JP6194745B2 - Storage device leakage detection device - Google Patents

Description

  The present invention relates to a leakage detection device for a power storage device.

  Conventionally, a power storage device such as a secondary battery or a capacitor includes an exterior member (case), an electrode assembly housed in the exterior member, and an electrolyte filled in the exterior member. For example, as disclosed in Patent Document 1, a leak detection device that detects an electrolyte leaked from an exterior member has been proposed. The leak detection device of Patent Literature 1 includes two copper foil patterns, and detects leakage of the electrolyte by detecting a short circuit between the two copper foil patterns.

JP 2001-84996 A

  However, in the leak detection apparatus of Patent Document 1, two copper foil patterns for detecting leakage of the electrolyte solution are arranged in parallel at an interval of 1 mm. For this reason, the leak detection apparatus of Patent Document 1 cannot detect the leakage of the electrolyte until the lump of the electrolyte leaked from the exterior member becomes 1 mm or more.

  The present invention has been made paying attention to the problems existing in the above-described prior art, and an object of the present invention is to provide a leakage detection device for a power storage device capable of detecting a small amount of electrolyte leakage.

A leak detection device for a power storage device that solves the above problems includes a bottomed rectangular tube-shaped main body that accommodates an electrode assembly, and a lid that seals the opening by being welded to the opening of the main body. A leakage detection device for a power storage device, comprising: a base member and an electrode assembly housed in the case; and an electrolyte solution filled in the case. A plurality of conductive members arranged, and an interval between the plurality of conductive members is 1 μm or more and 100 μm or less, and an energization detection unit that detects energization between the plurality of conductive members, The base material is disposed at a position corresponding to a welded portion between the main body and the lid, and a battery module is configured by arranging a plurality of the power storage devices. The base material is welded to the main body portion and the lid portion. In a corresponding position, the power storage devices are arranged so as to extend along the direction in which the power storage devices are arranged, and the plurality of conductive members extend in parallel with each other along the direction in which the power storage devices are arranged, and The both ends are open, and the plurality of conductive members are disposed at the second end opposite to the first end from the power storage device disposed at the first end in the direction in which the power storage devices are arranged. A first conductive member extending across the power storage device, and a plurality of second conductive members extending across the two or more power storage devices including the power storage device disposed at the first end. The gist of the plurality of second conductive members is that the number of the power storage devices extending from the power storage device disposed at the first end is different .

According to this configuration, the adjacent conductive members are short-circuited even if the volume of the electrolyte solution leaked from the exterior member is less than 300 μm. And the short circuit between electroconductive members is detected by the electricity supply detection means. Therefore, a smaller amount of electrolyte leakage can be detected .

  Regarding the leak detection device for the power storage device, the base material is preferably subjected to ozone treatment. According to this structure, the fine unevenness | corrugation is provided in the surface of the base material by ozone treatment. The interval between the conductive members can be reduced because the adhesion between the conductive member and the substrate is improved. Furthermore, since the affinity between the electrolytic solution and the base material is improved, a smaller amount of leakage of the electrolytic solution can be detected.

  About the said leakage detection apparatus of an electrical storage apparatus, it is preferable that the said electroconductive member is copper printed wiring and the width | variety of the said copper printed wiring is 1 micrometer or more and 100 micrometers or less. According to this structure, the area | region in which a conductive member is arrange | positioned in a base material can be further reduced. Therefore, a smaller amount of electrolyte leakage can be detected.

  According to the present invention, it is possible to detect a small amount of electrolyte leakage.

The perspective view which shows an electrical storage apparatus module typically. The schematic diagram of a leak detection apparatus. The perspective view which shows typically the electrical storage apparatus module in another embodiment. The perspective view which shows typically the electrical storage apparatus module in another embodiment.

Hereinafter, an embodiment of a leakage detection device for a power storage device will be described.
Initially, with reference to FIG. 1, the electrical storage apparatus module 11 used as the test object of the leak detection apparatus 10 is demonstrated. The power storage device module 11 includes a plurality of power storage devices 12a to 12i. The power storage devices 12a to 12i are arranged in a straight line and in a line. Hereinafter, for convenience of explanation, the direction in which the power storage devices 12a to 12i are arranged is simply referred to as an arrangement direction D as indicated by arrows in the drawing. Each of the power storage devices 12a to 12i is, for example, a lithium ion secondary battery, a nickel hydride secondary battery, and an electric double layer capacitor.

  Each of the power storage devices 12a to 12i includes a case 13 as an exterior member, an electrode assembly accommodated in the case 13, and an electrolytic solution (electrolyte) filled in the case 13. The case 13 includes a bottomed rectangular tube-shaped main body portion 13a that houses the electrode assembly, and a lid portion 13b that seals an opening of the main body portion 13a. As for the cover part 13b, the perimeter of the cover part 13b is welded to the main-body part 13a.

  The lid portion 13b operates when the internal pressure of the case 13 rises to a specified pressure, and has a safety valve 13c for reducing the internal pressure. The lid portion 13b has an external terminal 13d that is electrically connected to the electrode assembly. The external terminal 13 d protrudes outside the case 13.

  Next, the leak detection apparatus 10 will be described with reference to FIG. The leak detection apparatus 10 includes a printed circuit board 22 as a detection unit having a flexible substrate 21 as a base material and copper printed wirings LB and L1 to L9 as a plurality of conductive members, and a plurality of copper printed wirings LB and L1. And an energization detection circuit 23 as an energization detecting means for detecting energization between L9 and L9.

  The printed wiring board 22 extends along the arrangement direction D at the positions corresponding to the welded portions of the main body portion 13a and the lid portion 13b on both side surfaces of the power storage device module 11 in the direction orthogonal to the arrangement direction D. Are arranged to be. That is, the copper printed wirings LB, L1 to L9 extend along the arrangement direction D. In the present embodiment, the copper printed wiring LB is a first conductive member, and the copper printed wirings L1 to L9 are second conductive members.

  The length of the printed wiring board 22 along the arrangement direction D is larger than the length of the power storage device module 11 along the arrangement direction D. And the copper printed wiring LB is extended over the electrical storage apparatus 12i arrange | positioned from the electrical storage apparatus 12a arrange | positioned in the 1st end in the arrangement direction D to the 2nd end opposite to the 1st end. . The copper printed wiring L1 is connected to each of the power storage devices 12a to 12i, the copper printed wiring L2 is connected to each of the power storage devices 12a to 12h, the copper printed wiring L3 is connected to each of the power storage devices 12a to 12g, and the copper printed wiring L4 is connected to each of the power storage devices 12a to 12f. It extends across.

  The copper printed wiring L5 is each power storage device 12a-12e, the copper printed wiring L6 is each power storage device 12a-12d, the copper printed wiring L7 is each power storage device 12a-12c, the copper printed wiring L8 is each power storage device 12a-12b, Copper printed wiring L9 extends across power storage device 12a. That is, each of the copper printed wirings L1 to L9 includes a plurality of copper printed wirings having different numbers of power storage devices extending from the first power storage device 12a.

  Each copper printed wiring LB, L1 to L9 is disposed on one surface of the flexible substrate 21. The printed wiring board 22 is disposed with the surface on which the copper printed wirings LB, L1 to L9 are disposed facing the power storage devices 12a to 12i.

  The copper printed wirings LB, L1 to L9 are parallel to each other. The intervals between the copper printed wirings LB, L1 to L9 are 1 μm or more and 100 μm or less. The width of each copper printed wiring LB, L1 to L9 is, for example, not less than 1 μm and not more than 100 μm. Each copper printed wiring LB, L1-L9 is open at both ends. For convenience of explanation, in FIG. 2, the width of the printed wiring board 22 and the widths and intervals of the copper printed wirings LB, L1 to L9 are shown larger than actual.

  The flexible substrate 21 is subjected to ozone treatment. The ozone treatment is a treatment in which the flexible substrate 21 is immersed in an ozone solution and the surface of the flexible substrate 21 is eroded. For this reason, the surface of the flexible substrate 21 is covered with fine irregularities.

  For this reason, even if the interval between the copper printed wirings LB, L1 to L9 is 1 μm to 100 μm, and the width of each copper printed wiring LB, L1 to L9 is fine, for example, 1 μm to 100 μm. Even when exposed to vibration or temperature change, it is difficult to peel off from the flexible substrate 21.

  In addition, an energization detection circuit 23 is connected to each of the copper printed wirings LB, L1 to L9. The energization detection circuit 23 includes a battery unit 24 as a supply unit that supplies current (electric power) between the copper printed wiring LB and the copper printed wirings L1 to L9. The copper printed wiring LB is connected to the positive electrode of the battery unit 24. Moreover, each copper printed wiring L1-L9 is connected to the negative electrode of the battery part 24. FIG.

  The energization detection circuit 23 includes a plurality of voltage sensors 25 that respectively detect voltage values between the copper printed wiring LB and the copper printed wirings L1 to L9. The energization detection circuit 23 includes a plurality of current sensors 26 that detect current values between the copper printed wiring LB and the copper printed wirings L1 to L9. The energization detection circuit 23 calculates a resistance value between the copper printed wiring LB and each of the copper printed wirings L1 to L9 based on the detected voltage value and current value, and based on the calculated change in resistance value. ECU (Electronic Control Unit) 27 for detecting energization separately. In FIG. 2, a part of the voltage sensor 25, the current sensor 26, and the wiring are illustrated.

Next, a leak detection method using the leak detection apparatus 10 configured as described above will be described together with its function.
The printed wiring board 22 extends along the arrangement direction D at the positions corresponding to the welded portions of the main body portion 13a and the lid portion 13b on both side surfaces of the power storage device module 11 in the direction orthogonal to the arrangement direction D. Arrange them as you like.

  In this state, when the electrolytic solution does not leak from the power storage device module 11, the copper printed wirings LB, L1 to L9 are opened on the side where the energization detection circuit 23 is not connected. For this reason, the current supplied from the battery unit 24 does not flow because the resistance value between the copper printed wiring LB and each of the copper printed wirings L1 to L9 is high. The ECU 27 determines that no leakage of the electrolyte has occurred because the resistance value between the copper printed wiring LB and each of the copper printed wirings L1 to L9 does not change.

  On the other hand, when the electrolytic solution leaks from the power storage device module 11, the copper printed wiring LB and the copper printed wirings L1 to L9 form a closed circuit by the leaked electrolytic solution. In the present embodiment, at least the copper printed wiring LB and the copper printed wiring L1 are short-circuited even if the volume of the electrolyte leaked from the case 13 is less than 300 μm. The current supplied from the battery unit 24 flows because the resistance value between the copper printed wiring LB and the copper printed wirings L1 to L9 in which a short circuit has occurred decreases. When the resistance value between the copper printed wiring LB and each of the copper printed wirings L1 to L9 decreases, the ECU 27 determines that the electrolyte solution has leaked. In this case, the ECU 27 may control a notifying unit (not shown) to notify that the electrolyte is leaking.

  Moreover, ECU27 specifies the electrical storage apparatus from which electrolyte solution leaked out among electrical storage apparatuses 12a-12i based on the combination of the copper printed wiring in which resistance value fell. For example, when the copper printed wirings LB, L1 to L5 are short-circuited by the bulk electrolyte 30, the ECU 27 detects a decrease in the resistance value between the copper printed wiring LB and each of the copper printed wirings L1 to L5. A decrease in resistance value between the copper printed wiring LB and each of the copper printed wirings L6 to L9 is not detected. In this case, ECU 27 determines that electrolyte solution has leaked from power storage device 12e among power storage devices 12a to 12i. ECU27 may notify the electrical storage apparatus from which the electrolyte solution has leaked by controlling the alerting | reporting means which is not shown in figure, when the electrical storage apparatus from which the electrolyte solution leaked is specified.

Therefore, the above embodiment has the following effects.
(1) The intervals between the copper printed wirings LB, L1 to L9 are 1 μm or more and 100 μm or less. For this reason, the leak detection device 10 can detect the leakage of the electrolyte even when the lump of the electrolyte leaked from the case 13 has a size of less than 300 μm. Therefore, a smaller amount of electrolyte leakage can be detected.

  (2) The surface of the flexible substrate 21 is provided with fine irregularities by ozone treatment. For this reason, the adhesiveness of copper printed wiring LB, L1-L9 and the flexible substrate 21 is improved. That is, the copper printed wirings LB, L1 to L9 are difficult to peel from the flexible substrate 21 even when the interval is narrowed. Therefore, the distance between the copper printed wirings LB, L1 to L9 can be reduced as compared with the case where the ozone treatment is not performed. Furthermore, since the affinity between the electrolytic solution and the flexible substrate 21 is improved, a smaller amount of leakage of the electrolytic solution can be detected.

  (3) The width of each copper printed wiring LB, L1 to L9 is, for example, not less than 1 μm and not more than 100 μm. For this reason, in the flexible substrate 21, the area | region where copper printed wiring LB, L1-L9 is arrange | positioned can be made further smaller. Therefore, a smaller amount of electrolyte leakage can be detected.

  (4) The widths and intervals of the copper printed wirings LB and L1 to L9 as described above are possible because the adhesion between the flexible substrate 21 and the copper printed wirings LB and L1 to L9 is enhanced by ozone treatment. . The width of the printed wiring board 22 can be reduced by setting the widths and intervals of the copper printed wirings LB, L1 to L9 as described above.

  (5) The printed wiring board 22 is arranged so as to extend along the arrangement direction D at a position corresponding to a welded portion between the main body portion 13a and the lid portion 13b. For this reason, the leak detection apparatus 10 can easily detect the electrolyte solution leaked from the welded portion between the main body portion 13a and the lid portion 13b in the case 13, which may have insufficient strength.

  (6) The printed wiring boards 22 are respectively arranged on both side surfaces of the power storage device module 11 in a direction orthogonal to the arrangement direction D. Therefore, leakage of the electrolyte is detected more reliably.

The embodiment is not limited to the above, and may be embodied as follows, for example.
As shown in FIG. 3, the printed wiring board 22 may be wound so as to cover a welded portion between the main body portion 13 a and the lid portion 13 b in a part or all of the power storage devices 12 a to 12 i. In this case, every other power storage device in which the printed wiring board 22 is arranged may be provided.

  As shown in FIG. 4, the printed wiring board 22 may be disposed along the safety valve 13c. According to this configuration, it can be detected that the internal pressure of the case 13 has increased and the safety valve 13c has been activated.

The number and polarity of the copper printed wirings LB, L1 to L9 can be changed as appropriate.
The number of power storage devices that constitute the power storage device module 11 may be 8 or less, or 10 or more.

(Circle) copper printed wiring LB and L1-L9 may be arrange | positioned on the hard board | substrate. Further, the size and shape of the flexible substrate 21 may be changed.
The flexible substrate 21 may have a copper wire instead of the copper printed wirings LB, L1 to L9. Moreover, you may use metals other than copper.

Each of the power storage devices 12a to 12i may be a cylindrical power storage device, or may be a pentagonal prism or a hexagonal prism.
The number of power storage devices to be inspected by the leak detection device 10 may be one.

The leak detection device 10 only needs to be able to detect leakage of the electrolytic solution, and may have a configuration that does not specify the power storage device in which the leak has occurred.
The leak detection device 10 may have only one printed wiring board 22 or may have three or more.

  The ECU 27 may further function as a charge controller for each of the power storage devices 12a to 12i. In this case, the ECU 27 may stop charging the power storage devices 12a to 12i when leakage of the electrolyte is detected during charging.

  (Circle) the electrical storage apparatus module 11 which assembled | attached the leak detection apparatus 10 may be mounted in the vehicle. In this case, since the printed wiring board 22 can be reduced in size, it is possible to suppress the flow of the heat exchange medium for adjusting the temperature of the power storage device module 11 from being hindered.

Hereinafter, a technical idea that can be grasped from the embodiment and the modified examples will be additionally described.
(A) Preferably, the power storage device module includes a plurality of power storage devices, and the plurality of power storage devices are arranged side by side, and includes a leakage detection device for the power storage device.

(B) The conductive member extends along a direction in which the plurality of power storage devices are arranged, and includes a first conductive member and a second conductive member having a polarity different from that of the first conductive member. Have
The first conductive member extends from the power storage device disposed at the first end in the alignment direction to the power storage device disposed at the second end opposite to the first end,
The second conductive member preferably includes a plurality of conductive members having different numbers of power storage devices extending from the first power storage device.

  LB ... Copper printed wiring (conductive member, first conductive member), L1 to L9 ... Copper printed wiring (conductive member, second conductive member), 10 ... Leak detection device, 11 ... Power storage device module, 12a- 12i ... Power storage device, 21 ... Flexible substrate (base material), 22 ... Printed wiring board (detection unit), 23 ... Energization detection circuit (energization detection means).

Claims (3)

A case having a bottomed rectangular tube-shaped main body portion that accommodates the electrode assembly, and a lid portion that seals the opening portion by being welded to the opening portion of the main body portion;
An electrode assembly housed in the case;
An electrolyte solution filled in the case, and a leakage detection device for a power storage device,
A detection unit having a base material and a plurality of conductive members disposed on the base material, wherein the interval between the plurality of conductive members is 1 μm or more and 100 μm or less;
An energization detecting means for detecting energization between the plurality of conductive members,
The base material is disposed at a position corresponding to a welded portion between the main body portion and the lid portion ,
A battery module is configured by arranging a plurality of the power storage devices,
The base material is arranged so as to extend along a direction in which the power storage devices are arranged at a position corresponding to a welded portion between the main body portion and the lid portion,
The plurality of conductive members extend in parallel to each other along a direction in which the power storage devices are arranged, and both ends are open,
The plurality of conductive members extend from a power storage device disposed at a first end in a direction in which the power storage devices are arranged to straddle a power storage device disposed at a second end opposite to the first end. A first conductive member, and a plurality of second conductive members extending across the two or more power storage devices including the power storage device disposed at the first end,
Each of the plurality of second conductive members is a leakage detection device for a power storage device in which the number of power storage devices extending across the power storage device disposed at the first end is different . The leak detection device for a power storage device according to claim 1, wherein the base material is subjected to ozone treatment. The conductive member is a copper printed wiring,
The leakage detection device for a power storage device according to claim 1 or 2 , wherein a width of the copper printed wiring is 1 µm or more and 100 µm or less.