Transformer fault detection apparatus and method

What is claimed is: 1. A transformer fault detection apparatus, comprising: an integrated sensor unit for sensing signals through a plurality of sensors located on each of an upper drain valve and a lower drain valve present in a transformer; a first possible discharge area calculation unit for calculating a first possible discharge area estimated to be a location of a partial discharge source of the transformer, based on arrival times of signals sensed by different sensors located on the upper drain valve; a second possible discharge area calculation unit for calculating a second possible discharge area estimated to be the location of the partial discharge source of the transformer, based on arrival times of signals sensed by different sensors located on the lower drain valve; a final possible discharge area calculation unit for calculating a final possible discharge area estimated to be the location of the partial discharge source of the transformer, based on an overlapping area between the first possible discharge area and the second possible discharge area; and a partial discharge source location estimation unit for estimating the location of the partial discharge source from the final possible discharge area, based on a difference between arrival times of an identical signal that has reached a sensor located on the upper drain valve and a sensor located on the lower drain valve, wherein the first possible discharge area calculation unit calculates a three-dimensional (3D) first possible discharge area, based on a difference between arrival times of a first electromagnetic signal sensed by a first electromagnetic sensor located on the upper drain valve and a first ultrasonic signal sensed by a first ultrasonic sensor located on the upper drain valve, wherein the second possible discharge area calculation unit calculates a 3D second possible discharge area, based on a difference between arrival times of a second electromagnetic signal sensed by a second electromagnetic sensor located on the lower drain valve and a second ultrasonic signal sensed by a second ultrasonic sensor located on the lower drain valve, wherein the final possible discharge area calculation unit calculates a two-dimensional (2D) final possible discharge area generated by causing a point, at which the 3D first possible discharge area and the 3D second possible discharge area intersect each other, to be included in a circumference. 2. The transformer fault detection apparatus of claim 1 , further comprising a possible discharge area correction unit for correcting the first possible discharge area and the second possible discharge area based on media of the signals. 3. The transformer fault detection apparatus of claim 1 , wherein the integrated sensor unit comprises at least one ultrasonic sensor and at least one electromagnetic sensor, wherein the ultrasonic sensor and the electromagnetic sensor are integrally coupled to each other. 4. The transformer fault detection apparatus of claim 1 , wherein the partial discharge source location estimation unit estimates the location of the partial discharge source from the final possible discharge area, based on a difference between arrival times of the first electromagnetic signal and the second electromagnetic signal. 5. The transformer fault detection apparatus of claim 4 , wherein the integrated sensor unit further comprises a gas sensor located on the upper drain valve or the lower drain valve and configured to sense gas contained in insulating oil present in the transformer while being in direct contact with the insulating oil. 6. The transformer fault detection apparatus of claim 4 , wherein the integrated sensor unit further comprises a temperature sensor located on the upper drain valve or the lower drain valve and configured to sense a temperature of the insulating oil present in the transformer. 7. A transformer fault detection method, comprising: calculating, by a first possible discharge area calculation unit, a first possible discharge area estimated to be a location of a partial discharge source of a transformer, based on arrival times of signals sensed by different sensors located on an upper drain valve present in an upper portion of the transformer; calculating, by a second possible discharge area calculation unit, a second possible discharge area estimated to be the location of the partial discharge source of the transformer, based on arrival times of signals sensed by different sensors located on a lower drain valve present in a lower portion of the transformer; calculating, by a final possible discharge area calculation unit, a final possible discharge area estimated to be the location of the partial discharge source of the transformer, based on an overlapping area between the first possible discharge area and the second possible discharge area; and after calculating the final possible discharge area, estimating the location of the partial discharge source from the final possible discharge area, based on a difference between arrival times of an identical signal that has reached a sensor located on the upper drain valve and a sensor located on the lower drain valve, wherein calculating the first possible discharge area comprises calculating a three-dimensional (3D) first possible discharge area, based on a difference between arrival times of a first electromagnetic signal sensed by a first electromagnetic sensor located on the upper drain valve and a first ultrasonic signal sensed by a first ultrasonic sensor located on the upper drain valve, wherein calculating the second possible discharge area comprises calculating a 3D second possible discharge area, based on a difference between arrival times of a second electromagnetic signal sensed by a second electromagnetic sensor located on the lower drain valve and a second ultrasonic signal sensed by a second ultrasonic sensor located on the lower drain valve, wherein calculating the final possible discharge area comprises calculating a two-dimensional (2D) final possible discharge area generated by causing a point, at which the 3D first possible discharge area and the 3D second possible discharge area intersect each other, to be included in a circumference. 8. The transformer fault detection method of claim 7 , further comprising correcting the first possible discharge area and the second possible discharge area based on media of the signals. 9. The transformer fault detection method of claim 7 , wherein the upper drain valve and the lower drain valve are configured such that an ultrasonic sensor and an electromagnetic sensor are located on each of the upper drain valve and the lower drain valve, the ultrasonic sensor and the electromagnetic sensor being integrally coupled to each other. 10. The transformer fault detection method of claim 7 , wherein estimating the location of the partial discharge source comprises estimating the location of the partial discharge source from the final possible discharge area, based on a difference between arrival times of the first electromagnetic signal and the second electromagnetic signal. 11. The transformer fault detection method of claim 10 , further comprising sensing gas contained in insulating oil present in the transformer through a gas sensor located on the upper drain valve or the lower drain valve and configured to be in direct contact with the insulating oil. 12. The transformer fault detection method of claim 10 , further comprising sensing a temperature of insulating oil present in the transformer through a temperature sensor located on the upper drain valve or the lower drain valve.