JP2015156793A - Battery system and battery monitoring device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a battery system of higher reliability.

SOLUTION: A diagnostic circuit 160 provided for a battery system diagnoses whether or not all of a plurality of switches are in an open state on the basis of whether or not a relation between a threshold and voltage measured by an AD converter 122A in the state that potential of an output terminal of a multiplexer 120 is pulled up or pulled down is a relation when all the plurality of switches are in the open state. After the diagnosis, when a specific switch for selecting a battery cell to be measured, among the plurality of switches, is in a closed state, it is diagnosed whether or not the battery cell to be measured is selected by the specific switch on the basis of whether or not the relation between the threshold and voltage to be measured by the AD converter 122A in the state that the potential of the output terminal of the multiplexer 120 is pulled up or pulled down is a relation when the specific switch is in the closed state.

COPYRIGHT: (C)2015,JPO&INPIT

Description

  The present invention relates to a battery system and a battery monitoring device.

  In a battery system using a lithium battery, in particular, a battery system for a vehicle, one that diagnoses overcharge or overdischarge of a battery cell is known (see, for example, Patent Document 1). The battery system also has a function of diagnosing the operation state of a balance circuit provided to reduce the difference in charge amount between battery cells. Furthermore, a technique for detecting disconnection of a connection line between a battery cell and a circuit that detects a terminal voltage is also known (see, for example, Patent Document 2).

JP 2005-318751 A JP 2006-294339 A

  Thus, in the vehicle battery system, it is necessary to monitor the state of the battery cell by adjusting the charge amount by the balance circuit and performing the diagnosis of overcharge and overdischarge. However, it is necessary to improve the reliability of the entire battery system by increasing the reliability of the measurement system. An object of the present invention is to provide a vehicle battery system with higher reliability.

The battery system according to claim 1 is a battery module having a plurality of battery cells electrically connected in series, a voltage measuring circuit for measuring terminal voltages of the plurality of battery cells, and the voltage measuring circuit. A selection circuit that selects and outputs the terminal voltage of the battery cell to be measured from the terminal voltages of the plurality of battery cells, and the selection circuit. A pull-up circuit that pulls up the potential of the output terminal to a higher potential side, and a pull-down circuit that pulls down the potential of the output terminal of the selection circuit to a lower potential side. When the plurality of switches constituting the selection circuit are all opened, the voltage measuring circuit pulls up or pulls down the potential of the output terminal of the selection circuit. Based on whether or not the relationship between the measured voltage and the threshold value is the relationship when all of the plurality of switches constituting the selection circuit are opened, all of the plurality of switches constituting the selection circuit are opened. When the diagnosis is performed, and after the diagnosis, when the specific switch for selecting the battery cell to be measured is closed among the plurality of switches constituting the selection circuit, the selection circuit Based on whether the relationship between the voltage measured by the voltage measurement circuit in the state where the potential of the output terminal is pulled up or pulled down and the threshold is the relationship when the specific switch is closed, It is diagnosed whether or not the battery cell to be measured is selected by the specific switch.
According to a fourth aspect of the present invention, there is provided a battery monitoring device comprising: a voltage measuring circuit that measures each terminal voltage of a plurality of battery cells electrically connected in series; and a diagnostic circuit that diagnoses an abnormality in the voltage measuring circuit. The voltage measurement circuit selects a terminal voltage of the battery cell to be measured from the terminal voltages of the plurality of battery cells, and outputs a potential higher than that of the selection circuit. A pull-up circuit that pulls up to the potential side; and a pull-down circuit that pulls down the potential of the output terminal of the selection circuit to a lower potential side; and the diagnostic circuit includes a plurality of switches that constitute the selection circuit Are all open, the relationship between the voltage measured by the voltage measurement circuit in the state where the potential of the output terminal of the selection circuit is pulled up or pulled down and the threshold value is the selection circuit. Based on whether or not the plurality of constituent switches are in the open state, whether or not all of the plurality of switches constituting the selection circuit are in the open state is diagnosed. When the specific switch for selecting the battery cell to be measured is closed among the plurality of switches constituting the selection circuit, the voltage in the state where the potential of the output terminal of the selection circuit is pulled up or pulled down Whether or not the battery cell to be measured is selected by the specific switch based on whether or not the relationship between the voltage measured by the measurement circuit and the threshold is the relationship when the specific switch is in the closed state Diagnose.

  ADVANTAGE OF THE INVENTION According to this invention, the reliability of a battery system, especially a vehicle battery system can be improved more.

It is a figure which shows one Embodiment of the battery system for vehicles by this invention, and is a block diagram which shows the battery part 9, the cell controller 80, and the battery controller 20. FIG. It is a block diagram which shows the integrated circuit 3A in detail. It is explanatory drawing which showed an example of the transmission / reception method of the communication command of an integrated circuit. It is a figure explaining timing of diagnostic operation and measurement operation, and diagnostic operation items. It is a figure explaining the circuit relevant to diagnostic operation and measurement operation. It is a figure explaining the diagnostic operation | movement in 1st Embodiment. It is a figure explaining an example of the communication circuit which transmits / receives the communication command provided in the integrated circuit. It is explanatory drawing explaining an example of the setting procedure of the address register of each integrated circuit with the communication command from a battery controller. It is explanatory drawing explaining operation | movement of the circuit of FIG. 7 based on transmission of a communication command. It is explanatory drawing of embodiment which sets an address to each integrated circuit of FIG. 9 sequentially based on the communication command from a battery controller. It is the figure which showed an example of the processing flow which measures the charge condition of each battery cell, and performs discharge of the battery cell with many charge amounts. It is the figure which showed an example of the processing flow for testing whether each integrated circuit or each battery cell is abnormal. It is a circuit diagram which shows an example at the time of applying the battery system for vehicles of this Embodiment to the drive system of the rotary electric machine for vehicles. It is the figure which showed an example of the operation | movement flow in the battery system for vehicles shown in FIG. It is explanatory drawing which shows an example of the sequence which complete | finishes communication with the cell controller of a battery controller in the vehicle power supply system. It is explanatory drawing which shows the other example of the sequence which complete | finishes communication with the cell controller of a battery controller in the battery system for vehicles. It is explanatory drawing which shows an example at the time of making the number of the battery cells which each group has into a different number. 2 is a perspective view showing an external appearance of a battery module 900. FIG. 2 is an exploded perspective view of a battery module 900. FIG. 3 is a plan view showing an example of a cell controller built in a battery module 900. FIG. It is a figure which shows an example of a structure which implement | achieves control of both control of a balancing switch and measurement of the terminal voltage of each battery cell. It is a figure which shows other embodiment of the structure which implement | achieves control of both control of balancing switch and measurement of the terminal voltage of each battery cell. FIG. 22 is an operation diagram showing the relationship between measurement control and discharge control for adjusting the state of charge in the circuit shown in FIG. 21. FIG. 23 is an operation diagram illustrating a relationship between measurement control and discharge control for adjusting a charge state in the circuit illustrated in FIG. 22. It is a figure which shows an example of the circuit for performing control shown in FIG.23 and FIG.24. It is explanatory drawing which shows an example of a diagnosis when abnormality generate | occur | produces in the harness for a detection which connects the positive electrode and negative electrode for detecting the terminal voltage of battery cell BC, and a cell controller. It is explanatory drawing which shows the other example of a diagnosis when abnormality generate | occur | produces in the harness for a detection which connects the positive electrode and negative electrode for detecting the terminal voltage of battery cell BC, and a cell controller. FIG. 28 is an explanatory diagram showing a method of detecting that an abnormality has occurred in the electrical connection between the battery cell and each integrated circuit in the configuration shown in FIGS. 26 and 27. It is explanatory drawing which shows the interruption | blocking period of the signal based on a discharge control circuit, when giving priority control to a balancing switch over control for adjustment of a charge condition. It is explanatory drawing which shows the interruption | blocking period of the signal based on a discharge control circuit, when giving priority control to a balancing switch over control for adjustment of a charge condition. It is a figure explaining other embodiment of the circuit used as the object of a diagnosis, and the circuit for this diagnosis. It is a block diagram which shows other embodiment of a battery part and a cell controller. It is a figure explaining 1st Embodiment of a multiplexer diagnosis. It is a figure explaining operation | movement of the RES period of stage STGCV2. It is a figure which shows the circuit relevant to the multiplexer diagnosis of 2nd Embodiment. It is an operation | movement figure explaining the multiplexer diagnosis of 2nd Embodiment. It is a figure which shows the circuit relevant to the multiplexer diagnosis of 3rd Embodiment. It is a figure explaining the terminal voltage measurement operation | movement of battery cell BC3. It is an operation | movement figure explaining 4th Embodiment of a multiplexer diagnosis. It is a figure which shows the circuit relevant to the multiplexer diagnosis of 4th Embodiment. It is a figure explaining 5th Embodiment. It is a figure explaining the diagnosis of the HVMUX signal selection in 6th Embodiment.

A drive system provided with a battery system, which will be described below as an embodiment, or a battery system, an in-vehicle battery system, a battery module, a cell controller used in the battery module, and a circuit board and an integration included in the cell controller Circuit components such as circuits each have high reliability. In addition, the system described below and circuit components such as circuit boards and integrated circuits have been studied for use as products, and various problems have been solved in addition to improving reliability. . A typical example is described below.
[Improvement of reliability]
A vehicle drive system, which will be described later with reference to FIG. 13, mainly includes a battery module, an inverter device, and a rotating electric machine (hereinafter referred to as a motor) 230, and the inverter device 220 and the battery module 900 exchange information via a communication line. It has a structure that can be done. Particularly, the diagnosis result of the battery module 900 is sent to a control circuit (hereinafter referred to as MCU) 222 of the inverter device 220, and the inverter device 220 and the battery module 900 share important information such as an abnormal state. The battery module 900 has relays RLP and RLN that connect or cut off an electric circuit between the lithium battery and the inverter device 220, and the relays RLP and RLN are controlled by the MCU 222 of the inverter device 220. Since the MCU 222 of the inverter device 220 can control the relays RLP and RLN based on the state of the motor 230, the inverter device 220, and the battery module 900, the reliability of the entire system is improved. Also, the MCU 222 of the inverter device 220 can control the power consumption and generated power of the motor 230 by controlling the inverter in response to the control of the relays RLP and RLN, and high safety and high reliability can be obtained.
The battery module 900 includes a battery unit 9 having a lithium battery cell, a cell controller 80, and a battery controller 20 as main components. The cell controller 80 measures and diagnoses a terminal voltage of the lithium battery cell included in the battery unit 9, and a charging state. The discharge operation for adjusting the SOC is performed, and the battery controller 20 manages the battery module 900 in response to the measurement result and the diagnosis result of the cell controller 80. Thus, the reliability and safety | security of the battery module 900 improve by sharing the function.
The cell controller 80 has a plurality of integrated circuits having a function of detecting each terminal voltage of a plurality of lithium battery cells included in the battery unit 9. Unlike a single battery, a battery module using a lithium battery is very important in terms of safety to measure the terminal voltage of a lithium battery cell with high reliability. On the other hand, it is necessary to consider that the in-vehicle device is used in a high temperature or low temperature environment for a long period of time and is placed in a harsh environment as compared with the use environment of general industrial devices. In the embodiment described below, each integrated circuit includes a diagnostic circuit that diagnoses whether or not the terminal voltage of the lithium battery cell is correctly measured, and each of the integrated circuits repeatedly performs diagnosis at a predetermined cycle. Yes. The integrated circuit or the cell controller 80 using the integrated circuit has the above-described structure, and each integrated circuit or the cell controller 80 has high reliability.
As described above, there are known examples relating to the deterioration of the lithium battery cell and the diagnosis of the discharge circuit of the lithium battery cell, but the necessity of the diagnosis relating to the measurement operation of the terminal voltage of the lithium battery cell has not been considered. However, it has been found that it is desirable to diagnose the measurement operation of each integrated circuit in order to improve reliability and safety. In the embodiment described below, each integrated circuit diagnoses whether or not the terminal voltage measurement operation is performed correctly, for example, whether the selection of the terminal voltage of the lithium battery cell by the multiplexer is performed normally. It has a structure that repeatedly diagnoses with a circuit. Therefore, an extremely reliable integrated circuit can be obtained.
[Simplification of integrated circuits]
In the embodiment described below, as shown in FIG. 4, the diagnosis is repeatedly performed in a cycle synchronized with the measurement of the terminal voltage of the lithium battery cell, and the integrated circuit integrates the measurement control and the diagnosis control. In addition to improving reliability and safety, the circuit configuration of the integrated circuit can be relatively simplified.
In the embodiment described below, as shown in FIG. 4, a plurality of diagnoses of the integrated circuit can be performed in synchronization with the measurement operation, and the diagnosis of the entire integrated circuit is comprehensively performed. High reliability can be maintained for the circuit. The plurality of diagnoses include a diagnosis of a balance switch of an integrated circuit, a diagnosis of an analog / digital converter, a diagnosis of a multiplexer, a diagnosis of a digital comparison circuit, and the like. In other words, in addition to the original function of the integrated circuit, a diagnostic function will be added. However, as the function increases, the entire operation of the integrated circuit and the entire circuit configuration operate in an integrated manner. It has a relatively simplified structure.
[Reduction of abnormality diagnosis time]
In an in-vehicle battery module using a lithium battery, it is desirable to detect an abnormality in a short time and deal with the abnormality as soon as possible. However, as the power consumption increases, the number of lithium battery cells included in the battery unit increases, and the number of integrated circuits used increases. When performing diagnosis of each integrated circuit itself in addition to abnormality diagnosis of lithium battery cells, it is important to complete many diagnostic items in a short time.
In the embodiment described below, each integrated circuit is configured to repeatedly perform a measurement operation and a diagnosis operation once in a cycle determined independently, once a measurement operation and a diagnosis operation are started. Therefore, despite the large number of lithium battery cells and the number of integrated circuits, measurement operations and diagnostic operations as battery systems and battery modules can be completed in a short time. For example, the measurement and diagnosis can be performed in a short time even when the vehicle is started in a short time and is about to travel. Driving based on the diagnosis result is possible, and high safety can be maintained.
In addition, the battery module, battery system, and even the drive system shown in Fig. 13 can respond to abnormalities in integrated circuits and lithium battery cells, such as quickly reducing the amount of power transferred by the battery module and quickly opening the relay. It is said. Each integrated circuit includes a transmission / reception circuit that independently performs abnormality diagnosis and that promptly outputs a signal indicating the abnormality when the abnormality is detected. This transmission / reception circuit has an OR function as exemplified by the OR circuit 288. In other words, when an abnormal signal is received, an abnormal signal is output regardless of the diagnosis result of the integrated circuit, and even when the abnormal signal is not received, an abnormal signal is output when an abnormality is detected in the integrated circuit have. Therefore, a higher-level control circuit such as the battery controller 20 can quickly know the abnormality diagnosis result of the entire plurality of related integrated circuits by examining the result of the abnormality signal sent from the integrated circuit. In addition, since a comprehensive diagnosis result can be obtained without instructing special transmission of an abnormal signal, an increase in the processing load of the upper control circuit can be suppressed.
[Improve productivity]
In the embodiment described below, an integrated circuit is held on the substrate of the cell controller 80, the discharge state adjusting resistors R1 to R4 for adjusting the SOC of each lithium battery cell, and the noise elimination shown in FIGS. Capacitors C1 to C6 are also held on the substrate of the cell controller 80. Since the integrated circuit, the discharge state adjusting resistors R1 to R4 and the capacitors C1 to C6 are collectively held on the substrate of the cell controller 80, the productivity is improved. Moreover, reliability and safety are improved by arranging these circuit components close to each other.
Since the electric component and the lithium battery cell are connected using the connector and the communication harness 50, workability is improved.
Since the diagnostic circuit is built in each integrated circuit, productivity is improved and reliability and safety are improved.

Hereinafter, the best mode for carrying out the present invention will be described with reference to the drawings.
<Explanation of cell controller>
FIG. 1 is a diagram illustrating a battery unit 9 and a cell controller (hereinafter sometimes abbreviated as C / C) 80 of a vehicle battery system used for driving a vehicular rotating electrical machine.

  The battery unit 9 includes a plurality of battery cell groups GB1,... GBM,. Each group has a plurality of battery cells BC1 to BC4 connected in series. Therefore, the battery unit 9 has a plurality of battery cells connected in series. In this embodiment, for example, there are a large number of battery cells consisting of several tens, and in some cases several hundreds. In this embodiment, each battery cell is a lithium ion battery.

  The terminal voltage of each lithium battery cell changes depending on the state of charge of the battery cell. For example, the battery voltage is about 3.3 volts when the battery is discharged about 30%, and the terminal voltage is about 70% when charged. It will be about 3.8 volts. In an overdischarged state that has discharged beyond the normal operating state, it may be, for example, 2.5 volts or less, and in an overcharged state that has been charged beyond the normal operating range, it may be 4.2 volts or more. is there. The plurality of battery cells BC1 to BC4 connected in series can grasp the respective state of charge SOC by measuring the terminal voltage.

  In the present embodiment, one group is composed of four to six battery cells BC1 to BC4 for the purpose of facilitating measurement of the terminal voltages of the battery cells BC1 to BC12. In the embodiment shown in FIG. 1, each group includes four battery cells, that is, the group BG1, the group GBM, and the group GBN are configured by battery cells BC1 to BC4, respectively. In FIG. 1, there are further groups having battery cells between the group BG1 and the group GBM and between the group GBM and the group GBN. However, in order to avoid complicated explanation, the configuration is the same. Omitted.

  The cell controller 80 has integrated circuits 3A, ... 3M, ... 3N corresponding to the groups GB1, ... GBM, ... GBN constituting the battery unit 9. Each integrated circuit has a voltage detection terminal for detecting a terminal voltage of each battery cell, and each of the voltage detection terminals V1 to GND of each integrated circuit is connected to each battery cell constituting each group. Each is connected to a positive electrode and a negative electrode. Each integrated circuit has a transmission / reception terminal for signal transmission. The transmission / reception terminals of each integrated circuit are connected in series as described below, and are connected to the battery controller 20 via a signal transmission path. Further details will be described below.

  The cell controller 80 includes a plurality of, for example, several to several tens of integrated circuits corresponding to each group. In FIG. 1, the integrated circuit (hereinafter also abbreviated as IC) 3A,. ... 3M, ... 3N. Note that an integrated circuit having the same configuration exists between the integrated circuit 3A and the integrated circuit 3M and between the integrated circuit 3M and the integrated circuit 3N, but these are omitted to avoid complexity.

  Each of the integrated circuits 3A,..., 3M,..., 3N is a battery cell (hereinafter, may be referred to as a battery cell) BC1 to BC4 constituting each corresponding group GB1,. The voltage of is detected. Further, each of the integrated circuits 3A,..., 3M,..., 3N individually sets the SOCs of the battery cells BC1 to BC4 in order to equalize the state of charge (SOC) of all the battery cells of all the groups. Charge state adjustment resistors R1 to R4 for adjustment are connected in parallel to each battery cell via a switch element. The switch element will be described later with reference to FIG.

  Further, each of the integrated circuits 3A, 3M, 3N has a function of detecting an abnormal state of each of the battery cells BC1 to BC4 constituting each corresponding group GB1, ... GBM, ... GBN. These integrated circuits all have the same structure, and each integrated circuit has a battery cell (1) terminal voltage measurement circuit, (2) a charge state adjustment circuit, and (3) an abnormal state detection circuit. Yes. In this embodiment, the abnormal state is an overcharge or overdischarge of the battery cell, an abnormal increase in the battery cell temperature, or the like.

  Transmission and reception of signals between the integrated circuits 3A, 3M, and 3N and the upper battery controller 20 are performed via the communication harness 50. The battery controller 20 is configured to operate at a low potential of 12V or less with the chassis potential of the vehicle as ground (GND). On the other hand, the integrated circuits 3A, 3M, and 3N are held at different potentials and operate at different potentials because the potentials of the battery cells that constitute the corresponding group are different. As described above, since the terminal voltage of the battery cell changes based on the state of charge SOC, the potential of each group with respect to the lowest potential of the battery unit 9 changes based on the state of charge SOC. Each of the integrated circuits 3A, 3M, and 3N detects the terminal voltage of the battery cell of the corresponding group of the battery unit 9, or performs discharge control for adjusting the state of charge SOC of the battery cell of the corresponding group. The voltage difference applied to the integrated circuit becomes smaller when the reference potential of the integrated circuit is changed based on the potential of the corresponding group. When the voltage difference applied to the integrated circuit is smaller, there is an effect that the breakdown voltage of the integrated circuit can be further reduced, or safety and reliability are improved. In this embodiment, the integrated circuit is based on the related group potential. The reference potential is changed. By connecting the GND terminal serving as the reference potential of each integrated circuit to any of the battery cells of the related group, the reference potential of the integrated circuit can be changed based on the related group potential. In this embodiment, the terminal of the battery cell that is the lowest potential of each group is connected to the GND terminal of the integrated circuit.

  In addition, in order to generate a reference voltage and a power supply voltage for operating the internal circuit of the integrated circuit inside each integrated circuit, the V1 terminal of each integrated circuit is set to the positive terminal of the battery cell that is the highest potential of each corresponding group. And the GND terminal of each integrated circuit is connected to the negative terminal of the battery cell which is the lowest potential of each group. With such a configuration, each integrated circuit operates in response to a potential difference or voltage between the highest potential and the lowest potential of each group. The power consumption of each integrated circuit is equally shared by the battery cells of the battery group 9, and there is an effect of suppressing SOC imbalance.

  Since the power supply system of the battery controller 20 and the power supply system of the cell controller 80 are different in potential relation and the voltage value is also greatly different, the communication harness 50 connected to the battery controller 20 is connected to each integrated circuit 3A, 3M, It is necessary that the 3N transmission / reception terminals are electrically insulated from the transmission lines 52 and 54 connected in series. Therefore, an insulating circuit for electrically insulating is provided on each of the entrance side and the exit side of the transmission lines 52 and 54 formed of integrated circuits.

  An insulating circuit provided on the inlet side of the transmission lines 52 and 54 is indicated by an inlet side interface INT (E), and an insulating circuit provided on the outlet side is indicated by an outlet side interface INT (O). Each of these interfaces INT (E) and INT (O) has a circuit that once converts an electrical signal into an optical signal and then converts it back into an electrical signal, and transmits information through this circuit. As a result, the electrical insulation between the electric circuit of the battery controller 20 and the electric circuit of the cell controller 80 is maintained. The interface INT (E) on the entrance side includes photocouplers PH1 and PH2. The photocoupler PH1 is provided between the transmission terminal TX of the battery controller 20 and the reception terminal RX of the high potential side integrated circuit 3A, and the photocoupler PH2 is the transmission terminal FF-TEST of the battery controller 20 and the reception terminal of the integrated circuit 3A. It is provided between the FFI. The photocouplers PH1 and PH2 in the entrance side interface INT (E) maintain electrical insulation between the transmission terminals TX and FF-TEST of the battery controller 20 and the reception terminals RX and FFI of the integrated circuit 3A. ing.

  Similarly, the photocouplers PH3 and PH4 of the exit side interface INT (O) are provided between the reception terminal of the battery controller 20 and the low-potential side integrated circuit 3N. The reception terminal of the battery controller 20 and the integrated circuit Electrical insulation between the 3N transmission terminals is maintained. More specifically, a photocoupler PH3 is provided between the transmission terminal TX of the integrated circuit 3N and the reception terminal RX of the battery controller 20, and a photocoupler is provided between the transmission terminal FFO of the integrated circuit 3N and the reception terminal FF of the battery controller 20. A coupler PH4 is provided.

  A signal transmitted from the transmission terminal TX of the battery controller 20 is received by the reception terminal RX via the integrated circuits 3A,..., 3M,. That is, a signal transmitted from the transmission terminal TX of the battery controller 20 is received by the reception terminal RX of the integrated circuit 3A via the photocoupler PH1 in the entrance side interface INT (E), and is transmitted from the transmission terminal TX of the integrated circuit 3A. Transmitted, received at the receiving terminal RX of the integrated circuit 3M, transmitted from the transmitting terminal TX of the integrated circuit 3M, received at the receiving terminal RX of the integrated circuit 3N, transmitted from the transmitting terminal TX of the integrated circuit 3N, and exit-side interface A loop-shaped communication path that is received by the receiving terminal RX of the battery controller 20 via the INT (O) photocoupler PH3 is provided, and serial communication is performed via the loop-shaped communication path. Note that the battery controller 20 receives measurement values such as the terminal voltage and temperature of each battery cell through this serial communication. Further, the integrated circuits 3A to 3N are configured to automatically enter a wake up state when a command is received via this transmission path. Therefore, when a communication command 292 (described later) is transmitted from the battery controller 20, the integrated circuits 3A to 3N change from the sleep state to the operating state.

  Each of the integrated circuits 3A to 3N further performs abnormality diagnosis, and when there is an abnormality, a 1-bit signal is transmitted via the next transmission path. Each of the integrated circuits 3A to 3N transmits an abnormal signal from the transmission terminal FFO when it determines that it is abnormal or when it receives a signal indicating abnormality from the previous integrated circuit at the reception terminal FFI. On the other hand, when the signal indicating the abnormality that has already been received at the reception terminal FFI disappears or when the abnormality determination of itself becomes normal determination, the abnormality signal transmitted from the transmission terminal FFO disappears. This abnormal signal is a 1-bit signal in this embodiment. The battery controller 20 does not transmit an abnormal signal to the integrated circuit, but transmits a test signal that is a pseudo abnormal signal from the terminal FFTEST of the battery controller 20 in order to diagnose that the transmission path of the abnormal signal operates correctly. Next, the transmission path will be described.

  A test signal that is a pseudo-abnormal signal is transmitted from the transmission terminal FFTEST of the battery controller 20 to the reception terminal FFI of the integrated circuit 3A via the photocoupler PH2 of the entrance-side interface INT (E). In response to this signal, a signal indicating abnormality (hereinafter referred to as an abnormal signal) is transmitted from the transmission terminal FFO of the integrated circuit 3A to the reception terminal FFI of the next integrated circuit... Integrated circuit 3M. The abnormal signal is sequentially transmitted in this way, and is transmitted from the transmission terminal FFO of the integrated circuit 3N to the reception terminal FF of the battery controller 20 through the photocoupler PH4 of the exit side interface INT (O). If the transmission path is operating normally, the pseudo abnormal signal transmitted from the battery controller 20 returns to the reception terminal FF of the battery controller 20 via the transmission path. As described above, the battery controller 20 transmits and receives the pseudo-abnormal signal so that the communication path can be diagnosed, and the reliability of the system is improved. Further, as described above, even if there is no transmission request from the battery controller 20, the abnormal state is immediately transmitted to the battery controller 20 when the integrated circuit that has detected the abnormal state sends an abnormal signal to the next integrated circuit. Accordingly, countermeasures against abnormalities can be promptly promoted.

  In the above description, signal transmission is performed from the integrated circuit 3A corresponding to the high potential group of the battery unit 9 toward the integrated circuit 3N corresponding to the low potential group, but this is an example. On the contrary, a signal is transmitted from the battery controller 20 to the integrated circuit 3N corresponding to the low potential group of the battery unit 9, and then sequentially to each integrated circuit (including the integrated circuit 3M) corresponding to the high potential group. Alternatively, the integrated circuit 3A corresponding to the highest potential group may be sent to the battery controller 20 via the interface INT. By constructing a transmission line according to the potential change from the higher potential to the lower potential, or from the lower potential to the higher potential, there is no need to provide an insulating means such as a photocoupler between the integrated circuits. A transmission line can be made with a simple configuration.

  The DC power supply system shown in FIG. 1 supplies DC power to a load such as an inverter device via a positive-side relay RLP and a negative-side relay RLN. The opening / closing of the relays RLP and RLN is controlled from the battery controller 20 or from the inverter device when the integrated circuit detects an abnormality.

  Further, the battery controller 20 receives the output of the current sensor Si, detects the current supplied from the entire battery unit 9 to the inverter device, and outputs the DC voltage supplied from the battery unit 9 to the inverter device by the output of the voltmeter Vd. Detect.

<Integrated circuit>
FIG. 2 is a block diagram of an electronic circuit showing an example of the integrated circuit 3A. As described above, the integrated circuits 3A, ..., 3M, ..., 3N have the same structure. Therefore, the configuration of the integrated circuit other than the integrated circuit 3A is the same as the configuration shown in FIG. An integrated circuit 3A shown in FIG. 2 is connected to each of the battery cells BC1 to BC4 included in the group GB1 of the battery unit 9 corresponding to the integrated circuit. Although the integrated circuit 3A is described as a representative example, the integrated circuits other than the integrated circuit 3A are connected to the corresponding groups of the battery units 9 and perform the same operation. Although the integrated circuit 3A and the resistors R1 to R4 are provided in the cell controller 80 as shown in FIG.

  The input side terminal of the integrated circuit 3A is connected to the battery cells BC1 to BC4 constituting the group GB1. The positive terminal of the battery cell BC1 is connected to the input circuit 116 via the input terminal V1. The input circuit 116 includes a multiplexer as will be described later. The negative terminal of the battery cell BC1 and the positive terminal of the battery cell BC2 are connected via the input terminal V2. The negative terminal of the battery cell BC2 and the positive terminal of the battery cell BC3 are connected via the input terminal V3 of the battery cell B3. The positive terminal of the battery cell BC4, which is a negative terminal, is connected to the input circuit 116 via the input terminal V4. The negative terminal of the battery cell BC4 is connected to the GND terminal of the integrated circuit 3A.

  The power supply circuit 121 is constituted by, for example, a DC / DC converter or the like, converts power from each of the battery cells BC1 to BC4 into a predetermined constant voltage, and these voltages are supplied as drive power to each circuit in the integrated circuit 3A. Alternatively, it is supplied as a comparison reference voltage to the comparison circuit in order to determine the state.

  The voltage detection circuit 122 includes a circuit that converts each inter-terminal voltage of each of the battery cells BC1 to BC4 into a digital value, and each inter-terminal voltage converted into the digital value is sent to the IC control circuit 123. It is held in the internal storage circuit 125. These voltages are used for diagnosis or transmitted from the communication circuit 127 to the battery controller 20 shown in FIG.

  The IC control circuit 123 has an arithmetic function, and also includes a memory circuit 125, a power management circuit 124, and a timing control circuit 252 that periodically detects various voltages and performs state diagnosis. The storage circuit 125 is configured by a register circuit, for example, and stores the voltage between the terminals of the battery cells BC1 to BC4 detected by the voltage detection circuit 122 in association with the battery cells BC1 to BC4. The detection value is held so as to be readable at a predetermined address. The power management circuit 124 is configured to manage the state in the power circuit 121.

  A communication circuit 127 is connected to the IC control circuit 123, and signals can be received from the outside of the integrated circuit 3A via the communication circuit 127. For example, a communication command is received from the battery controller 20 at the RX terminal via the photocoupler PH1 of the entrance side interface INT (E). The communication command is sent from the communication circuit 127 to the IC control circuit 123, where the content of the communication command is decoded and processing corresponding to the content of the communication command is performed. For example, the communication command includes a communication command for requesting a measured value of the inter-terminal voltage of each battery cell BC1 to BC4, a communication command for requesting a discharge operation for adjusting the charging state of each battery cell BC1 to BC4, and the integrated circuit 3A. Communication command (Wake UP) for starting the operation, communication command (sleep) for stopping the operation, communication command for requesting address setting, and the like.

  In FIG. 2, the positive terminal of the battery cell BC1 is connected to the terminal B1 of the integrated circuit 3A via the resistor R1. A balancing switch 129A is provided between the terminal B1 and the terminal V2. The balancing switch 129A is connected in parallel with an operation state detection circuit 128A for detecting the operation state of the switch. The balancing switch 129A is controlled to be opened and closed by the discharge control circuit 132. Similarly, the positive terminal of the battery cell BC2 is connected to the terminal B2 via the resistor R2, and a balancing switch 129B is provided between the terminal B2 and the terminal V3. The balancing switch 129B is connected in parallel with an operation state detection circuit 128B for detecting the operation state of the switch. The balancing switch 129A is controlled to be opened and closed by the discharge control circuit 132.

  The positive terminal of the battery cell BC3 is connected to the terminal B3 via the resistor R3, and a balancing switch 129C is provided between the terminal B3 and the terminal V4. The balancing switch 129C is connected in parallel with an operation state detection circuit 128C for detecting the operation state of the switch. The balancing switch 129C is controlled to open and close by the discharge control circuit 132. The positive terminal of the battery cell BC4 is connected to the terminal B4 via the resistor R4, and a balancing switch 129D is provided between the terminal B4 and the terminal GND. An operation state detection circuit 128D for detecting the operation state of the switch is connected in parallel to the balancing switch 129D. The balancing switch 129C is controlled to be opened and closed by the discharge control circuit 132.

  The operation state detection circuits 128A to 128D repeatedly detect the voltage across the balancing switches 129A to 129D at a predetermined period, respectively, and detect whether or not the balancing switches 129A to 129D are normal. The balancing switches 129A to 129D are switches that adjust the charging state of the battery cells BC1 to BC4. If these switches are abnormal, the charging state of the battery cells cannot be controlled, and some of the battery cells are overcharged or overdischarged. There is a risk of becoming. The abnormality detection of each of the balancing switches 129A to 129D is, for example, a case where the voltage between the terminals of the corresponding balancing switch indicates the terminal voltage of the battery cell regardless of a state where a certain balancing switch is conductive. In this case, the balancing switch is not in a conduction state based on the control signal. On the other hand, when the voltage between terminals of the corresponding balancing switch is lower than the terminal voltage of the battery cell even though a certain balancing switch is open, in this case, the balancing switch is not related to the control signal. It will be conducted. As the switch operation state detection circuits 128A to 128D, a voltage detection circuit constituted by a differential amplifier or the like is used, and is compared with a predetermined voltage for performing the above determination by an abnormality determination circuit 131 described later.

  Balancing switches 129A to 129D are made of, for example, MOS FETs, and act to discharge the electric power stored in corresponding battery cells BC1 to BC4, respectively. An electric load such as an inverter is connected to the battery unit 9 in which a large number of battery cells are connected in series, and the supply of current to the electric load is performed by the entire number of battery cells connected in series. In addition, in a state where the battery unit 9 is charged, current is supplied from the electric load to the whole of a large number of battery cells connected in series. When a large number of battery cells connected in series are in different state of charge (SOC), the supply of current to the electric load is limited by the state of the battery cell in the most discharged state among the large number of battery cells. On the other hand, when a current is supplied from an electric load, the supply of current is limited by the most charged battery cell among many battery cells.

  For this reason, among the many battery cells connected in series, for example, for the battery cells in a charged state exceeding the average state, the balancing switch 129 connected to the battery cells is turned on, and the resistance connected in series A discharge current is passed through. As a result, the state of charge of the battery cells connected in series is controlled so as to approach each other. As another method, there is a method in which the battery cell in the most discharged state is used as a reference cell, and the discharge time is determined based on the difference in charge state from the reference cell. There are various other methods for adjusting the state of charge SOC. The state of charge can be obtained by calculation based on the terminal voltage of the battery cell. Since the charge state of the battery cell and the terminal voltage of the battery cell have a correlation, the charge state of each battery cell can be brought closer by controlling the balancing switch 129 so that the terminal voltage of each battery cell is made closer.

  The voltage between the source and drain of each FET constituting the balancing switch detected by the operation state detection circuits 128 </ b> A to 128 </ b> D is output to the potential conversion circuit 130. Since the potential between the source and drain of each FET is different from the reference potential of the integrated circuit 3A, it is difficult to make a comparison judgment as it is. Therefore, the potential is adjusted by the potential conversion circuit 130, and then the abnormality determination circuit 131 determines the abnormality. To do. The potential conversion circuit 130 also has a function of selecting the balancing switch 129 to be diagnosed based on the control signal from the IC control circuit 123. The voltage of the selected balancing switch 129 is sent to the abnormality determination circuit 131. The abnormality determination circuit 131 is based on the control signal from the IC control circuit 123, and is a terminal of the balancing switch 129 to be diagnosed that is a signal from the potential conversion circuit 130. The inter-voltage is compared with the determination voltage to determine whether each of the balancing switches 129A1 to 129D is abnormal.

  A command signal for turning on the balancing switch 129 corresponding to the battery cell to be discharged is sent from the IC control circuit 123 to the discharge control circuit 132, and based on this command signal, the discharge control circuit 132, as described above. A signal corresponding to the gate voltage for conducting the conduction of the balancing switches 129A to 129D composed of MOS type FETs is output. The IC control circuit 123 receives a discharge time command corresponding to the battery cell from the battery controller 20 of FIG. 1 through communication, and executes the discharge operation.

  The abnormality determination circuit 131 detects whether the balancing switches 129A to 129D are abnormal.

  The IC control circuit 123 outputs the abnormality of the balancing switches 129A to 129D from the 1-bit transmission terminal FFO of the communication circuit 127, and transmits it to the battery controller 20 via the communication circuit 127 of another integrated circuit. Further, the IC control circuit 123 transmits the abnormality of the balancing switches 129 </ b> A to 129 </ b> D and information for specifying the balancing switch that is the abnormality to the battery controller 20 via the transmission terminal TX of the communication circuit 127.

<Communication means>
FIG. 3 is an explanatory diagram showing a communication command transmission / reception method in each of the integrated circuits 3A,..., 3M,. FIG. 3A shows a signal 3A-RX received by the terminal RX of the integrated circuit 3A, a signal 3A-TX transmitted from the terminal TX of the integrated circuit 3A, and a signal 3B received by the terminal RX of the next integrated circuit 3B. -RX and the signal 3B-TX transmitted from the terminal TX of the next integrated circuit 3B, and also the signal 3C-RX received by the terminal RX of the next integrated circuit 3C and the signal transmitted from the terminal TX of the integrated circuit 3C 3C-TX is shown.

  The signal 3A-TX is divided by the resistor RA in the integrated circuit 3A and the resistor RB in the integrated circuit 3B to form a signal 3B-RX, and the signal 3B-TX is combined with the resistor RB ′ in the integrated circuit 3B. The signal 3C-RX is formed by dividing by the resistor RC in 3C. Thereafter, the voltage of the received signal is determined by dividing the voltage by the resistors in the integrated circuit in the communication paths connected in series.

  FIG. 3B shows the potential levels of the signals 3A-RX, 3A-TX, 3B-RX, 3B-TX, 3C-RX, and 3C-TX.

  As described above, the threshold voltage is set to a half voltage of the addition voltage for the four battery cells and the addition voltage for the two battery cells toward the downstream group from the highest group GB1 of the voltage level. Like to do. The reason for this is that when the signal from the TX terminal of the integrated circuit 3A is determined with the same threshold as that of the integrated circuit 3A on the basis of each voltage of the battery cell managed by the integrated circuit 3B, the Low level of the signal is set. This is to avoid the inconvenience that becomes 1/2 of the total voltage applied to the integrated circuit 3B. The signal level has been described on the premise of transmission from the high potential side to the low potential side, but transmission from the low potential side to the high potential side is also possible by performing level shift by resistance division.

<Diagnosis and measurement, (1) Outline of operation schedule>
FIG. 4 is a diagram for explaining the timing of the measurement operation. The integrated circuit 3A shown in FIG. 2 has a function of performing a diagnosis operation together with the measurement operation. The integrated circuit 3A performs measurement repeatedly at the operation timing shown in FIG. 4, and executes diagnosis in synchronization with this measurement. 1 and 2 described above are embodiments in which each of the groups GB1 to GBN constituting the battery unit 9 has four battery cells, but the integrated circuits 3A to 3N have six battery cells. It is a circuit that can cope with. Therefore, the number of battery cells constituting each group GB1 to GBN can be increased up to six. Therefore, also in the figure which shows the operation | movement timing of FIG. 4, it is comprised on the assumption that the battery cell is six pieces.

  In the integrated circuits 3A to 3N provided in association with the groups GB1 to GBN in FIG. 1, the number of battery cells constituting each group GB1 to GBN is set. Thereby, each of the integrated circuits 3A to 3N generates a stage signal corresponding to the number of battery cells in the associated group. With this configuration, it is possible to change the number of battery cells constituting the groups GB1 to GBN, increasing the degree of design freedom and enabling high-speed processing.

  FIG. 4 is a diagram for explaining the timing of the diagnostic operation and the measurement operation as described above. The timing and measurement cycle of the measurement operation or the diagnosis operation are managed by a start circuit 254 and a stage counter including a first stage counter 256 and a second stage counter 258. The stage counters 256 and 258 generate control signals (timing signals) for managing the operation of the entire integrated circuit 3A. The stage counters 256 and 258 are not actually separated, but are separated here for easy understanding. The stage counter may be a normal counter or a shift register.

  The startup circuit 254 receives (1) a communication command for requesting Wake UP sent from the transmission line at the terminal RX, or (2) when the power supply voltage of the IC of the integrated circuit is supplied and reaches a predetermined voltage. (3) Alternatively, when a signal indicating that the starter switch (key switch) of the vehicle has been turned on is received, a reset signal is output to the first and second stage counters 256 and 258, and the stage counters 256 and 258 are turned on. A clock signal is output at a predetermined frequency in an initial state. That is, the integrated circuit 3A performs the measurement operation and the diagnosis operation under the conditions (1) to (3). On the other hand, when a communication command requesting a sleep is received from the transmission line, or when the communication command is not received for a predetermined time or more, the start-up circuit 254 receives the clock at the timing when the stage counters 256 and 258 return to the reset state, that is, the initial state. Stop the output of. Since the progress of the stage is stopped by stopping the output of the clock, the execution of the measurement operation and the diagnosis operation is stopped.

  In response to the clock signal from the activation circuit 254, the first stage counter 256 receives a count value for controlling the processing timing in each period of the stage STG2 (each of [STGCal RES] period to [STGPSBG measurement] period described later). The decoder 257 generates a timing signal STG1 for controlling the processing timing within each period of the stage STG2. As the count value of the second stage counter 258 advances, the corresponding period switches from the left to the right in the operation table 260. A stage signal STG2 specifying each period is output from the decoder 259 in accordance with the count value of the second stage counter 258.

  The first stage counter 256 is a lower counter, and the second stage counter 258 is an upper counter. When the count value of the second stage counter 258 is “0000” and the count value of the first stage counter 256 is “0000” to “1111”, it is referred to as the RES period of the stage STGCal (hereinafter referred to as the [STGCal RES] period). ) Is output from the decoder 259. Various processes performed during the [STGCal RES] period are executed based on the signal of the decoder 257 output based on the count values “0000” to “1111” of the first stage counter 256.

  In FIG. 4, the first stage counter 256 is simply described as a 4-bit counter. However, for example, when the first stage counter 256 is an 8-bit counter, different processing is performed for each count. If the operation is performed, 256 types of processing are possible. The second stage counter 258 is the same as the case of the first stage counter 256, and a large number of processes can be performed by enabling a large number of counts.

  When the count value of the first stage counter 256 becomes “1111”, the [STGCal RES] period ends, and the count value of the second stage counter 258 becomes “0001” and becomes the [STGCal measurement] period. Then, during the [STGCal measurement] period in which the first stage counter 258 is the count value “0001”, based on the signal output from the decoder 257 based on the count values “0000” to “1111” of the first stage counter 256. Various processes are executed. Then, when the count value of the first stage counter 256 becomes “1111”, the [STGCal measurement] period ends, and the count value of the second stage counter 258 becomes “0010” and becomes the [STGCV1 RES] period. When the count value of the first stage counter 256 reaches “1111” during this [STGCV1 RES] period, the [STGCV1 RES] period ends, and the count value of the second stage counter 258 becomes “0011” [STGCV1 measurement] period. Is started.

  As described above, the operation period starts from the [STGCal RES] period of FIG. 4, and the operation period sequentially moves to the right according to the count of the second stage counter 258, and the basic operation ends at the end of the [STGPSGB measurement] period. Next, when the second stage counter 258 counts up, the [STGCal RES] period starts again.

  In the embodiment shown in FIG. 2, each group GB1 to GBN of the battery unit 9 is composed of four battery cells. Therefore, the stage STGCV5 and the stage STGCV6 in Table 260 are not used or skipped and the stage STGCV5. And stage STGCV6 does not exist. Further, when the content of the second stage counter 258 is forcibly set to a specific count value, processing within a period corresponding to the count value is executed.

<Diagnosis and measurement, (2) Diagnosis and measurement at each stage>
Next, the contents of measurement and diagnosis in each stage described in the row 260Y1 of the operation table 260 in FIG. 4 will be described. As described above, each stage has a RES period and a measurement period. In the RES period, a diagnosis operation is performed, and in the measurement period, a measurement target, a diagnosis operation, and a measurement target based on the measured value are diagnosed. The “circles” shown in the rows 260Y3 to 260Y9 of the table 260 indicate that the diagnostic items described in the respective rows are executed during the period in which the “circles” are given. These diagnostic items are self-diagnosis of the control device including the integrated circuit, that is, the measurement system shown in FIG. 2 or the discharge control system of the battery cell.

  Note that, in the RES period of each stage, not only diagnosis of items indicated by circles is performed, but also the analog-digital converter 122A used for measurement is initialized. In this embodiment, the charge / discharge type analog-digital converter 122A using a capacitor is used to reduce the influence of noise, and the discharge of the charge stored in the capacitor during the previous operation is also performed by this RES. Conduct in a period. In the measurement period of each stage in the row 260Y2, the measurement using the analog-digital converter 122A is executed and the measurement target is diagnosed based on the measured value.

  During the RES period of stage STGCal, the self-diagnosis shown in rows 260Y3 to 260Y9 is mainly performed, the diagnosis of the input circuit 116 functioning as a multiplexer described in row 260Y6 (HVMUX), and the switching operation of the input circuit 116 described in row 260Y7. Diagnosis of switching circuit to be performed (HVMUX signal selection), and diagnosis of selection signal of the part for performing digital comparison operation inside the integrated circuit, which is an item described in row 260Y9 (current value storage circuit 274 and reference value storage circuit in FIG. 6) 278 selection signal) and the like are diagnosed.

  In the measurement period of stage STGCal, measurement of the terminal voltage of balancing switch 129 and diagnosis of balancing switch 129 for adjusting the state of charge of the battery cell, which are items described in row 260Y3, are performed, and further described in row 260Y5. A diagnosis of the digital comparison circuit inside the integrated circuit, which is an item to be performed, is performed. In the diagnosis described in the row 260Y8, it is diagnosed whether or not a circuit that generates a threshold value for detecting when each battery cell is in an overcharge (overdischarge) state is normal. If a circuit that generates a threshold value becomes abnormal, a correct overdischarge diagnosis cannot be performed. In the measurement period of the stage STGCal, the diagnosis of the rows 260Y7 and 260Y9 is also performed. Note that the diagnostic items described in the row 260Y7 and the items described in the row 260Y9 are executed in the RES period and measurement period of all stages. These diagnosis execution cycles are merely examples, and the diagnosis may be performed at longer intervals instead of being diagnosed each time.

  In the measurement period of stage STGCV1 to stage STGCV6, the terminal voltage of the battery cell is measured in order, and it is further diagnosed whether each battery cell is overcharged or overdischarged from the measured value. The diagnosis of overcharge or overdischarge is set with a safety margin so that it does not actually become overcharged or overdischarged. As shown in FIGS. 1 and 2, when the number of battery cells in groups GB1 to GBN is four, stage STGCV5 and stage STGCV6 are skipped. In the measurement period of the stage STGVDD, the output voltage of the power supply circuit 121 shown in FIG. 2 is measured. During the measurement period of the stage STGTEM, the output voltage of the thermometer is measured. The reference voltage is measured during the measurement period of stage STGPSBG.

  With respect to the diagnostic operation, the same diagnostic operation as in the RES period of stage STGCal is performed in the RES period of stage STGCV1 to stage STGPSBG. Also, in the measurement periods of stage STGCV1 to stage STGTEM, the diagnostic items shown in row 260Y7 and row 260Y9 are executed in any period. In stage STGTEM, it is diagnosed whether or not the analog circuit, analog-digital converter, and reference voltage generation circuit inside the integrated circuit, which are diagnostic items described in row 260Y4, are comprehensively normal. In addition, the diagnostic items shown in the rows 260Y7 and 260Y9 are executed. The voltage output from the reference voltage generation circuit is a known voltage value. If the measurement result of the voltage value is not within the predetermined range, one of the above circuits can be determined to be abnormal, and control should be prohibited. Can be diagnosed as a condition.

<Diagnosis and measurement, (3) Battery cell terminal voltage measurement>
FIG. 5 is a diagram showing a measurement circuit and a diagnostic circuit. The input circuit 116 functions as a multiplexer and includes multiplexers 118 and 120 as will be described later. Signals STG1 and STG2 are input to the input circuit 116 from the decoders 257 and 259 shown in FIG. 4, and a selection operation by a multiplexer is performed based on the signals. In the multiplexer diagnosis (HVMUX), the output signal of the differential amplifier 262 of the voltage detection circuit 122 is taken into the diagnosis circuit 160 and a diagnosis as described later is performed. For example, when measuring the voltage of the battery cell BC1, the voltage of the battery cell BC1 is output from the input circuit 116 to the voltage detection circuit 122 when the terminal V1 and the terminal V2 are selected. Here, the terminal voltage measurement of a battery cell is demonstrated.

  The voltage detection circuit 122 includes a differential amplifier 262 and an analog-digital converter 122A. In addition, since battery cell BC1-BC4 (or BC1-BC6) is connected in series, the negative electrode potential of each terminal voltage differs. For this reason, the differential amplifier 262 is used to align the reference potential (GND potential in each of the integrated circuits 3A to 3N). The output of the differential amplifier 262 is converted into a digital value by the analog-digital converter 122A and output to the averaging circuit 264. The averaging circuit 264 obtains an average value of the measurement results for a predetermined number of times. The average value is held in the register CELL1 of the current value storage circuit 274 in the case of the battery cell BC1. The averaging circuit 264 calculates the average value of the number of measurements held in the averaging control circuit 263, and holds the output in the above-described current value storage circuit 274. If the averaging control circuit 263 instructs 1, the output of the analog-digital converter 122A is not averaged but is held in the register CELL1 of the current value storage circuit 274 as it is. If the averaging control circuit 263 instructs 4, the measurement result of the terminal voltage of the battery cell BC1 is averaged four times, and the average value is held in the register CELL1 of the current value storage circuit 274. In order to calculate the average of four times, it is first necessary to perform the measurement by the stage of FIG. 4 four times, but after the fourth time, four measurement values from the latest measurement results are used for the calculation. Thus, the averaging operation of the averaging circuit 264 can be performed for each measurement. As described above, by providing the averaging circuit 264 that performs averaging a predetermined number of times, the adverse effects of noise can be removed. The DC power of the battery unit 9 shown in FIG. 1 is supplied to the inverter device and converted into AC power. During the conversion from DC power to AC power by the inverter device, current conduction and interruption operations are performed at high speed, and a large noise is generated at that time. By providing the averaging circuit 264, such noise is reduced. It has the effect of reducing adverse effects.

  The digital value of the terminal voltage of the battery cell BC1 that has been digitally converted is held in the register CELL1 of the current value storage circuit 274. The measurement operation is performed in the [Measurement of STGCV1] period of FIG. Thereafter, a diagnostic operation based on the measured value is performed within the time indicated as the measurement of the stage STGCV1. The diagnostic operation includes overcharge diagnosis and overdischarge diagnosis. First, the digital value of the terminal voltage of the battery cell BC1 is held in the register CELL1 of the current value storage circuit 274. Next, the digital multiplexer 272 reads the terminal voltage of the battery cell BC1 from the register CELL1 of the current value storage circuit 274 and digitally converts it. Send to comparator 270. The digital multiplexer 276 reads the overcharge determination reference value OC from the reference value storage circuit 278 and sends it to the digital comparator 270. The digital comparator 270 compares the terminal voltage of the battery cell BC1 from the register CELL1 with the overcharge determination reference value OC, and if the terminal voltage of the battery cell BC1 is larger than the overcharge determination reference value OC, the flag A flag [MFflag] indicating abnormality is set in the memory circuit 284. In addition, a flag [OCflag] indicating overcharge is also set. In practice, control is performed so that an overcharge state does not occur, and such a state hardly occurs. However, the diagnosis is repeatedly performed to ensure reliability.

  Following overcharge diagnosis, further overdischarge diagnosis is performed. The digital multiplexer 272 reads the terminal voltage of the battery cell BC 1 from the register CELL 1 of the current value storage circuit 274 and sends it to the digital comparator 270. The digital multiplexer 276 reads the overdischarge determination reference value OD from the reference value storage circuit 278 and sends it to the digital comparator 270. The digital comparator 270 compares the terminal voltage of the battery cell BC1 from the register CELL1 with the overdischarge determination reference value OD. If the terminal voltage of the battery cell BC1 is smaller than the overdischarge determination reference value OD, A flag [MFflag] indicating abnormality is set in the flag storage circuit 284. In addition, a flag [OCflag] indicating overdischarge is also set. As in the case of the overcharge described above, control is performed so that an overdischarge state does not actually occur, and such an overdischarge state hardly occurs. However, the diagnosis is repeatedly performed to ensure reliability.

  The above description is the measurement and diagnosis related to the battery cell BC1 in the measurement period of the stage STGCV1 in FIG. Similarly, in the next stage STGCV2, the input circuit 116 in FIG. 5 selects the terminal voltage of the battery cell BC2 and outputs it to the voltage detection circuit 122. The voltage detection circuit 122 performs digital conversion, calculates an average value in the averaging circuit 264, and holds it in the register CELL 2 of the current value storage circuit 274. The digital comparator 270 compares the terminal voltage of the battery cell BC2 read from the register CELL2 by the digital multiplexer 272 with the overcharge determination reference value OC, and then compares the terminal voltage of the battery cell BC2 with the overdischarge determination reference. Compare with the value OD. The abnormal state is determined by comparison with the overcharge determination reference value OC or the overdischarge determination reference value OD. If an abnormal state is detected, a flag [MFflag] indicating an abnormality is set in the flag storage circuit 284. Then, the flag [OCflag] or the flag [ODflag] indicating the cause of the abnormality is set.

  Similarly, measurement of the terminal voltage of the battery cell BC3 and diagnosis of overcharge and overdischarge are performed during the measurement period of the stage STGCV3 in FIG. 4, and measurement of the terminal voltage of the battery cell BC4 and measurement of overcharge and overcharge are performed during the measurement period of the stage STGCV4. Diagnose the discharge.

<Diagnosis and measurement, (4) Diagnosis>
Hereinafter, among the diagnosis items performed in the RES period of each stage illustrated in FIG. 4, the multiplexer diagnosis illustrated in the row 260Y6 will be described.

(First embodiment)
A first embodiment of the multiplexer diagnostic operation will be described with reference to FIGS. FIG. 33 shows a circuit related to multiplexer diagnosis among the circuits shown in FIG. The input circuit 116 is an internal circuit of the integrated circuits 3 </ b> A to 3 </ b> N illustrated in FIG. 1 and includes multiplexers 118 and 120. Z1 to Z4 are constant voltage generating elements or circuits that generate a known constant voltage, and here, Zener elements are used. Each zener element Z1 to Z4 generates a constant voltage Vz at both ends by the current of the constant current circuit 117. Here, the Zener voltages Vz of the Zener elements Z1 to Z4 are set equal.

  The diagnostic circuit 160 is provided with a voltage comparison circuit 162, a determination circuit 164, an OR circuit 166, and voltage sources VH and VL. The STG1 and STG2 signals are input to the input circuit 116 and the diagnostic circuit 160, and operations of switches (described later) provided in the input circuit 116 and the diagnostic circuit 160 are performed in accordance with instructions of the STG1 and STG2 signals. Note that the state of the multiplexer 120 shown in FIG. 33 indicates the state in the stage STGCV1.

  The diagnosis of the multiplexer 120 is performed in all periods (RES period, measurement period) from the stage STGCal to the stage STGPSBG as shown in a row 260Y6 in FIG. Here, each period of stages STGCV1 to STGCV4 will be described on behalf of them. In the measurement period of each stage STGCV1 to STGCV4, the multiplexer 120 is diagnosed to confirm that the multiplexer 120 operates normally, and then the terminal voltage of the battery cell is measured. The same consideration applies to the measurement periods of stage STGCal, stage STGVDD to stage STGPSBG, and measurement is performed after the normal operation of multiplexer 120 is confirmed.

  FIG. 6 is a diagram for explaining the operation in the stages STGCV1 to STGCV4, and the operation proceeds from the left side to the right side of the table as time elapses. That is, such switch connection operation is instructed to the input circuit 116 and the diagnostic circuit 160 by the STG1 and STG2 signals. First, the stage STGCV1 will be described. With respect to the multiplexer 120, the switch SB1 is connected to the contact MB1 and the switch SB2 is connected to the contact MB2 in both the RES period and the measurement period of the stage STGCV1. On the other hand, for the multiplexer 118, the switch SA1 is connected to the contact MA1 during the RES period, and the switch SA1 is connected to the contact MA2 during the measurement period. The other switches SA2 to SA4 of the multiplexer 118 are opened in any period.

  This will be described with reference to FIGS. When the switch SA1 is connected to the contact MA1 during the RES period of the stage STGCV1, the Zener voltage Vz of the Zener element Z1 is input to the multiplexer 120. Then, the output voltage of the multiplexer 120 at that time is input to the voltage comparison circuit 162 via the differential amplifier 262. In addition, since battery cell BC1-BC4 (or BC1-BC6) is connected in series, the negative electrode potential of each terminal voltage differs. Therefore, as described above, the differential amplifier 262 is used to align the reference potentials (GND potentials in the integrated circuits 3A to 3N).

  In the [STGCV1 RES] period in which the multiplexer diagnosis is performed, the switch SC1 of the voltage comparison circuit 162 is connected. Then, in order to confirm whether or not the output voltage Vm of the multiplexer 120 matches the input Zener voltage Vz, that is, whether or not the multiplexer 120 is operating normally, the switch SD1 is connected to the voltage source VH for upper limit comparison. Connect with. The voltage VH generated by the voltage source VH is set higher than the Zener voltage Vz (known voltage) described above. The determination circuit 164 determines that the switch connection state of the multiplexer 120 is not normal when Vm> VH from the output of the voltage comparison circuit 162, that is, when the output voltage Vm does not match the input Zener voltage Vz. Output an abnormal signal.

  Next, the switch SD1 is connected to the voltage source VL for lower limit comparison. The voltage VL generated by the voltage source VL is set lower than the Zener voltage Vz (known voltage). The determination circuit 164 outputs an abnormal signal from the output of the voltage comparison circuit 162 when Vm <VL, that is, when the output voltage Vm does not match the input Zener voltage Vz. Here, since the output of the differential amplifier 262 is input to the voltage comparison circuit 162 to make an abnormality determination, not only when an abnormality occurs in the multiplexer 120, but also an abnormality occurs in the multiplexer 118 and the differential amplifier 262. In this case, the determination circuit 164 can detect an abnormality.

  The OR circuit 166 of the diagnostic circuit 160 outputs an abnormal signal to the abnormal flag storage circuit 168 when an abnormal signal is input from the determination circuit 164. As a result, the abnormality flag is set in the abnormality flag storage circuit 168. The abnormality flag storage circuit 168 is the same as the MFflag register of the flag storage circuit 284 shown in FIG. When the abnormality flag is set, the abnormality flag storage circuit 168 outputs an abnormality signal to the OR circuit 166 and the OR circuit 288 of the communication circuit 127. For this reason, if the abnormality flag is held in the abnormality flag storage circuit 168, an abnormality signal is output from the OR circuit 166 even if a normal signal is output from the determination circuit 164.

  Although a detailed circuit is not shown, the abnormality flag set in the abnormality flag storage circuit 168 can be reset by a command sent via the communication circuit 127.

  When the abnormality flag is held in the abnormality flag storage circuit 168, an abnormality signal is always output to the OR circuit 288. A signal from another integrated circuit is input to the OR circuit 288 via the input terminal FFI. The OR circuit 288 outputs an abnormal signal from the output terminal FFO when an abnormal signal is input from another integrated circuit via the input terminal FFI or when an abnormal signal is input from the abnormal flag storage circuit 168. That is, a signal indicating normality is output to the output terminal FFO only under the condition that a signal indicating normality is input to the input terminal FFI and the abnormality flag is not held in the abnormality flag storage circuit 168.

  When the [STGCV1 RES] period shifts to the [STGCV1 measurement] period based on the STG1 and STG2 signals, the switch SA1 of the multiplexer 118 is connected to the contact MA2 as shown in the operation diagram of FIG. The switches SC1 and SD1 are opened, and the terminal voltage of the battery cell BC1 is measured. At this time, the determination circuit 164 is in an inoperative state, and a normal / abnormal signal is not output from the determination circuit 164 to the OR circuit 166. Thus, since the terminal voltage is measured by switching the switch SA1 of the multiplexer 118 while maintaining the switch state of the multiplexer 120 diagnosed as normal by the multiplexer diagnosis, the terminal voltage measurement of the battery cell BC1 is performed. Can be performed reliably. Details of the terminal voltage measurement will be described later.

  When the [STGCV1 measurement] period ends, the process proceeds to the RES period of stage STGCV2. In stage STGCV2, as shown in FIG. 34, switch SB1 is connected to contact MB2, and switch SB2 is connected to contact MB3. As shown in FIG. 6, this switch state is maintained in both the RES period and the measurement period. On the other hand, for the multiplexer 118, the switch SA1 is connected to the contact MA2 and the switch SA2 is connected to the contact MA3 during the RES period. In the measurement period, the switch SA1 is connected to the contact MA2, and the switch SA2 is connected to the contact MA4. The other switches SA3 and SA4 of the multiplexer 118 are opened in any period.

  In the [STGCV2 RES] period in which the multiplexer diagnosis is performed, the switch SC1 of the voltage comparison circuit 162 is connected. Then, in order to confirm whether or not the output voltage Vm of the multiplexer 120 is equal to the inputted Zener voltage Vz, that is, whether or not the multiplexer 120 is operating normally, the switch SD1 is connected to the voltage source VH (upper comparison). Voltage VH). As described above, the voltage VH is set higher than the Zener voltage Vz (known voltage) described above. The determination circuit 164 outputs an abnormal signal from the output of the voltage comparison circuit 162 when Vm> VH.

  Next, the switch SD1 is connected to the voltage source VL (voltage VL) for lower limit comparison, and the voltage VL set lower than the Zener voltage Vz (known voltage) is input to the voltage comparison circuit 162. The determination circuit 164 outputs an abnormal signal from the output of the voltage comparison circuit 162 when Vm <VL. The subsequent processing after the abnormal signal is output from the voltage comparison circuit 162 is the same as that in the RES period of the above-described stage STGCV1, and description thereof is omitted here.

  When the [STGCV2 RES] period ends and the process proceeds to the [STGCV2 measurement] period, the switch SA2 of the multiplexer 118 is connected to the contact MA4 and the switch SC1 of the diagnostic circuit 160 and SD1 is opened, and the terminal voltage of the battery cell BC2 is measured. Also in the terminal voltage measurement during the [STGCV2 measurement] period, the terminal voltage is measured by switching the switch SA2 of the multiplexer 118 while maintaining the switch state of the multiplexer 120 diagnosed as normal by the multiplexer diagnosis. The terminal voltage of the battery cell BC2 can be reliably measured.

  In stage STGCV3, as shown in FIG. 6, in both the RES period and the measurement period, switch SB1 is connected to contact MB4, and switch SB2 is connected to contact MB5. On the other hand, for the multiplexer 118, the switch SA3 is connected to the contact MA5 and the switch SA4 is connected to the contact MA6 during the RES period. In the measurement period, the switch SA3 is connected to the contact MA4, and the switch SA4 is connected to the contact MA6. The other switches SA1 and SA2 of the multiplexer 118 are opened in any period. The diagnosis of the multiplexer 120 in the [STGCV3 RES] period is performed in the same manner as in the above-described [STGCV2 RES] period. When the [STGCV3 RES] period ends, the terminal voltage of the battery cell BC3 is measured in the [STGCV3 measurement] period.

  In stage STGCV4, as shown in FIG. 6, in both the RES period and the measurement period, switch SB1 is connected to contact MB5, and switch SB2 is connected to contact MB6. On the other hand, regarding the multiplexer 118, the switch SA4 is connected to the contact MA7 during the RES period, and the switch SA4 is connected to the contact MA6 during the measurement period. The other switches SA1 to SA3 of the multiplexer 118 are opened in any period. Then, with respect to the switches SC1 and SD1, the same operation as the above-described stage STGCV1 to stage STGCV3 is performed to diagnose the multiplexer 120 and measure the terminal voltage of the battery cell BC4.

  In both the stage STGCV3 and the stage STGCV4, the terminal voltage is measured by switching the switch of the multiplexer 118 while maintaining the switch state of the multiplexer 120 diagnosed as normal by the multiplexer diagnosis. Terminal voltage measurement of BC3 and BC4 can be reliably performed.

(Second Embodiment)
FIG. 35 is a diagram illustrating a second embodiment of the multiplexer diagnosis operation. In the second embodiment, the Zener voltages Vz1 to Vz4 of the Zener elements Z1 to Z4 provided in the input circuit 116 are all set to different values. The diagnostic circuit 160 is provided with voltage sources VH1 to VH4 and VL1 to VL4 corresponding to the Zener elements Z1 to Z4. Other configurations are the same as those of the circuits shown in FIGS.

  The connection states of the multiplexers 118 and 120 and the switch SC1 in the multiplexer diagnosis operation are the same as those shown in FIG. On the other hand, the connection state of the switch SD1 for selecting the voltage source for comparison is different from that in FIG. 6 as will be described below. First, in the [STGCV1 RES] period shown in FIG. 4, the diagnostic circuit 160 connects the switch SD1 to the upper limit comparison voltage source VH1 associated with the Zener element Z1 based on the input STG1 and STG2 signals. As a result, the voltage VH 1 of the voltage source VH 1 and the output Vm of the multiplexer 120 input via the differential amplifier 262 are input to the comparison circuit 162. The determination circuit 164 determines whether or not the multiplexer 120 is operating normally based on the output of the comparison circuit 162. The voltage VH1 is set to be higher than the Zener voltage Vz1 generated by the Zener element Z1, and when the determination circuit 164 satisfies Vm> VH1, that is, when the output Vm does not match the Zener voltage Vz1, the multiplexer 120 An abnormal signal is output assuming that the switch connection state is not normal.

  Next, the switch SD1 is connected to a voltage source VL1 for lower limit comparison associated with the Zener element Z1. When the voltage VL1 of the voltage source VL1 is set lower than the Zener voltage Vz1 of the Zener element Z1, and the determination circuit 164 is Vm <VL1, that is, when the output Vm does not coincide with the Zener voltage Vz1, An abnormal signal is output assuming that the switch connection state of the multiplexer 120 is not normal. The subsequent processing after the abnormal signal is output from the voltage comparison circuit 162 (processing after the OR circuit 166) is the same as in the case of the first embodiment described above, and the description thereof is omitted here.

  When the [STGCV1 RES] period ends, the process proceeds to the [STGCV1 measurement] period based on the STG1 and STG2 signals. The switch operation in the [STGCV1 measurement] period is the same as that shown in FIG. 6, the switch SA1 of the multiplexer 118 is connected to the contact MA2, and the switches SC1 and SD1 of the diagnostic circuit 160 are opened. As a result, the terminal voltage of the battery cell BC1 is input to the differential amplifier 262.

  In the [STGCV2 RES] period, the switching of the switches SA1, SA2, SB1, SB2, SC1 of the multiplexers 118, 120 is controlled as shown in FIG. The switch SD1 is connected to the upper limit comparison voltage source VH2 associated with the Zener element Z2, and the voltage VH2 of the voltage source VH2 is compared with the output Vm of the multiplexer 120 input via the differential amplifier 262. . The voltage VH2 is set higher than Vz2 generated by the Zener element Z2, and the determination circuit 164 outputs an abnormal signal when Vm> VH2, that is, when the output Vm does not coincide with the Zener voltage Vz2. Next, the switch SD1 is connected to a voltage source VL2 for lower limit comparison associated with the Zener element Z2. The voltage VL2 of the voltage source VL2 is set to be lower than the Zener voltage Vz2 of the Zener element Z2, and the determination circuit 164 has an abnormal signal when Vm <VL2, that is, when the output Vm does not match the Zener voltage Vz2. Is output. The subsequent processing after the abnormal signal is output from the voltage comparison circuit 162 (processing after the OR circuit 166) is the same as in the case of the first embodiment described above, and the description thereof is omitted here.

  When the [STGCV2 RES] period ends, the process proceeds to the [STGCV2 measurement] period based on the STG1 and STG2 signals. The switch operation during the [STGCV2 measurement] period is the same as that shown in FIG. 6, switch SA1 of multiplexer 118 is connected to contact MA2, switch SA2 is connected to contact MA4, and switches SC1 and SD1 of diagnostic circuit 160 are open. It is said. As a result, the terminal voltage of the battery cell BC2 is input to the differential amplifier 262.

  In the [STGCV3 RES] period, the switching of the switches SA1, SA2, SB1, SB2, and SC1 of the multiplexers 118 and 120 is controlled as shown in FIG. The switch SD1 is connected to the upper limit comparison voltage source VH3 associated with the Zener element Z3, and the voltage VH3 of the voltage source VH3 is compared with the output Vm of the multiplexer 120 input via the differential amplifier 262. . The voltage VH3 is set higher than Vz3 generated by the Zener element Z3, and the determination circuit 164 outputs an abnormal signal when Vm> VH3, that is, when the output Vm does not coincide with the Zener voltage Vz3. Next, the switch SD1 is connected to the lower limit comparison voltage source VL3 associated with the Zener element Z3. The voltage VL3 of the voltage source VL3 is set to be lower than the Zener voltage Vz3 of the Zener element Z3, and the determination circuit 164 has an abnormal signal when Vm <VL3, that is, when the output Vm does not match the Zener voltage Vz3. Is output. The subsequent processing after the abnormal signal is output from the voltage comparison circuit 162 (processing after the OR circuit 166) is the same as in the case of the first embodiment described above, and the description thereof is omitted here.

  When the [STGCV3 RES] period ends, the process proceeds to the [STGCV3 measurement] period based on the STG1 and STG2 signals. The switch operation in the [STGCV3 measurement] period is the same as that shown in FIG. 6, switch SA3 of multiplexer 118 is connected to contact MA5, switch SA4 is connected to contact MA6, and switches SC1 and SD1 of diagnostic circuit 160 are open. It is said. As a result, the terminal voltage of the battery cell BC3 is input to the differential amplifier 262.

  In the [STGCV4 RES] period, as shown in FIG. The switch SD1 is connected to the upper limit comparison voltage source VH4 associated with the Zener element Z4, and the voltage VH4 of the voltage source VH4 is compared with the output Vm of the multiplexer 120 input via the differential amplifier 262. . The voltage VH4 is set higher than Vz4 generated by the Zener element Z4, and the determination circuit 164 outputs an abnormal signal when Vm> VH4, that is, when the output Vm does not coincide with the Zener voltage Vz4. Next, the switch SD1 is connected to a voltage source VL4 for lower limit comparison associated with the Zener element Z4. The voltage VL4 of the voltage source VL4 is set to be lower than the zener voltage Vz4 of the zener element Z4, and the determination circuit 164 has an abnormal signal when Vm <VL4, that is, when the output Vm does not match the zener voltage Vz4. Is output. The subsequent processing after the abnormal signal is output from the voltage comparison circuit 162 (processing after the OR circuit 166) is the same as in the case of the first embodiment described above, and the description thereof is omitted here.

  When the [STGCV4 RES] period ends, the process proceeds to the [STGCV4 measurement] period based on the STG1 and STG2 signals. The switch operation in the [STGCV4 measurement] period is the same as that shown in FIG. 6, the switch SA4 of the multiplexer 118 is connected to the contact MA6, and the switches SC1 and SD1 of the diagnostic circuit 160 are opened. As a result, the terminal voltage of the battery cell BC4 is input to the differential amplifier 262.

  In the second embodiment, the constant voltages Vz1 to Vz4 generated by the Zener elements Z1 to Z4 are set to different values according to the connection state of the switches SB1 and SB2 of the multiplexer 120, thereby improving the diagnostic accuracy of the multiplexer diagnosis. Can be achieved. For example, in the [STGCV2 RES] period of the first embodiment, the switch connection state of the multiplexer 120 is not shown in FIG. 34, the switch SB1 is connected to the contact MB1, and the switch SB2 is connected to the contact MB2. Consider the case where such a situation occurs. Even in such a case, the determination circuit 164 determines that the output Vm of the multiplexer 20 matches the Zener voltage Vz, and outputs a signal indicating normality without outputting an abnormal signal. It will be.

  However, in the second embodiment, the Zener voltage differs depending on the switch connection state (that is, the battery cell selection state) of the multiplexer 120 indicated by the STG1 and STG2 signals. Therefore, as assumed above, if the switch connection state of the multiplexer 120 does not correspond to the voltage source to which the switch SD1 is connected, an abnormality signal is output from the determination circuit 164, and the multiplexer diagnosis is reliably performed. Is called.

(Third embodiment)
A third embodiment of the multiplexer diagnosis operation will be described with reference to FIGS. FIG. 37 shows a circuit related to multiplexer diagnosis among the circuits shown in FIG. The input circuit 116 includes a multiplexer 120, a constant current circuit 117, a resistor R, and switches S1 to S4. The output terminal MP1 and the output terminal MP2 of the multiplexer 120 are connected to the input terminal of the differential amplifier 262, respectively. Between the output terminal MP1 of the multiplexer 120 and the power supply line, a series circuit of the constant current circuit 117, the resistor R, and the switch S1 is connected. A series circuit of a switch S2, a resistor R, and a constant current circuit 117 is connected between the output terminal MP1 and the ground (reference potential) of the integrated circuit. Similarly, a series circuit of a constant current circuit 117, a resistor R, and a switch S3 is connected between the output terminal MP2 and the power supply line, and a switch is connected between the output terminal MP2 and the ground (reference potential) of the integrated circuit. A series circuit of S4, resistor R, and constant current circuit 117 is connected. The multiplexer 120 is provided with switches SB1 and SB2 for selecting the battery cells BC1 to BC4. The switches SB1 and SB2 in this embodiment are each composed of five switches as shown in FIG. Then, the positive side of the battery cells BC1 to BV4 is selected by opening and closing the five switches provided in the switch SB1, and the negative side of the battery cells BC1 to BV4 is selected by opening and closing the five switches provided in the switch SB2. The circuit configuration other than the input circuit 116 is the same as the configuration in FIG. 34 of the first embodiment.

  FIG. 36 is an operation diagram in the third embodiment, and the diagnosis operation of the multiplexer 120 will be described with reference to this diagram. FIG. 36 shows a portion corresponding to stage STGCV3 in the operation diagram shown in FIG. 6, and shows an opening / closing operation of switches S1 to S4 in stage STGCV3. In the first half of the [STGCV3 RES] period, diagnosis of the opening operation of the multiplexer 120 is performed, and in the second half of the [STGCV3 RES] period, diagnosis of the selection operation of the multiplexer 120 is performed. In the following description, the multiplexer diagnosis operation of the stage STGCV3 will be described as an example, but multiplexer diagnosis operations in the RES period of other stages are performed in the same manner.

  In the opening operation diagnosis in the first half of the [STGCV3 RES] period, after performing the opening operation diagnosis of one switch SB1 provided in the multiplexer 120, the opening operation diagnosis of the other switch SB2 is performed. In the open operation diagnosis of the switch SB1, the STG1 and STG2 signals open all the switches provided in the switches SB1 and SB2 of the multiplexer 120, and further open the switches S2 to S4 provided in the input circuit 116. Then, a command to close the switch S1 is sent to the input circuit 116. In addition, a command is sent to the diagnostic circuit 160 to connect the switch SC1 to the contact MD2 and connect the switch SD1 to the voltage source VH.

  When the switch S1 is in the closed state, the upper input terminal (non-inverting input terminal) of the comparison circuit 162 is connected to the high potential side power source via the constant current circuit 117 and the resistor R. On the other hand, the lower input terminal (inverting input terminal) of the comparison circuit 162 is connected to the voltage source VH of the voltage VH. The voltage VH is set to the maximum voltage of the lithium battery cell group to which the integrated circuit is connected, that is, four or six lithium battery cells, or a voltage slightly lower than that voltage. Therefore, if the switch SB1 of the multiplexer 120 is in an open state, the measurement voltage input to the upper terminal of the comparison circuit 162 should satisfy the normal determination condition “measurement voltage> VH”. The determination circuit 164 determines whether or not the condition “measurement voltage> VH” is satisfied based on the output of the comparison circuit 162. If “measurement voltage> VH” is not satisfied, the determination circuit 164 sends an abnormal signal to the OR circuit 166. Is output. The processing after the OR circuit 166 is the same as that in the first embodiment described above, and a description thereof is omitted here.

  In this embodiment, the voltage of the power line to which the constant current circuit 117 is connected and the positive terminal of the battery cell BC1 are at the same potential, and when the positive terminal of the battery cell BC1 is selected, the switch S1 or Diagnosis by S3 cannot be performed. On the other hand, when the ground potential and the negative potential of the battery cell BC4 are the same, and the negative terminal of the battery cell BC4 is selected, the diagnosis by the switches S2 and S4 cannot be performed. However, since diagnosis is possible when other terminals are selected, high reliability can be ensured.

  Subsequently, the STG1 and STG2 signals open all the switches provided in the switches SB1 and SB2 of the multiplexer 120, further open the switches S1, S3, and S4 provided in the input circuit 116, and switch S2 Is sent to the input circuit 116. In addition, a command is sent to the diagnostic circuit 160 to connect the switch SC1 to the contact MD2 and connect the switch SD1 to the voltage source VL.

  When the switch S2 is in the closed state, the potential of the upper input terminal of the comparison circuit 162 is the same as the GND of the integrated circuit. On the other hand, the lower input terminal of the comparison circuit 162 is connected to the voltage source VL of the voltage VL. The voltage VL is set to about 0.5 volts (a voltage slightly higher than the ground voltage of the integrated circuit and a voltage sufficiently lower than the voltage between the terminals of the lithium battery cell). Therefore, if the switch SB1 of the multiplexer 120 is open, the measurement voltage input to the upper terminal of the comparison circuit 162 should satisfy the normal determination condition “measurement voltage <VL”. The determination circuit 164 determines whether or not the condition “measurement voltage <VL” is satisfied based on the output of the comparison circuit 162. If “measurement voltage <VL” is not satisfied, the determination circuit 164 sends an abnormal signal to the OR circuit 166. Output. The processing after the OR circuit 166 is the same as that in the first embodiment described above, and a description thereof is omitted here. By such an opening operation diagnosis regarding the switch SB1, it is possible to diagnose whether or not the switch SB1 of the multiplexer 120 is in an open state as instructed.

  Next, the opening operation diagnosis of the switch SB2 of the multiplexer 120 is performed. In this case, the STG1 and STG2 signals open all the switches provided in the switches SB1 and SB2 of the multiplexer 120, further open the switches S1, S2 and S4 provided in the input circuit 116, and switch S3. Is sent to the input circuit 116. Further, a command is sent to the diagnostic circuit 160 to connect the switch SC1 to the contact MD1 and connect the switch SD1 to the voltage source VH.

  When the switch S3 is in the closed state, the potential of the upper input terminal of the comparison circuit 162 is connected to the high potential side power source via the constant current circuit 117 and the resistor R. On the other hand, the lower input terminal of the comparison circuit 162 is connected to the voltage source VH of the voltage VH. Therefore, if the switch SB2 of the multiplexer 120 is in an open state, the measurement voltage input to the upper terminal of the comparison circuit 162 should satisfy the normal determination condition “measurement voltage> VH”. The determination circuit 164 determines whether or not the condition “measurement voltage> VH” is satisfied based on the output of the comparison circuit 162. If “measurement voltage> VH” is not satisfied, the determination circuit 164 sends an abnormal signal to the OR circuit 166. Is output. The processing after the OR circuit 166 is the same as that in the first embodiment described above, and a description thereof is omitted here.

  Next, the STG1 and STG2 signals open all the switches provided in the switches SB1 and SB2 of the multiplexer 120, open the switches S1 to S3 provided in the input circuit 116, and close the switch S4. Is sent to the input circuit 116. In addition, a command is sent to the diagnostic circuit 160 to connect the switch SC1 to the contact point MD1 and connect the switch SD1 to the voltage source VL.

  When the switch S4 is in the closed state, the potential of the upper input terminal of the comparison circuit 162 is the same as GND of the integrated circuit. On the other hand, the lower input terminal of the comparison circuit 162 is connected to the voltage source VL of the voltage VL. Therefore, if the switch SB2 of the multiplexer 120 is open, the measurement voltage input to the upper terminal of the comparison circuit 162 should satisfy the normal determination condition “measurement voltage <VL”. The determination circuit 164 determines whether or not the condition “measurement voltage <VL” is satisfied based on the output of the comparison circuit 162. If “measurement voltage <VL” is not satisfied, the determination circuit 164 sends an abnormal signal to the OR circuit 166. Is output. The processing after the OR circuit 166 is the same as that in the first embodiment described above, and a description thereof is omitted here. By such opening operation diagnosis regarding the switch SB2, it is possible to diagnose whether or not the switch SB2 of the multiplexer 120 is in an open state as instructed.

  Next, the selection operation diagnosis of the multiplexer 120 performed in the latter half of the [STGCV3 RES] period of FIG. 36 will be described. Also in the selection operation diagnosis, after the selection operation diagnosis of one switch SB1 provided in the multiplexer 120 is performed, the selection operation diagnosis of the other switch SB2 is performed. In the selection operation diagnosis of the switch SB1, the STG1 and STG2 signals instruct the multiplexer 120 to select the battery cell BC3, the switches S2 to S4 are opened for the input circuit 116, and the switch S1 Is in the closed state. Further, the diagnostic circuit 160 is instructed to connect the switch SC1 to the contact point MD2 and connect the switch SD1 to the voltage source VH.

  In this case, the upper input terminal of the comparison circuit 162 is connected to the high potential power source via the constant current circuit 117 and the resistor R, and is connected to the positive electrode side of the battery cell BC3 via the switch SB1. On the other hand, the lower input terminal of the comparison circuit 162 is connected to the voltage source VH of the voltage VH. If the switch SB1 is in the open state, the potential of the upper input terminal of the comparison circuit 162 rises to about the potential of the high-potential side power supply. The potential of the input terminal is affected by the cell voltage and should be “measurement voltage <VH”. Therefore, the determination circuit 164 determines whether or not the condition “measurement voltage <VH” is satisfied based on the output of the comparison circuit 162. To 166. The processing after the OR circuit 166 is the same as that in the first embodiment described above, and a description thereof is omitted here.

  Subsequently, the STG1 and STG2 signals instruct the multiplexer 120 to select the battery cell BC3. The input circuit 116 opens the switches S1, S3, and S4, and closes the switch S2. To instruct. Further, the diagnostic circuit 160 is instructed to connect the switch SC1 to the contact MD2 and connect the switch SD1 to the voltage source VL.

  In this case, the upper input terminal of the comparison circuit 162 is connected to the GND of the integrated circuit via the switch S2, and is connected to the positive electrode side of the battery cell BC3 via the switch SB1. On the other hand, the lower input terminal of the comparison circuit 162 is connected to the voltage source VL of the voltage VL. If the switch SB1 is in the open state, the potential of the upper input terminal of the comparison circuit 162 becomes the GND potential of the integrated circuit. If the switch SB1 is correctly connected to the positive electrode side of the battery cell BC3, the input terminal Is affected by the cell voltage and should be “measurement voltage> VL”. Therefore, the determination circuit 164 determines whether or not the condition “measurement voltage> VL” is satisfied based on the output of the comparison circuit 162. If “measurement voltage> VL” is not satisfied, the determination circuit 164 outputs an abnormal signal to the OR circuit. To 166. The processing after the OR circuit 166 is the same as that in the first embodiment described above, and a description thereof is omitted here.

  In the selection operation diagnosis of the switch SB2, the STG1 and STG2 signals instruct the multiplexer 120 to select the battery cell BC3, and the input circuit 116 opens the switches S1, S2, and S4. An instruction is given to close switch S3. Further, the diagnostic circuit 160 is instructed to connect the switch SC1 to the contact point MD1 and connect the switch SD1 to the voltage source VH.

  In this case, the upper input terminal of the comparison circuit 162 is connected to the high potential side power source via the constant current circuit 117 and the resistor R, and is connected to the negative electrode side of the battery cell BC3 via the switch SB2. On the other hand, the lower input terminal of the comparison circuit 162 is connected to the voltage source VH of the voltage VH. If the switch SB1 is in an open state, the potential of the upper input terminal of the comparison circuit 162 rises to about the potential of the high potential side power supply, but if the switch SB2 is correctly connected to the negative electrode side of the battery cell BC3. The potential of the input terminal is affected by the cell voltage and should be “measurement voltage <VH”. Therefore, the determination circuit 164 determines whether or not the condition “measurement voltage <VH” is satisfied based on the output of the comparison circuit 162. To 166. The processing after the OR circuit 166 is the same as that in the first embodiment described above, and a description thereof is omitted here.

  Subsequently, the STG1 and STG2 signals instruct the multiplexer 120 to select the battery cell BC3, and the input circuit 116 opens the switches S1 to S3 and closes the switch S4. To instruct. In addition, the diagnostic circuit 160 is instructed to connect the switch SC1 to the contact MD1 and connect the switch SD1 to the voltage source VL.

  In this case, the upper input terminal of the comparison circuit 162 is connected to the GND of the integrated circuit via the switch S4, and is connected to the negative electrode side of the battery cell BC3 via the switch SB2. On the other hand, the lower input terminal of the comparison circuit 162 is connected to the voltage source VL of the voltage VL. If the switch SB2 is in the open state, the potential of the upper input terminal of the comparison circuit 162 becomes the GND potential of the integrated circuit. If the switch SB2 is correctly connected to the negative electrode side of the battery cell BC3, the input terminal Is affected by the cell voltage and should be “measurement voltage> VL”. Therefore, the determination circuit 164 determines whether or not the condition “measurement voltage> VL” is satisfied based on the output of the comparison circuit 162. If “measurement voltage> VL” is not satisfied, the determination circuit 164 outputs an abnormal signal to the OR circuit. To 166. The processing after the OR circuit 166 is the same as that in the first embodiment described above, and a description thereof is omitted here.

  As described above, the selection operation diagnosis of the multiplexer 120 is sequentially performed as shown in the selection operation diagnosis period of FIG. . When the [STGCV3 RES] period illustrated in FIG. 36 ends, terminal voltage measurement of the battery cell BC3 is performed during the [STGCV3 measurement] period.

  FIG. 38 is a diagram for explaining the terminal voltage measurement operation of the battery cell BC3. In this terminal voltage measurement operation, the STG1 and STG2 signals instruct the multiplexer 120 to select the battery cell BC3, and instruct the input circuit 116 to open the switches S1 to S4. To do. In addition, the diagnostic circuit 160 is instructed to open the switches SC1 and SD1. Since the battery cell BC3 selection state of the multiplexer 120 is determined to be normal by the diagnosis operation during the [STGCV3 RES] period, the terminal voltage of the battery cell BC3 is output from the multiplexer 120.

(Fourth embodiment)
In the second embodiment described above, the diagnosis of the multiplexer 120 is performed by an analog circuit. However, in the fourth embodiment shown in FIGS. 39 and 40, the diagnosis of the multiplexer 120 is performed using a digital circuit. FIG. 39 is an operation diagram in the fourth embodiment, and shows the operation of the stage STGCV1 to STGCV4 where the terminal voltage of the battery cell is measured. In the following, the multiplexer diagnosis of stage STGCV1 will be described as a representative, but the multiplexer diagnosis of stages STGCV2 to STGCV4 is performed in the same manner. Note that the switch connection states of the multiplexers 118 and 120 in each stage are the same as in the second embodiment.

  FIG. 40 is a diagram showing a circuit related to the multiplexer diagnosis, and shows the multiplexer diagnosis operation during the RES period of the stage STGCV1. Switch SB1 of multiplexer 120 is connected to contact MB1, and switch SB2 is connected to contact MB2. When the switch SA1 of the multiplexer 118 is connected to the contact MA1, the Zener voltage Vz1 generated by the Zener element Z1 is input to the multiplexer 120. If the operation of the multiplexer 120 is normal, the multiplexer 120 should output the Zener voltage Vz1 as the output voltage Vm. The output voltage Vm of the multiplexer 120 is input to the analog-digital converter 122A via the differential amplifier 262, where it is converted into a digital value.

  During the diagnostic operation, the digital value converted by the analog-digital converter 122A is held in a diagnostic voltage register provided in the current value storage circuit 274A. The current value storage circuit 274A is obtained by adding a diagnostic voltage register to the current value storage circuit 274 of the second embodiment. The reference value storage circuit 278A includes registers BC1VH to BC4VH4 and BC1VL to BC4VL that hold digital values corresponding to the analog voltages VH1 to VH4 and VL1 to VL4. Different from 278. Note that the values of the registers BC1VH to BC4VH4 and BC1VL to BC4VL of the reference value storage circuit 278A can be rewritten via the communication terminal RX and the internal data bus 294.

  First, it is confirmed whether or not the output voltage Vm of the multiplexer 120 is the same as the voltage Vz1 of the Zener element Z1, which is a known voltage. For that purpose, the digital value converted by the analog-to-digital converter 122A is compared with the value BC1VH held in the register BC1VH by the digital comparison circuit 162, and then the digital value is compared with the value BC1VL held in the register BC1VL. Compare with The value BC1VH is set to a value higher than the voltage Vz1, and the value BC1VL is set to a value lower than the voltage Vz1. Then, the determination circuit 164 determines whether the operation of the multiplexer 120 is normal based on the output value of the digital comparison circuit 162.

  Also in the present embodiment, as in the second embodiment, when an abnormality occurs in the multiplexer 118 including the multiplexer 120, the differential amplifier 262, and the analog-digital converter 122A, the determination circuit 164 detects the abnormality. be able to. Upon detection of an abnormality occurrence, an abnormality flag is set in the abnormality flag storage circuit 168. Since the operation related to the processing of the abnormal signal output from the abnormality flag storage circuit 168 is the same as that of the second embodiment, the description thereof is omitted. If an abnormality is determined by the determination circuit 164, the held value held in the diagnostic voltage register of the current value storage circuit 274A is stored in the register ANBC1 of the abnormal data storage circuit 275A. The abnormal data information recorded in the abnormal data storage circuit 275A is output to the outside by a transmission command via the data bus 294, the transmission / reception register 302/322, and the output terminal TX, so that the cause of the abnormality can be clarified.

  After confirming the diagnostic operation in the [STGCV1 RES] period, the connection of the switch SA1 is switched to the contact MA2 in the [STGCV1 measurement] period, and the terminal voltage of the battery cell BC1 is input to the multiplexer 120 and converted into a digital value by the analog-digital converter 122A. And stored in the register CELL1 of the current value storage circuit 274A. The same operation as described above is performed in order of stage STGCV2, stage STGCV3, and stage STGCV4 as shown in FIG.

  Note that, when digital conversion is performed and diagnosis is performed based on the digital comparison circuit as in the present embodiment, it is easily affected by noise. In order to remove the influence of such noise, analog-digital conversion may be performed a plurality of times, and the average value thereof may be used. An averaging circuit 264 shown in FIG. 40 is a circuit that calculates an average of values obtained by operating the analog-digital converter 122A a plurality of times. In particular, when the conversion operation of analog-digital conversion is high-speed, it is preferable to automatically calculate an average value operated a plurality of times and use the calculation result as an analog-digital conversion output.

(Fifth embodiment)
In the fifth embodiment shown in FIG. 41, the diagnosis operation (FIG. 36) in the third embodiment is performed digitally. Note that the connection state of the switches SB1 and SB2 and the switches S1 to S4 during the diagnostic operation is the same as that in the third embodiment. Similar to the fourth embodiment described above, the digital value converted by the analog-digital converter 122A is held in a diagnostic voltage register provided in the current value storage circuit 274A. The reference value storage circuit 278A is provided with registers VH and VL that hold digital values corresponding to the voltages VH and VL in the third embodiment. Note that, during the period for diagnosing the output terminal MP1 of the multiplexer 120, the switch S5 is connected to the output terminal MP1, and the switch S6 is connected to the ground potential. On the other hand, in the period for diagnosing the output terminal MP2 of the multiplexer 120, the switch 5 is connected to Vcc, and the switch S6 is connected to the output terminal MP2.

  First, it is confirmed whether or not the output voltage Vm of the multiplexer 120 is the same as the voltage Vz1 of the Zener element Z1, which is a known voltage. For this purpose, the digital value converted by the analog-digital converter 122A is compared with the value VH held in the register VH by the digital comparison circuit 162, and then the digital value is stored in the value VL held in the register VL. Compare with Then, the determination circuit 164 determines whether the operation of the multiplexer 120 is normal based on the output value of the digital comparison circuit 162. Also here, when an abnormality occurs in the multiplexer 118 including the multiplexer 120, the differential amplifier 262, and the analog-digital converter 122A, the determination circuit 164 can detect the abnormality. Upon detection of an abnormality occurrence, an abnormality flag is set in the abnormality flag storage circuit 168.

  If the determination circuit 164 determines that an abnormality has occurred, the held value held in the diagnostic voltage register of the current value storage circuit 274A is stored in the abnormal data storage circuit 275A. In the diagnosis operation of the battery cell BC1, when an abnormality occurs in the opening operation diagnosis of the multiplexer 120, the held value is held in the register BC1OP of the abnormality data storage circuit 275A. When an abnormality occurs in the selection operation diagnosis of the multiplexer 120, the held value is held in the register BC1ST of the data storage circuit 275A at the time of abnormality. The same operation is performed for the battery cells BC2 to BC4, and the register of the abnormal data storage circuit 275A in which the held value is held is held in the register BC2OP or BC2ST in the case of the battery cell BC2, and the battery cell BC3 In the case, it is held in the register BC3OP or BC3ST, and in the case of the battery cell BC4, it is held in the register BC4OP or BC4ST.

(Sixth embodiment)
In the first to fifth embodiments described above, the multiplexer diagnosis has been described. In the sixth embodiment, the diagnosis of the HVMUX signal selection shown in the row 260Y7 of FIG. 4 will be described with reference to FIG. In each of the integrated circuits 3A to 3N provided in the cell controller 80, the multiplexer 120 and other circuits operate based on the outputs of the stage counters 256 and 258 shown in FIG. That is, in each of the integrated circuits 3A to 3N, the entire operation of each integrated circuit is controlled based on the outputs of the built-in stage counters 256 and 258. The multiplexer 120 operates as one of circuits for realizing the operation of the entire integrated circuit.

  The multiplexer 120 includes a large number of switching circuits, and the switching circuit of the multiplexer 120 performs an ON / OFF (open / close) operation based on a signal from a selection circuit 2592 configured from a decoder circuit. Then, the selection operation of the multiplexer 120 is performed based on the ON / OFF operation of the switching circuit. Therefore, even if the multiplexer 120 itself operates normally, if the selection circuit 2592 transmits an incorrect open / close signal to the multiplexer 120, the multiplexer 120 performs an incorrect selection operation.

  For example, during the [STGCV3 measurement] period in which the terminal voltage of the battery cell BC3 is measured, the multiplexer 120 may select the terminal voltage of the battery cell BC2 due to the malfunction of the selection circuit 2592. In such a case, since the terminal voltage in the overcharge diagnosis of the battery cell BC3 is not the terminal voltage of the battery cell BC3, there is a possibility that the overcharge diagnosis for the battery cell BC is not performed at all. In the present embodiment, as shown in FIG. 42, a second selection circuit 2594 is provided and the following HVMUX signal selection diagnosis is performed to check whether a correct open / close signal is transmitted to the multiplexer 120. So that the situation described above can be avoided.

  The second selection circuit 2594 described above has the same circuit configuration as the selection circuit 2592, and signals from the stage counters 256 and 258 are input to both the selection circuit 2592 and the selection circuit 2594. Therefore, when the two selection circuits 2592 and 2594 are operating normally, the same open / close signal is output from the selection circuits 2592 and 2594. The open / close signal of the selection circuit 2592 is input to the multiplexer 120 and the diagnostic circuit 2596, and the open / close signal of the selection circuit 2594 is input to the diagnostic circuit 2596. The diagnosis circuit 2596 compares the two open / close signals input from the selection circuits 2592 and 2594 and diagnoses that the selection circuit 2592 is normal only when they match. On the other hand, if they do not match, at least one of the selection circuits 2592 and 2594 may be in an abnormal state, and the diagnostic circuit 2596 outputs an abnormal signal to the OR circuit 166.

  In the embodiment of FIG. 42, the selection circuit 2592 and the selection circuit 2594 are the same circuit, and when the outputs of both circuits match, the diagnosis is normal. However, when diagnosing whether the output signal is correct with respect to the input signal of the selection circuit 2592, the circuit configuration of the selection circuit 2592 and the circuit configuration of the selection circuit 2594 are not necessarily matched. For example, the selection circuit 2594 is configured so that the output of the selection circuit 2592 and the output of the selection circuit 2594 have a certain relationship when operating correctly, and the diagnosis circuit 2596 diagnoses whether a certain relationship has occurred. You may make it do.

<Diagnosis and measurement, (5) Retention of initial data>
In the DC power supply system shown in FIG. 1, the vehicle is stopped and no current is supplied from the battery module 9 to the inverter device before the driver starts driving. When the terminal voltage of each battery cell measured with no charge / discharge current flowing through each battery cell is used, the state of charge (SOC) of each battery cell can be accurately obtained. Based on a communication command 292 such as Wake Up from the controller 20, each integrated circuit starts its own measurement operation. When the measurement operation described in FIG. 5 starts measurement and battery cell diagnosis operation in each integrated circuit and the number of times held in the averaging control circuit 263 is measured, the averaging circuit 264 averages the measurement values. Is calculated. The calculation result is first held in the current value storage circuit 274. Each integrated circuit independently performs measurement measurement and calculation of the average value of the measurement results for all the battery cells of the group to which the integrated circuit is related, and the calculation result is stored in the current value storage circuit of each integrated circuit. 274 registers CELL1 to CELL6.

  In order to accurately grasp the state of charge (SOC) of each battery cell, it is desirable to measure the terminal voltage of each battery cell in a state where the charge / discharge current of each battery cell is not flowing. As described above, each integrated circuit starts its own measurement operation, so that each integrated circuit measures the terminal voltages of all the related battery cells before supplying current from the battery unit 9 to the inverter device, and stores the current value. The data is held in the registers CELL1 to CELL6 of the circuit 274. Since the measurement value held in the current value storage circuit 274 is rewritten by a new measurement result thereafter, the measurement result before starting the current supply is changed from the register CELL1 to the register CELL6 of the current value storage circuit 274 to the initial value storage circuit 275. The registers BCELL1 to BCELL6 are transferred to the initial value storage circuit 275. Thus, since the measured value before starting the current supply from the battery unit 9 to the inverter device is held in the initial value storage circuit 275, the processing such as the calculation of the state of charge (SOC) is postponed and the priority is high. Processing for diagnosis can be executed with priority. After high-priority processing is executed and current supply from the battery unit 9 to the inverter device is started, the state of charge (SOC) of each battery cell is calculated based on the measurement value held in the initial value storage circuit 275 Thus, it is possible to perform control for adjusting the state of charge (SOC) based on accurate state detection. The driver of the vehicle may have a desire to start driving as soon as possible, and it is desirable to enable the current supply to the inverter device as described above.

  In the embodiment shown in FIG. 5, the digital comparison circuit 270 performs overcharge or overdischarge at the timing when the measured value before the current supply to the inverter device, which is an electric load, is held in the current value storage circuit 274 as described above. Diagnosis of leakage current and the like can be performed. For this reason, an abnormal state can be grasped before supplying DC power to the inverter device. If an abnormal state occurs, an abnormality can be detected by the diagnosis before supplying current, and countermeasures such as not supplying DC power to the inverter device are possible. Further, since the measured value before the current supply can be held in the dedicated initial value storage circuit 275 by moving the stored value of the current value storage circuit 274 to the initial value storage circuit 275, the safety can be improved and the charged state can be accurately measured. There is an excellent effect in grasping (SOC).

<Communication command>
FIG. 7 is a circuit diagram illustrating the circuit of the communication circuit 127 that transmits and receives communication commands provided in the integrated circuit 3A shown in FIG. 2 and the operation thereof. The integrated circuit 3A represents each integrated circuit. The operation of the other integrated circuits is the same as described above. The communication command sent from the battery controller 20 to the reception terminal RX included in the communication circuit 127 has a total of five parts with 8 bits as one unit, and has 5 bytes as one basic configuration. However, as will be described below, it may be longer than 5 bytes, and is not particularly limited to 5 bytes. The communication command is input from the terminal RX to the reception register 322 and held. The reception register 322 is a shift register, and a signal serially input from the terminal RX is shifted in the order in which the signal is input to the reception register 322. Held, and subsequently held sequentially.

  As described above, the communication command 292 held in the reception register 322 has a break field 324 consisting of a signal indicating that a signal has arrived at the first 8 bits, and a signal serving to synchronize the second 8 bits. A synchronous field 326, and the third 8 bits are each integrated circuit 3A,..., 3M,..., 3N, and a target address indicating the circuit to be commanded, It is an identifier 328 indicating the contents of the command. The fourth 8 bits hold data necessary for executing the command as data 330 indicating communication contents (control contents). This part is not necessarily 1 byte. The fifth 8 bits is a checksum 332 for checking the presence / absence of an error in transmission / reception operation, and can detect the presence / absence when the transmission cannot be performed accurately due to noise. In this way, the communication command from the battery controller 20 is composed of five parts: a break field 324, a synchronous field 326, an identifier (328), data 330, and a checksum 312. When configured, the communication command is 5 bytes and is based on a 5-byte configuration, but the data 330 is not limited to 1 byte and may further increase as necessary.

  The synchronous field 326 is used to synchronize the transmission clock on the transmission side and the reception clock on the reception side, and the synchronization circuit 342 detects the timing at which each pulse of the synchronous field 326 is transmitted. Are synchronized with the timing of each pulse in the synchronous field 326, and the reception register 322 receives the subsequent signal at the adjusted timing. By doing this, it is possible to accurately select the comparison timing between the transmitted signal and the threshold value for judging the truth value of the signal, and there is an effect that errors in transmission and reception operations can be reduced.

  As shown in FIG. 1, the communication command 292 is sent from the battery controller 20 to the terminal RX of the integrated circuit 3A, sent from the terminal TX of the integrated circuit 3A to the terminal RX of the next integrated circuit, and so on. Sent to the terminal RX of the circuit 3M, sent from the terminal TX of the integrated circuit 3M to the terminal RX of the next integrated circuit, and further sent to the terminal RX of the next integrated circuit 3N, from the terminal TX of the integrated circuit 3N It is sent to the terminal RX of the battery controller 20. In this way, the communication command 292 communicates using the transmission line 52 in which the transmission / reception terminals of each integrated circuit are connected in series in a loop.

  The integrated circuit 3A will be described as a representative of each integrated circuit, but the other integrated circuits have the same configuration and operation as described above. The communication command 292 is transmitted to the terminal RX of the integrated circuit 3A, and each integrated circuit transmits the received communication command 292 from the terminal TX to the next integrated circuit. In the above operation, the command processing circuit 344 in FIG. 7 determines whether or not the received communication command 292 is an instruction target, and performs processing based on the communication command when the own integrated circuit is the target. The above processing is sequentially performed based on transmission / reception of the communication command 292 in each integrated circuit.

  Therefore, even when the communication command 292 held in the reception register 322 is not related to the integrated circuit 3A, it is necessary to perform transmission to the next integrated circuit based on the received communication command 292. The command processing circuit 344 captures the contents of the identifier unit 328 of the received communication command 292, and determines whether the integrated circuit 3A itself is a command target of the communication command 292. When the integrated circuit 3A itself is not the target of the communication command 292, the contents of the identifier unit 328 and the data 330 are transferred to the identifier unit 308 and the data 310 of the transmission register 302 as they are, and a transmission / reception malfunction check is performed. The checksum 312 is input to complete the transmission signal in the transmission register 302 and transmitted from the terminal TX. Similarly to the reception register 322, the transmission register 302 is made of a shift register.

  If the target of the received communication command 292 is itself, a command based on the communication command 292 is executed. The execution will be described below.

  The target of the received communication command 292 may relate to the entire integrated circuit including itself. For example, the RES command, the WakeUP command, and the Sleep command are such commands. When the RES command is received, the command processing circuit 344 decodes the command content and outputs a RES signal. When the RES signal is generated, the data held in the current value storage circuit 274, the initial value storage circuit 275, and the flag storage circuit 284 in FIG. 5 all become “zero” which is an initial value. The content of the reference value storage circuit 278 in FIG. 5 does not become “zero”, but may be “zero”. If the content of the reference value storage circuit 278 is changed to “zero”, the measurement and diagnosis shown in FIG. 4 are independently performed in each integrated circuit after the generation of the RES signal. It is necessary to quickly set the value of 278. In order to avoid this complexity, the circuit is configured such that the contents of the reference value storage circuit 278 are not changed by the RES signal. Since the value of the reference value storage circuit 278 is not data of an attribute that is frequently changed, the previous value may be used. If there is a need to change, it can be changed individually with another communication command 292. With the RES signal, the holding value of the averaging control circuit 263 is a predetermined value, for example, 16. In other words, if the communication command 292 does not change, the average of 16 measured values is set to be calculated.

  When the WakeUP command is output from the command processing circuit 344, the activation circuit 254 in FIG. 4 starts to operate, and measurement and diagnostic operations are started. This increases the power consumption of the integrated circuit itself. On the other hand, when the Sleep signal is output from the command processing circuit 344, the operation of the activation circuit 254 in FIG. 4 is stopped, and the measurement and diagnosis operations are stopped. This significantly reduces the power consumption of the integrated circuit.

  Next, writing and changing data by the communication command 292 will be described with reference to FIG. An identifier 328 (FIG. 9) of the communication command 292 indicates an integrated circuit to be selected. When the data 300 is a data write command to the address register 348 or the reference value storage circuit 278, or a data write command to the averaging control circuit 263 or the selection circuit 286, the command processing circuit 344 selects a write target based on the command content. Designate and write data 330 to the register to be written.

  The address register 348 is a register for holding the address of the integrated circuit itself, and its address is determined by the contents. The content of the address register 348 becomes zero by the RES signal, and the address of the integrated circuit itself becomes the “zero” address. When the contents of the address register 348 are newly changed by an instruction, the address of the integrated circuit itself is changed to the changed contents.

  In addition to changing the contents stored in the address register 348 by the communication command 292, the contents held in the reference value storage circuit 278, the flag storage circuit 284, the averaging control circuit 263, and the selection circuit 286 shown in FIG. . When the change target is specified for these, the contents of the data 330 as the change value are sent to the circuit to be changed via the data bus 294, and the held contents are changed. The circuit of FIG. 5 performs an operation based on the changed contents.

  The communication command 292 includes a data transmission command stored in the integrated circuit. The data to be transmitted is designated by the command of the identifier 328. For example, when the internal registers of the current value storage circuit 274 and the reference value storage circuit 278 are designated, the contents held in the designated registers are held in the data 310 circuit of the transmission register 302 via the data bus 294 and requested. Sent as data contents. In this manner, the battery controller 20 of FIG. 1 can capture a flag indicating the measured value or state of the integrated circuit required by the communication command 292.

<Address setting method for integrated circuit>
Each of the integrated circuits 3A,..., 3M,..., 3N address registers 348 is composed of a highly reliable volatile memory, and the contents of the volatile memory are erased or the reliability of the retained contents cannot be maintained. In such a case, the integrated circuit is configured so that a new address can be set. For example, when the cell controller 80 starts execution, a command for initializing the address register 348 of each integrated circuit is transmitted from the battery controller 20, for example. This command initializes the address register 348 of each integrated circuit, for example, sets the address to “zero”, and then sets a new address for each integrated circuit. A new address setting in each of the integrated circuits 3A,..., 3M,... 3N is performed by transmitting an address setting command from the battery controller 20 to each of the integrated circuits 3A,. Is called.

  In this way, the circuit configuration is such that the addresses of the integrated circuits 3A,..., 3M,. There is an effect that wiring can be made unnecessary. In addition, since the address setting can be performed by processing a communication command, the degree of freedom of control increases.

  8 is an explanatory diagram for explaining an example of the setting procedure of the address registers 348 of the integrated circuits 3A,..., 3M,... 3N by the communication command 292 from the battery controller 20, and FIG. FIG. 9 is an explanatory diagram illustrating an operation of the circuit of FIG. 7 based on transmission of 292. The integrated circuits 3A,..., 3M,... 3N are shown as integrated circuits IC1, IC2, IC3,. IC1, IC2, IC3,..., ICn-1, ICn are set by the following method so that the individual addresses are 1, 2, 3,. The reason why the IC code and its address number are matched is to facilitate understanding in the following description and does not need to be matched.

  FIG. 8 shows the message flow in the communication command 292 of the battery controller 20 and each integrated circuit IC, the data held in the address register 348 inside each integrated circuit IC, and the contents of the data 310 in the transmission register 302. . First, for example, a communication command 292 for initializing the address registers 348 of all the integrated circuits from the cell controller 80 is transmitted, and the address registers 348 of each integrated circuit are set to “zero” as an initial value. In FIG. 8, this procedure is omitted. By such an operation, an initial value such as “zero” is held in the address register 348 of each integrated circuit IC1, IC2, IC3,..., ICn−1. In FIG. 9, when the integrated circuit IC1 receives the communication command 292 that initializes the address registers 348 of all the integrated circuits, the communication command 292 is held in the reception register 322 of the integrated circuit IC1, and the contents of the identifier 328 are changed to the command. The command decoding circuit 345 of the processing circuit 344 fetches and initializes the address register 348 based on a message for setting the address register 348 to an initial state. The contents of the identifier 328 are set as they are in the identifier 308 of the transmission register 302 and sent to the next integrated circuit IC2. The integrated circuit IC that has received the communication command 292 that sets the address register 348 in the initial state sequentially performs such an operation, and the address registers 348 of all the integrated circuit ICs are initialized. Finally, this command is returned from the integrated circuit ICN to the battery controller 20, and the battery controller 20 can confirm that the address registers 348 of all the integrated circuits IC have been initialized.

  Based on the confirmation, address setting of each integrated circuit IC is performed next. Specifically, first, the battery controller 20 sets “the instruction execution target address to“ zero ”, further sets the value of the data 330 to“ zero ”, adds“ 1 ”to the value of the data 330, and sends it to the address register 348. A communication command 292 is transmitted, which means a message “Set to trusted data 310”. The communication command 292 is input to the reception register 322 of the integrated circuit IC1 located at the beginning of the transmission path 52. The identifier 328 part of the communication command 292 is taken into the command decoding circuit 345. Since the address register 348 of the integrated circuit IC1 is “zero” at the time of reception, (1) the value “1” added to the content “zero” of the data 330 is set in the address register 348, and (2) the above addition is performed. An operation of setting the result in the data 310 of the transmission register 302 is executed.

  In FIG. 9, based on the decoding of the command decoding circuit 345, the arithmetic circuit 346 takes in the value “zero” of 330 and performs an operation of adding “1” to this value. The operation result “1” is set in the address register 348 and in the data 310. This operation will be described with reference to FIG. When the integrated circuit IC1 receives the communication command 292 from the battery controller 20, the address register 348 of the integrated circuit IC1 becomes “1”, and the data 310 similarly becomes “1”. The data 310 of the communication command 292 is changed to “1” by the integrated circuit IC1 and is sent to the integrated circuit IC2. The identifier 308 of the communication command 292 transmitted from the integrated circuit IC1 is the same as that transmitted by the battery controller 20, and the contents of the data 310 are changed.

  Since “0” is held in the address register 348 of the integrated circuit IC2, the arithmetic circuit 346 also adds “1” to the value “1” of 330 as shown in FIG. Set in register 348 and data 310. The address register 348 of the integrated circuit IC2 is changed from “0” to “2”. As shown in FIG. 8, the address register 348 of the integrated circuit IC2 is changed from “0” to “2”, the data 310 of the transmission register 302 is changed to “2”, and the data is transmitted to the next integrated circuit IC3. In this way, the address register 348 of the integrated circuit IC3 is changed from “0” to “3”, and the data 310 of the transmission register 302 is changed to “3”.

  Thereafter, such an operation is sequentially repeated, the address register 348 of the integrated circuit ICn-1 is changed from “0” to “n−1”, and the data 310 of the transmission register 302 is further changed to “n−1”. To the next integrated circuit ICn. The address register 348 of the integrated circuit ICn is changed from “0” to “n”, and the data 310 of the transmission register 302 is changed to “n”. A communication command 292 is returned from the integrated circuit ICn to the battery controller 20. Since the returned data 330 of the communication command 292 is changed to “n”, the battery controller 20 can confirm that the address setting operation has been performed correctly.

  In this way, the address registers 348 of the integrated circuits IC1, IC2, IC3, IC4,... Is set.

  In this embodiment, each integrated circuit has a function of resetting the address registers 348 of all the integrated circuits to the initial value (zero), so that the address setting operation can be performed reliably.

<Other embodiments of address setting>
10, the communication command 292 is transmitted from the battery controller 20 to the integrated circuits IC1, IC2, IC3, IC4,..., ICn-1, ICn shown in FIG. An embodiment will be described.

  First, as a premise, similarly to the operations of FIGS. 8 and 9, a communication command 292 including a message “set contents of the address register 348 of all integrated circuits to an initial value, for example,“ zero ”” from the battery controller 20 And the contents of the address register 348 of all integrated circuits are set to “zero”. Next, in step 1 of FIG. 10, the target of the communication command 292 transmitted from the battery controller 20 is changed to the integrated circuit of “address“ zero [initial value] ”, the contents of the address register 348 are changed to“ 1 ”. A communication command 292 including the message “set address of integrated circuit“ 1 ”” is transmitted. Here, there is no problem with the value “1” of the target integrated circuit of the communication command 292 to be transmitted even if it is a value other than the address “1”, that is, a value other than “zero (initial value)”. If so, it can be executed.

  As shown in FIG. 1, the integrated circuit that first receives the communication command 292 is the integrated circuit IC <b> 1 (3 </ b> A) located at the beginning of the transmission line 52. The communication circuit 127 of the integrated circuit IC1 is as shown in FIG. 7, and the communication command 292 is held in the reception register 322. The address register 348 of the integrated circuit IC1 is already in the “zero [initial value]” state, and the command processing circuit 344 determines that the message of the communication command 292 is to be executed based on the identifier 328. The content of the address register 348 is changed to “1” according to the message of the communication command 292. Further, the contents of the identifier 308 of the transmission register 302 are changed, and the execution target address of the communication command 292 is changed to “1”. The changed communication command 292 is transmitted.

  The integrated circuit IC2 that next receives the communication command 292 determines that the content of the address register 348 is “zero [initial value]”, and the command processing circuit 344 of the integrated circuit IC2 is not the object to be executed. Is set in the transmission register 302 as it is, and the communication command 292 is transmitted to the next as it is. In the integrated circuit IC3 and later, similarly, the contents of the address register 348 are determined to be out of execution because the contents of the address register 348 are “zero [initial value]”, and the communication command 292 is returned to the battery controller 20 without being executed.

  The return of the communication command 292 is confirmed. Next, as shown in Step 2 of FIG. 10, the contents of the address register 348 are set to “2” from the battery controller 20 for the integrated circuit of “address“ zero [initial value] ”. Instead, the communication command 292 including the message “2” of the target integrated circuit of the communication command 292 to be transmitted is transmitted. Here, with respect to the point “set the address“ 2 ”of the target integrated circuit of the communication command 292 to be transmitted”, there is no problem even if it is a value other than the address “2”, that is, the address setting is not doubled. No problem. The address register 348 of the integrated circuit IC1 that is received first is “1”, the command processing circuit 344 determines that it is not subject to execution, and the communication command 292 is transmitted to the next integrated circuit IC2 as it is.

  Next, in the integrated circuit IC2 to be received, the address register 348 is “zero”, the command processing circuit 344 executes the communication command 292, sets “2” in the address register 348, and sets the execution target of the communication command 292 to “ Change to 2 "and send to the next. Since the address registers 348 are all “zero” after the integrated circuit IC3 and are not to be executed, the communication command 292 is returned to the battery controller 20 without being executed.

  Similarly, every time the battery controller 20 transmits a communication command 292, the contents of the address register 348 of the integrated circuit IC3 are changed from "zero" to "3", and the contents of the address register 348 of the integrated circuit IC4 are further "zero". Is changed to "4". Then, the contents of the address register 348 of the integrated circuit ICn are changed from “zero” to “n”.

<Adjustment of state of charge SOC>
FIG. 11 shows a processing flow for measuring the state of charge SOC of the battery cell of the battery unit 9, selecting a battery cell with a large amount of charge, calculating a discharge time for each of the selected battery cells, and executing discharge. Show. In the drawing, the left side shows the operation of each integrated circuit, and the right side shows the operation on the main controller 20 side.

  In FIG. 11, first, in step 400, a communication command 292 requesting reading of the initial voltage of the battery cell is transmitted from the battery controller 20 to the integrated circuit 3 </ b> A as a command target. When the integrated circuit 3A receives the communication command 292, the command processing circuit 344 shown in FIG. 7 sets the content held in the initial value storage circuit 275 in the data 310 of the transmission register 302 and transmits it to the next integrated circuit (step 410). .

  The battery controller 20 designates the next integrated circuit of the integrated circuit 3A, reads the voltage of the initial state of the battery cell, further sequentially takes in the integrated circuit 3M and the integrated circuit 3N, and all the battery cells of the battery unit 9 The voltage value in the initial state is taken from the initial value storage circuit 275 of each integrated circuit.

  In step 420, the battery controller 20 takes in the measured voltage of each battery cell of the entire battery unit 9, and calculates, for example, the state of charge SOC of each battery cell from the taken-in information. In step 430, the conduction time of the balancing switches 129A to 129D is calculated for battery cells that are larger than the average value. The method for obtaining the conduction time of the balancing switches 129A to 129D is not limited to the above method, and there are various methods. In any method, the conduction times of the balancing switches 129A to 129D related to the battery cells having a large state of charge SOC are determined.

  In step 440, the battery controller 20 transmits the obtained conduction time of the balancing switch to the corresponding integrated circuit using the communication command 292.

  In step 450, the integrated circuit that has received the energization time conducts the balancing switch based on the command.

  At step 460, the conduction time of each balancing switch is measured, and at step 470, each balancing switch conduction time is compared with the passage of conduction time to determine whether the measured conduction time value has reached the calculated conduction time. For the balancing switch whose conduction time has reached the calculated conduction time, the process proceeds to the next step 480 and step 480 is executed.

  In step 480, the battery controller 20 transmits a communication command 292 instructing the opening of the balancing switch that has reached the calculated energization time to the corresponding integrated circuit. In response to this communication command 292, in step 490, the corresponding integrated circuit stops the driving signal from the switch driving circuit 133 of the balancing switch instructed by the communication command 292, and opens the balancing switch. Thereby, the discharge of the corresponding battery cell is stopped.

<Testing whether each integrated circuit is abnormal>
FIG. 12 shows a processing flow for testing whether or not each of the integrated circuits 3A,..., 3M,. In the drawing, the left side shows the operation of each integrated circuit 3A,..., 3M,..., 3N, and the right side shows the operation of the main controller 20.

  In step 500, a communication command for detecting a state (abnormality) is transmitted from the battery controller 20 to the integrated circuit 3A. Next, in step 510, the communication command for detecting the state (abnormality) is transmitted from the integrated circuit 3A in the order of..., Integrated circuit 3M,.

  In step 520, the battery controller 20 receives each state (abnormality) sent from each integrated circuit, and checks the sent state (abnormality). Next, in step 530, the battery controller 20 determines which integrated circuit of the integrated circuits 3A, ..., 3M, ..., 3N is abnormal, or which of the battery cells BC1 to BC4 of each group is abnormal. Determine if there is any. Then, when it is determined that all the integrated circuits or the corresponding battery cells are not abnormal, this flow ends. On the other hand, if it is determined that any one of the integrated circuits 3A,..., 3M,.

  In step 540, the battery controller 20 transmits a communication command for detecting a state (abnormal content) for specifying the abnormal content by specifying the address of the integrated circuit having the abnormal.

  In step 550, the integrated circuit that has received the address designation transmits the measurement value or diagnosis result that caused the abnormal state (abnormal content). In step 560, the battery controller 20 confirms the integrated circuit having the abnormality and the cause of the abnormality. The process in FIG. 12 ends when the cause of the abnormality is confirmed. After that, according to the cause of the abnormality, it is determined whether to supply DC power from the lithium battery or to charge the generated electric power. Open the relay and stop the power supply.

<Vehicle power supply system>
FIG. 13 is a circuit diagram in which the DC power supply system described above based on FIG. 1 is applied to a drive system for a vehicular rotating electrical machine. The battery module 900 includes a battery unit 9, a cell controller 80, and a battery controller 20. In FIG. 13, the battery cells constituting the battery unit 9 are divided into two blocks, a high potential side block 10 and a low potential side block 11. The high potential side block 10 and the low potential side block 11 are connected in series via an SD (service disconnect) switch 6 for maintenance / inspection in which a switch and a fuse are connected in series.

  The positive electrode of the high potential side block 10 is connected to the positive electrode of the inverter device 220 via the positive high voltage cable 81 and the relay RLP. The negative electrode of the low potential side block 11 is connected to the negative electrode of the inverter device 220 via the negative high voltage cable 82 and the relay RLN. The high-potential side block 10 and the low-potential side block 11 are connected in series via the SD switch 6, for example, a high voltage battery having a nominal voltage of 340V and a capacity of 5.5Ah (a battery of a power supply system in which two battery units 9 are connected in series). Is configured. For example, a fuse having a rated current of about 125 A can be used as the fuse of the SD switch 6. With such a configuration, high safety can be maintained.

  As described above, the relay RLN is provided between the negative electrode of the low potential side block 11 and the inverter device 220, and the relay RLP is provided between the positive electrode of the high potential side block 10 and the inverter device 220. A parallel circuit of a resistor RPRE and a precharge relay RLPRE is connected in parallel with the relay RLP. A current sensor Si such as a Hall element is inserted between the positive side main relay RLP and the inverter device 220, and the current sensor Si is built in the junction box. The output line of the current sensor Si is led to the battery controller 20 so that the inverter device 220 can constantly monitor the amount of current supplied from the lithium battery DC power supply.

  As the relay RLP and the relay RLN, for example, those having a rated current of about 80 A are used, and for the precharge relay RLPRE, for example, those having a rated current of about 10 A can be used. For example, a resistor RPRE having a rated capacity of 60 W and a resistance value of about 50Ω can be used, and a current sensor Si having a rated current of about ± 200 A can be used.

  The negative high-voltage cable 82 and the positive high-voltage cable 81 described above are connected to the inverter device 220 that drives the motor 230 of the hybrid vehicle via the relay RLP, the relay RLN, and the output terminals 810 and 820. With such a configuration, high safety can be maintained.

  The inverter device 220 includes a power module 226, an MCU 222, and a power module 226 that constitute an inverter that converts DC power supplied from a power source of a 340 V high-power battery into three-phase AC power for driving the motor 230. And a smoothing capacitor 228 having a large capacity of about 700 μF to about 2000 μF. The smoothing capacitor 228 can obtain the desirable characteristics of the film capacitor than the electrolytic capacitor. The smoothing capacitor 228 mounted on the vehicle is influenced by the environment where the vehicle is placed, and is used in a wide temperature range from a low temperature of minus tens of degrees Celsius to about 100 degrees Celsius. When the temperature drops below zero degree, the electrolytic capacitor suddenly deteriorates in characteristics and the ability to remove voltage noise decreases. For this reason, there is a possibility that a large noise is added to the integrated circuit shown in FIGS. The film capacitor is less susceptible to temperature degradation and voltage noise applied to the integrated circuit can be reduced.

  In accordance with a command from the host controller 110, the MCU 222 switches the negative relay RLN from the open state to the closed state when driving the motor 230, then changes the precharge relay RLPRE from the open state to the closed state, and charges the smoothing capacitor 228. Thereafter, the positive relay RLP is changed from the open state to the closed state, and supply of power from the high-power battery of the power supply system 1 to the inverter device 220 is started. The inverter device 220 controls the phase of the AC power generated by the power module 226 with respect to the rotor of the motor 230, and operates the motor 230 as a generator during braking of the hybrid vehicle, that is, performs regenerative braking control, thereby operating the generator. The high-power battery is regenerated by regenerating the power generated by the high-power battery. When the charged state of the battery unit 9 is lower than the reference state, the inverter device 220 operates using the motor 230 as a generator, and the three-phase alternating current generated by the motor 230 is converted into direct current power by the power module 226 to generate strong power. The battery unit 9 that is a battery is supplied and charged.

  As described above, the inverter device 220 includes the power module 226, and the inverter device 220 performs power conversion between DC power and AC power. When the motor 230 is operated as a motor in accordance with a command from the host controller 110, the driver circuit 224 is controlled so as to generate a rotating magnetic field in the advance direction with respect to the rotation of the rotor of the motor 230, and the switching operation of the power module 226 is performed. To control. In this case, DC power is supplied from the battery unit 9 to the power module 226. On the other hand, the driver circuit 224 is controlled so as to generate a rotating magnetic field that is delayed with respect to the rotation of the rotor of the motor 230, and the switching operation of the power module 226 is controlled. In this case, electric power is supplied from the motor 230 to the power module 226, and DC power of the power module 226 is supplied to the battery unit 9. As a result, the motor 230 acts as a generator.

  The power module 226 of the inverter device 220 conducts and cuts off at high speed and performs power conversion between DC power and AC power. At this time, for example, a large current is cut off at a high speed, so that a large voltage fluctuation occurs due to the inductance of the DC circuit. In order to suppress this voltage fluctuation, a large-capacity smoothing capacitor 228 is provided in the DC circuit. In the inverter device 220 for in-vehicle use, heat generation of the power module 226 is a big problem, and in order to suppress this heat generation, it is necessary to increase the operation speed of conduction and interruption of the power module 226. When this operation speed is increased, the voltage jump due to the inductance increases, and a larger noise is generated. For this reason, the capacity of the smoothing capacitor 228 tends to be larger.

  In the operation start state of the inverter device 220, the charge of the smoothing capacitor 228 is substantially zero, and a large initial current flows when the relay RLP is closed. Since the initial flowing current from the high voltage battery to the smoothing capacitor 228 increases, the negative side main relay RLN and the positive side main relay RLP may be fused and damaged. In order to solve this problem, the MCU 222 changes the resistance of the precharge relay RLPRE from the open state to the closed state while the positive side relay RLP is kept open after the negative side relay RLN is changed from the open state to the closed state. The smoothing capacitor 228 described above is charged while limiting the maximum current via RPRE. After the smoothing capacitor 228 is charged to a predetermined voltage, the initial state is canceled and the precharge relay RLPRE and the resistor RPRE are not used. As described above, the negative-side relay RLN and the positive-side relay RLP are turned on. DC power is supplied from the power supply system 1 to the power module 226 in the closed state. By performing such control, the relay circuit can be protected and the maximum current flowing through the lithium battery cell or the inverter device 220 can be reduced to a predetermined value or less, and high safety can be maintained.

  Since reducing the inductance of the DC side circuit of the inverter device 220 leads to suppression of the noise voltage, the smoothing capacitor 228 is disposed close to the DC side terminal of the power module 226. The smoothing capacitor 228 itself is also configured to reduce inductance. When the initial charging current of the smoothing capacitor 228 is supplied in such a configuration, a large current flows instantaneously, and there is a possibility that high heat is generated and damaged. However, the damage can be reduced by the precharge relay RLPRE and the resistor RPRE. Although control of the inverter device 220 is performed by the MCU 222, as described above, control for initially charging the smoothing capacitor 228 is also performed by the MCU 222.

  The connection line between the negative electrode of the high-power battery of the power supply system 1 and the relay RLN on the negative electrode side, and the connection line between the positive electrode of the high-power battery and the relay RLP on the positive electrode side are connected to the case ground (the same potential as the vehicle chassis). Are respectively inserted with capacitors CN and CP. These capacitors CN and CP remove noise generated by the inverter device 220 to prevent malfunction of the weak electric system circuit and destruction due to the surge voltage of the IC constituting the cell controller 80. Although the inverter device 220 has a noise removal filter, these capacitors CN and CP further enhance the effect of preventing malfunction of the battery controller 20 and the cell controller 80, and improve the noise resistance reliability of the power supply system 1. Inserted to further enhance. In FIG. 13, the heavy electrical circuit of the power supply system 1 is indicated by a bold line. For these wires, rectangular copper wires having a large cross-sectional area are used.

  In FIG. 13, a blower fan 17 is a fan for cooling the battery unit 9 and operates via a relay 16 that is turned on by a command from the battery controller 20.

<Operation flow in power supply system for vehicles>
FIG. 14 is a diagram showing an operation flow in the vehicle power supply system shown in FIG. Hereinafter, it demonstrates in order of a step.

  In step 801, when the key switch of the vehicle is turned on and an operation for starting the engine is performed, or when the operation for running is performed from the parking state of the vehicle, or each integrated circuit is in the sleep state. When the battery controller 20 is activated in step 802, the battery controller 20 is initialized.

  In step 803, CAN communication is performed. As a result, a so-called empty message is issued to each controller, and the state of communication between the control devices is confirmed. In step 804, a communication command 292 for activation and initialization is transmitted from the battery controller 20 to the cell controller 80.

  The integrated circuits 3A,..., 3M,. The start circuit 254 starts operating, and the address register 348 of each integrated circuit is initialized. Thereafter, as described in FIGS. 8 and 10, a new address is set for each integrated circuit IC.

  In step 805, the voltage and current of the total battery in which all the battery cells are connected in series are detected by the voltmeter Vd and the current sensor Si shown in FIG. 1, and the respective outputs are input to the battery controller 20. For example, the temperature is measured by a temperature sensor (not shown).

  On the other hand, in step 804, the cell controller 80 receives the communication command 292 for starting and initializing, and the integrated circuits 3A,..., 3M,. The stage counter 256 and the second stage counter 258 start operation (step 806), and the measurement described in the operation table 260 is repeatedly executed (step 807). In step 807, as described with reference to FIGS. 4 and 6, each integrated circuit independently measures the terminal voltage of each battery cell and stores the measured value in the current value storage circuit 274 and the initial value storage circuit 275 (see FIG. 4). Step 808). From the voltage measurement result of each battery cell in step 807, each integrated circuit independently determines charge / discharge and overdischarge of each battery cell in step 809. If there is an abnormality, a diagnostic flag is set in the flag storage circuit 284 of FIG. 5, so the battery controller 20 can detect the diagnostic flag and can detect the abnormality. Since each integrated circuit independently measures the battery cell voltage and diagnoses the abnormality of the battery cell, the state of all the battery cells can be diagnosed in a short time even if the battery unit 9 is composed of many battery cells. As a result, the state of all the battery cells can be diagnosed before the relay RLP and the relay RLN are turned on, and high safety can be maintained.

  In step 810, it is confirmed that the state of each battery cell has been detected. In step 811, the initialization is completed, and it is confirmed that the diagnostic flag of the flag storage circuit 284 has not been set. It can be detected that no abnormal condition exists. When it is confirmed that there is no abnormality, the relay RLN shown in FIG. 13 is closed, then the relay RLPRE is closed, and finally the relay RLP is closed. Thereby, supply of DC power from the battery module 9 to the inverter device 220 is started.

  The elapsed time from when the key switch is turned on in step 801 to when the power supply can be started can be about 100 msec or less. Thus, it becomes possible to fully respond to a driver | operator's request | requirement by enabling supply of DC power in a short time.

  Further, during this short period, the address of each integrated circuit is set, and each integrated circuit measures all the voltages of the battery cells of each related group, and each measurement result is an initial value shown in FIG. It is stored in the storage circuit 275, and the abnormality diagnosis can be completed.

  The voltage of each battery cell is measured before each of relays RLP, RLN, and RLPRE is turned on, that is, before the inverter device 220 and the battery unit 9 are electrically connected. For this reason, the voltage of each battery cell is measured before the power supply to the inverter device 220, and the state of charge SOC can be accurately obtained from the terminal voltage of each battery cell measured before the current supply. .

  Thereafter, the normal mode is set at step 812, and the voltage, current, and temperature of each battery cell are measured at step 813. The measurement in this case is performed via communication with the cell controller 80 in step 812. The temperature measurement is based on an output from a temperature sensor (not shown).

  Then, based on the measured values of the voltage and current of each battery cell measured before the current supply, and based on the measured values of temperature, the discharge time (balancing) is calculated in step 815 as necessary. Based on the calculation result, the conduction time for controlling the balancing switches 129A, 129B, 129C, and 129D shown in FIG. 2 is transmitted to each integrated circuit. In step 816, each integrated circuit performs control to close the balancing switch based on the conduction time. This operation is performed according to the flow shown in FIG.

  In step 817, a test is performed to determine whether integrated circuits 3A-3N or each battery cell is abnormal. Next, in step 818, a state including the remaining amount or deterioration of each battery cell is calculated.

  In step 818, it is determined whether the count number has reached the conduction time calculated corresponding to each of the balancing switches 129A, 129B, 129C, and 129D. If not, the process returns to step 813, and the balancing in step 816, the test in step 817, and the state calculation of each battery cell in step 818 are repeated.

  When the count number reaches the conduction time of the balancing switches 129A, 129B, 129C, and 129D in step 818, the discharge operation is performed on the balancing switches 129A, 129B, 129C, and 129D whose count value has reached the conduction time. The battery controller 20 sends a command to the corresponding integrated circuit to make it open. Since the control for closing and discharging the balancing switch is performed only for the battery cells in the battery unit 9 having a large charged state SOC, the balancing switches for the battery cells having a small charged state SOC are maintained open from the beginning. As described above, the state of charge SOC of each battery cell of the battery unit 9 is calculated, the conduction time of the balancing switch is calculated for each battery cell, and is stored in the storage device of the battery controller 20. Since the conduction time is determined according to the state of charge SOC of each battery cell, the conduction time is usually different. Of course, there are battery cells with zero conduction time from the beginning. Therefore, in step 818, the energization time of each battery cell is compared with the count value, and a command to stop discharge of the corresponding battery cell is transmitted to the integrated circuit that controls the discharge of the battery cell after the energization time has elapsed. To do.

<Communication end sequence>
FIG. 15 is an explanatory diagram showing a sequence for ending communication with the cell controller 80 of the battery controller 20 in the vehicle power supply system shown in FIG. 1 or FIG. 13, for example.

  FIG. 15A is a diagram showing the timing of stopping power supply at the power (VC) terminal of the battery controller 20. FIG. 15B shows the power supply of the photocoupler PH1 of the entrance side interface INT (E) that is an insulation circuit, the photocoupler PH2 and the photocoupler PH3 of the exit side interface INT (O) that is an insulation circuit, and the photocoupler PH4. It is the figure which showed the timing of the stop of supply. FIG. 15C is a diagram showing the timing of stopping transmission / reception from the battery controller 20 via the TX terminal and the RX terminal. FIG. 15D is a diagram illustrating the timing of stopping the signal from the battery controller 20 via the Wake-up terminal.

  As is apparent from this figure, first, transmission / reception from the battery controller 20 via the TX terminal or RX terminal is stopped. Furthermore, when the signal from the Wake-up terminal from the battery controller 20 is used as a system, the transmission of this signal is stopped. Next, the supply of power to the power supply (VC) terminal of the battery controller 20 is stopped, and the photocouplers PH1 and PH2 of the entrance side interface INT (E) which is an insulation circuit and the exit side interface INT (O) which is an insulation circuit. The power supply to the photocouplers PH3 and PH4 is stopped.

  By stopping the operation of each unit in this order, each integrated circuit can be surely put into a sleep state.

  FIG. 16 illustrates a system that does not use a signal from the Wake-up terminal described in FIG. Since the signal from the Wake-up terminal is not used, it is not necessary to stop the signal in FIG. Other sequences are the same as those in FIG.

<Configuration of each integrated circuit and corresponding group of battery cells>
In the embodiment described above, the number of battery cells constituting each group is the same, and four battery cells are connected in each of the integrated circuits 3A,..., 3M,. Each of the integrated circuits 3A,..., 3M,..., 3N is configured to obtain information such as voltage from each of the four battery cells and to control charge / discharge of the battery cells. Also, the number of battery cells each of the integrated circuits 3A,..., 3M,.

  However, as shown in FIG. 17, the number of battery cells included in each group of the battery unit 9 can be different. The number of battery cells constituting the battery unit 9 can be freely selected and does not need to be a multiple of the number of groups. FIG. 17A shows the number of battery cells in each group, and FIG. 17B shows an integrated circuit corresponding to each group. There are different types of data regarding the terminal voltages of the battery cells held in the current value storage circuit 274 and the initial value storage circuit 275 inside each integrated circuit. When this data is transmitted to the battery controller 20 based on a request from the battery controller 20, a different number of data may be transmitted. However, as shown in FIG. Can be sent. By transmitting and receiving a fixed number of data in this way, it becomes possible to increase the reliability of transmission.

  As shown in FIG. 17 (b), the number of battery cells in the group related to each of the integrated circuits 3A,..., 3M,. As shown in FIG. 17 (a), each of the groups related to the uppermost integrated circuit 3A and the lowermost integrated circuit 3N has, for example, four battery cells. The number is decreasing. The number of battery cells in the inner group that is not the end group of the battery unit 9 is the number of battery cells in the end group, for example, six more than four.

  The uppermost integrated circuit 3A or the lowest integrated circuit 3N having the potential is connected to the battery controller 20 via the insulating circuit including the photocouplers PH1 and PH4 as described above. It is preferable in terms of safety and price to lower the breakdown voltage of the photocouplers PH1 and PH4. By reducing the number of battery cells in the group to which the integrated circuit connected to the photocouplers PH1 and PH4 is related, it is possible to reduce the required breakdown voltage of the photocoupler. That is, when the uppermost integrated circuit 3A and the lowermost integrated circuit 3N are configured by connecting, for example, six battery cells, a photocoupler connected between them and the battery controller 20 is necessary. The breakdown voltage needs to be larger than the maximum value of the terminal voltages of six battery cells. As the number of cells increases, the required breakdown voltage increases accordingly.

  In this case, there are four types of terminal voltages of battery cells held in the uppermost integrated circuit 3A and the lowermost integrated circuit 3N. Data in communication with the battery controller 20 is data in four battery cells. In other integrated circuits including the integrated circuit 3M, data in communication with the battery controller 20 is data in six battery cells.

  In this embodiment, as shown in FIG. 17C, among the data of four battery cells connected to the integrated circuit 3A, the data of six battery cells connected to the next-stage integrated circuit Data of four battery cells arranged on the upper side, data of two battery cells arranged on the lower side among the data of six battery cells connected to the integrated circuit in the next stage, and Further, of the data of six battery cells connected to the next-stage integrated circuit, the data of two battery cells arranged on the upper stage side,... As in the case of data for four battery cells, data for all the battery cells is transmitted and received in units of data for four battery cells.

  In the vehicle power supply system shown in FIG. 13, for example, the amount of data that can be sent at one time in communication between the battery controller 20 and the host controller 110 is limited (for example, the upper limit data amount is equivalent to four battery cells). . Therefore, by adopting the configuration of the battery unit 9 shown in FIG. 17 (c), it is possible to send and receive signals in an amount that does not exceed the above limit amount, and to send and receive signals with reliability. Become.

  In the embodiment described above, the number of battery cells connected to each of the integrated circuits 3A and 3N at the uppermost stage and the lowermost stage is four, and the number of battery cells connected to the other integrated circuits is six. However, the present invention is not limited to this, and it is the same if the number of battery cells connected to the uppermost and lowermost integrated circuits 3A and 3N is smaller than the number of battery cells connected to other integrated circuits. There is an effect, and when either one is smaller, the withstand voltage of the smaller photocoupler can be lowered.

  In the above-described embodiment, the data of four battery cells are sequentially transmitted and received in units, although the number of battery cells connected to each integrated circuit is different. However, the unit battery cell data is not limited to four pieces, and the number of battery cells connected to each integrated circuit is less than the number of battery cells, which is the largest number. The same effect can be obtained by transmitting / receiving the data in units.

<Battery module configuration>
18 and 19 show an example of a specific configuration of a battery module 900 including the battery unit 9 and the cell controller 80. FIG. The battery module 900 includes an upper lid 46 and a lower lid 45 and has a battery case 9a made of metal and having a substantially rectangular parallelepiped shape. The battery module 900 supplies power to the inverter device 220 or the like, or supplies DC power to the power generator, or DC power. Output terminals 810 and 820 for receiving power. A plurality of assembled batteries 19 are accommodated and fixed in the battery case 9a. The battery module 900 is covered with a battery case 9a, which is a metal case, and there are many wirings for detecting voltage and temperature in the battery case 9a. Protected from. Further, as described above, the battery cell is protected by the battery case 9a and the outer container, and the safety of the power supply system is maintained even if a traffic accident occurs.

  In this embodiment, the battery cell is a cylindrical lithium secondary battery in which a positive electrode active material is lithium manganese complex oxide and a negative electrode active material is amorphous carbon and is covered with a casing having high thermal conductivity. The battery cell of this lithium secondary battery has a nominal voltage of 3.6 V and a capacity of 5.5 Ah, but when the state of charge changes, the terminal voltage of the battery cell changes. When the charge amount of the battery cell decreases, it decreases to about 2.5 volts, and when the charge amount of the battery cell increases, it increases to about 4.3 volts.

  In the present embodiment, each battery cell facilitates the connection work of the detection harness 32 and the high voltage cables 81 and 82 and can maintain safety.

  As shown in FIGS. 18 to 19, two battery blocks 10 and 11 are fixed to the lower lid 45 so as to be juxtaposed. A cell controller box (C / C box) 79 containing a cell controller (hereinafter abbreviated as C / C) 80 shown in FIG. 20 is screwed to one end. As shown in FIG. 20, the C / C 80 is composed of a single board that is horizontally long and printed and printed on both sides, and is in an upright state through round holes formed in four positions at the top and bottom in the C / C box 79. It is fixed with screws. The substrate provided with the IC is disposed in a relationship facing the side surface of the battery cell constituting the assembled battery, and since this structure is adopted, the entire battery module 900 can be accommodated in a relatively small space. Moreover, the complexity of wiring between each assembled battery and C / C80 can be eliminated.

  Connectors 48 and 49 for connection via the detection harness 32 and the respective battery cells constituting the battery blocks 10 and 11 are provided at the left and right ends of the board constituting the C / C 80 at a distance from each other. Yes. A harness connector (not shown) attached to one side which is the substrate side of the detection harness 32 is connected to the connectors 48 and 49 of the C / C 80. That is, as shown in FIG. 19, the detection harness 32 is provided for each of the battery blocks 10 and 11. Since the battery module 900 is divided and accommodated in two battery blocks 10 and 11, two connectors 48 and 49 are mounted on the C / C 80. Since the two assembled battery blocks 10 and 11 are connected using connectors, they are excellent in wiring work and easy to maintain. One of the connectors 48 and 49 is used for connection with the high voltage side battery cell of the battery cells connected in series, and the other of the connectors 48 and 49 is connected with the low voltage side battery cell of the battery cells connected in series. Used for. The connection between the battery cells connected in series and the C / C 80 is divided into a plurality of connections based on the potentials of the battery cells connected in series, and a plurality of connectors corresponding to the division according to the potential state are used. Thus, the battery cell and C / C80 are connected. Thereby, the potential difference in the connection connected by each connector can be reduced. With such a configuration, excellent effects can be obtained with respect to withstand voltage, current leakage, and dielectric breakdown. Further, it is difficult to connect or open the entire connector at the same time in connection and release work of each connector, and a partial connection state occurs in the connection and release process. In the above configuration, the voltage difference of each connector can be reduced, so that it is possible to suppress an adverse electrical effect due to partial connection that occurs during the connection and release process.

  In addition, a plurality of ICs are prepared for a single voltage series connection housed in the battery module 900 on the C / C 80 substrate. How many battery cells a single IC is responsible for depends on the processing capability of each IC. In this embodiment, one IC is used for four battery cells. However, one IC may be used for five or six battery cells. Further, in the same system, a part using one IC for four battery cells and a part using one IC for six battery cells may be combined. The number of battery cells connected in series is not necessarily a multiple of the optimum number that each IC can handle. In this embodiment, it is a multiple of 4. However, since it is not always a multiple of 4, the number of battery cells handled by one IC may differ within the same system, but this is not a big problem. .

  The battery cells connected in series are divided into a plurality of groups based on the number of battery cells handled by one IC, and the corresponding IC is determined for each group, and the corresponding IC is configured by the corresponding IC. The terminal voltage is measured. As described above, the number of battery cells constituting each group may be different.

  Moreover, the communication harness 50 for communicating with the battery controller 20 is derived | led-out from the board | substrate of C / C80, and the communication harness 50 has a connector in the front-end | tip part. This connector is connected to a connector (not shown) on the battery controller 20 side. Note that chip elements such as resistors, capacitors, photocouplers, transistors, and diodes are mounted on the C / C80 substrate, but these elements are omitted in FIG. 20 to avoid complications. In the C / C 80 substrate, connectors 48 and 49 are provided for the two battery pack blocks, respectively, and a communication harness 50 for communicating with the battery controller 20 is provided separately from the connectors. Thus, by providing the connectors 48 and 49 and the communication harness 50 separately, wiring work becomes easy and maintenance becomes easy. In addition, as described above, one of the connectors 48 and 49 connects the battery cell on the high voltage side connected in series with the C / C80 substrate, and the other of the connectors 48 and 49 connects the battery on the low voltage side connected in series. Since the cell and the C / C80 substrate are connected, the voltage difference within the range of each connector can be reduced. A partial connection state in which only a part of the connectors is connected momentarily occurs when the connector is connected or opened. However, since the voltage difference within the range of each connector can be reduced, adverse effects caused by the partial connection state can be reduced.

  The assembled battery blocks 10 and 11 fixed in parallel to the lower lid 45 are connected in series by an inter-block connection bus bar (not shown). Output terminals 810 and 820 for supplying the power of the positive high voltage cable 81 and the negative high voltage cable 82 to the outside or receiving power from the outside are provided on the front portion of the lower lid base.

<Diagnosis of each battery cell>
The measurement of each battery cell and the overcharge and overdischarge diagnostic operations performed in the internal processing operation of each integrated circuit 3A... Integrated circuit 3M... Integrated circuit 3N shown in FIG. In stage STGCV1 to stage STGCV6 described in the row 260Y1 of the operation table 260 in FIG. 4, the terminal voltage of each battery cell is captured and diagnosed. In the measurement period of the stage STGCV1, as described above, the selection circuit 120 in FIG. 5 selects VCC (V1) and VC2 (V2). By this operation, the terminal voltage of the battery cell BC1 in FIG. 2 is selected and input to the voltage detection circuit 122A via the differential amplifier 262 having a potential shift function. The voltage detection circuit 122A converts it into a digital value, and the averaging circuit 264 calculates the average value based on the newest predetermined number of measurement values including the current measurement, and holds it in the register CELL1 of the current value storage circuit 274.

  Based on the measurement value held in the register CELL1 of the current value storage circuit 274, the overcharge or overdischarge diagnosis of the battery cell BC1 is performed within the measurement period of the stage STGCV1 in FIG. Before starting the diagnosis, a reference value for diagnosis is transmitted from the battery controller 20 to each integrated circuit, the overcharge diagnosis reference OC is stored in the register of the reference value storage circuit 278, and the overdischarge diagnosis reference OD is the reference value. It is held in the register of the memory circuit 278, respectively. Further, even if the reference value cannot be transmitted from the battery controller 20 using the communication command 292 or an erroneous value is held in the reference value storage circuit 278 due to noise or other causes, the communication is performed so that an abnormal state of overcharge can be grasped. The overcharge reference value OCFFO that cannot be rewritten by the command 292 is held in advance.

<Diagnosis of overcharge>
Following the measurement of the terminal voltage in the measurement of the stage STGCV1, the measured terminal voltage value is compared with the overcharge determination value OC by the digital comparison circuit 270. That is, the first stage counter 256 and the second stage in FIG. 4 are selected from the registers CELL1 to CELL6 of the current value storage circuit 274, a plurality of measured values held in the register VDD, and the VDD value or the reference power supply (PSBG). Based on the selection signal generated by the decoder 257 or the decoder 259 based on the output of the counter 258, the measured value of the register CELL1 is selected and input to the digital comparison circuit 270. Similarly, the overcharge diagnosis reference value OC is selected from a plurality of reference values held in the reference value storage circuit 278 by the selection signal generated by the decoder 257 or the decoder 259, and the digital comparison circuit 270 stores the register The measured value of the battery cell BC1 in CELL1 is compared with the overcharge diagnostic reference value OC. The digital comparison circuit 270 outputs a comparison result indicating an abnormality when the measured value of the battery cell BC1 is larger than the overcharge diagnosis reference value OC. The digital multiplexer 282 selects the storage destination of the output of the digital comparison circuit 270 based on the selection signal generated by the decoder 257 or the decoder 259. If the diagnosis result of the battery cell BC1 is abnormal, the abnormality diagnosis result is held in the register MFflag and the register OCflag of the flag storage circuit 284. That is, the MFflag and OCflag are set. The abnormality flag is output from the terminal FFO of the integrated circuit and transmitted to the battery controller 20.

  Next, in order to improve reliability, the digital comparison circuit 270 compares the measured value of the battery cell BC1 with the overcharge diagnostic reference value OCFFO. When the measured value of the battery cell BC1 is larger than the overcharge diagnosis reference value OCFFO, the abnormality diagnosis result is held in the register MFflag and the register OCflag of the flag storage circuit 284 as an abnormality related to overcharging. When the abnormality flag is set in the flag storage circuit 284, it is transmitted to the battery controller 20 as described above. The overcharge diagnosis reference value OCFFO is a reference value that cannot be rewritten from the battery controller 20, and even if an abnormality occurs in the program or operation of the battery controller 20, the overcharge diagnosis reference value OCFFO is not changed, so that a highly reliable determination can be made. The overcharge diagnostic reference value OC can be changed from the battery controller 20 and can be finely determined. Further, as described above, the overcharge diagnostic reference value OCFFO is maintained regardless of the state of the battery controller 20 or the transmission path and has high reliability. It is data, and a diagnosis with high reliability can be realized by making a diagnosis using these two types of data.

<Diagnosis of overdischarge>
The overdischarge diagnosis of the battery cell BC1 is further continued in the measurement period of the stage STGCV1. The measured value of the battery cell BC1 stored in the register CELL1 of the current value storage circuit 274 and the reference value OD of the reference value storage circuit 278 are compared by the digital comparison circuit 270. When the measured value of the battery cell BC1 is smaller than the reference value OD of the reference value storage circuit 278, it is determined as abnormal and an abnormal signal is output. The digital multiplexer 282 selects the MFflag and ODflag of the flag storage circuit 284 by a selection signal based on the outputs of the decoder 257 and the decoder 259, and the abnormal signal output from the digital comparison circuit 270 is set in the register MFflag and the register ODflag.

  If MFflag is set in the diagnosis of each item, the flag is output from the 1-bit output terminal FFO via the OR circuit 288 and transmitted to the battery controller 20.

  The function of the selection circuit 286 can be changed by the communication command 292 from the battery controller 20, and up to which flag the flag output from the terminal FFO is included can be selectively changed. For example, the condition for setting the MFflag of the flag storage circuit 284 may be only overcharge abnormality. In this case, the overdischarge abnormality diagnosis output of the digital comparison circuit 270 is not set in the register MFflag, but only ODflag is set. Whether or not ODflag is output from the terminal FFO can be determined by the setting condition of the selection circuit 286. In this case, since the setting condition can be changed from the battery controller 20, it is possible to cope with various controls.

  Following the stage STGCV1 described in the row 260Y1 of the operation table 260 in FIG. 4, next is the stage STGCV2. In FIG. 6, the selection circuit 120 selects VC2 (V2) and VC3 (V3), thereby selecting the terminal voltage of the battery cell BC2 in FIG. By the same operation as the above-described stage STGCV1, the terminal voltage of the battery cell BC2 is digitally converted by 122A, the averaging circuit 264 calculates the average of the latest predetermined number of measurements including the current measurement result, and stores the current value It is held in the register CELL2 of the circuit 274. The selection of the measurement result holding position is performed based on the outputs of the decoders 257 and 259 in FIG.

  Next, similarly to the above-described stage STGCV1, the measured value of the battery cell BC2 is selected from the current value storage circuit 274 based on the outputs of the decoders 257 and 259 of FIG. 4, and the overcharge diagnostic reference value of the reference value storage circuit 278 is selected. Diagnosis is performed by selecting the OC and comparing it with the digital comparison circuit 270. The diagnosis contents and operation are the same as those of the above-described stage STGCV1.

  In the following steps STGCV3 to STGCV6, diagnosis is performed following the measurement by the circuit of FIG. 5 with the same operation content as the above-described stage STGCV1 and stage STGCV2.

<Adjustment of state of charge SOC and measurement of terminal voltage>
The control for controlling the balancing switches 129A to 129F to adjust the state of charge SOC of each battery cell constituting the battery unit 9 and discharging the power of the battery cell having a large amount of charge through the discharge resistor has been described above. . The opening / closing control of the balancing switches 129A to 129F may adversely affect the detection of the terminal voltage of each battery cell. That is, when the balancing switch 129 is closed in the circuit of FIG. 2, a discharge current flows through the resistors R1 to R4, and the measurement accuracy of the terminal voltages of the battery cells BC1 to BC4 is lowered.

  The opening / closing control of the balancing switches 129A to 129F needs to be performed based on the state of the battery cells of the entire battery unit 9. Therefore, it is desirable that the battery controller 20 shown in FIG. 1 perform processing, and it is desirable that each of the integrated circuits 3A to 3N controls the balancing switches 129A to 129F based on a command from the battery controller 20. On the other hand, regarding the measurement of the terminal voltage of each battery cell, each of the integrated circuits 3A to 3N independently measures the battery cell voltage of the group in charge, and when receiving a measurement value transmission command from the battery controller 20, it is unique. It is desirable to promptly transmit the measured value of the terminal voltage that has been measured and held at the same time. Therefore, it is necessary to harmonize the control of the balancing switches 129A to 129F with different control circuits with the measurement of the terminal voltage of each battery cell, and to execute both controls comprehensively.

  A specific configuration for realizing both of the above-described controls will be described with reference to FIGS. In the following description, in addition to the discharging resistors R1 to R4 shown in FIG. 1 and FIG. 2, it is desirable to provide capacitors C1 to C6 in order to eliminate the influence of noise in the actual product. FIGS. 21, 22, 26, and 27 show circuits to which noise removing capacitors are added. In FIGS. 1 and 2, the number of battery cells is four, but FIG. 21, FIG. 22, and FIG. In FIG. 27, six are described. The resistors and capacitors are held by the cell controller indicated by the broken line 80 together with the integrated circuit indicated by the broken line, and are connected to the battery cells BC1 to BC6 of the battery block via the communication harness 50 shown in FIG.

  FIG. 22 shows a circuit devised to further reduce the influence of noise using the discharge resistors R1 to R6 shown in FIG. 23 and 24 are diagrams showing the operation of the discharge control for the measurement control and the adjustment of the state of charge SOC, FIG. 23 shows the operation of the circuit shown in FIG. 21, and FIG. 24 shows the operation of the circuit shown in FIG. The operation is shown. FIG. 25 shows a circuit for performing the control shown in FIGS.

  In the circuit of FIG. 21, the terminal voltage of the battery cell BC1 is measured at the stage STGCV1, and the terminal voltage of the battery cell BC2 is measured at the next stage STGCV2. Measurement of the terminal voltages of the battery cells BC3 to BC6 is performed in the following order. By repeating the measurement in this way, it is possible to always monitor the state of the terminal voltage of the battery cell.

  For example, when the balancing switch 129B is closed to adjust the state of charge SOC, a discharge current flows through the balancing switch 129B and the resistor R2, and the internal resistance and wiring resistance of the battery cell BC2 due to the discharge current are affected. Thus, the voltage VC2 input to the selection circuit 120 is lower than the terminal voltage when the balancing switch 129B is in the open state. That is, when the balancing switch 129B is closed, the terminal voltage input to the input circuit 116 becomes a low value, and the measurement accuracy decreases.

  In order to prevent the measurement accuracy from being lowered, as shown in FIG. 23, in the stage STGCV1 for measuring the terminal voltage of the battery cell BC1, the control of the state of charge SOC is temporarily stopped, the balancing switch 129A is opened, and the battery The terminal voltage of the cell BC1 is measured. In stage STGCV2 for measuring the terminal voltage of the next battery cell BC2, the charge state SOC control is temporarily stopped, the balancing switch 129B is opened, and the terminal voltage of the battery cell BC2 is measured. Thereafter, the balancing switches 129C to 129F (BSW3 to BSW6 in FIG. 23) are opened in order, and the terminal voltage of the battery cell is measured.

  Control for adjusting the state of charge SOC may be stopped in each measurement period of each stage STGCV1 to STGCV6. Alternatively, the control for adjusting the state of charge SOC may be stopped only for a short time during which the terminal voltage is actually measured within the period of each stage STGCV1 to STGCV6.

  Next, the circuit shown in FIG. 22 will be described. Large noise is mixed in the power lines supplied from the battery cells BC1 to BC6 connected in series to the inverter device. In order to reduce the influence of this noise, in the circuit shown in FIG. 22, resistors RA1 to RA7 are inserted between each battery cell terminal and the input terminal of the input circuit 116. The resistors RA1 to RA7 perform noise removal together with the capacitors C1 to C7 to protect the integrated circuit from noise.

  In the circuit shown in FIG. 22, when the balancing switch 129A is closed to adjust the state of charge SOC, the discharge current of the battery cell BC1 flows through the resistor R1, the balancing switch 129A, and the resistor RA2. Since the discharge current with the balancing switch 129A closed flows through the resistor RA2, this affects not only the measurement of the terminal voltage of the battery cell BC1, but also the measurement of the terminal voltage of the battery cell BC2. Accordingly, both the balancing switch 129A and the balancing switch 129B need to be opened when measuring the terminal voltage of the battery cell BC2. Similarly, when measuring the terminal voltage of the battery cell BC3, it is necessary to open both the balancing switch 129B and the balancing switch 129C, and the same applies to the measurement of other battery cells.

  FIG. 24 shows a situation in which the balancing switch 129 is forcibly opened when measuring the battery cell in the circuit shown in FIG. In stage STGCV2, since the terminal voltage of battery cell CB2 in FIG. 22 is measured, control for adjusting the charging state SOC of balancing switches 129A and 129B is stopped, and these balancing switches 129A and 129B are maintained in the open state. To do. In this case, the control for adjusting the state of charge SOC of the balancing switches 129A and 129B may be stopped over the entire period of the stage STGCV2, or balancing is performed only for a short period during which the voltage is actually measured during the stage STGCV2. Control for adjusting the state of charge SOC of switches 129A and 129B may be stopped as in the case of FIG.

  Further, since the terminal voltage of the battery cell B3 of FIG. 22 is measured at the stage STGCV3 of FIG. 24, the control for adjusting the state of charge SOC of the balancing switches 129B and 129C is stopped during the measurement period of the terminal voltage of the battery cell BC3. During the measurement period, the balancing switches 129B and 129C are kept open. In this case, the control for adjusting the state of charge SOC of the balancing switches 129B and 129C may be stopped over the entire period of the stage STGCV3. Alternatively, the control for adjusting the state of charge SOC of the balancing switches 129B and 129C may be stopped only during a short period during which the voltage is actually measured during the stage STGCV3.

  In stage STGCV4 or stage STGCV5, since the terminal voltage of battery cell BC4 or BC5 is measured, balancing switches 129C and 129D or balancing switches 129D and 129E are kept open. In stage STGCV6, the terminal voltage of battery cell BC6 is measured. Therefore, the balancing switch 129F is kept open during the measurement period of the terminal voltage of the battery cell BC6.

  Note that the period indicated by the arrow ← → in FIGS. 23 and 24 is a period in which the control of the balancing switches 129A to 129F for adjusting the state of charge SOC is performed. Further, a period described as “OFF” indicates a period during which the control of the balancing switches 129A to 129F for adjusting the state of charge SOC is stopped and the state is forcibly opened. As described above, the measurement accuracy of the battery cell terminal voltage can be improved by forcibly opening the balancing switch 129 related to the measurement period of the battery cell terminal voltage in preference to the adjustment control of the state of charge SOC performed by the battery controller 20. Can be improved.

  Next, the opening operation of the balancing switch 129 will be described using the circuit shown in FIG. First, a control value for adjusting the state of charge SOC is calculated in step 815 of FIG. 14, and is sent to each integrated circuit 3A... 3M. In each of the integrated circuits 3A... 3M... 3N, the balancing circuit 129A to 129F is controlled based on the reception result received by the communication circuit 127 shown in FIG.

  Data 330 shown in FIG. 25 is an enlarged view of the data 330 portion of the reception register 322 in FIG. 7, and the contents of the data 330 are input to the discharge control circuits 1321 to 1326. The input control signal is, for example, a signal indicating “1” or “zero”. “1” represents control for closing and discharging the balancing switch 129, and “zero” means control for opening the balancing switch 129 and not discharging. To do. These control signals are held in the discharge control circuits 1321 to 1326, and the balancing switches 129A to 129F are controlled based on the held data.

  The data held in the discharge control circuits 1321 to 1326 is added to the AND gates 12 to 62, and the balancing switches 129A to 129F are driven via the OR gates 11 to OR gate 61. On the other hand, when priority is given to the balancing switches 129A to 129F over the control for adjusting the state of charge SOC, the signals based on the discharge control circuits 1321 to 1326 are blocked by the AND gates 12 to 62. This cutoff period is the period described with reference to FIGS. 29 and 30, and the battery terminal voltage is measured based on the outputs of the decoder 257 and decoder 259. Therefore, the circuit 2802 is based on the outputs of the decoder 257 and decoder 259. A control stop signal is sent to each AND gate 12 to AND gate 62.

  During the period when each AND gate 12 to AND gate 62 is opened and the control for adjusting the state of charge SOC is stopped, the AND gate 11 to AND gate 61 are closed, and the outputs of the OR gate 12 to OR gate 62 are output. Accordingly, the balancing switches 129A to 129F are driven. Therefore, during the period in which each AND gate 12 to AND gate 62 is open and the AND gate 11 to AND gate 61 is closed, the balancing switches 129A to 129A to 129A are switched from the measurement control circuit 2811 to the measurement control circuit 2861 so that the measurement is optimally performed. A control signal for controlling 129F can be output. Further, when an abnormality diagnosis of the detection harness 32 described later is performed, control signals for controlling the balancing switches 129A to 129F are output from the diagnosis control circuit 2812 to the diagnosis control circuit 2862.

  In this way, each integrated circuit 3A... 3M... 3N prioritizes the control for adjusting the state of charge SOC and stops the state of charge SOC adjustment control, and each integrated circuit performs its own balancing during the stop period. Since the circuit that can control the switches 129A to 129F is provided, there is an effect that accurate measurement and diagnosis are possible.

<Diagnosis of ADC, differential amplifier 262, reference voltage>
The internal reference voltage and analog and voltage detection circuit 122A are diagnosed at stage STGPSBG described in row 260Y1 of operation table 260 shown in FIG. A power supply voltage for operating the analog circuit and the digital circuit shown in FIG. 5 is generated in the power supply circuit 121 (FIG. 2) inside the integrated circuit. When the power supply voltage is generated based on an absolute reference power supply, the highly accurate power supply voltage can be obtained relatively easily. However, if the absolute reference voltage changes, the power supply voltage may change.

  The stage STGPSBG can efficiently diagnose the reference power supply and the analog circuit and the voltage detection circuit 122A. This will be specifically described below.

  In the circuit of FIG. 5, the input circuit 116 selects the reference power supply and GND. By this selection, the differential voltage between the GND potential and the reference power supply is input to the differential amplifier 262, potential shift and scale adjustment are performed, and input to the analog-to-digital converter 122A. The analog-digital converter 122A converts the input signal into a digital value, and this digital signal is held in the PSBG register as data PSBG in the current value storage circuit 274 based on the decoder 257 and the decoder 259.

  The voltage of the reference power supply is known if the operation of the related circuit is normal, and the reference power supply's lower tolerance (PSBGmin), which is slightly smaller than the known voltage of the reference power supply, and slightly less than the known voltage of the reference power supply. The upper allowable value (PSBGmax) of the reference power source, which is a large value, is held in the lower allowable value and the storage area for the upper allowable value previously assigned to the register of the reference value storage circuit 278, respectively. These values are values between a lower allowable value and an upper allowable value of the reference power supply if the reference power supply is normal voltage. If the analog circuit does not operate normally, for example, if the differential amplifier 262 is not normal, the output of the analog-digital converter 122A will be out of the normal range even if the reference power supply is at a normal voltage. Even when the analog-digital converter 122A is not normal, the output of the analog-digital converter 122A is out of the normal range.

  Therefore, the digital comparison circuit 270 compares whether or not the retained value “reference power supply” of the current value storage circuit 274 is between the lower allowable value and the upper allowable value of the reference power stored in the reference value storage circuit 278. And diagnose.

  Based on the outputs of the decoders 257 and 259, the digital multiplexer 272 selects the measurement value “reference power supply” and sends it to the digital comparison circuit 270. On the basis of the outputs of the decoders 257 and 259, the digital multiplexer 272 determines the reference value. The lower allowable value of the power supply is selected and sent to the digital comparison circuit 270. The digital comparison circuit 270 stores an abnormality flag holding register selected by the digital multiplexer 282 based on outputs from the decoder 257 and the decoder 259 as abnormal when the measured value “reference power supply” is smaller than the lower allowable value of the reference power supply. In the embodiment, the abnormality flag is held in the register MFflag of the flag storage circuit 284. When the measured value “reference power supply” is larger than the lower allowable value of the reference power supply, it is determined to be normal, and the abnormality flag in the flag storage circuit 284 is not set.

  During the stage STGPSBG, the digital multiplexer 272 further selects a measurement value “reference power supply” based on the outputs of the decoder 257 and the decoder 259 and sends it to the digital comparison circuit 270, and also outputs it to the outputs of the decoder 257 and the decoder 259. Based on this, the digital multiplexer 272 selects the upper allowable value of the reference power supply and sends it to the digital comparison circuit 270. The digital comparison circuit 270 is an abnormality flag holding register selected by the digital multiplexer 282 based on the outputs of the decoder 257 and the decoder 259 as abnormal when the measured value “reference power supply” is larger than the upper allowable value of the reference power supply. In the embodiment, the abnormality flag is held in the register MFflag of the flag storage circuit 284. When the measured value “reference power supply” is smaller than the upper allowable value of the reference power supply, it is determined as normal, and the abnormality flag in the flag storage circuit 284 is not set. In this way, the diagnosis of whether the differential amplifier 262 and the analog-digital converter 122A, which are analog amplifiers, are operating normally can be executed during the stage STGPSBG, and high reliability can be maintained.

<Diagnosis of digital comparison circuit>
The digital comparison circuit is diagnosed at stage STGCal of the operation table 260 shown in FIG. The operation will be described below. The digital multiplexer 272 selects the increment operation value 280 based on the outputs of the decoder 257 and the decoder 259. The increase calculation value 280 is a value obtained by adding a predetermined value to a reference value held in the reference value storage circuit 278, for example, the reference value OC. The digital multiplexer 276 selects one of the reference values held in the reference value storage circuit 278, which is the reference value OC in this embodiment, and inputs it to the digital comparison circuit 270 as a comparison target. Furthermore, an increase calculation value 280 obtained by adding a predetermined value, for example, “1” to the selected reference value OC is input to the digital comparison circuit 270 via the digital multiplexer 272. If the digital comparison circuit 270 determines that the increase calculation value 280 is larger than the reference value OC, the digital comparison circuit 270 is operating correctly.

  Next, the digital multiplexer 272 selects the decrease calculation value 281 based on the outputs of the decoder 257 and the decoder 259. The decrease calculation value 281 is a value obtained by subtracting a predetermined value, for example, “1” from the reference value held in the reference value storage circuit 278, for example, the reference value OC. The digital multiplexer 276 selects one of the reference values held in the reference value storage circuit 278, which is the reference value OC in this embodiment, and inputs it to the digital comparison circuit 270 as a comparison target. Furthermore, a decrease value 281 obtained by subtracting a predetermined value, for example, “1”, from the selected reference value OC is input to the digital comparison circuit 270 via the digital multiplexer 272. If the digital comparison circuit 270 determines that the decrease calculation value 281 is smaller than the reference value OC, the digital comparison circuit 270 is operating correctly.

  As described above, the reference value OC held in the reference value storage circuit 278 is compared with a value obtained by adding a predetermined value to the reference value OC, or is compared with a value obtained by subtracting the predetermined value. Can be diagnosed as normal.

  The purpose of using the increase calculation value 280 and the decrease calculation value 281 is to create a condition whose magnitude relationship is known for the comparison target and diagnose the comparison result. Instead of adding or subtracting a predetermined value, data It is also possible to use a value that is shifted to the upper side or shifted to the lower side. In this case, multiplication or subtraction is performed with the predetermined value 4, and a known magnitude relationship can be created as described above.

  Based on FIG. 26 and FIG. 27, the diagnosis when abnormality occurs in the detection harness 32 that connects the positive and negative electrodes of the battery cell BC and the cell controller 80 will be described. FIG. 26 shows a case where the harness L2 in the detection harness 32 of FIGS. 1 and 2 is disconnected. FIG. 27 shows a case where the harness L2 in the detection harness 32 of the circuit of FIG. As the cause of the disconnection, there may be a contact failure between the connectors 48 and 49 at the connection portions between the battery cells and the detection harness 32 shown in FIG. 19 and the connection portions between the cell controller 80 and each harness shown in FIG. In rare cases, the detection harness 32 itself may be disconnected.

  It is important to detect the possibility of abnormality of each battery cell and prevent the abnormality from occurring. If an abnormality occurs in the electrical connection between the battery cell and each integrated circuit, the possibility of the battery cell abnormality cannot be detected. A detection method for detecting an abnormality in the electrical connection between the battery cell and each integrated circuit in FIGS. 26 and 27 will be described with reference to FIG. The basic operation of FIG. 26 and FIG. 27 is as described above, and it is assumed that the harness L2 in the detection harness 32 is disconnected, but any line from the harnesses L1 to L7 is used. Similarly, it is possible to diagnose abnormalities.

  In FIG. 28, even if the harness L2 of the detection harness 32 is disconnected while the balancing switches 129A to 129C are open, there are various capacitances including the capacitor C2, and thus the voltage VC2 input to the selection circuit 120 is apparent. Above, there is a possibility of showing a normal value close to the terminal voltage V2 of the battery cell. Therefore, an abnormality cannot be detected as it is.

  Therefore, next, the balancing switch 129B that causes the discharge current to flow through L2 of the detection harness 32 to be diagnosed is closed. By closing the balancing switch 129B, the electric charge stored in the capacitance including the capacitor C2 existing between the circuits of the harnesses L2 and L3 in the detection harness 32 is discharged, and the input voltage VC2 of the selection circuit 120 is rapidly increased. To drop. If not disconnected, current is supplied from the battery cell BC2, and therefore the input voltage VC2 of the input circuit 116 hardly decreases.

  The terminal voltage of the battery cell BC2 is measured at the terminal voltage measurement stage of the battery cell BC2 described with reference to FIGS. 23 and 24 (Measurement 1). As described above, the balancing switch 129B is opened during this measurement period. Since charge flows into and accumulates in the capacitance including the capacitor C2 existing between the circuits of the harnesses L2 and L3 in the detection harness 32, the input voltage VC2 of the input circuit 116 slightly rises. The voltage VC2 measured at is a very low voltage compared to the normal voltage. The measured voltage VC2 is held in BC2 of the current value storage circuit 274 shown in FIG.

  Under the above situation, in the diagnosis of the battery cell BC2 that is performed following the measurement, the measured value read from the current value storage circuit 274 is an abnormal value that is less than or equal to the overdischarge threshold OD of the reference value storage circuit 278. The digital comparator 270 can diagnose an abnormality. The abnormality diagnosis result is set in the register MFflag of the flag storage circuit 284. Since the voltage VC2 at the time of disconnection is lower than the overdischarge threshold OD, a disconnection threshold lower than the overdischarge threshold OD is provided, and the disconnection threshold and the measured value held in the register CELL2 of the current value storage circuit 274 are digital comparator 270. By making a comparison, it is possible to easily determine the disconnection. By making the value of the register OCFFO of the reference value storage circuit 278 in FIG. 5 the value of the disconnection threshold value, it is possible to always detect disconnection.

  In FIG. 28, when the balancing switches 129A and 129C are closed after the balancing switch 129B is opened, the voltage of the series connection of the battery cells BC1 and BC2 is applied to the capacitor C2, and the terminal voltage of the capacitor C2 is very high. To be high. For this reason, when the balancing switches 129A and 129C are closed immediately after measurement 1 and measurement is performed again on the battery cell BC2 (measurement 2), the voltage VC2 is now a very high value far exceeding the overcharge threshold. Therefore, it is possible to easily detect disconnection.

  As described above, the measurement result of the measurement 2 is held in the register CELL2 of the current value storage circuit 274 illustrated in FIG. The measured value held in the register CELL2 of the current value storage circuit 274 may be compared with a threshold value for detecting disconnection by the digital comparator 270 to detect disconnection, or the software of the battery controller 20 may be processed. A disconnection diagnosis may be performed based on this.

  FIG. 29 shows a method of making a diagnosis using a communication command 292 from the battery controller 20. As described above, it is assumed that the harness L2 of the detection harness 32 is disconnected. A communication command 292 for disconnection diagnosis is transmitted at a predetermined timing. The communication command 292 is an instruction for specifying an integrated circuit to be diagnosed and “open all balancing switches 129”. That is, the data 330 of the communication command 292 is “zero” meaning open. When this command is received, the target integrated circuit of this command opens the balancing switch 129.

  Next, in order to discharge the battery cell to which the diagnostic harness 32 to be diagnosed is connected at a predetermined timing, a closing command is sent to the balancing switch 129B to close the balancing switch 129B. When the harness L2 is disconnected, the input signal VC2 to the multiplexer 120 is almost zero. Thereafter, in the measurement stage of the battery cell BC2 based on the stage signal of the integrated circuit, the balancing switch 129B is opened before the command from the battery controller 20 is output, and the measurement for measuring the terminal voltage of the battery cell BC2 is performed. Is done. When the harness L2 is disconnected, the input signal VC2 to the multiplexer 120 is a very low voltage, and this low voltage is held in the register CELL2 of the current value storage circuit 274 in FIG.

  Since the integrated circuit independently measures the battery cell terminal at a short cycle, the balancing switch 129B is opened again, and measurement for measuring the terminal voltage of the battery cell BC2 is performed. When the harness L2 is disconnected, the measurement result is a very low value, and this value is held in the register CELL2 of the current value storage circuit 274.

  When receiving an instruction for fetching the diagnostic result from the battery controller 20, the integrated circuit transmits the measurement result held in the register CELL 2 of the current value storage circuit 274. The battery controller 20 can receive this measurement result and detect the disconnection based on the measurement result lower than the overdischarge state. That is, the measurement result sent from the integrated circuit is compared with the threshold value ThL1 shown in FIG. 29, and if the measurement result is below the threshold value ThL1, it is determined that the wire is disconnected, and the connection between the DC power source using the lithium battery and the inverter is made. Preparation for disconnecting is started, and relays RLP and RLN are opened as soon as preparation is completed.

  For further accuracy, the battery controller 20 sends a command to close the balancing switches 129A and 129C and open the balancing switch 129B. If it is disconnected, closing the balancing switch 129 on both sides of the battery cell to be diagnosed causes the input voltage VC2 to the selection circuit 120 to become very large, so that a voltage greater than the overcharge threshold is measured. This measurement result is held in the register CELL2 of the current value storage circuit 274.

  When receiving the measurement result fetch command from the battery controller 20, the integrated circuit transmits the measurement value to the battery controller 20. The battery controller 20 receives the measurement result, compares it with a threshold value ThL2 for disconnection detection higher than the overcharge threshold value, and determines that the disconnection occurs when the measurement result is larger than the threshold value ThL2. The disconnection can be detected accurately by comparing the result of measurement 1 or measurement 2 with the threshold ThL1 or by comparing the average value of measurement 1 and measurement 2 with the threshold ThL1, but by comparing with the threshold ThL1, It is possible to detect disconnection with high accuracy. In addition, it can be easily performed by using the measurement operation of the terminal voltage of a normal battery cell. Further, it is easy to make a diagnosis by using the balancing switch 129 for controlling the state of charge SOC that is already provided without increasing the number of special circuits.

  Next, a method for automatically diagnosing disconnection in each integrated circuit will be described with reference to FIGS. By performing unit voltage measurement and disconnection diagnosis based on the stage signal shown in FIG. 4, disconnection diagnosis can be automatically performed. FIG. 30 shows a specific measurement and diagnosis schedule, and FIG. 32 shows a specific circuit.

  30 shows the measurement and disconnection diagnosis of the integrated circuit 3A in the m-th and m + 1-th cycles of the stage signal, and the interruption shows the measurement and disconnection diagnosis of the integrated circuit 3B next to the integrated circuit 3A. Indicates measurement and disconnection diagnosis of the next integrated circuit 3C of the integrated circuit 3B. The integrated circuit 3B receives the synchronization signal from the integrated circuit 3A, and the integrated circuit 3C receives the synchronization signal from the integrated circuit 3B, and the processing of the stages shown in FIG. 4 is started. In FIG. 30, the display “ON” means a period during which the balancing switch 129 is closed and “OFF” means a period during which the balancing switch 129 is opened. “Measurement” means a period during which measurement of terminal voltage of a battery cell and control of disconnection diagnosis are performed. A portion where “ON”, “OFF”, and “measurement” are not described is a period during which the state of charge SOC is performed.

  The balancing switch 129A is closed at the stage STGCal of the integrated circuit 3A. If there is a break in the detection harness 32, the input voltage of the selection circuit 120 becomes very small as shown in FIG. 28 by closing the balancing switch 129A. Therefore, the terminal of the battery cell BC1 measured at the stage STGCV1 The voltage is detected by the analog-digital converter 122A in FIG. 31 as an abnormally small value. Therefore, the measurement value held in the register CELL1 of the current value storage circuit 274 is a very small value. Note that the balancing switch 129B is also controlled to be in the open state in order to increase the measurement accuracy at the stage STGCV1.

  In the disconnection diagnosis performed subsequent to the measurement, the measured value held in the register CELL1 of the current value storage circuit 274 and the threshold value ThL1 of the disconnection diagnosis held in the reference value storage circuit 278 are compared by the digital comparator 270. If the measured value held in the register CELL1 is smaller than the disconnection diagnosis threshold value ThL1, the diagnosis flag of the flag storage circuit 284 is set to “1” because an abnormality due to disconnection has occurred. The diagnosis flag set is immediately transmitted to the battery controller 20, as already described with reference to FIG. The basic operation of FIG. 31 is as already described with reference to FIG.

  If there is no abnormality such as disconnection, the terminal voltage of the battery cell BC1 measured at the stage STGCV1 shows a normal value, and the abnormality detection is not performed even by the diagnosis of the digital comparator 270. In the m cycle of FIG. 30, the terminal voltage of only the odd-numbered battery cells is measured and diagnosed. Next to the battery cell BC1, measurement of the terminal voltage of the battery cell BC3 and disconnection diagnosis are performed. At stage STGCV2, the balancing switch 129C of the battery cell BC3 is once closed, and then the balancing switch 129C is opened at the stage STGCV3 to measure the terminal voltage of the battery cell BC3. Further, the disconnection diagnosis is performed by the digital comparator 270 of FIG. 31 in the same manner as described above. The balancing switches 129B and 129D adjacent to the balancing switch 129C are maintained in the open state as shown in FIG. 30 in order to improve the detection accuracy and diagnostic accuracy of the battery cell BC3 in the stage STGCV3.

  Similarly, in stage STGCV5, balancing switches 129D and 129F are held in an open state in order to measure and diagnose the terminal voltage of battery cell BC3. The measurement and diagnosis are performed for odd-numbered battery cells BC1, BC3, and BC5. Similarly, measurement and diagnosis of the battery cells BC2, BC4, and BC6 are performed at the following m + 1 cycle. In this way, in FIG. 30, the odd-numbered battery cells and the even-numbered battery cells are measured and diagnosed at different stages.

  In the measurement and diagnosis related to the battery cell BC1 at the stage STGCV1 of the integrated circuit 3B, it is necessary to keep the balancing switch 129F of the previous integrated circuit 3A open. Therefore, a synchronization signal is sent from the integrated circuit 3A to the integrated circuit 3B, and the integrated circuit 3B generates a stage in synchronization with the synchronization signal of the integrated circuit 3A. In this embodiment, the generation of the first stage signal STGCal is started in response to the synchronization signal from the integrated circuit 3A.

  In this way, in the adjacent integrated circuits, a synchronization signal is sent to the other integrated circuit at a predetermined cycle of one integrated circuit, and the other integrated circuit starts a predetermined stage signal in response to the synchronization signal. The balancing switch 129A of the battery cell BC1 of the other integrated circuit 3B is held open during the measurement period of the battery cell BC6 of the other integrated circuit 3A, that is, the battery cell BC6 of the integrated circuit 3A. Further, during the measurement period of the battery cell BC1 of the other integrated circuit 3B, the balancing switch 129F of the battery cell BC6 on the other side of the one integrated circuit 3A is held open.

  In FIG. 30, the same applies to the integrated circuits 3B and 3C, and a synchronization signal is sent from the integrated circuit 3B to the integrated circuit 3C at a specific stage of the integrated circuit 3B. By doing in this way, the balancing switch 129 of the battery cell on both sides connected in series with the battery cell to be measured is maintained open, and accurate measurement and accurate diagnosis are realized.

  The circuit shown in FIG. 32 is provided with a transmission path 56 for sending a synchronization signal to the circuit of FIG. Other circuits and operations have already been described with reference to FIG. As shown in FIG. 38, the synchronization signal is transmitted from the synchronization signal output terminal SYNO of the integrated circuit 3A to the synchronization signal input terminal SYNI of the integrated circuit 3B. Similarly, the synchronization signal is transmitted from the synchronization signal output terminal SYNO of the integrated circuit 3M-1 to the synchronization signal input terminal SYNI of the integrated circuit 3M, and the integrated circuit from the synchronization signal output terminal SYNO of the integrated circuit 3N-1 A synchronization signal is transmitted to the 3N synchronization signal input terminal SYNI.

  In FIG. 30 and FIG. 32, the synchronization signal is transmitted from the integrated circuit having a high potential to the adjacent integrated circuit having a low potential. There is no problem even if you do it. What is important is that stage signals in adjacent integrated circuits are generated in synchronization with each other.

  As described above, the disconnection diagnosis can be easily performed by using the balancing switch 129.

  As described above, in this embodiment, abnormality in the integrated circuit, that is, diagnosis of the multiplexer 120, differential amplifier 262, AD converter 122A, digital comparison circuit 270, etc. in the integrated circuit is performed. As a result, the reliability of the integrated circuit in the cell controller 80 can be improved, whereby the reliability of the battery system can be further improved.

  Moreover, in the conventional battery system described in patent document 1, since the overcharge and overdischarge of a battery cell are diagnosed, the state of a battery cell can be appropriately maintained based on the result. However, if the reliability of the terminal voltage measured when diagnosing overcharge or overdischarge is low, that is, if an abnormality occurs in the terminal voltage measurement system, the reliability of the overcharge or overdischarge diagnosis itself is not reliable. There is a risk of a fall and misjudgment. However, in the battery system of the present embodiment, since the integrated circuit self-diagnose the selection operation of the multiplexer 120 that selects the terminal voltage, the measurement operation itself can be diagnosed, and the measured value measured normally. Based on the above, overcharge diagnosis and overdischarge diagnosis can be performed.

  Furthermore, by performing an operation diagnosis of the multiplexer 120 and the like in synchronization with the measurement of the terminal voltage, it is possible to reliably grasp the malfunction of the multiplexer 120 during measurement, and the reliability of the battery system is further increased.

  In addition, by transmitting the abnormality diagnosis result from the integrated circuit to the battery controller 20 via the transmission path 54, it is possible to quickly and accurately cope with the abnormality of the integrated circuit. In particular, a transmission path 54 for transmitting an abnormal signal is provided separately from the transmission path 52 for transmitting the measurement value, and a signal indicating abnormality / normality is constantly transmitted to the battery controller 20, so that the state of the integrated circuit can be always considered. Therefore, it is possible to respond to the abnormality of the integrated circuit more quickly.

  Each of the embodiments described above may be used alone or in combination. This is because the effects of the respective embodiments can be achieved independently or synergistically. In addition, the present invention is not limited to the above embodiment as long as the characteristics of the present invention are not impaired.

  BC1 to BC12: Battery cell, R, R1 to R6: Resistor, 3A, 3B, 4A, 4B, 5A, 5B ... Integrated circuit, Si ... Current sensor, Vd ... Voltmeter, 9 ... Battery part 20 …… Battery controller, 32 …… Detection harness, 50 …… Communication harness, 52 …… Transmission path (serial communication), 54 …… Transmission path (flag communication), 56 …… Transmission path (Wake UP), 66 ...... Center pole, 80 ... Self-controller, 81 ... Positive high voltage cable, 82 ... Negative high voltage cable, 92 ... Comparison circuit, 93 ... Changeover switch, 116 ... Input circuit, 118,120 ... Multiplexer , 121... Power supply circuit, 122... Voltage detection circuit, 122 A... Analog-digital converter, 123... IC control circuit, 124. , 127 ..communication circuit, 129A-F... Balancing switch, 130... Potential conversion circuit, 131 .. abnormality determination circuit, 132 .. discharge control circuit, 133... Switch drive circuit, 160, 2596. Circuit, 164... Judgment circuit, 168... Abnormal flag memory circuit, 220... Inverter device, 222... MCU, 224... Driver circuit, 226. 254... Start-up circuit, 256... First stage counter, 257... Decoder, 258... Second stage counter, 2582 ... Register, 2584, 2586 ... Logic circuit, 259 ... Decoder, 260. Table, 262 ... Differential amplifier, 263 ... Averaging control circuit, 264 ... Averaging circuit, 270 ... Digital comparator, 272, 276... Digital multiplexer, 274, 274A... Current value storage circuit, 275... Initial value storage circuit, 275A... Data storage circuit at abnormality, 278, 278A. ~ 2861 …… Measurement control circuit, 284 …… Flag storage circuit, 286 …… Selection circuit, 292 …… Communication command, 294 …… Data bus, 302 …… Transmission register, 322 …… Reception register, 344 …… Command processing Circuit, 345 ... Command decoding circuit, 346 ... Arithmetic circuit, 2592, 2594 ... Selection circuit, Z1 to Z4 ... Zener element, S1 to S4, SB1, SB2, SC1, SD1 ... Switch

Claims (6)

A battery module having a plurality of battery cells electrically connected in series;
A voltage measuring circuit for measuring a terminal voltage of each of the plurality of battery cells;
A diagnostic circuit for diagnosing an abnormality of the voltage measurement circuit,
The voltage measuring circuit is
A selection circuit for selecting and outputting the terminal voltage of the battery cell to be measured from the terminal voltages of the plurality of battery cells;
A pull-up circuit that pulls up the potential of the output terminal of the selection circuit to a higher potential side; and
A pull-down circuit that pulls down the potential of the output terminal of the selection circuit to a lower potential side than that,
The diagnostic circuit includes:
When all of the plurality of switches constituting the selection circuit are in an open state, the relationship between the voltage measured by the voltage measurement circuit in a state where the potential of the output terminal of the selection circuit is pulled up or pulled down, and the threshold value is Diagnosing whether or not all of the plurality of switches constituting the selection circuit are in an open state based on whether or not there is a relationship when the plurality of switches constituting the selection circuit are all in an open state,
After this diagnosis, when a specific switch for selecting a battery cell to be measured is closed among a plurality of switches constituting the selection circuit, the potential of the output terminal of the selection circuit is pulled up or pulled down. The battery cell to be measured is selected by the specific switch based on whether the relationship between the voltage measured by the voltage measurement circuit in the state and the threshold is the relationship when the specific switch is closed. Diagnose whether or not
A battery system characterized by that. The battery system according to claim 1,
The pull-up circuit and the pull-down circuit operate corresponding to a measurement period of terminal voltages of the plurality of battery cells by the voltage measurement circuit.
A battery system characterized by that. The battery system according to claim 1 or 2,
The pull-up circuit and the pull-down circuit are respectively provided corresponding to the two output terminals of the selection circuit.
A battery system characterized by that. A voltage measuring circuit that measures the terminal voltage of each of a plurality of battery cells electrically connected in series;
A diagnostic circuit for diagnosing an abnormality of the voltage measurement circuit,
The voltage measuring circuit is
A selection circuit for selecting and outputting the terminal voltage of the battery cell to be measured from the terminal voltages of the plurality of battery cells;
A pull-up circuit that pulls up the potential of the output terminal of the selection circuit to a higher potential side; and
A pull-down circuit that pulls down the potential of the output terminal of the selection circuit to a lower potential side than that,
The diagnostic circuit includes:
When all of the plurality of switches constituting the selection circuit are in an open state, the relationship between the voltage measured by the voltage measurement circuit in a state where the potential of the output terminal of the selection circuit is pulled up or pulled down, and the threshold value is Diagnosing whether or not all of the plurality of switches constituting the selection circuit are in an open state based on whether or not there is a relationship when the plurality of switches constituting the selection circuit are all in an open state,
After this diagnosis, when a specific switch for selecting a battery cell to be measured is closed among a plurality of switches constituting the selection circuit, the potential of the output terminal of the selection circuit is pulled up or pulled down. The battery cell to be measured is selected by the specific switch based on whether the relationship between the voltage measured by the voltage measurement circuit in the state and the threshold is the relationship when the specific switch is closed. Diagnose whether or not
A battery monitoring device. The battery monitoring device according to claim 4,
The pull-up circuit and the pull-down circuit operate corresponding to a measurement period of terminal voltages of the plurality of battery cells by the voltage measurement circuit.
A battery monitoring device. The battery monitoring device according to claim 4 or 5,
The pull-up circuit and the pull-down circuit are respectively provided corresponding to the two output terminals of the selection circuit.
A battery monitoring device.

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