JP2019090659A - Voltage detector - Google Patents

Abstract

To provide a voltage detector with which it is possible to make components sharable as much as possible even when patterns that each detection block can take are different.SOLUTION: A voltage detector 20 comprises terminals T1-T11 for detection, input-side connection parts LI1- LI11, intermediate connection parts MM1-MM11, input-side switches SW1-SW11, a capacitor 21, a first path K1, a second path K2, a voltage detection unit 23, output-side switches 22a, 22b, and jumpers 31-39, the voltage detector being constituted so as to correspond to a pattern that a detection block can take depending on installed positions of the jumpers 31-39.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a voltage detection device applied to a battery assembly having a series connection of a plurality of battery modules.

  As a voltage detection device of this type, as shown in Patent Document 1, a flying capacitor type is known. This device detects the voltage of each detection block configured by dividing the plurality of battery modules. Each detection block includes at least one battery module. Patent Document 1 discloses a voltage detection device corresponding to the case where the possible pattern of each detection block is a specific pattern.

Patent No. 5955507 gazette

  For example, the possible patterns of each detection block may differ depending on the specification of the voltage detection device. Specifically, for example, each detection block may be one battery module, or some of the detection blocks may be a series connection of a plurality of battery modules. Even if the possible patterns of each detection block are different, for example, in order to suppress an increase in the types of parts constituting the voltage detection device, commonality of the parts in the voltage detection device corresponding to each different pattern It is required to

  The main object of the present invention is to provide a voltage detection device capable of achieving the commonality of parts as much as possible even if the possible patterns of each detection block may be different.

  The present invention relates to a voltage detection apparatus applied to an assembled battery having a series connection of a plurality of battery modules, wherein a plurality of detection blocks are configured by dividing the plurality of battery modules, and each of the detection blocks is at least The negative electrode terminal of the battery module at the lowest potential side among the plurality of battery modules including the one battery module, the positive electrode terminal of the battery module at the highest potential side, and one positive electrode terminal of the adjacent battery modules A detection terminal individually provided corresponding to each connection point with the other negative electrode terminal, and an input side provided separately corresponding to each detection terminal and electrically connected to the detection terminal A connecting portion, an intermediate connecting portion individually provided corresponding to each of the input side connecting portions, and provided at a position separated from the input side connecting portion; Among the side connections, the positive and negative terminals of the detection block are individually provided correspondingly to the respective input connections, and the input connection and the input connection corresponding to the input connection. An input-side switch for opening and closing between the intermediate connection portion, a capacitor, and a first path forming a path for electrically connecting the intermediate connection portion corresponding to the input-side switch and the first end of the capacitor Detecting a voltage of the detection block on the basis of a voltage of the second path that constitutes a path electrically connecting the intermediate connection corresponding to the input-side switch and the second end of the capacitor; A voltage detection unit, an output-side switch for opening and closing between the capacitor and the voltage detection unit, and a jumper, and the pattern that the detection block can take depending on the location of the jumper It has been with the corresponding configuration.

  According to the present invention, it is possible to increase the degree of freedom in the connection aspect between the input side switch and the capacitor corresponding to the positive electrode terminal and the negative electrode terminal of each detection block by the installation place of the jumper. For this reason, even if the patterns that can be taken by the detection blocks may be different, the parts of the voltage detection device can be shared as much as possible.

  In addition, as a structure which can respond to the pattern which the said detection block can take by the installation location of the said jumper, the following invention is specifically employable, for example. In the invention, the first main path as the first path is electrically connected to the first end of the capacitor, and the second main path as the second path is electrically connected to the second end of the capacitor. And the main connection provided separately corresponding to the third and subsequent intermediate connections counted from the lowest potential side among the respective intermediate connections, and provided at a distance from the intermediate connection. A sub-connection provided separately at a position separated from the intermediate connection, separately corresponding to the third and subsequent intermediate connections counted from the lowest potential side among the intermediate connections; Each of the intermediate connection portions on the lowest potential side among the intermediate connection portions and each of the main connection portions are electrically connected to the first main path, and among the respective intermediate connection portions The second intermediate connection counting from the lowest potential intermediate connection, Note that each of the sub-connections is electrically connected to the second main path, and the jumpers are provided on positive terminals of even-numbered detection blocks counted from the lowest potential side among the detection blocks. Between the corresponding main connection portion and the intermediate connection portion corresponding to the main connection portion, and among the detection blocks, the odd-numbered third and subsequent detection blocks counted from the lowest potential side The sub connection portions corresponding to the respective positive electrode terminals are electrically connected to the intermediate connection portions corresponding to the sub connection portions.

  Moreover, as a structure which can respond to the possible pattern of the said detection block by the installation location of the said jumper, the following invention can also be employ | adopted specifically, for example. The invention provides a first output path, which is provided at a position separated from the first main input path as the first path, and is electrically connected to the first end of the capacitor, and the second path. A second output side path provided at a position separated from the second main input side path and electrically connected to the second end of the capacitor, a first sub-input side path as the first path, and A second sub-input side path as two paths, the output side switch being provided for each of the first output side path and the second output side path, and the lowest potential side of the respective intermediate connection portions And the first main input side path is connected to the odd-numbered intermediate connection portion, and the second main input side is connected to the even-numbered intermediate connection portion counted from the lowest potential side among the intermediate connection portions. A path is connected, and at least one of the detection blocks Corresponds to the positive electrode terminal of the odd-numbered detection block and the negative electrode terminal of the even-numbered detection block, counting from the highest potential side among the detection blocks when it is assumed that is a series connection of a plurality of battery modules Of the detection blocks in the case where it is assumed that the intermediate connection portion to be connected is connected to the first sub-input-side path, and at least one of the detection blocks is a series connection of a plurality of battery modules; The intermediate connection corresponding to the negative terminal of the odd-numbered detection block and the positive terminal of the even-numbered detection block counted from the highest potential side is connected to the second sub-input side path, and the jumper is Between the first main input path and the first output path and between the second main input path and the second output path, or 1 are electrically connected to each between the sub between the input side path and said first output-side path and the second auxiliary input path and said second output path.

  Moreover, as a structure which can respond to the possible pattern of the said detection block by the installation location of the said jumper, the following invention can also be employ | adopted specifically, for example. In the invention, as a possible pattern of each detection block, a first pattern in which each detection block is one battery module, and at least a second of the detection blocks counted from the lowest potential side. Among the detection blocks, there is a second pattern in which the detection block is one battery module, and at least the third detection block counting from the lowest potential side is a series connection of the plurality of battery modules, and There is a third pattern in which the detection block on the lowest potential side is one battery module and at least the second detection block counting from the lowest potential side is a series connection of a plurality of the battery modules, It is provided at a position separated from the first main input path as the first path, and electrically connected to the first end of the capacitor. A second output path provided at a position separated from the connected first output path and the second main input path as the second path and electrically connected to the second end of the capacitor; A first sub-input side path as the first path and a second sub-input side path as the second path, and the output side switch includes the first output side path and the second output side path The first main input side path is connected to an odd-numbered intermediate connection portion counted from the lowest potential side among the respective intermediate connection portions, and the lowest potential side among the respective intermediate connection portions. And the second main input path is connected to the even-numbered intermediate connection portion, and the lowest of the detection blocks in the case where it is assumed that the pattern of each detection block is the second pattern Odd from the potential side and The intermediate connection corresponding to the positive terminal of the third and subsequent detection blocks is electrically connected to the first sub-input path, and it is assumed that the pattern of each detection block is the third pattern Among the detection blocks in the case, the intermediate connection corresponding to the positive electrode terminal of the even-numbered detection block counting from the lowest potential side is electrically connected to the first sub-input-side path, Among the detection blocks in the case where it is assumed that the pattern of the detection block is the second pattern, the intermediate connection corresponding to the positive electrode terminal of the even-numbered detection block counting from the lowest potential side is the first sub It is electrically connected to the input path, and the lowest of the detection blocks in the case where it is assumed that the pattern of each detection block is the third pattern The intermediate connection portion corresponding to the positive electrode terminal of the third and subsequent detection blocks which are odd-numbered from the potential side is electrically connected to the second sub-input side path, and the jumper is Between the first main input path and the first output path, and between the second main input path and the first output path, the first sub input path and the first output path Between the second sub-input side path and the first output side path, and the second intermediate connection portion and the first sub-input side path counting from the lowest potential side among the respective intermediate connection portions And between the intermediate connection at the lowest potential side of the intermediate connections and the second auxiliary input path, or the first auxiliary input path and the first output path Between the second sub-input side path and the second output side path, and the lowest of the respective intermediate connections Between the second intermediate connection and the second sub-input-side path, and between the intermediate connection on the lowest potential side among the respective intermediate connections and the first sub-input-side path Are connected electrically.

BRIEF DESCRIPTION OF THE DRAWINGS The figure which shows the power supply system which concerns on 1st Embodiment. The figure which shows the outline of an assembled battery. The figure which shows an example of the connection aspect by a jumper. The figure which shows the power supply system which concerns on 2nd Embodiment. The figure which shows the detection block corresponding to the operation aspect of the input side switch. The figure which shows the power supply system which concerns on a modification to 2nd Embodiment. The figure which shows the power supply system which concerns on 3rd Embodiment. The figure which shows the detection block corresponding to the operation aspect of the input side switch. The figure which shows the power supply system which concerns on a modification to 3rd Embodiment. The figure which shows the power supply system which concerns on 4th Embodiment. The figure which shows the power supply system which concerns on 5th Embodiment. The figure which shows the power supply system which concerns on 6th Embodiment. The figure which shows the power supply system which concerns on the modification 1 of 6th Embodiment. The figure which shows the power supply system which concerns on the modification 2 of 6th Embodiment. The figure which shows the power supply system which concerns on 7th Embodiment. The figure which shows the power supply system which concerns on 8th Embodiment. The figure which shows the power supply system which concerns on 9th Embodiment.

First Embodiment
Hereinafter, a first embodiment in which a voltage detection device according to the present invention is embodied will be described with reference to the drawings. The voltage detection device according to the present invention is applied to, for example, a power supply system mounted on a hybrid vehicle or an electric vehicle.

  As shown in FIG. 1, the power supply system includes an assembled battery 10. The battery pack 10 serves as a power supply source of an on-vehicle electrical load including a rotating electric machine for traveling of the vehicle (not shown). The assembled battery 10 includes a series connection of battery cells as single cells, and the inter-terminal voltage is, for example, several hundred volts. As the battery cell, for example, a storage battery such as a lithium ion battery or a nickel hydrogen storage battery can be used.

  In the present embodiment, a battery module is configured by integrating a series connection of at least two battery cells among the battery cells constituting the assembled battery 10. The battery assembly 10 includes a plurality of battery modules. In the present embodiment, each battery module includes the same number of battery cells, and the rated voltages are the same. In the present embodiment, for convenience of explanation, the battery assembly 10 is provided with ten battery modules. Hereinafter, in the present embodiment, among the battery modules constituting the assembled battery 10, the first battery module B1, the second battery module B2,..., And the tenth battery module B10 are referred to in order from the battery module on the lowest potential side. I assume.

  In the present embodiment, each of the first to tenth battery modules B1 to B10 corresponds to a detection block. The pattern taken by the detection block of this embodiment is a first pattern.

  As shown in FIG. 2, each of the battery modules B1 to B10 has a flat rectangular parallelepiped shape. The battery modules B <b> 1 to B <b> 10 are arranged in a line while being in contact with each other. A plate-like plate member P is in contact with the first battery module B1 at the lowest electric potential side and the tenth battery module B10 at the highest electric potential side among the battery modules B1 to B10. The plate member P is made of, for example, a metal material.

  Returning to the description of FIG. 1, the voltage detection device 20 includes a circuit board, and the circuit board is provided with first to eleventh detection terminals T1 to T11. The number of detection terminals T1 to T11 is one more than the number of battery modules. When m is an integer from 1 to 10, the mth detection terminal Tm is connected to the negative electrode terminal of the mth module Bm via the mth input wiring INm. The positive terminal of the mth module Bm is connected to the (m + 1) th detection terminal Tm + 1 via the (m + 1) th input wiring INm + 1. Each of the input wirings IN1 to IN11 is integrated as, for example, a harness member in a state of being electrically insulated from each other.

  The voltage detection device 20 includes a capacitor 21, a first main path K1, and a second main path K2. The first main path K1 and the second main path K2 are formed on the circuit board. The first main path K1 is connected to the first end of the capacitor 21, and the second main path K2 is connected to the second end of the capacitor 21. The capacitor 21 is provided on a circuit board, and more specifically, for example, is mounted on a first surface of the circuit board or a second surface which is a back surface of the first surface. Hereinafter, the first and second surfaces are collectively referred to as the surface layer of the circuit board.

  The voltage detection device 20 includes first to eleventh input side connection parts LI1 to LI11 individually provided corresponding to the first to eleventh detection terminals T1 to T11. An m-th detection terminal Tm is connected to the m-th input-side connection unit LIm. The m-th input side connection portion LIm is formed on the circuit board.

  The voltage detection device 20 includes first to eleventh intermediate connection portions MM1 to MM11 individually provided corresponding to the first to eleventh input side connection portions IN1 to IN11. The m-th intermediate connection portion MMm is formed at a position separated from the m-th input-side connection portion LIm on the circuit board.

  The voltage detection device 20 includes first to ninth main connection portions LM1 to LM9. The first to ninth main connection portions LM1 to LM9 are individually provided corresponding to the third and subsequent intermediate connection portions MM3 to MM11 from the lowest potential side among the intermediate connection portions MM1 to MM11. When n is an integer from 3 to 111, the (n-2) th main connection portion LMn-2 is formed at a position separated from the nth intermediate connection portion MMn on the circuit board.

  The voltage detection device 20 includes first to ninth sub connection parts LS1 to LS9. The first to ninth sub connection portions LS1 to LS9 are individually provided corresponding to the third and subsequent intermediate connection portions MM3 to MM11 from the lowest potential side among the intermediate connection portions MM1 to MM11. In the circuit board, the (n-2) th sub-connection portion LSn-2 is formed at a position separated from the n-th intermediate connection portion MMn and the n-2th main connection portion LMn-2.

  The first main path K1 is connected to the first intermediate connection portion MM1 on the lowest potential side among the intermediate connection portions MM1 to MM11. A first main path K1 is connected to each of the main connection portions LM1 to LM9. A second main path K2 is connected to the second intermediate connection portion MM2 and the sub connection portions LS1 to LS9.

  The voltage detection device 20 includes first and second output side switches 22 a and 22 b, a differential amplifier circuit 23 as a voltage detection unit, and a control unit 100. The differential amplifier circuit 23 detects the terminal voltage of the detection block based on the terminal voltage of the capacitor 21. The first main path K1 is connected to one of the inverting input terminal side and the non-inverting input terminal side of the differential amplifier circuit 23 via the first output switch 22a. The second main path K2 is connected to the other via the second output switch 22b. In addition, as each output side switch 22a, 22b, N channel MOSFET, photo relay, or a relay with which a pair of sources were connected can be used, for example.

  The voltage detection device 20 includes first to eleventh input switches SW1 to SW11. The m-th input side switch SWm electrically connects the m-th input side connection portion LIm and the m-th intermediate connection portion MMm by being turned on (close operation). On the other hand, the m-th input side switch SWm is electrically disconnected between the m-th input connection part LIm and the m-th intermediate connection part MMm by being turned off (opened). Note that, for example, an N-channel MOSFET, a photo relay, or a relay in which a pair of sources are connected can be used as each of the input side switches SW1 to SW11.

  The control unit 100 operates the output side switches 22a and 22b and the input side switches SW1 to SW11.

  The voltage detection device 20 includes first to ninth jumpers 31 to 39. In the present embodiment, chip jumpers are used as the jumpers 31 to 39. In the present embodiment, the jumpers 31 to 39 are mounted on the surface layer of the circuit board. The broken line in FIG. 1 indicates that no jumper is mounted on the surface. The place where the jumper is installed will be described below.

  First, third, fifth, seventh, ninth mains corresponding to positive terminals of second, fourth, sixth, eighth, tenth battery modules B2, B4, B6, B8, B10 in even number The third, fifth, seventh corresponding to the connection parts LM1, LM3, LM5, LM7, LM9 and the first, third, fifth, seventh, ninth main connection parts LM1, LM3, LM5, LM7, LM9 , 9th, 11th intermediate connection parts MM3, MM5, MM7, MM9, MM11 are connected by the first, third, fifth, seventh, ninth jumpers 31, 33, 35, 37, 39 ( Short circuit).

  Jumpers are provided between the second, fourth, sixth and eighth main connection sections LM2, LM4, LM6 and LM8 and the fourth, sixth, eighth and tenth intermediate connection sections MM4, MM6, MM8 and MM10. It is electrically disconnected because it is not connected.

  Second, fourth, sixth, eighth auxiliary connection parts LS2, LS4, LS6, corresponding to positive terminals of third, fifth, seventh, ninth battery modules B3, B5, B7, B9 at odd numbers respectively The second, fourth, sixth and eighth jumpers 32, 34, 36 and 38 connect between the LS 8 and the fourth, sixth, eighth and tenth intermediate connection portions MM4, MM6, MM8 and MM10. It is done.

  First, third, fifth, seventh, ninth sub-connections LS1, LS3, LS5, LS7, LS9 and third, fifth, seventh, ninth, eleventh intermediate connection MM3, MM5, MM7 , MM 9 and MM 11 are electrically disconnected because they are not connected by jumpers.

  In the present embodiment, jumpers corresponding to the first intermediate connection portion MM1 and the second intermediate connection portion MM2 are not provided.

  Incidentally, FIG. 3 shows that each of the third intermediate connection portion MM3 and the first main connection portion LM1 formed on the surface layer of the circuit board is connected by the first jumper 31. When the circuit board is a multilayer board, each input connection portion, each intermediate connection portion, each main connection portion, each sub connection portion, and at least a portion of each of the first main path K1 and the second main path K2 are multilayers. It may be formed in the inner layer of the substrate. Here, the inner layer is a layer sandwiched between a pair of surface layers of the multilayer substrate.

  Subsequently, a voltage detection method of the detection block will be described.

  The control unit 100 selects a detection block to be detected. Hereinafter, the case where the third battery module B3 is selected as the detection block will be described as an example.

  First, with the output switches 22a and 22b turned off, the control unit 100 turns on the third and fourth input switches SW3 and SW4 corresponding to the positive and negative terminals of the selected third battery module B3. Do. Thereby, charging current flows from the third battery module B3 to the capacitor 21.

  The control unit 100 switches the third and fourth input switches SW3 and SW4 to the off operation, and then switches the output switches 22a and 22b to the on operation. Thereby, a voltage corresponding to the terminal voltage of the capacitor 21 is input from the differential amplifier circuit 23 to the control unit 100. The control unit 100 calculates the terminal voltage of the third battery module B3 based on the output signal of the differential amplifier circuit 23.

  The control unit 100 implements the above-described voltage detection while sequentially selecting detection blocks from the first to tenth battery modules B1 to B10. In the present embodiment, the detection range of the differential amplifier circuit 23 is set to a range suitable for the rated voltage of one battery module, and specifically, for example, the above-mentioned rated voltage or a value slightly higher than that voltage. It is set.

  According to the present embodiment described above, voltage detection corresponding to the first pattern can be implemented by mounting the input side switch and the jumper corresponding to the first pattern on the circuit board.

Second Embodiment
Hereinafter, the second embodiment will be described focusing on differences from the first embodiment with reference to the drawings. In the present embodiment, as shown in FIG. 4, one battery module and a series connection of two battery modules are mixed as a detection block constituting the battery assembly 10. The pattern taken by the detection block of this embodiment is referred to as a second pattern. In FIG. 4, the same components as those shown in FIG. 1 are given the same reference numerals for the sake of convenience.

  In the second pattern, each battery module B1 to B10 is divided into first to seventh detection blocks A1 to A7. The first and second detection blocks A1 and A2 are first and second battery modules B1 and B2, respectively. The third detection block A3 is a series connection of the third and fourth battery modules B3 and B4, and the fourth detection block A4 is a series connection of the fifth and sixth battery modules B5 and B6. The detection block A5 is a series connection body of seventh and eighth battery modules B7 and B8. The sixth and seventh detection blocks A6 and A7 are ninth and tenth battery modules B9 and B10.

  Incidentally, in the second pattern, the detection blocks on the low potential side and the high potential side are made into one battery module for the reason described below. As shown in FIG. 2, among the battery modules B1 to B10, the temperature change of the lowest and highest potential side first and tenth battery modules B1 and B10 located at the end is the temperature change of the other battery modules. Greater than. This is because, for example, the first and tenth battery modules B1 and B10 abut on the plate member P, and the plate member P deprives the heat of the first and tenth battery modules B1 and B10. In this case, when voltage detection is performed in units of a plurality of battery modules including the battery modules at the end, the voltage detection accuracy of the battery modules at the end is reduced compared to the case where voltage detection is performed for one battery module at the end. Resulting in. In order to avoid such a problem, each detection block located at the end is made into one battery module.

  In the present embodiment, the power supply system is not provided with the fourth, sixth, and eighth input wires IN4, IN6, and IN8. Further, the power supply system is not provided with the fourth, sixth and eighth input side switches SW4, SW6 and SW8. For this reason, the fourth, sixth, and eighth input side connection portions LI4, LI6, and LI8 are electrically disconnected from the fourth intermediate connection portions MM4, MM6, and MM8.

  The control unit 100 operates the output switches 22a and 22b and the input switches SW1 to SW3, SW5, SW7, and SW9 to SW11. FIG. 5 shows the relationship between the input-side switch to be turned on and the corresponding detection block. Further, in the present embodiment, the detection range of the differential amplifier circuit 24 is set to a range suitable for the rated voltage of the series connection of two battery modules. Specifically, for example, the rated voltage of this series connection or It is set to a value slightly higher than that voltage.

  The voltage detection device 20 includes first to sixth jumpers 41 to 46.

  First, fifth, eighth main connection portions LM1, LM5, LM8 corresponding to positive terminals of second, fourth, sixth detection blocks A2, A4, A6 respectively, and third, seventh, tenth intermediate connection The parts MM3, MM7 and MM10 are connected by first, third and fifth jumpers 41, 43 and 45, respectively.

  Jumpers are provided between the second to fourth, sixth, and seventh main connection portions LM2 to LM4, LM6, and LM7, and the fourth to sixth, eighth, and ninth intermediate connection portions MM4 to MM6, MM8, and MM9. It is electrically disconnected because it is not connected.

  Third, seventh, ninth sub-connections LS3, LS7, LS9, and fifth, ninth, eleventh intermediate connections corresponding to the positive terminals of the third, fifth, seventh detection blocks A3, A5, A7, respectively The sections MM5, MM9 and MM11 are connected by second, fourth and sixth jumpers 42, 44 and 46, respectively.

  First, second, fourth to sixth, eighth sub connection parts LS1, LS2, LS4 to LS6, LS8 and third, fourth, sixth to eighth, tenth intermediate connection parts MM3, MM4, MM6 Since ~ 8 and MM10 are not connected by jumpers, they are electrically disconnected.

  According to the present embodiment described above, it is possible to implement voltage detection corresponding to the second pattern by diverting the configuration that can also correspond to the first pattern. For this reason, it is possible to achieve commonality of the components constituting the voltage detection device 20.

Modification of Second Embodiment
As shown in FIG. 6, the voltage detection device 20 may include the first and second differential amplifier circuits 23 and 24. In this case, the second differential amplifier circuit 24 is used when the third to fifth detection blocks A3 to A5 are selected, and the first, second, sixth, and seventh detection blocks A1, A2, A6, and A7 are used. The first differential amplifier circuit 23 may be used in the case where is selected. In FIG. 6, the same components as those shown in FIG. 4 are denoted by the same reference numerals for the sake of convenience.

  Incidentally, in the configuration shown in FIG. 6, as described in Patent Document 1, the control unit 100 determines in advance the absolute value of the difference between the first differential amplifier circuit 23 and the second differential amplifier circuit 24. If it is determined that the determination value is exceeded, it may be determined that an abnormality has occurred in the voltage detection device 20.

Third Embodiment
The third embodiment will be described below with reference to the drawings, focusing on the differences from the first embodiment. In the present embodiment, as shown in FIG. 7, one battery module, a series connection of two battery modules, and a series connection of three battery modules are mixed as detection blocks constituting the battery assembly 10. ing. The pattern taken by the detection block of this embodiment is referred to as a third pattern. In FIG. 7, the same components as those shown in FIG. 1 are denoted by the same reference numerals for the sake of convenience.

  In the third pattern, each battery module B1 to B10 is divided into first to sixth detection blocks A1 to A6. The first detection block A1 is a first battery module B1. The second detection block A2 is a series connection of the second and third battery modules B2 and B3, and the third detection block A3 is a series connection of the fourth to sixth battery modules B4 to B6. The fourth detection block A4 is a series connection body of seventh and eighth battery modules B7 and B8, and the fifth and sixth detection blocks A5 and A6 are ninth and tenth battery modules B9 and B10.

  In the present embodiment, the power supply system is not provided with the third, fifth, sixth, and eighth input wires IN3, IN5, IN6, and IN8. Further, the power supply system is not provided with the third, fifth, sixth and eighth input side switches SW3, SW5, SW6 and SW8. Therefore, between the third, fifth, sixth and eighth input side connection parts LI3, LI5, LI6 and LI8 and the third, fifth, sixth and eighth intermediate connection parts MM3, MM5, MM6 and MM8 Are electrically disconnected.

  The control unit 100 operates the output switches 22a and 22b and the input switches SW1, SW2, SW4, SW7, and SW9 to SW11. FIG. 8 shows the relationship between the input-side switch to be turned on and the corresponding detection block. Further, in the present embodiment, the detection range of the differential amplifier circuit 25 is set to a range suitable for the rated voltage of the series connection of three battery modules, and specifically, for example, the rated voltage of the series connection or It is set to a value slightly higher than that voltage.

  The voltage detection device 20 includes first to fifth jumpers 51 to 55.

  The second, seventh, ninth main connection parts LM2, LM7, LM9, and the fourth, ninth, eleventh intermediate connections corresponding to the positive terminals of the second, fourth, sixth detection blocks A2, A4, A6, respectively The parts MM4, MM9, and MM11 are connected by first, third, and fifth jumpers 51, 53, 55, respectively.

  Jumpers are provided between the first, third to sixth, eighth main connecting portions LM1, LM3 to LM6, LM8 and the third, fifth to eighth, tenth intermediate connecting portions MM3, MM5 to MM8, MM10. It is electrically disconnected because it is not connected.

  Between the fifth and eighth sub-connections LS5 and LS8 corresponding to the positive terminals of the third and fifth detection blocks A3 and A5 and the seventh and tenth intermediate connections MM5 and MM10, 4 jumpers 52 and 54 are connected.

  First to fourth, sixth, seventh, ninth secondary connection parts LS1 to LS4, LS6, LS7, LS9, and third to sixth, eighth, ninth, eleventh intermediate connection parts MM3 to MM6, MM8 , MM 9 and MM 11 are electrically disconnected because they are not connected by jumpers.

  According to the present embodiment described above, it is possible to implement voltage detection corresponding to the third pattern by diverting the configuration that can also correspond to the first and second. For this reason, it is possible to achieve commonality of the components constituting the voltage detection device 20.

<Modification of Third Embodiment>
As shown in FIG. 9, the voltage detection device 20 may include first, second and third differential amplifier circuits 23, 24 and 25. In this case, the third differential amplifier circuit 25 is used when the third detection block A3 is selected, and the second differential amplifier circuit 24 is used when the second and fourth detection blocks A2 and A4 are selected. The first differential amplifier circuit 23 may be used when the first, fifth, and sixth detection blocks A1, A5, and A6 are selected. In FIG. 9, the same components as those shown in FIG. 7 are denoted by the same reference numerals for the sake of convenience.

  Incidentally, in the configuration shown in FIG. 9, the abnormality determination of the voltage detection device 20 as described in the modification of the second embodiment may be performed.

Fourth Embodiment
The fourth embodiment will be described below with reference to the drawings, focusing on the differences from the first embodiment. In this embodiment, as shown in FIG. 10, the configuration is changed to reduce the number of jumpers. In FIG. 10, the same components as those shown in FIG. 1 are denoted by the same reference numerals for the sake of convenience. In the present embodiment, the pattern taken by the detection block is a first pattern.

  The voltage detection device 20 includes a first main input path KM1, a second main input path KM2, a first output path LO1, and a second output path LO2. Each path KM1, KM2, LO1, LO2 is formed on the circuit board. The first output side path LO1 is formed at a position separated from the first main input side path KM1 on the circuit board. The first end of the capacitor 21 is connected to the first output path LO1. The second output side path LO2 is formed at a position separated from the second main input side path KM2 on the circuit board. The second end of the capacitor 21 is connected to the second output path LO2.

  A first output switch 22a is provided on the differential amplifier circuit 23 side of the connection point with the capacitor 21 in the first output path LO1. A second output switch 22b is provided on the differential amplifier circuit 23 side of the connection point with the capacitor 21 in the second output path LO2.

  The voltage detection device 20 includes a first sub input side path KS1 and a second sub input side path KS2. The first sub input side path KS1 and the second sub input side path KS2 are formed on the circuit board.

  The first, third, fifth, seventh, ninth, and eleventh intermediate connection units MM1, MM3, MM5, MM7, MM9, and MM11 that are odd-numbered from the lowest potential side among the intermediate connection units MM1 to MM11 Is connected to the first main input path KM1.

  The second, fourth, sixth, eighth, tenth intermediate connection portions MM2, MM4, MM6, MM8, MM10, which are even-numbered from the lowest potential side among the intermediate connection portions MM1 to MM11, The main input path KM2 is connected.

  As shown in FIG. 10, a first sub input side path KS1 is connected to the second, fifth, ninth, and eleventh intermediate connection portions MM2, MM5, MM9, and MM11. In this connection mode, referring to FIG. 11, among the detection blocks A1 to A7 in the case where it is assumed that the pattern taken by each detection block is the second pattern, the odd-numbered detection block counting from the highest potential side The intermediate connection corresponding to the positive electrode terminal of A7, A5, A3 and A1 and the negative electrode terminal of the even-numbered detection block A6, A4 and A2 corresponds to being connected to the first sub input side path KS1.

  As shown in FIG. 10, a second auxiliary input path KS2 is connected to the first, third, seventh and tenth intermediate connection portions MM1, MM3, MM7 and MM10. In this connection mode, referring to FIG. 11, among the detection blocks A1 to A7 in the case where it is assumed that the pattern taken by each detection block is the second pattern, the odd-numbered detection block counting from the highest potential side The intermediate connection corresponding to the negative electrode terminal of A7, A5, A3 and A1 and the positive electrode terminal of the even-numbered detection blocks A6, A4 and A2 is connected to the second auxiliary input path KS2.

  The voltage detection device 20 includes a first jumper 61 and a second jumper 62.

  The first jumper 61 connects between the first main input path KM1 and the first output path LO1. The second jumper 62 is connected between the second main input path KM2 and the second output path LO2. The first sub-input side path KS1 and the first output side path LO1 are electrically disconnected because they are not connected by a jumper. Further, the second sub-input side path KS2 and the second output side path LO2 are electrically disconnected since they are not connected by the jumper.

  According to the embodiment described above, voltage detection corresponding to the first pattern can be implemented while reducing the number of jumpers installed.

Fifth Embodiment
The fifth embodiment will be described below with reference to the drawings, focusing on the differences with the fourth embodiment. In the present embodiment, as shown in FIG. 11, the installation mode of the jumper corresponding to the second pattern is changed. In FIG. 11, the same components as those shown in FIGS. 1 and 10 are denoted by the same reference numerals for the sake of convenience.

  The voltage detection device 20 includes a first jumper 71 and a second jumper 72. The first jumper 71 connects between the first secondary input path KS1 and the first output path LO1. The second jumper 72 is connected between the second secondary input side path KS2 and the second output side path LO2.

  The first main input path KM1 and the first output path LO1 are electrically disconnected because they are not connected by a jumper. The second main input path KM2 and the second output path LO2 are electrically disconnected because they are not connected by a jumper.

  According to the present embodiment described above, it is possible to implement voltage detection corresponding to the second pattern while reducing the number of jumpers installed, using the configuration that can also correspond to the first pattern. For this reason, it is possible to achieve commonality of the components constituting the voltage detection device 20.

Modification of Fifth Embodiment
In the configuration shown in FIG. 11, the first and second differential amplifier circuits 23 and 24 may be provided as shown in FIG.

Sixth Embodiment
The sixth embodiment will be described below with reference to the drawings, focusing on the differences with the fifth embodiment. The present embodiment is configured to be compatible with the first to third patterns. In particular, in the present embodiment, as shown in FIG. 12, the configuration corresponds to the third pattern. In FIG. 12, the same components as those shown in FIGS. 9 and 10 are given the same reference numerals for the sake of convenience. Further, in the present embodiment, the first sub input side path KS1 is referred to as a first A sub input side path, and the second sub input side path KS2 is referred to as a first A sub input side path.

  The voltage detection device 20 includes a first B sub input side path KL1 and a second B sub input side path KL2. The first B sub-input side path KL1 and the second B sub-input side path KL2 are formed on the circuit board.

  The 1st B subinput side path KL1 is connected to the 1st, 4th, 9th, 11th middle connection parts MM1, MM4, MM9, MM11. In this connection mode, among the detection blocks A1 to A6 when it is assumed that the pattern taken by each detection block is the third pattern, the positive electrodes of the odd-numbered detection blocks A6, A4, and A2 counted from the highest potential side This corresponds to the fact that the intermediate connection portion corresponding to the terminal and the negative terminal of the even-numbered detection block A5, A3, A1 is connected to the first B sub-input side path KL1.

  The second B sub input side path KL2 is connected to the second, seventh, and tenth intermediate connection sections MM2, MM7, and MM10. In this connection mode, among the detection blocks A1 to A6 when it is assumed that the pattern taken by each detection block is the third pattern, the negative electrodes of the odd-numbered detection blocks A6, A4, and A2 counted from the highest potential side This corresponds to the fact that the intermediate connection portion corresponding to the terminal and the positive electrode terminal of the even-numbered detection block A5, A3, A1 is connected to the second B sub input side path KL2.

  The voltage detection device 20 includes a first jumper 81 and a second jumper 82.

  The first jumper 81 connects between the first B secondary input path KL1 and the first output path LO1. The second jumper 82 is connected between the second B secondary input path KL2 and the second output path LO2.

  According to the present embodiment described above, it is possible to implement voltage detection corresponding to the third pattern while reducing the number of jumpers installed, using the configuration that can also correspond to the first and second patterns.

<Modified Example 1 of Sixth Embodiment>
In the case of corresponding to the second pattern, the voltage detection device 20 may include the first jumper 91 and the second jumper 92 shown in FIG. In FIG. 13, the same components as those shown in FIG. 12 are denoted by the same reference numerals for the sake of convenience.

<Modification 2 of the sixth embodiment>
When it corresponds to a 1st pattern, the voltage detection apparatus 20 should just be equipped with the 1st jumper 101 and the 2nd jumper 102 which are shown in FIG. In FIG. 14, the same components as those shown in FIG. 12 are denoted by the same reference numerals for the sake of convenience.

Seventh Embodiment
The seventh embodiment will be described below with reference to the drawings, focusing on the differences with the first and fourth embodiments. The present embodiment is configured to be compatible with the first to third patterns. In particular, in the present embodiment, as shown in FIG. 15, the configuration corresponds to the first pattern. In FIG. 15, the same components as those shown in FIGS. 1 and 10 are denoted by the same reference numerals for the sake of convenience.

  A first secondary input path KS1 is connected to the fifth, ninth, and eleventh intermediate connection sections MM5, MM9, and MM11. In this connection mode, among the detection blocks A1 to A7 in the case where it is assumed that the pattern of each detection block is the second pattern, the third and subsequent detection blocks A3 are odd-numbered from the lowest potential side. , A5, and A7 correspond to the fact that the intermediate connection corresponding to the positive electrode terminal is connected to the first sub-input path KS1.

  A first secondary input path KS1 is connected to the fourth, ninth, and eleventh intermediate connection sections MM4, MM9, and MM11. In this connection mode, among the detection blocks A1 to A6 in the case where it is assumed that the pattern of each detection block is the third pattern, positive terminals of even-numbered detection blocks A2, A4 and A6 counted from the lowest potential side It corresponds to the fact that the intermediate connection corresponding to is connected to the first sub input path KS1.

  The second, sub-input side path KS2 is connected to the third, seventh, tenth intermediate connection portions MM3, MM7, MM10. This connection mode is a positive terminal of even-numbered detection blocks A2, A4 and A6 counted from the lowest potential side among the detection blocks A1 to A7 when it is assumed that the pattern of each detection block is the second pattern. It corresponds to the fact that the intermediate connection corresponding to is connected to the second sub input side path KS2.

  A second sub input side path KS2 is connected to the seventh and tenth intermediate connection portions MM7 and MM10. In this connection mode, among the detection blocks A1 to A6 in the case where it is assumed that the pattern of each detection block is the third pattern, the third and subsequent detection blocks A3 are odd-numbered from the lowest potential side. , A5 corresponds to the fact that the intermediate connection portion corresponding to the positive electrode terminal is connected to the second sub input path KS2.

  The voltage detection device 20 includes a first jumper 111 and a second jumper 112. The first jumper 111 connects between the first main input path KM1 and the first output path LO1. The second jumper 112 is connected between the second main input path KM2 and the first output path LO1.

  According to the present embodiment described above, the configuration corresponding to the second and third patterns is used to reduce the number of electrical paths (wirings) compared with the configuration shown in FIG. 12 to correspond to the first pattern. Voltage detection can be performed. For this reason, it is possible to achieve commonality of the components constituting the voltage detection device 20.

Eighth Embodiment
The eighth embodiment will be described below with reference to the drawings, focusing on the differences from the seventh embodiment. In the present embodiment, as shown in FIG. 16, the installation mode of the jumper corresponding to the second pattern is changed. In FIG. 16, the same components as those shown in FIGS. 6 and 15 are denoted by the same reference numerals for the sake of convenience.

  The voltage detection device 20 includes first to fourth jumpers 121 to 124.

  The first jumper 121 is connected between the first secondary input path KS1 and the first output path LO1. A second jumper 122 connects between the second secondary input path KS2 and the first output path LO1.

  A second jumper 123 is connected between the second middle connection part MM2 and the first sub-input side path KS1 counting from the lowest potential side among the middle connection parts MM1 to MM11. A fourth jumper 124 connects between the first intermediate connection portion MM1 on the lowest potential side and the second sub-input side path KS2 among the intermediate connection portions MM1 to MM11.

  According to the embodiment described above, the voltage detection corresponding to the second pattern can be performed while reducing the number of wires.

The Ninth Embodiment
The ninth embodiment will be described below with reference to the drawings, focusing on the differences from the seventh embodiment. In the present embodiment, as shown in FIG. 17, the installation mode of the jumper corresponding to the third pattern is changed. In FIG. 17, the same components as those shown in FIGS. 9 and 15 are denoted by the same reference numerals for the sake of convenience.

  The voltage detection device 20 includes first to fourth jumpers 131 to 134.

  The first jumper 131 is connected between the first secondary input path KS1 and the first output path LO1. The second jumper 132 is connected between the second secondary input side path KS2 and the second output side path LO2.

  A second jumper 133 is connected between the second middle connection part MM2 and the second sub-input side path KS2 counting from the lowest potential side among the middle connection parts MM1 to MM11. A fourth jumper 134 connects between the first intermediate connection portion MM1 on the lowest potential side and the first sub-input side path KS1 among the intermediate connection portions MM1 to MM11.

  According to the present embodiment described above, the voltage detection corresponding to the third pattern can be performed while reducing the number of wires.

<Other Embodiments>
The above embodiments may be modified as follows.

  The jumper is not limited to a chip, and may be, for example, a pin-like jumper pin or a jumper wire.

  The rated voltage of each battery module may be different.

  The battery modules B1 to B10 are not limited to those integrated as shown in FIG. For example, each of the battery modules B1 to B10 may be divided and disposed in each space of the vehicle.

  DESCRIPTION OF SYMBOLS 10 Battery pack 20 Voltage detection device 21 Capacitor 23 Differential amplifier circuit 31 to 39 Jumpers 1 to 9 Jumpers K1 and K2 1st and 2nd main paths B1 to B10 1 to 10 battery modules, T1 to T11: first to eleventh detection terminals, LI1 to LI11, first to eleventh input side connection units, MM1 to MM11, first to eleventh intermediate connection units, SW1 to SW11 ... 1st to 11th input side switches, 22a, 22b ... 1st and 2nd output side switches.

Claims (9)

In a voltage detection device (20) applied to a battery assembly (10) having a series connection of a plurality of battery modules (B1 to B10),
A plurality of detection blocks (A1 to A7) are configured by dividing the plurality of battery modules, and each detection block includes at least one battery module,
Among the plurality of battery modules, the negative electrode terminal of the battery module (B1) at the lowest potential side and the positive electrode terminal of the battery module (B10) at the highest potential side, and one positive electrode terminal and the other of the adjacent battery modules Detection terminals (T1 to T11) individually provided corresponding to respective connection points with the negative electrode terminal;
Input-side connection parts (LI1 to LI11) provided individually corresponding to the detection terminals and electrically connected to the detection terminals;
Intermediate connection parts (MM1 to MM11) provided individually corresponding to the input side connection parts and provided at positions separated from the input side connection parts;
The positive and negative terminals of the detection block among the respective input connections are individually provided corresponding to the respective input connections to which the positive and negative terminals of the detection block are electrically connected. Input-side switches (SW1 to SW11) for opening and closing between the corresponding intermediate connection portions;
A capacitor (21),
A first path (K1, KM1, KS1, KL1) constituting a path electrically connecting the intermediate connection portion corresponding to the input side switch and the first end of the capacitor;
A second path (K2, KM2, KS2, KL2) constituting a path electrically connecting the intermediate connection portion corresponding to the input-side switch and the second end of the capacitor;
A voltage detection unit (23 to 25) for detecting the voltage of the detection block based on the voltage of the capacitor;
An output side switch (22a, 22b) for opening and closing between the capacitor and the voltage detection unit;
Jumpers (31 to 39, 41 to 46, 51 to 55, 61, etc.);
A voltage detection device configured to correspond to a possible pattern of the detection block depending on the installation location of the jumper. A first main path (K1) as the first path is electrically connected to the first end of the capacitor,
A second main path (K2) as the second path is electrically connected to the second end of the capacitor,
Main connections (LM1 to LM9) individually provided corresponding to the third and subsequent intermediate connections counted from the lowest potential side among the respective intermediate connections and separately from the intermediate connections When,
Sub-connections provided individually corresponding to the third and subsequent intermediate connections (MM3 to MM11) counted from the lowest potential side among the respective intermediate connections, and provided at a distance from the intermediate connection. (LS1 to LS9), and
Each of the intermediate connection portion (MM1) on the lowest potential side among the intermediate connection portions and each of the main connection portions is electrically connected to the first main path,
Each of the second intermediate connection (MM2) and each of the sub connections, counting from the intermediate connection on the lowest potential side among the respective intermediate connections, are electrically connected to the second main path, Yes,
The jumpers (31 to 39, 41 to 46, 51 to 55) are
Among the detection blocks, between the main connection portion corresponding to each positive terminal of the even-numbered detection block counting from the lowest potential side, and the intermediate connection portion corresponding to the main connection portion;
Among the detection blocks, the sub-connections corresponding to the positive terminals of the third and subsequent detection blocks are odd-numbered counting from the lowest potential side, and the intermediate connection corresponding to the sub-connections The voltage detection device according to claim 1, wherein the voltage detection device is electrically connected. A first output path (LO1) provided at a position separated from the first main input path (KM1) as the first path and electrically connected to the first end of the capacitor;
A second output path (LO2) provided at a position separated from the second main input path (KM2) as the second path and electrically connected to the second end of the capacitor;
A first secondary input path (KS1, KL1) as the first path;
A second secondary input path (KS2, KL2) as the second path;
The output switch is provided in each of the first output path and the second output path,
The first main input path is connected to an odd-numbered intermediate connection (MM1, MM3, MM5, MM7, MM9, MM11) counted from the lowest potential side among the respective intermediate connections,
The second main input path is connected to the even-numbered intermediate connection parts (MM2, MM4, MM6, MM8, MM10) counted from the lowest potential side among the respective intermediate connection parts,
Among the detection blocks in the case where it is assumed that at least one of the detection blocks is a series connection of a plurality of the battery modules, the positive terminal of the odd-numbered detection block counting from the highest potential side and the even number The intermediate connection corresponding to the negative terminal of the detection block is connected to the first sub-input side path,
Among the detection blocks in the case where it is assumed that at least one of the detection blocks is a series connection of a plurality of battery modules, the negative terminal and the even number of odd-numbered detection blocks counted from the highest potential side The intermediate connection corresponding to the positive terminal of the detection block is connected to the second sub-input path;
The jumpers (61, 62, 71, 72, 81, 82, 91, 92, 101, 102)
Between the first main input path and the first output path and between the second main input path and the second output path, or
The electric motor according to claim 1, wherein the first sub-input side path and the first output side path and the second sub-input side path and the second output side path are electrically connected to each other. Voltage detection device. Each said detection block is one said battery module,
The jumpers (61, 62, 101, 102) are disposed between the first main input path and the first output path and between the second main input path and the second output path, respectively. The voltage detection device according to claim 3, wherein the voltage detection device is electrically connected. Among the detection blocks, at least one of the detection block on the lowest potential side and the detection block other than the detection block on the highest potential side is a series connection of a plurality of the battery modules,
The jumpers (71, 72, 81, 82, 91, 92) are provided between the first sub input path and the first output path, and between the second sub input path and the second output path. The voltage detection device according to claim 3, wherein each of the two is electrically connected. As a possible pattern of each detection block,
A first pattern in which each detection block is one battery module;
Among the detection blocks, at least the second detection block (A1, A2) counted from the lowest potential side is one battery module (B1, B2), and at least three from the lowest potential side. A second pattern in which the second detection block (A3 to A5) is a series connection of the plurality of battery modules (B3 to B8);
Among the detection blocks, at least the detection block (A1) on the lowest potential side is one battery module (B1), and at least the second detection block (A2 to A4) counting from the lowest potential side There is a third pattern which is a series connection of a plurality of the battery modules (B2 to B8),
A first output path (LO1) provided at a position separated from the first main input path (KM1) as the first path and electrically connected to the first end of the capacitor;
A second output path (LO2) provided at a position separated from the second main input path (KM2) as the second path and electrically connected to the second end of the capacitor;
A first secondary input path (KS1) as the first path;
And a second secondary input path (KS2) as the second path,
The output switch is provided in each of the first output path and the second output path,
The first main input path is connected to an odd-numbered intermediate connection (MM1, MM3, MM5, MM7, MM9, MM11) counted from the lowest potential side among the respective intermediate connections,
The second main input path is connected to the even-numbered intermediate connection parts (MM2, MM4, MM6, MM8, MM10) counted from the lowest potential side among the respective intermediate connection parts,
Of the detection blocks (A1 to A7) in the case where it is assumed that the pattern of each detection block is the second pattern, the third and subsequent detection blocks (odd-numbered from the lowest potential side) The intermediate connection (MM5, MM9, MM11) corresponding to the positive electrode terminal of A3, A5, A7) is electrically connected to the first sub-input side path,
Of the detection blocks (A1 to A6) in the case where it is assumed that the pattern of each detection block is the third pattern, the even-numbered detection blocks (A2, A4, and A6) counted from the lowest potential side The intermediate connection (MM4, MM9, MM11) corresponding to the positive electrode terminal is electrically connected to the first auxiliary input path,
Of the detection blocks (A1 to A7) when it is assumed that the pattern of each detection block is the second pattern, the even-numbered detection blocks (A2, A4, and A6) counted from the lowest potential side The intermediate connection (MM3, MM7, MM10) corresponding to the positive electrode terminal is electrically connected to the second auxiliary input path,
Among the detection blocks (A1 to A6) in the case where it is assumed that the pattern of each detection block is the third pattern, the third and subsequent detection blocks (odd-numbered from the lowest potential side) The intermediate connection (MM7, MM10) corresponding to the positive electrode terminal of A3, A5) is electrically connected to the second auxiliary input path,
The jumpers (111, 112, 121 to 124, 131 to 134) are
Between the first main input path and the first output path, and between the second main input path and the first output path,
Counting from the lowest potential side among the intermediate connection portions between the first sub-input side path and the first output side path, between the second sub-input side path and the first output side path Between the second intermediate connection (MM2) and the first sub-input side path, and between the intermediate connection (MM1) on the lowest potential side among the respective intermediate connections and the second sub-input side path Between each, or
Counting from the lowest potential side among the intermediate connection portions between the first sub-input side path and the first output side path, between the second sub-input side path and the second output side path Between the second intermediate connection (MM2) and the second sub-input-side path, and between the intermediate connection (MM1) on the lowest potential side of the respective intermediate connections and the first sub-input-side path The voltage detection device according to claim 1, wherein each of the two is electrically connected. The pattern of each detection block is the first pattern,
The jumpers (111, 112) electrically connect the first main input path and the first output path, and the second main input path and the first output path, respectively. The voltage detection device according to claim 6, wherein the voltage detection device is connected to The pattern of each detection block is the second pattern,
The jumpers (121 to 124) are provided between the first sub input path and the first output path, between the second sub input path and the second output path, and at each of the intermediate connection portions. The second intermediate connection between the second intermediate connection and the first auxiliary input path, counting from the lowest electric potential side, and the intermediate connection between the lowest potential of the intermediate connections and the second auxiliary input The voltage detection device according to claim 6, wherein each of the paths is electrically connected. The pattern of each detection block is the third pattern,
The jumpers (131 to 134) are provided between the first sub input path and the first output path, between the second sub input path and the first output path, and at each of the intermediate connection portions. Between the second intermediate connection (MM2) and the second sub-input side path, counting from the lowest electric potential side among them, and the intermediate connection (MM1) at the lowest electric potential side among the intermediate connections, The voltage detection device according to claim 6, wherein each of the first sub input side paths is electrically connected.

Images