智能化母猪饲喂控制系统设计与试验

doi:10.13733/j.jcam.issn.2095-5553.2021.10.12

摘要/Abstract

摘要： 母猪饲喂是生猪养殖中极为重要的一部分,为提高母猪产仔率,设计一种智能化母猪饲喂控制系统,该系统基于嵌入式Linux,硬件设备包括Exynos4412母板、外围控制电路集成接口板以及传感器和执行机构,负责对母猪进行信息采集、定时定量下料下水并控制装置中猪的数量。软件主要由驱动程序与应用程序协同工作保持饲喂逻辑正常运行,服务器建立在云端,应用层通过调用SQlite-API完成与后台的实时数据同步,实现精细化饲喂。试验结果表明:控制系统下料误差小于3.6%,下水误差小于3.75%;能够实时监测猪只的体温信号,重复测温误差为±0.2℃,利于饲养员对母猪健康的管理。

关键词: 母猪饲喂, 智能控制, Linux, 驱动电路

Abstract: Sow feeding is a very important part of pig breeding. In order to improve the litter rate of sows, an intelligent sow feeding control system was designed. The design of the system was based on embedded Linux, and the hardware equipment included Exynos4412 motherboard, peripheral control circuit integrated interface board, sensors, and actuators, which were responsible for information collection of sows, timing, quantitative feeding and launching, and control of the number of pigs in the device. The software was mainly composed of drivers and applications working together to keep the feeding logic running normally. The server was built in the cloud, and the application layer completed realtime data synchronization with the background through calling SQLiteAPI to achieve fine feeding. The experimental results showed that the discharge error of the control system was less than 3.6%, and the discharge error was less than 3.75%. It could monitor the temperature signal of pigs in realtime, and the error of repeated temperature measurement was ±0.2 ℃, which is beneficial to the management of sow health.

Key words: feeding of sows, intelligent control, Linux, drive circuit

中图分类号:

S817.3

黄昊, 刘俊灵, 胡腾达, 石军锋, . 智能化母猪饲喂控制系统设计与试验[J]. 中国农机化学报, 2021, 42(10): 78-86.

Huang Hao, Liu Junling, Hu Tengda, Shi Junfeng. . Design and experiment of intelligent sow feeding control system[J]. Journal of Chinese Agricultural Mechanization, 2021, 42(10): 78-86.

参考文献

［１］　
朱增勇, 浦华. 新冠肺炎疫情对全球猪肉市场及中国猪肉贸易影响研究［J］. 价格理论与实践, 2020(4): 16-19.

Zhu Zengyong, Pu Hua. Study on the impact of COVID-19 on global pork market and chinas pork trade ［J］. Price: Theory & Practice, 2020(4): 16-19.

［2］　
占志, 李美琪, 季勇, 等. 非洲猪瘟对我国肉类价格波动的影响研究——基于PVAR模型的实证分析［J］. 中国农机化学报, 2021, 42(1): 173-178.

Zhan Zhi, Li Meiqi, Ji Yong, et al. Study on the influence of African swine fever on the fluctuation of meat prices in China: Empirical analysis based on PVAR model ［J］. Journal of Chinese Agricultural Mechanization, 2021, 42(1): 173-178.

［3］　
Benjamin M, Yik S. Precision livestock farming in swine welfare: A review for swine practitioners ［J］. Animals, 2019, 9(4): 133.

［4］　
Jasmund N V, Wellnitz A, Krommweh M S. Using passive infrared detectors to record group activity and activity in certain focus areas in fattening pigs ［J］. Animals, 2020, 10(5): 792.

［5］　
Angermann E, Raoult C, WenschDorendorf M, et al. Development of a groupadapted housing system for pregnant sows: A field study on performance and welfare aspects ［J］. Agriculture, 2021, 11(28): 1-15.

［6］　
陈冲, 刘星桥, 黄邵春, 等. 国内外家猪精细养殖研究进展［J］. 江苏农业科学, 2019, 47(6): 1-4.

［7］　
王京威. 基于4G网络的妊娠母猪精准饲喂远程监控系统设计［D］. 南昌: 南昌大学, 2020.

Wang Jingwei. Design of remote monitoring system for precise feeding of pregnant sows based on 4G network ［D］. Nanchang: Nanchang University, 2020.

［8］　
王衡, 赵宸瑜. 基于STM32的猪饲喂槽剩余量检测设备设计与实现［J］. 山西电子技术, 2020(1): 32-35.

Wang Heng, Zhao Chenyu. Design and implementation of the equipment for detecting the surplus of pig feeding trough based on STM32 ［J］. Shanxi Electronics Technology, 2020(1): 32-35.

［9］　
杨亮, 裴孟侠, 肖强, 等. 母猪发情监测装置的设计［J］. 现代农业装备, 2019, 40(5): 40-43.

Yang Liang, Pei Mengxia, Xiao Qiang, et al. Design of estrus monitoring device for sow ［J］. Modern Agricultural Equipments, 2019, 40(5): 40-43.

［10］　
杜虹, 沈谋, 张晓健. 基于1500以太网养猪场的智能饲喂控制系统的设计与实现［J］. 装备制造技术, 2020(1): 31-35.

Du Hong, Shen Mou, Zhang Xiaojian. Design and implementation of intelligent feeding control system based on S7-1500 Ethernet pig farm ［J］. Equipment Manufacturing Technology, 2020(1): 31-35.

［11］　
张泽峰. 母猪体温红外监测系统设计与实现［D］. 晋中: 山西农业大学, 2019.

Zhang Yifeng. Design and implementation of infrared monitoring system for sow body temperature ［D］. Jinzhong: Shanxi Agricultural University, 2019.

［12］　
潘松, 黎敏, 张凯, 等. 小猪饮水嘴密封性自动检测设备设计与试验［J］. 中国农机化学报, 2020, 41(9): 68-75.

Pan Song, Li Min, Zhang Kai, et al. Design and test of automatic testing equipment for the leakproofness of Piglets drinking water nozzle ［J］. Journal of Chinese Agricultural Mechanization, 2020, 41(9): 68-75.

［13］　
李喜武, 徐博, 袁月明. 自适应模糊PID算法仔猪床温度控制系统研究［J］. 中国农机化学报, 2020, 41(10): 48-53, 73.

Li Xiwu, Xu Bo, Yuan Yueming. Research on temperature control system of piglet bed based on adaptive fuzzy PID algorithm ［J］. Journal of Chinese Agricultural Mechanization, 2020, 41(10): 48-53, 73.

［14］　
谢露露. 智能化母猪饲养管理系统设计与研发［D］. 重庆: 西南大学, 2020.

Xie Lulu. Design and development of intelligent sow feeding management system ［D］. Chongqing: Southwest University, 2020.

［15］　
贾龙, 韩华, 王浚峰, 等. 浅谈薄膜太阳能电池在现代化猪场设计中的应用［J］. 家畜生态学报, 2015, 36(4): 69-73.

Jia Long, Han Hua, Wang Junfeng, et al. Application of thinfilm solar cells in modern pig farm designing ［J］. Acta Ecologae Animalis Domastici, 2015, 36(4): 69-73.

［16］　
刘俊灵, 石军锋. 智能母猪饲喂系统的高效可靠数据通信协议设计［J］. 中国农机化学报, 2020, 41(8): 185-190, 210.

Liu Junling, Shi Junfeng. Design of efficient and reliable data communication protocol for intelligent sows feeding system ［J］. Journal of Chinese Agricultural Mechanization, 2020, 41(8): 185-190, 210.

［17］　
赵昕, 郭恩全, 李小杰. LINUX系统下GPIB驱动优化设计与实现［J］. 计算机测量与控制, 2020, 28(3): 163-167.

Zhao Xin, Guo Enquan, Li Xiaojie. Design and implementation of GPIB driver optimal in LINUX system ［J］. Computer Measurement and Control, 2020, 28(3): 163-167.

［18］　
中国饲料成分及营养价值表（2019年第30版）［J］. 中国饲料, 2019(21): 30-35.

Tables of feed composition and nutritive in China (2019 thirty edition) ［J］. China Feed, 2019(21): 30-35.

［19］　
GB/T 39235—2020, 猪营养需要量［S］.

［20］　
王美芝, 安涛, 刘继军, 等. 智能饲喂器对哺乳母猪采食量体况和生产性能的影响［J］. 农业工程学报, 2019, 35(6): 190-197.

Wang Meizhi, An Tao, Liu Jijun, et al. Effect of intelligent feeder on feed intake, body condition and production performance of lactating sows ［J］. Transactions of the Chinese Society of Agricultural Engineering, 2019, 35(6): 190-197.

[1]	贾桃, 谭蓉, 赵倩, 王利春, 郭文忠. 我国设施生菜无土生产装备研究现状及展望[J]. 中国农机化学报, 2022, 43(2): 67-74.
[2]	张正中;谢方平;田立权;刘大为;王修善;李旭;. 国外谷物联合收割机脱粒分离系统发展现状与展望[J]. 中国农机化学报, 2021, 42(1): 20-29.
[3]	刘俊灵;石军锋;. 智能母猪饲喂系统的高效可靠数据通信协议设计[J]. 中国农机化学报, 2020, 41(8): 185-190+210.
[4]	崔中凯;张华;周进;邸志峰;王兴军;. 智能玉米籽粒联合收获机设计与试验[J]. 中国农机化学报, 2019, 40(9): 26-30.
[5]	唐兴隆;任桂英;李英奎;王虹;赵平;张生;. 优质水稻工厂化育秧关键技术研究[J]. 中国农机化学报, 2019, 40(6): 35-38.
[6]	王学良;范国强;李强;冯海明;沈典诰;. 大型履带式远程遥控圆盘开沟机的设计与试验[J]. 中国农机化学报, 2019, 40(4): 19-24+30.
[7]	赵进;张越;赵丽清;王士彪;李杰;. 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.