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Experimental Investigation on Grinding Temperature of Ti–6Al–4 V Using Biomimetic Engineered Grinding Wheel

Ti–6Al–4 V is classed as difficult-to-process material due to its lower thermal conductivity and specific heat. Furthermore, the contact area between grinding wheel and workpiece is larger than other processing methods generally. Therefore, the process of grinding Ti–6Al–4 V is easier to generate hi...

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Published in:International journal of precision engineering and manufacturing-green technology 2019-04, Vol.6 (2), p.163-173
Main Authors: Yu, Haiyue, Lyu, Yushan, Wang, Jun
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Language:English
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description Ti–6Al–4 V is classed as difficult-to-process material due to its lower thermal conductivity and specific heat. Furthermore, the contact area between grinding wheel and workpiece is larger than other processing methods generally. Therefore, the process of grinding Ti–6Al–4 V is easier to generate high temperature. Most grinding fluid are used and wasted in usual grinding process to dissipate heat. Some green technologies are used to solve this issue in the aspect of fluid supply usually. This paper is to reduce grinding temperature from the other way–grinding wheel. In order to lower grinding temperature without increasing liquid coolant flow, an innovative grinding wheel inspired by phyllotaxis theory was manufactured using electroplating method and photo etching technique. Some contrastive experiments of grinding temperature for the alloy were conducted with the measured method of artificial thermocouple. The change rule of grinding temperature with the change of grinding parameters was found. The results shown that the grinding temperature of Ti–6Al–4 V with the biomimetic engineered grinding wheel was always the lowest in experiments due to less heat generation and more heat dissipation. Finally, the grinding temperature of the biomimetic engineered grinding wheels with different phyllotactic coefficient were investigated and discussed. A new point of view to lower grinding temperature was present and proved in this paper, which may become an important green technology for grinding in future.
doi_str_mv 10.1007/s40684-019-00050-3
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Furthermore, the contact area between grinding wheel and workpiece is larger than other processing methods generally. Therefore, the process of grinding Ti–6Al–4 V is easier to generate high temperature. Most grinding fluid are used and wasted in usual grinding process to dissipate heat. Some green technologies are used to solve this issue in the aspect of fluid supply usually. This paper is to reduce grinding temperature from the other way–grinding wheel. In order to lower grinding temperature without increasing liquid coolant flow, an innovative grinding wheel inspired by phyllotaxis theory was manufactured using electroplating method and photo etching technique. Some contrastive experiments of grinding temperature for the alloy were conducted with the measured method of artificial thermocouple. The change rule of grinding temperature with the change of grinding parameters was found. The results shown that the grinding temperature of Ti–6Al–4 V with the biomimetic engineered grinding wheel was always the lowest in experiments due to less heat generation and more heat dissipation. Finally, the grinding temperature of the biomimetic engineered grinding wheels with different phyllotactic coefficient were investigated and discussed. 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subjects Biomimetics
Ceramics industry
Clean technology
Deposition
Dissipation
Electron beams
Electroplating
Etching
Grinding wheels
Heat
Heat conductivity
Heat generation
Heat transfer
High speed machining
High temperature
Irradiation
Leaves
Lubricants & lubrication
Melting
Morphology
Plating
Post-production processing
Process parameters
Solid lubricants
Specific heat
Surface properties
Thermal conductivity
Thermocouples
Titanium
Titanium alloys
Vanadium
Wheels
Workpieces
title Experimental Investigation on Grinding Temperature of Ti–6Al–4 V Using Biomimetic Engineered Grinding Wheel
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