Machining power supply device for electric discharge machine

The invention claimed is: 1. A machining power supply device for an electric discharge machine configured to machine a workpiece by applying a voltage to a machining gap between an electrode and the workpiece to cause an electric discharge across the gap, the machining power supply device comprising: a DC power supply; a capacitor directly or indirectly connected in parallel with the machining gap; a first semiconductor switching element arranged in a first circuit loop including the DC power supply and the capacitor; a second semiconductor switching element arranged in parallel with the capacitor; a rectifier element inserted in a second circuit loop including the capacitor and the second semiconductor switching element; a third semiconductor switching element arranged in a third circuit loop including the machining gap and the capacitor; and a controller programed to control the first, second and third semiconductor switching elements, wherein the controller is programmed to during a first time period, turn on the first semiconductor switching element to fully charge the capacitor in a first direction, during a second time period after the first time period, turn off the first semiconductor switching element and turn on the third semiconductor switching element to discharge the fully charged capacitor and to charge the capacitor to a residual voltage in a second direction opposite to the first direction, and during a third time period after the second time period, turn off the third semiconductor switching element and turn on the second semiconductor switching element while the first semiconductor switching element is off to reverse the residual voltage of the capacitor. 2. A machining power supply device for an electric discharge machine configured to machine a workpiece by applying a voltage to a machining gap between an electrode and the workpiece to cause an electric discharge across the gap, the machining power supply device comprising: a DC power supply; a capacitor directly or indirectly connected in parallel with the machining gap; a first semiconductor switching element arranged in a first circuit loop including the DC power supply and the capacitor; a second semiconductor switching element arranged in parallel with the capacitor; a voltage or current detector configured to detect a voltage or a current of the capacitor; a third semiconductor switching element arranged in a second circuit loop including the machining gap and the capacitor; and a controller programed to control the first, second and third semiconductor switching elements, wherein the controller is programmed to during a first time period, turn on the first semiconductor switching element to fully charge the capacitor in a first direction, during a second time period after the first time period, turn off the first semiconductor switching element and turn on the third semiconductor switching element to discharge the fully charged capacitor and to charge the capacitor to a residual voltage in a second direction opposite to the first direction, during a third time period after the second time period, turn off the third semiconductor switching element and turn on the second semiconductor switching element while the first semiconductor switching element is off to charge the capacitor in the first direction to reduce the residual voltage of the capacitor, and turn off the second semiconductor switching element in accordance with a value of the voltage or the current of the capacitor detected by the voltage or current detector. 3. The machining power supply device according to claim 1 , wherein the third semiconductor switching element is arranged in series between the machining gap and the capacitor. 4. The machining power supply according to claim 1 , wherein the controller is further programmed to keep the third semiconductor switching element turned on during the second time period, which includes a time point when the electric discharge is detected. 5. The machining power supply according to claim 1 , wherein the controller is further programmed to turn off the second semiconductor switching element at the end of the third time period while the third switching element is turned off. 6. The machining power supply according to claim 1 , wherein the rectifier element is inserted in the second circuit loop in a direction in which the rectifier element reverses the residual voltage of the capacitor charged in the second direction.