Non-contact discharge test method and device

The invention claimed is: 1. A non-contact discharge test method of evaluating, in a non-contact manner, the magnitude of discharge or spark of a measurement object on the basis of optical light emission data obtained by optically measuring a light emission phenomenon occurring as a result of the discharge or spark, the method comprising: creating a database by applying a voltage or current from a known power source to the measurement object such that light emission of discharge or spark occurs, measuring an area of a light intensity waveform which is an integral value of the discharge light emission intensity through use of a light emission measuring device and simultaneously measuring area of a current waveform of the discharge or spark which is an integral value of a discharge current value through use of a current measuring device, and storing the relation between analysis data sets obtained through analysis of the intensity waveform of the light emission and the current waveform of the discharge or spark in the database on the basis of applied power supply information which is information of the voltage or current applied to the measurement object; detecting an electromagnetic wave generated as a result of the discharge or spark of the measurement object, and measuring the intensity waveform of the light emission of the discharge or spark generated from the measurement object by using the light emission measuring device or a second light emission measuring device, wherein the second light emission measuring device is identical to the light emission measuring device, while using the electromagnetic wave as a timing reference for the generation of the discharge or spark; and comparing light emission data obtained through analysis of the measured intensity waveform of the light emission of the discharge or spark with the data recorded in the database to thereby estimate the magnitude of the discharge or spark as a value. 2. A non-contact discharge test method according to claim 1 , further comprising: disposing each of the light emission measuring device and the current measuring device in a shield box. 3. A non-contact discharge test method according to claim 1 , further comprising using the method in a lightning resistance test, wherein the test comprises using an impulse power source as the known power source causing the light emission of the discharge or spark, and using a current detector or a voltage detector to detect the applied power supply information. 4. A non-contact discharge test method according to claim 1 , wherein the magnitude of the discharge or spark is a charge amount which is an integral value of the current of the discharge or spark, or the energy of the discharge or spark. 5. A non-contact discharge test device for evaluating, in a non-contact manner, the magnitude of discharge or spark of a measurement object on the basis of optical light emission data obtained by optically measuring a light emission phenomenon occurring as a result of the discharge or spark, the device comprising: a shielded light emission measuring device for measuring an area of a light intensity waveform which is an integral value of the discharge light emission intensity by applying a voltage or current from a known power source to the measurement object such that light emission of discharge or spark occurs; a shielded current measuring device for measuring an area of a current waveform of the discharge or spark; a database in which the relation between analysis data sets obtained through analysis of the intensity waveform of the light emission and the current waveform of the discharge or spark is recorded on the basis of applied power supply information which is information of the voltage or current applied to the measurement object; an antenna for detecting an electromagnetic wave generated as a result of the discharge or spark of the measurement object; a waveform intensity obtaining device for measuring the intensity waveform of the light emission of the discharge or spark generated from the measurement object and obtaining the waveform intensity of the intensity waveform, which is measured by using the light emission measuring device or a second light emission measuring device, wherein the second light emission measuring device is identical to the light emission measuring device, while using the electromagnetic wave as a timing reference for the generation of the discharge or spark; a waveform analyzing section for analyzing the waveform intensity obtained by the waveform intensity obtaining device; a comparison section for comparing light emission data obtained as a result of the analysis by the waveform analyzing section with the data recorded in the database to thereby estimate the magnitude of the discharge or spark as a value; and a display section for displaying the estimated magnitude of the discharge or spark. 6. A non-contact discharge test device according to claim 5 , wherein an impulse power source is used as the known power source so as to cause the light emission of the discharge or spark for performing a lightning resistance test, and the applied power supply information is detected through use of a current detector or a voltage detector. 7. A non-contact discharge test device according to claim 5 , wherein the magnitude of the discharge or spark is a charge amount which is an integral value of the current of the discharge or spark, or the energy of the discharge or spark. 8. A non-contact discharge test device according to claim 5 , wherein the light emission measuring device is disposed to face the measurement object through an optical guide. 9. A method of evaluating a magnitude of an electrical discharge, the method comprising the steps of: creating a plurality of different reference electrical discharges to create a database; measuring a light intensity waveform of each of the plurality of reference electrical discharges; determining an integral of the light intensity waveform for each of the plurality of reference electrical discharges; measuring a current intensity waveform of each of the plurality of reference electrical discharges; determining an integral of the current intensity waveform for each of the plurality of reference electrical discharges; storing a relationship of the light intensity waveform, the current intensity waveform, the integral of the light intensity waveform and the integral of the current intensity waveform in the database for each of the plurality of reference electrical discharges; performing a test electrical discharge; measuring a light intensity waveform of the test electrical discharge; determining an integral of the light intensity waveform for the test electrical discharge; estimating a magnitude of the test electrical discharge using the integral of the light intensity waveform for the test electrical discharge and the relationships stored in the database. 10. A method in accordance with claim 9 , wherein: the estimated magnitude of the test electrical discharge is an integral value of the current of the test electrical discharge. 11. A method in accordance with claim 9 , wherein: the estimated magnitude of the test electrical discharge is an energy of the test electrical discharge. 12. A method in accordance with claim 9 , further comprising the steps of: determining an energy of each of the plurality of reference electrical discharges; storing a relationship of the energy of the plurality of reference electrical discharges to the light intensity waveform, to the current intensity waveform, to the integral of the light intensity waveform and to the integral of the current intensity waveform in the