Dual-drive wheel track changing system

What is claimed is: 1. A dual-drive wheel track changing system configured for a research on track changing performance, the system comprising: a left lifting support track changing moving body, a right lifting support track changing moving body, a four-hole connected track changing force measurement rocker arm, a No. 1 dual-ring connected force measurement sensor, a No. 2 dual-ring connected force measurement sensor, a track changing driving actuator, and a central shaft seat, wherein the central shaft seat further includes: the four-hole connected track changing force measurement rocker arm is connected to each of the left lifting support track changing moving body and the right lifting support track changing moving body through the No. 1 and No. 2 dual-ring connected force measurement sensors, respectively; the left lifting support track changing moving body and the right lifting support track changing moving body are arranged on the left side and the right side of the central shaft seat; and the track changing driving actuator drives the left lifting support track changing moving body and the right lifting support track changing moving body to change tracks through the four-hole connected track changing force measurement rocker arm. 2. The dual-drive wheel track changing system according to claim 1 , wherein the four-hole connected track changing force measurement rocker arm further includes: a four-hole connected track changing force measurement rocker arm body, two four-hole connected track changing force measurement rocker arm bearing pin shaft bodies mounted on the four-hole connected track changing force measurement rocker arm body, a central shaft seat force measurement rocker arm connecting bearing, and a track changing driving connecting pin shaft; and the four-hole connected track changing force measurement rocker arm is connected to the central shaft seat through the central shaft seat force measurement rocker arm connecting bearing, and is connected to the No. 1 and No. 2 dual-ring connected force measurement sensors through the two four-hole connected track changing force measurement rocker arm bearing pin shaft bodies, and is connected to the track changing driving actuator through the track changing driving connecting pin shaft. 3. The dual-drive wheel track changing system according to claim 1 , wherein: the track changing driving actuator is located on one side of the left lifting support track changing moving body; a track changing driving actuator connecting base is mounted on the external Ema beam structure through a shaft seat; and a track changing driving actuator connecting lock ring is connected to the four-hole connected track changing force measurement rocker arm through the track changing driving connecting pin shaft to achieve an effect of pushing track changing. 4. The dual-drive wheel track changing system according to claim 1 , wherein: the central shaft seat is fixed between the left and right lifting support track changing moving bodies; the centers of the bottom surfaces of the central shaft seat and the left and right lifting support track changing moving bodies are in a straight line; the central shaft seat is bolted to the external integral structure constructed by Ema beams; a central shaft seat force measurement rocker arm connecting shaft ( 6 - 1 ) is connected to the four-hole connected track changing force measurement rocker arm body by penetrating through the central shaft seat force measurement rocker arm connecting bearing; the two ends of the No. 1 and No. 2 dual-ring connected force measurement sensors ( 4 - 1 ) and ( 4 - 2 ) are connected to the four-hole connected track changing force measurement rocker arm body through the four-hole connected track changing force measurement rocker arm bearing pin shaft bodies respectively; and the two dual-ring connected force measurement sensors and the track changing force measurement connecting rocker arm are connected and arranged in a Z shape. 5. The dual-drive wheel track changing system according to claim 1 , wherein: the left lifting support track changing moving body and the right lifting support track changing moving body are of the same structure; the left lifting support track changing moving body includes a left mounting guide track bottom plate, a left track changing sliding middle plate body, a left lifting airbag, a left track changing vertical moving upper plate, and wheels; the left mounting guide track bottom plate is fixedly mounted on an external integral Ema beam structure; two long guide tracks are arranged on the left mounting guide track bottom plate; the left track changing sliding middle plate body includes four left vertical lifting moving guide posts, left track changing guide track sliding clamping seat sliding block bodies, and a No. 1 bearing pin shaft body arranged on a left track changing sliding support middle plate; the left vertical lifting moving guide posts and the left track changing guide track sliding clamping seat sliding block bodies are respectively arranged at the four corners of the upper surface and the lower surface of the left track changing sliding support middle plate; ribs are arranged on the lower surface of the left track changing sliding support middle plate; the four left vertical lifting moving guide posts are mounted on the left track changing sliding support middle plate through left track changing sliding support middle plate through hole cylinders ( 16 - 2 ) respectively; the No. 1 bearing pin shaft body is mounted on the left track changing sliding support middle plate through a left track changing sliding support middle plate protruding hollow cuboid; the left track changing guide track sliding clamping seat sliding block bodies are fixed to the lower surface of the left track changing sliding support middle plate through bolting bodies respectively, and are matched with the two long guide tracks on the guide track bottom plate; and a circular hole in one end of the No. 1 dual-ring connected force measurement sensor is placed in the protruding hollow cuboid and is coaxial with the circular hole of the hollow cuboid, so that the No. 1 bearing pin shaft body is arranged therein in a sleeving manner to connect the four-hole connected track changing force measurement rocker arm to the left track changing sliding support middle plate. 6. The dual-drive wheel track changing system according to claim 5 , wherein: the left lifting airbag is arranged between the left track changing sliding support middle plate and the left track changing vertical moving upper plate, and is circumferentially fixed to the left track changing sliding support middle plate by bolts. 7. The dual-drive wheel track changing system according to claim 5 , wherein: the left track changing vertical moving upper plate includes a left track changing vertical moving upper plate base plate, four drive wheel assembling bearing seats, eight bearing seat connecting plate bolted assembling bodies ( 23 ), a left No. 1 drive wheel, a left No. 2 drive wheel, a left motor drive wheel roller chain wheel, a left dual-drive wheel connecting chain, and a left planetary reducer motor assembling body; a circular hole corresponding to the protruding hollow cuboid is formed in the left lifting moving upper plate base plate; and hollow left vertical moving upper plate bottom plate bearing cylinders are arranged at the four corners of the left track changing vertical moving upper plate base plate, are assembled with the four left vertical lifting moving guide posts in the left track changing sliding middle plate body in a matched manner through linear movement bearings arranged in the cylinders, and move up and down along the guide posts.