System for and method of controlling driving of an electronic vacuum pump

What is claimed is: 1. A system for controlling driving of an electronic vacuum pump, the system comprises: a first electronic vacuum pump and a second electronic vacuum pump, each providing a negative pressure to a booster when an electric vehicle brakes; and an electronic vacuum pump (EVP) controller that performs control which alternately or concurrently drives the first electronic vacuum pump and the second electronic vacuum pump on the basis of signals of sensors each of which senses information associated with starting and braking of the electric vehicle, wherein the EVP controller is configured to perform control that drives the first and second electronic vacuum pumps at a speed in terms of revolutions per minute (RPM) that is set in a manner that varies with each vehicle speed and to perform control that ends the driving when the negative pressure generated by driving each of the first and second electronic vacuum pumps satisfies a reference negative pressure. 2. The system according to claim 1 , wherein the EVP controller is configured to determine conditions for allowing and disallowing the first and second electronic vacuum pumps to operate, on the basis of sensing signals of the sensors, and to apply an alternately-driving signal or a concurrently-driving signal to the first and second electronic vacuum pumps according to the determined conditions. 3. The system according to 1 , wherein the sensors are configured to include: a pressure sensor that senses an operating pressure of a master cylinder and provides the sensed operating pressure to the EVP controller; a wheel speed sensor that detects a vehicle speed and provides the detected vehicle speed to the EVP controller; a negative-pressure sensor that senses the negative pressure provided to the booster and provides the sensed negative pressure to the EVP controller; and an I/G (ignition) signal providing unit that provides an ignition signal to the EVP controller when the electric vehicle starts. 4. The system according to claim 3 , wherein the EVP controller is configured to apply an alternation control signal for alternate driving to the first and second electronic vacuum pumps in a basic vehicle traveling and braking situation other than a vehicle starting switch-on situation, a rapid-deceleration and sudden-braking situation, or a low negative-pressure situation. 5. The system according to claim 3 , wherein the EVP controller is configured to apply a concurrent driving control signal for concurrent driving to the first and second electronic vacuum pumps when a vehicle starting switch is on, on the basis of a signal of the negative-pressure sensor and a starting signal of the I/G signal providing unit. 6. The system according to claim 5 , wherein the EVP controller is configured to perform control that applies the concurrent driving control signal for concurrent driving to the first and second electronic vacuum pumps if the negative pressure is equal to or lower than the reference negative pressure when the vehicle starting switch is on, on the basis of the signal of the negative-pressure sensor, and to perform control that ends the driving of the first and second electronic vacuum pumps when the negative pressure generated by concurrently driving the first and second electronic vacuum pumps satisfies the reference negative pressure, on the basis of the signal of the negative-pressure sensor. 7. The system according to claim 3 , wherein the EVP controller is configured to apply a concurrent driving control signal for concurrent driving to the first and second electronic vacuum pumps when it is determined on the basis of signals of the pressure sensor and the negative-pressure sensor that a rapid deceleration situation or a sudden-braking situation occurs. 8. The system according to claim 7 , wherein the EVP controller is configured to perform control that determines that the rapid deceleration situation occurs, when a brake hydraulic pressure of the master cylinder is equal to or higher than a predetermined pressure on the basis of the signal of the pressure sensor, or determines that the sudden-braking situation occurs, when an ascending slope for the brake hydraulic pressure of the master cylinder is equal to or greater than a predetermined slope on the basis of the signal of the pressure sensor, and to perform control that concurrently drives the first and second electronic vacuum pumps, but to perform control that ends the driving of the first and second electronic vacuum pumps, when a generation negative pressure generated in the first and second electronic vacuum pumps reaches a target negative pressure. 9. The system according to claim 3 , wherein the EVP controller is configured to perform control that concurrently drives the first and second electronic vacuum pumps, when it is determined on the basis of signals of the pressure sensor and the negative-pressure sensor that a state where the negative pressure of the booster is a low negative pressure equal to or less than a reference value is reached due to successive brake operation of a brake pedal during vehicle traveling. 10. A method of controlling driving of an electronic vacuum pump, the method comprising: providing signals of sensors, each sensing information associated with electric starting and braking of an electric vehicle, to an electronic vacuum pump (EVP) controller; causing the EVP controller to determine conditions for allowing and disallowing a first electric vacuum pump and a second electric vacuum pump, each providing a negative pressure to a booster, to operate, on the basis of sensing signals of the sensors; and causing the EVP controller to perform control that, according to the determined conditions, applies an alternately-driving signal for alternate driving of the first electric vacuum pump and the second electric vacuum pump or applies a concurrently-driving signal for concurrent driving of the first electric vacuum pump and the second electric vacuum pump, wherein in the causing of the EVP controller to performing control, the control is performed to drive the first and second electronic vacuum pumps at a speed in terms of revolutions per minute (RPM) that is set in a manner that varies with each vehicle speed, and the control is performed to end the driving when the negative pressure generated by driving each of the first and second electronic vacuum pumps satisfies a reference negative pressure. 11. The method according to claim 10 , wherein the EVP controller is configured to apply an alternation control signal for alternate driving to the first and second electronic vacuum pumps when the determined condition is a basic vehicle traveling and braking situation other than a vehicle starting switch-on situation, a rapid-deceleration and sudden-braking situation, or a low negative-pressure situation. 12. The method according to claim 10 , wherein the EVP controller applies a concurrent driving control signal for concurrent driving to the first and second electronic vacuum pumps when the condition determined on the basis of a signal of the negative-pressure sensor and a starting signal of an JIG (ignition) signal providing unit is a vehicle starting switch-on situation. 13. The method according to claim 12 , wherein the EVP controller performs control that applies the concurrent driving control signal for concurrent driving to the first and second electronic vacuum pumps when the negative pressure is equal to or lower than the reference negative pressure when a vehicle starting switch is on, on the basis of the signal of the negative-pressure sensor, and performs control that ends the driving of the first and seco