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工程设计学报
Chin J Eng Design  2023, Vol. 30 Issue (1): 39-47    DOI: 10.3785/j.issn.1006-754X.2023.00.008
Optimization Design     
Design and simulation optimization of motorized spindle cooling system
Yi LI1(),Guo-hua CHEN1,2(),Ming XIA1,Bo LI1,2
1.College of Mechanical Engineering, Hubei University of Arts and Science, Xiangyang 441053, China
2.XY-HUST Advanced Manufacturing Engineering Research Institute, Xiangyang 441000, China
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Abstract  

In order to solve the problem of poor cooling effect caused by complex internal temperature field of motorized spindle, a water cooler system for motorized spindle cooling was designed. According to the analysis results of the thermal characteristics of motorized spindle, a water cooler cooling scheme was proposed, the relevant heat transfer parameters were calculated, and the temperature?velocity control model for the motorized spindle was established. Then, the finite element simulation of fluid cooling for motorized spindle was carried out by ANSYS Fluent software, and the simulation results were verified by the motorized spindle cooling experiment. By comparing the simulation results and experimental results, it could be seen that the maximum temperature of the motorized spindle motor stator decreased by 60% and the deformation of the shaft decreased by 70% after cooling. The results show that the water cooler system has a good cooling effect on the motorized spindle, which can provide a certain reference for the research of active thermal control technology of high-precision machine tools.

Key wordsmotorized spindle      temperature field      water cooler system      finite element simulation     
Received: 30 May 2022      Published: 06 March 2023
CLC:  TH 133.2  
Corresponding Authors: Guo-hua CHEN     E-mail: trfmeliyi@163.com;59782071@163.com
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Yi LI
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Cite this article:

Yi LI,Guo-hua CHEN,Ming XIA,Bo LI. Design and simulation optimization of motorized spindle cooling system. Chin J Eng Design, 2023, 30(1): 39-47.

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https://www.zjujournals.com/gcsjxb/10.3785/j.issn.1006-754X.2023.00.008     OR     https://www.zjujournals.com/gcsjxb/Y2023/V30/I1/39


电主轴冷却系统设计与仿真优化

为解决电主轴因内部温度场复杂而造成冷却效果差的问题,设计了一种用于电主轴冷却的水冷机系统。根据电主轴热特性分析结果,提出了水冷机冷却方案,计算了相关的传热参数,并建立了电主轴温度?流速控制模型。然后,利用ANSYS Fluent软件对电主轴进行了流体冷却有限元仿真,并通过电主轴冷却实验对仿真结果进行了验证。通过对比仿真结果和实验结果可知,冷却后电主轴电机定子最高温度约下降了60%,转轴的形变量约降低了70%。结果表明:利用水冷机系统对电主轴进行冷却具有良好的冷却效果,这可为高精密机床主动热控制技术的研究提供一定的借鉴和参考。


关键词: 电主轴,  温度场,  水冷机系统,  有限元仿真 
Fig.1 Profile of motorized spindle
Fig.2 Schematic diagram of heat distribution and transfer of motorized spindle
Fig.3 Overall structure of water cooler system
Fig.4 Principle of multi-circuit liquid supply device
Fig.5 Design scheme of cooling channel of motorized spindle
几何尺寸前端流道中部流道后端流道
截面尺寸(L×H12×620×106×3
长度S1 5223 1291 124
Table 1 Geometric dimension of cooling channel of motorized spindle
技术参数数值
额定功率/kW7.5
额定电压/V380
额定电流/A17
额定频率/Hz545
最高扭矩/Nm4.4
最高转速/(r/min)16 000
Table 2 Main technical parameters of AMS-120 high-speed motorized spindle
零件与冷却介质材料

密度/

(kg/m3)

导热率/

[W/(m·K)]

比热容/

[J/(kg·K)]

转轴45号钢7.8560.5434
轴承GCr157.8330670
定子8.93401390
转子8.93401390
冷却介质10.5994 184
Table 3 Material parameters of motorized spindle simulation model
位置对流换热系数/[W/(m2·K)]
前端流道1 463.65~1 765.87
中部流道2 257.39~2 628.49
后端流道1 067.35~1 325.41
转轴端部8
Table 4 Heat transfer coefficient in motorized spindle
Fig.6 Distribution of temperature monitoring points of motorized spindle
Fig.7 Temperature and deformation nephogram of motorized spindle before cooling
Fig.8 Temperature and deformation nephogram of motorized spindle after cooling (before optimization of refrigeration parameters)
Fig. 9 Temperature and deformation nephogram of motorized spindle after cooling (after optimization of refrigeration parameters)
Fig.10 Temperature nephogram of main structure of motorized spindle after cooling
Fig.11 Temperature change of key structure monitoring points of motorized spindle
Fig.12 Temperature change of key part monitoring points motorized spindle
Fig.13 Motorized spindle cooling test site
Fig.14 Experimental results of temperature change of motorized spindle
Fig.15 Experimental results of rotating shaft elongation of motorized spindle
组别对比项前端轴承组电机后端轴承组
第1组仿真值38.9556.0038.50
实验值40.8056.6039.90
相对误差/%4.751.073.64
第2组仿真值24.9028.3424.23
实验值25.7329.0524.98
相对误差/%3.332.503.09
第3组仿真值21.1022.0021.90
实验值22.4023.5023.10
相对误差/%6.166.825.48
Table 5 Comparison of simulation results and experimental results of motorized spindle temperature
对比项第1组第2组第3组
相对误差/%3.644.836.25
仿真值0.1650.0620.048
实验值0.1710.0650.051
Table 6 Comparison of simulation results and experimental results of rotating shaft elongation of motorized spindle
[1]   GRAMA S N, MATHUR A, BADHE A N. A model-based cooling strategy for motorized spindle to reduce thermal errors[J]. International Journal of Machine Tools and Manufacture, 2018, 132: 3-16.
[2]   XIANG S T, YAO X D, DU Z C, et al. Dynamic linearization modeling approach for spindle thermal errors of machine tools[J]. Mechatronics, 2018, 53: 215-228.
[3]   YAN Z, TAO T, HOU R, et al. A new modeling method for thermal errors of motorized spindle based on the variation characteristics of spindle temperature field[J]. The International Journal of Advanced Manufacturing Technology, 2020, 110(3/4): 989-1000.
[4]   ZHANG L X, GONG W J, ZHANG K, et al. Thermal deformation prediction of high-speed motorized spindle based on biogeography optimization algorithm[J]. The International Journal of Advanced Manufacturing Technology, 2018, 97(5/8): 3141-3151.
[5]   ZHANG Y, WANG L F, ZHANG Y D, et al. Design and thermal characteristic analysis of motorized spindle cooling system[J]. Advances in Mechanical Engineering, 2021, 13(5): 1-14.
[6]   HE Q, ZHANG Y, YE J, et al. Thermal characteristics of high speed motorized spindle with helical water cooling channel[J]. Recent Patents on Mechanical Engineering, 2012, 5(1): 69-76.
[7]   LEI C L, RUI Z Y, ZHOU Y C. Simulation and analysis for cooling system of high-speed motorized spindle[J]. Advanced Materials Research, 2014, 945-949: 1677-1680.
[8]   TANG Y, JING X, LI W, et al. Analysis of influence of different convex structures on cooling effect of rectangular water channel of motorized spindle[J]. Applied Thermal Engineering, 2021, 198: 117478.
[9]   XIA C H, FU J G, LAI J T, et al. Conjugate heat transfer in fractal tree-like channels network heat sink for high-speed motorized spindle cooling[J]. Applied Thermal Engineering, 2015, 90: 1032-1042.
[10]   LI K Y, LUO W J, WEI S J. Machining accuracy enhancement of a machine tool by a cooling channel design for a built-in spindle[J]. Applied Sciences, 2020, 10(11): 3991.
[11]   MA C, YANG J, ZHAO L, et al. Simulation and experimental study on the thermally induced deformations of high-speed spindle system[J]. Applied Thermal Engineering, 2015, 86: 251-268.
[12]   MENG J, HE G F, HU G C, et al. Simulation and analysis on temperature field of bearingless high speed motorized spindle[J]. International Journal of Mechanical Engineering and Robotics Research, 2019, 8(3): 380-384.
[13]   BRECHER C, IHLENFELDT S, NEUS S, et al. Thermal condition monitoring of a motorized milling spindle[J]. Production Engineering, 2019, 13(5): 539-546.
[14]   LI F, GAO J, SHI X, et al. Experimental investigation of single loop thermosyphons utilized in motorized spindle shaft cooling[J]. Applied Thermal Engineering, 2018, 134: 229-237.
[15]   SHI X J, YIN B T, CHEN G Q, et al. Numerical study on two-phase flow and heat transfer characteristics of loop rotating heat pipe for cooling motorized spindle[J]. Applied Thermal Engineering, 2021, 192: 116927.
[16]   LIU J F, ZHANG P. Thermo-mechanical behavior analysis of motorized spindle based on a coupled model[J]. Advances in Mechanical Engineering, 2018, 10(1): 1-12.
[17]   ZHANG Y, WANG P, LIU T, et al. Active and intelligent control onto thermal behaviors of a motorized spindle unit[J]. The International Journal of Advanced Manufacturing Technology, 2018, 98(9/12): 3133-3146.
[18]   LIU T, LIU D, ZHANG Y, et al. Temperature detection based transient load/boundary condition calculations for spindle thermal simulation[J]. The International Journal of Advanced Manufacturing Technology, 2020, 108(1/2): 35-46.
[19]   LI K Y, LUO W J, ZENG Y R, et al. Increase in accuracy of a built-in spindle by adaptive cooling control with varied coolant volume and temperature[J]. Sensors and Materials, 2020, 32(11): 3689-3706.
[20]   CHIEN H, JANG Y. 3-D numerical and experimental analysis of a built-in motorized high-speed spindle with helical water cooling channel[J]. Applied Thermal Engineering, 2008, 28(17/18): 2327-2336.
[21]   孟令聪,李陈涛,余兵,等.基于热载荷优化修正的电主轴热特性分析方法[J].机械强度,2020,42(6):1445-1452.
MENG Ling-cong, LI Chen-tao, YU Bing, et al. Thermal characteristic analysis method of motorized spindle based on thermal load optimization correction[J]. Journal of Mechanical Strength, 2020, 42(6): 1445-1452.
[22]   芮执元,陈涛,雷春丽,等.基于CFX的高速电主轴水冷系统的仿真分析[J].机床与液压,2014,42(7):24-28. doi:10.3969/j.issn.1001-3881.2014.07.007
RUI Zhi-yuan, CHEN Tao, LEI Chun-li, et al. Simulation analysis for water cooling system of high-speed motorized spindle based on CFX[J]. Machine Tool & Hydraulics, 2014, 42(7): 24-28.
doi: 10.3969/j.issn.1001-3881.2014.07.007
[23]   焦宇琳.高速电主轴新型层板冷却水套的热特性研究[D].西安:西安理工大学,2020:12-13.
JIAO Yu-lin. Study on thermal characteristics of new laminated cooling water jacket for high-speed motorized spindle[D]. Xi’an: Xi’an University of Technology, 2020: 12-13.
[24]   CHEN N, ZHANG K, ZHANG L X, et al. Analysis on the effects of cooling water velocity on temperature rise of motorized spindle[J]. Applied Mechanics & Materials, 2014, 543-547: 68-71.
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