초록 ▼

A fuel cell stack includes a heat exchange unit that performs heat exchange between a gas mixture containing source hydrogen and a circulating gas and cooling water used for controlling the temperature of the fuel cell stack. A system controller adjusts the temperature of the cooling water by contro

A fuel cell stack includes a heat exchange unit that performs heat exchange between a gas mixture containing source hydrogen and a circulating gas and cooling water used for controlling the temperature of the fuel cell stack. A system controller adjusts the temperature of the cooling water by controlling a temperature control unit on the basis of the temperature of source hydrogen flowing into a junction at which the source hydrogen and a circulating gas are mixed such that the temperature of a source/recirculated hydrogen mixture that is mixed at the junction and that is supplied to the fuel cell stack is kept within a managed temperature range.

대표청구항 ▼

1. A fuel cell system comprising: a fuel cell that generates electric power by electrochemically reacting a reactant gas mixture;a reactant gas supply unit configured to supply a reactant gas;a gas circulation unit configured to mix a circulating reactant gas from the fuel cell with the reactant gas

1. A fuel cell system comprising: a fuel cell that generates electric power by electrochemically reacting a reactant gas mixture;a reactant gas supply unit configured to supply a reactant gas;a gas circulation unit configured to mix a circulating reactant gas from the fuel cell with the reactant gas to supply the reactant gas mixture to the fuel cell;a temperature control unit having a cooling flow path through the fuel cell, a circulating pump configured to circulate a heat transfer medium through the fuel cell, and a radiator on the cooling flow path to adjust the temperature of the heat transfer medium;a gas temperature-detecting unit configured to detect an inlet reactant gas mixture temperature of the reactant gas mixture before the reactant gas mixture enters the fuel cell;a heat exchange unit in the fuel cell through which an outlet side of the reactant gas mixture and an inlet side of the heat transfer medium flows, the heat exchange unit configured to perform heat exchange between the reactant gas mixture and a portion of the heat transfer medium; anda control unit programmed to: determine a target inlet side temperature of the heat transfer medium based on a reactant gas supply unit temperature, a reactant gas flow rate, and a reactant gas mixture flow rate, the target inlet side temperature determined to maintain the inlet reactant gas mixture temperature within a predetermined range; andadjust a temperature of the heat transfer medium to achieve the target inlet side temperature by controlling the temperature control unit. 2. The fuel cell system according to claim 1, wherein the predetermined temperature range is set in a range from a lower heat-resistance temperature limit of the fuel cell to an upper heat-resistance temperature limit of the fuel cell. 3. The fuel cell system according to claim 2, wherein the control unit adjusts the temperature of the heat transfer medium when the inlet reactant gas mixture temperature is outside of a control temperature range that is set on the basis of the predetermined temperature range and is within the predetermined temperature range. 4. The fuel cell system according to claim 3, wherein the control unit adjusts the temperature of the heat transfer medium and adjusts a flow rate of the heat transfer medium such that the temperature of the reactant gas mixture is kept within the predetermined temperature range. 5. The fuel cell system according to claim 1, wherein the control unit further adjusts a flow rate of the reactant gas on the basis of the temperature of the heat transfer medium such that the temperature of the gas mixture is kept within the predetermined temperature range. 6. The fuel cell system according to claim 5, further comprising: an electric power extraction unit configured to extract electric power from the fuel cell,wherein when flow rate of the reactant gas is decreased, the control unit controls the electric power extraction unit to limit the electric power extracted from the fuel cell when flow rate of the reactant gas is decreased. 7. The fuel cell system according to claim 5, further comprising: a purge unit configured to discharge impurities contained in the circulating reactant gas,wherein the control unit controls the purge unit to decrease an amount of impurities discharged from the purge unit. 8. The fuel cell system according to claim 7, wherein the control unit controls the purge unit such that the amount of impurities is equal to or lower than an acceptable upper limit of the amount of impurities in the circulating gas. 9. The fuel cell system according to claim 1, wherein the control unit further adjusts a flow rate of the circulating reactant gas on the basis of the temperature of the heat transfer medium such that the temperature of the reactant gas mixture is kept within the predetermined temperature range. 10. The fuel cell system according to claim 1, wherein the control unit further adjusts a pressure of the reactant gas mixture on the basis of the temperature of the heat transfer medium such that the temperature of the reactant gas mixture is kept within the predetermined temperature range. 11. The fuel cell system according to claim 1, wherein the reactant gas mixture and the heat transfer medium having opposing flows. 12. The fuel cell system according to claim 1, further comprising: a moisturizer configured to add moisture to a compressed gas. 13. The fuel cell system according to claim 12, wherein the moisturizer is configured to receive a gas exiting the fuel cell. 14. The fuel cell system according to claim 1, further comprising: a hydrogen concentration sensor. 15. The fuel cell system according to claim 1, further comprising: an aftercooler configured to reduce the temperature of a compressed gas. 16. A method of controlling a fuel cell system comprising: supplying a reactant gas using a reactant gas supply unit;mixing a circulating gas discharged from a fuel cell with the reactant gas using a gas circulation unit to supply a reactant gas mixture to the fuel cell, the fuel cell generating electric power by electrochemically reacting a resultant reactant gas mixture;circulating a heat transfer medium through the fuel cell using a temperature control unit having a cooling flow path, a circulating pump and a radiator on the cooling flow path;detecting an inlet reactant gas mixture temperature of the reactant gas mixture before the reactant gas mixture enters the fuel cell using a gas temperature-detecting unit;exchanging heat between the reactant gas mixture at an outlet of the fuel cell and a portion of the heat transfer medium at an inlet of the fuel cell in a heat exchange unit in the fuel cell;determining a target inlet side temperature of the heat transfer medium based on a reactant gas supply unit temperature, a reactant gas flow rate, and a reactant gas mixture flow rate, the target inlet side temperature determined to maintain the inlet reactant gas mixture temperature within a predetermined range; andadjusting a temperature of the heat transfer medium to achieve the target inlet side temperature by controlling the temperature of the heat transfer medium using the temperature control unit. 17. The method according to claim 16, wherein the predetermined temperature range is set in a range from a lower heat-resistance temperature limit of the fuel cell to an upper heat-resistance temperature limit of the fuel cell. 18. The method according to claim 16, further comprising: increasing a flow rate of the heat transfer medium while maintaining the temperature of the heat transfer medium at an allowable upper temperature limit for the heat transfer medium when the temperature of the heat transfer medium reaches the allowable upper temperature limit. 19. The method according to claim 16, further comprising: adjusting a flow rate of the reactant gas on the basis of the temperature of the heat transfer medium such that the temperature of the gas mixture is kept within the predetermined temperature range. 20. The method according to claim 16, further comprising: limiting an amount of electric power extracted from the fuel cell when flow rate of the reactant gas is decreased. 21. The method according to claim 16, further comprising: adjusting at least one of a flow rate or a pressure of the circulating reactant gas on the basis of the temperature of the heat transfer medium such that the temperature of the reactant gas mixture is kept within the predetermined temperature range. 22. A fuel cell system comprising: electric power generating means that electrochemically reacts a reactant gas mixture to generate electric power;reactant gas supplying means that supplies a reactant gas;gas circulating means that mixes a circulating reactant gas from the electric power generating means with the reactant gas to supply the reactant gas mixture to the electric power generating means;temperature controlling means having a cooling flow path, a circulating pump that circulates a heat transfer medium through the electric power generating means, and a radiator on the cooling flow path to adjust the temperature of the heat transfer medium;gas temperature detecting means that detects an inlet reactant gas mixture temperature of the reactant gas mixture before the reactant gas mixture enters the electric power generating means;heat exchange means in the electric power generating means through which an outlet side of the reactant gas mixture and an inlet side of the heat transfer medium flows, the heat exchange means configured to exchange heat between the reactant gas mixture and a portion of the heat transfer medium; andcontrolling means programmed to: determine a target inlet side temperature of the heat transfer medium based on a reactant gas supply unit temperature, a reactant gas flow rate, and a reactant gas mixture flow rate, the target inlet side temperature determined to maintain the inlet reactant gas mixture temperature within a predetermined range; andadjust a temperature of the heat transfer medium to achieve the target inlet side temperature by controlling the temperature control unit.