JP2019106884A - Battery control circuit, battery control device, and battery pack - Google Patents

Abstract

To efficiently perform balancing between respective cell voltage values of a plurality of cells connected in series.SOLUTION: A battery control circuit for controlling a balance between respective cell voltage values of a plurality of cells connected in series comprises: a plurality of connection terminals capable of being connected to a positive electrode of a corresponding cell of the plurality of cells; a ground terminal that is connected to an internal ground of the battery control circuit and is capable of being connected to a negative electrode of a cell at the lowest stage of the plurality of cells; a control circuit that from the plurality of connection terminals, selects at least one connection terminal connected to the internal ground via an internal current path of the battery control circuit; and a current generation circuit that makes terminal current having a current value changing depending on a cell voltage value of a cell having a positive electrode capable of being connected to the connection terminal selected by the control circuit flow from the connection terminal selected by the control circuit to the internal ground via the internal current path.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a battery control circuit, a battery control device, and a battery pack.

  Conventionally, a balancing circuit including a plurality of current regulators that flow current from the positive terminal of the corresponding cell to ground so that a bypass path is formed in each of the plurality of cells in order to balance the voltages of the plurality of cells connected in series. Are known (see, for example, Patent Document 1).

JP, 2009-201345, A

  However, in the prior art, since the constant current generated by the current regulator flows to the terminal connected to the positive electrode of the cell regardless of the level of the cell voltage of the cell, the cell voltage value of each cell is It is difficult to balance well.

  Thus, the present disclosure provides a battery control circuit, a battery control device, and a battery pack that can efficiently balance each cell voltage value of a plurality of cells connected in series.

The present disclosure
A battery control circuit for controlling the balance of cell voltage values of a plurality of cells connected in series, comprising:
A plurality of connection terminals that can be connected to a positive electrode of a corresponding one of the plurality of cells;
A ground terminal connected to the internal ground of the battery control circuit and capable of being connected to the negative electrode of the lowermost cell of the plurality of cells;
A control circuit that selects at least one connection terminal connected to the internal ground via the internal current path of the battery control circuit from among the plurality of connection terminals;
The terminal current whose current value changes according to the cell voltage value of the cell whose positive terminal can be connected to the connection terminal selected by the control circuit is transmitted from the connection terminal selected by the control circuit via the internal current path. A battery control circuit including: a current generation circuit flowing to an internal ground.

Also, the present disclosure
A battery control circuit for controlling the balance of cell voltage values of a plurality of cells connected in series, comprising:
A plurality of connection terminals that can be connected to a positive electrode of a corresponding one of the plurality of cells;
A ground terminal connected to the internal ground of the battery control circuit and capable of being connected to the negative electrode of the lowermost cell of the plurality of cells;
A current generation circuit that generates a plurality of currents whose current value changes in accordance with a voltage value between adjacent ones of the plurality of connection terminals and the ground terminal;
And a control circuit for selecting at least one terminal current to be supplied to the internal ground from the terminal having the higher potential of the adjacent terminals from the plurality of currents via the internal current path of the battery control circuit. Provided is a battery control circuit.

Also, the present disclosure
A battery control circuit for controlling the balance of cell voltage values of a plurality of cells connected in series, comprising:
A plurality of connection terminals that can be connected to a positive electrode of a corresponding one of the plurality of cells;
A ground terminal connected to the internal ground of the battery control circuit and capable of being connected to the negative electrode of the lowermost cell of the plurality of cells;
A control circuit which selects at least one cell to be discharged from the plurality of cells;
The terminal current whose current value changes in accordance with the cell voltage value of the cell selected by the control circuit is passed from the connection terminal to which the positive electrode of the cell selected by the control circuit can be connected via the internal current path of the battery control circuit And a current control circuit flowing to the internal ground.

Also, the present disclosure
A cell balance circuit for balancing cell voltage values of a plurality of cells connected in series;
A battery control circuit for controlling the cell balance circuit;
The battery control circuit is
A plurality of connection terminals that can be connected to a positive electrode of a corresponding one of the plurality of cells;
A ground terminal connected to the internal ground of the battery control circuit and capable of being connected to the negative electrode of the lowermost cell of the plurality of cells;
A control circuit that selects at least one connection terminal connected to the internal ground via the internal current path of the battery control circuit from among the plurality of connection terminals;
The terminal current whose current value changes according to the cell voltage value of the cell whose positive terminal can be connected to the connection terminal selected by the control circuit is transmitted from the connection terminal selected by the control circuit via the internal current path. A battery control device is provided, which includes: a current generation circuit flowing to an internal ground.

Also, the present disclosure
A plurality of cells connected in series;
A cell balance circuit for balancing cell voltage values of the plurality of cells;
A battery control circuit for controlling the cell balance circuit;
The battery control circuit is
A plurality of connection terminals connected to the positive electrode of the corresponding cell among the plurality of cells;
A ground terminal connected to the internal ground of the battery control circuit and connected to the negative electrode of the lowermost cell of the plurality of cells;
A control circuit that selects at least one connection terminal connected to the internal ground via the internal current path of the battery control circuit from among the plurality of connection terminals;
The terminal current whose current value changes according to the cell voltage value of the cell whose positive terminal is connected to the connection terminal selected by the control circuit is transmitted from the connection terminal selected by the control circuit via the internal current path. A battery pack comprising: a current generating circuit flowing to an internal ground.

  According to the present disclosure, cell voltage values of a plurality of cells connected in series can be efficiently balanced.

It is a figure which shows an example of a structure of a battery pack. It is a figure which shows an example of a structure of a battery control circuit. It is a functional block diagram of a control circuit. It is a timing chart which shows an example of operation of a battery control circuit.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a diagram showing an example of the configuration of a battery pack. A battery pack 100 shown in FIG. 1 includes a secondary battery 30 and a battery protection device 80.

  The secondary battery 30 is an example of a chargeable / dischargeable battery. The secondary battery 30 can supply power to the load 90 connected to the plus terminal 5 (P + terminal) and the minus terminal 6 (P− terminal). The secondary battery 30 can be charged by a charger (not shown) connected to the plus terminal 5 and the minus terminal 6. Examples of the secondary battery 30 include lithium ion batteries and lithium polymer batteries. The battery pack 100 may be built in the load 90 or may be externally attached.

  The load 90 is an example of a load powered by the secondary battery 30 of the battery pack 100. Specific examples of the load 90 include electronic devices such as portable portable terminal devices. Specific examples of the mobile terminal device include electronic devices such as a mobile phone, a smartphone, a tablet computer, a game machine, a television, a music and video player, and a camera.

  The secondary battery 30 is configured to include a plurality of cells connected in series (exemplified by five cells 31 to 35 in FIG. 1). The positive electrode of the secondary battery 30 is connected to the positive electrode of the topmost cell 35 of the highest potential among the cells 31 to 35 configured in the secondary battery 30, and the negative electrode of the secondary battery 30 is connected to the secondary battery 30. It is connected to the negative electrode of the lowermost cell 31 of the lowest potential among the constructed cells 31 to 35. The positive electrode of the cell is the electrode on the high potential side of the cell, and the negative electrode of the cell is the electrode on the low potential side of the cell.

  The battery protection device 80 is an example of a battery control device that operates using the secondary battery 30 as a power source, and protects the secondary battery 30 from overcharging and the like by controlling charging and discharging of the secondary battery 30. The battery protection device 80 includes a plus terminal 5, a minus terminal 6, a cell balance circuit 20, a charge control transistor 1, a discharge control transistor 2, and a battery protection circuit 70.

  The positive terminal 5 is an example of a terminal connected to the load 90 or the positive terminal of the charger. The negative terminal 6 is an example of a terminal connected to the load 90 or the negative terminal of the charger.

  The positive electrode of the secondary battery 30 (positive electrode of the cell 35) and the positive terminal 5 are connected by the positive power supply path 9a, and the negative electrode of the secondary battery 30 (negative electrode of the cell 31) and the negative terminal 6 are negative power supplies. It is connected by the route 9b. The positive side power supply path 9 a is an example of a charge / discharge current path between the positive electrode of the secondary battery 30 and the positive terminal 5, and the negative side power supply path 9 b is between the negative electrode of the secondary battery 30 and the negative terminal 6. It is an example of the charge / discharge current path of

  The negative electrode of the secondary battery 30 (the negative electrode of the cell 31) is connected to the VSS terminal through the wiring 160. The positive electrode of the cell 31 and the negative electrode of the cell 32 are connected to the V1 terminal through the wiring 161. The resistor 11 is inserted in series in the wiring 161. The positive electrode of the cell 32 and the negative electrode of the cell 33 are connected to the V2 terminal through the wiring 162. The resistor 12 is inserted in series in the wiring 162. The positive electrode of the cell 33 and the negative electrode of the cell 34 are connected to the V3 terminal through the wiring 163. The resistor 13 is inserted in series in the wiring 163. The positive electrode of the cell 34 and the negative electrode of the cell 35 are connected to the V4 terminal through the wiring 164. The resistor 14 is inserted in series in the wiring 164. The positive electrode of the secondary battery 30 (the positive electrode of the cell 35) is connected to the V5 terminal through the wiring 165, and is connected to the VDD terminal through the wiring 166. The resistor 15 is inserted in series in the wiring 165. The resistor 16 is inserted in series in the wiring 166.

  The resistor 16 is inserted in series in the wiring 166. In addition, a capacitor element 46 is provided, one end of which is connected to the wiring 166 and the other end of which is connected to the wiring 164. The resistor 16 and the capacitive element 46 form a low pass filter that smoothes the power supply voltage applied to the VDD terminal.

  The cell balance circuit 20 is an equalizing circuit that balances the cell voltage values of the cells 31 to 35 and reduces variations in cell voltage values among the cells 31 to 35. The cell balance circuit 20 includes five cell balance circuit units as many as the cells 31 to 35. The first cell balance circuit unit is connected to the cell 31 via the wirings 160 and 161. The second cell balance circuit unit is connected to the cell 32 through the wirings 161 and 162. The third cell balance circuit unit is connected to the cell 33 via the wirings 162 and 163. The fourth cell balance circuit unit is connected to the cell 34 via the wirings 163 and 164. The fifth cell balance circuit unit is connected to the cell 35 via the wirings 164 and 165.

  The first cell balance circuit discharges the cell 31 in accordance with the terminal current IV1 flowing from the positive electrode of the cell 31 to the V1 terminal. The second cell balance circuit discharges the cell 32 according to the terminal current IV2 flowing from the positive electrode of the cell 32 to the V2 terminal. The third cell balance circuit discharges the cell 33 according to the terminal current IV3 flowing from the positive electrode of the cell 33 to the V3 terminal. The fourth cell balance circuit discharges the cell 34 in accordance with the terminal current IV4 flowing from the positive electrode of the cell 34 to the V4 terminal. The fifth cell balance circuit discharges the cell 35 in accordance with the terminal current IV5 flowing from the positive electrode of the cell 35 to the V5 terminal. By discharging each of the cells 31 to 35 so that the cell voltage value of each of the cells 31 to 35 is equal to each other, it is possible to maintain the balance of the cell voltage value among the cells 31 to 35.

  For example, the first cell balance circuit unit has a discharge circuit configured to include the resistor 11, the discharge transistor 21, and the capacitive element 41. The discharge transistor 21 is connected in parallel to the cell 31. The resistor 11 is inserted in series in the wiring 161. When a terminal current IV1 flowing into the V1 terminal flows through the resistor 11, a voltage drop occurs across the resistor 11. As the discharge transistor 21 is turned on by this voltage drop, the cell 31 is discharged via the discharge transistor 21.

  The configuration of the second to fifth cell balance circuit units is the same as that of the first cell balance circuit unit, as apparent from the drawings, and thus the detailed description thereof will be omitted. Further, the operations of the second to fifth cell balance circuit units are also the same as the first cell balance circuit unit, and thus the detailed description thereof will be omitted.

  The discharge transistors 21 to 25 are, for example, pnp bipolar transistors. For example, the discharge transistor 21 has a collector connected to the negative electrode of the cell 31, an emitter connected to the positive electrode of the cell 31 and one end of the resistor 11, and a base connected to the other end of the resistor 11. It is apparent from the drawings that the configurations and connection destinations of the discharge transistors 22 to 25 are the same as those of the discharge transistor 21, and thus the detailed description thereof will be omitted.

  The charge control transistor 1 is an example of a charge path blocker that blocks the charge path of the secondary battery 30, and the discharge control transistor 2 is an example of a discharge path blocker that blocks the discharge path of the secondary battery 30. In the case of FIG. 1, the charge control transistor 1 shuts off the power supply path 9 b through which the charge current of the secondary battery 30 flows, and the discharge control transistor 2 shuts off the power supply path 9 b through which the discharge current of the secondary battery 30 flows. The transistors 1 and 2 are switching elements that switch on / off of the power supply path 9b, and are inserted in series in the power supply path 9b.

  The transistors 1 and 2 are, for example, N-channel MOS (Metal Oxide Semiconductor) transistors.

  The N channel type MOS transistor is referred to as an NMOS transistor, and the P channel type MOS transistor is referred to as a PMOS transistor.

  The battery protection circuit 70 is an example of a battery control circuit. The battery protection circuit 70 used in the battery protection device 80 is an integrated circuit (IC) that performs the protection operation of the cells 31 to 35 of the secondary battery 30. The battery protection circuit 70 includes, for example, a COUT terminal, a V− terminal, a DOUT terminal, a VDD terminal, a VSS terminal, V1 to V5 terminals, and a control circuit 150.

  The COUT terminal is an example of a charge control terminal that is connected to the gate of the charge control transistor 1 and that outputs a gate control signal that turns the charge control transistor 1 on or off. The V− terminal is connected between the transistors 1 and 2 and the negative terminal 6 in the negative side power supply path 9 b connecting the negative electrode of the secondary battery 30 and the negative terminal 6. The DOUT terminal is an example of a discharge control terminal that is connected to the gate of the discharge control transistor 2 and that outputs a gate control signal that turns the discharge control transistor 2 on or off.

  The VDD terminal is a power supply terminal of the battery protection circuit 70, and is connected to the positive electrode of the cell 35 and the positive side power supply path 9a. The VDD terminal is connected to the positive electrode of the cell 35 via the resistor 16. The VSS terminal is a ground terminal of the battery protection circuit 70, and is connected to the negative electrode of the cell 31 and the negative power supply path 9b.

  The VSS terminal and the V1 terminal are terminals used to detect the cell voltage value of the cell 31. The V1 terminal and the V2 terminal are terminals used to detect the cell voltage value of the cell 32. The V2 terminal and the V3 terminal are terminals used to detect the cell voltage value of the cell 33. The V3 terminal and the V4 terminal are terminals used to detect the cell voltage value of the cell 34. The V4 terminal and the V5 terminal are terminals used to detect the cell voltage value of the cell 35. Further, terminal currents IV1 to IV5 for controlling the discharge of the corresponding cells 31 to 35 flow through the V1 to V5 terminals, respectively. Therefore, the V1 to V5 terminals double as the cell voltage value detection terminal and the cell balance control terminal.

  For example, when overcharging or charging overcurrent of the secondary battery 30 is detected, the control circuit 150 outputs a gate control signal for turning off the charge control transistor 1 from the COUT terminal. The control circuit 150 turns off the charge control transistor 1 to inhibit the current in the direction of charging the secondary battery 30 from flowing in the power supply path 9 b.

  For example, when an overdischarge or a discharge overcurrent of the secondary battery 30 is detected, the control circuit 150 outputs, from the DOUT terminal, a gate control signal that turns the discharge control transistor 2 from on to off. The control circuit 150 turns off the discharge control transistor 2 to inhibit the current in the direction in which the secondary battery 30 is discharged from flowing into the power supply path 9 b.

  The control circuit 150 is formed, for example, using a plurality of analog logic circuits without using a CPU (Central Processing Unit).

  FIG. 2 is a diagram showing an example of the configuration of the battery protection circuit 70. As shown in FIG. The battery protection circuit 70 is an example of a battery control circuit that controls the balance of cell voltage values of a plurality of cells connected in series. The battery protection circuit 70 includes, for example, a VDD terminal, V1 to V5 terminals, a VSS terminal, a control circuit 150, a current generation circuit 170, a switch circuit 120, a detector 130, and an oscillator 140.

  The VDD terminal is a power supply terminal connected to the internal power supply line 172 of the battery protection circuit 70 and connected to the positive electrode of the uppermost cell among the plurality of cells. The V1 to V5 terminals are a plurality of connection terminals connected to the positive electrode of the corresponding cell among the plurality of cells. The VSS terminal is a ground terminal connected to the internal ground 171 of the battery protection circuit 70 and connected to the negative electrode of the lowermost cell of the plurality of cells.

  In one embodiment, the control circuit 150 selects at least one connection terminal connected to the internal ground 171 via the internal current path of the battery protection circuit 70 from the plurality of V1 to V5 terminals. For example, the control circuit 150 is connected to the internal ground 171 from the plurality of V1 to V5 terminals through the internal current path of the battery protection circuit 70 by turning on at least one of the selection switches 111 to 115. Select at least one connection terminal to be connected. In this embodiment, the current generation circuit 170 generates a terminal current whose current value varies in accordance with the cell voltage value of the cell whose positive terminal can be connected to the connection terminal selected by the control circuit 150. Then, the current generation circuit 170 causes the generated terminal current to flow from the connection terminal selected by the control circuit 150 to the internal ground 171 via the internal current path of the battery protection circuit 70.

  For example, when the connection terminal selected by the control circuit 150 is the V2 terminal, the current generation circuit 170 generates a terminal current IV2 whose current value varies in accordance with the cell voltage value of the cell 32. Then, the current generation circuit 170 causes the generated terminal current IV2 to flow from the V2 terminal selected by the control circuit 150 to the internal ground 171 via the internal current path of the battery protection circuit 70.

  In one embodiment, the current generation circuit 170 generates a plurality of currents whose current values are variable according to the voltage value between the V1 to V5 terminals and the adjacent terminals among the VSS terminals. In this embodiment, the adjacent terminals represent a pair of adjacent terminals among six terminals including the V1 to V5 terminals and the VSS terminal (for example, the V3 terminal and the V2 terminal, or the V1 terminal and the VSS terminal) Such). In this embodiment, of the plurality of currents generated by the current generation circuit 170, the control circuit 150 is internally connected via the internal current path of the battery protection circuit 70 from the terminal having the higher potential among the adjacent terminals. At least one terminal current flowing to the ground 171 is selected. For example, the control circuit 150 turns on at least one of the selection switches 111 to 115 to cause the internal ground via the internal current path of the battery protection circuit 70 from the terminal with the higher potential among the adjacent terminals. At least one terminal current to be supplied to 171 is selected.

  In one embodiment, the control circuit 150 selects at least one cell to be discharged from the plurality of cells 31 to 35. For example, the control circuit 150 selects at least one cell to be discharged by turning on at least one of the selection switches 111 to 115. In this embodiment, the current generation circuit 170 generates a terminal current whose current value varies in accordance with the cell voltage value of the cell (cell to be discharged) selected by the control circuit 150. Then, the current generation circuit 170 causes the generated terminal current to flow from the connection terminal to which the positive electrode of the cell selected by the control circuit 150 can be connected to the internal ground 171 via the internal current path of the battery protection circuit 70.

  Next, cell balance control for discharging at least one of the plurality of cells will be described. In the following description, the operation in the case where the cell 32 is discharged when the cell protection circuit 70 performs cell balance control will be representatively described.

  In FIG. 2, the current generation circuit 170 shifts the level of the potential difference (voltage) between adjacent terminals of the V1 to V5 terminals and the VSS terminal to the reference of the internal ground 171 connected to the VSS terminal. Then, the current generation circuit 170 generates each terminal current by applying each voltage after the level shift to both ends of each resistance 91 to 95.

  Specifically, the V1 terminal is connected to the low potential side end of the resistor 52, and the V2 terminal is connected to the gate of the NMOS transistor 122. The NMOS transistor 122 has a gate connected to the V2 terminal, a drain connected to the input of the current mirror 62, and a source connected to the high potential end of the resistor 52. Therefore, the current value of the drain current of the NMOS transistor 122 is (V2−V1−Vth) / R52. Here, V2-V1 represents a potential difference between the terminal V2 and the terminal V1, Vth represents a voltage between the gate and the source of the NMOS transistor 122, and R52 represents a resistance value of the resistor 52.

  The drain current of the NMOS transistor 122 is turned back by the current mirror 62 and flows from the output portion of the current mirror 62 to the drain of the NMOS transistor 72. The current mirror 62 is formed using a pair of PMOS transistors. The NMOS transistor 72 has a drain connected to the output of the current mirror 62, a source connected to the internal ground 171 via the resistor 82, and a gate connected to the source of the NMOS transistor 102. NMOS transistor 102 has a source connected to internal ground 171 through resistor 92 and selection switch 112, a drain connected to the gate of NMOS transistor 122 and the V2 terminal, and a gate connected to the drain of NMOS transistor 72. Have. The NMOS transistors 72 and 122 have the same transistor characteristics, and the resistors 52 and 82 have the same resistance value. Also, the current mirror 62 has a current mirror characteristic such that the input / output current ratio is 1: 1.

  Therefore, according to such a circuit configuration, due to the feedback by the NMOS transistor 102, the voltage between the gate and source of the NMOS transistor 122 becomes equal to the voltage between the gate and source of the NMOS transistor 102. That is, the potential difference between the V2 terminal and the V1 terminal is level-shifted to the voltage based on VSS, and the voltage after the level shift is applied to the resistor 92. Therefore, when the selection switch 112 is turned on, the terminal current IV2 has a current value of (V2−V1) / R92 from the V2 terminal to the internal ground 171 via the transistor 102, the resistor 92 and the selection switch 112. Flow to Here, V2-V1 represents the potential difference between the terminal V2 and the terminal V1, and R92 represents the resistance value of the resistor 92.

  When the terminal current IV2 flows, the base current of the discharge transistor 22 increases and the discharge transistor 22 is turned on, so that the cell 32 is discharged with a collector current that is hfe times the base current. hfe represents the direct current amplification factor of the bipolar transistor.

Here, the current value Ib22 of the base current of the discharge transistor 22 is
Ib22 = (V2-V1) / R92-Vf / R12
= (V2CELL-Vf) / R92-Vf / R12
It can be expressed as. Vf represents the forward voltage between the base and the emitter of the discharge transistor 22, R12 represents the resistance value of the resistor 12, and V2CELL represents the cell voltage value between the positive electrode and the negative electrode of the cell 32.

  For example, when the cell voltage value of the cell 32 is 4.2 V, the current value Ib22 of the base current is 6.3 mA. When the cell voltage value of the cell 32 is 3.9 V, the current value Ib22 of the base current is 5.7 mA. When the cell voltage value of the cell 32 is 3.6 V, the current value Ib22 of the base current is 5.1 mA. Note that Vf = 0.7 V, R92 = 500 Ω, and R12 = 1 kΩ.

  Thus, as the cell voltage value of the cell 32 becomes higher, the current value (= (V2−V1) / R92) of the terminal current IV2 increases. The same applies to the other terminal currents IV1 and IV3 to IV5. That is, the current value of each terminal current at the time of cell balance control changes in accordance with the corresponding cell voltage value. Therefore, a large terminal current can flow to the terminal to which the positive electrode of the cell having a large cell voltage value is connected, and a small terminal current can be supplied to the terminal to which the positive electrode of the cell having a small cell voltage value is connected. it can. Therefore, even if the cell voltage value is dispersed among a plurality of cells, it is possible to shorten the time until convergence to the same voltage value. Therefore, the cell voltage values of the plurality of cells 31 to 35 connected in series can be balanced efficiently.

  Further, as the cell voltage value of the cell 32 becomes higher, the current value Ib22 of the base current increases, so the current value of the collector current of the discharge transistor 22 (that is, the discharge current of the cell 32) also increases. The same applies to the discharge currents of the other cells 31, 33 to 35. That is, the current value of each discharge current at the time of cell balance control changes in accordance with the corresponding cell voltage value. Therefore, the time until the cell voltage value of each cell converges to the same value can be shortened, so that the cell voltage values of the plurality of cells 31 to 35 connected in series can be balanced efficiently.

  It is apparent from the drawing that the configuration of the current generation unit connected to the V1, V3 to V5 terminals in the current generation circuit 170 is the same as the above-described configuration of the current generation unit connected to the V2 terminal. Therefore, the description of the detailed configuration and operation is omitted.

  FIG. 3 is a functional block diagram of control circuit 150. As shown in FIG. The control circuit 150 includes a timer 156, a cell selection unit 157, cell voltage detection units 151 to 155, and a selection unit 158.

  The timer 156 is a circuit block that sets a period in which the detector 130 monitors the cell voltage value of each of the cells 31 to 35 based on the clock signal from the oscillator 140.

  The cell selection unit 157 selects a monitoring target of the cell voltage value from among the plurality of cells 31 to 35. In one embodiment, the cell selection unit 157 is a circuit block that generates a switch signal for switching a cell whose cell voltage value is monitored by the detector 130 during a monitoring period set by the timer 156. Each switch signal is supplied to the cell voltage detection units 151 to 155, the selection unit 158, and the switch circuit 120 (see FIG. 2).

  The switch circuit 120 selects at least one cell connected to the detector 130 from the plurality of cells 31 to 35 based on the switch signal supplied from the cell selection unit 157. The detector 130 can monitor the cell voltage value of the cell connected to itself, but can not monitor the cell voltage value of a cell not connected to itself.

  The cell voltage detection units 151 to 155 (see FIG. 3) acquire the monitor result of the cell voltage value to be monitored selected by the cell selection unit 157. In one embodiment, the cell voltage detection units 151 to 155 fetch the monitoring result from the detector 130 in the monitoring period of the cell voltage value of the corresponding monitoring target cell, and when it is not the monitoring period, the fetched voltage value It is a circuit block to hold.

  Selection unit 158 selects at least one terminal from which the terminal current flows from the V1 to V5 terminals using the monitoring results acquired by cell voltage detection units 151 to 155 and the selection result of cell selection unit 157. . In one embodiment, the selection unit 158 outputs a selection signal to turn on or off each of the selection switches 111 to 115 (see FIG. 2) according to the input from the cell voltage detection units 151 to 155 and the cell selection unit 157. Do.

  FIG. 4 is a timing chart showing an example of the operation of the battery protection circuit 70. In this operation example, one detector 130 monitors each cell voltage value one by one in order. The cells whose cell voltage values are being monitored by the detector 130 and their monitoring periods are shown at the top of FIG. The horizontal axis t represents time. The vertical axis VSELL represents the cell voltage value between the positive electrode and the negative electrode of the cell (or the voltage value between adjacent terminals of the V1 to V5 terminals and the VSS terminal). Terminal currents IV1 to IV5 on the vertical axis represent respective current values. This timing chart shows an example of the operation when the cell voltage value exceeds the cell balance threshold Vdet in the order of the cell 35, the cell 34, the cell 33, the cell 32, and the cell 31. The threshold Vdet is an example of a first threshold.

  Next, the operation shown in FIG. 4 will be described with reference to FIGS.

  The detector 130 monitors each cell voltage value by time division. The cell voltage detection units 151 to 155 obtain cell voltage values from the detector 130, and detect whether the cell voltage value of the cell corresponding to itself is over the threshold value Vdet. The selection unit 158 identifies the cell whose cell voltage value exceeding the threshold value Vdet has been monitored, using the signals from the cell voltage detection units 151 to 155. The selection unit 158 outputs a selection signal that operates the selection switches 111 to 115 such that the terminal current flows to the connection terminal that can be connected to the positive terminal of the identified cell. The current generation circuit 170 causes a terminal current to flow to at least one of the V1 to V5 terminals according to the selection signal from the selection unit 158. Thus, cells whose cell voltage value exceeds the threshold value Vdet are discharged.

  The voltage input from the terminal connected to the positive electrode and the negative electrode of the cell being discharged drops by the forward voltage Vf of the discharge transistor. Therefore, when monitoring the cell voltage value, the control circuit 150 stops the discharge of the monitoring target to improve the detection accuracy of the cell voltage value.

  For example, when the terminal current IV4 flows to the V4 terminal, the voltage of the V4 terminal decreases by the voltage (forward voltage Vf) between the base and the emitter of the external discharge transistor 24. In this case, the cell voltage value of the cell 35 is monitored to be large by Vf, and the cell voltage value of the cell 34 is monitored to be small by Vf. Therefore, during monitoring of the cell voltage values of the cells 35 and 34, the control circuit 150 controls the current generation circuit 170 so as not to flow the terminal current IV4.

  Thus, in the current generation circuit 170, for example, while the cell voltage value is being monitored, the connection terminal that can be connected to the positive electrode of the cell whose cell voltage value is being monitored, and the cell whose cell voltage value is being monitored The terminal current is not allowed to flow to the connection terminal that can be connected to the negative electrode of.

  In addition, when the cell voltage values of all the plurality of cells 31 to 35 exceed the threshold value Vdet, as shown in FIG. 4, the cell voltage values are balanced among the cells 31 to 35. Therefore, in one embodiment, the control circuit 150 prevents the current generation circuit 170 from flowing the terminal current to all the V1 to V5 terminals when the cell voltage values of all the plurality of cells 31 to 35 exceed the threshold Vdet. Control. Thereby, the discharge of all the cells 31 to 35 is stopped.

  In one embodiment, in the cell voltage detection units 151 to 155 of the control circuit 150, a release threshold Vdet2 smaller than the threshold Vdet is set for releasing the cell balance control. The release threshold Vdet2 is an example of a second threshold.

  The selection unit 158 of the control circuit 150 prevents the terminal current from flowing to the connection terminal to which the cell voltage value lower than the release threshold Vdet2 can be connected to the positive electrode of the monitored cell. A selection signal for controlling 115 is output (see the right side of FIG. 4).

  Therefore, according to one embodiment, since the terminals for detecting the cell voltage value and the terminals for controlling the cell balance are shared by the V1 to V5 terminals, the number of external connection terminals of the battery protection circuit 70 is reduced, Cost reduction is possible. In addition, since one detector 130 monitors the cell voltage value in time division, the chip size of the battery protection circuit 70 can be reduced and power saving can be achieved. Further, since the terminal current at the time of cell balance control flows from the V1 to V5 terminals to the internal ground 171 via the internal current path of the battery protection circuit 70, all the terminal currents flow out from the VSS terminal. In other words, all the terminal currents do not flow out from the terminals other than the VSS terminal (specifically, the V1 to V5 terminals). Therefore, it becomes possible to discharge a plurality of cells simultaneously. Further, since the current value of the terminal current is determined for each cell voltage value of each cell, it is possible to prevent the terminal current from being influenced by the cell voltage values of other cells.

  As mentioned above, although a battery control circuit, a battery control device, and a battery pack were explained by the embodiment, the present invention is not limited to the above-mentioned embodiment. Various modifications and improvements, such as combinations or permutations with part or all of the other embodiments, are possible within the scope of the present invention.

  For example, although the case where the number of series connection of the cell comprised by the secondary battery 30 is five was illustrated, the case of other numbers of series can be considered similarly. Further, the arrangement positions of the transistors 1 and 2 may be replaced with each other with respect to the illustrated positions.

  Further, the charge control transistor 1 and the discharge control transistor 2 may be inserted into the plus side power supply path 9a without being limited to the form in which the charge control transistor 1 and the discharge control transistor 2 are inserted into the minus side power supply path 9b.

  The discharge transistor is not limited to the bipolar transistor, and may be another switching element such as a MOS transistor.

DESCRIPTION OF SYMBOLS 1 charge control transistor 2 discharge control transistor 11-16, 51-55, 81-85, 91-95 resistance 20 cell balance circuit 21-25 discharge transistor 30 secondary battery 31-35 cell 41-46 capacity element 70 battery protection circuit 80 battery protection device 90 load 100 battery pack 150 control circuit 170 current generation circuit 171 internal ground

Claims (10)

A battery control circuit for controlling the balance of cell voltage values of a plurality of cells connected in series, comprising:
A plurality of connection terminals that can be connected to a positive electrode of a corresponding one of the plurality of cells;
A ground terminal connected to the internal ground of the battery control circuit and capable of being connected to the negative electrode of the lowermost cell of the plurality of cells;
A control circuit that selects at least one connection terminal connected to the internal ground via the internal current path of the battery control circuit from among the plurality of connection terminals;
The terminal current whose current value changes according to the cell voltage value of the cell whose positive terminal can be connected to the connection terminal selected by the control circuit is transmitted from the connection terminal selected by the control circuit via the internal current path. A battery control circuit comprising: a current generation circuit flowing to an internal ground.   The battery control circuit according to claim 1, wherein the current generation circuit causes the terminal current to flow to a connection terminal that can be connected to a positive electrode of a cell whose cell voltage value exceeding a first threshold value is monitored.   3. The battery according to claim 2, wherein the current generation circuit prevents the terminal current from flowing to all of the plurality of connection terminals when cell voltage values of all of the plurality of cells exceed the first threshold. Control circuit. A second threshold smaller than the first threshold is set,
4. The method according to claim 2, wherein the current generation circuit prevents the terminal current from flowing to a connection terminal to which a cell voltage value lower than the second threshold value may be connected to a positive electrode of a monitored cell. Battery control circuit.   The current generation circuit may be connected to a connection terminal which may be connected to the positive terminal of the cell whose cell voltage is monitored and to the negative terminal of the cell whose cell voltage is monitored while the cell voltage is being monitored. The battery control circuit according to any one of claims 1 to 4, wherein the terminal current is not supplied to the connection terminal. The control circuit
A cell selection unit that selects a monitoring target of a cell voltage value from among the plurality of cells;
A cell voltage detection unit that acquires a monitoring result of a cell voltage value to be monitored selected by the cell selection unit;
A selection unit that selects at least one connection terminal to which the terminal current flows from the plurality of connection terminals using the monitoring result acquired by the cell voltage detection unit and the selection result of the cell selection unit; The battery control circuit according to any one of claims 1 to 5, comprising: A battery control circuit for controlling the balance of cell voltage values of a plurality of cells connected in series, comprising:
A plurality of connection terminals that can be connected to a positive electrode of a corresponding one of the plurality of cells;
A ground terminal connected to the internal ground of the battery control circuit and capable of being connected to the negative electrode of the lowermost cell of the plurality of cells;
A current generation circuit that generates a plurality of currents whose current value changes in accordance with a voltage value between adjacent ones of the plurality of connection terminals and the ground terminal;
And a control circuit for selecting at least one terminal current to be supplied to the internal ground from the terminal having the higher potential of the adjacent terminals from the plurality of currents via the internal current path of the battery control circuit. Battery control circuit. A battery control circuit for controlling the balance of cell voltage values of a plurality of cells connected in series, comprising:
A plurality of connection terminals that can be connected to a positive electrode of a corresponding one of the plurality of cells;
A ground terminal connected to the internal ground of the battery control circuit and capable of being connected to the negative electrode of the lowermost cell of the plurality of cells;
A control circuit which selects at least one cell to be discharged from the plurality of cells;
The terminal current whose current value changes in accordance with the cell voltage value of the cell selected by the control circuit is passed from the connection terminal to which the positive electrode of the cell selected by the control circuit can be connected via the internal current path of the battery control circuit And a current control circuit for supplying current to the internal ground. A cell balance circuit for balancing cell voltage values of a plurality of cells connected in series;
A battery control circuit for controlling the cell balance circuit;
The battery control circuit is
A plurality of connection terminals that can be connected to a positive electrode of a corresponding one of the plurality of cells;
A ground terminal connected to the internal ground of the battery control circuit and capable of being connected to the negative electrode of the lowermost cell of the plurality of cells;
A control circuit that selects at least one connection terminal connected to the internal ground via the internal current path of the battery control circuit from among the plurality of connection terminals;
The terminal current whose current value changes according to the cell voltage value of the cell whose positive terminal can be connected to the connection terminal selected by the control circuit is transmitted from the connection terminal selected by the control circuit via the internal current path. A battery control device comprising: a current generation circuit that flows to an internal ground. A plurality of cells connected in series;
A cell balance circuit for balancing cell voltage values of the plurality of cells;
A battery control circuit for controlling the cell balance circuit;
The battery control circuit is
A plurality of connection terminals connected to the positive electrode of the corresponding cell among the plurality of cells;
A ground terminal connected to the internal ground of the battery control circuit and connected to the negative electrode of the lowermost cell of the plurality of cells;
A control circuit that selects at least one connection terminal connected to the internal ground via the internal current path of the battery control circuit from among the plurality of connection terminals;
The terminal current whose current value changes according to the cell voltage value of the cell whose positive terminal is connected to the connection terminal selected by the control circuit is transmitted from the connection terminal selected by the control circuit via the internal current path. A battery pack comprising: a current generating circuit flowing to an internal ground.

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