基于土壤负压原理、产品结构优化设计和信息感知、无线传输、微电子控制等先进技术,研发了适用于输配水管路的灌溉流量自调节阀新型样品,具有土壤实际水分状况感知采集、信息反馈和输水流量实时调节控制等复合功能。根据其工作原理和设计技术指标,通过室内试验对灌溉流量自调节阀进行指标测试和性能分析,结果表明:试制的DN25流量自调节阀样品的开度调节范围0~100%,在100~300 kPa供水压力下,流量自调节精准度达81%~99%,且控制灵敏度较高,阀片响应时间随着阀门开度增大而逐渐延长,单程启闭最长响应时间不足3 s,较好地实现了节水灌溉的流量精量调配功效,为流量自调节阀的进一步结构优化、性能改进和产品定型等提供技术依据。
Abstract
According the principle of soil negative pressure, product structure optimization design and utilizing advanced technologies such as information perception, wireless transmission, and microelectronic control, we have developed and assembled a new type of irrigation flow regulating valve suitable for water distribution pipes, with the actual soil water condition sensing collection, information feedback and real-time adjustment and control of water flow and other composite functions. According to its working principle and design technical indicators, the index test and performance analysis of the irrigation flow regulating valve were performed through indoor simulation tests. The results show that the opening range of the test DN25 flow regulating valve sample is 0~100%, under 100~300 kPa water supply pressure, the accuracy of flow adjustment is 81% -99%, and the control sensitivity is high. The response time of the valve blade gradually increases with the increase of the valve opening, and the maximum response time for one-way opening and closing is less than 3s. It not only achieve better flow precision allocation effect of water-saving irrigation, but also provides technical basis for further structural optimization, performance improvement, and product shaping of the flow control valve.
关键词
流量调节 /
自动 /
阀门 /
节水 /
精准灌溉
{{custom_keyword}} /
Key words
flow regulating /
auto /
valve /
water-saving /
precision irrigation
{{custom_keyword}} /
基金
“十三五”国家重点研发计划项目( 2016YFC0400202) ; 科技部科技伙伴计划项目( KY201702008) ; 运城学院博士科研项目( YQ-
2020003) 。
{{custom_fund}}
{{custom_sec.title}}
{{custom_sec.title}}
{{custom_sec.content}}
参考文献
[1]徐文静,王翔翔,施六林,等.中国节水灌溉技术现状与发展趋势研究[J].中国农学通报,2016,32(11):184-187.
[2]WANG F, KANG Y, LIU S, et al. Effects of soil matric potential on potato growth under drip irrigation in the North China Plain[J]. Agricultural Water Management, 2007(88):34-42.
[3]康跃虎, 王凤新, 刘士平, 等. 滴灌调控土壤水分对马铃薯生长的影响[J]. 农业工程学报,2004,20(2):66-72.
[4]李亚龙,崔远来,李远华,等.以土水势为灌溉指标的水稻节水灌溉研究[J].灌溉排水学报,2004(5):14-16,49.
[5]冯俊杰,仵峰,郭群善,等.自适应地下滴灌灌水器的设计开发[J].节水灌溉,2008(10):24-26,30.
[6]孙浩,李明思,李金山,等.滴头流量对桶栽棉花根系分布与耗水的影响[J].排灌机械工程学报,2014,32(10):906-913.
[7]冯俊杰,刘杨,蔡九茂,等.自动调流式滴头的内部流场数值模拟[J].节水灌溉,2017(9):88-93.
[8]孙锡铭,刘妍,袁湘月,等.节水灌溉设备研究现状[J].林业机械与木工设备,2014,42(3):11-14.
[9]袁颖华,顾晓峰,孙颖奇,等. 灌溉阀在应用中存在的问题及优化设计[J].中国农村水利水电,2017(6):14-17.
[10]樊铭京,吴德华,王爱军,等.低压管道灌溉系统中专用水力驱动控制阀的研究与应用[J].山东农业大学学报(自然科学版),2017,48(2):226-228.
[11]冯俊杰,翟国亮,邓忠,等.微灌过滤器用水压驱动反冲洗阀启闭机构的力学计算[J].农业机械学报,2007(12):212-214.
[12]王颖,张建煜,供水管网阀门调节的思路,《阀门调节技术在郑州市供水管网调度中的应用》[J].供水技术,2011(5):47-50.
[13]袁颖华,孙颖奇,苑宝玉,等. 一种用于灌溉隔膜阀的阀门状态反馈装置的设计与实现[J].中国农村水利水电,2016(11) : 130-132.
[14]中华人民共和国机械行业标准. JB/T 10674-2006,水力控制阀[S].中华人民共和国国家发展与改革委员会,2007.
[15]中华人民共和国水利行业标准.SL364-2015 土壤墒情监测规范[S]. 中华人民共和国水利部,2015.
[16]王吉星, 孙永远. 土壤水分监测传感器的分类与应用[J]. 水利信息化,2010(4):37-41.
[17]袁颖华,孙颖奇,吴秋明,等.新型节水灌溉低功耗自动控制阀的研究[J].中国农村水利水电,2015(6):95-98.
[18]孙锡铭闫海峰. 用于深海舱室排水的流量自适应阀门设计及流噪声分析[D].哈尔滨:哈尔滨工程大学,2016.
[19]孙颖奇,袁颖华,吴秋明,等.低功耗智能灌溉控制阀的研究[M]∥ 大数据时代的信息化建设,2015.
[20]冯俊杰,费良军,邓忠,等.自适应滴灌灌水器的水力性能试验[J].农业工程学报,2013,29(4):87-94.
PDF(575 KB)
