Compressor driving apparatus and chiller including the same

What is claimed is: 1. A compressor driver comprising: a compressor including a compressor motor and a magnetic bearing; a coil driver including a switching element, wherein the coil driver applies a current to a bearing coil of the magnetic bearing by a switching operation of the switching element to cause a rotor of the compressor motor to be moved between a first state in which the rotor is positioned away from the magnetic bearing and a second state in which the rotor is positioned to contact the magnetic bearing; and a controller to control the switching element of the coil driver, wherein, when the rotor of the compressor motor is being brought into contact with the magnetic bearing, the controller is further configured to control the switching element such that the current applied to the bearing coil decreases by less than a prescribed amount during a time period, wherein the coil driver includes: a capacitor to store direct current power; a first switching element and a first diode element connected between two leads of the capacitor; and a second diode element and a second switching element connected between the two leads of the capacitor, and connected in parallel with the first switching element and the first diode element, wherein the bearing coil is connected between the first switching element and the first diode element, and between the second diode element and the second switching element. 2. The compressor driver of claim 1 , wherein, when the rotor of the compressor motor is being brought into contact with the magnetic bearing, the controller is configured to control the switching element such that first and second modes alternate with each other, the first mode being a mode in which current stored in the bearing coil is discharged, and the second mode being a mode in which current flows to the bearing coil based on power stored in a capacitor. 3. The compressor driver of claim 1 , wherein, when the rotor of the compressor motor is being brought into contact with the magnetic bearing, the controller is configured to control the switching element to alternate between a first mode that includes turning on either the first switching element or the second switching element and a second mode that includes turning on both the first switching element and the second switching element based on power stored in the capacitor. 4. The compressor driver of claim 1 , wherein the controller is configured to control the switching element to, as periods in which the rotor of the compressor motor is being positioned away from the magnetic bearing and rotated increase, decrease a first period that includes turning on either the first switching element or the second switching element and a second period that includes turning on both the first switching element and the second switching element, during which the rotor of the compressor motor is being brought into contact with the magnetic bearing. 5. The compressor driver of claim 1 , wherein, when the rotor of the compressor motor is being brought into contact with the magnetic bearing, the controller is configured to sequentially increase a first period that includes turning on either the first switching element or the second switching element and a second period that includes turning on both the first switching element and the second switching element. 6. The compressor driver of claim 1 , further comprising: a bearing coil current detector that detects the current applied to the bearing coil; and a gap sensor that senses the gap between the bearing coil and the rotor, wherein the controller is further configured to output a switching control signal to control the first switching element and the second switching element based on the gap sensed by the gap sensor and the detected current applied to the bearing coil. 7. The compressor driver of claim 2 , wherein, when the rotor of the compressor motor is being positioned away from the magnetic bearing, the controller is configured to control the switching element such that: the second mode and the first mode alternate with each other, and a first period for the first mode and a second period for the second mode, during which the rotor of the compressor motor is brought into contact with the magnetic bearing, are respectively shorter than a third period for the first mode and a fourth period for the second mode, during which the rotor of the compressor motor is being positioned away from the magnetic bearing. 8. The compressor driver of claim 2 , wherein, when the rotor of the compressor motor is being positioned away from the magnetic bearing and rotates, the controller is configured to control the switching element such that: the first mode and the second mode alternate with each other, and a first period for the first mode and a second period for the second mode, during which the rotor of the compressor motor is brought into contact with the magnetic bearing, are respectively longer than a fifth period for the first mode and a sixth period for the second mode, during the rotation of the rotor of the compressor motor. 9. The compressor driver of claim 2 , wherein the controller is configured to control the switching element such that, as respective periods when the rotor of the compressor motor is being positioned away from the magnetic bearing and rotates increase, a first period for the first mode and a second period for the second mode, while the rotor of the compressor motor is being brought into contact with the magnetic bearing decrease. 10. The compressor driver of claim 2 , wherein, when the rotor of the compressor motor is being brought into contact with the magnetic bearing, the controller is configured to control the switching element to sequentially increase a first period for the first mode and a second period for the second mode. 11. The compressor driver of claim 3 , wherein, when the rotor of the compressor motor is being positioned away from the magnetic bearing, the controller is configured to control the switching element to alternate the second mode and the first mode with each other, and a first period that includes turning on either the first switching element or the second switching element and a second period that includes turning on both the first switching element and the second switching element, while the rotor of the compressor motor is being brought into contact with the magnetic bearing, are respectively shorter than a third period for the first mode and a fourth period for turning on both the first switching element and the second switching element, in which the rotor of the compressor motor is being positioned away from the magnetic bearing. 12. The compressor driver of claim 3 , wherein, when rotor of the compressor motor is being positioned away from the magnetic bearing and rotates, the first mode and the second mode alternate with each other, and a first period that includes turning on either the first switching element or the second switching element and a second period that includes turning on both the first switching element and the second switching element, during which the rotor of the compressor motor is being brought into contact with the magnetic bearing, are respectively longer than a fifth period that includes turning on either the first switching element or the second switching element and a sixth period that includes turning on both the first switching element and the second switching element, during which the rotor of the compressor motor is being positioned away from the magnetic bearing and rotated. 13. The compressor driver of claim 6 , wherein the controller includes: a current command generator t