农业工程学报
農業工程學報
농업공정학보
2015年
15期
12-18
,共7页
向伟%吴明亮%官春云%徐玉娟
嚮偉%吳明亮%官春雲%徐玉娟
향위%오명량%관춘운%서옥연
移栽%机械%成型%打孔机构%靠模凸轮%栽植孔%油菜苗
移栽%機械%成型%打孔機構%靠模凸輪%栽植孔%油菜苗
이재%궤계%성형%타공궤구%고모철륜%재식공%유채묘
transplants%machinery%forming%transplanter%hole forming device%copying cam%planting hole%rape seedlings
为设计新型油菜移栽机,基于旱地移栽作业的工作特点,融合油菜移栽农艺要求,研制了一种履带式油菜移栽栽植孔成型装置。通过分析土壤物理机械力学特性,求取打孔机构垂直出土所受摩擦阻力参数方程,为关键部件打孔机构的机构设计提供力学参数与理论依据;完成关键部件—打孔机构、靠模凸轮进行设计及优化后,设计并试制试验样机,进行田间试验。试验结果表明:机器以慢一档工作状态下前进速度为1.65~1.78 km/h,作业效率达到0.231~0.249 hm2/h,其成孔的平均合格率也达到93.8%。研制的机器能形成满足设计要求的栽植孔,为新型移栽机的设计提供技术支持。
為設計新型油菜移栽機,基于旱地移栽作業的工作特點,融閤油菜移栽農藝要求,研製瞭一種履帶式油菜移栽栽植孔成型裝置。通過分析土壤物理機械力學特性,求取打孔機構垂直齣土所受摩抆阻力參數方程,為關鍵部件打孔機構的機構設計提供力學參數與理論依據;完成關鍵部件—打孔機構、靠模凸輪進行設計及優化後,設計併試製試驗樣機,進行田間試驗。試驗結果錶明:機器以慢一檔工作狀態下前進速度為1.65~1.78 km/h,作業效率達到0.231~0.249 hm2/h,其成孔的平均閤格率也達到93.8%。研製的機器能形成滿足設計要求的栽植孔,為新型移栽機的設計提供技術支持。
위설계신형유채이재궤,기우한지이재작업적공작특점,융합유채이재농예요구,연제료일충리대식유채이재재식공성형장치。통과분석토양물리궤계역학특성,구취타공궤구수직출토소수마찰조력삼수방정,위관건부건타공궤구적궤구설계제공역학삼수여이론의거;완성관건부건—타공궤구、고모철륜진행설계급우화후,설계병시제시험양궤,진행전간시험。시험결과표명:궤기이만일당공작상태하전진속도위1.65~1.78 km/h,작업효솔체도0.231~0.249 hm2/h,기성공적평균합격솔야체도93.8%。연제적궤기능형성만족설계요구적재식공,위신형이재궤적설계제공기술지지。
In order to resolve some key issues about the machinery of transplanter for rape seedlings, a new type of transplanter with crawler planting hole forming tools for rape was designed based on the working characteristic in the dry land and agronomic requirement. Research on soil physical and mechanical characteristics were conducted to provide the technical parameters for the design of the hole forming device. First, we completed the whole structure design and analyzed the working principle of the device. The crawler was drove by power system to go forward, on which the hole forming device was installed and synchronously moving. The surface cam was mounted on the chassis. As the caterpillar moved forward, the pore forming device installed on the track vertically stabbed into the soil under the pressure of surface cam supplied by body weight. As the tracks moved forward, the hole forming device was out of the surface cam profiling. As such, a plant hole was formed. We analyzed the curve of surface cam limit, confirmed the limited point so that a coordinate system was established. We then chose the definition curve interpolation method to solve the parameter equation of surface cam profiling combining with Matlab7.0 software plot function in the program and generated surface cam outline curve. For the optimization of punch mechanism of structural design, the surface cam profiling and reset spring control capacity into hole device unearthed vertically. The cylindrical hole was pressured by shearing and extrusion soil. We analyzed the same track number, it had two tracks. Each of them had two linear holes. When the machine moved forward, each side could dig holes in four rows at one time. We installed rolling bearing in the hole forming device for rolling friction instead of sliding friction to reduce friction in the cylindrical hole and the friction between the surface cams. By use of the prototype machine in field, we recorded variables, such as the time, moving distance, distance between holes, the depth of effective planting hole, and the diameter of planting hole. We analyzed indexes such as the rate of qualified hole, hole forming frequency, efficiency, etc.. The result showed that if the machine at lower speed at 1.65-1.78 km/h, the efficiency was up to 0.231-0.249 hm2/h, and the rate of qualified hole up to 93.8% on average. The various performance indicator met the design requirement. The planting and hole forming machine can get holes at 1 400 mm in length each, 50 mm in diameter, 50 mm in depth, and 120000 holes/hm2 in hole density per area. This could get the planting hole to satisfy agronomic requirement. The research provided theoretical and technical references for design of the new type of transplanter.