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The experimental testing equipment: (a) the ultra-depth-of-field microscope; (b) the white light interferometer.
Source publication
Surface topography parameters are an important factor affecting the wear resistance of parts, and topography parameters are affected by process parameters in order to explore the influence law of process parameters on surface topography parameters and to find the quantitative relationship between milling surface topography parameters and wear resis...
Contexts in source publication
Context 1
... experimental testing equipment used the ultra-depth-of-field microscope (KEYENCE company, Osaka, Japan) and Taylor Map CCI white light interferometer (Taylor Hobson company, Leicester, UK). Figure 4a is the ultra-depth-of-field microscope, and Figure 4b is Taylor Map CCI white light interferometer. Materials ...
Context 2
... cutting was used in the milling experiment. The experimental testing equipment used the ultra-depth-of-field microscope (KEYENCE company, Osaka, Japan) and Taylor Map CCI white light interferometer (Taylor Hobson company, Leicester, UK). Figure 4a is the ultra-depth-of-field microscope, and Figure 4b is Taylor Map CCI white light interferometer. Materials ...
Context 3
... experimental testing equipment used the ultra-depth-of-field microscope(KEYENCE company, Osaka, Japan) and Taylor Map CCI white light interferometer(Taylor Hobson company, Leicester, UK). Figure 4a is the ultra-depth-of-field microscope, and Figure 4b is Taylor Map CCI white light interferometer. ...
Context 4
... experimental testing equipment used the ultra-depth-of-field microscope(KEYENCE company, Osaka, Japan) and Taylor Map CCI white light interferometer(Taylor Hobson company, Leicester, UK). Figure 4a is the ultra-depth-of-field microscope, and Figure 4b is Taylor Map CCI white light interferometer. ...
Citations
... In order to obtain curve of the maximum value of the friction area of the tool flank with the increase of the cutting stroke, the maximum friction and wear width on the tool flank of the cutter tooth was measured by stopping the machine [12,13]. These studies ignored the information at different locations on the friction boundary of the milling cutter tooth [14,15]. As the same time, this method ignored the effect of dissipation of the thermal coupling field of the cutter teeth due to stopping measurements on the frictional behavior of the tool flank of the cutter teeth at different locations during long, uninterrupted cutting. ...
... Based on the above experimental results, the Eqs. (13) and (14) were used to solve for the instantaneous normal vector angle of the tool flank. The results are shown in Fig. 4. ...
The friction contact boundary between the tool flank of the milling cutter and the machining transition surface is important indicator to reveal the third deformation zone tool contact relationship and assessing the frictional wear performance of milling cutter. The existing models for friction boundary identification pay attention to the maximum width of accumulated friction and wear on the tool flank, ignoring the variability of the overall and local morphology of the friction boundary on the flank. Aimed at the influence of milling vibration on the instantaneous position of the cutter teeth and the machining transition surface, the solution and discrimination for the instantaneous position vector on the flank was proposed. Based on the mutagenicity of the instantaneous temperature and stress distribution, the influence of the instantaneous contact, extrusion, and deformation between the tool flank and the machined transition surface on the friction area was recognized. The calculation model of friction boundary of the flank was established. The irregularities of the distributions of the friction boundaries of the tool flank were revealed. The fractal recognition methods for instantaneous and cumulative friction boundary of the flank were proposed. And response was studied and verified with experiments. The results showed that it could effectively identify the irregular distribution of the friction boundary on the flank with the use of the above models. The formation and evolution of the friction boundary on the tool flank of the high-energy efficiency milling cutters were revealed.
... In order to obtain curve of the maximum value of the friction area of the tool flank with the increase of the cutting stroke, the maximum friction and wear width on the tool flank of the cutter tooth was measured by stopping the machine [12][13]. These studies ignored the information at different locations on the friction boundary of the milling cutter tooth [14][15]. As the same time, this method ignored the effect of dissipation of the thermal coupling field of the cutter teeth due to stopping measurements on the frictional behavior of the tool flank of the cutter teeth at different locations during long, uninterrupted cutting. ...
The friction contact boundary between the tool flank of the milling cutter and the machining transition surface is important indicator to reveal the third deformation zone tool contact relationship and assessing the frictional wear performance of milling cutter. The existing models for friction boundary identification pay attention to the maximum width of accumulated friction and wear on the tool flank, ignoring the variability of the overall and local morphology of the friction boundary on the flank. Aimed at the influence of milling vibration on the instantaneous position of the cutter teeth and the machining transition surface, the solution and discrimination for the instantaneous position vector on the flank was proposed. Based on the mutagenicity of the instantaneous temperature and stress distribution, the influence of the instantaneous contact, extrusion and deformation between the tool flank and the machined transition surface on the friction area was recognized. The calculation model of friction boundary of the flank was established. The irregularities of the distributions of the friction boundaries of the tool flank were revealed. The fractal recognition methods for instantaneous and cumulative friction boundary of the flank were proposed. And response was studied and verified with experiments. The results showed that it could effectively identify the irregular distribution of the friction boundary on the flank with the use of the above models. The formation and evolution of the friction boundary on the tool flank of the high-energy-efficiency milling cutters were revealed.
