Apparatus and method for insulation design of high voltage direct current transmission system

What is claimed is: 1. An apparatus for insulation design of a high voltage direct current (HVDC) transmission system, the apparatus comprising: a contingency state voltage calculation unit calculating a first insulation voltage level according to a variation in grid impedance of an AC part of the HVDC transmission system based on grid data of an insulation basic model of the HVDC transmission system when the HVDC transmission system is in a contingency state; a case analysis performance unit using the calculated first insulation voltage level to perform a case analysis of the HVDC transmission system in the contingency state in order to calculate a maximum insulation voltage level; and a rated insulation level calculation unit applying the calculated maximum insulation voltage level to the insulation basic model and performing the insulation design on the insulation basic model to which the calculated maximum insulation voltage level is applied in order to calculate a rated insulation level of the HVDC transmission system. 2. The apparatus according to claim 1 , further comprising a normal state voltage calculation unit calculating a second insulation voltage level of the AC part of the HVDC transmission system when the HVDC transmission system is in a normal state based on the grid data of the insulation basic model, wherein the case analysis performance unit further uses the calculated second insulation voltage and the calculated first insulation voltage level to perform the case analysis. 3. The apparatus according to claim 2 , wherein the normal state voltage calculation unit further calculates the second insulation voltage level according to a variation in grid impedance of the AC part of the HVDC transmission system in the normal state. 4. The apparatus according to claim 3 , wherein the normal state voltage calculation unit further calculates the second insulation voltage level according to a variation in voltage and grid impedance of the AC part of the HVDC transmission system in the normal state; and the contingency state voltage calculation unit further calculates the first insulation voltage level according to a variation in voltage and grid impedance of the AC part of the HVDC transmission system in the contingency state. 5. The apparatus according to claim 4 , further comprising: a normal state voltage verification unit verifying the calculated second insulation voltage level; and a contingency state voltage verification unit verifying the calculated first insulation voltage level, wherein the case analysis performance unit further uses the verified second insulation voltage level and the verified first insulation voltage level to perform the case analysis. 6. The apparatus according to claim 1 , further comprising: a model generation unit modeling the HVDC transmission system to generate the insulation basic model; and an impedance mapping unit performing impedance mapping of the insulation basic model to acquire the grid data. 7. The apparatus according to claim 1 , wherein: the case analysis performance unit further uses the calculated first insulation voltage level to calculate grid impedance for the calculated maximum insulation voltage level; and the rated insulation level calculation unit further applies the calculated grid impedance to the insulation basic model. 8. The apparatus according to claim 1 , wherein the calculated rated insulation level comprises a voltage value and distance value at at least one position of the HVDC transmission system. 9. An apparatus for insulation design of a high voltage direct current (HVDC) transmission system, the apparatus comprising: a contingency state voltage calculation unit calculating a first insulation voltage level according to a variation in grid impedance of an AC part of the HVDC transmission system based on grid data of an insulation basic model of the HVDC transmission system when the HVDC transmission system is in a contingency state; a case analysis performance unit using the calculated first insulation voltage level to perform a case analysis of the HVDC transmission system in the contingency state in order to calculate a maximum insulation voltage level; a rated insulation level calculation unit applying the calculated maximum insulation voltage level to the insulation basic model and performing the insulation design on the insulation basic model to which the calculated maximum insulation voltage level is applied in order to calculate a rated insulation level of the HVDC transmission system; a normal state voltage calculation unit calculating a second insulation voltage level of the AC part of the HVDC transmission system when the HVDC transmission system is in a normal state based on the grid data of the insulation basic model, wherein the case analysis performance unit further uses the calculated second insulation voltage and the calculated first insulation voltage level to perform the case analysis, wherein the normal state voltage calculation unit further calculates the second insulation voltage level according to a variation in grid impedance of the AC part of the HVDC transmission system in the normal state, wherein the normal state voltage calculation unit further calculates the second insulation voltage level according to a variation in voltage and grid impedance of the AC part of the HVDC transmission system in the normal state, and wherein the contingency state voltage calculation unit further calculates the first insulation voltage level according to a variation in voltage and grid impedance of the AC part of the HVDC transmission system in the contingency state; a normal state voltage verification unit verifying the calculated second insulation voltage level; and a contingency state voltage verification unit verifying the calculated first insulation voltage level, wherein the case analysis performance unit further uses the verified second insulation voltage level and the verified first insulation voltage level to perform the case analysis, wherein the normal state voltage verification unit further verifies power stability of the calculated second insulation voltage level, and wherein the contingency state voltage verification unit further verifies power stability of the calculated first insulation voltage level. 10. The apparatus according to claim 9 , wherein each of the normal state voltage verification unit and the contingency state voltage verification unit utilizes a power system simulator for engineering (PSS/E) software.