JP2017173071A - Cell voltage measuring device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cell voltage measuring device which can be simply configured at a low cost.SOLUTION: A cell voltage measuring device has a plurality of cell voltage measuring modules aligned and disposed so as to measure the voltage of one or a plurality of cells of a laminated battery 1; and an address applying device which applies consecutive addresses to the cell voltage measuring modules adjacent to each other, of the plurality of cell voltage measuring modules.SELECTED DRAWING: Figure 9

Description

  The present invention relates to a cell voltage measurement device.

  2. Description of the Related Art Conventionally, a cell voltage measurement device that measures the voltage of an electrochemical cell that constitutes a stacked battery such as a fuel cell is known. In particular, Patent Document 1 has a plurality of voltage measurement modules that measure the voltage of a group of cells arranged adjacent to each other, and measurement voltage data is obtained by a computer connected to the voltage measurement module via a wired communication bus. A voltage measuring device adapted to be acquired is described.

Special table 2014-534589 No.

  In the cell voltage measurement device of Patent Document 1, each voltage measurement module directly attached to a cell is connected by a wired communication bus, so that the configuration can be simplified by relatively reducing the number of harnesses. In this cell voltage measurement device, in order to identify each voltage measurement module, it is necessary to assign a different address to each voltage measurement module in advance.

  However, in this case, it is necessary to incorporate in each module a circuit that has a different address and is not mutually substitutable, which increases manufacturing costs. Also, when assembling the voltage measurement module to the cell, it is necessary to perform the operation while confirming the module having the address corresponding to the attachment position, and therefore the assembly operation is complicated.

  In view of the above circumstances, an object of the present invention is to provide a cell voltage measuring device that can be easily configured at low cost.

  According to an aspect of the present invention, there is provided a cell voltage measurement device having a plurality of cell voltage measurement modules arranged side by side so as to measure the voltage of one or a plurality of cells of a laminated battery. The cell voltage measuring device includes an address assigning device that assigns continuous addresses to adjacent cell voltage measuring modules among the plurality of cell voltage measuring modules.

  According to the present invention, even if the cell voltage measurement module attached arbitrarily is unknown in the initial state, the address assigning device continuously addresses the adjacent cell voltage measurement modules when the cell voltage measurement modules are assembled. Can be granted. Therefore, even if each cell voltage measurement module has the same specification, an address can be given to each cell voltage measurement module, so that the manufacturing cost of the apparatus can be suppressed and the assembly work is prevented from becoming complicated. .

FIG. 1 is a diagram illustrating the overall configuration of the cell voltage measurement device according to the first embodiment. FIG. 2A is a diagram illustrating a state in which each cell voltage measurement module is arranged. FIG. 2B is a diagram illustrating the configuration of one cell voltage measurement module. FIG. 3 is a diagram illustrating the circuit configuration of each cell voltage measurement module and the master module. FIG. 4 is a diagram illustrating a detailed circuit configuration of the cell voltage measurement module. FIG. 5 is a diagram illustrating the configuration of the module microcomputer of the cell voltage measurement module. FIG. 6 is a diagram for explaining the configuration of the voltage insulation part of the cell voltage measurement module. FIG. 7 is a diagram illustrating the circuit configuration of the master module. FIG. 8A is a flowchart for explaining the processing flow of the master module in the address setting mode. FIG. 8B is a flowchart for explaining the process flow of the cell voltage measurement module in the address setting mode. FIG. 9 is a timing chart for explaining the flow of processing in the address setting mode. FIG. 10A is a flowchart for explaining the flow of processing in the master module in the normal measurement mode. FIG. 10B is a flowchart illustrating a process flow in the cell voltage measurement module according to the normal measurement mode. FIG. 11 is a timing chart for explaining the flow of processing in the normal measurement mode. FIG. 12 is a timing chart for explaining the flow of processing in the cell abnormality diagnosis mode. FIG. 13 is a diagram illustrating the circuit configuration of each cell voltage measurement module and master module in the cell voltage measurement device according to the second embodiment. FIG. 14 is a diagram illustrating the circuit configuration of the master module. FIG. 15 is a flowchart for explaining the flow of processing of the cell voltage measurement module in the address setting mode. FIG. 16 is a timing chart for explaining the flow of processing in the address setting mode. FIG. 17 is a diagram illustrating the configuration of the cell voltage measurement device according to the third embodiment. FIG. 18 is a diagram illustrating the circuit configuration of the master module. FIG. 19 is a diagram illustrating the configuration of the cell voltage measurement device according to the fourth embodiment. FIG. 20 is a diagram illustrating the configuration of the cell voltage measurement device according to the fifth embodiment. FIG. 21A is a diagram illustrating a modification of the transmission unit and the reception unit of the cell voltage measurement module. FIG. 21B is a diagram illustrating a modification of the transmission unit and the reception unit of the cell voltage measurement module. FIG. 22A is a diagram illustrating a modification of the transmission unit and the reception unit of the cell voltage measurement module. FIG. 22B is a diagram illustrating a modification of the transmission unit and the reception unit of the cell voltage measurement module. FIG. 23A is a diagram illustrating a modification of the transmission unit and the reception unit of the cell voltage measurement module. FIG. 23B is a diagram illustrating a modification of the transmission unit and the reception unit of the cell voltage measurement module.

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

(First embodiment)
FIG. 1 is a diagram for explaining the configuration of a cell voltage measuring apparatus 100 according to the first embodiment. The cell voltage measuring device 100 is used as a stacked battery in which a plurality of electrochemical cells are stacked, for example, in a fuel cell stack in which a plurality of fuel cells are stacked. Here, the cell voltage measuring apparatus 100 includes a cell voltage measuring module MO and a power / communication bus line 12.

  The cell voltage measurement module MO includes a cell voltage measurement module substrate 20, a module microcomputer 22 as an address assignment device, a transmission unit 24 and a reception unit 26 as inter-module communication means constituting the address assignment device, and a stacked battery 200. The CVM (Cell Voltage Monitoring Connector) connector 28 connected to the tab 204 of each cell E, the bus connector pin 30 connected to the power / communication bus line 12, and the CVM connector 28 and the bus connector pin 30 are exposed to the outside. However, it has a cell voltage measurement module housing 32 that accommodates the cell voltage measurement module substrate 20.

  The module microcomputer 22 is provided on the cell voltage measurement module substrate 20 and AD-converts the detected voltage of each cell E of the stacked battery 200 by giving an address to the cell voltage measurement module MO and an address assignment device for giving a predetermined voltage. It has a function as a voltage measurement value calculation processing circuit for calculating a measurement value.

  The transmission unit 24 and the reception unit 26 are connected to the module microcomputer 22 in the cell voltage measurement module substrate 20. The configurations of the module microcomputer 22, the transmission unit 24, and the reception unit 26 will be described in detail later.

  The cell voltage measurement module substrate 20 is provided with a plurality of CVM connectors 28 (eight in this embodiment). As indicated by an arrow A in FIG. 1, each of these CVM connectors 28 is attached so as to clamp the tab 204 of each of the cells E1 to E8, and the voltage between adjacent terminals for each of the cells E1 to E8 is detected.

  The CVM connector 28 is connected to the module microcomputer 22 on the cell voltage measurement module substrate 20. Therefore, the detected inter-terminal voltage is input to the module microcomputer 22 via the CVM connector 28.

  Further, the cell voltage measurement module substrate 20 is provided with a plurality of bus connector pins 30 (six in this embodiment). Each bus connector pin 30 is connected to the module microcomputer 22 and clamped to the bus connector socket 34. Therefore, the cell voltage measuring module MO is connected to the power / communication bus line 12 via the bus connector pin 30 and the bus connector socket 34.

  The power / communication bus line 12 includes, for example, a plurality of power supply lines (for example, two lines) that supply power from a battery such as a lithium ion battery (12V power supply) to the cell voltage measurement module MO, a cell voltage measurement module MO, and And a plurality of signal lines (for example, three lines) for transmitting / receiving signals to / from the master module using the I2C method. The power / communication bus line 12 configures the power supply line and the signal line on a substrate such as a flexible printed wiring board. The power / communication bus line 12 may be configured as a flat cable.

  Therefore, the cell voltage measurement module MO can send and receive a signal in the serial system with the power / communication bus line 12 via the bus connector pin 30 and the bus connector socket 34 and can receive power supply. It is.

  Further, a connection portion between the cell voltage measurement module MO and the power / communication bus line 12, that is, a connection portion between the bus connector pin 30 and the bus connector socket 34 is covered and protected by the cell voltage measurement module cover 14.

  FIG. 2A is a diagram illustrating a state in which each cell voltage measurement module MO is arranged. FIG. 2B is a diagram illustrating the configuration of one cell voltage measurement module MO.

  As shown in FIG. 2A, in the cell voltage measurement device of the present embodiment, cell voltage measurement modules MO having the same configuration are arranged side by side in the stacking direction of the cells E of the stacked battery 200. In FIG. 2A, the symbols MO1, MO2,... MOn are attached in order from the top module, and according to this, the symbols of the module microcomputer, the transmitter, and the receiver are 22-1 to 22-. n, 24-1 to 24-n, and 26-1 to 26-n are attached.

  In the following description, k (k = 1 to n) is adopted as a general number to represent the cell voltage measurement modules MOk, unless otherwise specified, in describing the cell voltage measurement modules MO1 to MOn. That is, the description regarding the cell voltage measurement module MOk can be arbitrarily applied to each of the cell voltage measurement modules MO1 to MOn.

  The cell voltage measurement module MOk includes a module microcomputer 22-k, a transmission unit 24-k, and a reception unit 26-k. The transmission unit 24-k transmits a signal L to the cell voltage measurement module next to the cell voltage measurement module MOk based on a command from the module microcomputer 22-k. In the present embodiment, the transmission unit 24-k is configured as a light emitting diode, and the signal L is a light emission signal.

  The receiving unit 26-k receives a signal from the transmitting unit 24- (k-1) of the previous cell voltage measurement module MO (k-1) and outputs the received signal to the module microcomputer 22. In the present embodiment, the receiving unit 26-k includes a light receiving element such as a phototransistor that receives light from the light emitting diode. That is, a photocoupler is configured by the transmission unit 24- (k-1) of the previous cell voltage measurement module MO (k-1) and the reception unit 26-k of the cell voltage measurement module MOk.

  This enables mutual communication between adjacent cell voltage measurement modules MOk, k + 1. More specifically, the reception unit 26-k of the cell voltage measurement module MOk receives a signal from the transmission unit 24- (k-1) of the previous cell voltage measurement module MO (k-1), The reception is detected by the module microcomputer 22-k. The module microcomputer 22-k instructs the transmission unit 24-k to transmit a signal, and when the signal is transmitted from the transmission unit 24-k, the reception unit 26- (k + 1) of the next cell voltage measurement module MO (k + 1). ).

  By repeating such an intercommunication process, signals can be transmitted and received between all the cell voltage measurement modules MO1 to MOn. In such an intercommunication process, there is no cell voltage measurement module immediately before the first cell voltage measurement module MO1, and therefore no signal is received by the receiving unit 26-1 of the cell voltage measurement module MO1.

  Therefore, when executing the above-mentioned mutual communication process, in order to transmit a signal from the transmission unit 24-1 of the leading cell voltage measurement module MO1, a command signal that becomes a trigger in addition to receiving the signal by the reception unit 26-1 To the module microcomputer 22-1. This command signal is given by a master module described later. Details of this processing will be described later.

  FIG. 3 is a diagram for explaining circuit configurations of the cell voltage measurement modules MO1 to MOn and the master module.

  As shown in the figure, the cell voltage measurement module MOk has input ports CV1 to CV8 that receive the voltage signals between the terminals of the eight cells E1-k to E8-k, respectively. In particular, in the present embodiment, the cell voltage measurement module MOk receives the voltage signal from the cell E8-k on the most positive pole side in the input port CV8 among the eight cells E1-k to E8-k, and receives CV7, It is configured to receive a voltage signal on the minus pole side in the order of CV6,... CV1.

  Furthermore, the other end of the cell voltage measurement module MOk is connected to the power / communication bus line 12 by the bus connector pin 30 (34) to which the bus connector pin 30 and the bus connector socket 34 are connected as described above. . The cell voltage measurement module MOk includes three signal lines (module connection line 12a, synchronization signal bus line 12b, and data bus line 12c) constituting the bus connector pin 30 (34), and two power supply lines (power bus). The line 12d and the GND bus line 12e) have six ports CVu, CLK, DATA, VDD, GND, and CV0 for inputting and outputting signals and power, respectively.

  The port CVu of the cell voltage measurement module MOk transmits the voltage of the cell E8-k detected by the cell voltage measurement module MOk and input from the port CV8 to the next cell voltage measurement module MOk + 1 via the module connection line 12a. Terminal. The port CV0 of the cell voltage measurement module MOk receives the voltage of the cell E8- (k-1) detected by the previous cell voltage measurement module MO (k-1) via the module connection line 12a. It is a terminal to do. Note that the voltage at the minus terminal (anode terminal) of the laminated battery 200 is input to CV0 of the leading cell voltage measurement module MO1.

  Note that the voltage at the port CV1 of the cell voltage measurement module MOk is obtained based on the voltage of the cell E8- (k-1) input from the port CV0.

  The port CLK is a terminal that transmits and receives a clock signal for synchronizing with a master module 40 to be described later via the synchronization signal bus line 12b.

  The port DATA is a terminal that outputs a measured value of the cell voltage calculated based on the voltages of the cells E1-k to E8-k input to the ports CV1 to CV8 to the data bus line 12c. In particular, in the present embodiment, in addition to the cell voltage measurement value, address data calculated by the module microcomputer 22 is output from the port DATA to the data bus line 12c.

  The port VDD is a port that receives power supply from a battery or the like (not shown) via the power supply bus line 12d. The port GND is a ground terminal connected to the GND bus line 12e.

  Further, as shown in the figure, the synchronization signal bus line 12b, the data bus line 12c, the power supply bus line 12d, and the GND bus line 12e of the power / communication bus line 12 are connected to the master module 40 that controls the cell voltage measurement module MOk. Has been.

  The master module 40 receives the clock signal and the cell voltage measurement value via the synchronization signal bus line 12b and the data bus line 12c. In particular, in the present embodiment, the master module 40 outputs an address setting mode command, which is an address assignment command, to the cell voltage measurement module MOk, and receives data of an address assigned to the cell voltage measurement module MOk. Function. Further, the master module 40 has a power output port VDD that outputs power to the power supply bus line 12d and a GND port to which the GND bus line 12e is connected.

  Then, the master module 40 performs measurement control of the voltages of the cells E1-k to E8-k in the cell voltage measurement module MOk, and the maximum value, minimum value, or average of the cell voltage measurement values received from the cell voltage measurement module MOk. Calculate the calculated value. Furthermore, the master module 40 outputs the calculated value to a system controller 42 that performs overall control of the system in which the stacked battery 200 is mounted using a communication protocol such as CAN (Controller Area Network).

  Further, in the present embodiment, the master module 40 performs overall control of processing related to the address setting mode of the cell voltage measurement module MOk. The master module 40 receives power supply from a power supply source such as a battery (not shown) via the Vin port.

  Next, a detailed configuration of the cell voltage measurement module MOk will be described with reference to FIGS. 4 to 7, the subscript “k” is omitted in the drawings for simplification of the drawings.

  FIG. 4 is a diagram illustrating a detailed circuit configuration of the cell voltage measurement module MOk. The cell voltage measurement module MO includes an input voltage processing circuit 50 that performs voltage adjustment processing for attenuating the voltages of the eight cells E1 to E8 input via the input ports CV1 to CV8, the module microcomputer 22 described above, and a stacked battery. And a voltage insulating unit 52 for preventing the voltage of 200 from being applied to the power supply / communication bus line 12.

  The input voltage processing circuit 50 has input ports Si1 to Si8 to which cell voltages from the input ports CV1 to CV8 are input, respectively. The input voltage processing circuit 50 includes a circuit for limiting the attenuation of each input cell voltage and the current due to the cell voltage and removing noise having a predetermined frequency or higher. In particular, the input voltage processing circuit 50 reduces each input cell voltage to an allowable voltage of the module microcomputer 22, and outputs each of the cell voltages with a predetermined gain (for example, 1/2) at the output ports So1 to So8. Is output to the module microcomputer 22 via

  FIG. 5 is a diagram illustrating a detailed configuration of the module microcomputer 22. As illustrated, the module microcomputer 22 includes input ports Ai1 to Ai8 for inputting cell powers output from the output ports So1 to So8 of the input voltage processing circuit 50, a channel switch 231, an AD converter 232, and the like. , A computing unit 234, a memory 235, and a communication interface 236.

  The channel switch 231 switches the connection between the input ports Ai1 to Ai8 and the AD converter 232 at predetermined time intervals. For example, the channel switch 231 outputs the cell voltage to the AD converter 232 in a state where the input port Ai8 and the AD converter 232 are connected in order to output the cell voltage value of the cell E8 to the AD converter 232 first. Is switched to the next input port Ai7 after a lapse of a predetermined amount of time. That is, the channel switch 231 functions as a cell switch that switches connection between the AD converter 232 and each of the input ports Ai1 to Ai8 (each CVM connector 28).

  The AD converter 232 performs AD conversion for converting the cell voltage input via the channel switch 231 into digital data.

  The calculator 234 receives cell voltage digital data from the AD converter 232 and calculates cell voltage measurement values of the cells E1 to E8 based on the data. Further, the calculator 234 calculates the minimum value, the maximum value, and the average value of the cell voltage measurement values of the cells E1 to E8.

  Further, the computing unit 234 confirms that the reception unit 26 has received a signal from the transmission unit 24- (k−1) of the previous cell voltage measurement module MO (k−1) via the communication interface 236. Detect. Further, the computing unit 234 instructs the transmission unit 24 to transmit a signal via the communication interface 236 based on the detection. The computing unit 234 counts the signal reception time included in the signal received by the reception unit 26 and the signal transmission time by the transmission unit 24.

  Then, the arithmetic unit 234 generates address data of the cell voltage measurement module MO based on the presence / absence of signal reception at the reception unit 26, the signal reception time, the presence / absence of signal transmission at the transmission unit 24, the signal transmission time, and the like. .

  The memory 235 stores the cell voltage measurement value and address data calculated by the calculator 234. These data are read by the computing unit 234 as necessary, and used for various processes.

  The communication interface 236 performs input / output processing of a clock signal and various data via the port SI0 and the port SI1. In particular, the communication interface 236 functions as a serial output port that outputs the cell voltage measurement value.

  In this embodiment, the communication interface 236 receives a reception signal indicating that the reception unit 26 has received a signal. Further, the communication interface 236 outputs a transmission command from the computing unit 234 to the transmission unit 24.

  FIG. 6 is a diagram illustrating the configuration of the voltage insulating unit 52. As illustrated, the voltage insulating unit 52 prevents the voltage of the stacked battery 200 from being applied to the power / communication bus line 12. The voltage insulation unit 52 includes an insulation DC / DC converter 261 that insulates the power supply line, and an insulation signal transmission element 262 that insulates the transmission / reception line of the clock signal and data.

  FIG. 7 is a diagram illustrating the circuit configuration of the master module 40. As illustrated, the master module 40 includes an input connector 60, a master module microcomputer 62, and a power supply stabilization circuit 64. The input connector 60 inputs / outputs CAN communication performed with the system controller 42 (see FIG. 3) and transmits power from a power source such as a battery (not shown) such as a CAN port that transmits communication data to the master module microcomputer 62. Power supply ports Vb + and Vb− for supplying to the power stabilization circuit 64 are provided.

  The master module microcomputer 62 has a CAN port for converting the cell voltage measurement values of the cells E1 to E8 received from the cell voltage measurement module MO via the power / communication bus line 12 to the CAN and converting them to the system controller 42. ing. Further, the master module microcomputer 62 calculates the minimum value, maximum value, and average value of the cell voltage measurement values of the cells E1 to E8. The master module microcomputer 62 outputs an address setting mode command for instructing the cell voltage measurement module MO to shift to the address setting mode to the power / communication bus line 12 via the serial ports SI0 and SI1.

  The power supply stabilization circuit 64 supplies power from the port Vo to the cell voltage measurement module MO via the power supply / communication bus line 12. Instead of the power supply stabilization circuit 64, a power supply such as a battery may be directly installed in the master module 40.

  Next, the flow of the address setting mode in the cell voltage measuring apparatus having the above configuration will be described.

  FIG. 8A is a flowchart for explaining the process flow in the master module according to the address setting mode, and FIG. 8B is a flowchart for explaining the process flow in the cell voltage measurement module MOk according to the address setting mode.

  Note that the address setting mode according to the present embodiment is, for example, when the device is set up at the time of shipment of the cell voltage measuring device 100, that is, the cell voltage measuring module MOk and the master module 40 are connected to the power / communication bus line 12. This is performed when the cell voltage measuring apparatus 100 is set up for the first time.

  In particular, in the present embodiment, the process of the master module 40 shown in FIG. 8A and the process of the cell voltage measurement module MOk shown in FIG. 8B are executed in parallel. Hereinafter, the process of the master module 40 and the process of the cell voltage measurement module MOk will be described more specifically.

  First, as shown in FIG. 8A, when the master module 40 is started, in step S110, the master module 40 determines whether or not to shift to the module address setting mode.

  Specifically, for example, the master module 40 sets a predetermined address setting mode execution flag before shipment of the cell voltage measuring device 100, determines whether the flag is set at the start, When the flag is set, it is determined that the mode is shifted to the module address setting mode. The address setting mode execution flag may be cleared once the module address setting mode is entered. Thereby, the master module 40 shifts to the module address setting mode only at the time of shipment when the master module 40 is first started.

  Then, when the master module 40 determines not to shift to the module address setting mode, it shifts to the normal measurement mode described later. On the other hand, if the master module 40 determines to shift to the module address setting mode, the process proceeds to step S120.

  In step S120, the master module 40 issues an address setting mode command. Specifically, the master module 40 sends an address setting mode command for instructing all the cell voltage measurement modules MO1 to MOn to shift to the address setting mode to the power supply / communication bus line 12 using a so-called general call address. Output.

  Next, in step S130, the master module 40 determines whether or not the cell voltage measurement module MOk responds to the address setting mode command, that is, whether or not address data is output from the cell voltage measurement module MOk to the power / communication bus line 12. Determine whether. Specifically, the master module 40 monitors the data bus line 12c of the power / communication bus line 12, and determines that there is a response when address data is output from the cell voltage measurement module MOk to the data bus line 12c. If no address data is output, it is determined that there is no response.

  If the master module 40 determines that there is no response from the cell voltage measurement module MOk in step S130, the master module 40 waits for a response for a predetermined time longer than the output interval time of the address data to the data bus line 12c. Wait (“No” in step S130).

  On the other hand, when determining that there is a response from the cell voltage measurement module MOk, the master module 40 proceeds to step S140 and stores the address data of the cell voltage measurement module MOk in a memory (not shown) or the like.

  In step S150, the master module 40 determines whether or not an elapsed time since the address setting mode command is issued, that is, a time for waiting for the response from the cell voltage measurement module MOk is equal to or longer than a predetermined time. More specifically, the master module 40 waits for the response, the time when the cell voltage measurement module MOk outputs the address data to the data bus line 12c, and the next cell voltage measurement module MO (k + 1) is the data bus line. In 12c, it is determined whether or not the time difference between the time of outputting the address data exceeds the predetermined time T. Then, the master module 40 continues the standby if the time for waiting for a response is less than the predetermined time T, and ends the standby if the time for waiting for a response is equal to or longer than the predetermined time T, and proceeds to step S160.

  In step S160, the master module 40 collates the number of responses from each cell voltage measurement module MOk described above with the number of each cell voltage measurement module MOk that is actually arranged. Specifically, the master module 40 compares the actual number of cell voltage measurement modules MOk stored in advance in the system controller 42 and the like with the number of address data stored in the memory or the like in step S140.

  Here, if the collation result is inconsistent, the process proceeds to step S190, where the master module 40 determines that an abnormality has occurred in the cell voltage measurement module MO and interrupts the process.

  On the other hand, if the collation results match, the process proceeds to step S180, where the master module 40 normally ends the address setting mode and shifts to a normal measurement mode described later. At this time, the master module 40 transmits an address setting mode end command indicating that the address setting mode has ended to the all-cell voltage measurement modules MO1 to MOn via the power / communication bus line 12.

  Next, processing in the cell voltage measurement module MOk will be described. Note that the process of the cell voltage measurement module MOk described below is a process executed in parallel in all the cell voltage measurement modules MO1 to MOn.

  First, as shown in FIG. 8B, when the cell voltage measurement module MOk is started, in step S210, for example, the cell voltage measurement module MOk performs an initialization process for performing processing necessary for each component of the module to start the module. Execute. Here, the initialization process includes, for example, an abnormality diagnosis process for diagnosing whether or not there is an abnormality in the component of the cell voltage measurement module MOk.

  In step S220, the cell voltage measurement module MOk determines whether or not to shift to the module address setting mode. Specifically, if the cell voltage measurement module MOk has received the address setting mode command issued by the master module 40 in step S120, the cell voltage measuring module MOk determines that the module address setting mode is to be entered, and receives the address setting mode command. If not, it is determined not to shift to the module address setting mode.

  Here, if it is determined not to shift to the module address setting mode, the cell voltage measurement module MOk shifts to the normal measurement mode. On the other hand, if it is determined to shift to the module address setting mode, the process proceeds to step S230.

  In step S230, the cell voltage measurement module MOk performs a transmission process of emitting a signal from the transmission unit 24-k (see FIG. 2B and the like).

  In step S240, the cell voltage measurement module MOk determines whether or not a signal is received by the reception unit 26-k. In other words, it is determined whether or not the transmission unit 24- (k-1) of the previous cell voltage measurement module MO (k-1) is transmitting a signal.

  Here, with respect to the first cell voltage measurement module MO1, since there is no previous module, no signal is received by the receiving unit 26-1. Therefore, the cell voltage measurement module MOk can identify itself as the head cell voltage measurement module MO1 when no signal is received by the receiving unit 26-k.

  Thereby, in step S240, when the reception of the signal in the receiving unit 26-k is not detected, the processing after step S241 is performed as the processing for the leading cell voltage measurement module MO1. On the other hand, when the reception of the signal in the receiving unit 26-k is detected, the process after step S250 is performed as a process for the cell voltage measurement module MOk (hereinafter, k ≠ 1) other than the head cell voltage measurement module MO1. Processing is performed.

  First, as a process for the first cell voltage measurement module MO1, in step S241, the cell voltage measurement module MO1 sets its own address in the memory 235 (see FIG. 5). Here, as an address, a continuous numerical sequence or character string with a certain regularity such as “1, 2, 3,...”, “A, B, C. Can be used. In the present embodiment, “a1, a2, a3..., Ak,. In the following, incrementing the address means obtaining the next address for a certain address in a continuous numerical sequence with a certain regularity. For example, the address obtained by incrementing the address “ak” is “ak + 1”.

  Next, in step S242, the cell voltage measurement module MO1 ends the transmission process. That is, the transmission of the signal by the transmission unit 24-1 is stopped.

  In step S243, the cell voltage measurement module MO1 transmits its own address “a1” set in the memory 235 to the master module 40 via the power / communication bus line 12. This transmission of address data is received by the master module 40 as the response described in step S130.

  On the other hand, if reception of a signal is detected in the reception unit 26 in step S240, the process proceeds to step S250 as processing for the cell voltage measurement modules MO2 to 10-n other than the head. In the following, for simplification of reference numerals, any one of the cell voltage measurement modules MO2 to 10-n other than the head is also referred to as “cell voltage measurement module MOk”.

  In step S250, the cell voltage measurement module MOk determines whether or not reception of a signal in the reception unit 26-k is continued. If it is determined that the reception of the signal in the receiving unit 26-k is continued, the address data flowing through the power / communication bus line 12 is monitored to be transmitted to the master module 40 in step S260. And get. The acquired address data is sequentially stacked in the memory 235.

  If it is determined in step S250 that reception of the signal in the receiving unit 26-k is not continued (finished), the process proceeds to step S270.

  In step S270, the cell voltage measurement module MOk increments the address “ak-1” acquired last in step S260 and stores it in the memory 235 as its own address “ak”.

  In step S280, the cell voltage measurement module MOk ends the transmission process. That is, the transmission of the signal by the transmission unit 24-1 is stopped.

  In step S 290, the cell voltage measurement module MOk transmits its own address “ak” set in the memory 235 to the master module 40 via the power / communication bus line 12. As described above, the transmitted address “ak” is received by the master module 40 as the response described in step S130.

  Next, the process in the address setting mode described above will be described in more detail.

  FIG. 9 is a timing chart for explaining the flow of communication between each cell voltage measurement module MO and the master module 40 in the address setting mode.

  In FIG. 9, the state in which the transmission unit 24-k is transmitting a signal is shown as the Hi level in the chart of the cell voltage measurement module (transmission) in FIG. The state where -k is receiving a signal is shown as the Hi level in the chart of the cell voltage measurement module (reception) in FIG.

  First, as shown in FIG. 9A, the master module 40 sends an address setting mode command to the all-cell voltage measurement modules MO1 to MO1 via the power / communication bus line 12 as described in step S120 of FIG. 8A. MOn is transmitted.

  Then, as described in step S230, when the cell voltage measurement modules MO1 to MOn receive the address setting mode command, the transmission units 24-1 to 24-n transmit signals as inter-module communication processing. Accordingly, as described in step S240 of FIG. 8B, each cell voltage measurement module MOk (k ≠ 1) other than the head cell voltage measurement module MO1 transmits the previous module by the reception unit 26-k. The signal from the unit 24- (k-1) is received.

  Here, referring to FIG. 9C, even if the first cell voltage measurement module MO1 receives the address setting mode command from the master module 40, reception by the receiving unit 26-1 is not detected (FIG. 8B). (See “No” in step S240). Therefore, the head cell voltage measurement module MO1 can recognize that it is the head.

  Then, the head cell voltage measurement module MO1 sets the head address “a1” in the memory 235 (see step S241), and after the elapse of a predetermined time Δt from the reception of the address setting mode command, Transmission is stopped (see step S242). Further, the obtained address address “a1” is transmitted to the master module 40 via the power / communication bus line 12 (step S243), and the normal measurement mode is entered.

  Further, as shown in FIG. 9C, for the second and subsequent cell voltage measurement modules MOk (k ≠ 1), the previous cell voltage is received when the address setting mode command is received from the master module 40. The reception unit 26-k starts to receive a signal from the transmission unit 24- (k-1) of the measurement module MOk-1 (see “Yes” in step S240).

  Here, in the reception unit 26-k of the cell voltage measurement module MOk, the signal is received until the previous cell voltage measurement module MOk-1 stops transmission of the signal by the transmission unit 24- (k-1). Will continue (see “Yes” in step S250). Then, the cell voltage measurement module MOk monitors the address flowing through the power / communication bus line 12 while receiving this signal (see step S260).

  Next, as shown in FIG. 9B, when the cell voltage measurement module MOk-1 stops the signal transmission by the transmission unit 24- (k-1), the cell voltage measurement is performed as shown in FIG. 9C. The reception of the signal in the receiving unit 26-k of the module MOk is also stopped.

  Then, when the reception of the signal in the receiving unit 26-k is stopped, the cell voltage measuring module MOk sets “ak-1” which is the address transmitted last among the addresses flowing through the power / communication bus line 12. Obtain (see “No” in step S250). In the case of the second cell voltage measurement module MO2, since only the address “a1” of the head cell voltage measurement module MO1 flows to the power / communication bus line 12, the head cell voltage measurement module MO1 The address “a1” is acquired as the last transmitted address.

  Then, the cell voltage measurement module MOk sets the address “ak” obtained by incrementing the acquired address “ak-1” of the previous cell voltage measurement module MOk-1 as its own address in the memory 235 (Step S1). S270), signal reception by the receiving unit 26-k is stopped, and transmission of the signal by the transmitting unit 24-k is stopped after a predetermined time Δt has elapsed (see step S280). Further, the obtained own address “ak” is transmitted to the master module 40 via the power / communication bus line 12 (see step S290), and the process proceeds to the normal measurement mode.

  By repeating the process described above in order for the cell voltage measurement modules MOk of k = 2 to n, it is possible to set unique addresses for the cell voltage measurement modules MO1 to MOn.

  Then, as shown in FIG. 9A, when the master module 40 does not receive an address for a predetermined time T, that is, the master module 40 receives the address “an” of the last cell voltage measurement module MOn and receives the predetermined time T. When elapses, an address setting mode end command is transmitted to the power / communication bus line 12 (step S180 in FIG. 8A).

  As described above, according to the present embodiment described above, consecutive addresses are automatically assigned to the cell voltage measurement modules MO1 to MOn in the address setting mode without setting a unique address for each cell voltage measurement module in advance. Can be granted.

  Next, a normal measurement mode in which voltage measurement for each cell E is performed will be described.

  FIG. 10A is a flowchart for explaining the flow of processing in the master module 40 according to the normal measurement mode, and FIG. 10B is a flowchart for explaining the flow of processing in the cell voltage measurement module MO according to the normal measurement mode. The normal measurement mode in the master module 40 is executed when the address setting mode ends normally (see step S180 in FIG. 8A). The normal measurement mode in the cell voltage measurement module MOk is after the address setting mode is completed, that is, after the address “ak” is transmitted to the master module 40 via the power / communication bus line 12 (step of FIG. 8B). Step S243 and step S290).

  In particular, the processing of the master module 40 shown in FIG. 10A and the processing of each cell voltage measurement module MOk shown in FIG. 10B are executed in parallel as in the address setting mode. Hereinafter, the normal measurement mode of the master module 40 and each cell voltage measurement module MOk will be described more specifically.

  First, as shown in FIG. 10A, in step S310, the master module 40 performs an initialization process. Here, the initialization process of the master module 40 is, for example, a process such as initialization of the master module microcomputer 62 or an activation response request with each cell voltage measurement module MO to which an address has already been assigned. In particular, the master module 40 sets the cell reversal voltage threshold, which is the upper limit of the measured value determined so as not to cause cell voltage reversal, in the initialization process of the cell voltage measurement module MO described later. To the cell voltage measurement module MOk.

  When the initialization process ends, in step S320, the master module 40 issues an AD conversion command for the cell voltage. Specifically, the master module 40 outputs an AD conversion command signal for instructing execution of AD conversion of the cell voltage detected by the cell voltage measurement module MOk (hereinafter also referred to as voltage AD conversion processing), and a general call address. And transmitted to the all-cell voltage measurement modules MO1 to MOn via the power / communication bus line 12.

  In step S330, the master module 40 determines whether or not the voltage AD conversion process has ended. That is, the master module 40 performs voltage AD conversion based on whether or not the cell voltage measurement module MOk has received a response indicating that the voltage AD conversion processing has been executed in response to the AD conversion command issued in step S320. It is determined whether or not the processing is completed. This response includes a numerical value calculated by AD conversion of the cell voltage, that is, a cell voltage measurement value.

  In particular, the master module 40 determines that the voltage AD conversion processing has been completed when the response is received from all the cell voltage measurement modules MO1 to MOn, and has received a response from any of the cell voltage measurement modules MOk. If not, it is determined that the voltage AD conversion process has not ended.

  If the master module 40 determines that the voltage AD conversion processing has not ended, the master module 40 waits for a predetermined time. That is, it waits for a response from the cell voltage measurement module MO. On the other hand, if it is determined that the voltage AD conversion process has been completed, the process proceeds to step S340.

  In step S340, the master module 40 records the cell voltage measurement value included in the response from the cell voltage measurement module MOk received in step S330 in a memory or the like. Here, as already described, since the cell voltage measurement module MOk measures the voltages of the eight cells E1-k to E8-k, the cell voltage measurement value of the cell voltage measurement module MOk includes eight values. ing.

  In step S350, the master module 40 performs an averaging process on the eight cell voltage measurement values of the cell voltage measurement module MOk. Specifically, eight cell voltage measurement values are calculated.

  Here, the master module 40 may not only calculate the average value of the eight cell voltage measurement values but also obtain the maximum value and the minimum value of the eight cell voltage measurement values and perform an abnormality diagnosis. For example, among the E1-k to E8-k in which the cell voltage measurement module MOk detects the voltage based on whether or not the maximum value and the minimum value of the obtained cell voltage measurement values deviate from within a predetermined allowable range. It is possible to determine whether or not there is an abnormal cell.

  In step S360, the master module 40 determines whether or not it is time to transmit control data such as the average value of the cell voltage measurement values obtained in step S350 and the determination result of the abnormality diagnosis to the system controller 42 shown in FIG. to decide.

  When it is time to transmit control data to the system controller 42, the control data is transmitted to the system controller 42 via the power / communication bus line 12 in step S 370.

  In step S370, if any abnormality occurs when the master module 40 transmits control data to the system controller 42, the watchdog time-out process in step S380 is performed again so as to repeat the processes in and after step S310. Is called. If such an abnormality does not occur, the process returns to S320 again and this routine is repeated.

  Next, the normal measurement mode in the cell voltage measurement module MOk will be described. The normal measurement mode is a process that is executed almost in parallel in all the cell voltage measurement modules MO1 to MOn.

  First, as shown in FIG. 10B, when the cell voltage measurement module MO receives the cell reversal voltage threshold value from the master module 40 in step S310, the cell voltage measurement module MO performs an initialization process in step S410.

  Here, the initialization process of the cell voltage measurement module MOk is a process of performing an internal diagnosis of the AD converter 232 of the cell voltage measurement module MOk, for example.

  In step S420, the cell voltage measurement module MOk determines whether or not the AD conversion command signal from the master module 40 in step S320 has been received. Here, when it is determined that the cell voltage measurement module MOk has not received the AD conversion command signal, the cell voltage measurement module MOk stands by until it is received. On the other hand, when the cell voltage measurement module MOk determines that the AD conversion command signal has been received, the process proceeds to step S430.

  In step S430, the cell voltage measurement module MOk performs AD conversion processing on the cell voltages detected for the cells E1-k to E8-k. In step S440, the cell voltage measurement value obtained after AD conversion is transmitted to the master module 40 as the response described in step S330. After the AD conversion process in step S430, for example, an abnormality occurs in the cell based on whether or not the cell voltage detected in each of the cells E1-k to E8-k is larger than a predetermined cell reversal voltage threshold value. An initial abnormality diagnosis process for diagnosing whether or not there is a problem may be performed.

  In step S450, the cell voltage measurement module MOk, when any abnormality occurs when transmitting the cell voltage measurement value to the master module 40, the watchdog time-out process so as to repeat the processing from step S410 again. Is done. If such an abnormality does not occur, the process returns to S420 again and this routine is repeated.

  Next, the process in the normal measurement mode described above will be described in more detail.

FIG. 11 is a timing chart for explaining the flow of processing in the normal measurement mode.
In particular, the timing chart shows the processing in step S320 in the master module 40 and the processing in steps S420, S430, and S440 in each of the cell voltage measurement modules MO1 to MOn.

  In FIG. 11B, the state in which the AD conversion processing of the cell voltage is being performed is shown as the Hi level in the chart of the cell voltage measurement module (AD conversion).

  First, as shown in FIG. 11A, the master module 40 sends the cell voltage AD conversion command described in step S320 of FIG. 10A to the all-cell voltage measurement modules MO1 to MOn via the power / communication bus line 12. Send.

  Then, as described in step S430, the cell voltage measurement module MOk (k = 1 to n) performs AD conversion processing when receiving an AD conversion command.

  Then, as shown in FIG. 11A, the master module 40, after the AD conversion processing time of the cell voltage measurement module MOk calculated in advance from the time of transmission of the AD conversion command, has passed, the leading cell voltage measurement module MO1. Referring to the address “a1”, a data transfer command signal for instructing data transfer to the leading cell voltage measurement module MO1 is output.

  Then, referring to FIG. 11C, when the head cell voltage measurement module MO1 receives the data transfer command signal from the master module 40, the cell voltage measurement value after AD conversion should be transmitted to the master module 40 as a response. The cell voltage measurement value is output to the power / communication bus line 12.

  For the cell voltage measurement modules MOk (k ≠ 1) other than the head, after the cell voltage measurement value is output to the power / communication bus line 12 by the cell voltage measurement module MO (k−1), the power / communication bus line is output. The cell voltage measurement value is transmitted to 12.

  As can be understood from FIG. 11C, after the previous cell voltage measurement module MO (k−1) outputs the cell voltage measurement value data to the power / communication bus line 12, the cell voltage is measured. The measurement module MOk has a predetermined time interval Δt ′ before the cell voltage measurement value data on the power / communication bus line 12. This is for so-called polling such as avoiding communication conflicts on the power / communication bus line 12.

  Then, when the master module 40 receives all the cell voltage measurement value data from all the cell voltage measurement modules MO1 to MOn, this process ends. This process is repeated an arbitrary number of times at a predetermined time period.

  Next, the flow of abnormality diagnosis performed by the master module 40 described in step S350 described above will be described.

  FIG. 12 is a timing chart illustrating the flow of cell abnormality diagnosis. In this timing chart, each cell voltage measurement module MO1 to MOn has an AD for monitoring voltage abnormality in each cell at almost the same timing as the output of the data transfer command signal by the master module 40 described in FIG. Conversion processing (hereinafter also referred to as “abnormal voltage monitoring AD conversion processing”) is performed (see FIG. 12A). The abnormal voltage monitoring AD conversion process is continued until a predetermined time Δt ″ before the master module 40 issues an AD conversion command.

  During abnormal voltage monitoring AD conversion, if one or more of all the cell voltage measurement modules MO1 to MOn, for example, the cell voltage measurement module MO2 is abnormal, the cell voltage measurement module MO2 is connected via the power / communication bus line 12. The abnormality detection signal D is transmitted to the next cell voltage measurement module MO3.

  The cell voltage measurement module MOk (3 ≦ k ≦ n−1) after the cell voltage measurement module MO3 that has received the abnormality detection signal D transmits the abnormality detection signal D to the cell voltage measurement module MOk + 1. Then, the last cell voltage measurement module MOn transmits the abnormality detection signal D received from the cell voltage measurement module MOn-1 to the master module 40.

  As described above, the abnormality detection signal D is sequentially transmitted and received between the cell voltage measurement modules MO1 to MOn, so that the abnormal state occurring in the cell is promptly transmitted to the master module 40 and the system controller 42 communicating with the master module 40. Therefore, it can be reflected in the predetermined control of the system in which the laminated battery 200 is used.

  Note that the communication of the abnormality detection signal D between the cell voltage measurement modules MO1 to MOn is replaced with the communication via the power source / communication bus line 12, or together with the transmission units 24-1 to 24-n and the reception unit 26. You may make it carry out by the mutual communication using -1-26-n.

  For example, when an abnormality is detected in a cell by any one of the cell voltage measurement modules MOk, transmission of the abnormality detection signal D in the cell voltage measurement module MOk and the subsequent cell voltage measurement modules MOk + 1, MOk + 2,. It is also possible to carry out by mutual communication using the transmission unit 24 and the reception unit 26 which they have.

  According to the cell voltage measuring apparatus 100 described above, the following effects can be obtained. In the following description, k takes a value of an arbitrary natural number from 1 to n-1.

  The cell voltage measurement device 100 according to this embodiment includes cell voltage measurement modules MO1 to MOn as a plurality of cell voltage measurement modules arranged side by side so as to measure the voltages of the plurality of cells E1 to E8 of the laminated battery 200. Among the plurality of cell voltage measurement modules MO1 to MOn, the module microcomputer 22 as an address assigning device for giving consecutive addresses ak, ak + 1 to the adjacent cell voltage measurement modules MOk, MO (k + 1), the transmission unit 24, and the reception Part 26.

  As a result, even if the cell voltage measurement modules MO1 to MOn that are arbitrarily attached have their own addresses unknown in the initial state, the cell address measurement modules MO1 to MOn are assembled by the address assigning devices 22, 24, and 26. Consecutive addresses can be given to adjacent cell voltage measurement modules MOk and MO (k + 1). Therefore, even if all the cell voltage measurement modules MO1 to MOn have the same specification, addresses can be assigned to them, so that the manufacturing cost of the apparatus can be suppressed and the assembly work is prevented from becoming complicated.

  In the cell voltage measuring device 100 according to the present embodiment, the address assigning devices 22, 24, and 26 are incorporated in the plurality of cell voltage measuring modules MO1 to MOn. As a result, it is not necessary to separately configure a device for assigning addresses, so that the entire configuration of the cell voltage measuring device 100 can be simplified and the number of necessary wirings can be reduced.

  Furthermore, in the cell voltage measurement device 100 according to the present embodiment, the address assignment devices 22, 24, and 26 include module mutual communication units 24 and 26 that perform communication between adjacent cell voltage measurement modules MOk and MO (k + 1), And a module microcomputer 22 as an address setting unit for setting consecutive addresses ak, ak + 1 to adjacent cell voltage measurement modules MOk, MO (k + 1) based on communication by the module mutual communication units 24, 26.

  As a result, for example, communication between adjacent cell voltage measurement modules MOk and MO (k + 1) is performed without using a communication transmission path with a large communication volume such as a communication bus, so that addresses can be assigned to these cell voltage measurement modules MOk and MO (k + 1). Can be set. Therefore, the address setting for all the cell voltage measurement modules MO1 to MOn can be performed more smoothly.

  Further, in the cell voltage measurement device 100 according to the present embodiment, the module intercommunication units 24 and 26 include a transmission unit 24-k that transmits a signal to the cell voltage measurement module MO (k + 1) next to the cell voltage measurement module MOk. A receiving unit 26-k that receives a signal from the transmitting unit 24- (k-1) in the previous cell voltage measurement module MO (k-1), and a module microcomputer 22- serving as an address setting unit k is the address ak of the cell voltage measurement module MOk when the reception unit 26-k receives a signal from the transmission unit 24- (k-1) of the previous cell voltage measurement module MO (k-1). Set. When the address ak is set by the module microcomputer 22-k, a signal is transmitted to the next cell voltage measurement module MO (k + 1) by the transmission unit 24-k.

  Thereby, when the cell voltage measurement device 100 is assembled, a simple logic for assigning an address to the cell voltage measurement module MOk is configured. Therefore, the address setting process in the cell voltage measuring apparatus 100 can be further simplified.

  Further, in the cell voltage measurement device 100 according to the present embodiment, the module microcomputer 22-k as the address setting unit is the transmission unit 24- (k-1) of the previous cell voltage measurement module MO (k-1). Is not received by the receiving unit 26-k, a predetermined head address a1 is set.

  That is, the module microcomputer 22-k can recognize that the cell voltage measurement module MOk in which the module microcomputer 22-k is incorporated is the first cell voltage measurement module MO1 because the reception is not performed by the reception unit 26-k. . Therefore, the address of the leading cell voltage measurement module MO1 can be set without preparing a special module with an address for the leading module in advance. Addresses can also be assigned to the cell voltage measurement module MO2 and subsequent modules.

  Furthermore, in the cell voltage measurement device 100 according to the present embodiment, the module microcomputer 22-k serving as the address setting unit receives the previous cell voltage measurement module MO (k) when the signal from the reception unit 26-k is received. -1) is acquired, and the next address ak of the acquired address ak-1 is set.

  Thereby, the next address ak can be set in the next cell voltage measurement module MOk with respect to the address ak-1 set in the previous cell voltage measurement module MO (k-1). That is, it is possible to easily assign an order address to each cell voltage measurement module MOk.

  Further, in the cell voltage measurement device 100 according to the present embodiment, the module microcomputer 22-k as the address setting unit is the transmission unit 24- (k-1) of the previous cell voltage measurement module MO (k-1). When the signal from the receiver 26-k is received, the immediately preceding module address ak-1, which is the address set in the previous cell voltage measurement module MO (k-1), is acquired, and immediately before the acquisition. The next address ak of the module address ak-1 is set.

  Thereby, addresses a1, a2,..., Consecutive in this order can be more easily set in the cell voltage measurement modules MO1 to MOn.

  Furthermore, in the cell voltage measuring device 100 according to the present embodiment, the address assignment devices 22, 24, 26 receive the addresses a1, a2,..., An assignment command and the address ak attached to the cell voltage measurement module MOk. And a power supply / communication bus line 12 as a bus line that connects the cell voltage measurement module MOk and the master module 40 so that they can communicate with each other. The immediately preceding module address ak-1 is output to the power / communication bus line 12, and the module microcomputer 22-k as an address setting unit receives the immediately preceding module address ak-1 output to the power / communication bus line 12. get.

  As a result, the master module 40 can uniformly manage address assignment commands (step S120 in FIG. 8A) in all the cell voltage measurement modules MO1 to MOn. Then, the module microcomputer 22-k of the cell voltage measurement module MOk uses the address ak−1 of the cell voltage measurement module MO (k−1) output to the power supply / communication bus line 12 addressed to the master module 40 as the bus line 12. Can be obtained more easily. That is, the module microcomputer 22-k can more easily acquire the address ak-1 of the cell voltage measurement module MO (k-1) used when setting the address of the cell voltage measurement module MOk.

  In the cell voltage measurement device 100 according to the present embodiment, the cell voltage measurement module MOk is connected to the plurality of tabs 204 corresponding to the plurality of cells E1-k to E8-k of the stacked battery 200, respectively. A CVM connector 28, an input voltage processing circuit 50 that is connected to a plurality of CVM connectors 28 and performs a voltage adjustment process for adjusting a cell voltage input through the connector, and a cell voltage subjected to the voltage adjustment process A module microcomputer 22-k as a voltage measurement value calculation processing circuit for calculating a cell voltage measurement value by AD conversion, a voltage insulation unit 52 that prevents transmission of voltage from the laminated battery 200 to the power supply / communication bus line 12, Have

  As a result, a specific circuit configuration of the cell voltage measurement module MOk is realized. In particular, the voltage insulation unit 52 can prevent transmission of a high voltage from the stacked battery 200 to the power supply / communication bus line 12.

  Furthermore, in the cell voltage measuring apparatus 100 according to the present embodiment, the module microcomputer 22-k switches between the AD converter 232 that performs the AD conversion and the connector that is connected to the AD converter 232 among the plurality of CVM connectors 28. A channel switch 231 as a cell switch, a calculator 234 that calculates a cell voltage measurement value from a value after the AD converter 232, and a communication interface 236 as a serial output port that outputs the calculated cell voltage measurement value Have.

  As a result, it is possible to easily realize a configuration in which voltages individually detected in the cells E1-k to E8-k are individually AD-converted by the AD converter 232 and output to the calculator 234. In particular, since the AD converter 232, the channel switch 231 and the arithmetic unit 234 are configured as an integrated unit, the reduction of wiring and the simplification of the circuit configuration are further contributed.

  In the cell voltage measurement device 100 according to the present embodiment, the master module 40 as the main module issues an address assignment command when the cell voltage measurement device 100 is activated for the first time. As a result, the addresses are assigned to all the cell voltage measurement modules MO1 to MOn at the time of initial activation such as when the product is shipped, and the subsequent processing such as cell voltage measurement can be performed smoothly.

  Further, in the cell voltage measuring device 100 according to the present embodiment, the module microcomputer 22-k as the address assignment device outputs a response (address assignment end information) to the address assignment command to the master module 40 when the address assignment is finished. (Step S243 and Step S290 in FIG. 8B), the master module 40 determines whether or not the number of cell voltage measurement modules MO is a predetermined number based on the response from the module microcomputer 22 (see Step S170). ).

  In this way, the master module 40 determines whether the number of cell voltage measurement modules MOk for which the address assignment processing has been completed is a predetermined number. If these numbers do not match, the master cell 40 measures all cell voltages. It can be determined that the module MO1 to MOn has an abnormality such as a failure.

  Furthermore, in the cell voltage measurement device 100 according to the present embodiment, as described above, the specifications of all the cell voltage measurement modules MO1 to MOn can be made the same. Therefore, workers do not need to consider that the cell voltage measurement modules MO1 to MOn are attached at fixed positions according to addresses in the work for assembling each cell E of the laminated battery, and the efficiency in the assembling work is improved. It will be extremely improved. Further, even if a failure occurs in some of the cell voltage measurement modules MO1 to MOn after assembly and a situation occurs in which some modules are replaced, the type of the module is not selected. Therefore, the replacement work is easy.

(Second Embodiment)
Hereinafter, a second embodiment will be described. In addition, the same code | symbol is attached | subjected to the element similar to 1st Embodiment, and the description is abbreviate | omitted.

  FIG. 13 is a diagram illustrating the circuit configuration of each cell voltage measurement module MOk (k = 1 to n) and the master module 40 of the cell voltage measurement device according to the second embodiment.

  As illustrated, the master module 40 according to the present embodiment includes a transmission unit 70 having the same configuration as the transmission unit 24-k included in the cell voltage measurement module MOk. The master module 40 is adjacent to the cell voltage measurement module MO1 so that the transmission of the signal by the transmission unit 70 of the master module 40 can be received by the reception unit 26-1 of the leading cell voltage measurement module MO1. Are arranged.

  FIG. 14 is a diagram illustrating a circuit configuration of the master module 40 according to the present embodiment. As shown in the drawing, in the present embodiment, the transmission of the signal of the transmitter 70 of the master module 40 is controlled by the master module microcomputer 62.

  Next, the flow of the address setting mode in the cell voltage measuring apparatus having the above configuration will be described. The processing in the master module 40 is the same as that in the first embodiment except that the transmission unit 70 transmits a signal when the address setting mode command is issued in step S120 of FIG. 8A. Omitted. In the present embodiment, the control in the normal measurement mode and the abnormal state diagnosis mode is the same as in the first embodiment.

  FIG. 15 is a flowchart for explaining the processing flow of the cell voltage measurement module MOk in the address setting mode according to this embodiment.

  First, as shown in the figure, when the cell voltage measurement module MOk is started, in step S310, the cell voltage measurement module MOk performs an initialization process similar to step S210 in FIG. 8B. Here, in the present embodiment, unlike the first embodiment, the cell voltage measurement module MOk starts signal transmission by the transmission unit 24.

  In step S320, the cell voltage measurement module MOk determines whether or not to shift to the module address setting mode similar to step S220 in FIG. 8B. Here, if it is determined not to shift to the module address setting mode, the cell voltage measurement module MOk shifts to the normal measurement mode. On the other hand, if it is determined to shift to the module address setting mode, the process proceeds to step S330.

  In step S330, the cell voltage measurement module MOk stops signal transmission by the transmission unit 24-k.

  In step S340, the cell voltage measurement module MOk determines whether reception of a signal in the reception unit 26-k is detected. Here, in the present embodiment, in step S330, signal transmission by the transmission unit 24-k of each cell voltage measurement module MOk is stopped, but signal transmission by the transmission unit 70 of the master module 40 is performed. It is in a state.

  Therefore, the cell voltage measurement module MOk that receives the signal from the transmission unit 70 of the master module 40 can recognize itself as the head cell voltage measurement module MO1. Thereby, when the reception of the signal in the receiving unit 26-k is detected, the process after step S341 is performed as the process for the leading cell voltage measurement module MO1. On the other hand, when reception of a signal is not detected in the receiving unit 26-k, the processing after step S350 is performed as processing for the cell voltage measurement module MOk (k ≠ 1) other than the head cell voltage measurement module MO1. .

  First, as processing for the first cell voltage measurement module MO1, in step S341, the cell voltage measurement module MO1 sets its own module address in the memory 235 in the same manner as in step S241 in FIG. 8B.

  Next, in step S342, the cell voltage measurement module MO1 performs signal transmission by the transmission unit 24-1.

  In step S343, the cell voltage measurement module MO1 transmits its own address “a1” set in the memory 235 to the master module 40 via the power / communication bus line 12.

  On the other hand, in step S340, when reception of the signal in the reception unit 26-k is not detected, in step S350, the cell voltage measurement module MOk continues to be in a state where no signal is received by the reception unit 26-k. Judge whether or not.

  If it is determined that the state where no signal is received by the receiving unit 26-k continues, the address transmitted to the master module 40 via the power / communication bus line 12 is monitored in step S360. And get. This monitoring and acquisition of the address is continued while the state in which no signal is received by the receiving unit 26-k continues. The acquired address data is stacked in the memory 235.

  Then, when reception of a signal is detected by the receiving unit 26-k, the process proceeds to step S370.

  In step S370, the cell voltage measurement module MOk increments the address “ak-1” last acquired in step S360 and stores the address “ak” as its own address in the memory 235, as in step 270 of FIG. 8B. Remember.

  In step S380, the cell voltage measurement module MOk starts signal transmission by the transmission unit 24-k. In step S390, the cell voltage measurement module MOk transmits its own address data set in the memory 235 to the master module 40 via the power / communication bus line 12.

  Next, the process in the address setting mode described above will be described in more detail.

  FIG. 16 is a timing chart for explaining the flow of processing in the address setting mode.

  First, as shown in FIG. 16A, the master module 40 transmits an address setting mode command to the all-cell voltage measurement modules MO1 to MOn via the power / communication bus line 12, while the signal from the transmission unit 70 is transmitted. Send. At this time, as shown in FIG. 16B, signal transmission by the transmission unit 24-k of each cell voltage measurement module MOk (k = 1 to n) is stopped (step S330).

  Then, the cell voltage measurement module MOk receives the address setting mode command. Here, in the present embodiment, as already described, only the reception unit 26-1 of the leading cell voltage measurement module MO1 receives the signal from the transmission unit 70 of the master module 40 (FIG. 16B). . Therefore, the cell voltage measurement module MOk that has received the signal by the receiving unit 26-k together with the reception of the address setting mode command can recognize that it is the first cell voltage measurement module MO1.

  Then, as shown in FIG. 16C, the leading cell voltage measurement module MO1 sets a predetermined leading address “a1” in the memory 235 with the reception of the signal in the receiving unit 26-1 as a trigger. Then (step S341), transmission of the signal by the transmission unit 24-1 is started (step S342 and FIG. 16B). Further, the obtained own address “a1” is transmitted to the master module 40 via the power / communication bus line 12 (step S343), and the process proceeds to the normal measurement mode.

  On the other hand, as shown in FIGS. 16B and 16C, for the second and subsequent cell voltage measurement modules MOk (k = 2 to n), the transmission unit 24 of the previous cell voltage measurement module MOk−1. -The address flowing through the power / communication bus line 12 is monitored until the signal from (k-1) is received by the receiver 26- (k-1) (see "Yes" in step S250).

  When the second and subsequent cell voltage measurement modules MOk receive a signal from the transmission unit 24- (k-1) of the immediately preceding cell voltage measurement module MOk-1, the power / communication bus at the time of the reception is received. The address “ak-1” output last among the addresses flowing through the line 12 is acquired (see “No” in step S350). In particular, in the case of the second cell voltage measurement module MO2, only the address data of the first cell voltage measurement module MO1 is transmitted through the power / communication bus line 12, and therefore the address “ a1 "is acquired.

  Then, the second and subsequent cell voltage measurement modules MOk set the address “ak” obtained by incrementing the acquired address “ak-1” of the previous cell voltage measurement module MOk-1 as its own address in the memory 235. Then (see step S370), signal transmission by the transmission unit 24-k is started (see step S380). Further, the obtained own address “ak” is transmitted to the master module 40 via the power / communication bus line 12 (see step S390), and the normal measurement mode is entered.

  Thereby, a unique address can be given to each of the cell voltage measurement modules MO1 to MOn.

  According to the cell voltage measuring apparatus 100 described above, the following effects can be obtained.

  In the cell voltage measurement apparatus 100 according to the present embodiment, the module intercommunication units 24 and 26 are connected to a transmission unit 24-k that transmits a signal to the cell voltage measurement module MO (k + 1) next to the cell voltage measurement module MOk. A receiving unit 26-k that receives a signal from the transmitting unit 24- (k-1) in the previous cell voltage measurement module MO (k-1), and the module microcomputer 22-k serving as an address setting unit When reception of the signal from the transmission unit 24- (k-1) of the previous cell voltage measurement module MO (k-1) is stopped in the reception unit 26-k, the address ak of the cell voltage measurement module MOk. Set. Then, when the address ak is set by the module microcomputer 22-k, the transmission to the next cell voltage measurement module MO (k + 1) by the transmission unit 24-k is stopped.

  Thereby, when the cell voltage measurement device 100 is assembled, a simple logic for assigning an address to the cell voltage measurement module MOk is configured. Therefore, the address setting process in the cell voltage measuring apparatus 100 can be further simplified.

  In the cell voltage measurement device 100 of the present embodiment, the master module 40 as the main module has a transmission unit 70 as a main module signal transmission unit that transmits a signal to the reception unit 26 of the leading cell voltage measurement module MO1. Then, a signal is transmitted by the transmission unit 70 as an address setting mode command which is an address assignment command.

  As a result, as the address setting mode command is issued, the transmission unit 70 of the master module 40 transmits a signal to the reception unit 26-1 of the leading cell voltage measurement module MO1, so that the power supply for transmitting the address setting mode command is used. / There is no need to use the communication bus line 12. Therefore, the length of the power / communication bus line 12 can be reduced, and the material cost can be further reduced.

  In this embodiment, when starting the address setting mode, the first cell voltage measurement module MO1 is configured to receive signal transmission by the transmission unit 70 of the master module 40. The transmission state by the transmission unit 70 of the master module 40 may be maintained from the stage before the start, and the transmission of the signal by the transmission unit 70 may be stopped when the address setting mode command is issued. As a result, communication between the cell voltage measurement modules MO according to the address setting mode can be started with the reception unit 26-1 of the first cell voltage measurement module MO1 receiving no signal.

(Third embodiment)
Hereinafter, the third embodiment will be described. In addition, the same code | symbol is attached | subjected to the element similar to 1st Embodiment or 2nd Embodiment, and the description is abbreviate | omitted.

  FIG. 17 is a diagram for explaining circuit configurations of the cell voltage measurement modules MO1 to MOn and the master module 40 of the cell voltage measurement device 100 according to the third embodiment.

  As illustrated, the master module 40 according to the present embodiment includes a reception unit 72 having the same configuration as the reception unit 26-k included in the cell voltage measurement module MOk (k = 1 to n). The master module 40 is provided adjacent to the last cell voltage measurement module MOn so that the reception unit 72 receives a signal from the transmission unit 24-n of the last cell voltage measurement module MOn. ing.

  FIG. 18 is a diagram illustrating the circuit configuration of the master module 40 according to the present embodiment. As shown in the figure, in the present embodiment, reception of a signal in the receiving unit 72 of the master module 40 is detected by the master module microcomputer 62.

  In the present embodiment, the control in the address setting mode, the normal measurement mode, and the abnormal state diagnosis mode is the same as in the first embodiment.

  In the present embodiment, a receiving unit 72 is provided in the master module 40. The master module 40 is provided adjacent to the last cell voltage measurement module MOn. Therefore, when the cell voltage measurement module MO is assembled to the multilayer battery 200 for the first time, for example, at the time of shipment of the cell voltage measurement device 100, the instructions in FIGS. 8A, 8B, and 9 of the first embodiment are based on the command of the master module 40. As described, addresses are sequentially set in the cell voltage measurement modules MO1 to MOn and stored in the memory 235 thereof.

  When the transmission of the signal by the transmission unit 24-n of the last cell voltage measurement module MOn is stopped, the master module 40 detects that the reception of the signal in the reception unit 72 is stopped. That is, the master module 40 recognizes that the address setting of all the cell voltage measurement modules MO1 to MOn has been completed when the reception unit 72 detects the stop of reception.

  In the present embodiment, since the master module 40 is located adjacent to the last cell voltage measurement module MOn, in the abnormal state diagnosis mode executed in the same manner as in the first embodiment, the abnormal state shown in FIG. Is transmitted immediately to the master module 40 using the transmitter 24-k and receiver 26-k, which are inter-module communication paths of the cell voltage measurement module MOk, and the receiver 72 of the master module 40. Is possible. In other words, a signal indicating an abnormal state can be smoothly communicated without using the power / communication bus line 12 having a large communication amount to which other data and the like are communicated.

  According to the cell voltage measuring apparatus 100 described above, the following effects can be obtained.

  According to the cell voltage measurement device 100 of the present embodiment, the master module 40 has the reception unit 72 as a main module signal reception unit that receives a signal from the transmission unit 24-n of the last cell voltage measurement module MOn. Then, a signal is received by the receiving unit 72 of the master module 40 as address assignment end information, which is information indicating that address assignment has ended.

  Accordingly, the master module 40 can recognize in a timely manner that the sequential address setting in the first cell voltage measurement module MO1 to the last cell voltage measurement module MOn has been completed. The address setting process time is reduced.

  Note that communication between the transmission unit 24 of the last cell voltage measurement module MOn and the reception unit 72 of the master module 40 may be used to transmit abnormality detection during normal measurement to the system controller 42. As a result, the abnormal state can be promptly transmitted to the system controller 42, which contributes to improving control responsiveness in a system in which the stacked battery 200 is used (for example, a fuel cell system mounted on a vehicle). it can.

  In the address setting mode, a signal is transmitted from the transmission unit 24-n of the last cell voltage measurement module MOn, and when the address setting mode ends, the signal is transmitted from the transmission unit 24-n. Transmission may be stopped. Accordingly, the master module 40 can recognize that the address assignment has ended by detecting the stop of signal reception in the receiving unit 72 of the master module 40.

(Fourth embodiment)
The fourth embodiment will be described below. In addition, the same code | symbol is attached | subjected to the element similar to either of 1st-3rd embodiment, and the description is abbreviate | omitted.

  FIG. 19 is a diagram illustrating the circuit configuration of the cell voltage measurement module MO and the like of the cell voltage measurement device 100 according to the fourth embodiment.

  As illustrated, in the present embodiment, the function of the master module 40 is incorporated in the system controller 42.

  That is, in the cell voltage measuring device 100 of the present embodiment, the master module 40 as the main module is incorporated in the system controller 42 as a host controller that controls a predetermined system in which the stacked battery 200 is used. Thereby, further space saving and simplification of the structure of the cell voltage measuring apparatus 100 can be achieved.

  In the present embodiment, the control in the address setting mode, the normal measurement mode, and the abnormal state diagnosis mode is the same as in the first embodiment.

(Fifth embodiment)
Hereinafter, a fifth embodiment will be described. In addition, the same code | symbol is attached | subjected to the element similar to either of 1st-4th embodiment, and the description is abbreviate | omitted.

  FIG. 20 is a diagram illustrating the circuit configuration of each cell voltage measurement module MO and the like of the cell voltage measurement device according to the fifth embodiment.

  In the present embodiment, a shipment setting device 75 is disposed adjacent to the leading cell voltage measurement module MO1. The shipment setting device 75 transmits a signal to the receiving unit 26-1 of the leading cell voltage measurement module MO 1 based on a command from the system controller 42.

  In particular, in this embodiment, instead of issuing an address setting mode command (step S120 in FIG. 8A) when the master module 40 shifts to the module address setting mode as in the first embodiment, the system controller 42 commands the shipment setting device 75 to transmit a signal to the receiving unit 26-1 of the leading cell voltage measurement module MO1.

  In the present embodiment, the control in the address setting mode, the normal measurement mode, and the abnormal state diagnosis mode is the same as that in the first embodiment.

  According to the cell voltage measurement device 100 described above, the cell voltage measurement device 100 further includes the shipment setting device 75 that transmits a signal to the reception unit 26-1 of the lead cell voltage measurement module MO1, and the lead cell voltage measurement module MO1 is the shipment setting device. When the transmission of the signal from 75 is received, the address setting by the module microcomputer 22-k (k = 1, 2,... N) as the address setting unit is started.

  As a result, it is possible to prevent the address setting from being executed without a shipping device, and therefore, it is possible to more reliably prevent the possibility that the address setting is unintentionally rewritten due to a problem such as a trouble in the master module 40.

  Next, modifications of the transmission unit 24 and the reception unit 26 of the cell voltage measurement module MO will be described.

  21A, FIG. 21B, FIG. 22A, FIG. 22B, FIG. 23A, FIG. 23B, FIG. 24A, and FIG. 24B are diagrams for explaining modifications of the transmission unit 24 and the reception unit 26 of the cell voltage measurement module MO.

  In FIG. 21A and FIG. 21B, as one modification, the transmitting coil 24-k and the receiving coil 126-k are respectively used as the transmitting unit 24-k and the receiving unit 26-k of the cell voltage measurement module MOk (k = 1 to n). Is used. Each of the transmission coil 124-k and the reception coil 126-k is configured by winding a wire made of copper or the like around a magnetic material such as an iron core or ferrite.

  Moreover, in FIG. 22A and FIG. 22B, as another modified example, the transmission electrode 224-k and the reception electrode 226-k are used for the transmission unit 24-k and the reception unit 26-k of the cell voltage measurement module MOk, respectively. The transmission electrode 224-k is provided so as to be exposed on the surface of the housing 32 of the cell voltage measurement module MOk, and a resistor 77 for current detection is provided between the transmission electrode 224-k and the module microcomputer 22-k. Similarly, the reception electrode 226-k is exposed on the surface of the housing 32 of the cell voltage measurement module MOk, and a flexible contact such as a cantilever for contacting the transmission electrode 224-k is formed. ing.

  Further, in FIG. 23A and FIG. 23B, as another modified example, the transmitting unit 24-k and the receiving unit 26-k of the cell voltage measurement module MOk are connected to the transmitting electrode 324-k and the receiving electrode 326-k that perform electric field communication. It is configured as. The transmission pole 324-k is configured to be covered with the housing 32 of the cell voltage measurement module MOk, and is charged by receiving power supply from the substrate 20. On the other hand, the reception pole 326-k is also configured to be covered by the housing 32 of the cell voltage measurement module MOk. The reception pole 326-k is charged as the transmission pole 324-k is charged. As a result, a current flows to the module microcomputer 22-k via the resistor 77, and reception is detected.

  The embodiment of the present invention has been described above. However, the above embodiment only shows a part of application examples of the present invention, and the technical scope of the present invention is limited to the specific configuration of the above embodiment. Absent.

  For example, in the above-described embodiment, one cell voltage measurement module MOk is configured to measure the cell voltages of eight cells E1-k to E8-k. However, a cell measured by one cell voltage measurement module MOk is used. The number of is not limited to this, and can be variously changed according to the situation. In particular, one cell voltage measurement module MOk may be provided for one cell. Further, in one cell voltage measuring device 100, the cell voltage is measured by using a cell voltage measuring module MOk that can measure voltages of eight cells and a cell voltage measuring module MOk ′ that can measure voltages of seven cells. A plurality of types of cell voltage measurement modules having different numbers of cells may be used.

  In each of the above embodiments, the address assignment device is configured as the module microcomputer 22-k, the transmission unit 24-k, and the reception unit 26-k provided in the cell voltage measurement module MOk. The form is not limited to this. For example, instead of mutual communication between adjacent cell voltage measurement modules MOk and MOk + 1 in the address setting mode described above, mutual communication between these modules may be performed by the power supply / communication bus line 12. The function of setting the address of the cell voltage measurement module MOk may be provided to the master module 40 or the system controller 42 instead of or together with the module microcomputer 22-k.

  Furthermore, even when the number of cells E of the laminated battery 200 is variously changed depending on the use of the laminated battery 200, the cell voltage measuring device 100 of the present invention can be applied according to an arbitrary number of cells. Is possible. For example, when the laminated battery 200 is mounted on an automobile and 300 cells are used, 37 cell voltage measurement modules MOk that measure the voltages of 8 cells and cell voltages that measure the voltages of 4 cells are used. A cell voltage measurement device can be configured using one measurement module MOk ″.

  Further, the above embodiments can be arbitrarily combined.

DESCRIPTION OF SYMBOLS 12 Power supply / communication bus line 22 Module microcomputer 22 Address assignment apparatus 24 Transmission part 26 Reception part 28 CVM connector 30 Bus connector pin 34 Bus connector socket 40 Master module 42 System controller 50 Input voltage processing circuit 52 Voltage insulation part 60 Input connector 62 Master Module microcomputer 64 Power supply stabilization circuit 70 Transmitter 72 Receiver 75 Shipping setting device 77 Resistance 100 Cell voltage measuring device 124 Transmitting coil 126 Receiving coil 200 Stacked battery 204 Tab 224 Transmitting electrode 226 Receiving electrode 231 Channel switch 232 AD converter 234 Arithmetic unit 235 Memory 236 Communication interface 261 Isolated DC / DC converter 262 Insulated signal transmission element 324 Transmission pole 326 Reception pole

Claims (15)

A plurality of cell voltage measurement modules arranged side by side to measure the voltage of one or a plurality of cells of the laminated battery;
Among the plurality of cell voltage measurement modules, an address assigning device that assigns continuous addresses to adjacent cell voltage measurement modules;
A cell voltage measuring device having: The cell voltage measuring device according to claim 1,
The address assignment device is a cell voltage measurement device incorporated in the plurality of cell voltage measurement modules. The cell voltage measuring device according to claim 2, wherein
The addressing device includes a module intercommunication unit that performs communication between adjacent cell voltage measurement modules;
Based on communication by the module intercommunication unit, an address setting unit that sets the continuous address to the adjacent cell voltage measurement modules;
A cell voltage measuring device having: The cell voltage measuring device according to claim 3, wherein
The module intercommunication unit includes a transmission unit that transmits a signal to a cell voltage measurement module next to the cell voltage measurement module, and a reception unit that receives a signal from the previous cell voltage measurement module,
The address setting unit sets an address of the cell voltage measurement module when a signal from the previous cell voltage measurement module is received by the reception unit or when reception of the signal is stopped,
The module intercommunication unit, when an address is set by the address setting unit, transmits a signal to the next cell voltage measurement module by the transmission unit or stops transmission of the signal. The cell voltage measuring device according to claim 4,
The address setting unit is a cell voltage measurement device that sets a predetermined head address when a signal from the previous cell voltage measurement module is received by the reception unit. The cell voltage measuring device according to claim 4 or 5,
The address setting unit is set to the previous cell voltage measurement module when a signal from the previous cell voltage measurement module is received by the reception unit or reception of the signal is stopped. A cell voltage measuring device that acquires the immediately preceding module address that is an address and sets the next address of the acquired immediately preceding module address. The cell voltage measuring device according to claim 6, wherein
A main module that receives an address assignment command from the address assignment device and the address given to the cell voltage measurement module; and a bus line that communicatively connects the cell voltage measurement module and the main module. ,
The immediately preceding module address is output to the bus line,
The address setting unit is a cell voltage measurement device that acquires the immediately preceding module address output to the bus line. The cell voltage measuring device according to claim 7,
The cell voltage measurement module includes:
A plurality of connectors respectively coupled to a plurality of tabs corresponding to the plurality of cells of the laminated battery;
An input voltage processing circuit connected to the plurality of connectors and performing a voltage adjustment process for adjusting a cell voltage input through the connectors;
A voltage measurement value calculation processing circuit for calculating a cell voltage measurement value by AD converting the cell voltage subjected to the voltage adjustment processing;
A voltage insulator that prevents transmission of voltage from the stacked battery to the bus line;
A cell voltage measuring device having: The cell voltage measuring device according to claim 8, wherein
The voltage measurement value calculation processing circuit is:
An AD converter for performing the AD conversion;
A cell switch for switching a connector connected to the AD converter from the plurality of connectors;
An arithmetic unit for calculating a cell voltage measurement value from the value of the AD converter;
A serial output port for outputting the calculated cell voltage measurement value;
A cell voltage measuring device having: The cell voltage measurement device according to any one of claims 7 to 9,
The main module is a cell voltage measurement device that issues the address assignment command when the cell voltage measurement device is activated for the first time. It is a cell voltage measuring device given in any 1 paragraph of Claims 7-10,
When the address assignment device finishes giving the address, it outputs address assignment end information to the main module as a response to the address assignment command,
The main module is a cell voltage measurement device that determines whether or not the number of the cell voltage measurement modules is a predetermined number based on the response from the address assigning device. It is a cell voltage measuring device given in any 1 paragraph of Claims 7-11,
The main module is
A main module signal transmission unit that transmits a signal to the reception unit of the cell voltage measurement module at the top,
A cell voltage measuring device that transmits a signal by the main module signal transmitter as the address assignment command. The cell voltage measuring device according to claim 12, wherein
The main module is
A main module signal receiver that receives a signal from the transmitter of the cell voltage measurement module at the end;
A cell voltage measuring device in which a signal is received by the main module signal receiving unit as the address assignment end information. The cell voltage measuring device according to any one of claims 7 to 13,
The main module is a cell voltage measuring device incorporated in a host controller that controls a predetermined system in which the laminated battery is used. The cell voltage measurement device according to any one of claims 4 to 14,
A shipping setting device for transmitting a signal to the reception unit of the cell voltage measurement module at the top,
A cell voltage measuring device in which address setting by the address setting unit is started when the leading cell voltage measuring module receives transmission of a signal from the shipment setting device.

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