issues that may emerge during actual flight.’’
The GAO’s review was requested by Representative Eddie Bernice Johnson of Texas, Representative Donna Edwards of Maryland and Representative Jerry Costello of Illinois, all Democrats.
They wrote a letter to FAA Administrator Randy Babbitt on Oct. 20, asking that he explain what ‘‘practical and proactive’’ steps are being taken to ensure ‘‘robust oversight’’ of the 787’s maintenance and repair.

Training Personnel

As the model enters service, the FAA will need to train more personnel to deal with composites and certify more repair centers to handle work on the new planes, the GAO report said. Boeing has orders for about 800 of the 787s from carriers around the world, making it the company’s fastest-selling new plane ever.
‘‘Composite-built aircraft present opportunities as well as unique and complex challenges, and we need to make sure the FAA is addressing all of these challenges appropriately,” Johnson said yesterday in a statement.
All Nippon Airways’s first Dreamliner already suffered some slight surface damage to the engine cowling when it hit a passenger boarding bridge earlier this month, Flightglobal reported Oct. 19. The plane resumed regular flight tests with the carrier in Japan after the company did some checks, the trade publication said.

Friday, December 6, 2013

MRO Europe: Airbus cautious about bonded structural repairs on A350

It was an old articel but still worth to read..... OEMs VS MRO in Composite Repairs...

Source : http://www.flightglobal.com/news/articles/mro-europe-airbus-cautious-about-bonded-structural-repairs-on-a350-377511/

  MICHAEL GUBISCH LONDON
05:51 10 Oct 2012 
Source: 
Airbus wants to concentrate structural repair development for critical composite parts on the A350 to bolted repairs, as it views alternative bonded repairs as "too big a step" on primary load-bearing structures for the time being.
Frédéric Gaible, A350 structures engineer in the airframer's customer services engineering and maintenance division, says there will be "limited scope" for bonded repairs on the largely composite twinjet, as regulations do not allow for them "at this stage".
The focus will remain on repairs with bolt-on reinforcements, because the development of bonded repairs for critical parts in the outer fuselage and wing area, where in-service damage is likely to occur, would be "too big a step", he says.
Gaible made the comments during a discussion at the MRO Europe conference about the changing relationship between manufacturers and maintenance providers in regard to composite repairs.
Airbus views itself as the main source for structural repair development on its aircraft, while operators and MRO providers will implement the respective approved processes.
But MRO companies are calling for greater sharing of technical data to be able to develop their own repairs. James Kornberg, general manager for customer support, products and business development at Air France Industries' aerostructures unit, says it frequently discovers damage on aircraft "which the OEMs didn't know about".
He believes operational experience with the aircraft gives MRO providers an advantage over the airframers. While repairs on new-generation aircraft are becoming more difficult, competition between OEMs and MRO providers must continue, he says.
Arne Lewis, associate technical fellow for Boeing's 787 service engineering division, denies MRO providers are under threat from the OEMs. However, he warns that intellectual property will not be as freely available for new aircraft as on legacy models.

Friday, April 5, 2013

Monday, March 18, 2013

FUTURE AIRCRAFT ADVANCED MATERIAL


http://www.airbus.com/innovation/future-by-airbus/concept-planes/the-airbus-concept-cabin/future-technologies/
Bionic Structures

Future aircraft could be built using a bionic structure that mimics the bone structure of birds. Bone is both light and strong because its porous interior carries tension only where necessary, leaving space elsewhere. By using bionic structures, the fuselage has the strength it needs, but can also make the most of extra space where required. This not only reduces the aircraft's weight and fuel burn, but also makes it possible to add features like oversized doors for easier boarding and panoramic windows.
Biopolymer membrane

The cabin's bionic structure will be coated with a biopolymer membrane, which controls the amount of natural light, humidity and temperature, providing opacity or transparency on command and eliminating the need for windows. This smarter structure will make the aircraft lighter and more fuel-efficient while giving passengers 360 degree views of the skies. This will offer unparalleled, unobstructed views of the wonders of the five continents - where you will be able see the pyramids or the Eiffel Tower through the transparent walls of the aircraft.
Composite Materials

Future materials may not even be the materials we see and use today. 'Composite' materials will be used - new matter made of a combination of different materials. In the future materials may not even take a solid state, but could be a composition of fluid and gas for example!
Integrated Neural Network

The cabin electrical system can be compared to the human brain, with a network of intelligence pulsating through the cabin. This network will be absorbed into the structural materials, making the hundreds of kilometres of cables and wires found in today's aircraft a thing of the past. Known as 'Smart' materials they can perform numerous functions, recognising the passenger, so that you too are 'connected' to the plane.
Morphing Materials

Materials that change shape and return to their initial form, growing like the leaves of a plant, are a very real possibility. Morphing materials might be metals or polymers that have a 'memory'; or are covered with a 'skin' that will instigate a shape change. A memory is created using sensor and activator systems that give materials a certain level of artificial intelligence, allowing them to adapt to the passengers' needs.
Self-reliant Materials

Materials will be self-cleaning. Think of the leaves of a lotus plant, which water rolls off in beads, taking contaminants with it. Today, coatings inspired by this are used on the surfaces of cabin bathrooms. In the future they will be found on the fabric of seats and the carpets.

These intelligent materials could also be self-repairing, which is already used today in surface protection. Certain paints can seal a scratch by themselves, just as the human skin does. 
Ecological Materials

The future passenger cabin will be fully ecological. Fully recyclable plant fibres that can be grown to a custom shape will be sourced from responsible and sustainable practices.
3D Printing

Some of the elements in the cabin could be created using additive layer manufacturing, which is a bit like printing in 3D. The process repeatedly prints very thin layers of material on top of each other until the layers form a solid object in materials ranging from high-grade titanium alloys to glass and concrete. As well as making it simpler to produce very complex shapes, this form of production wastes a lot less material than cutting shapes out of bigger blocks. While this technique is already being tested for small aircraft parts today, in the future, its use could be widespread - not only in industry but in people's homes!
Holographic Technology

Scenes showing the destination, a city skyline or a tropical forest, will be projected onto the walls. A private cabin can reflect your bedroom at home, a business conference or even a zen garden, thanks to the projection of virtual decors. Holographic technology will have advanced to such a degree that the virtual world will be indistinguishable from the real.
Energy Harvesting

Smart energy solutions such as energy harvesting will be a part of the cabin environment. The body heat you give out will be collected by your seat or pod as you relax or sleep, and combined with energy collected from other sources, like solar panels, to fuel cabin appliances.

Saturday, March 16, 2013

Testimonial of Young Engineer - Astrium



25 year old Belgian/French Elise Debry works as a design engineer for Astrium, the space division of the EADS Group, in Les Mureaux near Paris. For the young professional the position is her first job after completing her studies in engineering.

My career start

My interest in EADS was first ignited during an internship at Astrium as part of my studies. During the last year of my engineering course, I specialised in space engineering. After that, an internship at Astrium, one of the main European space companies, was a natural next step. When deciding what offer to take, I had a choice between staying at EADS or working for the French Space Agency (CNES). I’ve chosen a position at Astrium Space Transportation because this company, as the prime contractor of Ariane 5, the European heavy launcher, offers a very broad spectrum of activities (from mechanical design to propulsion or software) and many career opportunities. Moreover, the international aspect of Astrium was very compelling. The reason why I decided to get involved in the aeronautics field was clear: ‘problem solving’ is the name of the game. And the bigger or more complex the problem, the more fun and gratification I get from solving it.

A truly thrilling job

I am currently working on the Ariane 5 E/S Galileo project. The goal is to adapt the Ariane 5 launcher (the vessel taking the payload into space) to launch Galileo satellites into orbit. These will be used for the future European Global Positioning System. Four Galileo satellites will be launched in one mission. This requires some modifications to the existing launcher, and particularly the development of a specific structure to carry the four satellites. My role as a design engineer on this project is to ensure the consistency of the development of primary structures of the launcher so that, once assembled, the different parts, also called Stages, result in a robust launcher able to sustain the loads and carry out its mission: carry satellites into space.

Ariane 5 is a truly European project. The various parts of the launcher are designed and built in several European countries. I especially like the international aspect of my job; working with German, French and Spanish people is really interesting. After starting out at Astrium, I found everything I wanted and more in the job description. When asked what the most important prerequisites for my job are, these are very clear to me: you need a critical mind, a great deal of creativity and global thinking. Every day brings new and different situations and challenges. You have to come up with answers that prove to be right and that are able to stand the test.

A typical working day

As my contribution is the design of the launcher, I have to take care of all sorts of aspects. Questions ranging from the most appropriate materials to choose to mathematical problem-solving are my daily business – but I’m not alone! As an engineer on a very complex project, I’m really part of the team.

I frequently have to analyse new or altered problems which arise as the project progresses, and I have to be able to find appropriate solutions, elaborate a strategy and justify my solutions to highly complex technical issues. Sometimes finding a solution seems to be like looking for a needle in a haystack – but that is precisely what makes the work so interesting.

Male vs. female?

Clearly I am working in an environment with fewer women than men – about 20 per-cent of the workforce at Astrium are women. But this gender imbalance is not new for me: this is what I have been used to since the beginning of my scientific studies (in mechanical engineering). However, things are changing slowly: there are more women engineers of my age now than there were a few decades ago.

I have always liked the cooperative team work element and the focus being clearly on the many problems to solve. Also, I have never felt under pressure or alienated by my minority position. Among engineers, gender issues seem to matter less than elsewhere. Engineers – men and women alike – are focused on technical problem solving.

Work-life balance

Astrium offers me many career options and also supports me in more ways than one. The Les Mureaux site has many sports facilities which we can avail of during lunchtime or after work. Such a break in the working day improves our feeling of well-being and helps our concentration and work performance. When I look at some of my colleagues, I see that they get full maternity/paternity support in the form of part-time work and home office options. That is a good and mutually beneficial choice for employee and employer as both sides profit from such a solution.

The space race

The thought of being part of a team that actually develops a launcher to put payloads into space is one of the most challenging aspects of my daily routine. Still after three years now, I love the thought that somewhere satellites can be put into space and serve their purpose because I helped to design the launcher in just the right way.

Live launch

Each time Ariane 5 takes off, I watch the launch from Kourou live on the Internet. The launch brings everything together in one single event. I enjoy being at the forefront of cutting-edge technical development in one of my favourite fields – space!

I’m looking forward to seeing the launcher version I am working on, Ariane 5 E/S Galileo, take off! Unfortunately, I will have to wait until the end of 2014. This is one of the disadvantages of working on space development projects. You have to be patient to see the concrete results!

No drawbacks?

Well, a truly hard challenge is that you cannot test-drive a launcher before it is put into space. It goes up or it does not. So you’d better get it right straight away. No second chance for a first impression. That is quite a credo for me. I guess it is really the problem solving part that I love most! 

Friday, March 8, 2013

Hentikan penswastaan pintu belakang GLC kepada Syed Mokhtar

Hanya sekadar berita dan tidak mewakili pandangan saya secara keseluruhannya- Awaneer

Sumber : http://www.keadilandaily.com

Saya sertakan surat Kementerian Kewangan Diperbadankan (MOF Incorporated atau MKD) bertarikh 30 Ogos 2012 kepada Datuk Wira Syed Ali Tan Sri Syed Abbas Alhabshee, Pengerusi Composites Technology Research Malaysia Sdn Bhd (CTRM).Rafizi Ramli
Surat itu menyampaikan keputusan MKD bertarikh 24 Ogos 2012 untuk melupuskan pegangan ekuiti sebanyak 96.8% di dalam CTRM kepada DRB-HICOM Defense Technologies Sdn Bhd, salah satu syarikat yang dikuasai oleh Tan Sri Syed Mokhtar Albukhary.
CTRM adalah syarikat Malaysia yang paling terkedepan dalam bidang pembuatan dan teknologi penerbangan (aerospace). Jumlah kontraknya dengan syarikat-syarikat penerbangan dan aerospace terkemuka dunia adalah berjumlah RM8.26 bilion di antara tempoh 2012 hingga 2017. Portfolio pelanggannya termasuklah syarikat-syarikat terbesar di dunia seperti Airbus, Eurocopter, Spirit UK dan Goodrich.
CTRM juga adalah salah sebuah syarikat milik kerajaan yang mempamerkan prestasi kewangan yang membanggakan, dengan keuntungan di peringkat kumpulan berjumlah RM13 juta (2010) dan RM11 juta (2011). Perolehan kumpulan CTRM juga meningkat dari RM256 juta (2010) kepada RM293 juta (2011).
Prestasi yang baik ini telah dipamerkan secara konsisten sejak lima tahun yang lalu.
Saya telah meneliti dokumen-dokumen yang diserahkan kepada saya oleh whistleblowers dan berpuas hati bahawa cubaan untuk menswastakan CTRM kepada Tan Sri Syed Mokhtar Albukhary ini dibuat dengan melanggar prosedur dan mengenepikan kebajikan kakitangan CTRM.
Syed Mokhtar bersama Najib
Syed Mokhtar bersama Najib
Saya khuatir ini juga sebahagian daripada proses pelupusan syarikat-syarikat milik kerajaan yang berprestasi baik (dengan kontrak yang dijamin dalam tempoh yang panjang di masa hadapan) kepada kroni sebagai langkah berjaga-jaga sekiranya Pakatan Rakyat mengambil alih Putrajaya kelak. Jika ini berterusan, banyak syarikat-syarikat yang berprestasi dan mempunyai aset besar dipindahmilik tanpa pengetahuan awam.
Sewajarnya sebarang proses penswastaan syarikat milik kerajaan perlu melalui proses tender terbuka dan mengambil kira pandangan pengurusan dan pekerja, lebih-lebih lagi yang melibatkan CTRM kerana ia dibina di atas keringat tenaga kerja professional tempatan yang bertungkus lumus menaikkan imejnya selama ini.
Saya mendesak supaya Datuk Seri Najib Tun Razak sebagai Menteri Kewangan menghentikan penjualan ini serta-merta. Saya juga melontarkan cabaran kepada Ketua Pemuda Umno, Saudara Khairy Jamaluddin untuk berani bersuara membela nasib kakitangan professional CTRM yangrata-ratanya professional Bumiputra dengan turut sama mendesak supaya urusniaga ini dihentikan.

Rafizi Ramli
Pengarah Strategi KEADILAN
Short URL: http://www.keadilandaily.com/?p=46807

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