农业工程学报
農業工程學報
농업공정학보
2015年
4期
76-84
,共9页
丁素明%薛新宇%兰玉彬%蔡晨%张玲%秦维彩%张宋超
丁素明%薛新宇%蘭玉彬%蔡晨%張玲%秦維綵%張宋超
정소명%설신우%란옥빈%채신%장령%진유채%장송초
风洞%设计%喷雾%植保%雾滴飘移%流场%流场品质
風洞%設計%噴霧%植保%霧滴飄移%流場%流場品質
풍동%설계%분무%식보%무적표이%류장%류장품질
wind tunnels%design%spraying%plant protection%droplet drift%quality of the flow field%flow quality
针对农药雾滴飘移特性研究的需要,依照流体力学、空气动力学及相似理论设计了 NJS-1型植保低速风洞。该风洞型式为直流闭口式,主要由进气段、动力段、过渡段、扩散段、稳定段、收缩段及试验段等部分组成,采用理论计算确定各段结构,风洞总体尺寸为20 m×2.7 m×4.3 m(长×宽×高);动力段流道型式为R+S级,叶轮直径1.2 m,叶片数为8,后导叶叶片宽度0.18 m,叶片数为7;扩散段为大角度扩散,扩散角40°;稳定段采用六角形蜂窝器和两层阻尼网组合设计;试验段长度为7.5 m,出口截面尺寸为1.8 m×1.2 m(高×宽)。通过性能试验测定了风洞试验段气流品质,试验结果表明:试验段风速1.0~10 m/s连续可调,气流动压稳定系数小于1.5%,气流紊流度小于1%;同时在1.0~9.0 m/s风速下测定试验段入口截面风场均匀性,表明随着风速的增加,风场的风速分布更加均匀。该文为进一步研究植保风洞的结构设计和飘移试验参数优化提供依据。
針對農藥霧滴飄移特性研究的需要,依照流體力學、空氣動力學及相似理論設計瞭 NJS-1型植保低速風洞。該風洞型式為直流閉口式,主要由進氣段、動力段、過渡段、擴散段、穩定段、收縮段及試驗段等部分組成,採用理論計算確定各段結構,風洞總體呎吋為20 m×2.7 m×4.3 m(長×寬×高);動力段流道型式為R+S級,葉輪直徑1.2 m,葉片數為8,後導葉葉片寬度0.18 m,葉片數為7;擴散段為大角度擴散,擴散角40°;穩定段採用六角形蜂窩器和兩層阻尼網組閤設計;試驗段長度為7.5 m,齣口截麵呎吋為1.8 m×1.2 m(高×寬)。通過性能試驗測定瞭風洞試驗段氣流品質,試驗結果錶明:試驗段風速1.0~10 m/s連續可調,氣流動壓穩定繫數小于1.5%,氣流紊流度小于1%;同時在1.0~9.0 m/s風速下測定試驗段入口截麵風場均勻性,錶明隨著風速的增加,風場的風速分佈更加均勻。該文為進一步研究植保風洞的結構設計和飄移試驗參數優化提供依據。
침대농약무적표이특성연구적수요,의조류체역학、공기동역학급상사이론설계료 NJS-1형식보저속풍동。해풍동형식위직류폐구식,주요유진기단、동력단、과도단、확산단、은정단、수축단급시험단등부분조성,채용이론계산학정각단결구,풍동총체척촌위20 m×2.7 m×4.3 m(장×관×고);동력단류도형식위R+S급,협륜직경1.2 m,협편수위8,후도협협편관도0.18 m,협편수위7;확산단위대각도확산,확산각40°;은정단채용륙각형봉와기화량층조니망조합설계;시험단장도위7.5 m,출구절면척촌위1.8 m×1.2 m(고×관)。통과성능시험측정료풍동시험단기류품질,시험결과표명:시험단풍속1.0~10 m/s련속가조,기류동압은정계수소우1.5%,기류문류도소우1%;동시재1.0~9.0 m/s풍속하측정시험단입구절면풍장균균성,표명수착풍속적증가,풍장적풍속분포경가균균。해문위진일보연구식보풍동적결구설계화표이시험삼수우화제공의거。
Drift potential is one of the most important factors affecting spraying quality. Plant protection wind tunnel is an important and preferred tool for quantitative study on drift potential, which is an effective, reliable and feasible research tool for the parameter localization of spray model building. Wind tunnel can provide a well controlled environment for drift measurements under a range of wind speeds and spraying conditions. The NJS-1 type of plant protection wind tunnel was designed based on the drift potential theory, principle of wind tunnel design and atmospheric boundary layer similarity theory, which was composed of inlet section, power section, flexible section, transition section, diffusion section, stability section, contraction section and working section. The total length of the wind tunnel was about 20.0 m; the length of the working section (including five subsections) was about 7.5 m, while the cross section the of the working section was 1.2 m wide and 1.8 m high; the contraction section was 3.0 m long and the contraction ratio was 4; the settling chamber was 2.5 m long and the cross section was 2.4 m wide and 3.6 m high; a hexagon honeycomb of stainless steel and two 18-mesh stainless steel screens were embedded inside the settling chamber; the diffusion section was 2.5 m long, and diffusion ratio was 4 and diffusion angle was 40°; the transition section was 2.8 m long and its main function coupled the power section and the diffusion section. The power section was composed of collector device, impeller, nose cowl, guide vane unit, trail hood and air duct, and was produced by an axial fan which was driven by the 25 kW electric machine. The design of the air supply device and main technical parameters of key parts was based on the theories of fluid mechanics. The air volume of the fan was 21.6 m3/s at the fan speed of 960 r/min, which was determined to adopt 8 impellers and 9 guide glades, the impeller diameter was 1.2 m and the guide glade width was 0.18 m. Wind profiles and flow dynamic characteristics were investigated for the NJS-1 type of plant protection wind tunnel. The objective of this research was to determine the suitability of the wind tunnel for the experiment research and provide the basic information for droplet drift and deposit experiments in this wind tunnel. The experiment was conducted under the condition of the empty wind tunnel. And the experiment strictly followed the flow field specification on high-speed wind tunnel and low-speed wind tunnel (GJB1179-1991). Pitot tube, spectrum analyzer and contractive segment were applied under different wind velocities. Some tests were finished, which referred to the main characteristic parameter testing of field aerodynamics flows in the plant protection wind-tunnel such as air velocity, turbulence intensity, flow stability and flow field uniformity. The results showed that the flow stability coefficient was less than 1.5%, the turbulence was about 1% within air velocity scope from 1.0 to 9.0 m/s, and wind field distribution was more uniform with the increase of the air velocity. This study suggests that the NJS-1 type of plant protection wind tunnel meets the design standard and experiment requirement.