JP6287218B2 - Anomaly detection device - Google Patents

Description

  The present invention relates to an abnormality detection apparatus for a system in which a control board and a plurality of detection boards are daisy chain connected.

  2. Description of the Related Art In recent years, for the purpose of improving ease of assembly in a vehicle, simplifying wiring, and the like, circuit boards mounted on a vehicle are divided and connected to each other with a harness (for example, Patent Document 1). reference).

  In Patent Document 1, an output unit of a first control unit including a control unit and an A / D conversion circuit of a second control unit are connected by a harness. In Patent Document 1, voltage dividing circuits that use different voltages to be input to the A / D conversion circuit according to the type of abnormality are installed in both control units and input to the A / D conversion circuit. Based on the voltage, the disconnection abnormality of the harness, the short circuit abnormality of the harness, and the system abnormality are determined.

JP 2001-133502 A

  It is also conceivable to divide the circuit board into one control board and a plurality of slave boards (detection boards) and to daisy chain each board. In the case where a plurality of slave boards are connected in a daisy chain, it is possible to detect a disconnection abnormality between a plurality of slave boards by applying Patent Document 1 that is intended for detection of a disconnection between two divided boards. Can not.

  In view of the above circumstances, it is a primary object of the present invention to provide an abnormality detection apparatus that can detect and detect an abnormality detected by a detection board and a disconnection abnormality between each board connected in a daisy chain. .

  In order to solve the above-mentioned problem, the present invention is an abnormality detection device, comprising an A / D conversion circuit, a first voltage source, a second voltage source having a voltage different from that of the first voltage source, and the first voltage. A control board on which a first resistor connected in series between the power source and the input part of the A / D converter circuit is mounted, a detection circuit for detecting an abnormality of the electric unit, and the abnormality by the detection circuit A plurality of detection boards each mounted with a first switch that is closed when the first switch is detected; and a second resistor connected in parallel to the first switch; and the plurality of detections One end of the second resistor mounted on the first detection board is connected between the first detection board and the control board among the first detection board and the input part of the A / D conversion circuit. And a first harness for connecting the other end of the second resistor to the second voltage source; A second harness for connecting the second resistors respectively mounted on the detection substrates adjacent to each other between the detection substrates adjacent to each other in order from the first detection substrate; Based on the voltage value acquired by the A / D conversion circuit, the abnormality of the electric unit, the disconnection of the first harness, the disconnection of the second harness, and the disconnection location thereof are determined and detected.

  According to the present invention, the second resistor mounted on each of the plurality of detection boards is connected in parallel to the downstream side by the second harness. Furthermore, the first switch mounted on each of the plurality of detection boards is connected in parallel to the second resistor connected in parallel downstream. Therefore, when an abnormality of the electric unit is detected by the detection circuit mounted on at least one detection board and the first switch is closed, both ends of all the second resistors connected in parallel are short-circuited.

  A plurality of second resistors connected in parallel to each other and the first resistor are connected in series between the second voltage source and the first voltage source by the first harness. And the voltage of the connection point of the some 2nd resistance connected in parallel downstream and the 1st resistance is inputted into an A / D conversion circuit.

  Therefore, when normal, that is, when no abnormality is detected by all the detection circuits and the first harness and the second harness are not disconnected, the voltage difference between the first voltage source and the second voltage source is set to the downstream side. A voltage divided by the plurality of second resistors connected in parallel with each other and the first resistor is input to the A / D conversion circuit. In addition, when the second harness is disconnected, the number of second resistors connected in parallel to the downstream side changes according to the disconnected portion. Therefore, the voltage input to the A / D conversion circuit varies depending on the location where the second harness is disconnected.

  When the first harness is disconnected, the voltage of the first voltage source is input to the A / D conversion circuit. Further, when an abnormality is detected by at least one detection circuit, both ends of all the second resistors connected in parallel downstream are short-circuited, and the A / D conversion circuit includes a voltage of the second voltage source. Is entered. That is, different voltages are input to the A / D conversion circuit according to the disconnection location of the second harness when the electrical unit is normal, when the electrical unit is abnormal, when the first harness is disconnected.

  Therefore, based on the voltage value acquired by the A / D conversion circuit, the abnormality of the electric unit, the disconnection of the first harness, the disconnection of the second harness, and the disconnection location thereof can be determined and detected. The first voltage source or the second voltage source includes ground.

The figure which shows the structure of the abnormality detection apparatus which concerns on this embodiment. The figure which shows the equivalent circuit at the time of normal in this embodiment. The figure which shows the equivalent circuit at the time of the harness disconnection between the control board in this embodiment, and a detection board. The figure which shows the equivalent circuit at the time of the harness disconnection between the detection boards in this embodiment. The table | surface which shows a response | compatibility with the time of the time of normality in this embodiment, and various abnormality occurrence, and an input voltage. The figure which shows the structure of the abnormality detection apparatus of a reference example. The figure which shows the equivalent circuit at the time of normal in a reference example. The figure which shows the equivalent circuit at the time of the abnormality detection in a reference example, and the time of harness disconnection. The table | surface which shows a response | compatibility with the time of normal and various abnormality generation | occurrence | production in a reference example, and input voltage.

  Hereinafter, an embodiment in which an abnormality detection device is embodied will be described with reference to the drawings. The abnormality detection apparatus according to the present embodiment is assumed to be mounted on a vehicle. First, the configuration of the abnormality detection apparatus according to the present embodiment will be described with reference to FIG. The abnormality detection apparatus according to the present embodiment includes N detection boards 10 (# 1) to 10 (#N) that detect abnormalities in the blocks 61 (# 1) to 61 (#N) of the assembled battery 60, and a control. A substrate 30 is provided.

  The assembled battery 60 is a storage battery configured by connecting a plurality of battery cells in series with each other, and is divided into N blocks 61 (# 1) to 61 (#N) (electrical units). The assembled battery 60 supplies DC power to the inverter 70 and also receives DC power from the inverter 70 via the relay SW2 (second switch). The relay SW2 is a switch that opens and closes the connection between the assembled battery 60 and the inverter 70, driven by a relay drive circuit 31 described later. When relay SW2 is closed, assembled battery 60 and inverter 70 are connected, and when relay SW2 is opened, assembled battery 60 and inverter 70 are disconnected.

  The inverter 70 (electrical device) converts the DC power of the assembled battery 60 into AC power, supplies the AC power to the motor generator 80, and operates the motor generator 80 as a motor. Inverter 70 operates motor generator 80 as a generator, converts AC power generated by motor generator 80 into DC power, supplies the battery pack 60, and charges battery pack 60. The motor generator 80 operates as a motor that generates traveling power of the vehicle and also operates as a generator that supplies electric power to the assembled battery 60.

  Each of the detection boards 10 (# 1) to 10 (#N) (N is an integer of 2 or more) includes an abnormality detection circuit 21 (detection circuit) and a relay SW1 (first switch). The abnormality detection circuit 21 mounted on the detection boards 10 (# 1) to 10 (#N) detects abnormalities in the blocks 61 (# 1) to 61 (#N) of the assembled battery 60, respectively. Specifically, each abnormality detection circuit 21 detects an overvoltage state of battery cells included in the corresponding block 61 as an abnormality. The relay SW1 is a switch that is opened and closed according to whether or not an abnormality is detected by the abnormality detection circuit 21.

  The control board 30 includes a voltage source Vc (first voltage source) having a voltage of 5 V, a ground Vd (second voltage source), a resistor R1 (first resistor), a relay drive circuit 31 (drive circuit), and a microcomputer 32. The relay drive circuit 31 opens and closes the relay SW2 according to the input voltage. The microcomputer 32 is configured as a computer including a CPU, a ROM, a RAM, an I / O, a data input unit DI, a bus line connecting these, and the like. The resistor R1 is connected in series between the voltage source Vc and the input part of the relay drive circuit 31, and is connected in series between the voltage source Vc and the input part of the microcomputer 32. That is, the resistor R1 is connected in series between the connection point between the input unit of the relay drive circuit 31 and the input unit of the microcomputer 32 and the voltage source Vc. The voltage of the voltage source Vc is referred to as voltage Vc, and the voltage of the ground Vd is referred to as voltage Vd.

  Next, a method of daisy chain connecting the N detection boards 10 (# 1) to 10 (#N) and the control board 30 will be described. As a method of daisy chain connecting the N detection boards 10 (# 1) to 10 (#N) and the control board 30, a connection method as shown in the reference example of FIG. 6 can be considered. Hereinafter, the abnormality detection apparatus of the reference example shown in FIG. 6 will be described.

  In the abnormality detection apparatus of the reference example shown in FIG. 6, N detection boards 110 (# 1) to 110 (#N) and the control board 130 are daisy chain connected by harnesses 140, 150, and 160. Specifically, between the detection board 110 (# 1) and the control board 130, one end of the relay SW 11 mounted on the detection board 110 (# 1), the input unit of the relay drive circuit 131, and the microcomputer 132 are connected by the harness 140. Connect to the input section.

  Furthermore, between the detection board 110 (# 1) and the detection board 110 (# 2), the harness 150 is connected to the harness 140 among both ends of the relay SW11 mounted on the detection board 110 (# 1). One end of the relay SW11 mounted on the detection board 110 (# 2) is connected. And relay SW11 is connected in series by the harness 150 between the adjacent detection boards 110. FIG.

  Further, between the detection board 110 (#N) and the control board 130, one end of the relay SW11 mounted on the detection board 110 (#N) by the harness 160 that is not connected to the harness 150, Connect to ground Vd.

  In the abnormality detection device of the reference example, the abnormality detection circuit 121 mounted on each detection board 110 turns off the relay SW11 when an overvoltage is detected, and turns on the relay SW11 when no overvoltage is detected. This is a circuit to be closed. The relay drive circuit 131 mounted on the control board 130 is a circuit that turns off the relay SW12 when a high level voltage is input, and turns on or closes the relay SW12 when a low level voltage is input. It is.

  As described above, in the abnormality detection device of the reference example connected in the daisy chain, when no overvoltage is detected by each abnormality detection circuit 121 and when the harnesses 140, 150, 160 are not disconnected, each detection board All the relays SW11 mounted on 110 are closed. Therefore, in the abnormality detection device of the reference example, the voltage V1 input to the relay drive circuit 131 and the microcomputer 132 in the normal state can be expressed by the equivalent circuit shown in FIG. 7, and the voltage V1 becomes the voltage Vd, that is, 0V.

  Further, in the abnormality detection device of the reference example, when abnormality is detected by at least one of the abnormality detection circuits 121 or when any of the harnesses 140, 150, 160 is disconnected, the input of the relay drive circuit 131 is performed. And the input part of the microcomputer 132 are open. Therefore, in the abnormality detection device of the reference example, when any abnormality occurs, the voltage V1 input to the relay drive circuit 131 and the microcomputer 132 can be expressed by the equivalent circuit shown in FIG. 8, and the voltage V1 is the voltage Vc. That is, it becomes 5V.

  Therefore, in the abnormality detection device of the reference example, as shown in the table of FIG. 9, the voltage V <b> 1 input to the microcomputer 132 is different between the normal time and the abnormality occurrence time. However, regardless of the type of abnormality, the voltage V1 is the same regardless of what kind of abnormality occurs. That is, even when the abnormality detection circuit 121 detects an overvoltage or when the harnesses 140, 150, and 160 are disconnected, the voltage V1 is the same voltage. Therefore, the microcomputer 132 can discriminate between the normal time and the abnormality occurrence based on the input voltage V1, but the harness 140 determines whether the abnormality that has occurred is an overvoltage of the cell battery included in the assembled battery 60. , 150, 160 cannot be determined. Further, the microcomputer 132 cannot determine which board is disconnected.

  Further, when an overvoltage of a cell battery included in the assembled battery 60 is detected, it is necessary to disconnect the assembled battery 60 and the inverter 70 so that the cell battery included in the assembled battery 60 is not charged any more. . On the other hand, when the harnesses 140, 150, 160 are disconnected, the assembled battery 60 and the inverter 70 do not need to be disconnected. However, even when an overvoltage of the assembled battery 60 is detected or when the harnesses 140, 150, 160 are disconnected, the voltage V1 input to the relay drive circuit 131 is the same voltage. Therefore, not only when the overvoltage of the assembled battery 60 occurs but also when the harnesses 140, 150, 160 are disconnected, the relay SW12 is opened, and the assembled battery 60 and the inverter 70 are disconnected.

  Therefore, in the abnormality detection device according to the present embodiment, the voltage V1 input to the microcomputer 32 and the relay drive circuit 31 differs depending on the normal state, when the overvoltage is detected by the abnormality detection circuit 21, and according to the disconnection location of the harness. Daisy chain connection so that the voltage is the same.

  Specifically, as shown in FIG. 1, a resistor R2 (second resistor) connected in parallel to the relay SW1 is mounted on each detection board 10. Further, the control board 30 is equipped with an A / D conversion circuit 33 for converting an analog value into a digital value at the input section of the microcomputer 32. Then, between the detection board 10 (# 1) (first detection board) and the control board 30, the harness 40 (first harness) connects one end of the resistor R2 to the voltage source Vc of both ends of the resistor R1. Connected to one end not connected, the input part of the relay drive circuit 31, and the input part of the A / D conversion circuit 33. Further, the other end of the resistor R2 is connected to the ground Vd by the harness 40 between the detection board 10 (# 1) and the control board 30. That is, the input part of the A / D conversion circuit 33 and the input part of the relay drive circuit 31 are connected to one end of the resistor R2 mounted on the detection board 10 (# 1) not connected to the ground Vd. 40 are connected in parallel.

  In addition, the resistors R2 respectively mounted on the detection boards 10 adjacent to each other are connected in parallel to the downstream side by the harness 50 (second harness) between the detection boards 10 adjacent to each other sequentially from the detection board 10 (# 1). Connecting. That is, between the detection boards 10 adjacent to each other, one end of the resistor R2 mounted on the upstream detection board 10 close to the control board 30 and one end of the resistance R2 mounted on the downstream detection board 10 by the harness 50. And connect. Further, the harness 50 connects the other end of the resistor R2 mounted on the upstream detection board 10 to the other end of the resistor R2 mounted on the downstream detection board 10. In this manner, the resistor R2 mounted on the downstream detection board 10 is connected sequentially from the detection board 10 (# 1).

  In addition, the abnormality detection circuit 21 mounted on each detection board 10 turns on the relay SW1 when the overvoltage of the assembled battery 60 is detected, or turns off the relay SW1 when the overvoltage of the assembled battery 60 is not detected. This is a circuit to be opened. The relay drive circuit 31 mounted on the control board 30 is a circuit that turns off the relay SW2 on the condition that the voltage Vd is input. Specifically, the relay drive circuit 31 is a circuit that opens the relay SW2 on condition that a low-level voltage is input.

  In the abnormality detection device according to the present embodiment, when the overvoltage of the assembled battery 60 is not detected by each abnormality detection circuit 21 and when the harnesses 40 and 50 are not disconnected, they are mounted on each detection board 10. Relays SW1 are all opened. Therefore, in the abnormality detection difference according to the present embodiment, the voltage V1 input to the relay drive circuit 31 and the A / D conversion circuit 33 in the normal state can be represented by the equivalent circuit shown in FIG. Specifically, a voltage V1 = Vc × (R2 / N) / (R1 + R2 / N) obtained by dividing the voltage Vc by N resistors R2 connected in parallel with each other and the resistor R1 is the relay drive circuit 31 and Input to the A / D conversion circuit 33.

  In the abnormality detection device according to the present embodiment, when the overvoltage of the assembled battery 60 is detected by at least one abnormality detection circuit 21, the relay SW1 is closed in FIG. 2 and connected in parallel to each other. Both ends of the N resistors R2 are short-circuited. Therefore, when an overvoltage is detected by at least one abnormality detection circuit 21, the voltage V1 input to the relay drive circuit 31 and the A / D conversion circuit 33 becomes the voltage Vd, that is, 0V.

  In addition, when the harness 40 is disconnected between the detection board 10 (# 1) and the control board 30, the input portions of the relay drive circuit 31 and the A / D conversion circuit 33 are opened. Therefore, the voltage V1 input to the relay drive circuit 31 and the A / D conversion circuit 33 can be expressed by the equivalent circuit shown in FIG. 3, and the voltage V1 becomes the voltage Vc, that is, 5V.

  In addition, when the harness 50 is disconnected between the detection substrates 10 adjacent to each other, the resistors R2 mounted on the detection substrate 10 on the upstream side of the disconnected portion are connected in parallel to each other, but the disconnected portion The resistor R2 mounted on the detection board 10 on the downstream side is not connected in parallel. For example, when the harness 50 is disconnected between the detection board 10 (# 2) and the detection board 10 (# 3), the two resistors R2 are connected in parallel to each other. In this case, the voltage V1 input to the relay drive circuit 31 and the A / D conversion circuit 33 can be represented by the equivalent circuit shown in FIG. Therefore, in this case, a voltage V1 = Vc × (R2 / 2) / (R1 + R2 / 2) obtained by dividing the voltage Vc by the two resistors R2 connected in parallel with each other and the resistor R1 is the relay drive circuit. 31 and the A / D conversion circuit 33.

  When the harness 50 is disconnected between the detection board 10 (# α) and the detection board 10 (# α + 1), α resistors R2 are connected in parallel to each other. Therefore, in this case, the voltage V1 = Vc × (R2 / α) / (R1 + R2 / α) obtained by dividing the voltage Vc by α resistors R2 connected in parallel with each other and the resistor R1 is the relay drive circuit. 31 and the A / D conversion circuit 33.

  Therefore, in the abnormality detection device according to the present embodiment, as shown in the table of FIG. 5, the voltage V1 input to the A / D conversion circuit 33 is different between the normal time and the abnormality occurrence time, The voltage varies depending on the type. Specifically, the voltage V1 is different when the overvoltage of the assembled battery 60 is detected by the at least one abnormality detection circuit 21, when the harness 40 is disconnected, and when the harness 50 is disconnected. Furthermore, when the harness 50 is disconnected, the voltage V1 becomes a different voltage depending on the disconnection location, that is, what number of detection substrates 10 is disconnected.

  Therefore, the microcomputer 32 is converted into a digital value by the A / D conversion circuit 33, and based on the voltage value of the voltage V1, the overvoltage state of the assembled battery 60 (abnormality of the electric unit), the disconnection of the harness 40, and the disconnection of the harness 50 The disconnection portion is discriminated and detected.

  The relay drive circuit 31 compares the input voltage V1 with a threshold value and determines whether the input voltage V1 is a low level voltage or a high level voltage. For example, the relay drive circuit 31 determines a low level voltage when the voltage V1 is 1 V or less, and determines a high level voltage when the voltage V1 is 2.5 V or more. The voltage Vd is a voltage recognized as a low level voltage by the relay drive circuit 31, and the voltage Vc is a voltage recognized as a high level voltage by the relay drive circuit 31.

  Here, N, Vc, and so that the normal voltage V1 = (Vc−Vd) × (R2 / N) / (R1 + R2 / N) is in a range recognized by the relay drive circuit 31 as a high level voltage. Each value of Vd, R1, and R2 is set. Since the voltage V1 when the harness 50 is disconnected is a voltage of Vc to (Vc−Vd) × (R2 / 2) / (R1 + R2 / N), the voltage V1 when the harness 50 is disconnected is also determined by the relay drive circuit 31. Recognized as a high level voltage. For example, when the value of the resistor R2 is R2 = 4 × N × R1, the voltage V1 at the normal time is 4V, and the voltage V1 when the harness 50 is disconnected is a voltage between 5V and 4V.

  Therefore, as shown in the table of FIG. 5, only when the overvoltage of the assembled battery 60 is detected by the abnormality detection circuit 21, the voltage V1 is recognized as a low level voltage by the relay drive circuit 31, and the assembled battery 60 The inverter 70 is disconnected. During normal operation and when the harnesses 40 and 50 are disconnected, the relay drive circuit 31 recognizes the voltage V1 as a high level voltage, and the assembled battery 60 and the inverter 70 remain connected.

  The input part of the A / D conversion circuit 33 and the input part of the relay drive circuit 31 are connected in parallel to one end of the resistor R2 mounted on the detection board 10 (# 1), and the voltage V1 is A The signal is input to each of the / D conversion circuit 33 and the relay drive circuit 31. Therefore, based on the voltage value of the voltage V1 acquired by the A / D conversion circuit 33, the microcomputer 32 determines whether or not there is an abnormality and the type of abnormality, and the relay drive circuit 31 without using the microcomputer 32. The process of controlling the connection between the assembled battery 60 and the inverter 70 with a digital signal is performed separately.

  According to this embodiment described above, the following effects are obtained.

  In normal operation, the voltage V1 obtained by dividing the voltage difference between the voltage Vc (5V) and the voltage Vd (0V) by the N resistors R2 and the resistor R1 connected in parallel with each other is the A / D converter circuit. 33 is input. Further, when an overvoltage is detected by at least one abnormality detection circuit 21, both ends of all the resistors R <b> 2 connected in parallel with each other are short-circuited, and the voltage Vd is input to the A / D conversion circuit 33. .

  When the harness 40 is disconnected, the voltage Vc is input to the A / D conversion circuit 33. Further, when the harness 50 is disconnected, the resistors R2 mounted on the detection board 10 on the upstream side of the disconnected position are connected in parallel to each other, and the voltage V1 that differs depending on the disconnected position is A / D converted. Input to the circuit 33. Therefore, based on the voltage value acquired by the A / D conversion circuit 33, the abnormality of the assembled battery 60, the disconnection of the harness 40, the disconnection of the harness 50, and the disconnection location thereof can be determined and detected.

  Only when the voltage Vd, that is, the low-level voltage is input to the relay drive circuit 31, the connection between the assembled battery 60 and the inverter 70 is opened. Therefore, when the overvoltage state of the battery cell included in the assembled battery 60 is detected by the at least one abnormality detection circuit 21, the voltage Vd is input to the relay drive circuit 31, and the assembled battery 60 and the inverter 70 are disconnected. be able to. That is, the battery cell in an overvoltage state can be prevented from being charged any more.

  The relay drive circuit 31 can control the opening / closing of the connection between the assembled battery 60 and the inverter 70 with a digital signal based on whether or not the input voltage V1 is a low level voltage.

  The values of N, Vc, Vd, R1, and R2 are such that Vc and (Vc−Vd) × (R2 / N) / (R1 + R2 / N) are recognized as a high level voltage by the relay drive circuit 31. Is set. As a result, the assembled battery 60 and the inverter 70 can be connected in a normal state and when the harnesses 40 and 50 are disconnected. That is, when the harnesses 40 and 50 are disconnected, the disconnection of the harness 40, the disconnection of the harness 50, and the disconnection location thereof can be detected in a state where the assembled battery 60 and the inverter 70 are connected.

  The voltage V1 at the connection point between the resistor R1 and the resistor R2 is input to the A / D conversion circuit 33 and the relay drive circuit 31, respectively. Therefore, the battery pack 60 and the inverter 70 are acquired according to the process of acquiring the voltage value of the input voltage V1, determining the abnormality based on the acquired voltage value, and whether the input voltage V1 is a low level voltage. And the process of controlling the connection with the digital signal can be performed separately.

(Other embodiments)
The ground Vd may be a voltage source that is recognized as a low level voltage by the relay drive circuit 31.

  The microcomputer 32 and the relay drive circuit 31 are connected in series to one end of the resistor R2 mounted on the detection board 10 (# 1), and the voltage value acquired by the A / D conversion circuit 33 is the value of the voltage Vd. If there is, the relay drive circuit 31 may open the relay SW2.

  The voltage Vc may be a voltage recognized as a low level voltage by the relay drive circuit 31, and the voltage Vd may be a voltage recognized as a high level voltage by the relay drive circuit 31. In this case, the relay drive circuit 31 opens the relay SW2 on condition that the voltage V1 is a high level voltage. Moreover, when N, Vd, Vc, R1, and R2 are set so that (Vd−Vc) × R1 / (R1 + R2 / N) is recognized as a low level voltage, when the harnesses 40 and 50 are disconnected. Is recognized as a low level voltage by the relay drive circuit 31, and the relay SW2 is closed.

  -The abnormality detection device is not limited to the one installed in the vehicle. Further, the abnormality detection circuit 21 may detect an abnormality of an electric unit other than the assembled battery, for example, an actuator or a driving device for a liquid crystal display.

  DESCRIPTION OF SYMBOLS 10 ... Detection board, 21 ... Abnormality detection circuit, 30 ... Control board, 31 ... Relay drive circuit, 32 ... Microcomputer, 33 ... A / D conversion circuit, 40, 50 ... Harness, 61 ... Block, R1, R2 ... Resistance, SW1, SW2 ... Relay.

Claims (6)

An A / D conversion circuit (33), a first voltage source (Vc), a second voltage source (Vd) having a voltage different from that of the first voltage source, the first voltage source, and the A / D conversion circuit. A control board (30) on which a first resistor (R1) connected in series with the input unit is mounted;
A detection circuit (21) for detecting an abnormality of the electric unit (61), a first switch (SW1) that is closed when the abnormality is detected by the detection circuit, and the first switch A plurality of detection boards (10) each having a second resistor (R2) connected in parallel with each other;
One end of the second resistor mounted on the first detection board between the first detection board and the control board among the plurality of detection boards is connected to the first resistor and the A / D conversion circuit. A first harness (40) for connecting to the input unit and connecting the other end of the second resistor to the second voltage source;
A second harness (50) for connecting the second resistors respectively mounted on the detection boards adjacent to each other in parallel between the detection boards adjacent to each other in order from the first detection board; Prepared,
Based on the voltage value acquired by the A / D conversion circuit, the abnormality of the electric unit, the disconnection of the first harness, the disconnection of the second harness, and the disconnection location thereof are determined and detected. Anomaly detection device. A drive circuit (31) for driving a second switch (SW2) for opening and closing the connection between the electric unit and the electric device (70) is mounted on the control board,
The input portion of the drive circuit is connected to one end of the two ends of the second resistor mounted on the first detection board that is not connected to the second voltage source via the first harness. ,
The abnormality detection device according to claim 1, wherein the drive circuit opens the second switch on condition that a voltage of the second voltage source is input. The voltage of the second voltage source is a voltage recognized as a low level voltage by the driving circuit,
The abnormality detection device according to claim 2, wherein the driving circuit opens the second switch on condition that the low-level voltage is input. The number of detection substrates is N (an integer greater than or equal to 2), the voltage of the first voltage source is Vc, the voltage of the second voltage source is Vd, the first resistor is R1, and the second resistor is R2. When
N, Vc, Vd, R1 so that the voltage represented by Vc and (Vc−Vd) × (R2 / N) / (R1 + R2 / N) is in a range recognized as a high level voltage by the drive circuit. The abnormality detecting device according to claim 3, wherein each value of R2 and R2 is set.   The input part of the A / D conversion circuit and the input part of the drive circuit are connected to the one end of the second resistor mounted on the first detection board and not connected to the second voltage source. The abnormality detection device according to claim 3 or 4 connected in parallel via the first harness. The electric unit is one block obtained by dividing an assembled battery in which a plurality of battery cells are connected in series into a plurality of blocks (61),
The electrical device is a device that supplies power to the assembled battery,
The abnormality detection device according to claim 2, wherein the detection circuit mounted on each detection board detects an overvoltage state of a battery cell included in the corresponding block as an abnormality.

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