Active Material Container, Battery Housing, and Method for Mounting the Active Material Container in the Battery Housing

Abstract

An active material container for a functional housing has an air-permeable casing with an interior and an active material arranged inside the interior. One or more rim-side guide elements are arranged at the air-permeable casing and are provided to linearly slidably guide the active material container in an insertion direction in corresponding guide elements of a receptacle of the functional housing. The functional housing is preferably a battery housing.

Claims

1. An active material container for a functional housing, the active material container comprising: an air-permeable casing comprising an interior; an active material arranged inside the interior; one or more rim-side guide means arranged at the air-permeable casing and configured to linearly slidably guide the active material container in an insertion direction in corresponding guide means of a receptacle of the functional housing.

2. The active material container according to claim 1, wherein the one or more rim-side guide means extend in the insertion direction.

3. The active material container according to claim 1, wherein the casing comprises walls that are facing away from each other and wherein the rim-side guide means are arranged at the walls that are facing away from each other.

4. The active material container according to claim 1, wherein the casing comprises at least one lattice-shaped wall section or a lattice-shaped wall.

5. The active material container according to claim 4, wherein the at least one lattice-shaped wall section or the lattice-shaped wall comprises an average lattice mesh width of more than 0.5 mm.

6. The active material container according to claim 4, wherein the casing is a lattice housing.

7. The active material container according to claim 4, wherein the at least one lattice-shaped wall section or the lattice-shaped wall comprises lattice stays and the lattice stays have a thickness of at least 0.8 mm.

8. The active material container according to claim 1, wherein the one or more rim-side guide means are embodied as a guide rail, respectively, wherein the guide rail extends away in a radial direction from a wall of the casing.

9. The active material container according to claim 1, wherein the casing is embodied in a basket shape and comprises an insertion opening configured to enable an exchange of the active material in the interior of the casing, wherein the exchange of the active material is realized in the insertion direction, wherein the active material container comprises a cover configured to close the insertion opening.

10. The active material container according to claim 1, wherein the one or more rim-side guide means are embodied as a guide rail, respectively, and wherein the guide rail comprises a locking means.

11. The active material container according to claim 10, wherein the locking means is at least one locking tongue.

12. The active material container according to claim 10, wherein the guide rail is embodied in an arc shape and comprises a central segment extending parallel to the insertion direction.

13. The active material container according to claim 12, wherein the guide rail comprises a locking tongue arranged at the central segment.

14. The active material container according to claim 13, wherein the locking tongue comprises a first springy end comprising at least one locking means and further comprises a second end connected to the central segment.

15. The active material container according to claim 14, wherein the at least one locking means is a locking nose.

16. The active material container according to claim 1, further comprising a fiber receptacle arranged in the casing, wherein the fiber receptacle comprises at least one first material layer of nonwoven material and at least one second material layer of nonwoven material, wherein between the at least one first material layer and the at least one second material layer a cavity is formed, wherein the cavity is at least partially filled with the active material, wherein the fiber receptacle comprises an air-permeable filter region and an at least partially reinforced rim region, wherein the at least partially reinforced rim region comprises a reinforced partial region, wherein the reinforced partial region comprises a reduced air permeability in comparison to the air-permeable filter region.

17. The active material container according to claim 1, wherein the active material comprises or is comprised of at least one drying agent and/or an adsorbent agent for harmful gases.

18. The active material container according to claim 1, wherein the active material is selected from the group consisting of active carbon; zeolite; an adsorbent agent for CO, CO.sub.2, NO.sub.X and/or hydrocarbons; and combinations thereof.

19. A battery housing comprising: a receptacle comprising edge-side guide means; an active material container comprising: an air-permeable casing comprising an interior; an active material arranged inside the interior; and one or more rim-side guide means arranged at the air-permeable casing and configured to linearly slidably guide the active material container in an insertion direction in the edge-side guide means of the receptacle.

20. The battery housing according to claim 19, wherein the edge-side guide means are guide slots and wherein the rim-side guide means are guide rails, wherein the guide rails and the guide slots interact to achieve a linear slidable guiding action of the active material container in the receptacle.

21. The battery housing according to claim 20, wherein the guide rails and the guide slots comprise an interface, comprising a locking cutout and a locking nose interacting with the locking cutout to limit a mutual linear slidability of the guide rails and the guide slots.

22. A method for mounting an active material container in a battery housing, the method comprising: moving the active material container in a linear sliding action into an end position in a receptacle of the battery housing by inserting one or more rim-side guide means arranged at an air-permeable casing of the active material container into corresponding edge-side guide means of the receptacle of the battery housing; and locking the active material container in the end position in the receptacle.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0035] Further advantages, features, and details of the invention will be described in the following description in which an embodiment of the invention will be explained in more detail with the aid of the accompanying drawings. A person of skill in the art will expediently consider the features disclosed in the drawings, the description, and the claims in combination also individually and combine them to expedient further combinations.

[0036] FIG. 1 shows a perspective view of a detail of a battery housing and an active material housing for arrangement in a receptacle in the battery housing prior to its arrangement in the receptacle.

[0037] FIG. 2 shows a side view of FIG. 1.

[0038] FIG. 3 shows a perspective view of a detail of a battery housing and of the active material housing with the active material housing in an end position in the receptacle.

[0039] FIG. 4 shows a side view of FIG. 3.

[0040] FIG. 5 shows a fiber container for positioning in the active material housing.

DESCRIPTION OF PREFERRED EMBODIMENTS

[0041] FIGS. 1-4 show in detail and in several views a battery housing 30 according to the invention and an active material container 1 according to the invention.

[0042] The active material container 1 comprises a casing 2. The casing 2 is embodied in a basket shape and comprises a bottom 8, two main walls 6, and two sidewalls 7. The main walls 6 comprise in this context a larger surface area, preferably at least twice as large, than the sidewalls 7. The casing 2 is configured as a lattice housing and comprises thus on all sides a lattice structure. It is however also possible that only individual walls 6, 7, 8, in particular at least one main wall 6 or only wall sections of the walls 6, 7, 8, are configured as lattice structures. The aforementioned surface area of a wall comprises the surface area of the lattice structure as well as the surface area of the intermediately positioned free spaces or lattice meshes.

[0043] The casing 2 delimits an interior 3 in which an active material is introduced.

[0044] The active material can be arranged in an arbitrary configuration in the interior 3. For example, the active material can be introduced as bulk material or exchangeably in an air-permeable fiber receptacle 18 which is illustrated in FIG. 5 in an embodiment variant. The fiber receptacle 18 comprises a central filter region 19 and comprises in this context at least two air-permeable nonwoven layers that are fused together as material layers 21 and 22 and a cavity 23 therebetween which is filled with the active material 25 partially or completely.

[0045] For facilitating the positioning of the active material, the fiber receptacle 18 can comprise in addition a reinforced rim region 20. Moreover, the fiber receptacle 18 comprises a central arrangement of reinforcement ribs 24.

[0046] For introducing the active material in the insertion direction 70 into the casing 2, the casing 2 comprises an insertion opening 9. The latter is closed by a cover 13 which is detachably arranged at the casing 2. This can be done e.g. by a locking action. The casing 2 comprises accordingly locking cutouts in the region of the insertion opening 9.

[0047] From each one of the two sidewalls 7, a guide means 4 is projecting which serves for guiding and holding the casing 2 inside a receptacle 31 of the battery housing 30. In FIGS. 1-4, it is embodied as a guide rail 5. The guide rail 5 enables in particular guiding of the casing 2 in interaction with guide slots 32 which are arranged at the edges in the receptacle 31 into which the casing 2 is insertable in an insertion direction 70.

[0048] The guide rail 5 comprises a central segment 10 which extends parallel to the sidewall 7, thus parallel to the insertion direction 70. For stabilization and for positioning within the respective guide slot 32 perpendicularly to the insertion direction 70 in the battery housing 30, the guide rail 5 comprises in addition two end sections 11 which extend perpendicularly to the insertion direction 70 and to the central segment 10. As a whole, the guide rail 5 is embodied in an arc shape of central section 10 and the two end sections 11 and is connected with its longitudinal side to the sidewall 7. In this context, an end section 11 forms in addition a stop with a slot bottom 34 of the guide slot 32, as can be seen best in FIG. 4.

[0049] At the same level as the central segment 10, the guide rail 5 comprises a locking tongue 12. The locking tongue 12 is connected at one end to the central segment 10 and comprises at the opposite side a springy end 14, 15.

[0050] A locking nose 15 is projecting away from the locking tongue 12 at a slant perpendicularly to the insertion direction 70 and thus also at a slant to the central segment 10. The locking tongue 12 and the locking nose 15 thus form together a locking means 14 for preventing a sliding action of the casing 2 and thus of the entire active material container 1 in insertion direction within the guide slots 32.

[0051] The receptacle 31 in the battery housing 30 is divided into three sides: two edge sides 35 and a backside 36 which at the same time are a part of a housing wall of a battery housing 30 delimiting the battery housing in relation to the environment. The housing wall comprises in this context a substantially uniform wall thickness in the region of the receptacle compared to neighboring regions.

[0052] The guide slots 32 are embodied in this context in a U-shape, wherein the guide slots 32 are arranged along the edge sides 35 such that the openings of the U-shape face each other.

[0053] In the following, reference is being had to a lower region and to an upper region of the receptacle 31, wherein the guide slots 32 in relation to the upper region are open in such a way that the guide rails 5 can be threaded into the guide slots 32 in this region.

[0054] The receptacle 31 comprises in addition in the lower region, in particular at the bottom of the receptacle 31, guide ribs 37 which enable an air supply and/or air discharge of air which exits through the main wall 6 which is facing the backside 36 of the receptacle. In this context, the bottom 8 of the casing 2 in the inserted end position can hit the guide ribs 37. Alternatively or additionally, the end sections of the guide rails 4, 5 which are facing in the insertion direction 70 toward the interior of the battery housing 30 can serve as a stop in that they contact in an end position a corresponding counter element of the guide slots 32 of the battery housing 30.

[0055] The receptacle 31 comprises in addition along the backside 36 a partial section 38 which is recessed relative to the remaining region of the backside 36. The guide slots 32 have in addition locking cutouts 33 which correspond with the locking noses 15 and interact with them.

[0056] A respective locking nose 15 and locking cutout 33 form thus an interface 17. It is understood that the interface 17 can also be embodied in reverse so that the locking tongue and the locking nose can be part of the boundary of the guide slot and the locking cutout can be arranged in the guide rail.

[0057] Also, alternatively, the guide slot and corresponding boundary walls can be arranged at the sidewall 7 of the casing 2 and the receptacle can comprise corresponding guide rails.

[0058] The casing 2 is embodied to be air-permeable. For this purpose, the casing comprises selectively lattice-shaped wall sections or lattice-shaped walls. The casing is embodied in FIGS. 1-4 as lattice housing so that all walls are embodied lattice-shaped.

[0059] Lattice-shaped means in the context of the present invention in particular that lattice meshes 51 between lattice stays 52 are present through which air flow in or air flow out of the interior 3 of the casing 2 is possible, which can be seen best in FIG. 2. The lattice meshes 51 can be preferably embodied rectangular and in particular square. The lattice mesh width 50 in the meaning of the present invention is the largest distance of two parallel extending lattice stays 52 in case of rectangularly arranged lattice stays 52.

[0060] In other forms, for example, triangular or pentagonal lattice meshes, the lattice mesh width is the bisecting line of the surface with the greatest possible extension.

[0061] The aforementioned average lattice mesh width 50 can amount to more than 0.5 mm, preferably at least 1 mm. In this context, the average lattice mesh width 50 is the average value of all same-type lattice meshes of the wall section or the wall.

[0062] The lattice stays 52 of the casing 2 have a thickness of preferably at least 0.8 mm, preferably 1-3 mm.

[0063] The casing 2 can be comprised preferably of plastic material or of a plastic metal combination wherein the metal can be preferably provided as a lattice-shaped wall section.