Battery state control circuit, battery state control device, and battery pack

What is claimed is: 1. A battery state control circuit for connection to multiple rechargeable batteries, the multiple batteries being connected in series, for connection to a primary coil connected in series to the multiple batteries, and for connection to multiple secondary coils to which electrical energy stored in the primary coil is transferred, the multiple secondary coils being connected in parallel to the multiple batteries, respectively, the battery state control circuit comprising: an adjustment unit to adjust the energy amount stored in the primary coil, in accordance with a state of at least one of the multiple batteries, wherein the primary coil repeats a cycle of storing and releasing the energy stored in the primary coil, and the adjustment unit adjusts a length of a storing period during which the primary coil stores the energy, relative to the cycle, in accordance with the state of said at least one of the multiple batteries. 2. The battery state control circuit as claimed in claim 1 , wherein the adjustment unit adjusts a length of the cycle relative to the storing period during which the primary coil stores the energy, in accordance with the state of the batteries. 3. The battery state control circuit as claimed in claim 1 , further comprising: a terminal to receive an input of a charger connection signal indicating that a charger to charge the multiple batteries is connected; wherein the adjustment unit adjusts the energy amount, in accordance with the charger connection signal, the charger connection signal serving to indicate the state of the batteries. 4. The battery state control circuit as claimed in claim 3 , wherein the adjustment unit sets the energy amount to be greater when the charger connection signal is input to the terminal, than when the charger connection signal is not input. 5. The battery state control circuit as claimed in claim 1 , further comprising: a voltage detection circuit to detect respective voltages of the batteries; wherein the adjustment unit adjusts the energy amount, in accordance with the detected voltages, the detected voltages serving to indicate the state of the batteries. 6. The battery state control circuit as claimed in claim 1 , further comprising: a connection terminal connectable to a load or a charger; and an AD converter to detect a value of a current flowing between the batteries and the connection terminal; wherein the adjustment unit adjusts the energy amount, in accordance with the current value detected by the AD converter, the current value serving to indicate the state of the batteries. 7. The battery state control circuit as claimed in claim 6 , wherein the adjustment unit increases the energy amount when an absolute value of the current value detected by the AD converter is greater than a predetermined threshold current. 8. The battery state control circuit as claimed in claim 1 , further comprising: a drive switching element connected in series to the primary coil; and a control unit to control switching ON/OFF of the drive switching element. 9. The battery state control circuit as claimed in claim 8 , wherein the adjustment unit includes a current adjustment circuit having multiple resistors connectable to the primary coil via the drive switching element, and wherein the current adjustment circuit changes connection of the multiple resistors to adjust a threshold current for switching ON/OFF of the drive switching element, for adjusting the length of the storing period during which the primary coil stores the energy, relative to the cycle. 10. The battery state control circuit as claimed in claim 8 , wherein the adjustment unit includes a frequency adjustment circuit having multiple resistors connectable to the control unit, and wherein the frequency adjustment circuit changes the connection of the resistors to adjust a switching frequency to define an ON/OFF cycle of switching of the drive switching element, for adjusting a length of the cycle relative to the storing period during which the primary coil stores the energy. 11. A battery state control circuit for connection to multiple rechargeable batteries, the multiple batteries being connected in series, for connection to a primary coil connected in series to the multiple batteries, and for connection to multiple secondary coils to which electrical energy stored in the primary coil is transferred, the multiple secondary coils being connected in parallel to the multiple batteries, respectively, the battery state control circuit comprising: an adjustment unit to adjust the energy amount stored in the primary coil, in accordance with a state of at least one of the multiple batteries; a drive switching element connected in series to the primary coil; and a control unit to control switching ON/OFF of the drive switching element, wherein the control unit keeps the drive switching element in an off state, so that the adjustment unit sets the energy amount to be zero, and wherein the primary coil repeats a cycle of storing and releasing the energy stored in the primary coil, and the adjustment unit adjusts a length of a storing period during which the primary coil stores the energy, relative to the cycle, in accordance with the state of said at least one of the multiple batteries. 12. A battery pack comprising: a battery assembly having multiple rechargeable batteries, the multiple batteries being connected in series; a transformer, connected to the battery assembly, the transformer including a primary coil connected in series to the multiple batteries; and multiple secondary coils to which electrical energy stored in the primary coil is transferred, the multiple secondary coils being connected in parallel to the multiple batteries, respectively, and a battery state control circuit for connection to the multiple batteries, the primary coil, and the multiple secondary coils, the battery state control circuit including an adjustment unit to adjust the energy amount stored in the primary coil, in accordance with a state of at least one of the multiple batteries, wherein the primary coil repeats a cycle of storing and releasing the energy stored in the primary coil, and wherein the adjustment unit adjusts a length of a storing period during which the primary coil stores the energy, relative to the cycle, in accordance with the state of said at least one of the multiple batteries.