Mobile X-ray apparatus

What is claimed is: 1. A mobile X-ray apparatus comprising: an X-ray radiation device configured to emit X-rays; a controller configured to control the X-ray radiation device; a power supply configured to supply operating power to the X-ray radiation device and the controller; and a charger configured to charge the power supply, and wherein the power supply comprises: a lithium ion battery including a plurality of battery cells, a current sensor configured to detect current of the lithium ion battery, and a battery management system (BMS) configured to detect an occurrence of an overcurrent in the lithium ion battery via the current sensor in response to receiving an X-ray emission preparation signal, and to control the overcurrent that occurs during emission of X-rays. 2. The mobile X-ray apparatus of claim 1 , wherein the power supply further comprises a temperature sensor configured to detect a temperature of the power supply, and wherein the BMS is further configured to control a charge current path to be an off-state based on the temperature detected by the temperature sensor being higher than a threshold value. 3. The mobile X-ray apparatus of claim 2 , wherein the BMS is further configured to control an on-state or an off-state of a discharge current path in which a discharge current flows from the lithium ion battery to the controller and the X-ray radiation device, and wherein the power supply is further configured to supply the operating power to the X-ray radiation device and the controller via the discharge current path being in the on-state. 4. The mobile X-ray apparatus of claim 2 , wherein the power supply further comprises a charge switch connected to the charger and configured to be turned on and off, and based on the charge switch turned on, the charge current path in which a charge current flows from the charger to the lithium ion battery is in an on-state. 5. The mobile X-ray apparatus of claim 4 , wherein the power supply further comprises a discharge switch connected to the lithium ion battery and used to form a discharge current path, and wherein the discharge current path is a current path in which a discharge current flows from the lithium ion battery to the controller and the X-ray radiation device. 6. The mobile X-ray apparatus of claim 5 , wherein the discharge switch includes a plurality of FETs connected in parallel to one another. 7. The mobile X-ray apparatus of claim 5 , wherein the BMS is further configured to detect a state of the power supply, to control the charge current path by turning off the discharge switch and turning on the charge switch, and control the discharge current path by turning on the discharge switch and turning off the charge switch. 8. The mobile X-ray apparatus of claim 1 , wherein the power supply further comprises: a temperature sensor configured to detect a temperature of the power supply, wherein the temperature sensor is directly monitored by the controller. 9. The mobile X-ray apparatus of claim 1 , wherein the BMS is further configured to control an operation of a protection circuit for protection against at least one from among an over-discharge, the overcurrent, an overheating, and an unbalance between at least two cells among the plurality of battery cells included in the lithium ion battery. 10. The mobile X-ray apparatus of claim 1 , wherein the current sensor includes a first current sensor configured to detect a first current, and wherein the BMS is further configured to detect a value of the overcurrent in the lithium ion battery via the first current sensor in response to receiving the X-ray emission preparation signal. 11. The mobile X-ray apparatus of claim 10 , wherein the power supply further includes a second current sensor configured to detect a second current smaller than the first current. 12. The mobile X-ray apparatus of claim 1 , wherein each of the controller, the power supply, and the charger includes a respective communication interface, and the controller, the power supply, and the charger are configured to communicate with one another via the respective communication interface. 13. The mobile X-ray apparatus of claim 12 , wherein the respective communication interface performs communication according to a controller area network (CAN) protocol. 14. The mobile X-ray apparatus of claim 1 , wherein the charger includes a wireless charging system including, a transmitter and a receiver. 15. The mobile X-ray apparatus of claim 1 , wherein the charger is further configured to receive power wirelessly from an external device and charge the lithium ion battery based on the received power. 16. The mobile X-ray apparatus of claim 1 , wherein the power supply further comprises: a shutdown circuit configured to turn off the BMS; a discharge switch connected to the lithium ion battery and used to form a discharge current path; and a charge switch connected to the charger and configured to turn on and off to charge the lithium ion battery. 17. A mobile X-ray apparatus comprising: an X-ray radiation device configured to emit X-rays; a controller configured to control the X-ray radiation device; a power supply configured to supply operating power to the X-ray radiation device and the controller; and a charger configured to charge the power supply, and wherein the power supply comprises: a lithium ion battery including a plurality of battery cells, a current sensor configured to detect current of the lithium ion battery, a temperature sensor configured to detect a temperature of the power supply, and a battery management system (BMS) configured to detect an occurrence of an overcurrent in the lithium ion battery via the current sensor in response to receiving an X-ray emission preparation signal, and wherein, the controller is further configured to directly monitor information about the temperature of the power supply detected by the temperature sensor.