Magnetic bearing control device and control method

What is claimed is: 1. A device for controlling a magnetic bearing, the device comprising: a bearing controller configured to output a plurality of switching control signals, based on gap information between a bearing coil and a rotor, and current information applied to the bearing coil; and a coil driver configured to turn on or off a plurality of switching elements contained therein, based on the plurality of switching control signals, thereby to control a current amount applied to the bearing coil and thus to control an intensity of a magnetic field generated between the bearing coil and the rotor, wherein the coil driver includes a first capacitor charged or discharged by a switching operation of a first switching element, and a bootstrap capacitor charged or discharged by a switching operation of a second switching element, and wherein the bearing controller is configured to generate and output the plurality of switching control signals so that the bootstrap capacitor is gradually charged or gradually discharged. 2. The device of claim 1 , wherein the bearing controller is configured to: generate the plurality of switching control signals to perform a first operation mode in which each of the bearing coil and the bootstrap capacitor of the coil driver are charged, such that the rotor takes off from the bearing coil; vary the plurality of switching control signals to perform a second operation mode in which the current amount applied to the bearing coil is maintained by the bootstrap capacitor of the coil driver; and vary and output the plurality of switching control signals to perform a third operation mode in which each of the bearing coil and the bootstrap capacitor of the coil driver is discharged in a stepwise manner, such that the rotor lands on the bearing coil. 3. The device of claim 1 , wherein the bearing controller includes: a current command generator configured to generate a current command value for controlling the current amount of the coil driver, based on the gap information input from at least one the gap sensor and a preset gap command value; and a duty generator configured to: generate a duty command value for controlling on/off of each of the switching elements contained in the coil driver for each switching element, based on current information input from at least one current detector and the current command value; and generate the plurality of switching control signals in a corresponding manner to the duty command value for each switching element. 4. The device of claim 3 , wherein the current command generator includes: a first calculator configured to output a difference value between the gap information and the preset gap command value; a first controller configured to generate and output the current command value for controlling the current amount of the coil driver, based on the difference value between the gap information and the gap command value; and a limiter configured to limit a level of the current command value so that the current command value does not exceed a preset allowable range. 5. The device of claim 3 , wherein the duty generator includes: a second calculator configured to output a difference value between the current information from the current detector and the current command value from the current command generator; and a second controller configured to: generate the duty command value for controlling on/off of each of the switching elements contained in the coil driver for each switching element, based on the difference value between the current information and the current command value; and generate the plurality of switching control signals in a corresponding manner to the duty command value for each switching element. 6. The device of claim 5 , wherein the second controller is configured to: generate the plurality of switching control signals to perform a first operation mode in which each of the bearing coil and the bootstrap capacitor of the coil driver are charged, such that the rotor takes off from the bearing coil; vary the plurality of switching control signals to perform a second operation mode in which the current amount applied to the bearing coil is maintained by the bootstrap capacitor of the coil driver; and vary and output the plurality of switching control signals to perform a third operation mode in which each of the bearing coil and the bootstrap capacitor of the coil driver is discharged in a stepwise manner, such that the rotor lands on the bearing coil. 7. The device of claim 5 , wherein the second controller is configured to output the plurality of switching control signals such that, for a period in which the coil driver is activated in each of the first to third operation modes, at least one of first to fourth switching modes for switching first and second switching elements of the coil driver, respectively, is selectively applied. 8. A method for operating a magnetic bearing control device, the method comprising: outputting, by a coil driver, a plurality of switching control signals, based on gap information between a bearing coil and a rotor, and current information applied to the bearing coil; and turning on or off a plurality of switching elements contained in the device, based on the plurality of switching control signals, thereby to control a current amount applied to the bearing coil and thus to control an intensity of a magnetic field generated between the bearing coil and the rotor, wherein the coil driver includes a first capacitor charged or discharged by a switching operation of a first switching element, and a bootstrap capacitor charged or discharged by a switching operation of a second switching element, and wherein outputting the plurality of switching control signals includes generating and outputting the plurality of switching control signals so that the bootstrap capacitor is gradually charged or gradually discharged. 9. The method of claim 8 , wherein outputting the plurality of switching control signals includes: generating the plurality of switching control signals to perform a first operation mode in which each of the bearing coil and the bootstrap capacitor of the coil driver are charged, such that the rotor takes off from the bearing coil; varying the plurality of switching control signals to perform a second operation mode in which the current amount applied to the bearing coil is maintained by the bootstrap capacitor of the coil driver; and varying and outputting the plurality of switching control signals to perform a third operation mode in which each of the bearing coil and the bootstrap capacitor of the coil driver is discharged in a stepwise manner, such that the rotor lands on the bearing coil. 10. The method of claim 9 , wherein outputting the plurality of switching control signals includes outputting the plurality of switching control signals such that, for a period in which the coil driver is activated in each of the first to third operation modes, at least one of first to fourth switching modes for switching first and second switching elements of the coil driver, respectively, is selectively applied. 11. The method of claim 8 , wherein outputting the plurality of switching control signals includes generating a current command value for controlling the current amount of the coil driver, based on the gap information input from at least one the gap sensor and a preset gap command value; generating a duty command value for controlling on/off of each of the switching elements contained in the coil driver for each switching element, based on current information input from at least one current detector and the current command value; and generating the plur