|
|
Solution to Wall Thickness of Continuous Casting LadleBased on Laser Positioning and Ranging |
LIU Jun1,2,WU Xin-hua2,MENG Xian-wu2,FANG Jiang-xiong1,2,HOU Qing-ming2,ZHAO Peng2,YANG Feng1,2 |
1. Engineering Research Center of Nuclear Technology Application, Ministry of Education, East China University of Technology, Nanchang, Jiangxi 330013, China
2. School of Geophysics and Measurement-Control Technology, East China University of Technology, Nanchang, Jiangxi 330013, China |
|
|
Abstract A method to measure wall thickness of continuous casting ladle based on laser positioning and ranging is proposed. Firstly, positioning lasers are used to detect the spatial coordinates of the measured ladle. Secondly, the inner surface of the ladle is scanned by measuring laser driven by a rotary platform. According to the spatial coordinate transformation, the data of the measured points on the inner surface of the ladle are mapped to the wall thickness of the ladle. Finally, the thickness distribution of the inner wall of the ladle is obtained by comparing wall thickness with the standard initial data of the ladle. After test in the metallurgy filed, it shows that the method can measure the thickness of ladle wall accurately, the maximum measuring error is 5.2 mm, the minimal error is 2.6 mm, and the average error comes to 3.6 mm.
|
Received: 20 July 2018
Published: 10 June 2019
|
|
|
|
|
[1]潘贻芳, 吴燕, 侯葵, 等. 转炉炉衬激光测厚技术的应用及定量化[J]. 钢铁, 2013, 48(8): 29-33,54.
Pan Y F, Yan W U, Hou K, et al. Application of Thickness Measuring Technique by Laser on Converter Lining and Quantitative Research[J]. Iron & Steel, 2013, 48(8): 29-33,54.
[2]Zhao H X, Yuan Z F, Wu Y, et al. Study on Thickness Control and Quantitative of Converter Lining[J]. Applied Mechanics & Materials, 2013, 433-435: 2156-2163.
[3]Bonin M P, Harvill T L, Hoog J H. Apparatus, process, and system for monitoring the integrity of containers[P]: US, EP 8958058 B2. 2014.
[4]Schmitz J, Lamm R, Carlhoff C. System for measuring the inner space of a container and method of performing the same[P]: US, US8072613. 2011.
[5]Kleinloh J, Blissenbach D, Kirchhoff S, et al. Method for measuring wear in the refractory lining of a metallurgical melting vessel[P]: US, US7924438 B2. 2011.
[6]曹英杰, 张建良, 国宏伟等. 高炉炉墙内型厚度的计算[J]. 钢铁研究学报, 2015, 27(1): 7-11.
Cao Y J, Zhang J L, Guo H W, et al. Calculation of blast furnace inner wall thickness[J]. Journal of Iron & Steel Research, 2015, 27(1): 7-11.
[7]刘燃, 刘桥, 何健鹰. 基于WIFI的无线转炉激光测厚仪的设计与实现[J]. 仪表技术与传感器, 2012, (11): 61-63.
Liu R, Liu Q, Jian-Ying H E. Design and Implementation of Wireless Converter laser measure margin system Based on WIFI[J]. Instrument Technique & Sensor, 2012, (11): 61-63.
[8]Que Y H, Li S J, Liu Y L, et al. Application of Online Thickness Monitoring Technology of Blast Furnace Stack[J]. Advanced Materials Research, 2012, 562-564: 1796-1800.
[9]Isei Y, Honda T, Akahane K, et al. Development of refractory thickness meter for torpedo ladle car[C]// IMEKO.XIX IMEKO World Congress. Lisbon, Portugal, 2009:1948-1952.
[10]王金涛, 刘翔, 佟林, 等. 用于油库安全监控的立式储罐钢板变形激光测量方法[J]. 计量学报, 2018, 39(2): 217-221.
Wang J T, Liu X, Tong L, et al. Method of Deformation Measurement for Vertical Tank Based on 3D Laser Scanning Method for Production Safety Oil Depot[J]. Acta Metrologica Sinica, 2018, 39(2): 217-221.
[11]郝华东, 李存军, 刘瑛, 等. 基于激光扫描的立式金属罐容量计量方法[J]. 计量学报, 2018, 39(2): 222-227.
Hao H D, Cun-Jun L I, Liu Y, et al. Volume Measurement Method of Vertical Metal Tank Based on Laser Scanning[J]. Acta Metrologica Sinica,2018, 39(2): 222-227.
[12]Harvill T L, Bonin M P, Jensen S T. Automated positioning method for contouring measurements using a mobile range measurement system: US, US6922252[P]. 2005.
[13]Dresen D, Carlhoff C, Lamm R. Local positioning system for refractory lining measuring: US, US 20140140176 A1[P]. 2014.
[14]李培玉, 董月, 张志欣. 基于激光测距的炉衬测厚系统[J]. 钢铁研究学报, 2013, 25(10): 58-62.
Li P Y, Dong Y, Zhang Z X. Thickness measurement system of converter lining based on laser ranging[J]. Journal of Iron & Steel Research, 2013, 25(10): 58-62. |
|
|
|