JP2019067671A - Monitoring device - Google Patents

Abstract

To provide a monitoring device that suppresses an increase in the number of parts and physical size.SOLUTION: A monitoring device includes a flexible substrate 31 formed with a wiring pattern 32 electrically connected to respective electrode terminals 221 and 222 of a plurality of battery cells 220 connected in series, a monitoring unit that monitors a voltage of the battery cell input through the wiring pattern, and a fixing portion 50 that fixes the flexible substrate to the plurality of battery cells, and a gas vent valve 224 is formed on the electrode terminal formation surface 220a of the battery cell, and the flexible substrate is fixed to the plurality of battery cells in a mode of facing away from the gas vent valve, and therefore, a part of an exhaust passage EP for exhausting a gas released from the gas vent valve is partitioned by a part of the flexible substrate.SELECTED DRAWING: Figure 9

Description

  The disclosure of the present specification relates to a battery cell monitoring device.

  DESCRIPTION OF RELATED ART As patent document 1 shows, the electrical storage apparatus provided with an electrical storage unit and a holding member is known. The storage unit includes a plurality of storage elements and a plurality of bus bars. A gas discharge valve is formed in each of the plurality of storage elements. The electrode terminals of the plurality of storage elements are electrically connected by the bus bar. The holding member is provided with a wire for electrically connecting the circuit board and the bus bar.

JP, 2017-152374, A

  The storage unit of Patent Document 1 includes, in addition to the plurality of storage elements and the plurality of bus bars, a bus bar frame and a heat shield plate that constitute an exhaust passage of the gas discharge valve of each of the plurality of storage elements. And this heat shield plate and the holding member provided with the wiring which electrically connects a circuit board and a bus-bar are another members. As a result, there was a problem that the number of parts was large and the physical size was large.

  Therefore, an object of the present disclosure is to provide a monitoring device in which the increase in the number of parts and the physical size is suppressed.

One of the disclosures is a flexible substrate (31) formed with a wiring pattern (32) electrically connected to the electrode terminals (221, 222) of the plurality of battery cells (220) connected in series in series. When,
A monitoring unit (10) for monitoring the voltage of the battery cell input through the wiring pattern;
And a fixing portion (50) for fixing the flexible substrate to the plurality of battery cells,
A gas vent valve (224) is formed on the surface (220a) on which the electrode terminal of the battery cell is formed,
The flexible substrate is fixed to the plurality of battery cells by the fixing portion in a manner facing away from the degassing valve, and an exhaust passage for exhausting the gas released from the degassing valve by a part of the flexible substrate Part of (EP) is divided.

  A part of the exhaust passage (EP) is partitioned by the flexible substrate (31) on which the wiring pattern (32) is formed as described above. According to this, unlike the configuration in which the substrate having the wiring pattern and the member for partitioning the exhaust passage are separately provided, an increase in the number of parts is suppressed. In addition, the increase in physical size of the monitoring device is suppressed.

  The reference numerals in the parentheses above merely indicate the correspondence with the configurations described in the embodiments to be described later, and do not limit the technical scope at all.

It is a circuit diagram of a battery pack. It is sectional drawing for demonstrating a battery module and a wiring part. It is a top view which shows a battery stack. It is a top view which shows a wiring part and a monitoring part. It is sectional drawing in alignment with the VV line shown in FIG. It is a top view which shows a fixing | fixed part. It is a top view which shows the state in which the fixing | fixed part was provided in the battery stack. It is a top view which shows the state in which the fixing | fixed part and the wiring part were provided in the battery stack. It is sectional drawing in alignment with the IX-IX line shown in FIG. It is sectional drawing which shows the modification of the wiring part of 1st Embodiment. It is a top view which shows the fixing | fixed part of 2nd Embodiment. It is a top view which shows the state in which the wiring part was provided in the battery stack. It is a top view which shows the state in which the wiring part and the fixing | fixed part were provided in the battery stack. It is sectional drawing which follows the XIV-XIV line shown in FIG. It is a top view which shows the fixing | fixed part of 3rd Embodiment. It is a top view which shows the state in which the wiring part and the fixing | fixed part were provided in the battery stack. It is sectional drawing in alignment with the XVII-XVII line shown in FIG. It is sectional drawing for demonstrating the modification of a fixing | fixed part. It is sectional drawing for demonstrating the modification of a fixing | fixed part. It is sectional drawing for demonstrating the modification of a fixing | fixed part. It is a graph for demonstrating the modification of a wiring part.

  Hereinafter, embodiments will be described based on the drawings.

First Embodiment
The monitoring apparatus of the battery pack concerning this embodiment is demonstrated based on FIGS. 1-9. The battery pack of the present embodiment is applied to a hybrid vehicle.

  In the following, three directions orthogonal to each other will be referred to as a lateral direction, a longitudinal direction, and a height direction. In the present embodiment, the lateral direction is along the advancing and retracting direction of the hybrid vehicle. The longitudinal direction is along the lateral direction of the hybrid vehicle. The height direction is along the vertical direction of the hybrid vehicle. The vertical direction corresponds to the alignment direction.

<Overview of Battery Pack>
Battery pack 400 functions to supply power to the electric load of the hybrid vehicle. The electrical load includes a motor generator that serves as a power source and a power source. For example, when the motor generator is in power running, the battery pack 400 is discharged to supply power to the motor generator. When the motor generator generates power, battery pack 400 charges generated power generated by the power generation.

  Battery pack 400 has a battery ECU 300. The battery ECU 300 is electrically connected to various ECUs (vehicle-mounted ECUs) mounted on a hybrid vehicle. The battery ECU 300 and the in-vehicle ECU mutually transmit and receive signals to coordinately control the hybrid vehicle. By this cooperative control, the power generation and power running of the motor generator according to the charge amount of the battery pack 400, the output of the internal combustion engine, and the like are controlled.

  The battery pack 400 has a battery module 200. As shown in FIGS. 2 and 3, the battery module 200 has a battery stack 210 in which a plurality of battery cells 220 are electrically and mechanically connected in series. The battery module 200 also has a battery case 230 that houses the battery stack 210.

  The battery pack 400 has a monitoring device 100. The monitoring device 100 detects the voltage of each of the battery cells 220 that constitute the battery stack 210. The monitoring device 100 then monitors the detected voltage. Monitoring device 100 outputs the monitoring result to battery ECU 300. The monitoring device 100 performs equalization processing of the plurality of battery cells 220 based on an instruction from the battery ECU 300.

  As described above, the battery pack 400 includes the monitoring device 100, the battery module 200, and the battery ECU 300. Although not shown, the battery pack 400 further includes a blower fan for cooling the battery module 200. The drive of the blower fan is controlled by the battery ECU 300. The number of blower fans can be determined as appropriate regardless of the number of battery stacks 210.

  Battery pack 400 is provided, for example, in an arrangement space under a seat of the hybrid vehicle. For example, the lower rear seat is wider than the lower front seat. For that purpose, the battery pack 400 of the present embodiment is provided in the arrangement space under the rear seat. However, the installation location of battery pack 400 is not limited to this, and, for example, between the rear seat and the trunk room, between the driver's seat and the front passenger seat, etc. can be adopted as appropriate. Hereinafter, the battery module 200 and the monitoring device 100 will be described.

<Overview of Battery Module>
As described above, the battery module 200 has the battery stack 210 and the battery case 230. The battery case 230 has a housing 231 and a lid 232. The housing 231 is manufactured by aluminum die casting. The housing 231 can also be manufactured by pressing iron or stainless steel.

  The housing 231 has a box shape that is open in the height direction and has a bottom. The housing 231 has a bottom wall 233 facing in the height direction, and a side wall 234 annularly extending along the height direction from the edge of the bottom wall 233. The side wall 234 constitutes the above-mentioned opening. The opening is covered by a lid 232. The lid 232 is formed of a resin material or a metal material.

  The housing 231 is provided with a support wall (not shown). The support wall extends from the bottom wall 233 of the housing 231 toward the opening. A plurality of battery cells 220 are mounted on the support wall. A part of battery cell 220 is mounted on the support wall, and a space is formed between battery cell 220 and an inner bottom surface 233 a of bottom wall 233. This space functions as a distribution channel through which wind flows.

  The side wall 234 of the housing 231 is formed with a communication port 234a to which the suction port of the above-described blower fan is connected. The communication port 234a is located on the bottom wall 233 side, and is aligned with the flow path in the longitudinal direction. The blower fan is in communication with the flow path through the communication port 234a.

  Although not shown, at least one of the housing 231 and the lid 232 has a communication hole for communicating the external atmosphere with the communication path. The communication hole is located on the opening side of the housing 231. Therefore, the communication hole is separated from the communication port 234a in the height direction. The communication holes are aligned laterally with an exhaust pipe 235 described later shown in FIG. The exhaust pipe 235 is longitudinally separated from the communication port 234a. Therefore, the communication hole is separated from the communication port 234a also in the vertical direction.

  With the above configuration, when the blower fan sucks out air, air flows from the external atmosphere into the communication hole. The air flows in the height direction and flows into the circulation path. The wind that has flowed into the circulation path flows in the vertical direction and is sucked into the blower fan via the communication port 234a.

  Further, as shown in FIG. 2, the battery case 230 is provided with an exhaust pipe 235 for discharging the gas of the battery cell 220 described later out of the hybrid vehicle. The exhaust pipe 235 communicates with an exhaust passage EP described later.

  The battery stack 210 has a plurality of battery cells 220. The plurality of battery cells 220 are arranged in the longitudinal direction. The plurality of battery cells 220 are electrically and mechanically connected in series. Therefore, the output voltage of the battery module 200 is a voltage obtained by summing the output voltages of the plurality of battery cells 220.

<Overview of monitoring device>
As shown in FIG. 1, the monitoring device 100 has a monitoring unit 10 that monitors the voltage of each of the plurality of battery cells 220, and a wiring unit 30 that electrically connects the monitoring unit 10 and each of the plurality of battery cells 220. . The monitoring device 100 also has a fixing unit 50 shown in FIG. The fixing unit 50 functions to fix the wiring unit 30 to the battery stack 210.

  Monitoring device 100 is provided in battery module 200. Specifically, the monitoring unit 10 of the monitoring device 100 is provided side by side with the battery stack 210 in the height direction. Alternatively, the monitoring unit 10 is provided side by side with the battery stack 210 in the longitudinal direction. Wiring portion 30 and fixing portion 50 are provided side by side with battery stack 210 in the height direction.

<Configuration of battery stack>
Next, the battery stack 210 will be described in detail based on FIGS. 2 and 3. As described above, the battery stack 210 has a plurality of battery cells 220. Battery cell 220 has a square pole shape. Therefore, the battery cell 220 has six sides.

  Battery cell 220 has an upper end surface 220a and a lower end surface 220b facing in the height direction. The battery cell 220 has a laterally facing first side surface 220c and a second side surface 220d. Battery cell 220 has a first main surface 220 e and a second main surface 220 f facing in the longitudinal direction. Among the six surfaces, the first main surface 220 e and the second main surface 220 f have larger areas than the other four surfaces.

  The battery cell 220 is a secondary battery. Specifically, the battery cell 220 is a lithium ion battery. Lithium ion batteries generate an electromotive force by a chemical reaction. A current flows in the battery cell 220 due to the generation of the electromotive voltage. Thereby, the battery cell 220 generates heat to generate gas. The battery cell 220 expands. The battery cell 220 is not limited to a lithium ion battery. For example, as the battery cell 220, a nickel hydrogen secondary battery, an organic radical battery, or the like can be employed.

  As described above, the areas of the first main surface 220 e and the second main surface 220 f of the battery cell 220 are larger than those of the other four surfaces. Therefore, in the battery cell 220, the first main surface 220e and the second main surface 220f are easily expanded. Thus, the battery cell 220 expands in the longitudinal direction. That is, the battery cells 220 expand in the direction in which the plurality of battery cells 220 are arranged.

  The battery stack 210 has a restraint not shown. The plurality of battery cells 220 are mechanically and longitudinally connected in series by the restraints. Further, the restraint suppresses an increase in the size of the battery stack 210 due to the expansion of each of the plurality of battery cells 220. A gap is formed between adjacent battery cells 220. By passing air through the air gap, heat dissipation of each battery cell 220 is promoted.

  The lower end surface 220 b of the battery cell 220 is mounted on the support wall of the housing 231 described above. The lower end surface 220 b of the battery cell 220 and the inner bottom surface 233 a of the bottom wall 233 are spaced apart and opposed in the height direction. The above-mentioned distribution route is constituted among these. The air gap between the adjacent battery cells 220 described above is in communication with the flow path. Therefore, when the blower fan sucks in air in the flow path, the air on the upper end surface 220 a side of the battery cell 220 flows to flow in the flow path via the air gap. Conversely, when the blower fan blows air to the flow path, the air in the flow path flows to flow to the upper end surface 220 a through the air gap.

  A positive electrode terminal 221 and a negative electrode terminal 222 are formed on the upper end surface 220 a of the battery cell 220. The positive electrode terminal 221 and the negative electrode terminal 222 are arranged in the lateral direction. The positive electrode terminal 221 is located on the first side surface 220 c side. The negative electrode terminal 222 is located on the second side surface 220 d side. The upper end surface 220a corresponds to the formation surface.

  As shown in FIGS. 2 and 3, the two battery cells 220 arranged adjacent to each other face each other between the first main surfaces 220 e and between the second main surfaces 220 f. Thereby, one positive electrode terminal 221 and the other negative electrode terminal 222 of the two battery cells 220 arranged adjacent to each other are arranged in the vertical direction. As a result, in the battery stack 210, the positive electrode terminals 221 and the negative electrode terminals 222 are alternately arranged in the longitudinal direction.

  The one positive electrode terminal 221 and the one negative electrode terminal 222 adjacent to each other in the longitudinal direction are electrically connected via a series terminal 223 extending in the longitudinal direction. Thus, the plurality of battery cells 220 constituting the battery stack 210 are electrically connected in series.

  The battery stack 210 of the present embodiment has nine battery cells 220. These nine battery cells 220 are connected in series. For this reason, the total number of the positive electrode terminal 221 and the negative electrode terminal 222 is eighteen. As shown in FIG. 1 and FIG. 3, these eighteen electrode terminals are given numbers that increase in number from the lowest potential to the highest potential. As the number of the number (No) shown in the figure increases, the potential (voltage) of the electrode terminal becomes higher.

  In FIG. The negative electrode terminal 222 of the battery cell 220 described as 0 is at the ground potential (minimum potential). No. The positive electrode terminal 221 of the battery cell 220 described as 17 has a potential (maximum potential) obtained by summing the outputs of the battery cells 220. The negative terminal 222 at the lowest potential and the positive terminal 221 at the highest potential are connected to the electric load. As a result, the potential difference between the lowest potential and the highest potential is output to the electrical load as the output voltage of the battery module 200.

  Between the positive electrode terminal 221 and the negative electrode terminal 222 on the upper end surface 220a of the battery cell 220, a gas removal valve 224 for releasing the gas generated in the battery cell 220 is formed. As shown in FIG. 3, the degassing valves 224 of the plurality of battery cells 220 are arranged in the longitudinal direction.

  The degassing valve 224 is a portion where the thickness of the outer wall of the battery cell 220 is locally thin and the rigidity is low. When the internal pressure of the battery cell 220 rises due to the generation of gas, stress concentration occurs in the degassing valve 224. The rise in internal pressure causes a crack in the degassing valve 224, and the gas in the battery cell 220 is released from the crack. This gas is exhausted out of the hybrid vehicle via an exhaust passage EP described later and the exhaust pipe 235 described above.

<Circuit configuration of monitoring device>
Next, the circuit configuration of the monitoring apparatus 100 will be described based on FIGS. 1 and 4.

  As shown in FIG. 1, the monitoring unit 10 includes a printed circuit board 11, a first electronic element 12, and a monitoring IC chip 13. The first electronic element 12 and the monitoring IC chip 13 are mounted on the printed circuit board 11. The first electronic element 12 and the monitoring IC chip 13 are electrically connected via the substrate wiring 14 of the printed board 11.

  The wiring unit 30 is connected to the printed circuit board 11 of the monitoring unit 10. Thereby, the battery stack 210 and the monitoring unit 10 are electrically connected via the wiring unit 30. The printed circuit board 11 of the monitoring unit 10 is provided with a connector (not shown). The wire 301 shown in FIG. 1 is connected to this connector. The monitoring unit 10 and the battery ECU 300 are electrically connected via the wire 301.

  As shown in FIG. 4, the wiring portion 30 has a flexible substrate 31 having flexibility. A plurality of wiring patterns 32 are formed on at least one of the surface and the inside of the flexible substrate 31. The plurality of wiring patterns 32 are provided at the middle point of the battery cells 220 electrically connected in series as shown in FIG. 1, the positive terminal 221 of the battery cell 220 of the highest potential, and the negative terminal 222 of the battery cell 220 of the lowest potential. It is connected. Substrate wirings 14 corresponding to each of the plurality of wiring patterns 32 are formed on the printed substrate 11. The wiring pattern 32 and the substrate wiring 14 are electrically connected.

  In the following, in order to simplify the description, the wiring pattern 32 and the substrate wiring 14 electrically connected to each other are collectively referred to as a voltage detection wiring.

  As shown in FIG. 1, the second electronic element 60 is mounted on the flexible substrate 31 of the wiring portion 30. The second electronic element 60 has a fuse 61 and an inductor 62. The monitoring unit 10 further includes a Zener diode 15, a parallel capacitor 16, and a resistor 17 as the first electronic element 12. Each of the Zener diode 15, the parallel capacitor 16 and the resistor 17 is mounted on the printed circuit board 11.

  As shown in FIG. 1, a fuse 61, an inductor 62, and a resistor 17 are provided for each of the plurality of voltage detection lines. From the battery cell 220 to the monitoring IC chip 13, the fuse 61, the inductor 62, and the resistor 17 are connected in series in order.

  The zener diode 15 and the parallel capacitor 16 are connected in parallel between two adjacent voltage detection lines. Specifically, the Zener diode 15 and the parallel capacitor 16 are connected between the inductor 62 and the resistor 17 in the voltage detection line. The anode electrode of the Zener diode 15 is connected to the low potential side. The cathode electrode of the Zener diode 15 is connected to the high potential side.

  Although not shown, the monitoring IC chip 13 has a microcomputer and a switch corresponding to each of the plurality of battery cells 220. This switch controls the connection between the two voltage detection lines. Therefore, charging / discharging of the battery cell 220 electrically connected to the corresponding voltage detection line is controlled by the open / close control of this switch.

  As shown in FIG. 1, the monitoring IC chip 13 and each of the plurality of voltage detection lines are electrically connected. Therefore, the output voltages of the plurality of battery cells 220 are input to the monitoring IC chip 13. The microcomputer of the monitoring IC chip 13 detects and monitors the output voltage (electromotive voltage) of each of the plurality of battery cells 220. This output voltage is input to battery ECU 300.

  There is a correlation between the state of charge (SOC) of the battery cell 220 and the electromotive voltage. SOC is an abbreviation of state of charge. Battery ECU 300 stores this correlation. The battery ECU 300 detects the SOC of each of the plurality of battery cells 220 based on the output voltage (electromotive voltage) input from the monitoring IC chip 13 and the stored correlation.

  Battery ECU 300 determines the equalization processing of the SOCs of the plurality of battery cells 220 based on the detected SOC. Then, battery ECU 300 outputs an instruction of equalization processing based on the determination to the microcomputer of monitoring IC chip 13. The microcomputer opens / close controls the switch corresponding to each of the plurality of battery cells 220 based on the instruction of the equalization process. An equalization process is implemented by this.

  Battery ECU 300 also detects the charge state of battery stack 210 based on the input voltage or the like. The battery ECU 300 outputs the detected charge state of the battery stack 210 to the onboard ECU. The on-vehicle ECU outputs a command signal to the battery ECU 300 based on the state of charge, vehicle information such as the amount of depression of an accelerator pedal input from various sensors mounted on the vehicle and the throttle valve opening, and an ignition switch. Battery ECU 300 controls the connection between battery stack 210 and the electrical load based on this command signal.

  Although not shown, a system main relay is provided between the battery stack 210 and the electrical load. The system main relay controls the electrical connection between the battery stack 210 and the electrical load by the generation of a magnetic field. Battery ECU 300 controls the connection between battery stack 210 and the electrical load by controlling the generation of the magnetic field of the system main relay.

<Configuration of monitoring device>
Next, the configuration of the monitoring apparatus 100 will be described in detail based on FIGS. 4 to 9. As shown in FIG. 4, the wiring portion 30 has a flexible substrate 31 and a wiring pattern 32. The flexible substrate 31 is thinner than the printed circuit board 11 and is made of a flexible resin material. Therefore, the flexible substrate 31 can be bent. That is, the flexible substrate 31 is elastically deformable. Although not shown, a notch may be formed in a part of the flexible substrate 31 or a part thereof may have a bellows structure so that large deformation in the longitudinal direction and the lateral direction is possible. Further, in order to prevent the flow of the air in the accommodation space formed by the battery case 230 from being disturbed, a notch or a hole penetrating in the longitudinal direction may be formed in the flexible substrate 31. These notches and holes are formed in the formation region 33 of the flexible substrate 31 described later. The flexible substrate 31 corresponds to a flexible substrate.

  The flexible substrate 31 has a rectangular shape extending in the longitudinal direction. As shown in FIG. 8, the flexible substrate 31 is provided between the positive electrode terminal 221 and the negative electrode terminal 222 of the battery stack 210. Therefore, the horizontal length (horizontal width) of the flexible substrate 31 is shorter than the horizontal separation distance between the positive electrode terminal 221 and the negative electrode terminal 222.

  As shown in FIG. 4, the wiring pattern 32 has a horizontal wiring 32a extending in the horizontal direction and a vertical wiring 32b extending in the vertical direction. The end portions of the horizontal wires 32a and the vertical wires 32b are connected to each other, whereby the wiring pattern 32 has an L-shaped crank shape. One end of the horizontal wire 32 a opposite to the end connected to the vertical wire 32 b is electrically connected to the electrode terminal of the battery cell 220. One end of the vertical wiring 32 b opposite to the end connected to the horizontal wiring 32 a is electrically connected to the monitoring unit 10.

  The flexible substrate 31 is formed with a plurality of protrusions 31c corresponding to one end of the horizontal wiring 32a. The plurality of protrusions 31 c extend from the two lateral ends of the flexible substrate 31 toward the corresponding electrode terminals. The plurality of protrusions 31c are arranged in the longitudinal direction. One end of the horizontal wire 32a is provided to each of the plurality of protrusions 31c.

  Further, on the flexible substrate 31, a protruding portion 31d corresponding to one end of the vertical wiring 32b is formed. The protruding portion 31 d extends from the end of the flexible substrate 31 in the vertical direction toward the monitoring unit 10 toward the monitoring unit 10. One end of a plurality of vertical wires 32b is provided in the protruding portion 31d. The protruding portion 31 d is connected to the surface 11 a of the printed circuit board 11. Of course, the protrusion 31 d may be connected to the back surface of the printed circuit board 11 opposite to the surface 11 a. The protruding portion 31 d can be curved according to the arrangement of the printed circuit board 11.

  The flexible substrate 31 has a formation region 33 where the wiring pattern 32 is formed and a non-formation region 34 where the wiring pattern 32 is not formed. As clearly shown in FIG. 4, the wiring patterns 32 are formed on two end sides in the lateral direction of the flexible substrate 31. The wiring pattern 32 is not formed in the center between the two ends of the flexible substrate 31. The central portion is the non-forming region 34 of the wiring pattern 32. The two end portions are the formation region 33 of the wiring pattern 32. However, the central portion on the end side where the protruding portion 31 d is formed in the longitudinal direction of the flexible substrate 31 is not the non-formation region 34 but the formation region 33. For this purpose, the formation area 33 is C-shaped. In FIG. 4, the boundary between the formation region 33 and the non-formation region 34 is indicated by a broken line. Further, the non-forming area 34 is hatched to emphasize it.

  As described above, the gas vent valve 224 is formed between the positive electrode terminal 221 and the negative electrode terminal 222. The non-forming area 34 of the flexible substrate 31 is spaced apart from the gas removal valve 224 in the height direction. As shown in FIGS. 5 and 9, the non-forming area 34 is curved so as to be convex in the direction away from the cell stack 210 in the height direction. The boundary between the non-formation region 34 and the formation region 33 is fixed to the fixing portion 50.

  As shown in FIG. 6, the fixing portion 50 has a longitudinally extending shape. The longitudinal length of the fixing portion 50 is determined by the longitudinal length of the battery stack 210. In other words, the longitudinal length of the fixing portion 50 is determined by the number of battery cells 220 aligned in the longitudinal direction.

  The fixing portion 50 is mounted on the upper end surface 220 a of each of the plurality of battery cells 220 as shown in FIGS. 7 and 9. The above-mentioned air gaps are formed between the adjacent battery cells 220. The air gap is open on the upper end surface 220 a side of the adjacent battery cell 220. A part of the opening on the upper end surface 220 a side of the air gap is covered by the fixing portion 50.

  The fixing portion 50 is made of a resin material. A plurality of through holes 50 c penetrating in the height direction are formed in the fixing portion 50. The through hole 50c penetrates the opposite surface 50a to the upper end surface 220a of the fixing portion 50 and the back surface 50b opposite to the opposite surface 50a. In FIGS. 6 and 7, the fixing portion 50 is hatched to clearly show the through hole 50 c.

  In the fixed portion 50, the same number of through holes 50c as the battery cells 220 are formed. The through hole 50 c is formed at a position opposite to the degassing valve 224 in the fixing portion 50 in the height direction. When the fixing portion 50 is provided in the battery stack 210, as described above, a part of the opening on the upper end surface 220a side of the air gap is covered by the fixing portion 50 and the inner annular surface 50d that divides the through hole 50c of the fixing portion 50. Surrounds the periphery of the degassing valve 224. The inner annular surface 50 d that defines the through hole 50 c constitutes a part of the exhaust passage EP that exhausts the gas released from the gas release valve 224.

  A gap is generated between the facing surface 50a of the fixed portion 50 and the upper end surface 220a of the battery cell 220 due to manufacturing variations of the plurality of battery cells 220 and variations in assembly of the plurality of battery cells 220 into the housing 231. There is a risk. As a result, the gas released from the degassing valve 224 may flow into the gap between the fixed portion 50 and the battery cell 220.

  In order to avoid this, an annular resinous packing may be provided between the fixing portion 50 and the upper end surface 220a so as to surround the opening edge of the through hole 50c in the facing surface 50a. The packing is sandwiched between the fixing portion 50 and the upper end surface 220a. The fixing portion 50 is fixed to the battery stack 210 by fixing the fixing portion 50 to the above-described restraint or the like by fitting, bolting, or the like.

<How to attach the monitoring device to the battery module>
Next, a method of attaching the monitoring device 100 to the battery module 200 will be described. First, the battery stack 210 housed in the housing 231 is prepared. Next, as shown in FIG. 7, the fixing portion 50 is fixed to the battery stack 210. At this time, the battery fixing portion 50 is formed so that the gas vent valve 224 is exposed to the outside through the through hole 50 c while preventing a gap from being formed between the opposing surface 50 a and the upper end surface 220 a of the fixing portion 50. It is fixed to the upper end surface 220 a of the cell 220.

  Then, the monitoring unit 10 and the wiring unit 30 shown in FIG. 4 electrically and mechanically connected to each other are prepared. Then, the monitoring unit 10 and the wiring unit 30 are mounted on the battery stack 210 as shown in FIG. Thus, the fixed portion 50 and the gas vent valve 224 are covered by the wiring portion 30. In FIG. 8, the fixed portion 50 hidden by the wiring portion 30 is indicated by an alternate long and short dash line, and the gas vent valve 224 is indicated by a dotted line.

  Next, each wiring pattern 32 of the wiring portion 30 is welded to the corresponding electrode terminal. Alternatively, each wiring pattern 32 is welded and connected to the series terminal 223 connected to the corresponding electrode terminal.

  Further, as shown by a broken line in FIG. 8, the boundary between the formation region 33 and the non-formation region 34 in the C-shaped flexible substrate 31 is continuously welded without break to the fixing portion 50 by ultrasonic waves or the like. Thus, the flexible substrate 31 is continuously fixed to the fixing portion 50 along the longitudinal direction on both sides of the plurality of through holes 50c in the longitudinal direction. Also, the flexible substrate 31 is continuously fixed in the lateral direction at the end between the through hole 50c located closest to the monitoring unit 10 among the plurality of through holes 50c in the fixed unit 50 and the above-mentioned protruding portion 31d. Ru. The fixed portions of the flexible substrate 31 with the fixed portion 50 along the longitudinal direction and the fixed portions with the fixed portion 50 along the lateral direction are connected.

  As described above, the opening on the back surface 50 b side of all the through holes 50 c of the fixing portion 50 is surrounded by the fixing portion of the flexible substrate 31 and the fixing portion 50 around the height direction. Then, as shown in FIG. 9, all the gas vent valves 224 exposed to the outside from the through holes 50c are spaced apart from the inner surface 31a of the non-forming area 34 in the height direction and are opposed. In FIG. 9, the ultrasonic waves for welding the flexible substrate 31 and the fixing portion 50 are indicated by solid arrows.

  By the above fixing, the non-forming area 34 of the flexible substrate 31 and the fixing portion 50 constitute an exhaust passage EP for exhausting the gas released from the gas release valve 224. Specifically, the exhaust passage EP is constituted by the inner surface 31a of the non-formation region 34, the region opposite to the non-formation region 34 on the back surface 50b of the fixed portion 50, and the inner annular surface 50d constituting the through hole 50c. Strictly speaking, a part of the exhaust passage EP is also configured by the formation portion of the degassing valve 224 on the upper end surface 220 a of the battery cell 220.

  The exhaust passage EP is open on the opposite side to the monitoring unit 10 in the longitudinal direction. An exhaust pipe 235 shown in FIG. 2 is connected to this opening. With this configuration, the gas released from the degassing valve 224 flows to the exhaust pipe 235 via the exhaust passage EP. In FIG. 8, the gas flowing to the exhaust pipe 235 is indicated by a white arrow.

  As described above, the degassing valve 224 and the non-forming area 34 face each other with a gap in the height direction. Therefore, when the gas is released from the degassing valve 224, the gas strikes the non-forming region 34. As a result, the non-forming region 34 locally heats up. The temperature of the released gas is approximately 100 ° C to 200 ° C. Therefore, the flexible substrate 31 is made of a resin material whose melting temperature is higher than the temperature of the released gas. As such a resin material, for example, a silicon-based resin can be adopted. The flexible substrate 31 can also be manufactured by adding a filler such as glass to the resin material in the range in which the flexibility is not lost. Thereby, the heat resistance of the flexible substrate 31 is improved.

  The monitoring unit 10 and the wiring unit 30 may be fixed after the wiring unit 30 is connected to the battery stack 210 and the fixing unit 50. Further, the monitoring unit 10 is configured such that the protruding portion 31 d of the wiring unit 30 described above is curved, for example, as shown in FIG. You may provide in 1st main surface 220e of the battery cell 220 which has the negative electrode terminal 222 of zero. Alternatively, the monitoring unit 10 may be provided on the upper end surface 220 a of the plurality of battery cells 220 via the wiring unit 30 by curving the protruding portion 31 d.

<Function effect>
Next, the operation and effect of the monitoring device 100 will be described. As described above, the wiring unit 30 electrically connecting the battery stack 210 and the monitoring unit 10 divides (configures) a part of the exhaust passage EP. According to this, unlike the configuration in which the substrate connecting the battery stack and the monitoring unit and the member that divides the exhaust passage are separately provided, an increase in the number of parts is suppressed. Moreover, the increase in the physique of the monitoring device 100 is suppressed.

  A flexible flexible substrate 31 is connected to the electrode terminals of the plurality of battery cells 220 and is joined to the fixing portion 50 fixed to the plurality of battery cells 220. According to this, even if manufacturing variations and assembly variations of the plurality of battery cells 220 and positional deviation of the fixing portion 50 with respect to the plurality of battery cells 220 occur, the variation or the deviation is flexible. It can respond by the deformation of the substrate 31. Therefore, it is suppressed that the connection of the flexible substrate 31 and the battery cell 220 and the bonding of the flexible substrate 31 and the fixing portion 50 become difficult. It is suppressed that the electrical connection defect with the flexible substrate 31 and the battery cell 220 generate | occur | produces, and the airtightness of the exhaust passage EP comprised by joining of the flexible substrate 31 and the fixing | fixed part 50 falling.

  The exhaust passage EP is configured by welding the fixed portion 50 and the flexible substrate 31 by ultrasonic waves or the like. According to this, as compared with the structure in which the fixing portion and the member for partitioning the exhaust passage are mechanically connected by fitting or the like, the reduction in the airtightness of the exhaust passage EP is suppressed.

  A part of the exhaust passage EP is partitioned (configured) by the non-formation region 34. According to this, it is suppressed that the formation area 33 is softened by the gas. Therefore, the occurrence of an electrical connection failure in the wiring pattern 32 is suppressed.

  The non-forming area 34 is curved so as to be convex in the direction away from the battery stack 210 in the height direction. Thus, the capacity of the exhaust passage EP is increased. According to this, the gas discharged from the degassing valve 224 in the height direction can be diffused. Therefore, application of the stress of the gas upon discharge to the non-formation region 34 is suppressed. Therefore, application of stress to the joint portion between the flexible substrate 31 and the fixing portion 50 is suppressed. This prevents the flexible substrate 31 from being damaged. It is suppressed that the airtightness of exhaust passage EP falls.

(First modification)
In the present embodiment, as shown in FIG. 9, an example is shown in which the non-formation region 34 is curved so as to be convex in the direction away from the battery stack 210 in the height direction. However, the non-formation region 34 is slightly curved in the height direction according to the discharge of the gas from the battery cell 220, so long as the gas can be exhausted to the exhaust pipe 235, and it is curved when the gas is not generated It is not necessary. For example, as shown in FIG. 10, the non-forming area 34 may not be curved in the height direction.

Second Embodiment
Next, a second embodiment will be described based on FIGS. 11 to 14. The monitoring device of each embodiment shown below has many points in common with those according to the above-described embodiment. Therefore, in the following, the description of the common parts will be omitted, and the different parts will be mainly described. In the following, the same reference numerals are given to the same elements as the elements shown in the above-described embodiment.

  In the first embodiment, the fixing portion 50 is provided on the upper end surface 220 a of the battery cell 220, and the flexible substrate 31 is welded to the fixing portion 50. On the other hand, in the present embodiment, the flexible substrate 31 is provided on the upper end surface 220 a of the battery cell 220, and the flexible substrate 31 is pressed and fixed to the upper end surface 220 a by the fixing portion 50. In particular, the inner surface 31 a located at the boundary between the formation region 33 of the flexible substrate 31 and the non-formation region 34 is pressed and fixed in such a manner as to contact the upper end surface 220 a of the plurality of battery cells 220.

  As shown in FIG. 11, the fixing portion 50 of the present embodiment connects the first leg 51 and the second leg 52 extending in the longitudinal direction, and the lateral direction connecting the first leg 51 and the second leg 52. The connecting leg 53 extends to the The longitudinal length of each of the first leg 51 and the second leg 52 is determined by the longitudinal length of the battery stack 210. In other words, the length in the vertical direction of each of the first leg 51 and the second leg 52 is determined by the number of battery cells 220 aligned in the vertical direction. The first leg 51, the second leg 52, and the connecting leg 53 correspond to a pressing portion.

  The first leg 51 and the second leg 52 are laterally spaced apart and aligned. One of the two longitudinal end portions of each of the first leg 51 and the second leg 52 is connected by the connecting leg 53. Thus, the fixing portion 50 has a C shape. The lateral length of the connection leg portion 53 is determined in accordance with the lateral length of the non-formation region 34 of the flexible substrate 31.

  The non-forming region 34 of this embodiment is curved to be convex in the direction away from the battery stack 210 in the height direction, as in the first embodiment. Each of the first leg 51, the second leg 52, and the connecting leg 53 has a length in the height direction longer than a curved portion of the non-forming region 34.

  Next, a method of attaching the monitoring device 100 of the present embodiment to the battery module 200 will be described. As shown in FIG. 12, first, the monitoring unit 10 and the wiring unit 30 are mounted on the battery stack 210. At this time, the non-forming region 34 of the wiring portion 30 and the gas vent valve 224 are disposed to face each other. Then, each wiring pattern 32 is electrically connected to the corresponding electrode terminal.

  Next, as shown in FIG. 13, the fixing portion 50 is mounted on the wiring portion 30. At this time, the degassing valve positioned closest to the monitoring unit 10 among the plurality of degassing valves 224 while the plurality of degassing valves 224 are each positioned between the first leg 51 and the second leg 52 The fixing portion 50 is mounted on the wiring portion 30 so that the connection leg portion 53 is positioned between the reference portion 224 and the monitoring portion 10. That is, the first leg 51 and the second leg 52 are mounted on a portion extending in the vertical direction at the boundary between the formation region 33 and the non-formation region 34. The connecting leg 53 is mounted at a laterally extending portion in this boundary. Simply speaking, the fixing portion 50 is mounted at the boundary between the C-shaped formation region 33 and the non-formation region 34 described in the first embodiment.

  The mounted state of the wiring portion 30 and the fixing portion 50 is shown in FIG. The lid portion 232 is brought into contact with the fixing portion 50 as schematically shown in FIG. Then, the lid portion 232 is fixed to the housing 231 so as to approach the housing 231 side in the height direction. Thereby, as shown by a solid line arrow, fixed part 50 is pressed to the battery stack 210 side. As a result, the wiring portion 30 is pressed and fixed to the battery stack 210 by the fixing portion 50. The boundary between the formation region 33 and the non-formation region 34 in the wiring portion 30 is pressed and fixed to the upper end surface 220 a of the battery cell 220 constituting the battery stack 210 by the fixing portion 50. As a result, the exhaust passage EP is divided by the inner surface 31a of the non-formation region 34 and the region facing the non-formation region 34 in the plurality of upper end surfaces 220a. The lid 232 corresponds to a support.

  As described above, there is a gap between the plurality of battery cells 220. Therefore, the exhaust passage EP is in communication with the communication space via the air gap. Therefore, when air in the communication space is allowed to flow by the cooling fan as described in the first embodiment, the gas discharged from the battery cell 220 may be sucked into the cooling fan and diffused in the vehicle. Therefore, the communication port 234a and the communication hole are not formed in the battery case 230 of the present embodiment. The communication path with the external space of the accommodation space constituted by the battery case 230 is only the exhaust pipe 235 via the air gap between the plurality of battery cells 220 and the exhaust passage EP.

  According to this, even if the gas in the battery cell 220 flows into the gap between the adjacent battery cells 220, the gas can be exhausted to the outside of the hybrid vehicle through the exhaust passage EP and the exhaust pipe 235. .

  Further, in the present embodiment, the cross-sectional area orthogonal to the longitudinal direction of the exhaust passage EP configured by the non-formation region 34 is larger than the opening area opened to the exhaust passage EP in the gap between the adjacent battery cells 220 There is. Therefore, the flow resistance of the gas is lower in the exhaust passage EP than in the gap between the adjacent battery cells 220. Thereby, the gas released from the degassing valve 224 actively flows toward the exhaust passage EP more than the gap between the adjacent battery cells 220.

  It goes without saying that the monitoring device 100 of the present embodiment exhibits the same function and effect as the monitoring device 100 described in the first embodiment.

Third Embodiment
Next, a third embodiment will be described based on FIGS.

  In the second embodiment, an example is shown in which the fixing portion 50 includes the first leg 51, the second leg 52, and the connecting leg 53. On the other hand, the fixing portion 50 of the present embodiment has a substrate support portion 54 for supporting the non-formed area 34 in addition to these three legs. The substrate support 54 is in the form of a longitudinally extending rectangle. The substrate support 54 is provided on the upper surface of each of the three legs in the height direction away from the battery stack 210, and integrally connects the three legs. In FIG. 15 and FIG. 16, the boundaries between the three legs and the substrate support 54 in the height direction are indicated by broken lines.

  As shown in FIGS. 16 and 17, when the fixing portion 50 is provided on the wiring portion 30, the substrate support portion 54 of the fixing portion 50 is disposed opposite to the gas vent valve 224 in the height direction via the non-forming region 34. The substrate support portion 54 is in contact with the outer surface 31 b of the non-forming area 34.

  As described above, even if the non-forming area 34 is pressed by the injection of gas from the degassing valve 224, the non-forming area 34 is supported by the substrate support portion 54. Thereby, the deformation of the non-formation region 34 is suppressed from occurring to such an extent that the non-formation region 34 is damaged. As a result, leakage of gas to the outside of the exhaust passage EP is suppressed.

  It goes without saying that the monitoring device 100 of the present embodiment exhibits the same effects as the monitoring device 100 described in the second embodiment.

(Second modification)
In the second embodiment and the third embodiment, the fixing unit 50 is pressed to the battery stack 210 by the battery case 230, so that the wiring unit 30 is pressed and fixed to the battery stack 210. However, it is also possible to adopt a configuration in which the fixing portion 50 is fixed to the battery stack 210 and the wiring portion 30 is pressed and fixed to the battery stack 210 by adopting the mode shown in FIGS. 18 to 20, for example.

  For example, in the case of the modification shown in FIG. 18, the fixing portion 50 having the above three legs is fixed (supported) to the battery stack 210 by the first connecting portion 55 and the second connecting portion 56. The first connection portion 55 is provided on the upper surface of each of the three legs in the height direction of the three legs, which is spaced from the battery stack 210. The first connecting portion 55 has a shape extending in the lateral direction more than the battery cell 220. The second connection portion 56 has a shape surrounding the lower end surface 220 b, the first side surface 220 c, and the second side surface 220 d of the battery cell 220. The second connection portion 56 is in contact with the lower end surface 220 b of each of the plurality of battery cells 220 constituting the battery stack 210.

  The first connecting portion 55 and the second connecting portion 56 face each other in the height direction. Bolt holes 57 a for inserting the bolts 57 are formed in mutually opposing portions of the first connection portion 55 and the second connection portion 56. By inserting and fastening the bolt 57 into the bolt hole 57a, the first connecting portion 55 and the second connecting portion 56 approach each other in the height direction. As a result, the three legs of the fixing portion 50 in contact with the first connection portion 55 and the battery stack 210 in contact with the second connection portion 56 approach each other in the height direction. Thus, the wiring portion 30 is pressed and fixed between the fixing portion 50 and the battery stack 210. The first connecting portion 55, the second connecting portion 56, and the bolt 57 correspond to a support portion.

  In the case of the modified example shown in FIG. 19, the pin 70 for pressing the series terminal 223 to the battery cell 220 is formed in the first connecting portion 55 shown in FIG.

  In the case of the modification shown in FIG. 20, the fixing portion 50 having the above-described three legs is fixed (supported) to the battery stack 210 by an elastically deformable annular band 58. The fixing portion 50, the wiring portion 30, and the battery stack 210 are provided in the area surrounded by the band 58. By the contraction force of the band 58, the fixing portion 50 and the battery stack 210 approach each other in the height direction. As a result, the wiring portion 30 is pressed and fixed between the fixing portion 50 and the battery stack 210. The band 58 corresponds to the support portion.

  Although the preferred embodiments of the present disclosure have been described above, the present disclosure is not limited to the above-described embodiments and can be variously modified and implemented without departing from the spirit of the present disclosure. It is.

(Third modification)
In each embodiment, for example, as shown in FIG. 9, the longitudinal cross-sectional shape of the exhaust passage EP partitioned by the non-formation region 34 separated from the battery cell 220 in the height direction from the formation region 33 forms a semicircle. An example is shown. However, the cross-sectional shape is not limited to the above example. For example, as shown in the (a) column of FIG. 21, the cross-sectional shape of the exhaust passage EP divided by the non-formation region 34 may be rectangular. As shown in the (d) column of FIG. 21, the cross-sectional shape of the exhaust passage EP divided by the non-formation region 34 may be triangular.

  In each embodiment, an example is shown in which the flexible substrate 31 is made of a resin material whose melting temperature is higher than the temperature of the gas released from the degassing valve 224. However, as shown in, for example, the columns (b) and (d) of FIG. 21, the resin material constituting the non-forming region 34 for partitioning a part of the exhaust passage EP of the flexible substrate 31 has a melting point higher than that of the above resin material. And a rigid high retention member 36 may be provided. The holding member 36 may be provided inside the resin material, or may be provided on the surface thereof.

  The holding member 36 may be formed at a position facing the gas release valve 224 in the height direction in the non-formation region 34, as shown in column (b) of FIG. According to this, damage to the resin material constituting the non-forming area 34 by the gas discharged from the gas release valve 224 is suppressed. As a result, leakage of gas out of the exhaust passage EP is suppressed.

  Further, as shown in the (c) column of FIG. 21, a configuration may be adopted in which the curved shape of the non-formation region 34 is defined by the holding member 36. In this modification, the cross-sectional shape of the exhaust passage defined by the non-formed area 34 is rectangular by one holding member 36 facing in the height direction and two holding members 36 facing in the lateral direction. The curved shape of the non-forming area 34 is defined. According to this, it is suppressed that the flow resistance of the gas flowing through the exhaust passage EP fluctuates due to the deformation of the non-formation region 34.

(The 4th modification)
In each embodiment, the exhaust passage EP is illustrated as being open in the longitudinal direction. However, the exhaust passage EP may open laterally. In the case of this modification, the opening side of the exhaust passage EP is formed by the formation region 33.

  In each embodiment, an example is shown in which the exhaust passage EP is opened to one side in the vertical direction. However, the exhaust passage EP may open to one side and the other side in the longitudinal direction.

(Fifth modification)
In each embodiment, an example in which the battery stack 210 has nine battery cells 220 is shown. However, the number of battery cells 220 included in the battery stack 210 is not limited to the above example and may be plural. The battery stack 210 may have an even number of battery cells 220.

  In each embodiment, the example in which the battery module 200 has one battery stack 210 is shown. However, the battery module 200 may have a plurality of battery stacks 210. In this case, an accommodation space corresponding to each battery stack 210 is formed in the housing 231 of the battery module 200. The plurality of accommodation spaces are provided side by side in the lateral direction.

  For example, when the battery cells 220 of two battery stacks 210 are connected in series, the two battery stacks 210 have an even number of battery cells 220. The negative electrode terminal 222 of the battery cell 220 positioned at the right end in one vertical direction of the two battery stacks 210 and the positive electrode terminal 221 of the battery cell 220 positioned at the other right end of the two battery stacks 210 It is electrically connected via a wire. As a result, the positive electrode terminal 221 of the battery cell 220 positioned at the left end in one vertical direction of the two battery stacks 210 has the highest potential, and the negative electrode terminal 222 of the battery cell 220 positioned at the other left end has the lowest potential. The highest potential positive electrode terminal 221 and the lowest potential negative electrode terminal 222 are arranged side by side in the lateral direction. Wiring portions 30 are provided for each of the two battery stacks 210.

(Sixth modification)
In each embodiment, an example in which the exhaust passage EP is configured by the non-formation region 34 is shown. However, the exhaust passage EP can also be constituted by at least one of the non-formation region 34 and the formation region 33.

(Other modifications)
In each embodiment, the example which applied the battery pack 400 to the hybrid vehicle was shown. However, the battery pack 400 can also be applied to, for example, a plug-in hybrid car or an electric car.

DESCRIPTION OF SYMBOLS 10 ... Monitoring part, 30 ... Wiring part, 31 ... Flexible substrate, 31a ... Inner surface, 32 ... Wiring pattern, 33 ... Formation area, 34 ... Non-formation area, 36 ... Holding member, 50 ... Fixing part, 50a ... Opposing surface, DESCRIPTION OF SYMBOLS 50b ... Back surface, 50c ... Through-hole, 51 ... 1st leg, 52 ... 2nd leg, 53 ... Connection leg, 54 ... Substrate support part, 55 ... 1st connection part, 56 ... 2nd connection part, 57 ... Bolts 58 Band 100 Monitoring device 200 Battery module 210 Battery stack 220 Battery cells 220a Upper end face 221 Positive electrode terminal 222 Negative electrode terminal 224 Degassing valve 230 Battery case, 231: case, 232: lid, 300: battery ECU, 400: battery pack, EP: exhaust passage

Claims (12)

A flexible substrate (31) formed with a wiring pattern (32) electrically connected to electrode terminals (221, 222) of a plurality of battery cells (220) connected in series in series;
A monitoring unit (10) for monitoring the voltage of the battery cell input through the wiring pattern;
And a fixing portion (50) for fixing the flexible substrate to the plurality of battery cells,
A gas vent valve (224) is formed on the surface (220a) on which the electrode terminal of the battery cell is formed;
The flexible substrate is fixed to the plurality of battery cells by the fixing portion in such a manner as to face the gas release valve in a separated manner, whereby the flexible substrate is released from the gas release valve by a part of the flexible substrate A monitoring device in which a part of an exhaust passage (EP) for exhausting gas is partitioned. The degassing valves of the plurality of battery cells are arranged in the arranging direction of the plurality of battery cells,
The fixing portion has a shape extending in the arranging direction so as to be disposed to face the formation surface of each of the plurality of battery cells.
In the fixing portion, a plurality of through holes (50c) passing through the facing surface (50a) facing the formation surface and the back surface (50b) opposite to the facing surface are respectively included in the plurality of battery cells It is formed in the fixed part corresponding to the degassing valve,
2. The monitoring device according to claim 1, wherein the flexible substrate is continuously fixed to the fixing portion along the alignment direction on both sides of the alignment of the plurality of through holes.   The monitoring device according to claim 2, wherein the flexible substrate is fixed to one of two end portions farther in the alignment direction than the plurality of through holes in the fixing portion. The degassing valves of the plurality of battery cells are arranged in the arranging direction of the plurality of battery cells,
The fixing portion includes a pressing portion (51 to 54) for pressing the flexible substrate against the formation surface of each of the plurality of battery cells, and a supporting portion (55 to 58, 232) for supporting the pressing portion. Have
The pressing portion has a first leg (51) and a second leg (52) extending in the row direction,
The flexible substrate is pressed and fixed to the formation surface of each of the plurality of battery cells by the pressing portion in a mode in which each of the plurality of degassing valves is positioned between the first leg and the second leg. And
The exhaust passage is divided by a region of the formation surface of the plurality of battery cells facing away from the flexible substrate and an inner surface (31a) facing away from the formation surface of the flexible substrate. The monitoring device according to claim 1, wherein A gap is formed between the plurality of battery cells adjacent in the row direction, and the gap is open to the exhaust passage,
The monitoring device according to claim 4, wherein a cross-sectional area orthogonal to the arranging direction of the exhaust passage is larger than an area of the space opened to the exhaust passage. The plurality of battery cells are accommodated in an accommodation space of a battery case (230),
The monitoring apparatus according to claim 4, wherein the exhaust passage communicates with the outside of the accommodation space. The pressing portion has, in addition to the first leg and the second leg, a connecting leg (53) connecting the first leg and the second leg,
The flexible substrate is formed by the pressing portion in such a manner that the flexible substrate is lined up with one of two of the plurality of degassing valves and one of the two positioned at the end with the connection legs in the arranging direction. The monitoring apparatus according to any one of claims 4 to 6, which is pressed and fixed to the.   In addition to the first leg and the second leg, the pressing portion further includes a substrate supporting portion (54) for supporting a portion of the flexible substrate facing the gas release valve so as to be opposed thereto. The monitoring apparatus of any one of -7. The flexible substrate has a formation area (33) of the wiring pattern and a non-formation area (34) of the wiring pattern,
The monitoring apparatus according to any one of claims 1 to 8, wherein a part of the exhaust passage is partitioned by the non-formation region.   10. The monitoring device according to claim 9, wherein the non-forming area is curved to be separated from the degassing valve.   The monitoring device according to claim 9 or 10, wherein a holding member (36) having a melting point and a rigidity higher than that of the resin material constituting the flexible substrate is provided in the non-formation region.   The monitoring device according to claim 11, wherein a shape of the non-forming area is defined by the holding member.

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