Fuel cell system

1 . A fuel cell system comprising: a fuel cell stack that is formed by stacking unit cells each including a cathode electrode, an anode electrode, and an electrolyte membrane arranged between the cathode electrode and the anode electrode, and includes a cathode passage and an anode passage formed inside the fuel cell stack; a cathode gas supply passage that includes a first pump that discharges cathode gas and is arranged in the cathode gas supply passage, and is connected to an inlet of the cathode passage; a cathode off-gas exhaust passage that includes a back pressure valve arranged in the cathode off-gas exhaust passage, and is connected to an outlet of the cathode passage; a circulation passage that connects a part located further downstream than the first pump in the cathode gas supply passage to a part located further upstream than the back pressure valve in the cathode off-gas exhaust passage, includes a second pump that discharges cathode off-gas and is arranged in the circulation passage, and circulates the cathode off-gas from the cathode off-gas exhaust passage to the cathode gas supply passage; and a control unit that executes, when idling operation is requested, cathode circulation control that operates the second pump to circulate the cathode off-gas so that a cathode back pressure increases to greater than a cathode back pressure during normal control, and executes, after the idling operation is shifted to load operation, depressurization control that increases an opening degree of the back pressure valve to greater than an opening degree during the idling operation to decrease the cathode back pressure to less than the cathode back pressure during the idling operation for a period taken for an oxygen concentration in the fuel cell stack to reach a predetermined value. 2 . The fuel cell system according to claim 1 , wherein the control unit closes the back pressure valve and executes the cathode circulation control during the idling operation. 3 . The fuel cell system according to claim 2 , wherein the control unit causes the first pump to discharge cathode gas to increase the cathode back pressure during the idling operation. 4 . The fuel cell system according to claim 1 , wherein the control unit executes depressurization control that fully opens the back pressure valve to decrease the cathode back pressure close to atmospheric pressure during shift from the idling operation to the load operation. 5 . The fuel cell system according to claim 4 , further comprising: an open valve arranged in parallel to the back pressure valve, wherein the control unit opens the open valve during the shift from the idling operation to the load operation. 6 . A fuel cell system comprising: a fuel cell stack that is formed by stacking unit cells each including a cathode electrode, an anode electrode, and an electrolyte membrane arranged between the cathode electrode and the anode electrode, and includes a cathode passage and an anode passage formed inside the fuel cell stack; a cathode gas supply passage that includes a first pump that discharges cathode gas and is arranged in the cathode gas supply passage, and is connected to an inlet of the cathode passage; a cathode off-gas exhaust passage that includes a back pressure valve arranged in the cathode off-gas exhaust passage, and is connected to an outlet of the cathode passage; a circulation passage that connects a part located further downstream than the first pump in the cathode gas supply passage to a part located further upstream than the back pressure valve in the cathode off-gas exhaust passage, includes a second pump that discharges cathode off-gas and is arranged in the circulation passage, and circulates the cathode off-gas from the cathode off-gas exhaust passage to the cathode gas supply passage; an open valve arranged in parallel to the back pressure valve; and a control unit that executes, when idling operation is requested, cathode circulation control that operates the second pump to circulate the cathode off-gas, executes, after the idling operation is shifted to load operation, depressurization control that fully opens the back pressure valve and opens the open valve to decrease the cathode back pressure close to atmospheric pressure for a period taken for an oxygen concentration in the fuel cell stack to reach a predetermined value.