Hybrid drive vehicle

The invention claimed is: 1. A hybrid drive vehicle ( 1 ) comprising: at least one driving wheel ( 3 ); an internal combustion engine ( 5 ) provided with a drive shaft ( 6 ); at least one electric machine ( 8 ) provided with a shaft ( 10 ); a gearbox ( 12 ), which transmits the motion to the driving wheel ( 3 ); a disengagable coupling ( 9 ), which is interposed between the drive shaft ( 6 ) and the shaft ( 10 ) of the electric machine ( 8 ) so as to establish a mechanical connection that can be interrupted; and a transmission shaft ( 11 ), which is interposed between the shaft ( 10 ) of the electric machine ( 8 ) on the opposite side relative to the coupling ( 9 ) and the gearbox ( 12 ) so as to establish a permanent mechanical connection; wherein the coupling ( 9 ) comprises: a clutch ( 26 ) which is suitable to cause the drive shaft ( 6 ) to rotate at the same speed as the shaft ( 10 ) of the electric machine ( 8 ) establishing a clutch coupling; and an actuator ( 32 ) which is suitable to actuate the clutch ( 26 ) to cause the drive shaft ( 6 ) to rotate at the same speed as the shaft ( 10 ) of the electric machine ( 8 ); wherein the coupling ( 9 ) comprises a shape coupling device ( 29 ) which is functionally independent and separate from the clutch ( 26 ) and is suitable to make the shaft ( 10 ) of the electric machine ( 8 ) angularly integral to the drive shaft ( 6 ) by means of a shape mating independent of the friction coupling established by the clutch ( 26 ); wherein the clutch ( 26 ) of the coupling ( 9 ) is never used to transmit the torque generated by the internal combustion engine ( 5 ) to the driving wheel ( 3 ); and wherein the clutch ( 26 ) of the coupling ( 9 ) is only used to transmit a torque generated by the electric machine ( 8 ) to the internal combustion engine ( 5 ) and intended solely for starting the internal combustion engine ( 5 ). 2. The hybrid drive vehicle ( 1 ) according to claim 1 , wherein: the actuator ( 32 ), in order to establish the connection between the shaft ( 10 ) of the electric machine ( 8 ) and the drive shaft ( 6 ) when there is no difference in rotation speed, i.e. when both are stationary, actuates the shape coupling device ( 29 ) to make the shaft ( 10 ) of the electric machine ( 8 ) angularly integral to the drive shaft ( 6 ); and the actuator ( 32 ), in order to establish the connection between the shaft ( 10 ) of the electric machine ( 8 ) and the drive shaft ( 6 ) when the drive shaft ( 6 ) is stationary, initially actuates the clutch ( 26 ) to cause the drive shaft ( 6 ) to rotate at the same speed as the shaft ( 10 ) of the electric machine ( 8 ) and, once the drive shaft ( 6 ) is rotating at the same speed as the shaft ( 10 ) of the electric machine ( 8 ), actuates the shape coupling device ( 29 ) to make the shaft ( 10 ) of the electric machine ( 8 ) angularly integral to the drive shaft ( 6 ). 3. The hybrid drive vehicle ( 1 ) according to claim 1 , wherein the clutch ( 26 ) is constructively integrated with the shape coupling device ( 29 ). 4. The hybrid drive vehicle ( 1 ) according to claim 3 , wherein the shape coupling device ( 29 ) comprises a sleeve ( 22 ), which is mounted so as to axially slide due to the thrust of the actuator ( 32 ), supports a first conical friction surface ( 27 ) that is part of the clutch ( 26 ), and supports first teeth ( 30 ) that enable the shape mating. 5. The hybrid drive vehicle ( 1 ) according to claim 4 , wherein the shape coupling device ( 29 ) comprises a support ring ( 25 ), which has a second conical friction surface ( 28 ), which is part of the clutch ( 26 ) and is suitable to be coupled to the first conical friction surface ( 27 ), and second teeth ( 31 ), which enable the shape mating together with the first teeth ( 30 ). 6. The hybrid drive vehicle ( 1 ) according to claim 5 , wherein the sleeve ( 22 ) is angularly integral to the shaft ( 10 ) of the electric machine ( 8 ) and the support ring ( 25 ) is angularly integral to the drive shaft ( 6 ). 7. The hybrid drive vehicle ( 1 ) according to claim 1 , wherein the disengagable coupling ( 9 ) is connected to the drive shaft ( 6 ) through the interposition of a flywheel ( 18 ). 8. The hybrid drive vehicle ( 1 ) according to claim 1 , wherein the disengagable coupling ( 9 ) is directly connected to the drive shaft ( 6 ), which is completely without a flywheel. 9. The hybrid drive vehicle ( 1 ) according to claim 1 , wherein the clutch ( 26 ) of the coupling ( 9 ) is sized so as to transmit a maximum torque, which is less than the maximum torque that can be generated by the internal combustion engine ( 5 ) and is equal to the starting torque needed to start the internal combustion engine ( 5 ) starting from the standstill condition. 10. The hybrid drive vehicle ( 1 ) according to claim 1 , wherein the shape coupling device ( 29 ) is functionally arranged parallel to the clutch ( 26 ) so that it is able to make the shaft ( 10 ) of the electric machine ( 8 ) angularly integral to the drive shaft ( 6 ) instead of to the clutch ( 26 ). 11. The hybrid drive vehicle ( 1 ) according to claim 1 , wherein the gearbox ( 12 ) is provided with at least one additional clutch ( 13 ) which is completely separate and independent from the clutch ( 26 ) of the coupling ( 9 ). 12. The control method according to claim 11 , wherein the internal combustion engine ( 5 ) is turned off when the coupling ( 9 ) is engaged until the shape mating is obtained and is turned on again immediately after shape mating is achieved. 13. A control method for the hybrid drive vehicle ( 1 ) according to claim 1 and comprising, in order to start the internal combustion engine ( 5 ) starting from the standstill condition and with the vehicle ( 1 ) in motion, the steps of: partially engaging the coupling ( 9 ) in order to operate the single clutch ( 26 ) of the coupling ( 9 ); starting the internal combustion engine ( 5 ) once the drive shaft ( 6 ) has reached the minimum starting speed; completely disengaging the coupling ( 9 ) once the internal combustion engine ( 5 ) has started; controlling the internal combustion engine ( 5 ) so as to cause the drive shaft ( 6 ) to rotate at substantially the same speed as the shaft ( 10 ) of the electric machine ( 8 ); and completely engaging the coupling ( 9 ) until the shape mating is obtained, when the drive shaft ( 6 ) rotates at substantially the same speed as the shaft ( 10 ) of the electric machine ( 8 ). 14. The control method according to claim 13 , wherein the internal combustion engine ( 5 ) is controlled so as to reach a rotation speed that is slightly faster than the rotation speed of the electric machine ( 8 ), before completely engaging the coupling ( 9 ) until the shape mating is obtained. 15. A control method for the hybrid drive vehicle ( 1 ) according to claim 1 and comprising, in order to start the internal combustion engine ( 5 ) starting from the standstill condition and with the vehicle ( 1 ) stationary, the steps of: partially engaging the coupling ( 9 ) so as to operate the single clutch ( 26 ) of the coupling ( 9 ) until the drive shaft ( 6 ) is synchronous with the shaft ( 10 ) of the electric machine ( 8 ); completely engaging the coupling ( 9 ) until the shape mating is obtained, when the drive shaft ( 6 ) is synchronous with the shaft ( 10 ) of the electric machine ( 8 ); and starting the internal combustion engine ( 5 ) once the shape mating of the coupling ( 9 ) has been obtained. 16. A control method for the hybrid drive vehicle ( 1 ) according to claim 1 and comprising, in order to start the inte