茶园开沟施肥覆土一体机的设计与试验

doi:10.13733/j.jcam.issn.2095⁃5553.2022.03.004

摘要/Abstract

摘要： 针对丘陵山区茶园机械化较为落后，大型茶园管理机体积庞大、机动性欠佳、维护成本较高，小型茶园管理机动力不足、耕作深度不合格，设计符合丘陵山区茶园作业的开沟施肥覆土一体机。介绍机具的工作原理，对开沟部件、施肥机构、仿形陷深装置等关键部件进行设计，分析开沟刀具的设计和工作过程，确定满足工作的结构要求及满足农艺要求的施肥覆土；分析整机功耗和工作受力过程，确定满足山区工况的动力要求。田间试验结果表明，该机开沟沟深138~149.8 mm，平均沟深145.5 mm，开沟深度稳定系数90.07%~92.21%，平均耕深稳定系数91.1%；各段平均施肥量为21.6 g，施肥均匀性变异系数为3.4%，其关键性能参数均满足茶园农艺要求，设计方案较为合理，能稳定高效作业。

关键词: 茶园, 开沟, 施肥, 一体机, 茶园机械

Abstract: Tea plantations in hilly mountainous areas are plagued by underdeveloped mechanization techniques which present challenges relating to large tea garden management machines being bulky,having poor maneuverability and high maintenance costs. On the other hand, small tea garden management machines face challenges such as insufficient power and unqualified plowing depth. To this regard,an integrated machine for trenching,fertilizing and mulching in line with the operation of tea plantations in hilly mountainous areas was designed. The working principle of the machine was introduced, and the key components such as furrowing parts, fertilizer application mechanism and imitation trapping depth device were designed. The design and working process of the furrowing tool were analyzed to determine the structural requirements needed for effective fertilizer application and mulching as well as to meet the agronomic requirements. The power consumption and working mechanism of the whole machine were analyzed to determine the power requirements to meet the working conditions in mountainous areas. The field test results showed that the machine had an open furrow depth of 138-149.8 mm, with an average furrow depth of 145.5 mm, an open furrow depth stability coefficient of 90.07%-92.21%, and an average plowing depth stability coefficient of 91.1%.The average fertilizer application volume of each section was 21.6 g, the coefficient of variation of fertilizer uniformity was 3.4%, and all its key performance parameters met the agronomic requirements of tea plantations.The design scheme is reasonable and can operate stably and efficiently.

Key words: tea garden, trenching, fertilizer application, all?in?one machine, tea garden machinery

中图分类号:

S224.21

张海鹏, 林聪, 陈凌霄, 张培坤, 郑书河. 茶园开沟施肥覆土一体机的设计与试验[J]. 中国农机化学报, 2022, 43(3): 28-35.

Zhang Haipeng, Lin Cong, Chen Lingxiao, Zhang Peikun, Zheng Shuhe. . Design and analysis of an integrated machine for trenching, fertilizing and mulching in tea plantations[J]. Journal of Chinese Agricultural Mechanization, 2022, 43(3): 28-35.

参考文献

[1] 高峰, 徐四清. 茶园管理机械的发展现状[J]. 茶叶机械杂志, 2001(4): 13-14.
Gao Feng, Xu Siqing. The current status about machine for managing tea garden [J]. Journal of Tea Machinery, 2001(4): 13-14.
[2] 肖宏儒, 权启爱. 茶园作业机械化技术及装备研究[M]．北京：中国农业科学技术出版社, 2012.
[3] 韩余, 肖宏儒, 秦广明, 等. 我国茶园机械研究新动态[J]. 中国农机化学报, 2013, 34(3): 13-16.
Han Yu, Xiao Hongru, Qin Guangming, et al. Latest research situations and trends about tea garden machinery in China [J]. Journal of Chinese Agricultural Mechanization, 2013, 34(3): 13-16.
[4] 李明, 刘仲华, 罗江河, 等. 一种茶园多功能可调开沟施肥机[P]. 中国专利: 2011103151160, 2012-06-20.
[5] Li S T, Chen X B, Chen W, et al. Soil⁃cutting simulation and parameter optimization of handheld tiller’s rotary blade by smoothed particle hydrodynamics modeling and taguchi method [J]. Journal of Cleaner Production. 2018, 179: 55-62.
[6] Senanarong A, Wannaronk K. Design and development of an off⁃set rotary cultivator for use with a two⁃wheel tractor for fruit tree cultivation [J]. Agricultural Mechanization in Asia, Africa and Latin America, 2006, 37(4): 87-89.
[7] 易文裕, 余满江, 姚金霞, 等. 四川茶园机械化生产现状分析与对策研究[J]. 中国农机化学报, 2014, 35(5): 292-295.
Yi Wenyu, Yu Manjiang, Yao Jinxia, et al. Current situation analysis of mechanized production of tea plantation in Sichuan [J]. Journal of Chinese Agricultural Mechanization, 2014, 35(5): 292-295.
[8] 肖宏儒, 李建国, 秦广明, 等. 高地隙自走式多功能茶园管理机田间试验研究[J]. 中国农机化, 2010(6): 41-44.
Xiao Hongru, Li Jianguo, Qin Guangming, et al. Field experimental study on the high⁃clearance self⁃propelled multi⁃function tea farm manager [J]. Chinese Agricultural Mechanization, 2010(6): 41-44.
[10] 李坤, 肖宏儒, 梅松, 等. 低地隙茶园管理机齿耕与旋耕作业性能试验分析[J]. 中国农机化学报, 2015, 36(3): 18-21.
Li Kun, Xiao Hongru, Mei Song, et al. Performance test analysis of tooth tillage and rotary tillage on the low⁃clearance tea farm manager [J]. Journal of Chinese Agricultural Mechanization, 2015, 36(3): 18-21.
[11] 徐良, 周训谦, 肖洁. 3ZFC-40型茶园中耕机的研制[J]. 农产品加工（上半月）, 2015(6): 52-54, 58.
Xu Liang, Zhou Xunqian, Xiao Jie. Research of 3ZFC-40 cultivation machinery for tea garden [J]. Academic Periodical of Farm Products Processing, 2015(6): 52-54, 58.
[12] 夏瑞花, 吴董军, 蒙贺伟. 2FPG-40型葡萄开沟施肥机的设计与试验[J]. 中国农机化学报, 2018, 39(12): 36-40.
Xia Ruihua, Wu Dongjun, Meng Hewei. Design and experiment of 2FPG-40 grape ditching fertilizer combined machine [J]. Journal of Chinese Agricultural Mechanization, 2018, 39(12): 36-40.
[13] 陈平录, 许静, 翟因敏, 等. 丘陵山区低矮树型果园立式微耕机的设计与试验[J]. 机械设计与制造, 2021(2): 299-303.
Chen Pinglu, Xu Jing, Zhai Yinmin, et al. Design and experimental study of vertical micro⁃cultivator for low trees in hilly orchard [J]. Machinery Design & Manufacture, 2021(2): 299-303.
[14] 张欣悦, 李连豪, 汪春, 等. 1GSZ-350型灭茬旋耕联合整地机的设计与试验[J]. 农业工程学报, 2009, 25(5): 73-77.
Zhang Xinyue, Li Lianhao, Wang Chun, et al. Design and test of 1GSZ-350 stubble⁃breaking and rotary tilling combined cultivating machine [J]. Transactions of the Chinese Society of Agricultural Engineering, 2009, 25(5): 73-77.
[15] 贺小伟. 高茬秸秆旋耕翻埋功耗检测系统设计与试验研究[D]. 武汉: 华中农业大学, 2014.
He Xiaowei. Design and experimental study of power consumption measurement system for high stubble returning and tillage machine [D]. Wuhan: Huazhong Agricultural University, 2014.
[16] 李宝筏. 农业机械学[M]. 北京：中国农业出版社, 2003.
[17] 尤泳, 王德成, 王光辉. 9QP-830型草地破土切根机[J]. 农业机械学报, 2011, 42(10): 61-67.
You Yong, Wang Decheng, Wang Guanghui. 9QP-830 soil⁃gashing and root⁃cutting mechanism [J].Transactions of the Chinese Society for Agricultural Machinery, 2011, 42(10): 61-67.
[18] 李明喜, 陈功振. 旋耕机刀轴的模糊可靠性优化设计[J]. 农业机械学报, 2002(5): 131-133.
[19] 孙红. 基于SPH算法的果园开沟刀具土壤切削过程仿真及试验[J]. 中国农机化学报, 2019, 40(3): 190-194.
Sun Hong. Simulation and experimental study of soil cutting process by ditching component in orchard [J]. Journal of Chinese Agricultural Mechanization, 2019, 40(3): 190-194.
[20] 耿端阳, 张道林. 新编农业机械学[M]. 北京: 国防工业出版社, 2011.
[21] 丁为民, 王耀华, 彭嵩植. 正、反转旋耕刀性能分析及切土扭矩比较试验[J]. 南京农业大学学报, 2001(1): 113-117.
Ding Weimin, Wang Yaohua, Peng Songzhi. Comparison experiment and property analysis of up⁃cut and down⁃cut rotary blades [J]. Journal of Nanjing Agricultural University, 2001(1): 113-117.
[22] GB/T 5668.3—1995, 旋耕机械试验方法[S].
[23] GB/T 5262—2008, 农业机械试验条件测定方法的一般规定[S].

[1]	薛忠, 张秀梅, 陈如约, 王槊, 潘睿. 2ZBL-90双行菠萝种植机设计与试验[J]. 中国农机化学报, 2022, 43(6): 9-14.
[2]	李灿, 戴文涛, 程颖, 李君, . 果园便携式油动施肥器作业疲劳评价[J]. 中国农机化学报, 2022, 43(5): 40-46.
[3]	古冬冬, 关阳, 张征, 杨杰, 赵俊强, 范素香. 基于新能源技术的夏玉米穴施肥作业电控设计与试验[J]. 中国农机化学报, 2022, 43(5): 121-126.
[4]	刘玉荣, 贾双勤, 强生军, 段文霞. 钾肥在旱地马铃薯栽培技术中的应用研究[J]. 中国农机化学报, 2022, 43(2): 121-126.
[5]	胡辰, 方学良, 史扬杰. 稻田气力施肥装置设计与试验#br#[J]. 中国农机化学报, 2022, 43(1): 14-.
[6]	陈彬, 陈新华, 陈小兵, 朱继平, 于庆旭, 缪友谊, 刘燕. 履带自走式草莓旋耕起垄施肥复式作业机设计与试验[J]. 中国农机化学报, 2022, 43(1): 55-60.
[7]	王佳, 严伟, 纪要, 祁兵, 胡双燕, 张文毅, . 甘薯施肥施药机械研究现状及展望[J]. 中国农机化学报, 2021, 42(9): 68-76.
[8]	韩连杰;俞金金;金佳俊;谢东升;张居正;张瑞宏;. 无管式小麦播种机电控排肥装置设计与试验[J]. 中国农机化学报, 2021, 42(6): 27-34.
[9]	王永涛;刘坚;李家春;李继学;蔡家斌;. 并联四通道文丘里射流器吸肥结构优化与仿真[J]. 中国农机化学报, 2021, 42(6): 182-190.
[10]	张鲁云;何义川;杨怀君;汤智辉;郑炫;孟祥金;. 液体施肥机械发展现状与现代农业关系分析[J]. 中国农机化学报, 2021, 42(4): 34-40.
[11]	周馨曌, 坎杂, 蒙贺伟, 戚江涛, 赵旭洋, 李亚萍, . 果园开沟深度宽度监测装备设计与试验[J]. 中国农机化学报, 2021, 42(12): 37-43.
[12]	王文明;宋志禹;赵映;夏先飞;占才学;. 我国茶园中耕管理机械研究现状与发展分析[J]. 中国农机化学报, 2021, 42(1): 52-58+218.
[13]	何青海;郑磊;褚幼辉;窦青青;慈文亮;孙宜田;. 水肥一体化系统首部研究现状与展望[J]. 中国农机化学报, 2021, 42(1): 122-129.
[14]	张紫涵;张红梅;宋月鹏;任龙龙;范国强;许令峰;. 偏置阶梯刀盘式果园开沟机设计与试验[J]. 中国农机化学报, 2020, 41(9): 53-56+75.
[15]	潘敏睿;马军;王杰;张学敏;. 水肥一体化技术发展概述[J]. 中国农机化学报, 2020, 41(8): 204-210.