Energy Store Floor System for an Electrically Drivable Motor Vehicle

Abstract

An energy store floor system for an electrically drivable motor vehicle includes a floor structure having respective side sills, to the underside of which is fastened a store housing of an energy store for an electrical drive of the motor vehicle, and having respective profile elements, which are arranged along longitudinal sides of the store housing and are fastened to the underside of the respectively assigned side sill. In order to create an energy store floor system with an improved accident behavior in the event of a side impact, the profile elements are connected to the respectively laterally assigned side sill via respective connection devices, which are detachable from the outside inwards when there is a relative movement, caused by an accident, of the respective side sill relative to the assigned profile element in the vehicle transverse direction.

Claims

1.-7. (canceled)

8. An energy store floor system for an electrically drivable motor vehicle, comprising: a floor structure having respective lateral side sills, to an underside of which is fastened a store housing of an energy store for an electric drive of the motor vehicle, and having respective profile elements which are arranged along longitudinal sides of the store housing and are fastened on the underside of a respectively assigned lateral side sill, wherein the profile elements are connected to the respectively assigned lateral side sill via respective connecting devices which are detachable in case of an accident-induced relative movement of the respective side sill with respect to the assigned profile element in a vehicle transverse direction from outside inward.

9. The energy store floor system according to claim 8, wherein the respective connecting device is formed by way of an opening in the profile element and a bolt which penetrates the opening and is held on the corresponding side sill.

10. The energy store floor system according to claim 9, wherein the profile element is held on the side sill by a holding force which is exerted on the profile element by way of the respective bolt of the connecting device, after the accident-induced exceeding of which holding force the side sill is movable relative to the assigned profile element in the vehicle transverse direction from the outside inward.

11. The energy store floor system according to claim 9, wherein the opening of the respective connecting device in the profile element widens in cross section from the outside inward in the vehicle transverse direction.

12. The energy store floor system according to claim 9, wherein the opening of the respective connecting device in the profile element has a keyhole-shaped configuration in cross section.

13. The energy store floor system according to claim 9, wherein in the course of the accident-induced relative movement of the respective side sill with respect to the assigned profile element in the vehicle transverse direction from the outside inward, the opening and the corresponding bolt of the corresponding connecting device are brought out of engagement by way of a relative movement in the vehicle vertical direction.

14. The energy store floor system according to claim 9, wherein the opening of the respective connecting device in the profile element is configured to be greater in cross section in an inner cross section than a portion of the bolt.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0018] FIG. 1 is a perspective view of a store housing of an energy store for an electric drive of a motor vehicle having respective profile elements which are arranged along longitudinal sides of the store housing,

[0019] FIG. 2 is a perspective view of one of the profile elements which, according to FIG. 1, is arranged on the corresponding longitudinal side of the store housing;

[0020] FIG. 3 is a plan view of the profile element according to FIGS. 1 and 2;

[0021] FIG. 4 is a perspective sectional view through the energy store floor system along a sectional plane, running in the vehicle transverse direction and in the vehicle vertical direction, in the region of one of the profile elements which is arranged along the corresponding longitudinal side of the store housing and is fastened on the lower side of the laterally assigned side sill;

[0022] FIGS. 5a and 5b show details of a respective bottom view of the energy store floor system according to an embodiment of the invention before (FIG. 5a) and during (FIG. 5b) a side impact of a pole with the laterally corresponding side sill in a longitudinal region in front of the assigned profile element of the store housing, as a result of which an accident-induced relative movement of the side sill with respect to the corresponding profile element in the vehicle transverse direction from the outside toward the inside is produced, which relative movement causes releasing of the corresponding connecting device in the vicinity of the pole impact; and

[0023] FIG. 6 shows details of a perspective view laterally from the outside of the energy store floor system in the region of the side sill which is affected during the pole impact and, as a consequence of its relative movement with respect to the corresponding profile element, is released from the profile element at the corresponding connecting devices and has passed out of engagement, as a result of which an excessive movement of the profile element in the direction of the store housing is avoided.

DETAILED DESCRIPTION OF THE DRAWINGS

[0024] FIG. 1 shows, in details of a perspective view of an energy store floor system for an electrically drivable motor vehicle, a store housing 1 of an energy store for an electric drive of the vehicle which is also arranged, in a way which will be described in greater detail in the further text, below a floor structure of the body of the motor vehicle. A respective laterally assigned profile element 3 which in the present case is connected, for example, by means of respective bolt connections to the store housing 1, is arranged along the respective longitudinal sides 2 of the store housing 1.

[0025] This profile element 3 is shown in FIG. 2 in a perspective view and in FIG. 3 in a plan view. In the present case, the profile element 3 is produced, in particular, as an extruded profile or multiple-chamber profile, in particular from an aluminum alloy. Other embodiments of the profile element 3 would of course also be possible.

[0026] FIG. 4 shows, in details of a perspective sectional view of a sectional plane which runs in the vehicle transverse direction and in the vehicle vertical direction, the energy store floor system, in the case of which the store housing 1 which is shown according to FIG. 1 is arranged on the lower side of a floor structure of the motor vehicle body which comprises respective side sills 5 which run on the vehicle outer sides and between which respective cross members 6 and a vehicle floor 7 or a floor panel extend. Here, the store housing 1 is fastened, inter alia, by means of the respective laterally associated profile elements 3 on the lower side of the respective laterally assigned side sill 5 via respective connecting devices 8.

[0027] These connecting devices 8, of which three are provided per lateral profile element 3 in the present case, in each case comprise a bolt element 9 which is held on the part of the corresponding side sill 5 and penetrates a corresponding opening 10 in an upper flange 11 of the profile element 3. Here, the bolt elements 9 comprise respective bolts 12 and bolt heads 13, between which a bush 14 is arranged. This bush 14 can also be seen in the profile elements 3 according to FIGS. 1 to 3. Here, the bushes 14 are adapted with an inner cross section 15 to an outer cross section 16 of the respective opening 10 within the profile element 3. In the present case, this outer cross section 16 is configured, for example, as a slot.

[0028] As can be seen, in particular, from FIGS. 1 to 3, the respective opening 10 in the profile element 3 widens from the outer cross section 16 in the vehicle transverse direction toward the inside to an inner cross section 17, in the manner of a keyhole. More precisely, the opening 10 increases from the outer cross section 16 toward the inner cross section 17 in such a way that the inner cross section 17 is of larger configuration than an outer circumference of the bush 14 of the respective bolt element 9. While an outer collar 18 of the respective bush 14 is accordingly supported by the corresponding upper flange 11 of the profile element 3 in its position which is shown in FIGS. 1 to 3 and in which it lies in congruence with the outer cross section 16 of the opening 10, the respective opening 10 in the inner cross section 17 is increased in such a way that the collar 18 of the bush 14 can no longer be supported.

[0029] Accordingly, the stated connecting device 8 brings about a connection of the respective profile element 3 to the laterally assigned side sill 5 which can be released in the case of an accident-induced relative movement of the respective side sill 5 with respect to the assigned profile element 3 in the vehicle transverse direction from the outside toward the inside.

[0030] A relative movement of this type of the respective side sill 5 with respect to the assigned profile element 3 results, for example, in the case of a side impact of a pole 19, as can be seen in combination with FIGS. 5a and 5b. Here, details of a respective bottom view show the energy store floor system with the store housing 1 which is fastened on the lower side of the respective laterally assigned side sill 5 via the respective profile element 3. If, as can be seen from FIG. 5a, a side impact with the pole 19 then occurs, the force (arrow 20) which is introduced by way of the pole 19 brings about a corresponding deformation and intrusion of the pole 19 into the motor vehicle body in the region of the side sill 5 in front of the profile element 3, with the result that it is first of all not yet loaded directly. Here, the intrusion of the pole 10 becomes clear from FIG. 5b.

[0031] As a consequence of this intrusion of the pole 19 into the motor vehicle body in the region of the side sill 5, a relative movement between this side sill 5 and the laterally assigned profile element 3 in the vehicle transverse direction from the outside toward the inside occurs. In order to avoid here, for example, that the profile element 3 moves excessively in the direction of the store housing 1 in the vehicle transverse direction inward and intrudes into the store housing 1 with an amount of energy which is so high that, for example, the energy store is damaged and a thermal event is produced, at least the connecting device 8 in the vicinity of the impact of the pole 19 is released in the present case.

[0032] Here, the profile element 3 is first of all fixed on the laterally associated side sill 5 via the respective connecting device 8 with a holding force which is brought about by way of the corresponding bolt element 9, with the result that the bolt elements 9 and the associated bushes 14 are held in the position which is shown in FIGS. 1 to 5a. If this holding force is exceeded as a consequence of the relative movement of the side sill 5 with respect to the profile element 3 in the vehicle transverse direction toward the inside, the respective bolt element 9 is moved with the associated bush 14 out of the position shown in FIGS. 1 to 5a in the vehicle transverse direction inward relative to the opening 10, with the result that the corresponding bolt element 9 and its bush 14 pass into the inner cross-sectional region 17 of the respective opening 10, in which the bush 14 and the associated bolt element 9 pass out of engagement with the opening 10.

[0033] As soon as the bolt element 9 with the bush 14 passes into the region of the inner cross section 17 of the corresponding opening 10 as a consequence of the relative movement between the side sill 5 and the profile element 3, the bolt element 9 with the bush 14 passes out of engagement with the opening 10 and, as a consequence of the weight, passes by way of a relative movement in the vehicle vertical direction into the position which is shown in FIG. 6, in which the profile element has been released from the corresponding side sill 5 as a result of releasing of the connecting devices 8 in the case of the corresponding pole impact. It is achieved here as a result that, in the event of a correspondingly large relative movement of the side sill 5, the profile element 3 is not moved via the respective connecting devices 8 with the latter and therefore excessively in the vehicle transverse direction inward, but rather the corresponding connecting devices 8 are released, with the result that an excessive intrusion on the longitudinal sides 2 of the store housing 1 cannot occur. As a result, inter alia, serious damage of the store housing 1 which can lead, for example, to a thermal event is effectively avoided.

[0034] Overall, it can therefore be seen that, in the present case, the corresponding profile element 3 and therefore the store housing 1 are held on the corresponding side sill 5 with a defined holding force which can be determined by way of the respective bolt element 9 of the connecting device 8, the respective connecting device 8 first of all being released in the case of a corresponding accident-induced force load and an associated relative movement of the side sill 5 with respect to the profile element 3, by the respective bolt element 9 with the associated bush 14 moving out of the outer cross section 16 of the opening 10 in the direction of the inner cross section 17. When this inner cross section 17 of the opening 10 is reached, the bolt element 9 with the bush 14 passes out of engagement with the respective opening 10 within the profile element 3, with the result that the weight of the profile element 3 brings it about, moreover, that the respective bolt element 9 with the bush 14 and the corresponding opening 10 within the profile element 3 pass out of engagement, and therefore the connecting devices 8 are released.

LIST OF DESIGNATIONS

[0035] 1 Store housing [0036] 2 Longitudinal sides [0037] 3 Profile element [0038] 4 Floor structure [0039] 5 Side sill [0040] 6 Crossmember [0041] 7 Vehicle floor [0042] 8 Connecting device [0043] 9 Bolt element [0044] 10 Opening [0045] 11 Upper flange [0046] 12 Bolt [0047] 13 Bolt heads [0048] 14 Bush [0049] 15 Inner cross section [0050] 16 Outer cross section [0051] 17 Inner cross section [0052] 18 Collar [0053] 19 Pole [0054] 20 Arrow