Control apparatus for rotating machine

What is claimed is: 1. A control apparatus for a rotating machine in a system including the rotating machine having a stator, around which a winding wire is wound, and a power conversion circuit electrically connected to the rotating machine to apply a voltage to the winding wire, wherein a fluctuating angular velocity of a fundamental wave current flowing in the winding wire is defined as a fundamental angular velocity, wherein a current having a fluctuating angular velocity obtained by multiplying the fundamental angular velocity by an integer equal to or more than 2, which is defined as K, is defined as a K-th order harmonic current, and wherein an electromagnetic force acting on the rotating machine and having the fluctuating angular velocity obtained by multiplying the fundamental angular velocity by the integer is defined as a K-th order electromagnetic force, the control apparatus comprising: a superimposition device that superimposes a plurality of harmonic currents, for converting a first electromagnetic force to a second electromagnetic force, on the fundamental wave current, the first electromagnetic force being a second or higher order electromagnetic force as a reduction object, the second electromagnetic force being a second or higher order electromagnetic force and different from the first electromagnetic force, an order of each harmonic current being disposed in a range between an order of the first electromagnetic force and an order of the second electromagnetic force; and a manipulation device that operates the power conversion circuit so as to flow the fundamental wave current, on which the plurality of harmonic currents are superimposed, in the winding wire. 2. The control apparatus according to claim 1 , wherein the order of the first electromagnetic force is defined as 6×M+2×L, wherein M is an integer, and L is an integer, wherein the order of the second electromagnetic force is defined as 6×M+2×N, wherein N is an integer different from L, and wherein the superimposition device superimposes all of the plurality of harmonic currents having odd number orders, which is disposed in a range between (6×M+2×L)-th order and (6×M+2×N)-th order. 3. The control apparatus according to claim 2 , wherein L is −1, and N is +1, and wherein the superimposition device superimposes a (6×M−1)-th order harmonic current and a (6×M+1)-th order harmonic current on the fundamental wave current so that the first electromagnetic force having a (6×M−2)-th order is converted to the second electromagnetic force having a (6×M+2)-th order. 4. The control apparatus according to claim 2 , wherein L is −1 and +1, and N is +1 and −1, wherein the superimposition device superimposes a (6×M−1)-th order harmonic current and a (6×M+1)-th order harmonic current on the fundamental wave current so that the first electromagnetic force having a (6×M−2)-th order is converted to the second electromagnetic force having a (6×M+2)-th order, and wherein the superimposition device superimposes a (6×M+1)-th order harmonic current and a (6×M−1)-th order harmonic current on the fundamental wave current so that the first electromagnetic force having a (6×M+2)-th order is converted to the second electromagnetic force having a (6×M−2)-th order. 5. The control apparatus according to claim 3 , wherein one of the (6×M−1)-th order harmonic current and the (6×M+1)-th order harmonic current is defined as a first harmonic current, and the other of the (6×M−1)-th order harmonic current and the (6×M+1)-th order harmonic current is defined as a second harmonic current, wherein, when the first harmonic current flows through the winding wire, an electromagnetic force is generated, and the electromagnetic force represents a first vector, which extends from an original point of a biaxial orthogonal coordinate system, wherein, when the second harmonic current flows through the winding wire, another electromagnetic force is generated, and the another electromagnetic force represents a second vector, which extends from the original point of the biaxial orthogonal coordinate system, wherein a reference axis extends from the original point of the biaxial orthogonal coordinate system toward a direction opposite to the first vector, wherein the reference axis intersects with a circle, which has a radius equal to a magnitude of the first vector and around the original point as a center, at an intersection point as a reference center, and wherein a region located inside of a circumference of another circle having a radius equal to the magnitude of the first vector around the reference center is defined as a reduction allowance region, the control apparatus further comprising: a storage device that stores information related to the first harmonic current in association with a rotation speed of the rotating machine; a first determination device hat determines the first harmonic current flowing in the winding wire according to the rotation speed and the information related to the first harmonic current and stored in the storage device; and a second determination device that determines the second harmonic current, which controls a front end of the second vector to be disposed in the reduction allowance region, according to the first harmonic current determined by the first determination device, wherein the superimposition device superimposes the first harmonic current determined by the first determination device and the second harmonic current determined by the second determination device on the fundamental wave current. 6. The control apparatus according to claim 5 , wherein the storage device stores a determination level indicative of information for specifying a reduction degree of the magnitude of the first vector, and wherein the second determination device determines the second harmonic current based on the first harmonic current and the determination level. 7. The control apparatus according to claim 6 , wherein an angle between the first vector and the second vector with reference to the extending direction of the first vector is defined as a positive value when the second vector rotates around the original point in a counterclockwise direction, and wherein the second determination device determines the second harmonic current to satisfy any one of a first condition, a second condition and a third condition according to the first harmonic current and the determination level, wherein the first condition is such that an amplitude ratio obtained by dividing a magnitude of the second vector by the magnitude of the first vector is larger than 0 and less than 1 when the angle is 120° or 240°, wherein the second condition is such that the amplitude ratio is larger than 1 and less than 2 when the angle is larger than 120° and less than 180° or when the angle is larger than 180° and less than 240°, and wherein the third condition is such that the amplitude ratio is larger than 0 and less than 2 when the angle is 180°. 8. The control apparatus according to claim 7 , wherein the second determination device provides a determined second harmonic current as the harmonic current to flow in the winding wire. 9. The control apparatus according to claim 7 , wherein the storage device stores information of the second harmonic current in association with the rotation speed of the rotating machine, wherein the second determination device retrieves the information of the second harmonic current, which satisfies any one of the first condition, the second condition and the third condition, from the information of the second harmonic current stored in the storage device according to the first harmonic current and the determination level, and wherein the second determina