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KCIThe minimization of error generation in machine tool spindle is important because high-speed and ultra-precision machining are extensively utilized in industrial fields. The thermal deformation of the machine tool spindle generated by the frictional h...
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RISS 인기검색어
https://www.riss.kr/link?id=A108463501
-
저자
Wonjun Bae (Pusan National University) ; Junghwan Kim (Korea Institute of Materials Science) ; Seungchan Cho (Korea Institute of Materials Science) ; 김양진 (부산대학교) ; 이상관 (한국재료연구원)
- 발행기관
- 학술지명
- 권호사항
-
발행연도
2022
-
작성언어
English
- 주제어
-
등재정보
KCI등재,SCIE,SCOPUS
-
자료형태
학술저널
-
수록면
2511-2520(10쪽)
- DOI식별코드
- 제공처
-
0
상세조회 -
0
다운로드
부가정보
다국어 초록 (Multilingual Abstract)
The minimization of error generation in machine tool spindle is important because high-speed and ultra-precision machining are extensively utilized in industrial fields. The thermal deformation of the machine tool spindle generated by the frictional heat between the outer and inner bearings can deteriorate the machining accuracy. In this study, a TiC-SUS431 composite was fabricated using the liquid pressing infiltration method to suppress thermal deformation, and its thermal properties were obtained by thermal characteristic tests. For the transient thermal analysis with finite element analysis, the parameters of the machine tool spindlebearing model were selected, and the boundary conditions were calculated. The temperature and thermal deformation of the analysis model were compared by applying SCM415 and TiCSUS431 to the material of the machine tool spindle and changing the rotation speed. From the analysis results, it was demonstrated that the TiC-SUS431 machine tool spindle can improve the machining accuracy by minimizing the spindle thermal deformation.
참고문헌 (Reference) 
1 A. T. Abbas, "Towards optimization of surface roughness and productivity aspects during high-speed machining of Ti-6Al-4V" 12 (12): 3749-, 2019
2 E. Uhlmann, "Thermal modeling of a high speed motor spindle" 1 : 313-318, 2012
3 J. Mayr, "Thermal issues in machine tools" 61 : 771-791, 2012
4 Y. Li, "Thermal error modeling of the spindle based on multiple variables for the precision machine tool" 72 : 1415-1427, 2014
5 B. Li, "Thermal error modeling of machine tool spindle based on the improved algorithm optimized BP neural network" 105 : 1497-1505, 2019
6 J. Yang, "Thermal error mode analysis and robust modeling for error compensation on a CNC turning center" 39 (39): 1367-1381, 1999
7 Z. C. Lin, "The building of spindle thermal displacement model of high speed machine center" 34 : 556-566, 2007
8 E. Miao, "Study on the effects of changes in temperature-sensitive points on thermal error compensation model for CNC machine tool" 97 : 50-59, 2015
9 C. Wu, "Spindle thermal error prediction approach based on thermal infrared images : a deep learning method" 59 : 67-80, 2021
10 H. Zhao, "Simulation of thermal behavior of a CNC machine tool spindle" 47 (47): 1003-1010, 2007
1 A. T. Abbas, "Towards optimization of surface roughness and productivity aspects during high-speed machining of Ti-6Al-4V" 12 (12): 3749-, 2019
2 E. Uhlmann, "Thermal modeling of a high speed motor spindle" 1 : 313-318, 2012
3 J. Mayr, "Thermal issues in machine tools" 61 : 771-791, 2012
4 Y. Li, "Thermal error modeling of the spindle based on multiple variables for the precision machine tool" 72 : 1415-1427, 2014
5 B. Li, "Thermal error modeling of machine tool spindle based on the improved algorithm optimized BP neural network" 105 : 1497-1505, 2019
6 J. Yang, "Thermal error mode analysis and robust modeling for error compensation on a CNC turning center" 39 (39): 1367-1381, 1999
7 Z. C. Lin, "The building of spindle thermal displacement model of high speed machine center" 34 : 556-566, 2007
8 E. Miao, "Study on the effects of changes in temperature-sensitive points on thermal error compensation model for CNC machine tool" 97 : 50-59, 2015
9 C. Wu, "Spindle thermal error prediction approach based on thermal infrared images : a deep learning method" 59 : 67-80, 2021
10 H. Zhao, "Simulation of thermal behavior of a CNC machine tool spindle" 47 (47): 1003-1010, 2007
11 C. Ma, "Simulation and experimental study on the thermally induced deformations of high-speed spindle system" 86 : 251-268, 2015
12 M. Weck, "Reduction and compensation of thermal errors in machine tools" 44 (44): 589-598, 1995
13 S. Xiang, "Modeling for spindle thermal error in machine tools based on mechanism analysis and thermal basic characteristics tests" 228 (228): 3381-3394, 2014
14 F. Li, "Evaluation of R404a single loop thermosyphon for shaft cooling in motorized spindle" 142 : 262-268, 2018
15 S. Cho, "Enhanced high-temperature compressive strength of TiC reinforced stainless steel matrix composites fabricated by liquid pressing infiltration process" 817 : 152714-, 2020
16 Y. H. Lee, "Effect of TiC particle size on high temperature oxidation behavior of TiC reinforced stainless steel" 480 : 951-955, 2019
17 Z. Ge, "Design of thermal error control system for high-speed motorized spindle based on thermal contraction of CFRP" 125 : 99-111, 2018
18 N. R. Oh, "Characterization of microstructure and tensile fracture behavior in a novel infiltrated TiC-steel composite" 112 : 123-127, 2016
19 Y. Li, "Axial thermal error compensation method for the spindle of a precision horizontal machining center" 2319-2323, 2012
20 E. Creighton, "Analysis of thermal errors in a high-speed micro-milling spindle" 50 (50): 386-393, 2010
21 K. Liu, "Analysis and prediction for spindle thermal bending deformations of a vertical milling machine" 16 (16): 1549-1558, 2020
22 M. Xu, "An improved thermal model for machine tool bearings" 47 (47): 53-62, 2007
23 Y. Li, "A review on spindle thermal error compensation in machine tools" 95 : 20-38, 2015
24 S. J. Zhang, "A review of machine-tool vibration and its influence upon surface generation in ultra-precision machining" 91 : 34-42, 2015
25 Z. Yan, "A new modeling method for thermal errors of motorized spindle based on the variation characteristics of spindle temperature field" 110 : 989-1000, 2020
26 S. N. Grama, "A model-based cooling strategy for motorized spindle to reduce thermal errors" 132 : 3-16, 2018
27 D. Kono, "A machine tool motorized spindle with hybrid structure of steel and carbon fiber composite" 68 (68): 389-392, 2019
28 이지안 ; 김동현 ; 이춘만, "A Study on the Thermal Characteristics and Experiments of High-Speed Spindle for Machine Tools" 한국정밀공학회 16 (16): 293-299, 2015
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