农业工程学报
農業工程學報
농업공정학보
2015年
9期
100-106
,共7页
葛茂生%吴普特%朱德兰%巩兴晖
葛茂生%吳普特%硃德蘭%鞏興暉
갈무생%오보특%주덕란%공흥휘
喷头%灌溉%喷洒%相邻喷头%理论组合%实际叠加%喷洒特性
噴頭%灌溉%噴灑%相鄰噴頭%理論組閤%實際疊加%噴灑特性
분두%관개%분쇄%상린분두%이론조합%실제첩가%분쇄특성
nozzles%irrigation%spraying%adjacent sprinklers%Theoretical combination%Actual superposition%spray characteristic
相邻喷头喷洒重叠区域内的射流来自不同喷头,喷射过程中往往产生冲撞等相互作用。为研究组合喷头喷洒过程中相邻喷头间射流相互作用对组合喷洒特性造成的影响,选取Nelson D3000锯齿状喷盘喷头和R3000旋转式喷头,对其单独喷洒和以2.5 m组合间距进行喷洒时的水量分布以及雨滴谱信息进行了测试与比较。结果表明:喷头之间相互影响的强弱程度受喷头几何结构的影响,R3000喷头受组合喷洒时喷头间射流的影响作用不明显;Nelson D3000喷头(锯齿状喷盘)受组合喷洒时喷头间射流的影响作用剧烈,水量分布集中点的位置因射流轨迹的变化而产生偏移,喷灌强度最大点向靠近喷头侧偏移约0.5 m。组合喷洒条件下测点MP5处的降水强度、能量通量密度以及水滴数目较单独射流分别增长91.27%、107.58%和239.29%,其中粒径大于0.9 mm水滴数目的增加对该测点水量和能量提升的贡献率达到40.89%和58.83%。变异性分析结果表明水量和能量的重分布主要是由组合喷洒时增加了水滴之间相互碰撞的机率所引起。在Nelson D3000锯齿状喷盘喷头这类喷头进行水量叠加计算时,应考虑相邻喷头间水滴互相碰撞、结合或碎裂等相互作用对组合后的水量分布形式产生的影响,采用单喷头水量分布直接叠加的方法可能会导致计算精度较低。
相鄰噴頭噴灑重疊區域內的射流來自不同噴頭,噴射過程中往往產生遲撞等相互作用。為研究組閤噴頭噴灑過程中相鄰噴頭間射流相互作用對組閤噴灑特性造成的影響,選取Nelson D3000鋸齒狀噴盤噴頭和R3000鏇轉式噴頭,對其單獨噴灑和以2.5 m組閤間距進行噴灑時的水量分佈以及雨滴譜信息進行瞭測試與比較。結果錶明:噴頭之間相互影響的彊弱程度受噴頭幾何結構的影響,R3000噴頭受組閤噴灑時噴頭間射流的影響作用不明顯;Nelson D3000噴頭(鋸齒狀噴盤)受組閤噴灑時噴頭間射流的影響作用劇烈,水量分佈集中點的位置因射流軌跡的變化而產生偏移,噴灌彊度最大點嚮靠近噴頭側偏移約0.5 m。組閤噴灑條件下測點MP5處的降水彊度、能量通量密度以及水滴數目較單獨射流分彆增長91.27%、107.58%和239.29%,其中粒徑大于0.9 mm水滴數目的增加對該測點水量和能量提升的貢獻率達到40.89%和58.83%。變異性分析結果錶明水量和能量的重分佈主要是由組閤噴灑時增加瞭水滴之間相互踫撞的機率所引起。在Nelson D3000鋸齒狀噴盤噴頭這類噴頭進行水量疊加計算時,應攷慮相鄰噴頭間水滴互相踫撞、結閤或碎裂等相互作用對組閤後的水量分佈形式產生的影響,採用單噴頭水量分佈直接疊加的方法可能會導緻計算精度較低。
상린분두분쇄중첩구역내적사류래자불동분두,분사과정중왕왕산생충당등상호작용。위연구조합분두분쇄과정중상린분두간사류상호작용대조합분쇄특성조성적영향,선취Nelson D3000거치상분반분두화R3000선전식분두,대기단독분쇄화이2.5 m조합간거진행분쇄시적수량분포이급우적보신식진행료측시여비교。결과표명:분두지간상호영향적강약정도수분두궤하결구적영향,R3000분두수조합분쇄시분두간사류적영향작용불명현;Nelson D3000분두(거치상분반)수조합분쇄시분두간사류적영향작용극렬,수량분포집중점적위치인사류궤적적변화이산생편이,분관강도최대점향고근분두측편이약0.5 m。조합분쇄조건하측점MP5처적강수강도、능량통량밀도이급수적수목교단독사류분별증장91.27%、107.58%화239.29%,기중립경대우0.9 mm수적수목적증가대해측점수량화능량제승적공헌솔체도40.89%화58.83%。변이성분석결과표명수량화능량적중분포주요시유조합분쇄시증가료수적지간상호팽당적궤솔소인기。재Nelson D3000거치상분반분두저류분두진행수량첩가계산시,응고필상린분두간수적호상팽당、결합혹쇄렬등상호작용대조합후적수량분포형식산생적영향,채용단분두수량분포직접첩가적방법가능회도치계산정도교저。
Spray jets in the overlap region of adjacent sprinklers come from different applicators. Collisions and other interactions in the injection process are inevitable. However, the water distribution of a single sprinkler nozzle is always used to calculate the combination of sprinkler irrigation uniformity by giving an overlapping space due to the limitations of test site, sprinklers layout or other conditions. To study the effect of jets interaction on the overlapped spray characteristics between adjacent sprinklers, two different types of sprinklers were selected, namely, Nelson D3000 sprinkler with coarse jagged plate and Nelson R3000 rotating spray plate sprinkler. Water distribution pattern and droplets spectrum were measured and compared with the two nozzles spraying separately and simultaneously, with a combinatorial space of 2.5 m. The water distribution and raindrop spectrum of separately sprinkling were added together as theoretical combination (TC) while the simultaneously sprinkling was named actual superposition (AS). The results showed that the strength of interaction between sprinklers was influenced by geometry structure of nozzle. The influence of jets interaction on Nelson R3000 rotating spray plate sprinkler was not significant. In contrast, Nelson D3000 sprinkler with coarse jagged plate was severely affected by the effect of jets interaction, and the water application rate and kinetic energy had obvious redistribution along the radial direction. The location of precipitation concentrated points had an offset due to the change of jets trajectories and the point with maximum precipitation intensity moved 0.5 m closer to the sprinkler nozzle. At the measuring point of 2.5 m, the application rate, energy flux density and droplet number of AS increased by 91.27%, 107.58% and 239.29% when compared with TC. The increase of the number of droplet size grater than 0.9 mm showed great contribution to the water and energy rise at this measuring point, and the contribution rate reached 40.89% and 58.83%, respectively. Both the drop landing velocity and landing angle under AS condition were lower than that under TC condition. Under TC condition, the largest drop landing velocity and landing angle were 6.01 m/sand 75.38o while the values changed into 4.59 m/s and 63.91ounder the condition of AS. The droplets spectrum variability analysis of the overlapping region reflected that the redistribution of water application rate and kinetic energy was mainly due to the increasing probability of droplets collision when multi-sprinklers were spaced for irrigation. Water droplets changed original trajectories by the effect of external forces, and interacted with other droplets to form bigger size of drop or dispersed into a large number of tiny droplets. The strength of jets interaction should be considered when calculating the overlapped water application rate with a relatively small space, a direct superposition of single sprinkler water distribution might cause distortion of the results. This study on spraying hydraulic performance tests were carried out in fixed nozzle under indoor conditions, and further studies on multiple nozzles under mobile condition are needed to determine the impact of jet interaction on the spray characteristics.