Forced charging method for PHEV vehicles using motor and HSG

What is claimed is: 1. A method of forcibly charging a high-voltage battery using a motor and a Hybrid Starter Generator (HSG), comprising: sensing, by a controller, speeds and temperatures of the motor and the HSG; calculating, by the controller, maximum chargeable power using three dimensional (3D) maximum charging power maps based on speeds, and torque (power), and torque applying times of the motor and the HSG; forcibly charging, by the controller, the high-voltage battery with the maximum chargeable power; adjusting, by the controller, maximum charging power using energy integration during the forced charging; executing, by the controller, a first excessive temperature prevention logic for the motor and the HSG to continuously perform the forced charging by one of the motor and the HSG, during the forced charging of the high-voltage battery using the motor and the HSG simultaneously; and executing, by the controller, a second excessive temperature prevention logic for adjusting current temperatures of the motor and the HSG below an operating power limiting temperature to maximize a time of an Electric Vehicle (EV) driving mode in which a vehicle is driven through motor-only operation, in response to the forced charging of the high voltage battery being completed. 2. The method of claim 1 , wherein the adjustment of the maximum charging power includes: operating, by the controller, the motor and the HSG simultaneously to output the maximum charging power, integrating, by the controller, power of the motor and the HSG; and comparing, by the controller, amounts of the integrated power of the motor and the HSG to the 3D maximum charging power maps to extract and determine usable charging power of the motor and the HSG from the 3D maximum charging power maps. 3. The method of claim 2 , wherein the adjustment of the maximum charging power includes reducing, by the controller, charging power of the motor and the HSG in response to an increase in the amounts of the integrated power of the motor and the HSG. 4. The method of claim 1 , wherein the adjustment of the maximum charging power includes reducing, by the controller, charging power of the motor and the HSG in response to an increase in amounts of the integrated power of the motor and the HSG. 5. The method of claim 1 , wherein the execution of the first excessive temperature prevention logic includes: comparing, by the controller, the current temperatures of the motor and the HSG to a charging power limiting temperature; continuing to forcibly charge, by the controller, the high-voltage battery using the HSG in response to the motor being in a motor power limited state in which the temperature of the motor exceeds the charging power limiting temperature to prevent the motor from generating power; and continuing to forcibly charge, by the controller, the high-voltage battery using the motor in response to the HSG being in a HSG power limited state in which the temperature of the HSG exceeds the charging power limiting temperature to prevent the HSG from generating power. 6. The method of claim 1 , further comprising: executing, by the controller, the second excessive temperature prevention logic; setting, by the controller, a charging power limiting temperature predetermined to limit power of the motor and the HSG during the forced charging to a temperature below the operating power limiting temperature for limiting operation of the motor after the forced charging is completed; and maintaining, by the controller, the current temperatures of the motor and the HSG below the operating power limiting temperature in the EV driving mode after the forced charging is completed. 7. The method of claim 1 , wherein the 3D maximum charging power maps are experimentally generated based on test results according to parameters selected from the group consisting of: speeds, torque (power), and torque applying times of the motor and the HSG. 8. A non-transitory computer readable medium containing program instructions executed by a processor for forcibly charging a high-voltage battery using a motor and a Hybrid Starter Generator (HSG), the computer readable medium comprising: program instructions that control a sensor to sense speeds and temperatures of the motor and the HSG; program instructions that calculate maximum chargeable power using three dimensional (3D) maximum charging power maps based on speeds, and torque (power), and torque applying times of the motor and the HSG; program instructions that forcibly charge the high-voltage battery with the maximum chargeable power; program instructions that adjust maximum charging power using energy integration during the forced charging; program instructions that execute a first excessive temperature prevention logic for the motor and the HSG to continuously perform forced charging by one of the motor and the HSG, during the forced charging of the high-voltage battery using the motor and the HSG simultaneously; and program instructions that execute a second excessive temperature prevention logic for adjusting current temperatures of the motor and the HSG below an operating power limiting temperature to maximize a time of an Electric Vehicle (EV) driving mode in which a vehicle is driven through motor-only operation, in response to the forced charging of the high voltage battery being completed. 9. The non-transitory computer readable medium of claim 8 , wherein the program instructions for the adjustment of the maximum charging power include: program instructions that operate the motor and the HSG simultaneously to output the maximum charging power, program instructions that integrate power of the motor and the HSG; and program instructions that compare amounts of the integrated power of the motor and the HSG to the 3D maximum charging power maps to extract and determine usable charging power of the motor and the HSG from the 3D maximum charging power maps. 10. The non-transitory computer readable medium of claim 9 , wherein the program instructions that adjust the maximum charging power includes: program instructions that reduce charging power of the motor and the HSG in response to an increase in the amounts of the integrated power of the motor and the HSG. 11. The non-transitory computer readable medium of claim 8 , wherein the program instruction that adjust the maximum charging power includes: program instructions that reduce charging power of the motor and the HSG in response to an increase in the amounts of the integrated power of the motor and the HSG. 12. The non-transitory computer readable medium of claim 8 , wherein the program instructions that execute the first excessive temperature prevention logic includes: program instructions that compare the current temperatures of the motor and the HSG to a charging power limiting temperature; program instructions that continue to forcibly charge the high-voltage battery using the HSG in response to the motor being in a motor power limited state in which the temperature of the motor exceeds the charging power limiting temperature to prevent the motor from generating power; and program instructions that continue to forcibly charge the high-voltage battery using the motor in response to the HSG being in a HSG power limited state in which the temperature of the HSG exceeds the charging power limiting temperature to prevent the HSG from generating power. 13. The non-transitory computer readable medium of claim 8 , further comprising: program instructions that execute the second excessive temperature prevention logic; program instructions that set a charging power limiting temperat