Fuel cell system

1 . A fuel cell system comprising: a fuel cell configured to be supplied with a fuel and air to generate an electric power; a combustor configured to combust an off-gas discharged from the fuel cell to produce a combustion discharged gas; a fuel heating part configured to heat the fuel to be supplied to the fuel cell by the combustion discharged gas; an air heating part configured to heat the air to be supplied to the fuel cell by the combustion discharged gas; an anode-side distribution passage configured to distribute the combustion discharged gas to the fuel heating part; a cathode-side distribution passage configured to distribute the combustion discharged gas to the air heating part; and a discharged gas distribution ratio adjustment part configured to adjust a discharged gas distribution ratio, the discharged gas distribution ratio being a ratio of an anode-side combustion discharged gas flow rate to a cathode-side combustion discharged gas flow rate, the anode-side combustion discharged gas flow rate being a flow rate of the combustion discharged gas that flows in the anode-side distribution passage, the cathode-side combustion discharged gas flow rate being a flow rate of the combustion discharged gas that flows in the cathode-side distribution passage, wherein the discharged gas distribution ratio adjustment part is configured to reduce the discharged gas distribution ratio according to an increase in a supply air flow rate as a flow rate of the air to be supplied to the fuel cell. 2 . The fuel cell system according to claim 1 , wherein: the discharged gas distribution ratio adjustment part includes a discharged gas distribution ratio adjustment structure provided in the anode-side distribution passage and the cathode-side distribution passage; and the discharged gas distribution ratio adjustment structure is configured such that a rate of increase in a pressure loss in the anode-side distribution passage according to the increase in the supply air flow rate becomes larger than a rate of increase in a pressure loss in the cathode-side distribution passage according to the increase in the supply air flow rate. 3 . The fuel cell system according to claim 2 , wherein the discharged gas distribution ratio adjustment structure includes a flow path cross-sectional area reduction part provided in the anode-side distribution passage and configured to reduce a flow path cross-sectional area for the combustion discharged gas. 4 . The fuel cell system according to claim 2 , wherein the discharged gas distribution ratio adjustment structure includes a flow path surface area increasing part provided in the cathode-side distribution passage and configured to increase a flow path surface area for the combustion discharged gas. 5 . The fuel cell system according to claim 1 , wherein: the discharged gas distribution ratio adjustment part includes a flow rate adjustment device configured to adjust the flow rate of the combustion discharged gas in at least one of the anode-side distribution passage and the cathode-side distribution passage, and a control device configured to operate the flow rate adjustment device; and the control device is configured to operate the flow rate adjustment device so that the discharged gas distribution ratio is reduced as the supply air flow rate is increased. 6 . The fuel cell system according to claim 5 , wherein: the control device is configured to estimate the anode-side combustion discharged gas flow rate based on the supply air flow rate; and the control device is configured to operate the flow rate adjustment device so that the anode-side combustion discharged gas flow rate estimated becomes equal to or less than an upper limit flow rate determined based on acceptable heat energy of the fuel in the fuel heating part. 7 . The fuel cell system according to claim 5 , wherein: the control device is configured to estimate the anode-side combustion discharged gas flow rate based on the supply air flow rate; and the control device is configured to operate the flow rate adjustment device so that the anode-side combustion discharged gas flow rate estimated becomes equal to or higher than a lower limit flow rate determined based on a target temperature of the fuel heating part according to power-generation electric power.