Design and test of on-line checking device for electronic belt weigher

Authors

ZHANG Linfeng, College of Metrology & Measurement Engineering, China Jiliang University, Hangzhou, Zhejiang 310018, China
LIU Suijun, China Tobacco Henan Industrial Co., Ltd., Nanyang, Henan 473000, China
YANG Linchao, China Tobacco Henan Industrial Co., Ltd., Nanyang, Henan 473000, China
LIU Ying, China Tobacco Henan Industrial Co., Ltd., Nanyang, Henan 473000, ChinaFollow
HU Jiacheng, College of Metrology & Measurement Engineering, China Jiliang University, Hangzhou, Zhejiang 310018, China
CAI Jinhui, College of Metrology & Measurement Engineering, China Jiliang University, Hangzhou, Zhejiang 310018, China
SHEN Yinchu, College of Metrology & Measurement Engineering, China Jiliang University, Hangzhou, Zhejiang 310018, China
LI Shaohua, China Tobacco Henan Industrial Co., Ltd., Nanyang, Henan 473000, China
LI Qing, China Tobacco Henan Industrial Co., Ltd., Nanyang, Henan 473000, China

Corresponding Author(s)

刘颖（1991—），女，河南中烟工业有限责任公司南阳卷烟厂工程师，学士。E-mail:nyliuaj@qq.com

Abstract

Objective: In order to prevent the problem of small range electronic belt scale with inefficient method of traditional intermediate verification, low verification accuracy and security. Methods: A on-line intermediate check device was designed for small range electronic belt scale, which was composed of digital transmission control module and automatic loading module. Taking standard weight as input quantity, the upper computer controlled the manipulator to grab the weight onto the transmission belt to implement cyclic loading, then evaluated the measurement results and upload the evaluation results to the cloud. Results: After verification test and data analysis, for electronic belt weigher, it could ensure that the checking loading accuracy fluctuates within ±0.5% of the error range at two flow nodes of 1 440 kg/h and 3 600 kg/h. The remote control and loading process were stable, single verification test took about 3 minutes which was only one third of that of traditional methods. Conclusion: The download and upload of verification data are stable, cloud can monitor and warn the verification results in real time.

Publication Date

10-20-2023

First Page

84

Last Page

88

DOI

10.13652/j.spjx.1003.5788.2023.80108

Recommended Citation

Linfeng, ZHANG; Suijun, LIU; Linchao, YANG; Ying, LIU; Jiacheng, HU; Jinhui, CAI; Yinchu, SHEN; Shaohua, LI; and Qing, LI (2023) "Design and test of on-line checking device for electronic belt weigher," Food and Machinery: Vol. 39: Iss. 8, Article 13.
DOI: 10.13652/j.spjx.1003.5788.2023.80108
Available at: https://www.ifoodmm.cn/journal/vol39/iss8/13

References

[1] 余松青, 许峰, 沈伟, 等. 变角度电子皮带秤关键技术的研究[J]. 中国测试, 2017, 43（S1）: 90-95. YU S Q, XU F, SHEN W, et al. Research on the key technology of variable-angle electronic belt scale[J]. China Measurement & Testing Technology, 2017, 43（S1）: 90-95.
[2] 杨明花, 余松青, 陈慧云, 等. 电子皮带秤在线远程自动校验与诊断系统的研究[J]. 中国电力, 2016, 49（5）: 102-105. YANG M H, YU S Q, CHEN H Y, et al. Study on electronic belt scale online remote automatic testing and diagnosis system[J]. Electric Power, 2016, 49（5）: 102-105.
[3] 马志艳, 李翱翔, 段宇飞, 等. 基于机械臂的食物储藏室热缺陷检测系统[J]. 食品与机械, 2022, 38（6）: 106-111, 240. MA Z Y, LI A X, DUAN Y F, et al. Design of thermal defect detection system for food storage room based on robotic arm[J]. Food & Machinery, 2022, 38（6）: 106-111, 240.
[4] 王述诚, 申东滨, 肖芳远, 等. 电子皮带秤在维护校准时需注意的几个问题[J]. 工业计量, 2022, 32（5）: 79-82. WANG S C, SHEN D B, XIAO F Y, et al. Several problems needing attention in maintenance and calibration of electronic belt weigher[J]. Industrial Metrology, 2022, 32（5）: 79-82.
[5] 王晓光, 刘柯, 郭天茂, 等. 相对行程传感器高低温动态校准装置设计[J]. 中国测试, 2021, 47（S2）: 153-158. WANG X G, LIU K, GUO T M, et al. Design of high and low temperature dynamic calibration device for displacement sensor[J]. China Measurement & Testing Technology, 2021, 47（S2）: 153-158.
[6] 卢小犇, 翟琼劼, 屠淳, 等. 压电式动态力传感器校准方法的研究[J]. 振动与冲击, 2021, 40（5）: 261-265. LU X B, ZHAI Q J, TU C, et al. Calibration method of piezoelectric dynamic force sensor[J]. Journal of Vibration and Shock, 2021, 40（5）: 261-265.
[7] 马娟, 韦宣, 曹逢. 0.2级高精度智控矩阵电子皮带秤在火电厂的应用[J]. 工业计量, 2021, 31（4）: 8-12. MA J, WEI X, CAO F. Application of 0.2 level high precision intelligent control matrix electronic belt scale in thermal power plants[J]. Industrial Metrology, 2021, 31（4）: 8-12.
[8] 胡强. 定量皮带秤自动定量误差测定方法研究[J]. 中国测试, 2019, 45（6）: 60-64. HU Q. Research on measuring methods for auto-quantifying error of constant feeding belt weigher[J]. China Measurement & Testing Technology, 2019, 45（6）: 60-64.
[9] 范爱军. 电子皮带秤恒张力自动纠偏机构的设计[J]. 烟草科技, 2021, 54（5）: 90-94. FAN A J. Design of automatic adjustment mechanism for constant tension of electronic belt weigher[J]. Tobacco Science & Technology, 2021, 54（5）: 90-94.
[10] 胡强. 连续累计自动衡器动态物料试验控制衡器的研究和应用[J]. 计量学报, 2017, 38（S1）: 122-126. HU Q. Application and research of control scales for continuous totalizing automatic weighing instruments material testing[J]. Acta Metrologica Sinica, 2017, 38（S1）: 122-126.
[11] 颜敏, 邓如勇, 黄校春, 等. 电子皮带秤计量准确性方法研究与设计[J]. 自动化仪表, 2019, 40（1）: 67-69, 73. YAN M, DENG R Y, HUANG X C, et al. Research and design of measurement accuracy method for electronic belt scale[J]. Process Automation Instrumentation, 2019, 40（1）: 67-69, 73.
[12] 张晓凯. 电子皮带秤的应用与使用维护分析[J]. 仪器仪表标准化与计量, 2018（5）: 33-35. ZHANG X K. Application and maintenance analysis of electronic belt scale[J]. Instrument Standardization & Metrology, 2018（5）: 33-35.
[13] 陈小明, 李皎, 张一帆, 等. 基于上位机的层间角联锁织物用织机开口控制系统设计[J]. 纺织学报, 2022, 43（4）: 174-179. CHEN X M, LI J, ZHANG Y F, et al. Design of loom shedding control system for interlayer angle interlocking fabric based on use of host computer[J]. Journal of Textile Research, 2022, 43（4）: 174-179.
[14] 陈友东, 常石磊, 冯强国. 基于CPS方法的工业机器人系统[J]. 北京航空航天大学学报, 2018, 44（5）: 931-938. CHEN Y D, CHANG S L, FENG Q G. Industrial robot system based on CPS approach[J]. Journal of Beijing University of Aeronautics and Astronautics, 2018, 44（5）: 931-938.