Electrostatic coater and electrostatic coating method

What is claimed is: 1. An electrostatic coater that charges an atomized paint to cause the atomized paint to electrostatically attach to a workpiece, the electrostatic coater comprising: a first high-voltage generator configured to generate a first high voltage for charging the atomized paint during operation in which the workpiece is coated by using the electrostatic coater; a second high-voltage generator configured to generate a second high voltage of reverse polarity of the first high voltage generated by the first high-voltage generator; a controller coupled to the first high-voltage generator and the second high-voltage generator wherein the controller is configured to monitor current flow between the workpiece and the controller to detect an abnormal current value, and wherein the controller is configured to control the second high-voltage generator to generate the second high voltage to reduce a charge on the electrostatic coater upon receiving power immediately after power to the first high-voltage generator is stopped in response to detection of the abnormal current value, wherein the charge is reduced by neutralizing the first high voltage with the second high voltage; and a rectifying device that prevents a current from flowing through the second high-voltage generator during electrostatic coating as the first high voltage generated by the first high-voltage generator is supplied to the electrostatic coater, wherein the rectifying device and the second high-voltage generator are connected in series. 2. The electrostatic coater of claim 1 , wherein the controller includes a safety circuit that forcibly stops power to the first high-voltage generator when detecting the abnormal current value, and when the safety circuit is operated, power is supplied to the second high-voltage generator for a predetermined time period. 3. The electrostatic coater of claim 2 , further comprising: a resistance interposed in a conducting wire configured to carry the second high voltage generated by the second high-voltage generator to a charged portion of the electrostatic coater. 4. The electrostatic coater of claim 3 , wherein the resistance is composed of a semiconductor. 5. The electrostatic coater of claim 1 , further comprising: a resistance interposed in a conducting wire configured to carry the second high voltage generated by the second high-voltage generator to a charged portion of the electrostatic coater. 6. The electrostatic coater of claim 5 , wherein the resistance is composed of a semiconductor. 7. The electrostatic coater of claim 1 , wherein the second high-voltage generator is configured to reduce the charge as a distance between the electrostatic coater and the workpiece is decreased. 8. The electrostatic coater of claim 1 , wherein the controller supplies power to the second high-voltage generator for a predetermined time period and then stops power to the second high-voltage generator. 9. The electrostatic coater of claim 1 , wherein the first high-voltage generator or the second high-voltage generator is a high tension generator. 10. The electrostatic coater of claim 1 , comprising a first electrical pathway between the controller and the first high-voltage generator, wherein the first electrical pathway comprises the first high-voltage generator and a bleeder resistor, wherein the first high-voltage generator and the bleeder resistor are connected in series, and wherein the bleeder resistor is upstream from the first-high voltage generator. 11. The electrostatic coater of claim 10 , comprising a second electrical pathway between the controller and the rectifying device, wherein the second electrical pathway comprises the rectifying device and the second high-voltage generator, and wherein the rectifying device is downstream from the second high-voltage generator. 12. An electrostatic coater, comprising: a first generator configured to provide a charge to a spray; and an ion generator, wherein the ion generator is configured to generate ions of reverse polarity from that of a high voltage generated by the first generator, the ion generator is arranged in an air passage configured to supply air to the electrostatic coater; and a controller coupled to the first generator and the ion generator, wherein the controller is configured to monitor current flow between a workpiece and the controller to detect an abnormal current value, and wherein the controller controls the ion generator to neutralize a charged state of the electrostatic coater upon receiving power in response to detection of the abnormal current value, and wherein the air ionized by the ion generator is supplied to the electrostatic coater immediately after power supply to the first generator is stopped. 13. The electrostatic coater of claim 12 , wherein the first generator comprises a first high-voltage generator. 14. An electrostatic coater configured to charge an atomized paint to cause the atomized paint to electrostatically attach to a workpiece, the electrostatic coater comprising: a first high-voltage generator configured to generate a high voltage to charge the atomized paint during operation in which the workpiece is coated by using the electrostatic coater; a second high-voltage generator configured to generate a high voltage of reverse polarity of the high voltage generated by the first high-voltage generator; a controller coupled to the first high-voltage generator and the second high-voltage generator, wherein the controller is configured to monitor current flow between the workpiece and the controller to detect an abnormal current value, and wherein the controller is configured to control the second high-voltage generator to generate the high voltage for neutralizing a charged state of the electrostatic coater upon receiving power immediately after power to the first high-voltage generator is stopped in response to detection of the abnormal current value; a rectifying device configured to prevent a current from flowing through the second high-voltage generator during electrostatic coating as the first high-voltage generated by the first high-voltage generator is supplied to the electrostatic coater, wherein the rectifying device and the second high-voltage generator are connected in series; and a first electrical pathway between the controller and the first high-voltage generator, wherein the first electrical pathway comprises the first high-voltage generator and a bleeder resistor, wherein the first high-voltage generator and the bleeder resistor are connected in series, and wherein the bleeder resistor is upstream from the first-high voltage generator.