Four-wheel-drive vehicle and method of controlling four-wheel-drive vehicle

What is claimed is: 1. A four-wheel-drive vehicle comprising: an electric motor; a pump that is actuated by torque output from the electric motor; a piston that is movable by a pressure of a working fluid discharged from the pump; a friction clutch that has a plurality of clutch plates that are pressed by the piston; a control device that controls the electric motor; a drive source that generates a drive force in accordance with an accelerator operation amount; main drive wheels to which the drive force of the drive source is always transferred; and auxiliary drive wheels to which the drive force of the drive source is transferred in accordance with a fastening force of the friction clutch, wherein the control device causes the electric motor to output torque that is larger than torque that the electric motor can continuously output when it is determined, on the basis of vehicle information including respective wheel speeds of the main drive wheels and the auxiliary drive wheels and the accelerator operation amount, that the vehicle is in a high fastening force-requiring state in which it is necessary for the friction clutch to transfer a large drive force temporarily. 2. The four-wheel-drive vehicle according to claim 1 , wherein the control device determines that the vehicle is in the high fastening force-requiring state when the vehicle is starting on a climbing road or a low-μ road, or when the vehicle is starting in a lock mode in which slipping of the friction clutch is not caused. 3. The four-wheel-drive vehicle according to claim 1 , wherein the control device determines that the vehicle is in the high fastening force-requiring state during abrupt starting in which a vehicle speed is equal to or less than a predetermined value and the accelerator operation amount is equal to or more than a predetermined value. 4. The four-wheel-drive vehicle according to claim 1 , wherein the control device determines that the vehicle is in the high fastening force-requiring state when a rotational speed difference, which is a difference between a rotational speed of the main drive wheels and a rotational speed of the auxiliary drive wheels, is equal to or more than a predetermined value, or when the vehicle is in a preliminary state in which it is foreseen that the rotational speed difference will become equal to or more than the predetermined value. 5. The four-wheel-drive vehicle according to claim 1 , wherein: the drive force of the drive source is transferred to the friction clutch via a propeller shaft; the drive force of the drive source is transferred to the propeller shaft via a mesh clutch; and the control device determines that the vehicle is in the high fastening force-requiring state when switching is made to a four-wheel-drive state during travel in a two-wheel-drive state, in which rotation of the propeller shaft is stopped with transfer of the drive force through the friction clutch and the mesh clutch blocked, and engages the mesh clutch by rotating the propeller shaft using a drive force transferred from the auxiliary drive wheels to the propeller shaft through the friction clutch. 6. The four-wheel-drive vehicle according to claim 1 , wherein: the electric motor is a three-phase brushless motor; and the control device causes the electric motor to output torque that is larger than torque that the electric motor can continuously output by performing at least one of advance angle control and overlap energization control when it is determined that the vehicle is in the high fastening force-requiring state. 7. A method of controlling a four-wheel-drive vehicle including an electric motor, a pump that is actuated by torque output from the electric motor, a piston that is movable by a pressure of a working fluid discharged from the pump, a friction clutch that has a plurality of clutch plates that are pressed by the piston, a control device that controls the electric motor, a drive source that generates a drive force in accordance with an accelerator operation amount, main drive wheels to which the drive force of the drive source is always transferred, and auxiliary drive wheels to which the drive force of the drive source is transferred in accordance with a fastening force of the friction clutch, the method comprising: determining, on the basis of vehicle information including respective wheel speeds of the main drive wheels and the auxiliary drive wheels and the accelerator operation amount, that the vehicle is in a high fastening force-requiring state in which it is necessary for the friction clutch to transfer a large drive force temporarily, and causing the electric motor to output torque that is larger than torque that the electric motor can continuously output when it is determined that the vehicle is in the high fastening force-requiring state.