Modeling method for low-loss transport technology with directied force application and slow landing

What is claimed is: 1 . A modeling method for a low-loss transport technology with directed force application and slow landing, comprising: S1: determining relevant parameters specified by a potato harvesting standard; S2: performing theoretical analysis, and determining structural parameters of a low-loss transport device with directed force application and slow landing; S3: modeling an auxiliary device for simulating a motion trail of a crop; and S4: modeling a modeling main body, auxiliary wheels, grid bars, and belts in sequence to form a low-loss transport device with directed force application and slow landing, and modeling a driving device at a rear portion of the low-loss transport device with directed force application and slow landing to drive the low-loss transport device with directed force application and slow landing to run; wherein the S2 comprises dividing the low-loss transport device with directed force application and slow landing into three segments to respectively perform the theoretical analysis on the crop; the theoretical analysis comprises stress analysis and speed analysis; the three segments comprise a first segment, a second segment, and a third segment, the first segment is from a front driven wheel to the modeling main body, the second segment is from the modeling main body to the auxiliary wheels, and the third segment is from the auxiliary devices to the driving device; the stress analysis and the speed analysis are as follows: in the first segment, a component velocity of the crop in a horizontal direction is slightly higher than a forward speed of the low-loss transport device with directed force application and slow landing, a vertical movement distance of the crop is not greater than a maximum height of falling of the crop, and stress on the crop is balanced; an inclination angle of the modeling main body of the low-loss transport technology with directed force application and slow landing is the same as an inclination angle of a digging shovel; in the second segment, a movement of the crop from the first segment to the second segment is an oblique projectile movement, and at a moment when the crop is in contact with the low-loss transport device with directed force application and slow landing, a resultant velocity direction of the crop is vertically downward and the stress on the crop is balanced; and in the third segment, the crop moves along with the low-loss transport device with directed force application and slow landing, the stress on the crop is balanced, and a height between a highest point of the crop in the third segment and a lowest point of the crop of a next step is within an allowable range of falling damage. 2 . The modeling method for the low-loss transport technology with directed force application and slow landing according to claim 1 , wherein in that at the moment when the crop is in contact with the low-loss transport device with directed force application and slow landing, the resultant velocity direction of the crop is vertically downward and the stress on the crop is balanced, a speed difference between an instantaneous resultant velocity of the crop falling on the low-loss transport device with directed force application and slow landing and a transporting velocity of the low-loss transport device with directed force application and slow landing is not greater than 0.02 m/s. 3 . The modeling method for the low-loss transport technology with directed force application and slow landing according to claim 1 , wherein in the stress analysis and the speed analysis performed on the second segment, the transporting velocity of the low-loss transport device with directed force application and slow landing is transported downward along an inclination angle, and plays a role in buffering the crop. 4 . The modeling method for the low-loss transport technology with directed force application and slow landing according to claim 1 , wherein the S3 comprises: analyzing the motion trail of the crop; and modeling the modeling main body. 5 . The modeling method for the low-loss transport technology with directed force application and slow landing according to claim 4 , wherein in the analyzing the motion trail of the crop, when the crop passes through the first segment into the second segment, the movement of the crop is the oblique projectile movement, and magnitudes and directions of an initial speed and a final speed of the oblique projectile movement depend on inclinations of the first segment and the second segment. 6 . The modeling method for the low-loss transport technology with directed force application and slow landing according to claim 4 , wherein in the modeling the modeling main body, when the crop passes through the first segment into the second segment, a motion radian of the low-loss transport device with directed force application and slow landing satisfies the motion trail of the crop, and the motion radian of the low-loss transport device with directed force application and slow landing is achieved by providing modeling main body auxiliary wheels, and an outer contour curve of each of the modeling main body auxiliary wheels in contact with the belts is the same as the motion trail of the crop. 7 . The modeling method for the low-loss transport technology with directed force application and slow landing according to claim 6 , wherein in that the motion radian of the low-loss transport device with directed force application and slow landing is achieved by providing the modeling main body auxiliary wheels, three modeling main body auxiliary wheels are provided, a diameter of an outer wheel of each of the modeling main body auxiliary wheels is less than a diameter of an outer wheel of each of the auxiliary wheels of the low-loss transport device with directed force application and slow landing. 8 . The modeling method for the low-loss transport technology with directed force application and slow landing according to claim 1 , wherein in the modeling the modeling main body, the auxiliary wheels, the grid bars, and the belts in sequence to form the low-loss transport device with directed force application and slow landing, and modeling the driving device at the rear portion of the low-loss transport device with directed force application and slow landing to drive the low-loss transport device with directed force application and slow landing to run, a pitch of the driving device is 45 mm and is adapted to a pitch of the low-loss transport device with directed force application and slow landing. 9 . The modeling method for the low-loss transport technology with directed force application and slow landing according to claim 1 , wherein in the modeling the modeling main body, the auxiliary wheels, the grid bars, and the belts in sequence to form the low-loss transport device with directed force application and slow landing, and modeling the driving device at the rear portion of the low-loss transport device with directed force application and slow landing to drive the low-loss transport device with directed force application and slow landing to run, two belts are disposed in the low-loss transport device with directed force application and slow landing to form a belt unit, and a plurality of the grid bars are disposed on an outer side of the belt unit at equal intervals, a fixing wheel of the low-loss transport device with directed force application and slow landing is disposed at a first side of an interior of the belt unit, and a driving wheel is disposed at a second side of the interior of the belt unit away from the fixing wheel of the low-loss transport device with directed force application and slow landing. 10 . The modeling method for the low-l