JP7107247B2 - battery module - Google Patents

Description

The disclosure provided herein relates to a battery module comprising a plurality of battery cells.

As shown in Patent Document 1, a battery module is known in which a plurality of cells are housed in a module case. A plurality of slits as ventilation holes are formed on both sides of the module case. Cooling air flows into the module case through a slit formed on one side surface. Cooling air flows out of the module case through a slit formed in the other side surface.

JP 2016-115599 A

In the battery module disclosed in Patent Document 1, if there is a difference in the amount of cooling air flowing into the plurality of slits, the cooling effect of the cooling air (fluid) for each of the plurality of single cells (battery cells) may vary. be.

Therefore, an object of the disclosure described in this specification is to provide a battery module that suppresses variation in the cooling effect of the fluid in each of the plurality of battery cells.

One of the disclosures is a battery stack (10) comprising four or more battery cells (11) arranged in order with gaps in the row direction,
a case (30) for storing four or more battery cells in the storage space;
The case has a housing (31) having an opening, and a lid body (32) that forms a storage space together with the housing by being connected to the housing in a manner that closes the opening of the housing,
The housing has a bottom wall (34) and an annular wall (35) standing annularly from an inner bottom surface (34a) of the bottom wall,
The annular wall includes a first end wall (35a) and a second end wall (35b) spaced apart in the row direction, and a first side wall (35c) and a second wall connecting the first end wall and the second end wall. having a side wall (35d);
Each of the first side wall and the second side wall has three or more slits (36) that open to the inner side surface (35e) of the first side wall and the second side wall on the storage space side and the outer side surface (35f) of the back side thereof. formed,
The slit formed in the first side wall and the slit formed in the second side wall are arranged in the horizontal direction in which the first end wall and the second end wall are arranged with a gap therebetween,
Of the three or more slits, the slit closest to the first end wall and the three or more slits closest to the second end wall in at least one of the outer surfaces of the first side wall and the second side wall prevents the flow of fluid supplied from the duct (300) to the outer surface from one of the first end wall and the second end wall to the other in the arrangement area (AR) between the slit located in Blocking members (90-92) are provided.

For example, when the fluid flowing from the first end wall (35a) side to the second end wall (35b) side on the outer surface (35f) is supplied from the duct (300), the fluid flows toward the second end wall (35b) side. The behavior of flowing from the slit (36) to the slit (36) on the side of the first end wall (35a) in order is shown. The flow rate of fluid flowing into the slit (36) on the second end wall (35b) side tends to be greater than the flow rate of fluid flowing into the slit (36) on the first end wall (35a) side.

In contrast, in the present disclosure, the arrangement area (AR) of the outer surface (35f) is provided with a structure that impedes the flow of fluid from one of the first end wall (35a) and the second end wall (35b) to the other. Blocking members (90-92) are provided. This makes it easier to reduce the flow rate of the fluid flowing into the slit (36) on the other side of the first end wall (35a) and the second end wall (35b). Due to the reduction, the flow rate of the fluid flowing into the slit (36) on one side of the first end wall (35a) and the second end wall (35b) is likely to increase. As a result, an increase in the difference in the flow rate of the fluid flowing into each of the plurality of gaps through each of the plurality of slits (36) is suppressed. This suppresses variation in the cooling effect of the fluid in each of the plurality of battery cells (11).

It should be noted that the reference numbers in parentheses above merely indicate the correspondence with the configurations described in the embodiments described later, and do not limit the technical scope in any way.

It is a top view for demonstrating a vehicle-mounted power supply. 3 is an exploded perspective view showing the internal configuration of the battery module; FIG. FIG. 2 is a perspective view showing an external configuration of a battery module; FIG. 2 is a perspective view showing an external configuration of a battery module; 1 is a side view of a battery module according to a first embodiment; FIG. It is a schematic diagram for demonstrating a comparison structure. FIG. 6 is a schematic diagram for explaining the vertical cross-sectional shape of the battery module along the cross-sectional line A shown in FIG. 5; FIG. 5 is a schematic diagram for explaining the flow of cooling air when the battery module is placed in an inverted position with respect to the duct; FIG. 4 is a side view of a battery module according to a second embodiment; FIG. 10 is a schematic diagram for explaining the vertical cross-sectional shape of the battery module along the cross-sectional line B shown in FIG. 9; FIG. 5 is a schematic diagram for explaining the flow of cooling air when the battery module is placed in an inverted position with respect to the duct; FIG. 11 is a side view of a battery module according to a third embodiment; FIG. 13 is a schematic diagram for explaining the vertical cross-sectional shape of the battery module along the cross-sectional line C shown in FIG. 12; FIG. 4 is a side view of the battery module showing a specific example of the blocking member;

Embodiments will be described below with reference to the drawings.

(First embodiment)
A battery module according to the present embodiment will be described with reference to FIGS. 1 to 8. FIG. The battery module of this embodiment is applied to vehicles such as electric vehicles and plug-in hybrid vehicles.

The three directions that are orthogonal to each other are hereinafter referred to as the x-direction, the y-direction, and the z-direction. The x direction corresponds to the horizontal direction. The y direction corresponds to the alignment direction.

<Automotive battery>
As shown in FIG. 1, a plurality of battery modules 100 are mounted on a vehicle. The plurality of battery modules 100 are connected in series by a wire harness 101 or the like. An on-vehicle power source 200 is thus configured. The onboard power supply 200 functions to power the electrical loads of the vehicle.

As shown in FIG. 1, a duct 300 of the vehicle is connected to each of the plurality of battery modules 100 included in the vehicle-mounted power source 200 . A fluid for adjusting the temperature of the plurality of battery cells 11 included in the battery module 100 is supplied from the duct 300 . As a result, excessive temperature changes in the battery cells 11 are suppressed. The flow direction of the fluid supplied from each of the plurality of ducts 300 is uniformly determined.

As the installation location of the vehicle-mounted power supply 200, for example, the space under the front seat of the vehicle, the space under the rear seat, the space between the rear seat and the trunk room, and the like can be adopted.

<Battery module>
As shown in FIGS. 2-4, the battery module 100 has a battery stack 10, a case 30, a monitor 50, and a cover . The battery stack 10 is housed in the housing space of the case 30 . The monitoring unit 50 is provided outside the case 30 . The cover 70 is connected to the case 30 so as to cover the monitoring section 50 .

The battery stack 10 has a plurality of battery cells 11 arranged in the y direction. A case 30 holds the plurality of battery cells 11 arranged in the y direction.

The case 30 has a housing 31 having an opening and a lid body 32 fixed to the housing 31 in a manner to close the opening. A slit 36 is formed in the housing 31 for communicating a storage space formed by the housing 31 and the lid 32 and a space outside the storage space (external space). Fluid supplied from the duct 300 flows through the slit 36 into the storage space. The fluid that has flowed through the storage space flows out of the storage space through this slit 36 .

A plurality of openings are formed in the lid 32 for exposing the positive terminal 12 and the negative terminal 13 of each of the plurality of battery cells 11 to the outside of the storage space. A series bus bar is provided on the outer wall of the lid body 32 in a manner to close the opening. The series bus bar is joined to one positive electrode terminal 12 and the other negative electrode terminal 13 of two battery cells 11 adjacent to each other in the y direction. Thereby, the plurality of battery cells 11 are electrically connected in series via the series bus bar.

Further, the cover 32 is provided with a sensor portion for detecting the output voltage of the plurality of battery cells 11 and the temperature of the battery stack 10 . The sensor unit outputs detection results indicating the output voltage of the battery cell 11 and the temperature of the battery stack 10 to the monitoring unit 50 as analog signals.

Specifically, the sensor section has a plurality of voltage detection lines each having one end connected to each of a plurality of series bus bars. The sensor section has a thermistor that detects the temperature of the battery stack 10 and a temperature detection line that is connected to the thermistor at one end. The sensor section has a sensor connector that connects the other ends of the plurality of detection lines.

The monitoring unit 50 has a printed board 51 , a first connector 52 and a second connector 53 . A first connector 52 and a second connector 53 are mounted on the printed circuit board 51 . A sensor connector is electrically connected to the first connector 52 via a wire harness. An external battery ECU is electrically connected to the second connector 53 via a wire harness.

Although not shown, the printed circuit board 51 is formed with circuit portions electrically connected to the first connector 52 and the second connector 53 respectively. The circuit section includes a high-voltage circuit section electrically connected to the first connector 52, a low-voltage circuit section electrically connected to the second connector 53, and electrically insulating these two circuit sections. and an isolation circuit unit for transmitting and receiving signals to and from each other. The high-voltage circuit section has a monitoring IC chip. The monitoring IC chip converts an analog signal as a detection result input from the sensor unit into a digital signal. The isolation circuit section outputs the digital signal input from the high-voltage circuit section to the low-voltage circuit section. The low-voltage circuit section has a communication microcomputer. Through communication with the battery ECU, the microcomputer outputs to the battery ECU a digital signal as a detection result input from the insulating circuit section.

The battery ECU determines equalization of the SOC of each of the plurality of battery cells 11 based on the input voltage and temperature detection results. Then, the battery ECU outputs an instruction for equalization processing to the monitoring unit 50 based on the judgment. This instruction signal is input to the monitoring IC chip of the high-voltage circuit section through the low-voltage circuit section and the insulating circuit section. The monitoring IC chip includes switches for individually charging and discharging the plurality of battery cells 11 . The monitoring IC chip controls opening and closing of the switch according to instructions input from the battery ECU. Thereby, the plurality of battery cells 11 are individually charged and discharged. As a result, the SOCs of the plurality of battery cells 11 are equalized. SOC is an abbreviation for state of charge.

The cover 70 is connected to the case 30 so as to face the outer wall of the lid 32 while being spaced apart in the z-direction. A space is formed between the cover 70 and the lid body 32 by this connection. A series busbar, a sensor section, and a monitoring section 50 are provided in this space. A cover 70 covers each of the series bus bar, the sensor section, and the monitoring section 50 .

The cover 70 has an opening for exposing the second connector 53 to the outside of the space between the lid 32 and the cover 70 . A connector of a wire harness can be inserted into and removed from the second connector 53 through this opening. Snap fit, for example, can be used to connect the cover 70 and the case 30 .

<Battery stack>
As described above, the battery stack 10 has four or more battery cells 11 arranged in the y direction. Each of the plurality of battery cells 11 has a power generation element and a metal battery case that houses the power generation element. The battery case has a square prism shape. Therefore, the battery case (battery cell 11) has six sides.

The battery cell 11 has an upper surface 11a and a lower surface 11b facing in the z-direction. The battery cell 11 has a first principal surface 11c and a second principal surface 11d facing in the y direction. The battery cell 11 has a first lateral surface 11e and a second lateral surface 11f facing in the x direction. Among these six surfaces, the first main surface 11c and the second main surface 11d are larger in area than the other four surfaces.

Battery cell 11 is a secondary battery. Specifically, the battery cell 11 is a lithium ion battery. Lithium-ion batteries generate an electromotive voltage through a chemical reaction. A current flows through the battery cell 11 due to the generation of the electromotive voltage. The battery cells 11 generate gas due to this energization and aged deterioration. The generation of gas causes the battery cell 11 to expand. When the battery cell 11 swells to such an extent that the external shape of the metal battery case changes, the battery cell 11 is desired to be replaced. Note that the battery cells 11 are not limited to lithium ion batteries. For example, as the battery cell 11, a nickel-hydrogen secondary battery, an organic radical battery, or the like can be employed.

As described above, the first main surface 11c and the second main surface 11d of the battery cell 11 are larger in area than the other four surfaces. Therefore, in the battery cell 11, the first main surface 11c and the second main surface 11d are likely to expand. As a result, the battery cell 11 expands in the y direction. That is, the battery cell 11 expands in the direction in which the plurality of battery cells 11 are arranged.

A positive terminal 12 and a negative terminal 13 are formed on the upper surface 11 a of the battery cell 11 . The positive terminal 12 and the negative terminal 13 are arranged in the x direction. The positive electrode terminal 12 is located on the side of the first horizontal surface 11e. The negative electrode terminal 13 is positioned on the second horizontal surface 11f side.

As shown in FIG. 2, two adjacent battery cells 11 face each other at their first main surfaces 11c and at their second main surfaces 11d. As a result, the positive terminal 12 of one of the two adjacent battery cells 11 and the negative terminal 13 of the other are arranged in the y direction. As a result, in the battery stack 10, the positive terminals 12 and the negative terminals 13 are alternately arranged in the y direction.

One positive electrode terminal 12 and one negative electrode terminal 13 adjacent to each other in the y direction are electrically connected via the series bus bar. Thereby, the plurality of battery cells 11 forming the battery stack 10 are electrically connected in series.

Due to the electrical connection configuration described above, the plurality of battery cells 11 are arranged in order of potential in the y direction. Among the plurality of battery cells 11 arranged in the y direction, the battery cell 11 with the highest potential is located on one side of both ends. Among the plurality of battery cells 11 arranged in the y direction, the battery cell 11 with the lowest potential is positioned on the other side of both ends. A positive connection terminal 14 is connected to the positive terminal 12 of the battery cell 11 with the highest potential. A negative connection terminal 15 is connected to the negative terminal of the battery cell 11 with the lowest potential.

As shown in FIGS. 3 and 4 , the positive connection terminal 14 and the negative connection terminal 15 are located outside the storage space of the case 30 . The positive connection terminal 14 and the negative connection terminal 15 are not covered with the cover 70 . A plurality of battery cells 11 are positioned between the positive electrode connection terminal 14 and the negative electrode connection terminal 15 .

As shown in FIG. 1 , the positive electrode connection terminal 14 of one of the two battery modules 100 arranged side by side in the x direction and the negative electrode connection terminal 15 of the other are electrically connected via a wire harness 101 . be done. In order to shorten the wiring length of the wire harness 101 as much as possible, the positive connection terminal 14 provided on one of the two battery modules 100 arranged adjacent to each other in the x direction and the negative connection terminal 15 provided on the other are arranged in the x direction. is placed in In order to realize such an arrangement, the arrangement positions of the two battery modules 100 that are adjacent to each other in the x direction are reversed by 180° in the circumferential direction around the z direction.

<Case>
As described above, case 30 has housing 31 and lid 32 . The housing 31 and the lid 32 are each manufactured by resin molding or the like.

The housing 31 has a box shape that is open in the z direction and has a bottom. The housing 31 has a bottom wall 34 with a thin thickness in the z direction, and an annular wall 35 annularly rising from the edge of the inner bottom surface 34a of the bottom wall 34 along the z direction. An opening of the housing 31 is configured by the tip side of the annular wall 35 .

Specifically, the annular wall 35 has first and second end walls 35a and 35b spaced apart in the y direction and first and second side walls 35c and 35d spaced apart in the x direction. have. The first end wall 35a, the first side wall 35c, the second end wall 35b, and the second side wall 35d are annularly connected in order in the circumferential direction around the z-direction.

A plurality of slits 36 are formed in each of the first side wall 35c and the second side wall 35d and open to an inner side surface 35e on the storage space side and an outer side surface 35f on the back side thereof. The slits 36 formed in the first side wall 35c and the slits 36 formed in the second side wall 35d are arranged in the x direction. Three or more slits 36 are arranged in the y direction at predetermined intervals on each of the first side wall 35c and the second side wall 35d.

<Intervening wall>
The housing 31 has a plurality of intervening walls 37 in addition to the bottom wall 34 and the annular wall 35 described above. Each of the plurality of intervening walls 37 rises from the inner bottom surface 34a of the bottom wall 34 in the z direction. Each of the intervening walls 37 extends in the x-direction and is connected to the inner side surface 35e of each of the first side wall 35c and the second side wall 35d. A plurality of intervening walls 37 are arranged in the y direction at predetermined intervals.

With the above-described configuration of the housing 31, the space on the inner bottom surface 34a side of the storage space is defined between the first end wall 35a and the intervening wall 37, between two intervening walls 37 that are adjacent in the y direction, And it is divided between the intervening wall 37 and the second end wall 35b. The lower surface 11b side of the battery cell 11 is provided in the plurality of partitioned layout spaces.

As shown in FIG. 2, the connection position of the intervening wall 37 with the inner side surface 35e of the first side wall 35c is closer to the bottom wall 34 than the position where the slit 36 is formed in the first side wall 35c. The connection position of the intervening wall 37 with the inner side surface 35e of the second side wall 35d is closer to the bottom wall 34 than the position of the slit 36 in the second side wall 35d. The intervening wall 37 is located between the slit 36 formed in the first side wall 35c and the slit 36 formed in the second side wall 35d in the x direction.

<Protrusion>
Each of the two intervening surfaces 37a of the intervening wall 37 facing in the y direction is formed with a minute protrusion that locally protrudes in the y direction. The inner end surfaces 35g of the first end wall 35a and the second end wall 35b on the storage space side are also formed with minute protrusions that locally protrude in the y direction. The inner side surfaces 35e of the first side wall 35c and the second side wall 35d are formed with minute protrusions that locally protrude in the x direction.

The battery cell 11 is press-fitted into the arrangement space in such a manner that the lower surface 11b of the battery cell 11 approaches the inner bottom surface 34a. As a result of this press-fitting, the projections formed on the intervening walls 37 and the end walls are brought into contact with the lower surfaces 11b of the battery cells 11 on the sides of the lower surfaces 11c and 11d of the battery cells 11, and these projections move in the z-direction and the y-direction. It deforms in a way that it shrinks. Similarly, the projections of the side walls come into contact with the lower surfaces 11b of the first horizontal surface 11e and the second horizontal surface 11f of the battery cell 11, and the projections are deformed so as to contract in the z direction and the x direction.

Due to this deformation, the intermediate wall 37 and the protrusions of the end walls generate restoring forces in the z-direction and the y-direction. The sidewall protrusions generate restoring forces in the z and x directions. The position of the battery cell 11 in the storage space is held by the restoring force of these protrusions. The arrangement state of the plurality of battery cells 11 in the y direction is maintained.

The lower surface 11b of the battery cell 11 and the inner bottom surface 34a of the bottom wall 34 are separated from each other in the z direction while the position of the battery cell 11 in the storage space is maintained. The bottom wall 34 is formed with a through hole opening to an inner bottom surface 34a and an outer bottom surface on the back side thereof. The through holes function to discharge conductive liquid (conductive water) such as water containing impurities to the outside of the storage space.

In addition, in a state in which the position of the battery cell 11 in the storage space is maintained, the first main surface 11c and the second main surface 11d of the battery cell 11 each correspond to the projection-free region of the intervening surface 37a of the intervening wall 37. They are spaced apart in the y-direction. Therefore, two battery cells 11 adjacent to each other in the y-direction are spaced apart in the y-direction by the length of one intervening wall 37 and the length of each of the two protrusions in the y-direction.

<Distribution channel>
In a state in which the position of the battery cell 11 in the storage space is maintained, the upper surface 11a side of the battery cell 11 is more distant from the inner bottom surface 34a in the z-direction than the upper end surface of the intervening wall 37 on the opening side of the case 30. . Therefore, the main surfaces of the two battery cells 11 adjacent to each other in the y-direction are separated from each other so that the main surfaces on the upper surface 11a side directly face each other in the y-direction. A gap is formed between the main surfaces of these two battery cells 11 .

The gap between the main surfaces of the two battery cells 11 adjacent to each other in the y direction is the gap between the slit 36 formed in the first side wall 35c and the slit 36 formed in the second side wall 35d in the x direction. located in between. The slit 36 formed in the first side wall 35c and the slit 36 formed in the second side wall 35d are separated in the x direction through the gap between the main surfaces of the two battery cells 11 adjacent to each other in the y direction. Lined up. These two slits 36 and one gap form a flow path for the fluid to pass through the storage space.

Due to the arrangement of the two slits 36 and one gap in the x direction as described above, when the fluid supplied from the duct 300 flows into the storage space through the slit 36 formed in the first side wall 35c, the fluid It passes through the gap between the main surfaces of the two battery cells 11 . The fluid that has passed through this gap flows out of the storage space through a slit 36 formed in the second side wall 35d. Thereby, each of the plurality of battery cells 11 is heat-exchanged with the fluid. The heat exchange between the fluid and the battery cell increases as the flow rate of the fluid flowing through the gap increases.

<Mouth>
As shown in FIGS. 4 and 5, the housing 31 has a mouth portion 38 in addition to the bottom wall 34, the annular wall 35, and the plurality of intervening walls 37 described so far. The opening 38 is for attaching and fixing the duct 300 to the battery module 100 .

The mouth portion 38 is formed on the outer side surface 35f of the first side wall 35c. The mouth portion 38 is annularly erected in the x-direction from the outer surface 35f in a manner separated from the storage space of the case 30. As shown in FIG. The mouth portion 38 surrounds the openings of all the slits 36 formed in the first side wall 35c on the side of the outer surface 35f.

Specifically, the mouth portion 38 has a first extension 38a and a second extension 38b spaced apart in the y direction and a third extension 38c and a fourth extension 38c spaced apart in the z direction. 38d.

The first extension portion 38a stands up in the x-direction and extends in the z-direction on the first end wall 35a side of the outer surface 35f of the first side wall 35c. The second extension 38b stands up in the x-direction and extends in the z-direction on the second end wall 35b side of the outer surface 35f of the first side wall 35c. All the openings of the slits 36 formed in the first side wall 35c on the side of the outer surface 35f are located between the first extension portion 38a and the second extension portion 38b.

The third extension portion 38c stands up in the x direction and extends in the y direction on the opening side of the housing 31 on the outer side surface 35f of the first side wall 35c. The fourth extension 38d stands up in the x-direction and extends in the y-direction on the bottom wall 34 side of the outer surface 35f of the first side wall 35c. All the openings of the slits 36 formed in the first side wall 35c on the side of the outer surface 35f are located between the third extension 38c and the fourth extension 38d. The third extension 38c corresponds to the upper extension. The fourth extension 38d corresponds to the lower extension.

These four extensions are annularly connected in the circumferential direction around the x-direction. That is, the first extension portion 38a, the third extension portion 38c, the second extension portion 38b, and the fourth extension portion 38d are annularly connected in order in the circumferential direction around the x direction. Thus, openings of all the slits 36 formed in the first side wall 35c on the side of the outer surface 35f are surrounded by the openings 38. As shown in FIG. The duct 300 is attached and fixed to the mouth portion 38 in such a manner that the opening of the mouth portion 38 and the supply passage of the duct 300 communicate with each other.

<Fluid flow direction>
As described above, the arrangement positions of the two battery modules 100 adjacent to each other in the x direction are reversed by 180° in the circumferential direction around the z direction. Therefore, as shown in FIG. 1, one first side wall 35c and the other side wall 35c of the two battery modules 100 adjacent to each other in the x-direction are spaced apart from each other so as to face each other in the x-direction. The openings 38 of two battery modules 100 that are adjacent to each other in the x direction are arranged in a spaced manner so as to face each other in the x direction. A duct 300 is attached and fixed to each of the two mouths 38 so that the openings of these two mouths 38 and the supply passage communicate with each other.

The flow direction of the fluid supplied from this duct 300 is along the y-direction. Again, the arrangement positions of the two battery modules 100 adjacent to each other in the x direction are reversed by 180° in the circumferential direction around the z direction. Therefore, the fluid supplied from the duct 300 flows from the first end wall 35a to the second end wall 35b on the outer surface 35f of the first side wall 35c of one of the two battery modules 100 that are arranged side by side in the x direction. flow to the side. The fluid supplied from the duct 300 flows from the second end wall 35b side to the first end wall 35a side on the outer surface 35f of the other first side wall 35c of the two battery modules 100 that are arranged side by side in the x direction. and flows towards

The fluid flowing along the y-direction along the outer surface 35f flows from one of the first end wall 35a and the second end wall 35b to the other, and then flows through the first end wall 35a and the second end wall 35b. It shows the behavior of sequentially flowing into the slit 36 located on one side from the other side.

For this reason, for example, as shown by the thickness of the arrow in FIG. The behavior of flowing into the slit 36 on the side of the first end wall 35a in order from the side of the second end wall 35b is shown. The fluid preferentially flows into the slits 36 on the second end wall 35b side and subordinately flows into the slits 36 on the first end wall 35a side. A large amount of fluid flows into the slit 36 on the side of the second end wall 35b, and a small amount of fluid flows into the slit 36 on the side of the first end wall 35a.

Due to the difference in the amount of fluid flowing into each of the plurality of slits 36 described above, the battery cells 11 located on the second end wall 35b side are more sensitive to fluid than the battery cells 11 located on the first end wall 35a side. heat exchange (cooling) with Conversely, the battery cells 11 located on the first end wall 35a side are more difficult to be cooled by the fluid than the battery cells 11 located on the second end wall 35b side. In this way, there is a possibility that the cooling effect of the fluid in each of the plurality of battery cells 11 may vary.

In order to solve such a problem, a blocking member 90 that blocks the flow of the fluid supplied from the duct 300 to the outer surface 35f from one of the first end wall 35a and the second end wall 35b to the other is provided in the second end wall 35a. It is provided on the outer surface 35f of the side wall 35c. Strictly speaking, as shown in FIG. 5, the blocking member 90 is provided with the slit 36 positioned closest to the first end wall 35a among the plurality of slits 36 on the outer surface 35f of the first side wall 35c and the slit 36 closest to the second end. It is provided in the arrangement area AR between the slit 36 located on the wall 35b side.

The blocking member 90 extends from the third extension 38c toward the fourth extension 38d. The blocking member 90 is located between the two slits 36 in the y-direction. The blocking member 90 faces the outer surface 35f of the first side wall 35c in the x direction. The blocking member 90 is not opposed to the slit 36 of the first side wall 35c in the x direction.

In this embodiment, one blocking member 90 is formed on the third extension 38c. This one blocking member 90 is positioned between two slits 36 of the plurality of slits 36 that are positioned closest to the first end wall 35a.

<Effect>
With the above-described configuration, when fluid is supplied from the duct 300 from the side of the first end wall 35a to the side of the second end wall 35b as shown in FIG. The blocking member 90 blocks the flow toward the second end wall 35b. As a result, the flow rate of the fluid flowing into the slit 36 on the side of the second end wall 35b is easily reduced. The flow rate of the fluid flowing into the slit 36 on the side of the first end wall 35a is likely to increase due to the reduction.

Further, for example, as shown in FIG. 8, when the fluid flowing from the second end wall 35b side to the first end wall 35a side is supplied from the duct 300, the fluid flows from the second end wall 35b side to the first end wall 35a side. Sideways flow is blocked by blocking member 90 . As a result, the flow rate of the fluid flowing into the slit 36 on the side of the first end wall 35a is easily reduced. The flow rate of the fluid flowing into the slit 36 on the side of the second end wall 35b is likely to increase due to the reduction.

As described above, an increase in the difference in the flow rate of the fluid flowing into each of the plurality of gaps through each of the plurality of slits 36 is suppressed. This suppresses variation in the cooling effect of the fluid in each of the plurality of battery cells 11 .

The blocking member 90 is not opposed to the slit 36 in the x direction. According to this, it is suppressed that the obstruction member 90 obstructs the communication between the opening of the slit 36 on the side of the outer surface 35f and the supply passage of the duct 300 . Therefore, the blocking member 90 prevents the fluid from flowing into the slit 36 .

(Second embodiment)
Next, a second embodiment will be described with reference to FIGS. 9 to 11. FIG. Battery modules according to the following embodiments and modifications have many points in common with those according to the above-described embodiments. Therefore, the description of the common parts will be omitted, and the different parts will be mainly described below. Also, hereinafter, the same reference numerals are given to the same elements as those shown in the above-described embodiment.

In the first embodiment, one blocking member 90 is formed on the third extension 38c. In contrast, in this embodiment, two blocking members 90 are formed on the third extension 38c. Hereinafter, one of the two obstruction members 90 will be referred to as a first obstruction member 91 and the other will be referred to as a second obstruction member 92 for simplicity of description. The same applies to the drawings.

As shown in FIG. 9, the first obstructing member 91 is located between two slits 36 arranged in order in the y direction on the side of the first end wall 35a in the arrangement area AR. In this embodiment, the first blocking member 91 is positioned between two slits 36 of the plurality of slits 36 that are positioned closest to the first end wall 35a.

The second obstructing member 92 is positioned between two slits 36 arranged in order in the y direction on the second end wall 35b side in the arrangement area AR. In this embodiment, the second blocking member 92 is positioned between two slits 36 of the plurality of slits 36 that are positioned closest to the second end wall 35b.

According to this, even if the flow direction of the fluid supplied from the duct 300 to each of the plurality of battery modules 100 is reversed in the y direction as shown in FIG. It is suppressed that the difference in the effect of That is, the effect of suppressing an increase in the difference in the flow rate of the fluid flowing into each of the plurality of gaps through each of the plurality of slits 36 by the obstructing member 90 may differ among the plurality of battery modules 100 . Suppressed. Variation in the cooling effect of the fluid in each of the plurality of battery cells 11 is suppressed.

In particular, in the present embodiment, the plurality of slits 36 are arranged symmetrically in the y-direction with respect to the center line CL passing through the center of the arrangement area AR in the y-direction in the x-direction. At the same time, the first obstructing member 91 and the second obstructing member 92 are arranged symmetrically in the y direction with respect to the center line CL. Therefore, the effect of suppressing variation in the cooling effect of the fluid in each of the plurality of battery cells 11 is more effectively suppressed from being different among the plurality of battery modules 100 .

Further, as described above, the first obstructing member 91 is located between the two slits 36 arranged in order in the y direction on the side of the first end wall 35a in the arrangement area AR. The first blocking member 91 is located on the first end wall 35a side of these two slits 36 . The second obstructing member 92 is positioned between two slits 36 arranged in order in the y direction on the second end wall 35b side in the arrangement area AR. The second obstructing member 92 is located on the second end wall 35b side of these two slits 36 .

According to this, when fluid is supplied to the battery module 100 from the first end wall 35a side to the second end wall 35b side as shown in FIG. The fluid is more easily guided to the slit 36 on the first end wall 35a side of the two slits 36 . The first obstructing member 91 and the second obstructing member 92 make it difficult for the fluid to be guided to the slit 36 on the second end wall 35b side.

On the contrary, for example, when fluid is supplied to the battery module 100 from the second end wall 35b side to the first end wall 35a side as shown in FIG. The fluid is easily guided to the slit 36 on the second end wall 35b side of the two slits 36 arranged side by side. The first obstructing member 91 and the second obstructing member 92 make it difficult for the fluid to be guided to the slit 36 on the second end wall 35b side.

As a result, an increase in the difference in the flow rate of the fluid flowing into each of the plurality of gaps through each of the plurality of slits 36 is more effectively suppressed. Variation in the cooling effect of the fluid in each of the plurality of battery cells 11 is more effectively suppressed.

Note that the battery module 100 according to the present embodiment includes components equivalent to those of the battery module 100 described in the first embodiment. Therefore, it goes without saying that the same effect can be obtained.

(Third Embodiment)
Next, a third embodiment will be described with reference to FIGS. 12 and 13. FIG.

In the second embodiment, one first obstruction member 91 and one second obstruction member 92 are formed in the third extension portion 38c. On the other hand, in this embodiment, as shown in FIG. 12, a plurality of first blocking members 91 and a plurality of second blocking members 92 are formed on the third extension portion 38c.

As shown in FIG. 13, the x-direction length of each of the plurality of first obstructing members 91 gradually decreases from the first end wall 35a side toward the center line CL side in the y-direction. The length in the x direction of each of the plurality of second obstructing members 92 gradually decreases from the second end wall 35b side toward the center line CL side in the y direction.

According to this, the plurality of first obstructing members 91 suppress the occurrence of a difference in the amount of fluid flowing into each of the plurality of slits 36 positioned on the first end wall 35a side of the arrangement area AR. The plurality of second obstruction members 92 suppress the occurrence of differences in the amount of fluid flowing into each of the plurality of slits 36 positioned on the second end wall 35b side of the arrangement area AR. As a result, the occurrence of differences in the amount of fluid flowing into each of the slits 36 is suppressed.

Note that the battery module 100 according to the present embodiment includes components equivalent to those of the battery module 100 described in the second embodiment. Therefore, it goes without saying that the same effect can be obtained.

Although the preferred embodiments of the present disclosure have been described above, the present disclosure is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the present disclosure. is.

(First modification)
Each embodiment did not specifically refer to the form of connection between the housing 31 and the lid 32 . As a form of connection between the housing 31 and the lid body 32, for example, bolting can be adopted. FIG. 14 shows a side view of the battery module 100 when the housing 31 and the lid 32 are bolted.

As shown in FIG. 14, in this modification, four blocking members 90 are formed on the third extension portion 38c. Each of these four blocking members 90 has a hole opening toward the lid 32 side. A screw hole for bolting is formed in this hole. A through hole communicating with the opening of the hole of the blocking member 90 is formed in the cover 32 . A bolt is tightened from this through hole toward the hole of the blocking member 90 . As a result, the housing 31 and the lid 32 are bolted together.

As for the connection between the housing 31 and the lid 32, for example, fitting may be employed. In this case, each blocking member 90 has a hole that opens toward the lid 32 side. The cover 32 is formed with a protruding portion that protrudes toward the opening of the hole of the obstructing member 90 . This protrusion is press-fitted into the hole of the blocking member 90 . As a result, the housing 31 and the lid 32 are fitted together.

As described above, the obstruction member 90 may have a function related to connection between the housing 31 and the lid 32 . The bolt and protrusion correspond to the fixing member.

(Second modification)
Each embodiment has shown an example in which the blocking member 90 is formed in the third extension portion 38c. However, the formation position of the blocking member 90 is not limited to the above example. For example, it may be formed on the outer surface 35f of the first side wall 35c or the fourth extension 38d. The obstructing member 90 can also adopt a form extending from the fourth extension portion 38d toward the third extension portion 38c.

(Third modification)
Each embodiment did not specifically refer to the length of the obstructing member 90 in the z direction. The length of the obstructing member 90 in the z direction may be longer than, the same as, or shorter than the length of the slit 36 in the z direction.

(Fourth modification)
Each embodiment has shown an example in which the opening 38 is formed on the outer side surface 35f of the first side wall 35c. However, it is also possible to employ a structure in which the mouth portion 38 is formed on the outer side surface 35f of the second side wall 35d. The blocking member 90 may be provided on the outer side surface 35f where the opening 38 is formed.

DESCRIPTION OF SYMBOLS 10... Battery stack, 11... Battery cell, 30... Case, 31... Case, 32... Lid body, 34... Bottom wall, 34a... Inner bottom surface, 35... Annular wall, 35a... First end wall, 35b... Second End wall 35c First side wall 35d Second side wall 35e Inner side 35f Outer side 36 Slit 38 Mouth 38c Third extension 38d Fourth extension 90 Blocking member 91 First blocking member 92 Second blocking member 100 Battery module 300 Duct AR Arrangement area CL Center line

Claims (8)

a battery stack (10) comprising four or more battery cells (11) arranged in order with gaps in the arrangement direction;
a case (30) for storing four or more battery cells in a storage space;
The case includes a housing (31) having an opening, and a lid body (32) that forms the storage space together with the housing by being connected to the housing in such a manner as to close the opening of the housing. , has
The housing has a bottom wall (34) and an annular wall (35) standing annularly from an inner bottom surface (34a) of the bottom wall,
The annular wall includes a first end wall (35a) and a second end wall (35b) spaced apart in the alignment direction, and a first side wall (35c) connecting the first end wall and the second end wall. ) and a second side wall (35d),
Slits (36) are provided in each of the first side wall and the second side wall and open to the inner side surface (35e) of the first side wall and the second side wall on the side of the storage space and the outer side surface (35f) of the back side thereof. ) are formed three or more times,
the slit formed in the first side wall and the slit formed in the second side wall are arranged in the horizontal direction in which the first end wall and the second end wall are arranged with the gap therebetween;
the slit closest to the first end wall among the three or more slits in at least one of the outer surfaces of the first side wall and the second side wall, and the three or more slits the first end wall and the second end wall of the fluid supplied from the duct (300) to the outer surface in the arrangement area (AR) between the slit located closest to the second end wall of the A battery module provided with obstructing members (90-92) that obstruct flow from one of them to the other. 2. The battery module according to claim 1, wherein said blocking member is not opposed to said slit in said lateral direction. 3. The battery module according to claim 2, wherein the blocking member is provided on each of the first end wall side and the second end wall side of the arrangement area. The blocking member provided on the first end wall side in the placement area is a first blocking member (91), and the blocking member provided on the second end wall side in the placement area is a second blocking member (92). ), then
The first blocking member is positioned on the first end wall side between the two slits arranged in order in the arranging direction and positioned on the first end wall side in the arrangement area in the arranging direction,
The second obstructing member is positioned on the second end wall side of the arrangement area in the arranging direction and is positioned on the second end wall side between the two slits arranged in order in the arranging direction. The battery module according to claim 3. The blocking member provided on the first end wall side in the placement area is a first blocking member (91), and the blocking member provided on the second end wall side in the placement area is a second blocking member (92). ), then
Each of the plurality of slits is arranged symmetrically in the arrangement direction via a center line (CL) passing through the center of the arrangement region in the arrangement direction in the horizontal direction, and the first obstruction member and the second obstruction 5. The battery module according to claim 3, wherein the members are arranged symmetrically in the arranging direction. Having a plurality of each of the first hindrance member and the second hindrance member,
the horizontal length of each of the plurality of first obstructing members gradually decreases from the first end wall side toward the center line side in the row direction;
6. The battery according to claim 5, wherein the lateral length of each of the plurality of second obstructing members gradually decreases from the second end wall side toward the center line side in the row direction. module. said housing having, in addition to said bottom wall and said annular wall, a mouth (38) for fixing said duct to at least one of said first side wall and said second side wall;
The mouth portion is an upper extension portion (38c) that stands up in the lateral direction from the opening side of the housing on the outer surface of at least one of the first side wall and the second side wall and extends in the row direction. and a lower extension (38d) standing in the lateral direction from the bottom wall side of the outer surface of at least one of the first side wall and the second side wall and extending in the row direction. ,
The battery module according to any one of claims 1 to 6, wherein the blocking member extends from one of the upper extension portion and the lower extension portion toward the other. The blocking member extends from the upper extension toward the lower extension and has a hole opening toward the lid,
8. The battery module according to claim 7, wherein the hole is provided with a fixing member for fixing to the lid.

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