农业工程学报
農業工程學報
농업공정학보
2015年
2期
37-44
,共8页
汤攀%李红%陈超%邹晨海%蒋跃
湯攀%李紅%陳超%鄒晨海%蔣躍
탕반%리홍%진초%추신해%장약
灌溉%喷头%压力%垂直摇臂式%运动规律%高速摄影%修正系数%喷灌均匀度
灌溉%噴頭%壓力%垂直搖臂式%運動規律%高速攝影%脩正繫數%噴灌均勻度
관개%분두%압력%수직요비식%운동규률%고속섭영%수정계수%분관균균도
irrigation%nozzle%pressure%vertical impact sprinkler%law of motion%high-speed photography%correction factor%irrigation uniformity
为了研究摇臂运动规律及配重对喷头水力性能的影响,以垂直摇臂式喷头为研究对象,对垂直摇臂式喷头摇臂的运动特征进行理论分析,推导出摇臂运动周期公式,并在公式中考虑了配重位置变化因素;采用高速摄影对 Nelson SR100喷头的摇臂运动情况进行了试验研究,将得出的摇臂运动周期与计算结果进行对比,并通过改变配重安装位置来考察运动周期变化对喷头水力性能的影响。结果表明:通过高速摄影试验得到的摇臂运动周期与理论公式计算值吻合较好,相对误差基本在10%以内,验证了推导公式的正确性,针对理论公式的计算误差,根据试验结果对理论进行了修正,进一步提高了理论公式的计算精度,相对误差都在3%以内;增大喷头工作压力和前移配重安装位置均可使喷头的运动周期减小。配重位置距摇臂旋转轴较近时,喷头近处的喷灌强度明显增加,3~10 m内的水量分布较配重在最远处时增加了40%左右;配重位置距摇臂旋转轴远时,喷头近处的喷灌强度随之降低,射程末端的喷灌强度随之增加。该研究可为垂直摇臂式喷头摇臂设计方法的建立和在喷头运行过程中能合理调节摇臂配重提供参考。
為瞭研究搖臂運動規律及配重對噴頭水力性能的影響,以垂直搖臂式噴頭為研究對象,對垂直搖臂式噴頭搖臂的運動特徵進行理論分析,推導齣搖臂運動週期公式,併在公式中攷慮瞭配重位置變化因素;採用高速攝影對 Nelson SR100噴頭的搖臂運動情況進行瞭試驗研究,將得齣的搖臂運動週期與計算結果進行對比,併通過改變配重安裝位置來攷察運動週期變化對噴頭水力性能的影響。結果錶明:通過高速攝影試驗得到的搖臂運動週期與理論公式計算值吻閤較好,相對誤差基本在10%以內,驗證瞭推導公式的正確性,針對理論公式的計算誤差,根據試驗結果對理論進行瞭脩正,進一步提高瞭理論公式的計算精度,相對誤差都在3%以內;增大噴頭工作壓力和前移配重安裝位置均可使噴頭的運動週期減小。配重位置距搖臂鏇轉軸較近時,噴頭近處的噴灌彊度明顯增加,3~10 m內的水量分佈較配重在最遠處時增加瞭40%左右;配重位置距搖臂鏇轉軸遠時,噴頭近處的噴灌彊度隨之降低,射程末耑的噴灌彊度隨之增加。該研究可為垂直搖臂式噴頭搖臂設計方法的建立和在噴頭運行過程中能閤理調節搖臂配重提供參攷。
위료연구요비운동규률급배중대분두수력성능적영향,이수직요비식분두위연구대상,대수직요비식분두요비적운동특정진행이론분석,추도출요비운동주기공식,병재공식중고필료배중위치변화인소;채용고속섭영대 Nelson SR100분두적요비운동정황진행료시험연구,장득출적요비운동주기여계산결과진행대비,병통과개변배중안장위치래고찰운동주기변화대분두수력성능적영향。결과표명:통과고속섭영시험득도적요비운동주기여이론공식계산치문합교호,상대오차기본재10%이내,험증료추도공식적정학성,침대이론공식적계산오차,근거시험결과대이론진행료수정,진일보제고료이론공식적계산정도,상대오차도재3%이내;증대분두공작압력화전이배중안장위치균가사분두적운동주기감소。배중위치거요비선전축교근시,분두근처적분관강도명현증가,3~10 m내적수량분포교배중재최원처시증가료40%좌우;배중위치거요비선전축원시,분두근처적분관강도수지강저,사정말단적분관강도수지증가。해연구가위수직요비식분두요비설계방법적건립화재분두운행과정중능합리조절요비배중제공삼고。
As a kind of advanced water-saving irrigation technology, sprinkler irrigation system is adaptable to many crops, soils, and topographic conditions. At present, the most representative and most widely used sprinkler of the high pressure sprinklers are vertical impact drive sprinkler. In order to study the arm movement law of the sprinkler and the influence of counterweight on the hydraulic performance of the sprinkler, with the vertical impact sprinkler as the research object, this paper analyzed the arm movement characteristics of the vertical impact sprinkler by use of theoretic and experimental methods. The arm movement model of the vertical impact sprinkler was established, and according to this model, the free and non-free arm movement times were deduced and then the calculation formula of arm movement period was obtained. In this calculation formula, the factor of counterweight position change was taken into account. The experimental study on the arm movement of Nelson SR100 sprinkler was made with high-speed photography, then the experimental results of arm movement period were compared with the theoretical values, and the effect of arm movement period change on the hydraulic performance of the sprinkler was studied by changing the counterweight installation positions. The results showed that: the free and non-free arm movement times both decreased with the increase of working pressure under the same counterweight installation position. The free arm movement time was considerably larger than the non-free arm movement time, and over 90% of one arm movement period was free movement. In the free movement period, the curve of the arm angular displacement approximated to a smooth semi-period sine curve with the change of time. The arm movement period values obtained through the experiment of high-speed photography well coincided with the calculated values, with most of the relative errors within 10%, which verified the accuracy of the theoretical period formula. In view of the calculation errors of the theoretical period formula, the theoretical period formula was corrected according to the experimental results, thus further improving the calculation accuracy of the theoretical period formula with all the relative errors within 3%. The maximum rotation angle of the arm increased with the increase of the distance between counterweight and arm rotational axis, which increased the arm movement period and decreased the frequency of breaking water jet. Under the same working pressure, the non-free arm movement time increased while the free arm movement time decreased with the decrease of the distance between counterweight and arm rotational axis. Within one arm movement period, the arm angular velocity approximated to a smooth semi-period sine curve with the change of time. The arm angular velocity and movement period were both related to the counterweight installation positions. The farther the counterweight installation position was from the arm rotational axis, the bigger the arm angular velocity and period values became. Both the increase of the sprinkler working pressure and the distance between counterweight and arm rotational axis could decrease the movement period of the sprinkler. When the distance between counterweight and arm rotational axis was short, the sprinkling irrigation intensity near the sprinkler obviously increased and the water distribution increased by about 40% within 3-10 meters; when the distance between counterweight and arm rotational axis was long, the sprinkling irrigation intensity near the sprinkler decreased correspondingly and the sprinkling irrigation intensity at the end of sprinkling irrigation increased correspondingly. The results can provide valuble information for the establishment of the arm design method of the vertical impact sprinkler as well as the reasonable adjustment of the arm counterweight installation position during the operational process.