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For further details see our joint press release.
A new industrial 3D-weaving machine has been jointly developed by Biteam AB and Department of Lightweight Structures, KTH, Stockholm, under the European 6th Framework Project MOJO.
The 3D-weaving machine, based on the technology invented by Dr. Nandan Khokar, will be gradually employed to produce advanced and complex profiles.
This weaving development was supported by, among others, Outokumpu for the special steel needed for manufacturing certain parts and Festo for technical support with pneumatics. The machine’s design specifications were evolved to satisfy a number of customers’ requirements.
At the heart of the 3D-weaving technology is the dual-directional shedding operation. The method is highly flexible in that woven 3D profile materials in solid, shell, tubular and their combination types are directly producible using all kinds of fibres and fibre combinations. Materials such as electrical wires, slender tubes etc. can be also incorporated.
The 3D-weaving machine is designed to process a maximum of 3600 warp yarns in a 60 columns x 60 rows arrangement. Accordingly, 60 vertical wefts and 60 horizontal wefts can be inserted into the sheds of their respective directions. To produce a profile, only the necessary number of warp yarns are arranged and fed in accordance with the required profile’s cross-section and the dimensions. A sample of Double Flanged Box Beam produced by the machine was exhibited during the JEC Show in Paris.
Woven 3D profiled materials having cross-sections up to 120×120 mm and 3 m length can be produced directly. The machine’s ability to produce families of cross-sectional profiles of Pi, H, T, L, J and many more makes the 3D-weaving process highly versatile and relevant. Families of such fully unitised woven 3D profiled materials are increasingly required for manufacturing composite materials for structural applications.
Production of a series of woven profiles is under progress now for evaluating the machine and the woven profiled materials. There is a demand from many industries for these novel woven 3D profiles, not only because of their improved performance and producibility, but also for practically and economically speeding up engineering of lightweight structural constructions to meet the challenges of the present global environmental concerns.
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