液晶玻璃面板光学检测仪器气浮平台系统参数优化设计

doi:10.3969/j.issn.1000-1158.2019.06.09

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Abstract During the on-line detection of liquid crystal glass plates, the distribution of the pressure and the velocity in the gas film flow field are required to be gentle and the stability. In order to compare the effects of different air-floating platforms on the stability of the gas film, combined with the gas lubrication theory, the pressure distribution of the stable gas film was obtained. The through holes were generally arranged in an array on the air floating plate. Gambit was used to mesh the three-dimensional model of the air-floating platform, and then introduced into the Fluent software to simulate the positive pressure air supply mode and the positive and negative pressure air supply mode. The distribution of the air buoyancy and velocity were obtained under two different air supply modes. From the above analysis, if the remaining variables in the air-floating system remain unchanged, the advantages of positive and negative pressure at the same time of gas supply are more obvious, and the air buoyancy and velocity distribution are smooth after the gas film is stabilized, and the mass flow rate of the required gas is less than that of the positive pressure. Based on the above research, a glass substrate optical defect detection prototype was fabricated by positive and negative pressure simultaneous gas supply. The experimental results show that the change of film gap is less than 1μm and the stability is good.

Key words： metrology liquid crystal glass panel air bearing support gas supply mode Fluent simulation;

Received: 09 November 2018 Published: 10 October 2019

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TB96

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	Articles by authors
	ZHOU Yang
	LI Cheng-wei
	XU Xiao-bo
	ZHANG Yong
	HUANG Bin

Cite this article:

ZHOU Yang,LI Cheng-wei,XU Xiao-bo, et al. Parameter Optimization Design of Air-floating Platform System for Optical Testing Instrument of Liquid Crystal Glass Panel[J]. Acta Metrologica Sinica, 2019, 40(6): 994-999.

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http://jlxb.china-csm.org:81/Jwk_jlxb/EN/10.3969/j.issn.1000-1158.2019.06.09 OR http://jlxb.china-csm.org:81/Jwk_jlxb/EN/Y2019/V40/I6/994

［1］张占永, 袁凤玲, 胡鹏. 液晶玻璃基板表面及内部缺陷检测设备光学原理［J］. 四川建材, 2017, 43(5):142-144.
Zhang Z Y,Yuan F L,Hu P. The optical principle of inspection machinefor TFT-LCD glass surface and inner defects［J］. Sichuan Building Materials, 2017, 43(5) :142-144.
［2］黄斌, 余晓芬, 黄英, 等. 压力式气浮测力传感器静特性研究［J］. 计量学报, 2012, 33(1):31-34.
Huang B, Yu X F, Huang Y, et al. Study on the static characteristics of force floating measurement sensor based on pressure measurement［J］. Acta Metrologica Sinica, 2012, 33(1): 31-34.
［3］Huang B. A flexible tactile sensor calibration method based on an air-bearing six-dimensional force measurement platform［J］. Review of Scientific Instruments, 2015,86(7): 7075003.
［4］杜碧. 负压吸附式气浮平台运载单元的设计与优化［D］. 合肥:合肥工业大学, 2017.
［5］李国芹, 吕胜宾, 张鹏程. 基于Fluent的孔式静压径向气体轴承承载性能分析［J］. 轴承, 2011, (11):17-21.
Li G Q, Lü S B, Zhang P C. Analysis on load capacity of aerostatic radial bearings with orifice based on Fluent［J］. Bearing, 2011, (11):17-21.
［6］孙昂, 马文琦, 王祖温. 平面静压气浮轴承的超声速流场特性［J］.机械工程学报, 2010, 46(9):113-119.
Su A, Ma W Q, Wang Z W. Characteristics of subsonic velocity field of externally pressurized gas thrust bearings［J］. Journal of Mechanical Engineering, 2010,46(9):113-119.
［7］李陆军, 张鸣, 胡金春. 平面静压气浮轴承垂直微冲击的稳定性［J］. 清华大学学报, 2011, 51(6):851-856.
Li L J, Zhang M, Hu J C. Stability to vertical impulse perturbation of plane externally pressurize gas bearings［J］. Journal of Tsinghua University, 2011,51(6):
851-856.
［8］Lu L H, Gao Q, Chen W Q, et al. Investigation on the fluid-structure interaction effect of an aerostatic spindle and the influence of structural dimensions on its performance［J］. Proceedings of the Institution of Mechanical Engineers, 2017, 231(11): 1434-1440.
［9］Dal A, Karaay T. Effects of angular misalignment on the performance of rotor-bearing systems supported by externally pressurized air bearing［J］. Tribology Internationa, 2017,111:276-288.
［10］Wang C. Non-periodic and chaotic response of three-multilobe air bearing system［J］. Applied Mathematical Modelling, 2017,47:859-871.
［11］卢明臻, 高思田, 施玉书,等. 精密测量系统气浮工作台瞬态控制方法［J］. 计量学报,2008,29(4A):11-14.
Lu M Z, Gao S T, Shi Y S, et al. A method for transient control of the air bearing stage in a precision measurement system［J］. Acta Metrologica Sinica, 2008, 29(4A): 11-14.
［12］崔骊水,李鹏,邱丽荣,等. 微风速标准装置的建立和热线风速仪校准方法的实验研究［J］. 计量学报,2018,39(3):289-293.
Cui L S, Li P, Qiu L R, et al. Experiment Investigation on Calibration of Hot Wire Anemometer Based on Low Air Speed Reference Facility［J］. Acta Metrologica Sinica, 2018,39(3):289-293.
［13］刘强, 张从鹏. 直线电机驱动的H型气浮导轨运动平台［J］. 光学精密工程 , 2007, 15(10):1540-1546.
Liu Q, Zhang C P. H-type air-bearing motion stage driven by linear motors［J］. Optics and Precision Engineering, 2007,15(10):1540-1546.