阅读说明：本技术 用于能量存储装置的包括变形区域的框架结构 (Frame structure for an energy storage device comprising a deformation region ) 是由 A·拉万塔布 F·奥沃加德 S·瓦拉纳西 S·斯特伦 K·阿蒙森 于 2020-10-23 设计创作，主要内容包括：本公开总体上涉及一种用于将车辆的能量存储装置维持就位的框架结构,其在侧面撞击的情况下以受控方式变形,以避免变形到车辆座椅的位置中。所提出的框架结构适于在与车辆座椅之间的位置对准的中心位置中可控地变形。以这种方式使车辆的乘员保持安全,因为在车辆座椅位置中没有发生或几乎不发生变形。上述优点由包括变形区域的框架横向支撑构件提供,该变形区域适于响应于被施加在横向支撑构件上的横向力而变形。变形区域定位成使得当框架结构安装在车辆中时,变形区域与车辆的座椅之间的位置对准。(The present disclosure generally relates to a frame structure for maintaining an energy storage device of a vehicle in place that deforms in a controlled manner in the event of a side impact to avoid deformation into position of a vehicle seat. The proposed frame structure is adapted to be controllably deformable in a central position aligned with a position between the vehicle seats. In this way, the occupant of the vehicle is kept safe, since no or hardly any deformation takes place in the vehicle seat position. The above advantages are provided by a frame cross support member that includes a deformation region adapted to deform in response to a lateral force applied to the cross support member. The deformation region is positioned such that when the frame structure is installed in a vehicle, the deformation region is aligned with a location between seats of the vehicle.)

1. A frame structure for maintaining an electrical energy storage device of a vehicle in place, the frame structure comprising:

a set of lateral support members adapted to be arranged along a lateral direction of the vehicle, the lateral support members defining at least one recess for the electrical energy storage device,

wherein at least one of the lateral support members includes a deformation region adapted to deform in response to a lateral force exerted on the lateral support member, the lateral support member being configured such that the deformation region is aligned with a position between seats of the vehicle when the frame structure is installed in the vehicle.

2. The frame structure according to claim 1, wherein the deformation region is configured to be telescopically deformed along a longitudinal axis of the lateral support member.

3. A frame structure according to any one of claims 1 and 2, wherein the deformation zone is located in a central portion of the lateral support member.

4. A frame structure according to any one of the preceding claims, wherein each of the lateral support members comprises a deformation region.

5. A frame structure according to any one of the preceding claims, wherein the lateral support members and the respective deformation regions are made in one piece.

6. A frame structure according to any one of the preceding claims, wherein the deformed region is structurally weaker than an adjacent portion of the lateral support member.

7. A frame structure according to any one of the preceding claims, wherein the deformation region comprises a hole in the lateral support member.

8. The frame structure of claim 7, wherein the deformation region comprises an array of holes in the lateral support member that extend around the entire perimeter of the lateral support member.

9. A frame structure according to any one of the preceding claims, wherein the transverse support member is adapted to pass from one side beam to the other side beam of the vehicle.

10. A frame structure according to any one of the preceding claims, wherein the transverse support members are connected at end portions thereof by longitudinal support members.

11. A frame structure according to any one of the preceding claims, wherein the lateral support members are made by extrusion.

12. A frame structure according to any one of the preceding claims, wherein the lateral support members are made of a material comprising aluminium.

13. A frame structure according to any one of the preceding claims, wherein the length of the deformation region along the respective transverse beam is shorter than the length of each transverse beam portion outside the deformation region.

14. A frame structure according to any one of the preceding claims, wherein the apertures are circular.

15. An energy storage module for a vehicle, comprising:

a frame structure according to any one of the preceding claims; and

a set of electrical energy storage devices disposed in the recess of the frame structure.

Technical Field

The present disclosure relates to a frame structure for holding an energy storage device of a vehicle in place. The present disclosure also relates to an energy storage module, and to a vehicle comprising an energy storage module.

Background

As the vehicle becomes electrified, the size of the battery increases. So-called traction batteries, which are used to provide propulsion for the vehicle, are therefore relatively large and heavy and must be supported by a strong mechanical structure in order to remain in place while the vehicle is running. The traction battery is typically arranged in a position under the floor of the vehicle, which inventively results in the traction battery often being arranged under a seat in the vehicle.

In order to protect the battery in the event of a collision, the structure around the traction battery must be able to handle large forces, especially in the event of a side impact, since the traction battery is usually located relatively close to the outer structure of the vehicle. The structure surrounding the battery is generally adapted to deform in a predetermined manner, so as to absorb energy from the impact and avoid that this energy is absorbed by the traction battery itself.

However, deformation of the structure may affect other parts of the vehicle in an undesirable manner and may even be dangerous for the occupants of the vehicle. Accordingly, there is a need for an improved way of protecting the traction battery of a vehicle in the event of a side impact vehicle.

Disclosure of Invention

The present disclosure generally relates to a frame structure for maintaining an energy storage device of a vehicle in place that deforms in a controlled manner in the event of a side impact. The frame structure deforms in a manner that avoids deformation into position of the vehicle seat.

The proposed frame structure is adapted to be controllably deformable in a central position aligned with a position between the vehicle seats. In this way, the occupant of the vehicle is kept safe, since no or hardly any deformation takes place in the vehicle seat position.

The above advantages are provided by the lateral support member of the frame structure comprising a deformation region, wherein the deformation region is adapted to deform in response to a lateral force exerted on the lateral support member. The deformation region is positioned such that when the frame structure is installed in a vehicle, the deformation region is aligned with a location between seats of the vehicle. Thus, the risk of deformation of the frame structure penetrating into a vehicle seat in which an occupant may be located is significantly reduced by the frame structure proposed herein, thereby better protecting the occupant.

The deformation region may be adjusted to deform at a predetermined force according to a particular load condition.

Furthermore, the lateral support members of the proposed frame structure are adapted to be arranged in the lateral direction of the vehicle, so as to be able to absorb energy from a side impact. The lateral support member defines at least one pocket for holding an energy storage device. In other words, the frame structure may be part of an energy storage module holding an energy storage device.

In one embodiment, the deformation region may be configured to telescopically deform along a longitudinal axis of the lateral support member. Thereby, the risk of deforming the lateral support member to penetrate a vehicle cabin vertically positioned from the lateral support member is further reduced.

Other features and advantages of the embodiments of the present disclosure will become apparent when studying the appended claims and the following description. Those skilled in the art realize that different features of the present disclosure can be combined to create embodiments other than those described in the following without departing from the scope of the present disclosure.

Drawings

These and other aspects of the present disclosure will now be described in more detail, with reference to the appended drawings showing exemplary embodiments of the invention, wherein:

FIG. 1 is a perspective view of a frame structure according to an embodiment of the present disclosure;

FIG. 2 conceptually illustrates an energy storage module including a frame structure disposed in a vehicle, in accordance with an embodiment of the present disclosure;

FIG. 3 conceptually illustrates an energy storage module including a frame structure disposed in a vehicle, in accordance with an embodiment of the present disclosure;

FIG. 4 conceptually illustrates a cross support member disposed between side sills, in accordance with an embodiment of the present disclosure; and

figure 5 conceptually illustrates a partial lateral support member, according to an embodiment of the present disclosure.

Detailed Description

In this detailed description, various embodiments of a frame structure according to the present invention are described. The framework of the present disclosure may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided for thoroughness and completeness, and fully convey the scope of the invention to those skilled in the art. Like reference numerals refer to like elements throughout.

Figure 1 conceptually illustrates a frame structure 100, in accordance with embodiments of the present disclosure. The frame structure 100 is configured to maintain an electrical energy storage device of the vehicle in place. The frame structure 100 includes a set of lateral support members 102 adapted to be arranged along a lateral direction of the vehicle. The lateral support member 102 defines at least one recess 104 for holding an electrical energy storage device (not shown). At least one of the lateral support members 102 includes a deformation region 106, the deformation region 106 adapted to deform in response to a lateral force 112 exerted on the lateral support member (e.g., a lateral force caused by an object 110 colliding laterally with the vehicle). The lateral support member 102 is configured such that when the frame structure 100 is installed in a vehicle, the deformation region 106 is aligned with a position between seats of the vehicle.

The inventors have realized that an electrical energy storage module comprising an electrical energy storage device and a support frame structure should be able to absorb crash energy in the event of a side impact without posing an unnecessary risk of injury to vehicle occupants. The inventors have therefore seen, based on the above recognition, that a deformation region is provided for a lateral support member of a frame structure housing an electrical energy storage device. The deformation zone is adapted to deform in the event of a collision, transferring energy into the lateral support member along a major longitudinal axis of the lateral support member. When the deformation zones deform, they absorb the impact energy. Furthermore, due to the specific configuration and location of the deformation zones, the deformation occurs in a controlled manner. In particular, the inventors have realized that in order to reduce the risk of injury to the vehicle occupants, the deformation region should be aligned with a position between the seats of the vehicle.

By way of example only, fig. 1 conceptually illustrates a frame structure 100 having four lateral support members 102. Adjacent lateral support members define a recess 104 in which an electrical energy storage device may be disposed and maintained in position. One such electrical energy storage device may include a plurality of cells, for example, a plurality of battery cells.

The lateral support members 102 are here shown connected at their end portions by longitudinal support members 114. The frame structure 100 may be attached to body structures 116a-b, and the body structures 116a-b may be side rocker beams (side rocker beams) or floor support beams, sometimes also referred to as rocker beams (side beams). Thus, the cross support member 102 may be adapted to pass from one side sill 116a to the other side sill 116b of the vehicle.

By way of example only, the lateral support members 102 may be lateral metal beams that are welded together with the longitudinal support members 114, with the longitudinal support members 114 also being provided as metal beams. The lateral support member 102 may, for example, comprise aluminum and be manufactured by extrusion. However, any tough material may be used for the lateral support members 102 and the longitudinal support members 114.

Preferably, the deformation zone is located in a central portion of the lateral support member, in order to more easily ensure that the deformation zone is aligned between the seats of the vehicle.

Preferably, each lateral support member 102 includes a deformation region 106. Thereby, more energy from the impact can be absorbed by the deformation zone along the entire side of the frame structure. Furthermore, each lateral support member may be controllably deformable in such a way that more occupants in the vehicle may be exposed to a reduced risk of injury due to the deforming frame structure.

Fig. 2 conceptually illustrates a vehicle 200, here a car, having an electrical energy storage module 202 disposed in the vehicle 200. The vehicle 200 is preferably an at least partially electrically driven vehicle, such as a hybrid vehicle or a fully electric vehicle. The electrical energy storage module 202 includes a frame structure 100, the frame structure 100 including a set of lateral support members 102 arranged in a lateral direction 204 of the vehicle 200. The lateral direction 204 is in a side-to-side (side-to-side) direction of the vehicle, perpendicular to an axis 206 in a direction of travel of the vehicle.

The energy storage module 202 includes electrical energy storage devices, only one electrical energy storage device 210 being shown here for clarity. An energy storage device 210 is disposed in the recess formed by two adjacent lateral support members 102a and 102 b. Energy storage devices 210 are interleaved (interleaved) between lateral support members 102 a-b.

Preferably, the energy storage device 210 comprises a battery for providing electric propulsion energy to the vehicle. The energy storage module 200 may include a plurality of batteries, each including a plurality of cells, such as lithium ion cells.

Fig. 3 shows a top view of a vehicle 200 with a frame structure 100 arranged under the vehicle floor. The electrical energy storage device is omitted in fig. 3. There are four vehicle seats 216a, 216b, 216c, 216d in the vehicle interior. The vehicle seats 216a and 216b are front row seats, and the vehicle seats 216c and 216d are rear row seats that are disposed rearward of the front row seats 216a, 216b along an axis 206 that is parallel to a general direction of travel of the vehicle 200.

The frame structure 100 is arranged such that the deformation zone 106 is aligned between the laterally disposed vehicle seats. In other words, the deformation region 106 included in the laterally-disposed cross support member 102 within the vehicle 200 is aligned between the front seats 216a-b or between the rear seats 216c-d, e.g., at least one deformation region 106 is aligned between the front seats 216 a-b.

Thus, deformation of the lateral support members 102 occurs in a location between the vehicle seats, thereby reducing the risk of deformation injuring the vehicle occupants. Thus, because the deformation zones are aligned between the vehicle seats, the deformation occurs further away from the occupant than at other deformation locations.

Figure 4 conceptually illustrates a side view of a lateral support member 102, such as the lateral beam 102 of the frame structure shown in figure 1. The transverse support beams 102 are arranged to reach between the longitudinal support beams 114, which longitudinal support beams 114 are attached to the side sills 116a-b of the vehicle, for example by welding or using screws or bolts. The longitudinal support beam 114 is illustrated here as having an L-shaped cross-section, but other possible longitudinal support beam configurations are possible and within the scope of the present disclosure. An L-shaped longitudinal support beam 114 provides for attaching the frame structure 100 from below where the shoulders 114a-b reach below the side beams 116 a-b.

The transverse support beam 102 includes a deformation region 106 adapted to deform when a sufficiently strong force 402 is applied. As a result of the force 402, the deformation region is preferably configured to telescopically deform along a longitudinal axis 404 of the cross-support beam 102. When the frame structure is arranged for use in a vehicle, the longitudinal axis 404 is parallel to the transverse direction 204 of the vehicle 200.

The telescoping deformation of lateral support member 102 is understood to cause compression of lateral support member 102 along longitudinal axis 404. The compression is irreversible, and thus deformation region 106 collapses along longitudinal axis 404, causing the length of the lateral support member along longitudinal axis 404 to decrease. When the deformed region 106 is subjected to a sufficiently large force 402, the deformed region 106 may irreversibly deform.

Deformed region 106 is structurally weaker than adjacent portions 107 and 109 of lateral support member 102. In this way it is ensured that the deformed region 106 is deformed before the adjacent portions 107 and 109. Thus, the less structurally deformed region 106 is designed such that when a force is applied on the deformed region 106 that is lower than the force required to deform the adjacent portions 107 and 109, the deformed region 106 collapses along the longitudinal axis 404. Thus, the adjacent portion may be subjected to a greater force 402 along the longitudinal axis 404 than the less structurally deformed region 106.

The deformation region 106 is designed to deform when the lateral force 402 exceeds a threshold. Thus, the structural weakness of the deformation region 106 is made such that it deforms to absorb energy with a well-adapted configuration when the applied force 402 is within a range known from empirical testing or from simulation of a crash scenario.

The deformed region 106 may be implemented in various ways. In one embodiment, the deformation region may include a hole 406 in the lateral support member 102. In other words, a hole may be formed in the lateral support member 102, and the lateral support member 102 may be a hollow beam. For example, a through hole may be formed in the material of the hollow beam such that a through hole is formed in the hollow interior space of the hollow beam 102. The holes are formed in a direction perpendicular to the longitudinal axis 404. In other possible embodiments, grooves are formed instead of or in addition to the holes 404. Forming the grooves is another possible way of providing a structurally weaker deformation zone 106 compared to the adjacent portions 107 and 109 of the beam.

In various embodiments, the length of the deformation region 106 along the transverse beam 102 is less than the length of each transverse beam portion 107, 109 outside the deformation region 106. In other words, the length of the deformed region 106 along the longitudinal axis 404 is shorter than each of the adjacent transverse beam portions 107, 109. However, the length of the deformation zone 106 is still long enough to provide a telescopic deformation of the transverse beam that allows for sufficient energy absorption.

The shape of the holes may be, for example, elongated, or in other possible embodiments, the shape of the holes is circular, such as shown in fig. 4-5, or square, or polygonal.

In various embodiments, the deformation region may include an array 408 of holes in the lateral support member 102. For example, as conceptually illustrated in fig. 5, the array 408 of holes 406 may extend around the entire perimeter of the lateral support member. The layout of the array of holes may be adapted to the specific implementation.

In one embodiment, the deformation zone has six circular holes on each side of the transverse beam 102. In one embodiment, the deformation region has a central axis of the bore that intersects the recess 114. When installed in a vehicle, the holes may each have a central axis along the direction of travel 206 of the vehicle. In one embodiment, the deformation region has only a hole with a central axis that intersects the recess 114. The central axis intersecting the recess 114 may be substantially horizontal when the frame structure is mounted in a vehicle and the vehicle is standing on a level ground.

In various embodiments, the lateral support members and the respective deformation regions are made in one piece. This allows for a cost effective manufacturing process. For example, the lateral support member may be manufactured by extrusion, and the hole 406 for forming the deformation region 106 may be made by punching or machining the hole through the material of the lateral support member 102.

Another possible way of manufacturing a lateral support member according to an embodiment of the present disclosure is to manufacture the deformation region 106 in a different material and/or in a different extrusion direction than the adjacent portions 107 and 109, and then attach the adjacent beam portions 107 and 109 on opposite sides of the deformation region.

The person skilled in the art realizes that the present invention by no means is limited to the preferred embodiments described above. On the contrary, many modifications and variations are possible within the scope of the appended claims.

For example, the material selection of the lateral support member may be selected from other materials suitable for holding the energy storage device in place and capable of providing for the creation of deformed regions in the material. A non-exhaustive list of materials for the lateral support members includes aluminum, aluminum alloys, steel, 3D printable polymers. In a preferred embodiment, the rear support member is made of extruded aluminum.

The vehicle may be of various types, for example a light vehicle such as a car, although a truck is also suitable.

Exemplary dimensions of the lateral support member are 20-30mm in width (i.e., along axis 206 in fig. 2) and 100-150mm in height. Furthermore, the thickness of the material of the transverse support member, which is provided for example in the form of a hollow beam, is about 3-6 mm.

A typical load situation for which the deformation zone is suitable may be a pole of 250mm diameter that impacts the vehicle from the side.

The energy storage devices may be interleaved between the lateral support members.

The energy storage device may be a battery for providing electric propulsion energy to the vehicle.

The energy storage module may be adapted to be arranged under a seat of a vehicle.

In the claims, the word "comprising" does not exclude other elements or steps, and the indefinite article "a" or "an" does not exclude a plurality. A single processor or other unit may fulfill the functions of several items recited in the claims. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage. Any reference signs in the claims shall not be construed as limiting the scope of the claims.

Various examples have been described. These and other examples are within the scope of the following claims.