JP7498076B2 - Vehicle battery protection mechanism - Google Patents

Description

The present invention relates to a vehicle equipped with a battery pack having multiple battery modules, and more specifically to a protection mechanism for the battery pack installed in the vehicle.

In recent years, there has been remarkable progress in hybridization and electrification of vehicles such as automobiles. In such electric vehicles, a battery module made up of multiple battery cells is installed to drive the motor.

In recent years, there has been a demand for longer driving distances, and in addition to increasing the capacity of battery cells as individual units, vehicles are being equipped with battery packs that include a large number of the above-mentioned battery modules. Therefore, in order to further improve safety, a battery circuit breaker device has been proposed that prevents secondary damage to the battery pack when the vehicle is in an emergency state (see Patent Documents 1 to 3).

JP 2004-7919 A JP 2007-259653 A JP 2012-506105 A

Not only the above-mentioned patent documents, but current technologies do not adequately meet market needs, and the following problems exist.
That is, while the conventional techniques including those described in the above Patent Documents 1 to 3 can certainly shut off the output from the battery in an emergency, they all only shut off the power supply to the battery pack.

However, as mentioned above, batteries have become increasingly high-capacity and high-output in recent years, and it is expected that in the future it will be necessary to devise ways to properly manage the energy state in emergencies, including battery placement.

The present invention was made in consideration of the above-mentioned problems, and aims to provide an in-vehicle battery protection mechanism that improves vehicle safety by controlling the arrangement state inside the battery pack in an emergency.

In order to solve the above problems, an on-board battery protection mechanism for a vehicle in one embodiment of the present invention is provided with: (1) an impact force conversion means for converting an impact force along the traveling direction generated when the vehicle is subjected to an impact into a force directed in a lateral direction intersecting the traveling direction, and separating at least some of the battery modules in a battery pack mounted on the vehicle by the force directed in the lateral direction , wherein the impact force conversion means includes: a front support member disposed at the front of the vehicle to receive the impact force; a relay member having one end connected to the front support member and extending to a rear of the vehicle; and a lateral rotating member having a curved portion curved from the traveling direction to the lateral direction, connected to the other end of the relay member, at least a portion of which rotates toward the lateral direction via the relay member pushed out by the impact force, and wherein at least a portion of the lateral rotating member is disposed inside the battery pack .

In addition, in the vehicle battery protection mechanism described in (1) above, (2) it is preferable that the impact force conversion means moves a first battery group consisting of at least a portion of the battery modules to one side in the lateral direction, and moves a second battery group consisting of the remaining battery modules to the opposite side to the one side in the lateral direction.

In addition, in the vehicle battery protection mechanism described in (2) above, (3) it is preferable that the first battery group and the second battery group are each composed of the same number of battery modules.

In addition, in the vehicle battery protection mechanism described in (1) above, (4) it is preferable that the lateral pivot member is disposed in the center of the battery pack and separates the battery modules so as to divide the battery pack in two.

The present invention can further improve vehicle safety by controlling the layout of the battery pack in an emergency.

1 is a schematic side view of a vehicle equipped with a battery protection mechanism according to an embodiment; 1 is a schematic diagram of a vehicle equipped with a battery protection mechanism according to an embodiment, viewed from the front. 1 is a schematic diagram of a vehicle equipped with a battery protection mechanism according to an embodiment, viewed from above. 4 is a schematic side view of the battery protection mechanism. FIG. FIG. 11 is a state transition diagram (part 1) illustrating the arrangement control of the battery modules in the battery pack during a frontal collision. FIG. 13 is a state transition diagram (part 2) illustrating the arrangement control of the battery modules in the battery pack during a frontal collision. 1 is a schematic diagram of a vehicle equipped with a battery protection mechanism of a first modified example, viewed from above. 11 is a schematic diagram of a vehicle equipped with a battery protection mechanism of a second modified example, viewed from above. FIG.

Next, a preferred embodiment for carrying out the present invention will be described. In the following description, for convenience, the vehicle height direction of the vehicle is defined as the Z direction, the vehicle length direction as the X direction, and the vehicle width direction perpendicular to the Z direction and the X direction as the Y direction. However, the present invention is not dependent on the above-mentioned directional definitions, and it goes without saying that the scope of the claims is not unduly restricted. Furthermore, configurations other than those described in detail below may be appropriately supplemented with publicly known component technologies related to vehicles, including the patent documents mentioned above, and the structure or circuit configuration of the battery pack.

[On-vehicle battery protection mechanism 100]
First, the configuration of an on-board battery protection mechanism 100 mounted on a vehicle according to the embodiment will be described with reference to Figures 1 to 4. Note that examples of vehicles suitable for this embodiment include various well-known electric vehicles equipped with secondary batteries such as lithium ion batteries and fuel cells.

As shown in the figure, the vehicle-mounted battery protection mechanism 100 of this embodiment is mounted on the vehicle body 1 and includes an impact force conversion means 10. This impact force conversion means 10 has a function of converting an impact force along the traveling direction (X direction) that occurs when the vehicle receives an impact, for example, by colliding with an obstacle in front of the vehicle, into a force in a lateral direction (Y direction in this embodiment) that intersects with the traveling direction. In addition, as described below, the impact force conversion means 10 has a function of separating at least some of the battery modules in the battery pack mounted on the vehicle by the force in the lateral direction.

More specifically, the impact force converter 10 of this embodiment includes a front support member 11, a relay member 12, a side pivot member 13, a base end support portion 14, and the like.
The front support member 11 is made of, for example, a known metal material or resin material, and is disposed at the front of the vehicle to receive the above-mentioned impact force. The "front of the vehicle" is not particularly limited as long as it is a position that can receive the above-mentioned impact force toward the rear of the vehicle generated during a collision. In this embodiment, the front support member 11 is disposed forward of the bulkhead 2 on the vehicle body 1 as an example of the front of the vehicle.

More specifically, as shown in Figures 1 to 4, the front support member 11 includes a first front support member 11a having a surface that receives the above-mentioned impact force, and a second front support member 11b that connects and fixes the first front support member 11a to the vehicle body 1.

As is clear from Figures 2 and 3, the front support member 11 of this embodiment is positioned approximately in the center of the vehicle in the vehicle width direction. This not only allows the impact force described above to be received efficiently, but also makes it possible to install relay member 12 (described later) between the driver's seat and the passenger seat, improving space efficiency.

The relay member 12 is made of a known metal material, such as high-strength steel, and has the function of transmitting the impact force received by the front support member 11 to the lateral pivot member 13 described below. As shown in Figures 3 and 4, the relay member 12 in this embodiment is disposed so that one end (the front side of the vehicle) is connected to the front support member 11 and extends to the rear of the vehicle. The other end (the rear side of the vehicle) of the relay member 12 is connected to the tip of the lateral pivot member 13.

As shown in FIG. 3, the relay member 12 of this embodiment is composed of a pair of metal bars, and has a first relay member 12a and a second relay member 12b, each of which is connected to the first front support member 11a. It is preferable that the first relay member 12a and the second relay member 12b are arranged non-parallel to each other in the vehicle length direction so that the distance between them increases slightly from the front side to the rear side of the vehicle. In addition, as shown in FIG. 2, since the relay member 12 is arranged between the driver's seat and the passenger seat, it is preferable that it is located below the center console box 3.

The connection between the first front support member 11a and the pair of relay members 12 is not particularly limited, and any known connection structure can be applied. More preferably, one end of the relay member 12 is axially supported by the front support member 11 so that, for example, one end of the relay member 12 serves as a fulcrum and the other end can move (pivot) laterally.

The lateral pivoting member 13 has a curved portion that is curved from the vehicle's traveling direction (X) to the side direction (Y direction), and has the function of pivoting at least a portion of it to the side via the relay member 12 that is pushed toward the rear of the vehicle by the impact force generated during the above-mentioned frontal collision.

More specifically, as shown in FIG. 3 and other figures, the side pivot member 13 of this embodiment has a tip (front side of the vehicle) connected to the other end of the relay member 12, and a rear end (rear side of the vehicle) connected to the base end support part 14. Furthermore, this side pivot member 13 has a curved portion that bends halfway between the tip and rear end so that the tip is located more to the side (in the direction of the vehicle width) than the rear end. Note that there are no particular limitations on the method of forming the curved portion in this embodiment, and any known molding method can be applied. For example, it may be a gently rounded shape, or it may have a curvature close to 90° to form a corner.

As shown in FIG. 3, the lateral pivot member 13 in this embodiment is, for example, made of a pair of metal rods, and has a pair of first lateral pivot members 13a and second lateral pivot members 13b, each of which is connected to the relay member 12. It is preferable that the first lateral pivot member 13a and the second lateral pivot member 13b are arranged so that their respective tips are spaced apart from each other toward the side (Y direction).

As shown in the figure, in this embodiment, it is preferable that the relay member 12 and the side rotating member 13 are connected via a bearing 15 so that they can move in the lateral direction (Y direction) with their connection point as a fulcrum. This allows the relay member 12 and the side rotating member 13 to move in the lateral direction with the bearing 15 as a base point, making it possible to suppress deformation at unintended locations when receiving the above-mentioned impact force. More specifically, in this embodiment, the first relay member 12a and the first side rotating member 13a are connected via a first bearing 15a, and the second relay member 12b and the second side rotating member 13b are connected via a second bearing 15b.

On the other hand, because the rear end of the lateral pivot member 13 is fixed to the base end support portion 14 as described above, it is prevented from unintentionally moving in the lateral direction (Y direction) when the above-mentioned impact force is received. In other words, this base end support portion 14 allows the rear end of the lateral pivot member 13 to act as a fulcrum and the tip to move in the lateral direction when the above-mentioned impact force is received.

As is clear from FIG. 3 and other figures, the base end support portion 14 of this embodiment may be disposed within the battery pack holding means 30 that holds the battery pack. More specifically, in this embodiment, the base end support portion 14 may be installed on the rear side of the vehicle within the battery pack holding means 30. As a result, as shown in the same figure and other figures, at least a portion of the lateral pivot member 13 described above is disposed inside the battery pack.

As shown in FIG. 4 and other figures, the vehicle-mounted battery protection mechanism 100 in this embodiment may further include a support member 16 that supports at least the relay member 12. The support member 16 is connected to the vehicle body 1 and stands with the vehicle body 1 as its base end, and has the function of supporting the relay member 12. In the figure, multiple support members 16 support the relay member 12, but there may be at least one, or at least some of the support members 16 may further support the lateral pivot member 13.

The battery pack holding means 30 is a container that holds the battery pack of this embodiment. Specific examples of such battery pack holding means 30 include known metal or resin storage containers that also take heat dissipation into consideration, such as the storage cases exemplified in JP 2019-175569 A. The known battery pack held by such battery pack holding means 30 includes a plurality of battery modules 21. The battery modules 21 are formed by electrically connecting battery cells, each of which has a positive electrode plate and a negative electrode plate alternately combined via a separator.
In this embodiment, a lithium ion secondary battery is suitable for the battery pack, but various known battery modules such as a fuel cell or a lead storage battery may also be used.

<Arrangement control of battery modules 21 in battery pack>
Next, the arrangement control of the battery modules 21 in the battery pack during a collision will be described with reference to FIGS.
As described above, the vehicle in this embodiment may collide with an obstacle ahead (also referred to as a forward collision) due to various unavoidable factors, etc. In the event of this forward collision, the front of the vehicle is first subjected to the impact force of the collision, but this embodiment is characterized in that a part of the impact force is used to change the arrangement of the battery modules 21 in the battery pack.

That is, as shown in Figure 5, when the above-mentioned impact force occurs at the front of the vehicle, the impact force IF is transmitted to a part (front support member 11) of the vehicle-mounted battery protection mechanism 100 that is connected to the vehicle body 1 (bulkhead 2 in this example). Then, as shown in the figure, the impact force IF transmitted to the front support member 11 is separated into a first impact force IFa and a second impact force IFb by the relay member 12 and transmitted.

At this time, since the vehicle-mounted battery protection mechanism 100 of this embodiment is equipped with the above-mentioned lateral pivoting member 13, the impact force IF along the traveling direction (first impact force IFa and second impact force IFb) is converted into a force directed in the lateral direction (first lateral force SFa and second lateral force SFb).

As shown in Figures 5 and 6, at least a portion of the lateral pivot member 13 is disposed inside the battery pack, and the movement (rotation) of this lateral pivot member 13 moves the first battery group C1, which is made up of at least a portion of the battery modules 21, to one side in the lateral direction, and moves the second battery group C2, which is made up of the remaining battery modules 21, to the opposite side in the lateral direction.

As can be seen from FIG. 6, in this embodiment, it is preferable that the first battery group C1 and the second battery group C2 are each composed of the same number of battery modules 21. In addition, it is preferable that the lateral pivot member 13 constituting the vehicle-mounted battery protection mechanism 100 is disposed in the center of the battery pack in the vehicle width direction (Y direction) and separates the multiple battery modules 21 so as to divide the battery pack in two.

This makes it possible to efficiently separate the originally generated impact force IF into multiple lateral forces SF, and move each battery group to the side. Note that in this embodiment, the battery groups are each made up of four battery modules 21, but it goes without saying that the battery groups may be made up of battery modules 21 other than four.

According to the vehicle battery protection mechanism of this embodiment described above, in an emergency such as a frontal collision, it is possible to separate some of the battery modules in the battery pack from each other by utilizing the impact force generated by the collision. By controlling the arrangement state inside the battery pack in this way in an emergency, this embodiment makes it possible to further improve the safety of the vehicle.

<Modification 1>
Next, an in-vehicle battery protection mechanism 100 according to a first modified example of the present invention will be described with reference to Fig. 7. In the above-described embodiment, the battery pack holding means 30 is provided at the end side in the vehicle width direction with a retraction space large enough for the battery module 21 to move (see Figs. 5 and 6).

In contrast, in this modified example 1, the battery pack holding means 30 does not have the above-mentioned evacuation space, and there is no gap on the side of the battery module 21 arranged at the end in the vehicle width direction. In addition to the above, in this modified example 1, a weakened portion 31 is provided in part of the side wall of the battery pack holding means 30 (in this example, the wall facing the battery module 21 arranged at the end).

Specific examples of such weakened portions 31 are not particularly limited and may be any known weakening mechanism, such as forming a crack along the vehicle height direction in part of the side wall, or constructing only the weakened portion 31 from a material that is relatively weaker than the surrounding area. As a result, during the state transition process shown in Figures 5 and 6, the battery module 21 pushed out to the side by the lateral pivot member 13 breaks the weakened portion 31, allowing the first battery group C1 and the second battery group C2 to smoothly move away from each other in the lateral direction.

<Modification 2>
Next, an in-vehicle battery protection mechanism 100 according to the second modified example of the present invention will be described with reference to Fig. 8. In the above-described embodiment, the first battery group C1 and the second battery group C2 are spaced apart laterally from each other by the multiple relay members 12 and the multiple lateral pivot members 13 (see Figs. 5 and 6).

In contrast to this, in the present modified example 2, a single relay member 12 and a single lateral pivot member 13 are used to separate one of the first battery group C1 and the second battery group C2 from the other. In other words, the present invention may include not only a configuration in which both the first battery group C1 and the second battery group C2 move sideways, but also a configuration in which at least one of the first battery group C1 and the second battery group C2 moves relative to the other to separate them.

8, it is preferable that the vehicle battery protection mechanism 100 in the second modification further includes a guide member 17 disposed between the front receiving member 11 and the base end support portion 14. That is, in the second modification, the guide member 17 is disposed adjacent to the bearing 15c, which is the connection point between the relay member 12c and the side pivot member 13c.

Therefore, by providing this guide member 17, it is possible to prevent the other end of the relay member 12c and the tip of the lateral pivot member 13c from moving in an unintended direction (the +Y direction in FIG. 8) when the impact force IF described above is converted into the lateral force SF.

The above-described modified examples 1 and 2 can also achieve the same effects as the above-described embodiment. Note that modified examples 1 and 2 may be combined and appropriately applied to the embodiment, for example, by applying both the weakened portion 31 and the guide member 17 to the embodiment.

The preferred embodiments and modifications of the present invention have been described in detail above with reference to the attached drawings, but the present invention is not limited to these examples. It is clear that a person with ordinary knowledge in the technical field to which the present invention pertains may attempt further modifications to these embodiments and modifications within the scope of the technical ideas described in the claims, and it is understood that these also naturally fall within the technical scope of the present invention.

10 Impact force conversion means 20 Battery pack 30 Battery pack holding means 100 Vehicle-mounted battery protection mechanism V Vehicle

Claims (4)

an impact force conversion means for converting an impact force along a traveling direction generated when a vehicle receives an impact into a force directed in a lateral direction intersecting the traveling direction, and separating at least some of the battery modules in a battery pack mounted on the vehicle by the force directed in the lateral direction ;
The impact force conversion means is
a front support member disposed at a front portion of the vehicle to receive the impact force;
a relay member having one end connected to the front support member and extending to a rear portion of the vehicle;
a lateral pivot member including a curved portion curved from the traveling direction to the lateral direction, the lateral pivot member being connected to the other end of the relay member and at least a portion of the lateral pivot member pivoting toward the lateral direction via the relay member pushed out by the impact force,
An on-vehicle battery protection mechanism , wherein at least a portion of the lateral pivot member is disposed inside the battery pack . The vehicle battery protection mechanism according to claim 1, wherein the impact force conversion means moves a first battery group consisting of at least a portion of the battery modules to one side in the lateral direction, and moves a second battery group consisting of the remaining battery modules to the opposite side to the one side in the lateral direction. The vehicle battery protection mechanism according to claim 2, wherein the first battery group and the second battery group are each composed of the same number of battery modules. The vehicle-mounted battery protection mechanism according to claim 1 , wherein the lateral pivot member is disposed at a center of the battery pack and separates the battery modules so as to divide the battery pack in two.