CAJ | 학술논문

为提高幼苗移栽质量，设计了1套双平行多杆栽植机构。为了分析和优化该机构的结构参数，建立了该机构的数学模型和运动学方程，并基于Matlab-gui编写了人机交互式程序界面。结合移栽农艺要求，建立了栽植机构运动轨迹与幼苗移栽直立度合格率的关系模型。根据仿真结果，优选了1组机构杆件长度、安装位置和初始角度等参数，并根据该参数设计和制造了幼苗移栽机样机。样机路面静轨迹和动轨迹的高速摄像试验表明，样机实际运动规律符合仿真设计要求，证明了机构设计、数学模型、软件程序和关系模型准确无误；田间试验时接苗准确率和直立度合格率均达100%，试验结果表明双平行多杆栽植机构符合幼苗作物移栽要求，同时也证明了Matlab-gui 的人机交互优化方法在多杆式移栽机构分析中准确可行。该研究形成的多杆式移栽机构的运动规律对提高机械化作物幼苗移栽质量具有一定的指导意义。
위제고유묘이재질량，설계료1투쌍평행다간재식궤구。위료분석화우화해궤구적결구삼수，건립료해궤구적수학모형화운동학방정，병기우Matlab-gui편사료인궤교호식정서계면。결합이재농예요구，건립료재식궤구운동궤적여유묘이재직립도합격솔적관계모형。근거방진결과，우선료1조궤구간건장도、안장위치화초시각도등삼수，병근거해삼수설계화제조료유묘이재궤양궤。양궤로면정궤적화동궤적적고속섭상시험표명，양궤실제운동규률부합방진설계요구，증명료궤구설계、수학모형、연건정서화관계모형준학무오；전간시험시접묘준학솔화직립도합격솔균체100%，시험결과표명쌍평행다간재식궤구부합유묘작물이재요구，동시야증명료Matlab-gui 적인궤교호우화방법재다간식이재궤구분석중준학가행。해연구형성적다간식이재궤구적운동규률대제고궤계화작물유묘이재질량구유일정적지도의의。
Hanging cup type transplanter is widely used because of its good protection to the seedlings, the strong adaptability to the soil and its flexibility of planting depth adjustment. In order to improve the quality of hanging cup type transplanter in transplanting seedlings, static trajectory graft seedlings test, planting perpendicularity comparison test and dynamic trajectory plant seedlings test have been designed according to the agronomic requirements. Through those tests, the relation model between the position of seedling mechanism and the accuracy of graft seedlings, the perpendicularity comparison model before and after plant, and the equations between the qualification rate of the plant perpendicularity and the overlap or deviate width of dynamic trajectory under the plant depth line have been established. The tests showed that the overlap or deviate width of dynamic trajectory under the plant depth line was an important factor to improve the qualification rate of planting. In order to meet those requirements, a double parallel multi-rod planting mechanism was designed. It was mainly composed of a horizontal movement control parallel mechanism and a vertical planting movement control parallel mechanism. Through analyzing and optimizing the structure data, the mathematical model and kinematic equation of this mechanism were built. In addition, based on Matlab-gui, the man-machine interaction program interface was written. According to the simulation results of computer program, a set of data including the length of the rod, the mounting location and the crank initial angle were optimized. Meanwhile, a seedling transplanter prototype was designed and made according to the data. By using a PCO.1200 hs camera produced by PCO Imaging Asia Private Trading Enterprise Limited, the movement of the recording spot in grafting seedling, in the static and dynamic trajectory of transplanting mechanism was observed with one photo being taken every 50 minutes. These pictures were analyzed through maximum intensity method of Ipp6.0 software to see if the transplanting mechanism met the requirements of the original design. The high-speed photography test of the grafting seedling showed that the send seedling mechanism could eject seedling to the center of the top of the planting device, and the planting device could receive it very accurately every time. The high-speed photography test of the static trajectory showed that the static trajectory tallied with its computer simulation perfectly. The high-speed photography test in dynamic trajectory showed that under the control of the transplanting mechanism, the endpoint in the bottom of the plant device oscillated quite a little (the design value was 1.05 mm) in horizontal direction under planting depth line. Since when the transplanter moves uniformly ahead, the plant device is planting seedling in zero-speed in horizontal direction under the control of the transplanting mechanism, the qualification of the transplanting is improved. These tests proved that the move laws of transplanting mechanism tallied with its original design, and the mechanism design, the data model, the software programme and the rational model were accurate. During the field test, when the accelerator pedal was shifted to the middle, the speed of the transplanter was around 0.3 m/s, one cycle plant takes 0.8 s, with rows spacing at 0.24 m, depth around 0.08-0.12 m. The accuracy of planting the seedling and the qualification ratio of the planting perpendicularity all reach 100%. The results of these tests proved that the double parallel multi-rod planting mechanism met the seedling transplanting requests of the rape, cotton, corn and so on. And the research method was proved to be accurate. All these can be the scientific basis for the design and analysis of the multi-rod transplanting mechanism.