Functional Approach to Development of Hybrid Technology of Cutting Diamond Carbides
Journal Title: International Journal of Bioprinting - Year 2018, Vol 2, Issue 1
Abstract
Background: Modern composite materials have a number of advantages in comparison with the traditionally used ones and allow implementing new methods of processing, which makes the finished product cheaper and makes its use more efficient. Objective: In order to improving the surface quality and productivity taken by A functional approach Method: A functional approach to the development of cutting technologies for Carbide and Super Hard Multilayered Composites is considered. It allows, by alternating the effects of different nature, to obtain qualitative edges, to lower the residual stresses in the surface layers, and to achieve a high surface quality. The essence of the approach is that the method of impact is determined on the basis of a morphological search of options for the execution of individual surface elements, each of which, combined into a set, uniquely forms the function of the finished product. The cutting is determined by a rational sequence of execution of technological transitions, provided that each harmful intermediate function at the finish stage turns into neutral or complements the required useful function. Results: Examples of figured cutting of plates from polycrystalline diamond-containing materials are given, the results of obtaining qualitative edges are shown. Conclusion: Thanks to the proposed technology based on the use of a functionally oriented approach, the functions of the tool for cutting are divided between the tool itself and the product part. As a result, the processing speed increases more than 3 times, and a high cut quality is achieved.
Authors and Affiliations
Salenko А. F. , Shchetinin V. Т. , Gabuzian G. V. , Nikitin V. А. , Klymenko S. А. , Potapov А. М. , Tanovic Lj
Keywords
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