Hydro-mechanical transmission device with dual-clutch transmission and control method thereof

What is claimed is: 1. A hydro-mechanical transmission device with a dual-clutch transmission, comprising: an input mechanism, a pump-controlled motor mechanism, an odd-numbered gear transmission mechanism, an even-numbered gear transmission mechanism, an output mechanism, and a jackshaft; wherein the input mechanism is connected to the odd-numbered gear transmission mechanism and the even-numbered gear transmission mechanism, and the input mechanism is connected to an input end of the pump-controlled motor mechanism; an output end of the pump-controlled motor mechanism is connected, through the jackshaft, to the odd-numbered gear transmission mechanism and the even-numbered gear transmission mechanism, and the output end of the pump-controlled motor mechanism is connected to the output mechanism; a first clutch is arranged between the input mechanism and the input end of the pump-controlled motor mechanism, a second clutch and a travel motor output brake are arranged between the output end of the pump-controlled motor mechanism and the jackshaft, and a third clutch is arranged between the jackshaft and the output mechanism; the odd-numbered gear transmission mechanism comprises an odd-numbered gear planetary gear transmission assembly, an odd-numbered gear clutch, and an odd-numbered gear shift assembly; the odd-numbered gear planetary gear transmission assembly comprises an odd-numbered gear planetary gear sun gear, an odd-numbered gear planetary gear planet carrier, and an odd-numbered gear planetary gear ring gear; the odd-numbered gear planetary gear transmission assembly is connected to the jackshaft through the odd-numbered gear planetary gear sun gear; the odd-numbered gear planetary gear transmission assembly is connected to the input mechanism through the odd-numbered gear planetary gear ring gear; the odd-numbered gear planetary gear planet carrier is connected to the odd-numbered gear shift assembly through the odd-numbered gear clutch; the odd-numbered gear shift assembly is connected to the output mechanism; the even-numbered gear transmission mechanism comprises an even-numbered gear planetary gear transmission assembly, an even-numbered gear clutch, and an even-numbered gear shift assembly; the even-numbered gear planetary gear transmission assembly comprises an even-numbered gear planetary gear sun gear, an even-numbered gear planetary gear planet carrier, and an even-numbered gear planetary gear ring gear; the even-numbered gear planetary gear transmission assembly is connected to the jackshaft through the even-numbered gear planetary gear sun gear; the even-numbered gear planetary gear transmission assembly is connected to the input mechanism through the even-numbered gear planetary gear planet carrier; the even-numbered gear planetary gear ring gear is connected to the even-numbered gear shift assembly through the even-numbered gear clutch; the even-numbered gear shift assembly is connected to the output mechanism; the pump-controlled motor mechanism comprises a first variable pump, a second variable pump, a pilot-operated relief valve, a relief valve, a three-position four-way valve, a two-position three-way valve, a travel motor, and a power output motor; the first variable pump has a greater flow than the second variable pump; the pilot-operated relief valve is arranged in a first bypass oil circuit of the first variable pump; the relief valve is arranged in a second bypass oil circuit of the second variable pump; the second bypass oil circuit is communicated with the first bypass oil circuit; the first bypass oil circuit and the second bypass oil circuit are communicated with the travel motor and the power output motor through the three-position four-way valve and the two-position three-way valve. 2. A method of operating the hydro-mechanical transmission device with the dual-clutch transmission according to claim 1 , comprising switching among a hydraulic transmission mode, a hydro-mechanical transmission mode, and a mechanical transmission mode between the input mechanism and the output mechanism by controlling a combination and engagement/disengagement of the first clutch, the second clutch, the third clutch, the odd-numbered gear clutch, the even-numbered gear clutch, and the travel motor output brake, wherein: in the hydraulic transmission mode, when the first clutch, the second clutch, and the third clutch are engaged while the odd-numbered gear clutch, the even-numbered gear clutch and the travel motor output brake are disengaged, power is transmitted through the pump-controlled motor mechanism and the jackshaft to the output mechanism; in the mechanical transmission mode, when the first clutch, the second clutch, and the third clutch are disengaged while the travel motor output brake is engaged, the power is transmitted to the output mechanism through the odd-numbered gear transmission mechanism and the even-numbered gear transmission mechanism connected in parallel; in the hydro-mechanical transmission mode, when the first clutch L 0 and the second clutch are engaged while the third clutch and the travel motor output brake are disengaged, the power is split into a first part and a second part, wherein the first part of the power passes through the pump-controlled motor mechanism to the jackshaft, and the second part of the power is transmitted to the odd-numbered gear transmission mechanism, the first part and the second part of the power are converged at the odd-numbered gear planetary gear transmission assembly and then transmitted through the odd-numbered gear clutch and the odd-numbered gear shift assembly to the output mechanism, or the first part of the power passes through the pump-controlled motor mechanism to the jackshaft, and the second part of the power is transmitted to the even-numbered gear transmission mechanism, the first part and the second part of the power are converged at the even-numbered gear planetary gear transmission assembly and then transmitted through the even-numbered gear clutch and the even-numbered gear shift assembly to the output mechanism. 3. The method of operating the hydro-mechanical transmission device with the dual-clutch transmission according to claim 2 , wherein when the three-position four-way valve is in a left position and the two-position three-way valve is in a right position, the travel motor is connected with either the first bypass oil circuit or the second bypass oil circuit and rotates in a forward direction; when the three-position four-way valve is in a right position and the two-position three-way valve is in the right position, the travel motor is connected with either the first bypass oil circuit or the second bypass oil circuit and rotates in a reverse direction; when the three-position four-way valve is in the left position and the two-position three-way valve is in a left position, the travel motor and the power output motor are connected in series with either the first bypass oil circuit or the second bypass oil circuit and rotate in the forward direction; when the three-position four-way valve is in the right position and the two-position three-way valve is in the left position, the travel motor and the power output motor are connected in series with either the first bypass oil circuit or the second bypass oil circuit and rotate in the reverse direction. 4. The method of operating the hydro-mechanical transmission device with the dual-clutch transmission according to claim 2 , wherein the odd-numbered gear shift assembly comprises a first gear shift assembly, a third gear shift assembly, and a first reverse-gear shift assembly connected in parallel; the first gear shift assembly comprises a first gear clutch, the third gear shift assembly comprises a third gear clutch, and the first reverse-gear shift as