JP6702116B2 - Battery module - Google Patents

Description

  The present invention relates to a battery module in which battery cells and separators are alternately laminated and arranged, and more particularly to a structure of a smoke exhaust duct.

  For high voltage, high current output batteries such as in-vehicle batteries, a battery module in which a large number of battery cells are stacked is used. Usually, a battery pack is formed by housing a plurality of battery modules in a package. In addition, a stack of battery cells in one row is referred to as a battery stack, a stack of battery stacks is referred to as a battery module, and a stack of battery modules is often referred to as a battery pack. Here, a plurality of battery cells are combined. The thing is called a battery module.

  The battery module is provided with a smoke exhaust duct for exhausting gas generated from the battery cell to the outside of the battery module when an abnormality occurs. In Patent Document 1, a smoke exhaust duct is provided in the space above the battery cell.

JP, 2015-149146, A

  Here, since the smoke exhaust duct is configured by partitioning the space above the stacked battery cells, the smoke exhaust duct increases the height of the battery module and the battery pack, and the installation site must have a sufficient height. .. In the case of a battery pack to be mounted on a vehicle, it may be placed under a seat or the like, and there is also a demand for lowering the height. Therefore, if the height of the battery pack is reduced, the cross-sectional area of the smoke exhaust duct becomes smaller, the internal pressure rises, and gas leakage easily occurs.

  An object of the present invention is to provide a battery module in which gas leakage does not easily occur even if the height of the battery module is reduced.

The present invention is a battery module in which battery cells and separators are alternately stacked and arranged, and an upper portion of each separator is provided with a resin frame that defines a tunnel-shaped space extending in the stacking direction. A smoke exhaust duct is formed by connecting the ends of the resin frames in the stacking direction, and a plate-shaped thin wall is thin on one side of the connection part between the resin frames as compared to the other parts of the resin frame. Part is formed, and the other side of the connecting part has a triangular shape whose end extends downward in a cross section in the stacking direction, and the tip of the thin part on one side contacts the triangular slope on the other side. Touching .

  The resin frame may be made of thermoplastic resin.

  According to the present invention, the thin-walled portion of the connecting portion is deformed by heat and is connected to the other side, so that the sealing property of the connecting portion of the exhaust duct is improved and the gas leakage does not easily occur even if the height is lowered. ..

It is a perspective view of a battery module. It is a perspective schematic diagram which abbreviate|omitted the detailed structure of the separator. It is a schematic front view of a separator. It is an axial sectional view of the upper wall of the smoke exhaust duct of the connection part. 3 is a side view and a front cross section of a resin frame 28. It is a figure explaining the effect|action of the thin part 34.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiments described here.

  FIG. 1 is a perspective view of a battery module 12 that is an embodiment of the present invention. The battery module 12 includes a battery stack 14 and a pair of end plates 16 arranged on both sides of the battery stack 14 in the stacking direction. Furthermore, the battery stack 14 is configured by stacking battery cells 18 and separators 20 made of resin alternately in the thickness direction.

  Here, the battery cell 18 is a chargeable/dischargeable secondary battery, such as a lithium ion secondary battery or a sodium ion secondary battery. The battery cell 18 of the present embodiment is a prismatic battery having an electrode body housed in a flat rectangular parallelepiped cell case. A positive electrode terminal 22p and a negative electrode terminal 22n project from the upper end surface of the battery cell 18. The positive electrode terminal 22p and the negative electrode terminal 22n are arranged at intervals in the width direction. In addition, in FIG. 1, the positive electrode terminal 22p and the negative electrode terminal 22n are illustrated as substantially cylindrical shapes, but the shapes of these terminals 22p and 22n may be appropriately changed.

  A gas release valve (not shown) is provided in the widthwise center of the upper end surface of the battery cell 18, that is, between the positive electrode terminal 22p and the negative electrode terminal 22n. The gas release valve is a valve that releases gas generated inside the battery cell 18 when the battery cell 18 reacts abnormally. The gas release valve is closed when the internal pressure of the battery cell 18 is less than a certain value, but is opened when the internal pressure becomes a certain value or more to release the gas to the outside. This gas release valve is configured by, for example, forming a part of the case of the battery cell 18 into a thin wall so as to be broken when receiving a pressure of a certain level or more. However, the configuration of the gas release valve is not limited to this, and may be changed as appropriate.

  The plurality of battery cells 18 are stacked in the thickness direction. At this time, the plurality of battery cells 18 are arranged by alternately changing the directions so that the positive electrode terminals 22p and the negative electrode terminals 22n are alternately arranged in the stacking direction. That is, when a certain battery cell 18 is arranged so that the positive electrode terminal 22p is located on the right side, the next battery cell 18 is arranged so that the negative electrode terminal 22n is located on the right side. Then, the plurality of battery cells 18 are electrically connected in series by sequentially connecting the positive electrode terminal 22p and the negative electrode terminal 22n that are adjacent to each other in the stacking direction with a bus bar (not shown).

  A separator 20 is arranged between the battery cells 18. In other words, the battery stack 14 is formed by alternately stacking the plurality of battery cells 18 and the plurality of separators 20. The separator 20 is made of an insulating material and includes a substantially flat base portion and a resin frame 28 protruding from the upper end of the base portion. The base portion is a portion arranged between the battery cells 18.

  A resin frame 28 is provided at the upper end of the separator 20 and at the center in the width direction. The resin frame 28 is formed so as to project from the upper end of the base portion of the separator 20, and defines a tunnel-shaped space that extends toward the upper end surface of the battery cell 18 and that extends in the stacking direction. The upper wall of the resin frame 28 faces the gas release valve of the battery cell 18. Further, the resin frame 28 projects in the thickness direction from the base portion of the separator 20 and is in close contact with the resin frame 28 of another adjacent separator 20. When the ends of the plurality of resin frames 28 are in close contact with each other, a tunnel extending in the stacking direction is formed in the battery stack 14. This tunnel serves as a smoke exhaust duct through which the gas released from the gas release valve flows.

  A pair of end plates 16 are arranged on both sides of the battery stack 14 including the battery cells 18 and the separator 20 in the stacking direction. A battery module 12 is composed of the battery stack 14 and the pair of end plates 16. A plurality of such battery modules 12 are combined to form the battery module 12, and a plurality of the battery modules 12 are housed to form a battery pack.

  FIG. 2 is a schematic perspective view in which the detailed configuration of the separator 20 is omitted. The separator 20 has a base portion 26 and a resin frame 28. The resin frame 28 is a tunnel-shaped frame body extending in the stacking direction of the battery cells 18.

  FIG. 3 shows a schematic front view of the separator 20. As described above, a plurality of ribs 30 for forming the coolant flow path are formed on the surface of the base portion 26 at intervals. Further, in the resin frame 28, a V-shaped deflecting plate 32 is provided at least above the gas ejection port, so that the gas ejected upward from the battery cell 18 at the time of an abnormality is discharged. In the cross section of the duct, the flow is separated into clockwise and counterclockwise flows to prevent the hot gas from colliding with only one place of the upper wall 28a.

  FIG. 4 shows an axial cross section of the upper wall 28a of the smoke exhaust duct at the connecting portion. In this way, the upper wall 28a of one resin frame 28 has the flat thin portion 34 having one axial side extending from the upper portion thereof. On the other side of the upper wall 28a of the resin frame 28, the lower end side has a triangular cross section in which the lower end side extends to the line end side, and a slope 36 is formed here. Therefore, the line end of the thin portion 34 at one end of the resin frame 28 is in contact with the slope 36 at the other end of the adjacent resin frame 28.

  5A and 5B show schematic side and front cross-sections of the resin frame 28 (the cross-section of the thin portion 34 can be seen). As described above, the thin portion 34 is provided not only on one side of the upper wall of the resin frame 28 but also on the left and right side walls, and has a U shape (inverted U shape in the figure) as a whole. The other end of the resin frame 28 has slopes 36 not only on the upper wall 28a but also on the left and right side walls. Therefore, at the connecting portion between the adjacent resin frames 28, the U-shaped thin portion 34 of one resin frame 28 is in contact with the slope 36 of the other resin frame 28. As described above, in the present embodiment, not only the upper wall of the resin frame 28 but also the side wall is provided with the thin portion 34 at the connection portion with the adjacent resin frame 28.

  FIG. 6 describes the operation of the thin portion 34. At the time of manufacturing the battery module 12 in a factory, as shown in FIG. 6A, the thin portion 34 on one side of the resin frame 28 extends straight and its tip is in contact with the slope 36 on the other side.

  On the other hand, when a high temperature gas is discharged from the battery cell 18 at the time of abnormality, the thin portion 34 near the gas discharge portion becomes high temperature and is deformed by the heat of the high temperature gas. In particular, when the thin wall portion 34 is formed of a thermoplastic resin, the thin wall portion 34 is plastically deformed by heat so that the tip end side hangs down, as shown in FIG. 6B. Then, the lower surface of the thin portion 34 melts, adheres to the slope 36 of the adjacent resin frame 28, and is sealed here. Then, the gas discharge from the battery cell 18 is only for the duration of the reaction of gas generation and not for a long time. Therefore, when the gas generation ends, the thin portion 34 is connected to the slope, and a sufficient airtight seal is formed here.

  As described above, according to the present embodiment, when the high temperature gas is discharged from the abnormal battery cell 18, the thin-walled portion 34 is slightly formed in the connection portion of the smoke exhaust duct in the vicinity where the gas discharge occurs. By melting, the sealing property of the smoke exhaust duct can be improved.

  Therefore, the height of the smoke exhaust duct is made relatively low, the cross-sectional area of the smoke exhaust duct is made small, and even if the pressure inside the smoke exhaust duct rises due to the exhaust gas from the battery cells, Can be prevented from leaking.

12 battery module, 14 battery stack, 16 end plate, 18 battery cell, 20 separator, 22n negative electrode terminal, 22p positive electrode terminal, 26 base portion, 28 resin frame, 28a upper wall, 30 rib, 32 deflection plate, 34 thin portion , 36 slopes.

Claims (1)

A battery module in which battery cells and separators are alternately stacked and arranged,
A resin frame for partitioning a tunnel-shaped space extending in the stacking direction is provided above each separator,
A smoke exhaust duct is formed by connecting the ends of the resin frames of the adjacent separators in the stacking direction,
On one side of the connecting portion between the resin frames, a thin plate-shaped thin portion is formed as compared to the other portion of the resin frame ,
The other side of the connection part has a triangular shape whose end extends downward in a cross section in the stacking direction,
The tip of the thin portion on one side is in contact with the triangular slope on the other side,
Battery module.

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