Electric power supply system for battery assembly control circuit of electricity storage device, and electricity storage device

1 . An electric power supplying method comprising: providing an electricity storage device including a battery module including a plurality of rechargeable battery cells and a battery assembly control circuit, and a power converting device configured to charge the battery module using commercial electric power and supply the commercial electric power to a load; supplying operating electric power from the power converting device to the battery assembly control circuit of the battery module while an output voltage of the power converting device is higher than a predetermined voltage, starting to supply operating electric power from the battery module to the battery assembly control circuit in response to a connection signal from a connection detector which detects that the power converting device starts to supply electric power to the battery assembly control circuit; and stopping supplying the electric power from the battery module to the battery assembly control circuit in response to a stop signal from a discharge-stop determination unit which detects that the battery module stops being discharged. 2 . An electricity storage device comprising: a power converting device configured to receive electric power from a commercial power supply and supply electric power to a load; a battery module including a plurality of rechargeable battery cells and a battery assembly control circuit; a switching circuit configured to switch electric power supplied to the battery assembly control circuit from the power converting device and the battery module; a connection detector configured to detect that the electric power is supplied from the power converting device to the battery assembly control circuit; and a discharge-stop determination unit configured to detect a stop of discharging of the battery module, wherein the switching circuit is configured to: supply electric power from the power converting device to the battery assembly control circuit while an output voltage of the power converting device is higher than a predetermined voltage; supply operating electric power from the battery module to the battery assembly control circuit in response to a connection signal from the connection detector which detects that the electric power from the power converting device is supplied to the battery assembly control circuit; and stop supplying the electric power from the battery module to the battery assembly control circuit in response to a discharge-stop signal from the discharge-stop determination unit. 3 . An electricity storage device comprising: a power converting device configured to receive electric power from a commercial power supply and supply electric power to a load; a battery module including a plurality of rechargeable battery cells and a battery assembly control circuit; a DC-DC converter configured to supply operating electric power to the battery assembly control circuit; a switching circuit configured to switch connection between the power converting device and the battery module; a connection detector configured to detect that electric power is supplied from the power converting device to the battery assembly control circuit; and a discharge-stop determination unit configured to detect a stop of discharging of the battery module, wherein the switching circuit is configured to: connect the power converting device to the DC-DC converter while an output voltage of the power converting device is higher than a predetermined voltage, the switching circuit; connect the battery module to the DC-DC converter in response to a connection signal from the connection detector which detects connection between the power converting device and the DC-DC converter; and cuts off the connection between the battery module and the DC-DC converter in response to a discharge-stop signal from the discharge-stop determination unit. 4 . The electricity storage device of claim 3 , wherein the switching circuit includes: a first power switch connected between the power converting device and the DC-DC converter; and a first input circuit configured to control turning on and off of the first power switch by comparing the output voltage of the power converting device with the predetermined voltage, and the first input circuit is configured to: supply electric power from the power converting device to the DC-DC converter by turning on the first power switch while the output voltage of the power converting device is higher than the predetermined voltage; and cut off the supply of the electric power from the power converting device to the DC-DC converter by turning off the first power switch while the output voltage of the power converting device is lower than the predetermined voltage. 5 . The electricity storage device of claim 4 , wherein the first input circuit includes a first control switch configured to switch turning on and off of the first power switch by being turned on and off controlled by the output voltage of the power converting device. 6 . The electricity storage device of claim 5 , wherein the first control switch comprises an FET and the first power switch comprises an FET, and the FET of the first control switch is configured to control the first power switch to control supply of the electric power from the power converting device to the DC-DC converter. 7 . The electricity storage device of claim 3 , wherein the switching circuit includes: a second power switch connected between the battery module and the DC-DC converter; and a second input circuit configured to control turning on and off of the second power switch in response to the connection signal of the connection detector. 8 . The electricity storage device of claim 7 , wherein the second input circuit includes a second control switch configured to switch turning on and off of the second power switch by being switched in response to the connection signal from the connection detector. 9 . The electricity storage device of claim 3 , wherein the switching circuit includes: a second power switch connected between the battery module and the DC-DC converter; and a second input circuit configured to turning off the second power switch in response to the discharge-stop signal from the discharge-stop determination unit. 10 . The electricity storage device of claim 9 , wherein the second input circuit includes a second control switch configured to turn off the second power switch by being switched in response to the discharge-stop signal from the discharge-stop determination unit. 11 . The electricity storage device of claim 8 , wherein the second power switch comprises an FET and the second control switch comprises an FET, and the FET of the second control switch is configured to control supplying of electric power from the battery module to the DC-DC converter by controlling the second power switch. 12 . The electricity storage device of claim 3 , further comprising: a back-flow prevention diode connected between an output side of the power converting device and the DC-DC converter; and another back-flow prevention diode connected between an output side of the battery module and the DC-DC converter. 13 . The electricity storage device of claim 2 , wherein the power converting device includes: a converter configured to charge the battery module using commercial electric power; and a DC-AC inverter configured to supply electric power of the battery module to the load. 14 . The electricity storage device of claim 10 , wherein the second power switch comprises an FET and the second control switch comprises an FET, and the FET of