JP2015220206A - Power storage device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power storage device capable of reducing the number of wires arranged between a substrate and a monitoring unit while suppressing increase in size.SOLUTION: A first voltage detection circuit 53 and a second voltage detection circuit 52 are provided on a substrate 50 and arranged on both sides of a duct, respectively. The first voltage detection circuit detects a total voltage value V of two single batteries 10 connected in series. The second voltage detection circuit detects the total voltage value V of the two single batteries connected in series, and voltage values V, VBof the single battery arranged at one end in a predetermined direction. A monitoring unit 60 is connected with the first voltage detection circuit and the second voltage detection circuit via a communication line 54, and calculates a voltage value VB of each single battery on the basis of the voltage value of the single battery arranged at one end in the predetermined direction and the total voltage value.

Description

  The present invention relates to a power storage device having a circuit configuration for detecting a voltage value of a power storage element.

  In patent document 1, the gas discharge duct for discharging | emitting gas is provided above the battery cell. A circuit board on which electronic components are mounted is disposed above the gas discharge duct.

Japanese Patent Laying-Open No. 2010-080135 (FIG. 5) JP2013-109914A JP 2008-128845 A

  If the circuit board is arranged above the gas discharge duct as in Patent Document 1, the battery system is easily increased in size in the vertical direction.

  The power storage device of the present invention includes a plurality of power storage elements, a duct, a plurality of bus bars, a voltage detection line, a voltage detection circuit (a first voltage detection circuit and a second voltage detection circuit), and a monitoring unit. The plurality of power storage elements are arranged in a predetermined direction, and each power storage element includes an electrode terminal (a positive electrode terminal and a negative electrode terminal). The duct is disposed between two electrode terminals in each power storage element, and extends in a predetermined direction. The duct is used for moving the gas discharged from the power storage element.

  The plurality of bus bars are used for connecting a plurality of power storage elements in series. On both sides of the duct, a plurality of bus bars are arranged side by side in a predetermined direction. Each bus bar is fixed to the electrode terminal. The voltage detection line is provided on the substrate and is connected to each bus bar. On both sides of the duct, a first voltage detection circuit and a second voltage detection circuit are respectively arranged. The monitoring unit monitors the voltage value of each power storage element.

  The first voltage detection circuit is connected via a voltage detection line to a bus bar arranged on the side where the first voltage detection circuit is located with respect to the duct, and is a total voltage value of two power storage elements connected in series. Is detected. The second voltage detection circuit is arranged on the side where the second voltage detection circuit is located with respect to the duct, and on the side where the first voltage detection circuit is located with respect to the duct, and is arranged at one end in a predetermined direction. A voltage detection line is connected to a bus bar fixed to the electrode terminal of the storage element. The second voltage detection circuit detects the total voltage value of the two power storage elements connected in series and the voltage value of the power storage element arranged at one end in the predetermined direction.

  The monitoring unit is connected to the first voltage detection circuit and the second voltage detection circuit via a communication line. The monitoring unit calculates the voltage value of each power storage element based on the voltage value and the total voltage value of the power storage elements arranged at one end in the predetermined direction.

  In the present invention, since the voltage detection circuit and the substrate are disposed on both sides of the duct, the power storage device is larger than the configuration in which the voltage detection circuit is disposed on the opposite side of the storage element from the duct. It becomes easy to suppress. In addition, since the voltage detection circuit connected to the voltage detection line is provided on the substrate and the voltage detection circuit and the monitoring unit are connected via the communication line, compared to the configuration in which the voltage detection line is connected to the monitoring unit, The number of wirings arranged between the monitoring unit and the substrate can be reduced.

It is a disassembled perspective view of a battery pack. It is a top view of a battery pack. It is a figure which shows the relationship between the voltage value detected by a voltage detection circuit, and the voltage value of a cell. It is a figure which shows the relationship between the voltage value detected by a voltage detection circuit, and the voltage value of a cell.

  Examples of the present invention will be described below.

  The structure of the battery pack (corresponding to the power storage device of the present invention) 1 in this embodiment will be described with reference to FIGS. FIG. 1 is an exploded perspective view of the battery pack 1, and FIG. 2 is a top view of the battery pack 1. 1 and 2, the X axis, the Y axis, and the Z axis are axes orthogonal to each other. In this embodiment, the axis extending in the vertical direction is the Z axis.

  The battery pack 1 includes a plurality of single cells (corresponding to the storage element of the present invention) 10 arranged in the X direction (corresponding to a predetermined direction of the present invention). The number of the single cells 10 constituting the battery pack 1 can be set as appropriate. A partition member 20 made of an insulating material such as resin is disposed between two unit cells 10 adjacent in the X direction. The partition member 20 has a protruding portion that protrudes in the X direction, and a space is formed between the partition member 20 and the single cell 10 when the tip of the protruding portion contacts the single cell 10. This space is a space where a heat exchange medium for adjusting the temperature of the unit cell 10 moves.

  The unit cell 10 includes a battery case 11 that houses a power generation element. The power generation element is an element that performs charge and discharge, and includes a positive electrode plate, a negative electrode plate, and an electrolyte disposed between the positive electrode plate and the negative electrode plate. As the unit cell 10, a secondary battery such as a nickel metal hydride battery or a lithium ion battery can be used. An electric double layer capacitor can be used instead of the secondary battery.

  A positive terminal (electrode terminal) 12 and a negative terminal (electrode terminal) 13 are provided on the upper surface of the battery case 11. The positive electrode terminal 12 is connected to the positive electrode plate of the power generation element, and the negative electrode terminal 13 is connected to the negative electrode plate of the power generation element. A valve 14 is provided between the positive terminal 12 and the negative terminal 13 on the upper surface of the battery case 11. The valve 14 is used for discharging gas generated inside the battery case 11 to the outside of the battery case 11.

  A duct 30 is provided on the upper surface of the battery pack 1. Specifically, the duct 30 is disposed above the valve 14 and extends in the X direction. In other words, the duct 30 is disposed between the positive terminal 12 and the negative terminal 13 in each unit cell 10. In FIG. 2, the duct 30 is omitted. When the gas is exhausted from the valve 14, the gas moves along the duct 30. The plurality of single cells 10 are electrically connected in series by a bus bar 41. The bus bar 41 is fixed to the positive electrode terminal 12 and the negative electrode terminal 13 that are adjacent in the X direction. Specifically, the bus bar 41 is fixed to the positive electrode terminal 12 or the negative electrode terminal 13 in a state where the positive electrode terminal 12 or the negative electrode terminal 13 penetrates the bus bar 41.

  The bus bar 42 is fixed to the positive electrode terminal 12 of the unit cell 10 that becomes the positive electrode terminal of the battery pack 1. Specifically, the bus bar 42 is fixed to the positive terminal 12 in a state where the positive terminal 12 penetrates the bus bar 42. The bus bar 43 is fixed to the negative electrode terminal 13 of the unit cell 10 which becomes the negative electrode terminal of the battery pack 1. Specifically, the bus bar 43 is fixed to the negative electrode terminal 13 in a state where the negative electrode terminal 13 penetrates the bus bar 43. The unit cell 10 to which the bus bar 42 is connected is located at one end of the battery pack 1 in the X direction, and the unit cell 10 to which the bus bar 43 is connected is located at the other end of the battery pack 1 in the X direction. .

  Bus bars 41 to 43 are arranged on both sides of the duct 30 in the Y direction. On one side with respect to the duct 30, a plurality of bus bars 41 and bus bars 42 are arranged side by side in the X direction. Further, on the other side of the duct 30, a plurality of bus bars 41 and bus bars 43 are arranged side by side in the X direction.

  The bus bars 41 to 43 are connected to a voltage detection line 51 formed on the substrate 50. The substrate 50 is disposed at a position adjacent to the duct 30 in the XY plane. That is, the board | substrate 50 and the duct 30 are arrange | positioned in the same plane (XY plane). Here, the substrate 50 includes a first region 50A, a second region 50B, and a third region 50C.

  The first region 50A and the second region 50B extend in the X direction, and the duct 30 is disposed between the first region 50A and the second region 50B. Bus bars 41 to 43 are disposed between the first region 50A and the second region 50B. Here, bus bars 41 and 42 arranged in the X direction are arranged between the first region 50A and the duct 30, and bus bars 41 and 43 arranged in the X direction are arranged between the second region 50B and the duct 30. ing.

  Note that the first region 50A can also be arranged between the bus bars 41 and 42 and the duct 30 arranged in the X direction. Similarly, the second region 50B can be disposed between the bus bars 41 and 43 and the duct 30 arranged in the X direction. The third region 50C extends in the Y direction and is connected to the first region 50A and the second region 50B.

  In the substrate 50, voltage detection circuits 52 and 53 are provided in the first region 50A and the second region 50B, respectively. The voltage detection circuits 52 and 53 are disposed on both sides of the duct 30 in the Y direction. A voltage detection line 51 is connected to the voltage detection circuits 52 and 53, and the voltage detection circuits 52 and 53 detect the voltage value V of the two unit cells 10 connected in series as will be described later.

  The voltage detection circuit 52 is connected via a voltage detection line 51 to bus bars 41 and 42 arranged on the side where the voltage detection circuit 52 is located with respect to the duct 30. The voltage detection circuit 52 is connected to the bus bar 43 via the voltage detection line 51. A part of the voltage detection line 51 connecting the voltage detection circuit 52 and the bus bar 43 is formed in the third region 50 </ b> C of the substrate 50. The voltage detection circuit 53 is connected via a voltage detection line 51 to bus bars 41 and 43 disposed on the side where the voltage detection circuit 53 is located with respect to the duct 30.

  In the substrate 50, communication lines 54 are provided in the first region 50A and the second region 50B, respectively. One end of the communication line 54 is connected to the voltage detection circuits 52 and 53, and the other end of the communication line 54 is connected to the monitoring unit 60. Here, a part of the communication line 54 is located outside the substrate 50. The voltage value V detected by the voltage detection circuits 52 and 53 is transmitted to the monitoring unit 60 via the communication line 54. The monitoring unit 60 monitors the voltage value VB of each unit cell 10. As will be described later, the monitoring unit 60 calculates the voltage value VB of each unit cell 10 based on the voltage value V detected by the voltage detection circuits 52 and 53.

3 and 4 show a voltage value _V 0 _{~V 10} detected by the voltage detection circuits 52 and 53, and a voltage value _VB 0 _{through Vb 10} of each cell 10. A voltage detection circuit (corresponding to the second voltage detection circuit in the present invention) 52 detects voltage values V ₀ and V _n (n is an even number). The voltage value V ₀ is the voltage value VB _{0 of the unit} cell 10 arranged at one end of the battery pack 1 in the X direction. Voltage value V _n is a total voltage value of the two cells 10 connected in series. For example, the voltage value V ₂ is a total value of the voltage values VB ₁ and VB ₂ of the unit cell 10, and the voltage value V ₁₀ is a total value of the voltage values VB ₉ and VB ₁₀ of the unit cell 10.

A voltage detection circuit (corresponding to the first voltage detection circuit in the present invention) 53 detects a voltage value V _n (n is an odd number). Voltage value V _n is a total voltage value of the two cells 10 connected in series. For example, the voltage value V ₁ is the total value of the voltage values VB ₀ and VB ₁ of the unit cell 10, and the voltage value V ₉ is the total value of the voltage values VB ₈ and VB ₉ of the unit cell 10.

If the voltage values V ₀ and V ₁ are detected, the voltage value VB ₁ can be calculated. That is, a value obtained by subtracting the voltage value V ₀ from the voltage value V ₁ is the voltage value VB ₁ . If the voltage value VB ₁ is calculated, the voltage value VB ₂ can be calculated based on the voltage values VB ₁ and V ₂ . That is, a value obtained by subtracting the voltage value VB ₁ from the voltage value V ₂ is the voltage value VB ₂ . In other words, by detecting the voltage value _{V 0, V 1, V 2} , it calculates a voltage value VB _2.

According to such a calculation method may be based on the voltage value _V 0 _{~V 10,} calculates a voltage value _VB 0 _{through Vb 10} of the cells 10. Here, the general formula for calculating the voltage value VB _n (n is an arbitrary integer) is represented by the following formula (1).

  In the present embodiment, voltage detection circuits 52 and 53 are provided on the substrate 50, and the voltage detection circuits 52 and 53 and the monitoring unit 60 are connected via the communication line 54, thereby being arranged between the substrate 50 and the monitoring unit 60. It is possible to reduce the number of wirings to be made. When connecting the voltage detection lines 51 to the monitoring unit 60, the voltage detection lines 51 are arranged between the substrate 50 and the monitoring unit 60 by the number of bus bars 41 to 43. As the number of bus bars 41 to 43 increases, the number of voltage detection lines 51 also increases. In this embodiment, it is only necessary to arrange the communication line 54 between the substrate 50 and the monitoring unit 60. By reducing the number of wirings arranged between the substrate 50 and the monitoring unit 60, it is possible to suppress an increase in the space for arranging the wirings.

  Further, by arranging the substrate 50 at a position adjacent to the duct 30 in the XY plane, it is possible to suppress an increase in size of the battery pack 1 in the Z direction. That is, the battery pack 1 can be downsized in the Z direction as compared with the configuration in which the substrate 50 is disposed above the duct 30. Although voltage detection circuits 52 and 53 are provided on the substrate 50, the voltage detection circuits 52 and 53 can be arranged using a space adjacent to the duct 30 in the Y direction.

1: battery pack, 10: single cell, 12: positive terminal, 13: negative terminal, 14: valve,
30: Duct, 41-43: Bus bar, 50: Substrate, 51: Voltage detection line,
52, 53: voltage detection circuit, 54: communication line, 60: monitoring unit

Claims (1)

A plurality of power storage elements each provided with an electrode terminal and arranged in a predetermined direction;
A duct that is disposed between the two electrode terminals in each power storage element, extends in the predetermined direction, and moves gas discharged from the power storage element;
A plurality of bus bars arranged side by side in the predetermined direction on both sides of the duct and fixed to the electrode terminal, and a plurality of bus bars for connecting the plurality of power storage elements in series,
A voltage detection line provided on the substrate and connected to each bus bar;
A first voltage detection circuit and a second voltage detection circuit provided on the substrate and disposed on both sides of the duct;
A monitoring unit that monitors the voltage value of each of the storage elements,
The first voltage detection circuit is connected to the bus bar arranged on the side where the first voltage detection circuit is located with respect to the duct via the voltage detection line, and the two storage elements connected in series The total voltage value of
The second voltage detection circuit is disposed on the side where the second voltage detection circuit is positioned with respect to the duct, and on the side where the first voltage detection circuit is positioned with respect to the duct, The voltage detection line is connected to the bus bar fixed to the electrode terminal of the power storage element disposed at one end in the predetermined direction, and the total voltage value of the two power storage elements connected in series and Detecting a voltage value of the power storage element disposed at one end in a predetermined direction;
The monitoring unit is connected to the first voltage detection circuit and the second voltage detection circuit via a communication line, and has a voltage value and a total voltage value of the power storage element arranged at one end in the predetermined direction. Based on this, a voltage value of each power storage element is calculated.