农业工程学报
農業工程學報
농업공정학보
2015年
4期
42-48
,共7页
邢赫%臧英%王在满%罗锡文%张国忠%曹晓曼%谷秀艳
邢赫%臧英%王在滿%囉錫文%張國忠%曹曉曼%穀秀豔
형혁%장영%왕재만%라석문%장국충%조효만%곡수염
农业机械%种子%气力式设备%群布吸孔%精量穴播%分层充种室
農業機械%種子%氣力式設備%群佈吸孔%精量穴播%分層充種室
농업궤계%충자%기력식설비%군포흡공%정량혈파%분층충충실
agricultural machinery%seed%pneumatic equipment%group holes%stratified structure%precision hill-drop
为改善水稻种子在充种室内的流动性并提高水稻气力式精量穴播排种器的排种精度,实现超级杂交稻(1~3)粒/穴精量穴播要求,在水稻气力式精量穴播排种器与种箱间设计了一种分层充种室。以含水率为20.3%(湿基)“培杂泰丰”超级杂交稻种子为对象,采用单因素试验和正交试验的方法,研究了不同吸室负压、吹种正压下,分层充种室对排种器排种性能的影响。试验结果表明,在吸种盘转速为30 r/min、吸室负压为1.6 kPa、送种正压为0.1 kPa、采用分层充种室的条件下,该排种器排出(1~3)粒/穴种子的概率为95.4%,空穴率为1.53%,大于4粒/穴的概率为3.07%,其中排出1粒/穴种子的概率为17.32%,2粒/穴种子的概率为58.72%,3粒/穴种子的概率为19.36%;与前期开展的水稻气力式精量穴播排种器排种性能试验结果相比较,增设分层充种室后,排种器播种精度提高。该研究表明,减小排种器中水稻种子之间的挤压力和摩擦力,改善种子的流动性,从而使吸种盘上吸孔对种子的吸附能力增强,是提高水稻气力式精量穴播排种器的性能的重要途径。该文为水稻气力式排种器结构优化与性能提升研究提供了重要参考。
為改善水稻種子在充種室內的流動性併提高水稻氣力式精量穴播排種器的排種精度,實現超級雜交稻(1~3)粒/穴精量穴播要求,在水稻氣力式精量穴播排種器與種箱間設計瞭一種分層充種室。以含水率為20.3%(濕基)“培雜泰豐”超級雜交稻種子為對象,採用單因素試驗和正交試驗的方法,研究瞭不同吸室負壓、吹種正壓下,分層充種室對排種器排種性能的影響。試驗結果錶明,在吸種盤轉速為30 r/min、吸室負壓為1.6 kPa、送種正壓為0.1 kPa、採用分層充種室的條件下,該排種器排齣(1~3)粒/穴種子的概率為95.4%,空穴率為1.53%,大于4粒/穴的概率為3.07%,其中排齣1粒/穴種子的概率為17.32%,2粒/穴種子的概率為58.72%,3粒/穴種子的概率為19.36%;與前期開展的水稻氣力式精量穴播排種器排種性能試驗結果相比較,增設分層充種室後,排種器播種精度提高。該研究錶明,減小排種器中水稻種子之間的擠壓力和摩抆力,改善種子的流動性,從而使吸種盤上吸孔對種子的吸附能力增彊,是提高水稻氣力式精量穴播排種器的性能的重要途徑。該文為水稻氣力式排種器結構優化與性能提升研究提供瞭重要參攷。
위개선수도충자재충충실내적류동성병제고수도기력식정량혈파배충기적배충정도,실현초급잡교도(1~3)립/혈정량혈파요구,재수도기력식정량혈파배충기여충상간설계료일충분층충충실。이함수솔위20.3%(습기)“배잡태봉”초급잡교도충자위대상,채용단인소시험화정교시험적방법,연구료불동흡실부압、취충정압하,분층충충실대배충기배충성능적영향。시험결과표명,재흡충반전속위30 r/min、흡실부압위1.6 kPa、송충정압위0.1 kPa、채용분층충충실적조건하,해배충기배출(1~3)립/혈충자적개솔위95.4%,공혈솔위1.53%,대우4립/혈적개솔위3.07%,기중배출1립/혈충자적개솔위17.32%,2립/혈충자적개솔위58.72%,3립/혈충자적개솔위19.36%;여전기개전적수도기력식정량혈파배충기배충성능시험결과상비교,증설분층충충실후,배충기파충정도제고。해연구표명,감소배충기중수도충자지간적제압력화마찰력,개선충자적류동성,종이사흡충반상흡공대충자적흡부능력증강,시제고수도기력식정량혈파배충기적성능적중요도경。해문위수도기력식배충기결구우화여성능제승연구제공료중요삼고。
The technology of rice’s mechanical direct seeding can significantly reduce the consumption of manpower and material resources, and meanwhile maintain the production of rice. Super hybrid rice is a kind of hybrid rice and its tillering ability is stronger than the general hybrid rice. Due to the characteristics of high tillering capacity of super hybrid rice, the sowing quantity is required to be 1-3 seeds for each hole when super hybrid rice seeds are directly seeded to the field by the drilling machine, so as to ensure the high precision of seeding and high rate of field seedling emergence. In order to meet the requirement of 1-3 seeds for each hole using the precise hill-drop drilling technique, a seed-filling stratified room was designed, which was between the seed-metering device and the seed box on pneumatic feed mechanism for precision rice hill-drop sowing. It also aimed at improving the liquidity of seeds and raising the seeding precision, the liquidity of rice seed would reduced after accelerating germination. This the reduction of the liquidity of rice seed after accelerating germination had so bad effects on filling process that it limited the improvement of metering performance. Indic hybrid Peizataifeng was taken as the research object, and the impacts of the seed-filling stratified room on the performance of the pneumatic feed mechanism was studied by the single-factor experiment and orthogonal experiment in this paper. These experiments were carried out under different negative pressures for sucking seeds and positive pressures for blowing seeds. The experimental results showed that there existed an optimization condition on the capability of the metering device to meet the needs of the production. The probability about the quantity for each hill was used to evaluate the capability of the pneumatic precise metering device. The seed-filling stratified room consisted of a barrel and two seed-guiding plates. The cross-section of the barrel was the square with 50 mm per side. There were the chutes on the lining of the barrel, which were 1.1 mm wide. Seed-guiding plates were 1 mm thick, which were connected with the barrel by chutes. The two seed-guiding plates formed an angle of 45 degrees. The optimization condition was that the sucking plate’s rotation speed was 30 r/min, the negative pressure for sucking seeds was 1.6 kPa and the positive pressure for blowing seeds was 0.1 kPa. With the seed-filling stratified room, the probability of 1-3 seeds per hill for the metering device was 95.4%; in addition, the probability of empty seed was 1.53%, and the probability of greater than or equal to4 seeds was 3.07%. Under the same condition, the probability of one seed per hill for the metering device was 17.32%; in addition, the two-seed probability was 58.72% and three-seed probability was 19.36%. Compared with the existed researches, the results showed that the seed-filling stratified room between the seed-metering device and the seed box on pneumatic feed device, had a good influence on the precision of the pneumatic seed-metering device, improved the fluidity of the seeds and decreased the friction force and extrusion force among the seeds. This study provides an important reference for the structure optimization and the performance improvement of the pneumatic metering device.
