Andrzej Gołąbczak scite author profile

Observing the latest manufacturing processes, the following tendencies can be noted: the gain of the energetic efficiency and shortening of the processing time with parallel preservation of the dimensions tolerance, shape tolerance and outer layer quality of the processed workpiece. Also the possibilities of gaining efficiency by rising criteria for process parameters are limited. It is mainly observed in the processing of hard machinable materials like titanium alloys or sintered carbides. Problems related to poor machinability were revealed during the final manufacturing processes using abrasive grinding [1,2]. In this work the results which have been presented are related to the influence by selected electrical parameters of the Abrasive Electrodischarge Grinding (AEDG) on the surface layer temperature of machined samples, in comparison to conventional grinding. Also the change in temperature during the AEDG has been depicted. The basis of this work is similar to the investigations of the deep grinding of surfaces of the titanium alloy Ti6Al4V using CBN and a diamond grinding wheel. For the comparative evaluation of the conventional grinding and AEDG, measurements of the specific grinding energy, energy of the spark discharge and internal stresses in the surface layer have been used.

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Investigations of surface layer temperature and morphology of hard machinable materials used in aircraft industry during abrasive electrodischarge grinding process

Gołąbczak

Święcik

Gołąbczak

et al. 2018

Materialwissenschaft Werkst

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In this work the results related to the influence of selected electrical parameters of the abrasive electrodischarge grinding process on the surface layer temperature and morphology of machined samples in comparison to the conventional grinding method are presented. The basis of this work has been investigations of the deep grinding of surfaces of the samples made of titanium 5553 β, Inconel 617, Hastelloy X and magnesium AZ31 using a cubic boron nitride (CBN) grinding wheel with metallic binding agent. For the comparative evaluation of the conventional grinding and abrasive electrodischarge grinding, measurements of the specific grinding energy, temperature on the surface layer (at the contact of the grinding wheel‐workpiece) and geometric structure of the surface layer have been used.

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Studies of Electrodischarge and Electrochemical System for Dressing of Metal Bond Grinding Wheels

Gołąbczak

Kozak

2006

Proceedings of the Institution of Mechanical Engineers, Part B:

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In this paper the development of an effective hybrid electrodischarge and electrochemical profiling/dressing system is depicted. To realize the profiling of superhard grinding wheels, an innovative segmental tool electrode has been designed and tested. The principle of operating this system, the case for its realization, mathematical modelling, and experimental results concerning dressing of grinding wheels is discussed. The results of the investigation demonstrate the usefulness of a hybrid system for the profiling of superhard grinding wheels and the shaping macro- and micro-geometry of the cutting surface grinding wheel (CSGW).

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