Wind-powered thermal power generation system

The invention claimed is: 1. A wind-powered thermal power generation system, comprising: a wind turbine; an induction motor including a field which has a field core and a field conductor arranged therearound, and an armature which has an armature core provided with a salient pole facing the field and an armature winding of three phases wound around the salient pole, and configured such that one of the field and the armature serves as a rotor coupled to a rotation shaft of said wind turbine, and the other serves as a stator; magnetic field control means for applying a direct current to at least two phases of armature windings among the three phases when said rotor is rotating in conjunction with said rotation shaft as a result of said wind turbine concurrently being rotated by wind, wherein said magnetic field control means applying the direct current to the at least two phases of armature windings when the wind turbine is being rotated by wind causes slip that forcibly provides load torque to said rotor rotating in conjunction with said rotation shaft that is larger than a rated torque of said induction motor, wherein said magnetic field control means applying the direct current to the at least two phases of armature windings causes a rotational speed of said rotor to become smaller than a rated rotational speed of the induction motor at a time when the wind turbine is being rotated by wind, and wherein said magnetic field control means applying the direct current to the at least two phases of armature windings when the wind turbine is being rotated by wind causes an induced current corresponding to the load torque to flow through the field conductor of the field, which in turn causes heat to be generated by the induction motor; a heating medium circulation mechanism for circulating a heating medium that receives heat generated by said induction motor, wherein the heating medium and circulation thereof are configured to prevent heat damage to said field conductor and said armature winding, while at the same time storing at least a portion of the heat generated by the induction motor; and a power generation portion for converting, into electricity, the heat of said heating medium generated by said induction motor. 2. The wind-powered thermal power generation system according to claim 1 , further comprising a heat insulating container that houses said induction motor, wherein said heating medium circulation mechanism circulates said heating medium inside said heat insulating container. 3. A wind-powered thermal power generation system, comprising: a wind turbine; an induction motor including a field which has a field core and a field conductor arranged therearound, and an armature which has an armature core provided with a salient pole facing the field and an armature winding wound around the salient pole, and configured such that one of the field and the armature serves as a rotor coupled to a rotation shaft of said wind turbine, and the other serves as a stator; magnetic field control means having a power supply for applying to said armature winding, an alternating current having a frequency that produces stalling torque greater than a rated torque of said induction motor when said rotor is rotating in conjunction with said rotation shaft as a result of said wind turbine concurrently being rotated by wind, wherein said magnetic field control means applying the alternating current to the armature winding when the wind turbine is being rotated by wind causes slip that forcibly provides load torque to said rotor rotating in conjunction with said rotation shaft that is greater than the rated torque of said induction motor, wherein said magnetic field control means applying the alternating current to armature winding causes a rotational speed of said rotor to become smaller than a rated rotational speed of the induction motor at a time when the wind turbine is being rotated by wind, and wherein said magnetic field control means applying the alternating current to the armature winding when the wind turbine is being rotated by wind causes an induced current corresponding to the load torque to flow through the field conductor of the field, which in turn causes heat to be generated by the induction motor; a heating medium circulation mechanism for circulating a heating medium that receives heat generated by said induction motor, wherein the heating medium and circulation thereof are configured to prevent heat damage to said field conductor and said armature winding, while at the same time storing at least a portion of the heat generated by the induction motor; and a power generation portion for converting, into electricity, the heat of said heating medium generated by said induction motor.