华南农业大学学报
華南農業大學學報
화남농업대학학보
JOURNAL OF SOUTH CHINA AGRICULTURAL UNIVERSITY
2014年
6期
99-103
,共5页
夏红梅%李志伟%甄文斌%张炳超
夏紅梅%李誌偉%甄文斌%張炳超
하홍매%리지위%견문빈%장병초
蔬菜%排种器%气力板式%真空流场%仿真
蔬菜%排種器%氣力闆式%真空流場%倣真
소채%배충기%기력판식%진공류장%방진
vegetable%seed metering device%pneumatic plate-type%vacuum flow field%simulation
【目的】优化气力板式蔬菜排种器气室结构参数,简化气室气流体为定常不可压的湍流模型。【方法】选用AN-SYS软件的FLOTRAN模块,对不同气室结构参数进行仿真分析。【结果和结论】相对整体矩形空腔结构,矩形横槽和纵槽连通气室结构更能节省气流量,提高整体强度;双气源口结构相比单气源口结构相对压力损失小,流场分布均匀性更好;优化的气源口位置在距排种器两侧边缘第4个和第5个吸种孔之间;气室槽深越大,过渡区域相对压力损失越小,吸种孔入口处的相对压力和速度分布越均匀,但排种器整体结构尺寸增大,气腔内形成一定相对压力的稳定流场所需时间更长,槽深取4 mm综合较好。验证试验结果表明,在吸种孔入口中心处,仿真分析结果与实际测量结果比较接近,趋势上具有较高一致性,表明仿真分析优化气室结构参数可行。
【目的】優化氣力闆式蔬菜排種器氣室結構參數,簡化氣室氣流體為定常不可壓的湍流模型。【方法】選用AN-SYS軟件的FLOTRAN模塊,對不同氣室結構參數進行倣真分析。【結果和結論】相對整體矩形空腔結構,矩形橫槽和縱槽連通氣室結構更能節省氣流量,提高整體彊度;雙氣源口結構相比單氣源口結構相對壓力損失小,流場分佈均勻性更好;優化的氣源口位置在距排種器兩側邊緣第4箇和第5箇吸種孔之間;氣室槽深越大,過渡區域相對壓力損失越小,吸種孔入口處的相對壓力和速度分佈越均勻,但排種器整體結構呎吋增大,氣腔內形成一定相對壓力的穩定流場所需時間更長,槽深取4 mm綜閤較好。驗證試驗結果錶明,在吸種孔入口中心處,倣真分析結果與實際測量結果比較接近,趨勢上具有較高一緻性,錶明倣真分析優化氣室結構參數可行。
【목적】우화기력판식소채배충기기실결구삼수,간화기실기류체위정상불가압적단류모형。【방법】선용AN-SYS연건적FLOTRAN모괴,대불동기실결구삼수진행방진분석。【결과화결론】상대정체구형공강결구,구형횡조화종조련통기실결구경능절성기류량,제고정체강도;쌍기원구결구상비단기원구결구상대압력손실소,류장분포균균성경호;우화적기원구위치재거배충기량측변연제4개화제5개흡충공지간;기실조심월대,과도구역상대압력손실월소,흡충공입구처적상대압력화속도분포월균균,단배충기정체결구척촌증대,기강내형성일정상대압력적은정류장소수시간경장,조심취4 mm종합교호。험증시험결과표명,재흡충공입구중심처,방진분석결과여실제측량결과비교접근,추세상구유교고일치성,표명방진분석우화기실결구삼수가행。
Objective] To optimize chamber structure parameters of the pneumatic plate-type vegetable seed metering device , and to simplify the vacuum flow field in the air chamber as steady , regular, incom-pressible and turbulent fluid .[Method] The FLOTRAN module of ANSYS software was applied to simu-late and analyze the air chamber with different structure parameters .[Result and conclusion] Compared to the rectangular cavity air chamber structure , the rectangular groove connected air chamber structure could save more gas flow and improve the overall strength .Pressure loss of double outlet was less than single outlet, and flow field uniformity of double outlet was better .The optimized air source location was between the fourth and the fifth suction holes calculated from both sides of the metering device .Increas-ing channel depth could reduce pressure loss at transition region and ensure more uniform pressure and velocity distribution .But if channel depth increased , the size of metering device would increase corre-spondingly , and the time for forming steady flow would be longer .According to simulation results , 4 mm channel depth was optimized .Verifying tests of the air flow field in the vacuum chamber of seed metering device show that the simulation analysis results are comparatively consistent with the actual measurement results, with a consistent pressure distribution trend .This proves the feasibility of the numerical simula-tion method.
