JP6048313B2 - Power supply - Google Patents

Description

  It is related with the power supply device which connects a some storage battery in parallel and implements charging / discharging in the some storage battery.

  Conventionally, a power supply device having a plurality of storage batteries (secondary batteries) connected in parallel to each other has been put into practical use. In such a power supply device, when charging is performed by supplying power from a charging power supply, if the output voltage of each storage battery is different, current outflow (backflow) occurs in the storage battery on the high voltage side, and the low voltage side In addition to the charging current from the charging power source, current flows into the storage battery from the storage battery on the high voltage side. As a result, excessive current flows through the storage battery on the low voltage side.

  In addition, when discharging from the above power supply device to an electric load, if the output voltage of each storage battery is different, an inflow of current (reverse flow) occurs in the storage battery on the low voltage side, and the storage battery on the high voltage side In addition to discharging to the battery, discharging to the low-voltage storage battery is also performed. As a result, excessive current flows through the storage battery on the high voltage side.

  In order to suppress the inflow of current from the storage batteries connected to each other in parallel to each other, a backflow prevention diode is connected in series to each storage battery, and a switch (opening / closing means) is connected in parallel to the diode. Technology has been proposed (Patent Document 1).

  In this case, the backflow prevention diode connected in series with the storage battery suppresses the backflow of current during charging or discharging, and the backflow prevention is achieved by opening and closing the switch according to the detected value of the voltage across each diode. The loss generated in the diode for use is reduced.

  More specifically, for example, when the output voltage of each storage battery is different at the time of charging the power supply device, the switch on the low voltage storage battery side is closed and the switch on the high voltage storage battery side is opened. Avoid discharge of voltage storage battery. And when the output voltage of each storage battery becomes substantially equal, all the switches are closed. Thereby, each storage battery is charged equally.

JP-A-9-140065

  However, the above prior art basically performs charging or discharging for a plurality of storage batteries at the same time, and in the state where charging or discharging is simultaneously performed for each storage battery, a mutual voltage difference is generated. On the other hand, there is a concern that a reverse current will occur. Therefore, it is considered that there is room for improvement with respect to charging or discharging a plurality of storage batteries.

  This invention is made | formed in view of the said subject, and it aims at providing the power supply device which can implement charging / discharging suitably about several storage battery.

This configuration is a power supply device (10) including a plurality of storage batteries (11, 12) connected in parallel to each other, and each of the current detection means (41) detects currents flowing through the plurality of storage batteries during charging or discharging. , 42), and a plurality of storage batteries connected in series, and a diode (51-54) for preventing a backflow of current during charging or a backflow of current during discharging, and a series connection to the plurality of storage batteries, respectively. In addition, the switching means (SW1 to SW4) connected in parallel to each of the diodes, and any one of the plurality of storage batteries is set as a charge / discharge target, and the battery connected as a charge / discharge target is connected in series. The opening / closing means is in a closed state, and the opening / closing means connected in series to a storage battery that is not the object of charging / discharging is in an open state, thereby making the charging / discharging object. An open / close control means (20) for charging / discharging the battery, and a determination means (20) for determining that a current flows through a storage battery that is not the target of charge / discharge based on a detection value by the current detection means; The open / close control means performs charging / discharging on the storage battery that is determined to have the current flowing when the determination means determines that the current is flowing through the storage battery that is not the target of charging / discharging. The storage battery to be charged / discharged should be changed as much as possible.

  At the time of charging or discharging of the power supply device, any of the plurality of storage batteries is subjected to charging / discharging, and at that time, by closing the open / close means connected in series to the storage battery targeted for charging / discharging, A bypass path that bypasses the diode is formed in the storage battery to be charged and discharged. Thereby, charging / discharging can be implemented about the storage battery made into the object of charging / discharging among several storage batteries, without producing the power loss by a diode.

  Moreover, it is monitored whether the electric current is flowing into the storage battery which is not the object of charging / discharging. And when the electric current is flowing into the storage battery which is not the object of charging / discharging, the storage battery used as the object of charging / discharging is changed in order to perform charging / discharging about the storage battery determined that the electric current is flowing. . In this case, the current is flowing in the storage battery that is not the target of charge / discharge, which means that the difference between the output voltage of the storage battery and the output voltage of the storage battery that is the target of charge / discharge is a value corresponding to the forward voltage of the diode. This means that the storage battery to be charged and discharged is changed when the voltage difference occurs. Therefore, it is possible to suppress the difference between the output voltages of the storage batteries from becoming excessively large in the process in which the storage batteries are sequentially charged or discharged.

  In the above configuration, charging or discharging of each storage battery is performed while the charge / discharge target is switched, and the occurrence of backflow due to the difference in the output voltage of each storage battery is suppressed. As a result, charging / discharging can be suitably performed for a plurality of storage batteries.

The electrical block diagram in 1st Embodiment. The flowchart which shows a discharge control process. The timing chart which shows a discharge control process. The electrical block diagram in 2nd Embodiment. The flowchart which shows a charge control process. The timing chart which shows charge control processing. The electrical block diagram in 3rd Embodiment. The flowchart which shows a parallel discharge control process. The flowchart which shows a parallel charge control process.

(First embodiment)
The power supply device according to the first embodiment is an on-vehicle power supply device mounted on a vehicle such as an automobile, and supplies power to various on-vehicle electric loads when the vehicle travels. Moreover, the power supply device has a configuration having a plurality of storage batteries made of secondary batteries, and each storage battery can be charged by supplying power from the in-vehicle power generation device when the vehicle is traveling. Further, in the present embodiment, the discharge is optimized in a state where electric power is supplied to an electric load using a plurality of storage batteries (that is, a discharge state). First, the electrical configuration of the power supply apparatus 10 will be described with reference to FIG. In particular, FIG. 1 shows a configuration related to the discharge of the power supply device 10.

  The power supply device 10 is connected to an electric load 100 having a resistance component 101 and a capacitance component 102, and supplies power to the electric load 100. The power supply device 10 includes a first storage battery 11 and a second storage battery 12. Both the storage batteries 11 and 12 are connected in parallel to each other and connected to the electric load 100. Both the storage batteries 11 and 12 are lithium ion storage batteries. Here, instead of the lithium ion storage battery, another storage battery such as a nickel hydride storage battery may be used.

  Both storage batteries 11 and 12 are connected to shunt resistors 31 and 32, respectively, and voltage sensors 41 and 42 are connected in parallel to the shunt resistors 31 and 32. The voltage sensors 41 and 42 detect currents flowing through the storage batteries 11 and 12 from the amount of voltage drop caused by the shunt resistors 31 and 32, and the detection result is notified to the ECU 20. In the present embodiment, a positive current is detected if each storage battery 11, 12 is in a discharged state, and a negative current is detected if each storage battery 11, 12 is in a charged state. The voltage sensors 41 and 42 correspond to current detection means.

  A first diode 51 and a second diode 52 are connected to the first storage battery 11 and the second storage battery 12, respectively. Both the diodes 51 and 52 have cathodes connected to the negative electrodes of the storage batteries 11 and 12 and permit discharge from the storage batteries 11 and 12 when the power supply device 10 is in a discharged state. 12 is prohibited from being charged. Each of the diodes 51 and 52 uses a discharge current as a forward current, and a forward voltage drop of, for example, about 0.6 V is generated by the forward current. The diodes 51 and 52 correspond to current backflow prevention means during discharge.

  A first switch SW1 and a second switch SW2 are connected in parallel to the first diode 51 and the second diode 52, respectively. The switches SW1 and SW2 form discharge paths that bypass the diodes 51 and 52. If the switches SW1 and SW2 are closed, a path that bypasses the diodes 51 and 52 is formed as a discharge path. If the switches SW1 and SW2 are open, a path that passes through the diodes 51 and 52 is formed as a discharge path. The

  The ECU 20 controls the open / close state of the switches SW1 and SW2 based on the detection results of the voltage sensors 41 and 42 (values of the currents I1 and I2 flowing through the storage batteries 11 and 12). In this case, the discharge control is performed while either one of the storage batteries 11 and 12 is used as a storage battery to be discharged and the storage battery to be discharged is alternately switched.

  FIG. 2 shows a discharge control process when the power supply apparatus 10 is discharged. The process is performed by the ECU 20 when the power supply device 10 is in a discharged state.

  In step S01, the first storage battery 11 is discharged by closing the first switch SW1 and opening the second switch SW2. In this case, the first storage battery 11 is a storage battery to be discharged, and a bypass path that bypasses the first diode 51 is formed as a discharge path on the first storage battery 11 side. Thereby, in the 1st storage battery 11, discharge is implemented in the state which suppressed the electric power loss by the 1st diode 51. FIG.

  In the subsequent step S02, it is determined whether or not a discharge current (positive current) is flowing through the second storage battery 12 that is a storage battery on the side that is not to be discharged at this time (switch opening side). And if the discharge current does not flow into the 2nd storage battery 12 (if I2> 0), the state which makes the 1st storage battery 11 the discharge object is maintained. If a discharge current is flowing through the second storage battery 12 (if I2> 0), the process proceeds to step S03, and both the first switch SW1 and the second switch SW2 are opened.

  Thereafter, in step S04, the first switch SW1 is opened and the second switch SW2 is closed, so that the second storage battery 12 is discharged. In this case, the discharge target is switched from the first storage battery 11 to the second storage battery 12, and a bypass path that bypasses the second diode 52 is formed as a discharge path on the second storage battery 12 side. Thereby, in the 2nd storage battery 12, discharge is implemented in the state which suppressed the electric power loss by the 2nd diode 52. FIG.

  In a succeeding step S05, it is determined whether or not a discharge current (positive current) is flowing through the first storage battery 11 that is a storage battery on the side that is not to be discharged at this time (switch opening side). And if the discharge current is not flowing into the 1st storage battery 11 (if I1> 0), the state which makes the 2nd storage battery 12 discharge object is maintained. If a discharge current is flowing through the first storage battery 11 (I1> 0), the process proceeds to step S06, and both the first switch SW1 and the second switch SW2 are opened. After step S06 is performed, the process returns to step S01.

  FIG. 3 shows a timing chart when the above discharge control process is performed.

  In FIG. 3, in the initial period, the first storage battery 11 is to be discharged, and SW1 = closed and SW2 = open. Therefore, a discharge current (positive current I1) flows through the first storage battery 11, and the SOC decreases with the discharge, and the output voltage V1 gradually decreases.

  At time T1, the output voltage V1 of the first storage battery 11 is lower than the output voltage V2 of the second storage battery 12, and the difference between the output voltages V1 and V2 is the forward drop of the second diode 52. It becomes larger than the voltage VF. That is, V1 <V2-VF. For this reason, the discharge current (positive current I2) starts to flow through the second storage battery 12.

  Thereafter, at time T2, both switches SW1 and SW2 are both opened due to the determination that the discharge current has flown through the second storage battery 12. Thereafter, at time T3, the state is switched to the state of SW1 = open and SW2 = closed, and accordingly, the second storage battery 12 is to be discharged.

  In the period from time T2 to T3, the first storage battery 11 and the second storage battery 12 are connected as a diode OR, and discharging is performed according to the voltage difference between the storage batteries 11 and 12. At this time, since the output voltage V2 of the second storage battery 12 is higher than the output voltage V1 of the first storage battery 11, only the second storage battery 12 is discharged. Here, when switching the first switch SW1 from the closed state to the open state and the second switch SW2 from the open state to the closed state, the second switch SW2 is closed before the first switch SW1 is switched to the open state. Is switched to the second storage battery 12 side, the current inflow from the first storage battery 11 side (backflow in the first storage battery 11) is a concern. In this respect, when the switches SW1 and SW2 are switched between open and closed, both the switches SW1 and SW2 are temporarily opened as described above, so that backflow in the first storage battery 11 is suppressed.

  Note that the period of time T2 to T3 may be a period in which the time for which both switches SW1 and SW2 are both closed is secured, and may be an extremely short period as long as the time is satisfied. In this case, the power loss in the diodes 51 and 52 can be reduced as the period of time T2 to T3 is shorter.

  After time T3, the second storage battery 12 is to be discharged, and SW1 = open and SW2 = closed. Therefore, a discharge current (positive current I2) flows through the second storage battery 12, and the SOC decreases with the discharge, and the output voltage V2 gradually decreases.

  At time T4, the output voltage V2 of the second storage battery 12 is lower than the output voltage V1 of the first storage battery 11, and the difference between the output voltages V1 and V2 is the forward drop of the first diode 51. It becomes larger than the voltage VF. That is, V2 <V1-VF. For this reason, the discharge current (positive current I1) starts to flow through the first storage battery 11.

  Thereafter, at time T5, it is determined that the discharge current has flown through the first storage battery 11, and both the switches SW1 and SW2 are both opened. Thereafter, at time T6, the state is switched to the state of SW1 = closed and SW2 = open, and the first storage battery 11 is again discharged as a result.

  In the period from time T5 to T6, as in the period from time T2 to T3, the first storage battery 11 and the second storage battery 12 are connected as a diode OR, and discharging is performed according to the voltage difference between the storage batteries 11 and 12. . At this time, discharging is performed only by the first storage battery 11.

  Thereafter, similarly to the above, the discharge of the first storage battery 11 and the discharge of the second storage battery 12 are alternately repeated.

  Hereinafter, the operational effects of the present embodiment will be described.

  When the power supply device 10 is discharged, one of the first storage battery 11 and the second storage battery is the target of discharge. At that time, by closing the switches SW1 and SW2 connected in series to the storage battery to be discharged, a detour path that bypasses the diodes 51 and 52 in the storage battery to be discharged is formed. Thereby, about the storage battery made into the discharge object among several storage batteries, it can discharge, without producing the power loss by the diodes 51 and 52 (T3-T4 of FIG. 3).

  Moreover, based on the detection result of the voltage sensors 41 and 42, it is monitored whether the electric current is flowing into the storage battery which is not the object of discharge. And when the electric current is flowing into the storage battery which is not the object of discharge, the storage battery used as the object of discharge is changed in order to start discharge about the storage battery determined that the electric current is flowing. In this case, the current is flowing through the storage battery that is not the target of discharge, which means that the difference between the output voltage of the storage battery and the output voltage of the storage battery that is the target of discharge reaches a value corresponding to the forward drop voltage VF of the diode. This means that the storage battery to be discharged is changed at the time when the voltage difference occurs (T2 and T5 in FIG. 3).

  That is, the charge / discharge target is switched when the output voltage of the storage battery to be discharged becomes lower than the output voltage of the other storage battery by the forward voltage drop VF of the diode. For this reason, generation | occurrence | production of the inflow (backflow) of the electric current to the storage battery made into the discharge object produced when the output voltage of the storage battery made into discharge object becomes lower than the output voltage of another storage battery is suppressed. As a result, it is possible to suitably discharge the plurality of storage batteries.

  In addition, before and after switching the storage battery to be discharged, the amount of change in the voltage supplied from the power supply device 10 is suppressed to about the forward voltage drop VF of the diode. For this reason, it is possible to suppress a large transient current from flowing to the electric load 100.

  After the switches connected in series to the storage battery currently being discharged are opened (T2 and T5 in FIG. 3), the switch connected in series to the storage battery newly charged / discharged is closed. State (T3, T6 in FIG. 3). Here, when both switches SW1, SW2 are opened, the storage batteries 11, 12 are connected by diode OR. For this reason, it is possible to discharge from the storage battery having a high output voltage, which is the storage battery targeted for discharge, to the electric load while suppressing the occurrence of backflow in the storage battery.

(Second Embodiment)
Next, differences of the second embodiment from the first embodiment will be mainly described. In the present embodiment, the charging is optimized in a state where the storage battery is charged by supplying power from the charging means to each storage battery. The electrical configuration of the power supply apparatus 10A in the second embodiment will be described with reference to FIG. FIG. 4 particularly shows a configuration related to charging of the power supply device 10A. In FIG. 4, the same components as those in FIG.

  A constant current power supply 200 is connected to the power supply device 10A as a charging means for supplying charging power to the storage batteries 11 and 12. A third diode 53 and a fourth diode 54 are connected to the storage batteries 11 and 12, respectively. Both diodes 53 and 54 have their anodes connected to the negative electrodes of the respective storage batteries 11 and 12 and permit charging of the respective storage batteries 11 and 12 when the power supply device 10 is in a charged state. Discharge from 12 is prohibited. The diodes 53 and 54 correspond to current backflow prevention means during charging.

  A third switch SW3 and a fourth switch SW4 are connected in parallel to the third diode 53 and the fourth diode 54, respectively. The switches SW3 and SW4 form a charging path that bypasses the diodes 53 and 54. If the switches SW3 and SW4 are closed, a path that bypasses the diodes 53 and 54 is formed as a charging path, and if the switches SW3 and SW4 are open, a path that passes through the diodes 53 and 54 is formed as a charging path. The

  The ECU 20 controls the open / close state of the switches SW3 and SW4 based on the detection results of the voltage sensors 41 and 42 (values of the currents I1 and I2 flowing through the storage batteries 11 and 12). In this case, while either one of the storage batteries 11 and 12 is used as a storage battery to be charged, charging control is performed while alternately switching the storage battery to be charged.

  FIG. 5 shows a charging control process at the time of charging the power supply apparatus 10A. The process is performed by the ECU 20 when the power supply device 10 is in a charged state.

  In step S11, the third switch SW3 is closed and the fourth switch SW4 is opened, so that the first storage battery 11 is charged. In this case, the first storage battery 11 is a storage battery to be charged, and a bypass path that bypasses the third diode 53 is formed as a charging path on the first storage battery 11 side. Thereby, in the 1st storage battery 11, charge is implemented in the state which suppressed the power loss by the 3rd diode 53. FIG.

  In continuing step S12, it is determined whether the charging current (negative current) is flowing into the 2nd storage battery 12 which is the storage battery of the side which is not charging object now. And if the charging current is not flowing into the 2nd storage battery 12 (if I2 <0), the state which makes the 1st storage battery 11 charge object is maintained. If a charging current is flowing through the second storage battery 12 (if I2 <0), the process proceeds to step S13, and both the third switch SW3 and the fourth switch SW4 are opened.

  Thereafter, in step S14, the second switch 12 is placed in a charged state by opening the third switch SW3 and closing the fourth switch SW4. In this case, the charging target is switched from the first storage battery 11 to the second storage battery 12, and a bypass path that bypasses the fourth diode 54 is formed as a charging path on the second storage battery 12 side. Thereby, in the 2nd storage battery 12, charge is implemented in the state which suppressed the electric power loss by the 4th diode 54. FIG.

  In continuing step S15, it is determined whether the charging current (negative current) is flowing into the 1st storage battery 11 which is the storage battery of the side which is not charging object now. And if the charging current does not flow into the 1st storage battery 11 (if I1 <0), the state which makes the 2nd storage battery 12 charge object is maintained. If the charging current is flowing through the first storage battery 11 (if I1 <0), the process proceeds to step S16, and both the third switch SW3 and the fourth switch SW4 are opened. After step S16 is performed, the process returns to step S11.

  FIG. 6 shows a timing chart when the above charge control process is performed.

  In FIG. 6, in the initial period, the first storage battery 11 is a target for charging, and SW3 = closed and SW4 = opened. Therefore, a charging current (negative current I1) flows through the first storage battery 11, and as the charging proceeds, the SOC increases and the output voltage V1 gradually increases.

  At time T11, the output voltage V1 of the first storage battery 11 is higher than the output voltage V2 of the second storage battery 12, and the difference between the output voltages V1 and V2 is the forward drop of the fourth diode 54. It becomes larger than the voltage VF. That is, V1> V2 + VF. For this reason, the charging current (negative current I2) starts to flow through the second storage battery 12.

  Thereafter, at time T12, both the switches SW3 and SW4 are opened in accordance with the determination that the charging current has flown through the second storage battery 12. After that, at time T13, the state is switched to the state of SW3 = open and SW4 = closed, and accordingly, the second storage battery 12 is charged.

  In the period from time T12 to T13, the first storage battery 11 and the second storage battery 12 are connected as a diode OR, and charging is performed according to the voltage difference between the storage batteries 11 and 12. At this time, since the output voltage V2 of the second storage battery 12 is lower than the output voltage V1 of the first storage battery 11, only the second storage battery 12 is charged. Here, when switching the third switch SW3 from the closed state to the open state and switching the fourth switch SW4 from the open state to the closed state, the fourth switch SW4 is closed before the third switch SW3 is switched to the open state. Is switched, the current inflow from the first storage battery 11 side to the second storage battery 12 side (backflow in the first storage battery 11) is concerned. In this respect, when the switches SW3 and SW4 are opened and closed, both the switches SW3 and SW4 are temporarily opened as described above, so that the back flow in the first storage battery 11 is suppressed.

  After time T13, the second storage battery 12 is charged, and SW3 = open and SW4 = closed. Therefore, a charging current (negative current I2) flows through the second storage battery 12, and as the charging proceeds, the SOC increases and the output voltage V2 gradually increases.

  At time T <b> 14, the output voltage V <b> 2 of the second storage battery 12 is higher than the output voltage V <b> 1 of the first storage battery 11, and the difference between the output voltages V <b> 1 and V <b> 2 is the forward drop of the third diode 53. It becomes larger than the voltage VF. That is, V2> V1 + VF. For this reason, the charging current (negative current I1) starts to flow through the first storage battery 11.

  Thereafter, at time T15, both the switches SW3 and SW4 are opened in accordance with the determination that the charging current has flown through the first storage battery 11. Thereafter, at time T16, the state is switched to the state of SW3 = closed and SW4 = open, and the first storage battery 11 is again charged as a result.

  In the period from time T15 to T16, similarly to the period from time T12 to T13, the first storage battery 11 and the second storage battery 12 are connected as a diode OR, and charging is performed according to the voltage difference between the storage batteries 11 and 12. . At this time, charging is performed only by the first storage battery 11.

  Thereafter, similarly to the above, charging of the first storage battery 11 and charging of the second storage battery 12 are repeatedly performed alternately.

  Hereinafter, the effect in this embodiment is shown.

  When the output voltage of the storage battery to be charged becomes higher by the forward drop voltage VF of the diodes 53 and 54 than the output voltage of the other storage battery, a charging current flows to the storage battery that is not to be charged. When it is determined that the charging current has flowed through the storage battery that is not the charging target, the charging target is switched. For this reason, generation | occurrence | production of the outflow (backflow) of the electric current from the storage battery made into charge object to another storage battery which arises because the output voltage of the storage battery made into charge object becomes higher than the output voltage of another storage battery is suppressed. Is done. As a result, charging can be suitably performed for a plurality of storage batteries.

  Further, before and after switching of the storage battery to be charged, the amount of change in the voltage supplied from the constant current power supply 200 to the power supply device 10A is suppressed to about the forward drop voltage VF of the diodes 53 and 54. For this reason, it is possible to suppress a large transient current from flowing in the power supply device 10.

  After the switch connected in series to the storage battery currently charged is opened (T12, T15 in FIG. 6), the switch connected in series to the storage battery newly charged is closed. (T13, T16 in FIG. 6). Here, when both switches SW3 and SW4 are opened, the storage batteries 11 and 12 are connected by diode OR. For this reason, it can charge with respect to the storage battery with a low output voltage which is the storage battery made into charge object, suppressing generation | occurrence | production of the backflow in a storage battery.

(Third embodiment)
Next, differences of the third embodiment from the above embodiments will be mainly described. In the present embodiment, a configuration having both a discharge control function and a charge control function will be described. The electrical configuration of the power supply apparatus 10B in the third embodiment will be described with reference to FIG. In FIG. 7, the same components as those in FIGS. 1 and 4 are denoted by the same reference numerals.

  In the power supply device 10B, diodes 51 and 53 whose forward directions are opposite to each other are connected in series to the first storage battery 11, and diodes 52 and 54 whose forward directions are opposite to each other are connected to the second storage battery 12 in series. It is connected. Further, switches SW1, SW2, SW3, and SW4 are connected in parallel to the diodes 51 to 54, respectively.

  The ECU 20 controls the open / close states of the switches SW1 to SW4 based on the detection results of the voltage sensors 41 and 42 (values of the currents I1 and I2 flowing through the storage batteries 11 and 12). In this case, while either one of the storage batteries 11 and 12 is a storage battery to be discharged or charged, charge / discharge control is performed while alternately switching the storage battery to be discharged or charged. The ECU 20 performs a parallel discharge control process shown in FIG. 8 and a parallel charge control process shown in FIG. 9 as the charge / discharge control. First, the parallel discharge control process of FIG. 8 will be described.

  In FIG. 8, in step S21, a process of disconnecting the second storage battery 12 from the power supply system is performed as an initial process. Specifically, the switches SW1 and SW3 on the first storage battery 11 side are closed, and the switches SW2 and SW4 on the second storage battery 12 side are opened.

  Thereafter, in step S22, the first storage battery 11 is placed in a discharged state by setting the first storage battery 11 side to SW1 = closed, SW3 = closed, and the second storage battery 12 side to SW2 = open, and SW4 = closed. To do. In this case, the first storage battery 11 is a storage battery to be discharged, and a bypass path that bypasses the diodes 51 and 53 is formed as a discharge path on the first storage battery 11 side.

  After that, in step S23, it is determined whether or not a charging current (negative current) is flowing through the first storage battery 11 that is the current discharge target. In the subsequent step S24, the second current that is not the current discharge target is determined. It is determined whether or not a discharge current (positive current) is flowing through the storage battery 12. And if step S23 is YES (if I1 <0), it will transfer to another parallel charge control processing (FIG. 9) noting that the power supply device 10B is in the charge state instead of discharging. Moreover, if step S24 is NO, the state which makes the 1st storage battery 11 discharge object is maintained. Moreover, if step S24 is YES, it will progress to step S25 and will make the 1st storage battery 11 side into the state of SW1 = open, SW3 = closed, and the 2nd storage battery 12 side in the state of SW2 = open and SW4 = closed. Both the storage batteries 11 and 12 are in a diode-or state.

  Thereafter, in step S26, the first storage battery 11 side is set to SW1 = open, SW3 = closed state, the second storage battery 12 side is set to SW2 = closed, and SW4 = closed state, so that the second storage battery 12 is set to the discharged state. To do. In this case, the discharge target is switched from the first storage battery 11 to the second storage battery 12, and a bypass path that bypasses the diodes 52 and 54 is formed as a discharge path on the second storage battery 12 side.

  In subsequent step S27, it is determined whether or not a charging current (negative current) is flowing through the second storage battery 12 that is currently subject to discharge. In subsequent step S28, the first storage battery that is not currently subject to discharge. 11 determines whether or not a discharge current (positive current) flows. If step S27 is YES (if I2 <0), it is determined that the power supply device 10B is in a charged state rather than discharged, and the process proceeds to another parallel charge control process (FIG. 9). Moreover, if step S28 is NO, the state which makes the 2nd storage battery 12 discharge object is maintained. Moreover, if step S28 is YES, it will progress to step S29 and will be in the state of SW1 = open and SW3 = closed on the 1st storage battery 11 side, SW2 = open and SW4 = closed state on the 2nd storage battery 12 side. Both the storage batteries 11 and 12 are in a diode-or state. And after implementation of step S29, it returns to the process of step S22.

  In FIG. 9, in step S31, a process of disconnecting the second storage battery 12 from the power supply system is performed as an initial process. Specifically, the switches SW1 and SW3 on the first storage battery 11 side are closed, and the switches SW2 and SW4 on the second storage battery 12 side are opened.

  Thereafter, in step S32, the first storage battery 11 is placed in a charged state by setting the first storage battery 11 side to SW1 = closed, SW3 = closed, and the second storage battery 12 side to SW2 = closed, SW4 = open. To do. In this case, the first storage battery 11 is a storage battery to be charged, and a bypass path that bypasses the diodes 51 and 53 is formed as a charging path on the first storage battery 11 side.

  Thereafter, in step S33, it is determined whether or not a discharge current (positive current) is flowing through the first storage battery 11 that is currently charged, and in step S34, the second battery that is not currently charged. It is determined whether or not a charging current (negative current) flows through the storage battery 12. And if step S33 is YES (if I1> 0), it will shift to another parallel discharge control processing (FIG. 8) noting that the power supply device 10B is in the state of discharge instead of charge. Moreover, if step S34 is NO, the state which makes the 1st storage battery 11 charge object is maintained. Moreover, if step S34 is YES, it will progress to step S35 and will make the 1st storage battery 11 side into the state of SW1 = closed, SW3 = open, the 2nd storage battery 12 side in the state of SW2 = closed, SW4 = open. Both the storage batteries 11 and 12 are in a diode-or state.

  Thereafter, in step S36, the first storage battery 11 side is set to SW1 = closed, SW3 = open state, the second storage battery 12 side is set to SW2 = closed, and SW4 = closed state, so that the second storage battery 12 is charged. To do. In this case, the charging target is switched from the first storage battery 11 to the second storage battery 12, and a bypass path that bypasses the diodes 52 and 54 is formed as a charging path on the second storage battery 12 side.

  In subsequent step S37, it is determined whether or not a discharge current (positive current) is flowing through the second storage battery 12 that is currently charged. In subsequent step S38, the first storage battery that is not currently charged. 11 determines whether or not a charging current (negative current) flows. If step S37 is YES (if I2> 0), it is determined that the power supply device 10B is in a discharging state, not a charging state, and the process proceeds to another parallel discharge control process (FIG. 8). Moreover, if step S38 is NO, the state which makes the 2nd storage battery 12 charge object is maintained. If step S38 is YES, the process proceeds to step S39, where the first storage battery 11 side is set to SW1 = closed, SW3 = open, the second storage battery 12 side is set to SW2 = closed, and SW4 = open. Both the storage batteries 11 and 12 are in a diode-or state. And after implementation of step S39, it returns to the process of step S32.

  As mentioned above, according to 3rd Embodiment, there exists an effect similar to 1st Embodiment and 2nd Embodiment. Furthermore, when it is determined that the charging current is flowing in the storage battery that is the target of discharge during the discharge process, the process is switched to the charge process. Moreover, if it determines with the discharge current flowing into the storage battery made into the object of charge during implementation of a charge process, it will switch to a discharge process. That is, when the target connected to the power supply apparatus 10B is switched from the constant current power source to the electric load, the discharge process is performed quickly, and when the target is switched from the electric load to the constant current power source, the charging process is performed quickly. To be implemented.

(Other embodiments)
-In the above-mentioned embodiment, although the power supply device was set as the structure provided with 2 storage batteries, it is good also as a structure provided with 3 or more storage batteries. In this case, a backflow prevention diode, a switch as a detour path, and current detection means are provided for the storage battery.

  When the difference between the voltage of the storage battery selected as the target for charging / discharging and the output voltage of the other storage battery becomes larger than the forward drop voltage VF of the diode for preventing backflow, current flows in the storage battery having the largest voltage difference. . When the current is detected, the storage battery through which the current has flowed is newly set as a charge / discharge target, whereby an excessive increase in the output voltage difference between the storage batteries can be suppressed.

  Even when storage batteries having different charge capacities are connected in parallel, the difference in output voltage between the storage batteries can be suppressed to the forward voltage drop VF of the diode. For this reason, it becomes possible to switch and use those storage batteries suitably.

  As the current detection means, a Hall element or the like may be used instead of the voltage sensor.

  DESCRIPTION OF SYMBOLS 10 ... Power supply device, 11 ... 1st storage battery, 12 ... 2nd storage battery, 20 ... ECU (opening-closing control means, determination means), 41, 42 ... Voltage sensor (current detection means), 51-54 ... Diode, SW1-SW4 ... Switch (open / close means).

Claims (2)

A power supply device (10) comprising a plurality of storage batteries (11, 12) connected in parallel to each other,
Current detection means (41, 42) for respectively detecting currents flowing through the plurality of storage batteries during charging or discharging;
A first diode (53, 54) connected in series to each of the plurality of storage batteries to prevent reverse current flow during charging , and a second diode (51 , 52 ) to prevent reverse current flow during discharging;
Open / close means (SW1 to SW4) connected in series to the plurality of storage batteries and connected in parallel to the first diode and the second diode , respectively.
As the charge control, any one of the plurality of storage batteries is to be charged , connected in series to a storage battery that is not the charge target, the open / close means connected in parallel to the first diode is opened, and all the other In the closed state of the opening and closing means , charging with the storage battery targeted for the charging ,
As the discharge control, any one of the plurality of storage batteries is to be discharged, the open / close means connected in series to the storage battery that is not the discharge target and connected in parallel to the second diode is opened, and the other Opening / closing control means (20) for performing discharge in the storage battery targeted for discharge by closing all the opening / closing means ,
Current is flowing through the storage battery that is not the target of charging when the charge control is performed, current is flowing through the storage battery that is not the target of discharging when the discharge control is performed, and target of the charging is performed when the charge control is performed Based on the detection value by the current detection means that the storage battery is discharged, and that the discharge control is being performed with the storage battery being charged when the discharge control is performed, respectively. A determination means (20) for determining ;
With
The opening / closing control means includes
If it is determined by said determining means and current to the battery the non charging of the target during the implementation of the charge control is flowing, and the target charging in order to implement charging for determined to be storage battery that current is flowing the made-acid battery change,
When it is determined by the determination means that a current is flowing in a storage battery that is not the target of discharge when the discharge control is performed, the storage battery that is determined to have the current flowing is determined to be discharged. Change the storage battery
When it is determined by the determination means that the storage battery that is the target of charging is being discharged at the time of performing the charging control, the charging control is shifted to the discharging control,
A power supply apparatus that shifts from the discharge control to the charge control when the determination unit determines that the storage battery that is the target of discharge is being charged when the discharge control is performed . The opening / closing control means includes
When changing the storage battery to be charged, the switching means connected in series to the storage battery to be charged before the change and connected in parallel to the first diode is changed from a closed state to an open state. After switching, the switching means connected in series to the storage battery to be newly charged and connected in parallel to the first diode is switched from the open state to the closed state,
When changing the storage battery to be discharged, the switching means connected in series to the storage battery to be discharged before the change and connected in parallel to the second diode is changed from a closed state to an open state. 2. The power supply according to claim 1, wherein after switching, the switching means connected in series to a storage battery to be newly discharged and connected in parallel to the second diode is switched from an open state to a closed state. apparatus.

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