Fuel cell system

What is claimed is: 1. A fuel cell system comprising: a stack that generates electric power using reformed gas; a fuel processing device that supplies the reformed gas to the stack; a first gas passage that connects the stack and the fuel processing device, the first gas passage carrying the reformed gas discharged from the fuel processing device toward the stack; a second gas passage that connects the stack and the fuel processing device, the second gas passage carrying an anode-off gas (AOG) discharged from the stack toward the fuel processing device; a buffer tank that stores at least a portion of the AOG discharged from the stack; a first buffer tank passage that connects the buffer tank and the second gas passage; a second buffer tank passage that is coupled to the buffer tank; a gas mixer that is connected to the second buffer tank passage and supplies the AOG stored in the buffer tank to the stack; and a controller that controls the gas mixer to supply the AOG stored in the buffer tank to the stack so as to at least one of preheat the stack or remove air remaining in the stack. 2. The fuel cell system of claim 1 , further comprising: a buffer tank valve provided on the first buffer tank passage, the buffer tank valve controlling a flow of the AOG supplied to the buffer tank; and a buffer tank compressor located on a front end of the buffer tank valve, buffer tank compressor compressing the AOG supplied to the buffer tank, wherein, during a power generation operation, the controller closes the gas mixer, opens the buffer tank valve, operates the buffer tank compressor such that a portion of the AOG discharged from the stack is pressurized and stored in the buffer tank. 3. The fuel cell system of claim 2 , further comprising a pressure sensor provided on the buffer tank, the pressure sensor measuring a pressure of the AOG stored in the buffer tank, wherein, when the pressure of the AOG stored in the buffer tank measured by the pressure sensor is equal to or greater than a first set pressure, the controller closes the buffer tank valve and deactivates the buffer tank compressor. 4. The fuel cell system of claim 1 , further comprising: a blower that supplies air to the stack; and an air supply valve provided between the stack and the blower, the air supply valve adjusting a flow of the air supplied from the blower to the stack, wherein, during a purge operation, the controller closes the air supply valve and opens the gas mixer so that the AOG stored in the buffer tank is supplied to the stack. 5. The fuel cell system of claim 4 , further comprising a pressure sensor provided on the buffer tank, the pressure sensor measuring a pressure of the AOG stored in the buffer tank, wherein, when the pressure of the AOG in the buffer tank measured by the pressure sensor is equal to or less than a second set pressure, the controller closes the gas mixer to terminate the purge operation. 6. The fuel cell system of claim 1 , further comprising: a blower that supplies air to the stack; and an air supply valve provided between the stack and the blower, the air supply valve adjusting a flow of the air supplied from the blower to the stack, wherein, during a stack preheating operation, the controller opens the gas mixer and the air supply valve and operates the blower so that air and AOG are mixed and then supplied to the stack. 7. The fuel cell system of claim 6 , further comprising: a first gas valve provided on the first gas passage, and controlling a flow of the reformed gas supplied to the stack; a bypass passage that connects the first gas passage and the fuel processing device; and a bypass valve provided on the bypass passage, the bypass valve controlling the flow of the reformed gas in the bypass passage, wherein, during the stack preheating operation, the controller closes the first gas valve and opens the bypass valve so that the reformed gas discharged from the fuel processing device flows back into the fuel processing device.