Fuel cell system

What is claimed is: 1 . A fuel cell system comprising: a reformer configured to perform a reforming process that provides hydrogen gas from a gasified fuel; a burner configured to provide heat to the reformer; a stack configured to provide electrical energy based on an electrochemical reaction using reforming gas; a first supply pipe configured to provide air to the burner; a second supply pipe configured to provide air to the stack; a first storage tank configured to store a liquid fuel; a second storage tank configured to provide a gasified fuel to the reformer; and a fuel evaporator configured to heat exchange the liquid fuel from the first storage tank with air from the first supply pipe or air from the second supply pipe, wherein the fuel evaporator is configured to provide a gaseous fuel to the second storage tank. 2 . The fuel cell system of claim 1 , wherein the fuel evaporator includes: a first fuel evaporator configured to heat exchange the liquid fuel from the first storage tank with the air flowing through the first supply pipe; and a second fuel evaporator configured to heat exchange the liquid fuel from the first storage tank with the air flowing through the second supply pipe. 3 . The fuel cell system of claim 2 , comprising: a first liquid gas supply pipe to connect the first storage tank and the first fuel evaporator; a second liquid gas supply pipe to connect the first storage tank and the second fuel evaporator; a first expansion valve disposed at the first liquid gas supply pipe, and configured to open or close an internal channel of the first liquid gas supply pipe or to adjust a degree of opening of the internal channel of the first liquid gas supply pipe; and a second expansion valve disposed at the second liquid gas supply pipe, and configured to open or close an internal channel of the second liquid gas supply pipe or to adjust a degree of opening of the internal channel of the second liquid gas supply pipe. 4 . The fuel cell system of claim 3 , wherein while the system is in a preheating mode that preheats the reformer, the first expansion valve is to increase the degree of opening of the internal channel of the first liquid gas supply pipe and the second expansion valve is to close the internal channel of the second liquid gas supply pipe. 5 . The fuel cell system of claim 3 , wherein while the system is in a power generation mode that generates electricity using the stack, the first expansion valve is to increase the degree of opening of the internal channel of the first liquid gas supply pipe and the second expansion valve is to increase the degree of opening of the internal channel of the second liquid gas supply pipe. 6 . The fuel cell system of claim 3 , comprising a reforming gas discharge pipe configured to provide reforming gas from the reformer to the burner or to the stack, wherein the liquid evaporator includes a third fuel evaporator disposed at the reforming gas discharge pipe, and the third fuel evaporator is configured to heat exchange the reforming gas from the reformer with a liquid fuel. 7 . The fuel cell system of claim 6 , comprising: a third liquid gas supply pipe to connect the first storage tank and the third fuel evaporator; and a third expansion valve disposed at the third liquid gas supply pipe, and configured to open or close an internal channel of the third liquid gas supply pipe or to adjust a degree of opening of the internal channel of the third liquid gas supply pipe. 8 . The fuel cell system of claim 7 , wherein while the system is in a reforming mode that is configured to increase an amount of hydrogen included in the reforming gas from the reformer, the first expansion valve is to increase the degree of opening of the internal channel of the first liquid gas supply pipe, and the third expansion valve is to increase the degree of opening of the internal channel of the third liquid gas supply pipe. 9 . The fuel cell system of claim 8 , wherein while the system is in the reforming mode, a size of the internal channel of the third liquid gas supply pipe that is opened by the third expansion valve is larger than a size of the internal channel of the first liquid gas supply pipe that is opened by the first expansion valve in the reforming mode. 10 . The fuel cell system of claim 7 , wherein while the system is in a power generation mode that is configured to generate electricity using the stack, the first expansion valve is to increase the degree of opening of the internal channel of the first liquid gas supply pipe, the second expansion valve is to increase the degree of opening of the internal channel of the second liquid gas supply pipe, and the third expansion valve is to increase the degree of opening of the internal channel of the third liquid gas supply pipe. 11 . The fuel cell system of claim 10 , wherein while the system is in the power generation mode, a size of the internal channel of the third liquid gas supply pipe that is opened by the third expansion valve is larger than a size of the internal channel of the first liquid gas supply pipe that is opened by the first expansion valve or a size of the internal channel of the second liquid gas supply pipe that is opened by the second expansion valve. 12 . The fuel cell system of claim 7 , comprising: a liquid gas common pipe to connect the first storage tank, the first liquid gas supply pipe, the second liquid gas supply pipe, and the third liquid gas supply pipe; and a common pipe valve configured to open or close the liquid gas common pipe. 13 . The fuel cell system of claim 12 , comprising: a first blower disposed at the first supply pipe, and configured to provide external air to the first supply pipe; and a second blower disposed at the second supply pipe, and configured to provide external air to the second supply pipe, wherein when the first blower is operated, the common pipe valve is to open the liquid gas common pipe. 14 . The fuel cell system of claim 1 , wherein the fuel evaporator includes: a housing; a fuel flow section disposed in the housing, and configured to allow a liquid fuel to flow; and a gas flow section disposed in the housing, and configured to allow flow of air or reforming gas. 15 . The fuel cell system of claim 14 , wherein each pipe of the fuel flow section includes a plurality of protrusions within the pipe, and each pipe of the gas flow section includes a plurality of protrusions within the pipe. 16 . A fuel cell system comprising: a reformer configured to perform a reforming process that provides a reforming gas; a burner configured to provide heat to the reformer; a stack configured to receive the reforming gas and to perform an electrochemical reaction to the received reforming gas; a first supply channel configured to provide air to the burner; a second supply channel configured to provide air to the stack; a first storage tank configured to provide a liquid fuel; a second storage tank configured to provide a gasified fuel; and a fuel evaporator in which the liquid fuel from the first storage tank is exchanged with air from the first supply channel or with air from the second supply channel, and the fuel evaporator is to provide a gaseous fuel based on the exchange. 17 . The fuel cell system of claim 16 , wherein the fuel evaporator includes: a first fuel evaporator configured to perform a heat exchange of the liquid fuel from the first storage tank with the air flowing through the first supply channel; and a second fuel evaporator configured to