Failure diagnostic apparatus and method for current sensors of 3-phase brushless AC motor

What is claimed is: 1. A failure diagnostic apparatus for a 3-phase motor comprising current sensors each configured to measure a phase current of the 3-phase motor, the apparatus comprising: a control unit configured periodically calculate a phase current error using the phase current fed back through each of the current sensors, and diagnose that a failure occurred in one of the current sensors, when an error count accumulated during a preset time reaches a preset value, based on the phase current error, wherein the control unit is further configured to: obtain an angle (A) of a motor rotor, calculate a current sum vector (Im) in each of three cases of the rotor angle (A), wherein the three cases comprise a case in which the rotor angle (A) ranges from 330° to 30° or from 150° to 210°, a case in which the rotor angle (A) ranges from 30° to 90° or from 210° to 270°, and a case in which the rotor angle A ranges from 90° to 150° or from 270° to 330°, calculate phase current errors (Du, Dv and Dw) at a preset time interval according to the rotor angle detected in each of the three cases, accumulate an error count when the calculated phase current errors are equal to or more than a preset value, detect whether the error count for each phase, accumulated during a preset time, reaches an another preset value, and diagnose a failure occurred in a current sensor, when the error count reaches the preset value, wherein when the rotor angle ranges from 330° to 30° or from 150° to 210°, the control unit is further configured to calculate the current sum vector Im according to Im=Iu/cos(A), and is configured to calculate the phase current errors (Du, Dv and Dw) according to Du=0, Dv=Im×cos(A−(2/3)π)−Ivf, and Dw=Im×cos(A+(2/3)π)−Iwf, where A is a rotor angle, Iu is a phase current of the 3-phase motor, and Ivf and Iwf are actually sensed currents. 2. The failure diagnostic apparatus of claim 1 , wherein the rotor angle is detected through an encoder. 3. The failure diagnostic apparatus of claim 1 , wherein one of the phase current errors is detected as zero at any one phase according to the rotor angle in each of the three cases, and the other phase current errors are detected only at the other two phases. 4. The failure diagnostic apparatus of claim 1 , wherein the control unit is further configured to calculate a current which is expected to flow for each phase, and to calculate the phase current errors by subtracting currents measured through the current sensors, from the calculated current. 5. A failure diagnostic method for a 3-phase motor comprising current sensors each configured to measure a phase current of the 3-phase motor, the method comprising: obtaining, by a control unit of the 3-phase motor, an angle (A) of a motor rotor; calculating, by the control unit, a current sum vector (Im) in each of three cases of the rotor angle (A), wherein the three cases comprise a case in which the rotor angle (A) ranges from 330° to 30° or from 150° to 210°, a case in which the rotor angle (A) ranges from 30° to 90° or from 210° to 270°, and a case in which the rotor angle (A) ranges from 90° to 150° or from 270° to 330°; calculating, by the control unit, phase current errors (Di, Dv, and Dw) at a preset time interval according to the rotor angle detected in each of the cases; accumulating, by the control unit, an error count when the calculated phase current errors are equal to or more than a preset value, and detecting whether the error count for each phase, accumulated during a preset time, reaches an another preset value; and diagnosing, by the control unit, that a failure occurred in a current sensor, when the error count reaches the preset value, wherein in the calculating of the current sum vector Im and the calculating of the phase current errors Du, Dv, and Dw, when the rotor angle ranges from 330° to 30° or from 150° to 210°, the control unit calculates the current sum vector (Im) according to Im=Iu/cos(A), and calculates the phase current errors (Du, Dv, and Dw) according to Du=0, Dv=Im×cos(A−(2/3)π)−Ivf, and Dw=Im×cos(A+(2/3)π)−Iwf, where A is a rotor angle, Iu is a phase current of the 3-phase motor, and Ivf and Iwf are actually sensed currents. 6. The method of claim 5 , wherein in the calculating of the current sum vector (Im) and the calculating of the phase current errors (Du, Dv, and Dw), when the rotor angle ranges from 30° to 90° or from 210° to 270°, the control unit calculates the current sum vector (Im) according to Im=Iw/cos(A+(2/3)π), and calculates the phase current errors Du, Dv, and Dw according to Du=Im×cos(A)−Iuf, Dv=Im×cos(A−(2/3)π)−Ivf, and Dw=0, where A is a rotor angle, Iw is a phase current of the 3-phase motor, and Iuf and Ivf are actually sensed currents. 7. The method of claim 5 , wherein in the calculating of the current sum vector (Im) and the calculating of the phase current errors (Du, Dv, and Dw), when the rotor angle ranges from 90° to 150° or from 270° to 330°, the control unit calculates the current sum vector Im according to Im=Iv/cos(A−(2/3)π), and calculates the phase current errors Du, Dv, and Dw according to Du=Im×cos(A)−Iuf, Dv=0, Dw=Im×cos(A+(2/3)π)−Iwf, where A is a rotor angle, Iv is a phase current of the 3-phase motor, and Iuf and Iwf are actually sensed currents. 8. The method of claim 5 , wherein one of the phase current errors is detected as zero at any one phase according to the rotor angles in each of the three cases, and the other phase current errors are detected only at the other two phases. 9. The method of claim 5 , wherein the control unit calculates a current which is expected to flow for each phase, and calculates the phase current errors by subtracting currents measured through current sensors, from the calculated current.