Adaptive control system for threshing separation load of tangential flow and longitudinal axial flow device

The invention claimed is: 1. An adaptive control system for load distribution between a tangential and a longitudinal threshing and separating device, comprising: a tangential drum; a longitudinal axial flow drum; a longitudinal flow concave plate screen mounted on the longitudinal axial flow drum; a return plate disposed below the longitudinal axial flow drum; a grain auger disposed below the return plate; a cleaning screen disposed above the grain auger and below the tangential drum and the return plate; an outlet adjustment device for regulating clearance of an outlet of the tangential flow concave plate; a jitter plate; a jitter plate load monitoring device mounted on the jitter plate; a return plate load monitoring device mounted on the return plate and disposed below the longitudinal axial flow drum; an online monitoring and control system connected to the return plate load monitoring device, the jitter plate load monitoring device, and the outlet adjustment device; and a displacement sensor connected to the online monitoring and control system, wherein jitter plate load monitoring device comprises a jitter impact force monitoring sensor and a jitter inertial force monitoring sensor, wherein the return plate load monitoring device comprises a return inertial force monitoring sensor, a first return monitoring board, a return impact force monitoring sensor, a second return monitoring board, a return mounting plate, and a return bracket supporting the return plate, wherein the return mounting plate is fixed below the return plate by the return bracket, wherein each of the return plate and the return mounting plate is provided with a through hole that has the same shape as the first return monitoring board and the second return monitoring board, wherein the through hole of the return plate corresponds to the through hole of the return mounting plate in a vertical direction, wherein the first return monitoring board is disposed in the through hole of the return mounting plate and maintains a gap of 0.5 mm-3 mm with an edge of the through hole, wherein the second return monitoring board is disposed in through hole of the return plate and maintains a gap of 0.5 mm-3 mm with an edge of the through hole, wherein a first end of the return inertial force monitoring sensor is fixed to the return mounting plate, and a second end of the return inertial force monitoring sensor opposite to the first end is fixed to the first return monitoring board, wherein a first end of the return impact force monitoring sensor is fixed to the return plate, and a second end of the return impact force monitoring sensor opposite to the first end is fixed to the second return monitoring board, wherein the return inertial force monitoring sensor and the return impact force monitoring sensor are connected to the online monitoring and control system, wherein the online monitoring and control system detects inertial force via the return inertial force monitoring sensor and the jitter inertial force monitoring sensor, wherein the online monitoring and control system detects impact force via the return impact force monitoring sensor and the litter impact force monitoring sensor, wherein the online monitoring and control system detects displacement via the displacement sensor, wherein the online monitoring and control system calculates a load of the tangential drum based on the jitter inertial force monitoring sensor, wherein the online monitoring and control system calculates a load of the longitudinal axial flow drum based on the return inertial force monitoring sensor and the return impact force monitoring sensor, and wherein the online monitoring and control system calculates a ratio of the load of the tangential drum to the load of the longitudinal axial flow drum and, based on the ratio and the displacement detected by the displacement sensor, causes the outlet adjustment device to adjust the clearance of the outlet of the tangential flow concave plate. 2. The adaptive control system according to claim 1 , comprising: a plurality of jitter plate load monitoring devices mounted on the jitter plate and arrange in an “X”-shaped layout; and a plurality of return plate load monitoring devices mounted on the return plate, disposed below the longitudinal axial flow drum, and arranged in an “X”-shaped layout. 3. The adaptive control system according to claim 1 , further comprising: an entrainment loss monitoring device disposed on the longitudinal How concave plate screen; and a longitudinal axial flow drum speed control device connected to the longitudinal axial flow drum, wherein the entrainment loss monitoring device is connected to the online monitoring and control system, and wherein the longitudinal axial flow drum speed control device comprises a first hydraulic cylinder, a first pulley movable part, a first belt, and a first pulley fixed part, wherein the first hydraulic cylinder and the first pulley movable part are disposed on a same side as each other, and wherein the longitudinal axial flow drum speed control device is configured to change a belt groove size of the longitudinal axial flow drum to control an axial flow speed of the longitudinal axial flow drum. 4. The adaptive control system according to claim 1 , further comprising: a grain crushing rate monitoring device mounted on the grain auger and connected to the online monitoring and control system; and a tangential drum speed control device, wherein the tangential drum speed control device comprises a second hydraulic cylinder, a second pulley movable part, a second belt, and a second pulley fixed part, wherein the second hydraulic cylinder and the second pulley movable part are disposed on a same side as each other, and wherein the tangential drum speed control device is configured to change a belt groove size of the tangential drum to control a speed of the tangential drum. 5. The adaptive control system according to claim 3 , wherein the entrainment loss monitoring device comprises two mounting brackets attached to the longitudinal flow concave plate screen and two monitoring sensors respectively disposed on the two mounting brackets, wherein the two monitoring sensors are connected to the online monitoring and control system. 6. The adaptive control system according to claim 4 , wherein the grain crushing rate monitoring device comprises an image processor, a CCD camera, a grain information acquisition board, and a light source, wherein the image the processor is mounted on an export platform in the grain auger, wherein the grain information acquisition board is fixed in the grain auger, wherein the CCD camera is installed in the grain information acquisition board, and wherein the image processor and the grain information acquisition board are connected to the online monitoring and control system. 7. An adaptive control method for load distribution between a tangential and a longitudinal threshing and separating device, the method comprising the following steps: (S0) providing the adaptive control system according to claim 1 ; (S1) according to characteristics of crop structure and desired standards, set initial values in the online monitoring control system for the ratio of the load of the tangential drum to the load of the longitudinal axial flow drum [R b R u ], a range of the clearance of the outlet of the tangential flow concave plate [C b C u ], a range of a speed of the tangential drum [n qb n qu ], a range of a speed of the longitudinal axial flow drum [n zb , n zu ], a threshold of a grain crushing rate of the grain auger [B r ], and a threshold of an entrainment loss rate [L j ]; (S2) performing real-time detection of the grain crushing rate with a grain crushing monito