Improvement of grinding technology with vortex cooling of steels that are liable to crack propagation

Author:

Ivanova Tatiana Nikolajevna1,Biały Witold2,Nordin Victor3

Affiliation:

1. Tchaikovsky branch of Federal State Budgetary Educational Institution of Higher Education “Perm National Research Polytechnic University” , Russia ; Federal State Budgetary Institution of Science “Udmurt Federal Research Center of the Ural Branch of the Russian Academy of Sciences“ , Russia

2. Silesian University of Technology , Poland

3. Kaliningrad State Technical University , Russia

Abstract

Abstract Complexity of grinding process and phenomena entailing it not always allow reaching required technological results, especially while machining surfaces of parts made of tough-to-machine steels, which are liable to crack propagation. Cracks can occur in these parts during grinding due to considerable temperature difference along the section, which can cause formation of high temporary internal tensile stress. Application of cooled air in grinding process exerts considerable influence over temperature decrease in cutting area. In addition, it depends not only on heat exchange, but also on properties of cold air flow. The greatest effect of temperature decrease can be reached by injection of cold air flow in cutting area with implementation of vortex effect, which occurs in swirl flow of compressed air originating in vortex tube. The study of heat generation during machining by tools with discontinuous cutting surface and vortex air cooling was carried out. Obtained thermophysical parameters of vortex air cooling (increase in speed of stream flowing, expansion degree, share of cold stream and decrease in humidity of air stream) allow reducing heat density due to growth of cooling effect in grinding zone. On the base of experimental studies we developed recommendations for choice of optimal grinding modes by tool with discontinuous cutting surface and vortex air cooling of flat parts made of steels being liable to cracking.

Publisher

Walter de Gruyter GmbH

Subject

General Chemical Engineering

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