Hybrid power source system

The invention claimed is: 1. A hybrid power source system comprising: a solar cell module or a fuel cell module; direct-current to direct-current (DC/DC) voltage converter configured to supply a voltage to a load and a secondary cell after said solar cell module or said fuel cell module is connected to an input side of the DC/DC voltage converter, said load and said secondary cell being connected to an output side of the DC/DC voltage converter, wherein a generated electric power which said solar cell module or said fuel cell module generates is converted into the voltage, and wherein said secondary cell is connected in parallel with said load; division resistors configured to divide a voltage developed across said secondary cell to generate a reference voltage; and a shunt circuit connected in parallel with said secondary cell on the output side of said DC/DC voltage converter, wherein said shunt circuit is configured to generate a voltage having a magnitude which enables the secondary cell to be substantially in a full charging state, and wherein said magnitude is such that an overcharging of said secondary cell is prevented, wherein said shunt circuit comprises: a standard voltage generating portion configured to generate a standard voltage, wherein operation of said DC/DC voltage converter is controlled based on a difference between said reference voltage and said standard voltage, and wherein a voltage at which said secondary cell becomes substantially fully charged is determined from the following: V max=( R +1) Vs, wherein Vmax is said voltage at which said secondary cell becomes substantially fully charged, R is a ratio of resistance values of said division resistors, and Vs is said standard voltage. 2. The hybrid power source system according to claim 1 , wherein an output voltage from said DC/DC voltage converter is set slightly higher than a voltage of said secondary cell. 3. The hybrid power source system according to claim 1 , wherein an input voltage of said DC/DC voltage converter is controlled so as to become an optimal operating voltage of said solar cell module or said fuel cell module, or the vicinity thereof. 4. The hybrid power source system according to claim 1 , wherein said shunt circuit is composed of a constant voltage diode having a Zener voltage, wherein a magnitude of said Zener voltage is such that said secondary cell is charged to a substantially full charging state, and wherein said magnitude is such that an overcharging of said secondary cell is prevented. 5. The hybrid power source system according to claim 1 , wherein said shunt circuit is composed of plural diodes connected in series, and a sum of forward voltage drops of said diodes is a voltage having a magnitude which enables said secondary cell to be substantially in a full charging state, and wherein said magnitude is such that an overcharging of said secondary cell is prevented. 6. The hybrid power source system according to claim 1 , wherein said shunt circuit is composed of a shunt regulator circuit having a shunt path composed of a transistor, and a maximum value of a voltage applied across terminals of said secondary cell is controlled by said shunt regulator circuit so as to become a voltage having a magnitude which enables said secondary cell to be substantially in a fully charged state, and wherein said magnitude is such that an overcharging of said secondary cell is prevented. 7. The hybrid power source system according to claim 6 , wherein the maximum value of the voltage controlled by said shunt regulator circuit is set by comparison between said reference voltage and said standard voltage. 8. The hybrid power source system according to claim 1 , wherein said solar cell is a dye-sensitized solar cell. 9. The hybrid power source system according to claim 1 , wherein said fuel cell is a direct methanol fuel cell. 10. The hybrid power source system according to claim 1 , wherein said secondary cell is a lithium-ion cell.