茶叶揉捻压力检测装置设计与试验

doi:10.13733/j.jcam.issn.2095-5553.2024.07.017

摘要/Abstract

摘要： 茶叶揉捻压力是影响茶叶揉捻品质的重要因素，对茶叶揉捻压力开展实时检测，是实现茶叶自动化加工的关键。在分析揉捻加压相关部件的受力情况与揉捻作用区域的分布基础上，运用SW-DAMS耦合仿真方法分析不同揉捻压力检测方法对应的感知传感器接触力学特性与作用力变化情况，对比优化出揉捻压力最佳检测点位于揉盖上端。确定压力传感器结构及量程，设计揉捻压力检测装置，完成压力校准及检测试验。结果表明：揉捻标准转速为45 r/min时，选用的环形压力感知传感器内部直径为32 mm、高度为20 mm，连接法兰高度为40 mm，压力输出精度达到0.1%，无超调现象；样机的生产率为65 kg/h，碎茶率为1%，动态压力数值随揉捻过程在3~35 N之间实时变化，能够满足自动化茶叶生产线对揉捻压力的检测要求。

关键词: 茶叶揉捻机, 揉捻压力, 压力检测, 运动仿真

Abstract: Tea rolling pressure is an important factor that affects the quality of tea rolling. Realtime detection of tea rolling pressure is the key to realize automatic tea processing. In this paper, based on the analysis of the force situation of the related components of the rolling pressure and the distribution of the rolling action area, the SW-DAMS coupling simulation method was used to analyze the contact mechanical characteristics and force changes of the sensing sensors corresponding to different rolling pressure detection methods, and the best detection point of the rolling pressure was located at the upper end of the gland. At the same time, the structure and measuring range of the pressure sensor were determined, and the rolling pressure detection device was designed to complete the pressure calibration and detection test. The results showed that when the standard rolling speed was 45 r/min, the selected annular pressure sensing sensor had an internal diameter of 32 mm, a height of 20 mm, connecting flange height 40 mm, a pressure output accuracy of 0.1%, and no overshoot. The productivity of the prototype was 65 kg/h, and the broken tea rate was 1%. The dynamic pressure changed in real time between 3-35 N with the rolling process, which could meet the requirements of automatic tea production line for testing the rolling pressure.

Key words: tea twisting machine, rolling pressure, pressure detection, motion simulation

中图分类号:

S225.2+9

张俊, 郑乐, 张富贵, 胡正军, 黄海松, 闫建伟, . 茶叶揉捻压力检测装置设计与试验[J]. 中国农机化学报, 2024, 45(7): 114-121.

Zhang Jun, Zheng Le, Zhang Fugui, , Hu Zhengjun, Huang Haisong, Yan Jianwei, . Design and experiment of the measuring device for the twisting pressure of tea twisting equipment [J]. Journal of Chinese Agricultural Mechanization, 2024, 45(7): 114-121.

参考文献

［1］　查传丽. 当前我国茶叶出口面临的问题分析及改善对策［J］. 现代商贸工业, 2022, 43(20): 51-52.
［2］　刘佳美. 数学建模在茶叶销售中的运用研究［J］. 福建茶叶, 2022, 44(8): 27-29.
［3］　安琪, 张莹, 肖明霁, 等. 中国茶叶检验发展概述［J］. 中国茶叶加工, 2022(2): 56-62.
An Qi, Zhang Ying, Xiao Mingji, et al. Development of tea inspection in China ［J］. China Tea Processing, 2022(2): 56-62.
［4］　肖宏儒. 绿茶加工设备的发展趋势［J］. 中国茶叶, 2006(3): 40-41.
［5］　周仁贵, 孙承业. 茶叶揉捻自动化的关键技术［J］. 中国茶叶, 2008(5): 13-15.
［6］　张哲, 牛智有. 揉捻过程中茶叶物理特性的变化规律［J］. 湖北农业科学, 2012, 51(13): 2767-2770.
Zhang Zhe, Niu Zhiyou. The variation law of physical properties of tea in the rolling process ［J］. Hubei Agricultural Sciences, 2012, 51(13): 2767-2770.
［7］　钟应富, 周正科, 佘小明, 等. 基于多台盘式揉捻机联合工作的PLC控制系统研发［J］. 西南农业学报, 2012, 25(3): 1085-1089.
Zhong Yingfu, Zhou Zhengke, She Xiaoming, et al. Development of PLCbased control system in multi discroller union work ［J］. Southwest China Journal of Agricultural Sciences, 2012, 25(3): 1085-1089.
［8］　韩志强, 刘晓婷. 步进电机PLC控制的研究设计［J］. 轻工机械, 2006(4): 114-115.
Han Zhiqiang, Liu Xiaoting. Research of PLC to the control of stepping motors ［J］. Light Industry Machinery, 2006(4): 114-115.
［9］　赵春芳, 严晓敏. 基于PLC的变频器控制在茶叶揉捻机中的应用［J］. 机床电器, 2010, 37(4): 29-30.
［10］　谭和平, 杨桩, 汤江文, 等. 基于PLC和步进伺服的茶叶揉捻压力柔性控制方法［J］. 中国测试, 2015, 41(2): 80-83.
Tan Heping, Yang Zhuang, Tang Jiangwen, et al. Flexible control method of tea rolling pressure based on PLC and stepping servo ［J］. China Measurement & Test, 2015, 41(2): 80-83.
［11］　徐海卫, 谢驰, 曹江萍, 等. 茶叶揉捻压力的优化调节控制研究［J］. 中国测试, 2015, 41(10): 112-116.
Xu Haiwei, Xie Chi, Cao Jiangping, et al. Research on the optimal regulation control of barreling pressure for the tea ［J］. China Measurement & Test, 2015, 41(10): 112-116.
［12］　许雪双. 绿茶生产线监控系统的设计与试验［D］. 合肥: 安徽农业大学, 2021.
［13］　Hu Jianjun, Lei Tingzhou, Xu Guangyin, et al. Experimental study of stress relaxation in the process of cold molding with straw ［J］. BioResources, 2009, 4(3): 1158.
［14］　Mani S, Tabil L G, Sokhansanj S. Effects of compressive force, particle size and moisture content on mechanical properties of biomass pellets from grasses ［J］. Biomass and Bioenergy, 2005, 30(7): 648-654.
［15］　Yao Yanping, Meng Wenjun, Kou Ziming. Study horizontal screw conveyors efficiency flat bottomed bins EDEM simulation ［J］. Sensors & Transducers, 2013, 159(11): 282-288.
［16］　Clemens F, Joachim K, Mathias U. Trends and potential of the market for combine harvesters in Germany ［J］. Machines, 2015, 3(4): 364-378.
［17］　张祖明, 张铭耀, 江子颖, 等. 自动化茶叶揉捻机的设计与实现［J］. 中国高新科技, 2018(1): 68-70.
［18］　赵进, 张越, 赵丽清, 等. 茶叶揉捻机组自动控制系统设计［J］. 中国农机化学报, 2019, 40(2): 140-144.
Zhao Jin, Zhang Yue, Zhao Liping, et al. Design of automatic control system for tea discroller ［J］. Journal of Chinese Agricultural Mechanization, 2019, 40(2): 140-144.
［19］　杨硕林, 李震, 李曰阳. 茶叶揉捻装置研究设计［J］. 农业装备与车辆工程, 2020, 58(9): 120-122.
Yang Shuolin, Li Zhen, Li Yueyang. Research and design of tea rolling device ［J］. Agricultural Equipment & Vehicle Engineering, 2019, 40(2): 140-144.
［20］　张开兴, 王文中, 吴昊, 等. 北方茶叶生产线揉捻机的设计优化与试验［J］. 中国农机化学报, 2019, 40(10): 117-122.
Zhang Kaixing, Wang Wenzhong, Wu Hao, et al. Design optimization and experiment of rolling machine for tea production line in North China ［J］. Journal of Chinese Agricultural Mechanization, 2019, 40(10): 117-122.
［21］　张开兴, 王文中, 赵秀艳, 等. 滚筒式茶叶热风复干机设计与试验［J］. 农业机械学报, 2020, 51(5): 377-386.
Zhang Kaixing, Wang Wenzhong, Zhao Xiuyan, et al. Design and experiment of drumtype hot air redryer for tea ［J］. Transactions of the Chinese Society for Agricultural Machinery, 2020, 51(5): 377-386.
［22］　张昆, 衣淑娟. 气吸滚筒式玉米排种器充种性能仿真与试验优化［J］. 农业机械学报, 2017, 48(7): 78-86.
Zhang Kun, Yi Shujuan. Simulation and experimental optimization on filling seeds performance of seed metering device with roller of airsuction ［J］. Transactions of the Chinese Society for Agricultural Machinery, 2017, 48(7): 78-86.
［23］　胡永光, 李建钢, 陆海燕, 等. 直径滚筒式茶鲜叶分级机设计与试验［J］. 农业机械学报, 2015, 46(S1): 116-121.
Hu Yongguang, Li Jiangang, Lu Haiyan, et al. Design and experiment of equantdiameter roller screening machine for fresh tea leaves ［J］. Transactions of the Chinese Society for Agricultural Machinery, 2015, 46(S1): 116-121.
［24］　Zhang G, Wei Y, Ju C, et al. Multiobjective optimization of vehicle handling and stability based on ADAMS ［J］. Mathematical Problems in Engineering, 2022.
［25］　舒彩霞, 曹士川, 廖宜涛, 等. 基于ADAMS的油菜割晒机顺向侧铺装置参数优化与试验［J］. 农业机械学报, 2022, 53(S2): 11-19, 38.
Shu Caixia, Cao Shichuan, Liao Yitao, et al. Parameter optimization and experiment of forward laying device for rape windrower based on ADAMS ［J］. Transactions of the Chinese Society for Agricultural Machinery, 2022, 53(S2): 11-19, 38.
［26］　李军. 如何科学选择压力传感器［J］. 工业计量, 2014, 24(2): 71.

[1]	杨家豪, 杜雅刚, 房欣, 周成. 甘蓝拔取输送装置设计与试验[J]. 中国农机化学报, 2024, 45(6): 32-36.
[2]	许斌星, 陈永生, 管春松, 於锋, 陈华. 韭菜收获机圆盘切割装置设计与试验[J]. 中国农机化学报, 2024, 45(2): 79-83.
[3]	何欢欢, 杨双平, 封伟. 导轨拉拔式红花采收装置设计与试验[J]. 中国农机化学报, 2024, 45(1): 42-48.
[4]	贾梦实, 张莲洁, 顿国强, 高嵩, 黄晓文, 王诗雨. 自走式草莓施药机设计与轨迹仿真可靠性分析[J]. 中国农机化学报, 2023, 44(7): 85-90.
[5]	王成军, 韩锰, 龚智强. 可变压捆室打捆机结构设计与仿真分析[J]. 中国农机化学报, 2022, 43(9): 1-6.
[6]	闫文彬;张克平;孙步功;张鹏;. 小型前悬挂双圆盘牧草收割机切割器仿真分析[J]. 中国农机化学报, 2019, 40(6): 21-25.
[7]	张开兴;王文中;吴昊;刘贤喜;赵秀艳;. 北方茶叶生产线揉捻机的设计优化与试验[J]. 中国农机化学报, 2019, 40(10): 117-122.