Automatic suppression device for cyclic disturbance

1 . A periodic disturbance automatic suppressing apparatus including a compensating table of values of a torque compensating quantity for suppressing torque pulsation, prepared beforehand by extracting a torque pulsation frequency component of a controlled object, determining the torque compensating quantity by inputting a torque command and a sensed rotational speed and suppressing torque pulsation of the controlled object at each frequency component by inputting a deviation between the torque compensating quantity and the torque command into the controlled object, the compensating table being a collection of compensation tables and the apparatus being configured to sense a main power source voltage of the controlled object, to input into the compensation table corresponding to the main power source voltage and to output the torque compensating quantity related with variation of the main power source voltage. 2 . A periodic disturbance automatic suppressing apparatus including a compensating table of values of a torque compensating quantity for suppressing torque pulsation, prepared beforehand by extracting a torque pulsation frequency component of a controlled object, determining the torque compensating quantity by inputting a torque command and a sensed rotational speed of the controlled object and suppressing torque pulsation of the controlled object at each frequency component by inputting a deviation between the torque compensating quantity and the torque command into the controlled object, the compensating table including a real part compensating table for correcting a real part and an imaginary part compensating table for correcting an imaginary part, and a compensation correcting section is provided to receive a sensed value of a main power source voltage V of the controlled object, and configured to correct the torque compensating quantity Tcn determined by a sum of an output Ta of the real part compensating table and a quantity jTb of the imaginary part compensating table, with a predetermined table or a proportional expression related with variation of the main power source voltage. 3 . The periodic disturbance automatic suppressing apparatus as claimed in claim 2 , wherein the proportional expression for correcting the torque compensating quantity Tcn is a linear polynomial expressed by; Tc n =Ta n ·( a·V+b )+ jTb n ·( c·V+d ) where a suffix n represents an nth order component. 4 . The periodic disturbance automatic suppressing apparatus as claimed in claim 2 , wherein there is provided a coefficient table to receive, as inputs, the torque command and the sensed rotational speed of the controlled object, to output a coefficient of the polynomial in dependence on torque and rotational speed, and to deliver the output of the coefficient table to the compensation correcting section, and the compensation correcting section is configured to correct the torque compensating quantity Tcn with the predetermined table or the proportional expression in dependence on the torque and rotational speed. 5 . The periodic disturbance automatic suppressing apparatus as claimed in claim 4 , wherein the proportional expression for correcting the torque compensating quantity Tcn is a linear polynomial expressed by; Tc n =Ta n ·{fa ( T cmd ,N )· V+fb ( T cmd ,N )}+ jTb n ·{fc ( T cmd ,N )· V+fd ( T cmd ,N )} where fa·fd are coefficients, T cmd is the torque command, N is the rotational speed, V is the sensed voltage and n represents an nth order component. 6 . The periodic disturbance automatic suppressing apparatus as claimed in claim 2 , wherein there is provided a coefficient table to receive, as an input, the torque command, to output a coefficient of the polynomial in dependence on the torque, and to delivers the output of the coefficient table to the compensation correcting section and the compensation correcting section is configured to correct the torque compensating quantity Tcn with the predetermined table or the proportional expression in dependence on the torque. 7 . The periodic disturbance automatic suppressing apparatus as claimed in claim 6 , wherein the proportional expression for correcting the torque compensating quantity Tcn is a linear polynomial expressed by; Tc n =Ta n ·{fa ( T cmd )· V+fb ( T cmd )}+ jTb n ·{fc ( T cmd )· V+fd ( T cmd )} where fa˜fd are coefficients, T cmd is the torque command, V is the sensed voltage and n represents an nth order component. 8 . The periodic disturbance automatic suppressing apparatus as claimed in claim 2 , wherein there is provided a coefficient table to receive, as input, the sensed rotational speed of the controlled object, to output a coefficient of the polynomial in dependence on the rotational speed, and to delivers the output of the coefficient table to the compensation correcting section and the compensation correcting section is configured to correct the torque compensating quantity Tcn with the predetermined table or the proportional expression in dependence on the rotational speed. 9 . The periodic disturbance automatic suppressing apparatus as claimed in claim 8 , wherein the proportional expression for correcting the torque compensating quantity Tcn is a linear polynomial expressed by; Tc n =Ta n ·{fa ( N )· V+fb ( N )}+ jTb n ·{fc ( N )· V+fd ( N )} where fa˜fd are coefficients, N is the rotational speed, V is the sensed voltage and n represents an nth order component. 10 . A periodic disturbance automatic suppressing apparatus preparing a compensating table of values of a torque compensating quantity for suppressing torque pulsation by extracting a torque pulsation frequency component of a controlled object, determining the torque compensating quantity by inputting a torque command and a sensed rotational speed of the controlled object and suppressing torque pulsation of the controlled object at each frequency component by inputting a deviation between the torque compensating quantity and the torque command into the controlled object, the controlled object employing a battery as a main power source, and including a voltage control section to control a voltage, and the compensating table being a table generated with compensating values by an applied voltage adjusted at each of operating points by the voltage controlling section.