阅读说明：本技术 结构构件、电池壳体和具有这种电池壳体的机动车 (Structural component, battery housing and motor vehicle having such a battery housing ) 是由 C.韦谢 S.沙赫特 H.费纳 R.格拉赫 于 2019-06-21 设计创作，主要内容包括：本发明涉及一种用于电驱动的机动车(2)的电池壳体(6)的结构构件(22),其具有壁(24),壁沿构件高度方向(H)从壁下侧(30)延伸至壁上侧(32),并且沿垂直于构件高度方向的构件纵向方向(L)从第一端侧(26)延伸至第二端侧(28),其中,壁(24)为了提高其抗弯强度具有在一侧布置在壁(24)上的和垂直于该壁定向的肋(40)和/或凹槽(38),并且其中,肋(40)或凹槽(38)基本上沿构件纵向方向(L)延伸。此外,本发明还涉及一种用于电驱动的机动车(2)的电池(36)的电池壳体(6),以及一种机动车(2)。(The invention relates to a structural component (22) for a battery housing (6) of an electrically driven motor vehicle (2), comprising a wall (24) which extends in a component height direction (H) from a wall underside (30) to a wall upper side (32) and in a component longitudinal direction (L) perpendicular to the component height direction from a first end side (26) to a second end side (28), wherein the wall (24) for increasing the bending strength thereof comprises a rib (40) and/or a groove (38) which is arranged on one side on the wall (24) and is oriented perpendicular thereto, and wherein the rib (40) or the groove (38) extends substantially in the component longitudinal direction (L). The invention further relates to a battery housing (6) for a battery (36) of an electrically driven motor vehicle (2), and to a motor vehicle (2).)

1. A structural component (22) for a battery housing (6) of an electrically driven motor vehicle (2), having a wall (24) which extends in a component height direction (H) from a wall underside (30) to a wall upper side (32) and in a component longitudinal direction (L) perpendicular to the component height direction from a first end side (26) to a second end side (28),

-wherein the wall (24) has, for increasing its bending strength, ribs (40) and/or grooves (38) arranged on one side on the wall (24) and oriented perpendicularly to said wall, and

-wherein the ribs (40) or grooves (38) extend substantially in the member longitudinal direction (L).

2. Structural element (22) according to claim 1, wherein the ribs (40) or grooves (38) in the element longitudinal direction (L) are at least partially slightly inclined towards the wall underside (30) of the wall (24).

3. Structural element (22) according to claim 1 or 2, wherein vertical ribs (42) are provided which are arranged on the wall (24) and which are oriented perpendicularly to the wall, wherein the vertical ribs (42) extend substantially in the element height direction (H).

4. Structural element (22) according to one of claims 1 to 3, wherein the wall height (44) of the wall (24) extending from the wall underside (30) to the wall upper side (32) decreases in the element longitudinal direction (L).

5. Structural component (22) according to one of claims 1 to 4, characterised in that a holding element (46), in particular for a housing cover, is provided, wherein the holding element (46) is formed on a wall upper side (32) of the wall (24).

6. Structural element (22) according to one of claims 1 to 5, wherein a projection (50) projecting dome-like relative to the wall (24) is provided for mounting in a battery housing (6) and/or for fixing a battery module (34) of a battery (36), which projection (50) is formed on the wall (24) in the region of the first end side (26) or the second end side (28).

7. A battery housing (6) for a battery (36) of an electrically driven motor vehicle (2), the battery housing having:

a trough-shaped receptacle (8) having a housing base (10) and having a housing frame (12), wherein the receptacle (8) forms a housing interior (14),

-a number of structural members (22) according to one of claims 1 to 6 arranged in the housing interior (14), which structural members are oriented perpendicularly to the housing bottom (10) and perpendicularly to two parallel and mutually spaced housing longitudinal sides (16) of the housing frame (12),

-wherein at least one structural component (22) is applied to each housing longitudinal side (16), and

-wherein the wall height (44) of the wall (24) of the structural member decreases from the respective housing longitudinal side (16).

8. The battery housing (6) according to claim 7, wherein a longitudinal carrier (20) is provided which is arranged transversely to the structural component (22) in the housing interior (14), on which longitudinal carrier the structural component (22) rests.

9. An electrically driven motor vehicle (2) having a battery housing (6) according to claim 7 or 8, wherein the member longitudinal direction (L) of the structural member (22) is parallel to the vehicle transverse direction (Y).

10. Motor vehicle (2) according to claim 9, characterized in that a rocker (4) is provided which extends in the vehicle longitudinal direction (X), wherein the battery housing (6) is arranged between the rockers (4).

Technical Field

The invention relates to a structural component for a battery housing of an electrically driven motor vehicle. The invention further relates to a battery housing for a battery of an electrically driven motor vehicle and to such a motor vehicle.

Background

Electrically driven motor vehicles usually have a battery (traction battery) which supplies the electric motor for driving the motor vehicle with energy. Electrically driven motor vehicles are understood to be, in particular, electric vehicles (BEV, battery electric vehicle) with range extender (REEV, range extended electric vehicle), hybrid vehicles (HEV, hybrid electric vehicle), and/or plug-in hybrid electric vehicles (PHEV, plug-in hybrid electric vehicle) in which the energy required for driving is stored only in the battery.

In particular, the force action caused by an accident, i.e. by a collision or an impact, can lead to damage of the battery. In this damage, the energy stored in the battery can be released, for example, explosively. Furthermore, a fire hazard and/or danger to the vehicle occupants (passengers) may develop based on the discharge of the battery.

In order to avoid damage to the battery, for example, a (reinforcing) element is arranged in the housing interior of the battery housing, which increases the strength of the housing and should prevent the battery housing from deforming into the housing interior.

A battery housing part for a traction battery of a vehicle having an electric drive is known, for example, from DE 102015111325 a 1. The battery housing part has a receiving body into which the traction battery can be received. The receiving body, which comprises at least one integrated organic sheet material part, is made of a thermoplastic plastic. Furthermore, it is provided that the organic sheet metal part has a base section and at least one reinforcing section extending perpendicularly to the base section.

DE 202016110330 a1 discloses a housing for a vehicle battery. The housing has a cover plate and a base plate, wherein a frame connected thereto is arranged between the cover plate and the base plate. At least one transverse carrier element is arranged in the space enclosed by the frame.

Disclosure of Invention

The object of the present invention is to provide a structural component which is suitable for protecting a battery accommodated in a battery housing from external forces and thus from possible damage. Furthermore, a battery housing having such a structural component and a motor vehicle having such a battery housing are to be provided.

According to the invention, this object is achieved by a structural component having the features of claim 1. Furthermore, according to the invention, the object is achieved by a battery housing having the features of claim 7 and by an electrically driven motor vehicle having the features of claim 9. Advantageous embodiments and embodiments are the subject matter of the dependent claims.

The structural component is provided and assigned to this purpose for a battery housing of an electrically driven motor vehicle. The structural member has a wall extending in a member height direction from a wall lower side to a wall upper side and extending in a member longitudinal direction perpendicular to the member height direction from a first end side to a second end side. The wall therefore has a planar extent in a plane spanned by the component height direction and the component longitudinal direction.

The wall has grooves and, alternatively or preferably, additionally ribs for increasing the bending strength of the wall, the ribs being arranged on one side on the wall and oriented perpendicular to the wall. The ribs or grooves extend substantially in the longitudinal direction of the component.

Particularly preferably, the wall has a plurality of ribs and/or grooves. The wall is therefore based on the groove being meandering in cross section, i.e. in a cross section with a cross section perpendicular to the longitudinal direction of the component. In other words, in the cross section, the sections of the wall extending in the component height direction are arranged alternately on the outside with respect to a component thickness direction perpendicular to the component height direction and the component longitudinal direction. One or more of the ribs are arranged here, for example, in a groove. It is also preferred that the ribs do not project beyond the grooves in the thickness direction of the element, so that the extent of the wall in this direction is determined by the greatest depth of the grooves.

Advantageously, the bending strength of the wall and thus of the structural member is increased by means of grooves or ribs. In particular, the wall is prevented from bending or bending (outwardly or inwardly) in the thickness direction of the component with a bending or bending edge perpendicular to the direction of extension of the rib or groove, i.e. essentially in the longitudinal direction of the component. In other words, bending or bending about a bending axis extending substantially along or against the height direction of the component is prevented. The idea is based on the fact that the area moment of inertia (also referred to as second moment) of the wall about the bending axis is amplified by means of grooves or ribs. In other words, the wall provided with grooves and/or ribs has a comparatively high, so-called stainer (Steiner) share with respect to the bending axis.

According to an advantageous embodiment, the ribs or grooves are at least partially slightly inclined in the longitudinal direction of the component, i.e. from the first end side to the second end side, towards the wall underside of the wall. A slight inclination is understood here to mean that the angle of inclination between the rib or groove and the underside of the wall is in particular greater than or equal to 10 °, and for example less than 45 °, in particular less than 30 °. Due to this inclination of the grooves or ribs, the forces acting on the first end side are correspondingly directed towards the wall underside. The wall underside rests against the housing base of the battery housing in a suitable manner, so that the forces acting on the first end side are at least partially conducted out of or into the battery base.

In short, the structural member functions as a so-called force transducer. In particular, the structural component absorbs externally introduced forces and/or guides them out or guides them further. In addition, the ribs or grooves have a dual function. The ribs or grooves thus on the one hand, on the basis of their inclination, effect a force acting on the first end side of the wall to be directed towards the force on the lower side of the wall. On the other hand, the ribs or grooves are used to improve the bending strength.

According to an advantageous embodiment, vertical ribs are arranged, in particular formed, on the wall, which are oriented perpendicularly to the wall and extend substantially in the height direction of the component. The vertical ribs, like the ribs or grooves, increase the bending strength of the wall. Furthermore, the vertical ribs also function as force transducers. The vertical ribs guide the forces acting on the wall upper side or wall lower side to the wall lower side or wall upper side.

According to an advantageous embodiment, the height of the wall extending from the lower side of the wall to the upper side of the wall, i.e. the extent of the wall in the direction of the height of the component, decreases in the longitudinal direction of the component. In other words, the wall tapers in the longitudinal direction of the component, i.e. from the first end side to the second end side. In this case, it is particularly preferred if the wall underside extends in the longitudinal direction of the component, wherein the wall upper side is inclined relative to the longitudinal direction. In particular, the structural component is advantageously designed in a weight-saving manner in that way, wherein the wall and thus the structural component are also resistant to bending on the basis of the grooves and/or ribs which are likewise inclined relative to the longitudinal direction of the component.

In a suitable embodiment, the support element is formed on the upper wall side of the wall. Alternatively, the holding element is fixed only on the upper side of the wall. The support element in particular takes on the bearing function of the housing cover for the battery housing. The mounting contour is additionally arranged or introduced in or on the support element, for example. The support element has, for example, (screw) receptacles for screws for fastening the housing cover or insertion contours for correspondingly adapted (mating) contours on the housing cover.

In a suitable embodiment, a projection projecting in a dome-like manner relative to the wall is formed on the wall. The projection is formed in the region of the first or second end side on the wall, i.e. on the end side in terms of the longitudinal direction of the component. The projection suitably projects beyond the rib or groove. The projection enables the structural component to be mounted in the battery housing, in particular on the housing base, and additionally or alternatively enables the battery module of the battery to be fixed. In order to reliably mount and/or fix the battery module, projections are preferably formed on both sides of the wall in the region of the first end face and also in the region of the second end face.

The structural component is in particular a cast part, preferably a cast part made of aluminum. Alternatively, the structural component is produced by forging. In particular, the structural element has a high functional integration compared to the construction of the structural element as an extruded profile. In particular, the projection and the support element can thus be integrally, i.e. integrally and jointly formed by the casting method and also formed in a suitable manner on the wall. It is thus additionally possible to achieve that the ribs or grooves are inclined relative to the longitudinal direction of the component and that the wall height is reduced in a weight-saving manner. Here, a high bending strength is also achieved on the basis of the grooves and/or ribs.

In an advantageous embodiment, the battery housing is provided and configured for a (traction) battery of an electrically driven motor vehicle. For this purpose, the housing has a trough-shaped receptacle with a housing base and a housing frame. The housing frame is therefore oriented perpendicularly to the housing base and has two parallel and spaced-apart housing longitudinal sides (frame longitudinal sides) and two housing transverse sides (frame transverse sides) extending transversely to the housing longitudinal sides. Here, the receiving portion forms an inner space of the housing. The housing interior is delimited by the housing base and by the housing frame.

In this case, a number of structural components in one of the variants shown above are arranged in the housing interior, wherein the component height direction extends perpendicular to the housing base, i.e. the structural components are arranged perpendicular to the housing base. Furthermore, the structural component is oriented perpendicular to the housing longitudinal side and thus parallel to the housing transverse side. In this case, at least one structural component rests with its first end side on each of the two housing longitudinal sides. The wall height of the wall of the structural component therefore decreases from the adjacent housing longitudinal side toward the housing interior.

In a further advantageous embodiment, a longitudinal support is accommodated in the housing interior, which longitudinal support extends parallel to the housing longitudinal sides and thus transversely to the structural component and extends from one of the housing transverse sides to the other housing transverse side. The structural component rests with its second end side against the longitudinal carrier. The structural members and the longitudinal carriers form a truss-like structure, wherein the battery modules of the (traction) batteries are accommodated in the housing interior space between the structural members or between the structural members and the housing frame.

The forces, which are caused and act on the housing frame, for example as a result of an accident or impact (Crash), are transmitted to the structural component, which in turn leads the forces out (into) the housing base and the longitudinal carriers. Furthermore, due to the increased bending strength by means of the ribs and/or grooves, bending or buckling of the structural component is avoided even when relatively large forces act on the end faces of the walls of the respective structural component. It is therefore particularly advantageous to avoid damage to the battery modules of the battery arranged between the structural components, or at least to significantly reduce the risk of such damage.

In an advantageous embodiment, an electrically driven motor vehicle, also referred to below simply as a motor vehicle, has a battery housing in one of the variants described above. In particular, a number of structural components are accommodated in the battery housing, wherein the walls of the structural components have recesses and/or ribs arranged on one side on the wall and oriented perpendicular to the wall. Here, the battery housing is arranged in the motor vehicle such that the member longitudinal direction of the structural members arranged in the battery housing is parallel to the vehicle transverse direction, which is also referred to as the Y direction. The structural component is therefore also referred to as a transverse carrier.

Therefore, in the event of a side impact (side impact), i.e., in the event of a force acting on the battery case in the vehicle transverse direction, the battery is reliably protected from damage, in particular on the basis of the action of the guiding force of the structural member and the truss-like arrangement of the structural member in the battery case.

In a suitable embodiment, the motor vehicle has a so-called rocker, which extends in the longitudinal direction of the vehicle, also referred to as the X direction, i.e. from the rear to the front of the motor vehicle. The rocker is arranged in particular on the floor side in the motor vehicle and is a component of the (vehicle) body of the motor vehicle. The battery case is disposed between the rocker panels. The rocker provides additional protection against deformation of the battery housing and damage to the battery on account of its comparatively great strength.

Drawings

Embodiments of the present invention are explained in detail later with reference to the drawings. Wherein:

fig. 1 shows an electrically driven motor vehicle with door sills, between which a battery housing for a battery is arranged, in a schematic top view;

fig. 2 shows a perspective view of a battery housing with a groove-shaped receiving portion, which forms a housing interior space, in which a plurality of structural components are arranged;

FIG. 3 shows in perspective a structural member having a wall with a groove and a rib projecting on one side; and

fig. 4 schematically shows a cross section of the structural member according to fig. 3.

In all the figures, mutually corresponding parts and parameters are provided with the same reference numerals throughout.

Detailed Description

Fig. 1 shows an electrically driven motor vehicle 2, also referred to below simply as a motor vehicle, in a schematic plan view. The longitudinal direction of the motor vehicle (X direction) and its transverse direction of the vehicle (Y direction) are indicated by X or Y in the lateral direction diagram. The motor vehicle 2 has a door sill 4, which is a component of a body of the motor vehicle 2, not shown in detail. The rocker panels 4 are arranged parallel to one another and at a distance from one another on the bottom side (on the floor side of the motor vehicle 2). Further, the rocker 4 extends in the vehicle longitudinal direction X.

Between the door sills 4, a battery housing 6 is arranged, which is shown in detail in fig. 2. The battery housing 6 has a groove-shaped receiving section 8 with a housing base 10 and a housing frame 12. The receptacle 8 forms a housing interior 14. In other words, the receptacle 8 delimits the housing interior 14. The housing frame 12 in turn has two housing longitudinal sides 16 extending parallel to the rocker 4, i.e. in the vehicle longitudinal direction X, and two housing transverse sides 18 extending transversely with respect to the rocker, i.e. in the vehicle transverse direction Y. Disposed in the housing interior 14 is a rectangular longitudinal carrier 20, which is oriented parallel to the housing longitudinal sides 16 and perpendicular to the housing bottom 10, wherein the longitudinal carrier 20 extends from one housing transverse side 18 to the other housing transverse side 18.

Furthermore, a number of structural members 22 are arranged into the housing interior 14. As is shown on an enlarged scale in fig. 3 and 4, each structural component 22 has a wall 24 with a planar extent in the component height direction H and in the component longitudinal direction L. The structural component 22 therefore extends in the component longitudinal direction L from the first end side 26 to the second end side 28 and in the component height direction H from the wall underside 30 to the wall upper side 32, wherein the extent in the component longitudinal direction L is greater than the extent in the component height direction H.

Each structural component 22 rests with its first end 26 of its wall 24 against the respective housing longitudinal side 16. The second end 28 of the wall 24 of each structural component 22 rests against the longitudinal support 20, and the wall underside 30 rests against the housing base 10. The component height direction H extends perpendicularly to the housing base 10. The structural component 22 is oriented transverse to the housing longitudinal side 16 and the longitudinal carrier 20. The structural member 22 thus extends in the vehicle transverse direction Y, and therefore, the structural member 22 is also referred to as a transverse carrier. The structural member 22 and the longitudinal carrier 20 form a truss-like structure. A battery module 34, shown in dashed lines, is accommodated in the housing interior 14 between the structural members 22 or between the structural members 22 and the housing frame 12, which forms a (traction) battery 36.

The wall 24 of each structural element 22 has several recesses 38 and several ribs 40, wherein the ribs 40 are arranged on one side on the wall 24 and are oriented perpendicularly thereto. As can be seen in fig. 4, the wall 24 is formed on the basis of a groove 38 in a meandering manner in cross section. Thus, the sections of the walls 24 extending in the component height direction H in cross section are arranged alternately on the outside with respect to the component thickness direction D perpendicular with respect to the component height direction H and the component longitudinal direction L. Furthermore, the ribs 40 do not project beyond the grooves 38 in the component thickness direction D here. In other words, the extension of the ribs 40 in the thickness direction D of the member is less than the groove depth of the grooves 38 in that direction.

The grooves 38 and the ribs 40 extend substantially in the longitudinal direction L of the component, i.e. from the first end side 26 to the second end side 28, wherein the ribs 40 and the grooves 38 are at least partially slightly inclined with respect to the longitudinal direction L of the component.

The ribs 40 and grooves 38 serve a dual function. The inclination of the ribs and recesses toward the housing base 10 results in a force guidance of the force F acting on the first end side 26 of the wall 24 toward the wall underside 30. In addition, the ribs 40 and grooves 38 serve to increase the bending strength of the wall 24 and thus the structural member 22.

In short, the structural member 22 functions as a so-called force transducer. The structural component in this case absorbs and/or conducts externally introduced forces, in particular. Therefore, when the force F acts on the battery case 6 in the vehicle lateral direction Y, the case frame 12 is supported on the structural member 22. The force F is introduced into the housing base 10 and the longitudinal support 20 on the basis of the force-converting (force-transmitting) effect of the structural component 22 resting against the housing frame 14. In this way, the battery 36 is protected against forces and corresponding damage. The force F is represented here by a corresponding arrow and is generated, for example, by an impact (side impact, accident).

Arranged on the wall 24 of the structural component 22 are vertical ribs 42 which are oriented perpendicularly with respect to the wall and extend substantially in the component height direction H and which further increase the bending strength of the wall 24. The vertical ribs 42 extend here over the entire extent of the wall 24 in the height direction H, i.e. from the wall underside 30 to the wall upper side 32, or only partially over the plurality of grooves 38. The extension of the wall 24 in the component height direction H is also referred to below as the wall height 44.

The wall height 44 of the wall 24 of each structural member 22 decreases in a weight-saving manner in its member longitudinal direction L from the first end side 26 to the second end side 28. In other words, the wall height 44 decreases from the housing longitudinal side 16, on which the respective structural component 22 rests, to the longitudinal support 20, i.e., toward the center of the housing interior 14. In this case, three support elements 46 standing upward for a housing cover, not shown in detail, are formed on the wall top 32 in the component height direction H. The first and third support elements 46 with respect to the longitudinal direction L of the component each have a screw receptacle 48 for a screw for mounting the housing cover.

Formed on the wall 24 of each structural member 22 is a respective projection 50 projecting dome-like relative thereto, which exceeds the groove 38 and the rib 40 in the member thickness direction D. The projections 50 are formed on both sides of the wall 24 in the region of the first end side 26 and in the region of the second end side 28. In other words, the convex portion 50 is formed on the end side with respect to the member longitudinal direction L, and is formed on both sides of the wall 24. Furthermore, projections are formed in the region of the wall underside 30 on the end sides with respect to the wall height direction H, wherein the projections 50 are configured as screw heads for mounting the respective structural component 22 on the housing base 10 and for fixing the respective battery module 34.

The invention is not limited to the embodiments described before. On the contrary, other variants of the invention can also be derived therefrom by the person skilled in the art without departing from the subject matter of the invention. Furthermore, in particular, all individual features described in connection with the exemplary embodiments can also be combined with one another in other ways without departing from the subject matter of the invention.

List of reference numerals

2 Motor vehicle

4 vehicle door threshold

6 Battery case

8 accommodating part

10 bottom of the housing

12 casing frame

14 inner space of the housing

16 longitudinal side of the housing

18 lateral side of the shell

20 longitudinal carrier

22 structural member

24 wall

26 first end side

28 second end side

30 wall underside

32 upper side of wall

34 battery module

36 cell

38 groove

40 Ribs

42 vertical rib

44 wall height

46 support element

48 screw receiving part

50 projection

D thickness direction of the member

Force F

Height direction of H member

Longitudinal direction of L-shaped member

Longitudinal direction of X vehicle

Y vehicle lateral direction