Method of controlling fuel cell system, method of controlling fuel cell automobile, and fuel cell automobile

What is claimed is: 1 . A method of controlling a fuel cell system, the fuel cell system comprising: a fuel cell configured to generate fuel cell voltage as a primary voltage; an electrical storage device configured to generate electrical storage device voltage as another primary voltage; a load drive unit to which a secondary voltage is supplied, the load drive unit being configured to drive a load; a first converter provided between the electrical storage device and the load drive unit, and configured to perform voltage conversion between the electrical storage device voltage and the secondary voltage; and a second converter provided between the fuel cell and the load drive unit, and configured to perform voltage conversion between the fuel cell voltage and the secondary voltage, the method comprising: a secondary-voltage stepping-up step of controlling the first converter to thereby allow the secondary voltage to become higher than the fuel cell voltage, without following a change of required electrical power for the load. 2 . The method of controlling the fuel cell system according to claim 1 , further comprising: before the secondary-voltage stepping-up step, an electrical storage device charging-state determining step of determining whether or not charging of the electrical storage device with electrical power generated by the fuel cell is in an acceptable state, wherein if it is determined that charging of the electrical storage device with the electrical power generated by the fuel cell is not in an acceptable state, the secondary-voltage stepping-up step is performed. 3 . The method of controlling the fuel cell system according to claim 2 , wherein in the electrical storage device charging-state determining step, a state of charge, i.e., SOC, of the electrical storage device is detected, and if the detected SOC is equal to or more than a SOC threshold value, the secondary-voltage stepping-up step is performed. 4 . The method of controlling the fuel cell system according to claim 1 , wherein, before the secondary-voltage stepping-up step, the first converter is placed in a stopped state to directly connect the electrical storage device to the load drive unit. 5 . The method of controlling the fuel cell system according to claim 1 , further comprising: a power generation current zero-value setting step of setting power generation current to a zero value before controlling the first converter to thereby allow the secondary voltage to become higher than the fuel cell voltage. 6 . A method of controlling a fuel cell system, the fuel cell system comprising: a fuel cell configured to generate fuel cell voltage as a primary voltage; an electrical storage device configured to generate electrical storage device voltage as another primary voltage; a load drive unit to which a secondary voltage is supplied, the load drive unit being configured to drive a load; a first converter provided between the electrical storage device and the load drive unit, and configured to perform voltage conversion between the electrical storage device voltage and the secondary voltage; and a second converter provided between the fuel cell and the load drive unit, and configured to perform voltage conversion between the fuel cell voltage and the secondary voltage, the method comprising: a secondary-voltage setting step of setting the secondary voltage by the first converter depending on required electrical power for the load; and a secondary-voltage temporarily-fixing step of, when the secondary voltage decreases based on decrease in the required electrical power for the load and/or regenerative electrical power of the load, temporarily fixing the decreasing secondary voltage by the first converter. 7 . The method of controlling the fuel cell system according to claim 6 , further comprising a SOC detecting step of detecting a state of charge, i.e., SOC, of the electrical storage device, wherein if the detected SOC is equal to or more than an SOC threshold value, the secondary-voltage temporarily-fixing step is performed. 8 . The method of controlling the fuel cell system according to claim 6 , wherein in a case where the decrease of the secondary voltage is caused by regenerative electrical power of the load, the secondary-voltage temporarily-fixing step continues until generation of the regenerative electrical power of the load is finished. 9 . A method of controlling a fuel cell automobile, the fuel cell automobile comprising: a fuel cell configured to generate fuel cell voltage as a primary voltage; an electrical storage device configured to generate electrical storage device voltage as another primary voltage; a motor drive unit to which a secondary voltage is supplied, the motor drive unit being configured to drive a motor which produces driving power for allowing travel of the fuel cell automobile, a first converter provided between the electrical storage device and the motor drive unit, and configured to perform voltage conversion between the electrical storage device voltage and the secondary voltage; and a second converter provided between the fuel cell and the motor drive unit, and configured to perform voltage conversion between the fuel cell voltage and the secondary voltage, the method comprising: a deceleration determining step of determining whether or not the fuel cell automobile is in a deceleration state; and a secondary-voltage stepping-up step of, when the fuel cell automobile is in the deceleration state, controlling the first converter to thereby allow the secondary voltage to become higher than the fuel cell voltage. 10 . A fuel cell automobile comprising: a fuel cell configured to generate fuel cell voltage as a primary voltage; an electrical storage device configured to generate electrical storage device voltage as another primary voltage; a motor drive unit to which a secondary voltage is supplied, the motor drive unit being configured to drive a motor which produces driving power for allowing travel of the fuel cell automobile, a first converter provided between the electrical storage device and the motor drive unit, and configured to perform voltage conversion between the electrical storage device voltage and the secondary voltage; and a second converter provided between the fuel cell and the motor drive unit, and configured to perform voltage conversion between the fuel cell voltage and the secondary voltage, a deceleration state detection sensor; and an electronic control unit connected to the fuel cell, the electrical storage device, the motor drive unit, the first converter, the second converter, and the deceleration state detection sensor, wherein when the electronic control unit determines that the fuel cell automobile is in a deceleration state based on an output of the deceleration state detection sensor, the electronic control unit controls the first converter to thereby allow the secondary voltage to become higher than the fuel cell voltage.