DE102022112645B4 - Fluid line and battery module - Google Patents

Abstract

A fluid line (20), in particular a cooling fluid line for a battery module (10), is specified, with at least a first and a second line section (22, 24) which are plugged into one another, one end of a line section (22) having a socket part (26). and one end of a line section (24) coupled thereto is a plug part (28) which is inserted into the socket part (26), with a sealing ring (30) having a cylindrical shape radially between the socket part (26) and the plug part (28). Base body (32) is arranged, with at least one sealing lip (38, 40) inclined to the base body (32) protruding from an inside (34) and an outside (36) of the cylindrical base body (32), and wherein the base body (32) of the sealing ring (30) has a support section (37) on one end face, which is designed to be supported axially on the socket part (26). Furthermore, a battery module (10) is specified.

Description

The invention relates to a fluid line, in particular a cooling fluid line for a battery module, and a battery module.

Battery modules with a large number of battery cells usually have to be cooled in order to avoid excessive heating of the battery cells, even during long-term operation.

It is known to provide actively cooled cooling plates for this purpose, against which the battery cells rest. In order to supply the cooling plates with coolant, fluid lines with line sections that are plugged into one another are provided.

The line sections must be reliably sealed from one another in order to prevent coolant from escaping. At the same time, tolerance compensation should be possible between the line sections that are inserted into one another.

However, the known solutions only inadequately meet these requirements. In particular, leaks can occur if the tolerance position is unfavorable, so that high manufacturing precision is required in known solutions, which, however, increases the manufacturing effort.

The DE 21 12 798 A discloses a sealing ring for plug-in connections of pipes, which has sealing lips that protrude laterally.

The DE 10 2017 106 200 A1 describes a plastic exhaust sleeve pipe with a pipe body in which an annular seal designed as a lip seal is arranged.

It is therefore an object of the present invention to provide a fluid line that enables the greatest possible tolerance compensation and at the same time a reliable seal.

This object is achieved according to the invention by a fluid line, in particular a cooling fluid line for a battery module, with at least a first and a second line section that are plugged into one another, one end of a line section being a socket part and one end of a line section coupled thereto being a plug part which is in the socket part is inserted, a sealing ring with a cylindrical base body being arranged radially between the socket part and the plug part, with at least one sealing lip inclined to the base body protruding from an inside and an outside of the cylindrical base body, and the base body of the sealing ring on one end face has a support section which is designed to be axially supported on the socket part.

Improved tolerance compensation is possible thanks to two oppositely projecting sealing lips. In particular, tolerances of up to 3 mm in the radial direction can be compensated for without negatively affecting the sealing effect of the sealing ring. Specifically, tolerance compensation can be made on both sides of the sealing ring.

At least one channel is formed between the end face of the base body, which rests on the socket part, and a sealing lip closest to the end face, which extends from the inside to the outside of the base body. This allows fluid to flow from the inside to the outside of the base body, whereby the sealing effect is self-reinforced by the prevailing fluid pressure. Specifically, the fluid pressure causes the sealing lip on the outside of the base body to be pressed more strongly against the socket part, which improves the sealing effect.

For example, there is a system pressure of up to 8 bar, in particular 2 bar, in the fluid line.

The at least one channel can be formed by a recess in the support section. In this way, the channel can be removed from the mold particularly easily when producing the sealing ring as an injection-molded part.

According to one embodiment, the sealing ring is axially fixed on the socket part. As a result, the sealing ring is permanently and reliably held in the fluid line and cannot be pushed out of the line by the fluid pressure.

For example, a fixing element is plugged onto the socket part, which has at least one stop surface which is located radially further inside than the inner circumference of the socket part. The installation of the sealing ring in the socket part is not made more difficult by the presence of the axial fixation, since the fixing element can be plugged on after the sealing ring has been installed.

The fixing element can be locked on the socket part. This means that the fixing element is automatically fixed when it is plugged onto the socket part, and no separate fastening means are necessary.

According to one embodiment, exactly one sealing lip protrudes from the inside of the base body and exactly two sealing lips protrude from the outside of the base body. In this embodiment, the risk of damage to the sealing ring during demolding is particularly low.

The base body preferably has an insertion bevel on one end face, in particular on an end face directed away from the socket part, which merges linearly into the inclined sealing lip on the inside of the sealing ring. In other words, the inclination of the sealing lip continues in the insertion slope. In this way, a particularly wide insertion bevel is achieved, whereby the plug part can be easily inserted into the socket part even with an unfavorable tolerance position, for example if there is a radial offset between a central axis of the socket part and a central axis of the plug part.

The sealing ring is preferably formed from an elastic material and a reinforcing element which has a higher rigidity than the elastic material can be embedded in the base body of the sealing ring. The reinforcing element stabilizes the base body and prevents the base body of the sealing ring from bending due to the fluid pressure or during assembly.

According to one embodiment, the profile of the sealing ring can be asymmetrical, in particular with the at least one sealing lip projecting outwards from the base body being longer than the sealing lip projecting inwards from the base body. This results in improved stability when inserting the plug part. More precisely, the sealing ring is supported stably on the socket part even if the tolerance position is unfavorable, so that the sealing ring does not tilt when the plug part is inserted.

The object is further achieved according to the invention by a battery module with a plurality of battery cells, a cooling system which has a plurality of actively cooled cooling plates, on which battery cells rest on both sides and which have a fluid inlet and a fluid outlet arranged concentrically to the fluid inlet, between two adjacent ones Cooling plates each have a fluid line according to the invention arranged in such a way that the socket part is fastened in a fluid-tight manner at the fluid inlet or at the fluid outlet of a cooling plate and the plug part of the fluid line is fastened in a fluid-tight manner at the opposite fluid inlet or fluid outlet of the adjacent cooling plate. The active cooled fluid plates can thus be connected to one another in series, with a particularly reliable seal being achieved by means of the fluid line according to the invention.

• - 1 ein erfindungsgemäßes Batteriemodul,
• - 2 einen Schnitt durch erfindungsgemäße Fluidleitungen eines Batteriemoduls in einem unvollständig montierten Zustand,
• - 3 einen Schnitt durch erfindungsgemäße Fluidleitungen eines Batteriemoduls in einem montierten Zustand,
• - 4 einen Dichtring einer erfindungsgemäßen Fluidleitung in einem Buchsenteil,
• - 5 einen Dichtring einer erfindungsgemäßen Fluidleitung in einer perspektivischen Ansicht,
• - 6 den Dichtring aus 5 in einer weiteren perspektivischen Ansicht,
• - 7 einen Querschnitt durch eine erfindungsgemäße Fluidleitung,
• - 8 einen Querschnitt durch eine weitere erfindungsgemäße Fluidleitung,
• - 9 einen Querschnitt durch eine wiederum weitere erfindungsgemäße Fluidleitung, und
• - 10 einen Querschnitt durch eine wiederum weitere erfindungsgemäße Fluidleitung.

Further advantages and features of the invention emerge from the following description and from the accompanying drawings, to which reference is made. Shown in the drawings:

• - 1 a battery module according to the invention,
• - 2 a section through fluid lines according to the invention of a battery module in an incompletely assembled state,
• - 3 a section through fluid lines according to the invention of a battery module in an assembled state,
• - 4 a sealing ring of a fluid line according to the invention in a socket part,
• - 5 a sealing ring of a fluid line according to the invention in a perspective view,
• - 6 the sealing ring 5 in another perspective view,
• - 7 a cross section through a fluid line according to the invention,
• - 8th a cross section through a further fluid line according to the invention,
• - 9 a cross section through another fluid line according to the invention, and
• - 10 a cross section through another fluid line according to the invention.

1 shows a part of a battery module 10. For example, the battery module 10 is intended for use in a vehicle, in particular a passenger motor vehicle or a commercial vehicle.

The battery module 10 has a large number of battery cells 12 and actively cooled cooling plates 14. Active cooling means that a fluid flows through the cooling plates 14, with which heat can be removed from the battery module.

The battery cells 12 lie on both sides of the cooling plates 14.

The cooling plates 14 have a fluid inlet 16 and a fluid outlet 18 arranged concentrically to the fluid inlet 16 (see also 2 ).

A fluid line 20 is arranged between two adjacent cooling plates 14.

Each fluid line 20 comprises a first line section 22 and a second line section 24, which are plugged into one another. One end of a line section is a socket part 26 and one end of a line section 24 coupled to this is a plug part 28 which is inserted into the socket part 26. This means that the socket part 26 and the plug part 28 are each integrally formed in a line section 22, 24.

In the exemplary embodiment, the socket part 26 is fastened in a fluid-tight manner at the fluid inlet 16 of a cooling plate 14 and the plug part 28 is fastened in a fluid-tight manner at the opposite fluid outlet 18 of the adjacent cooling plate 14. Alternatively, the socket part 26 can be attached to the fluid outlet 18 and the plug part 28 to the fluid inlet 16 in a fluid-tight manner.

The fluid-tight attachment is achieved, for example, by gluing.

A sealing ring 30 is arranged radially between the socket part 26 and the plug part 28, as shown in FIG 2 until 4 and 7 shown. The sealing ring 30 serves to seal the line sections 22, 24 relative to one another. At the same time, the sealing ring serves to compensate for tolerances, in particular a radial offset between the line sections 22, 24.

The sealing ring 30 is in the 2 until 7 to see.

In particular, it can be seen from the sectional views that the sealing ring 30 has a cylindrical base body 32.

In the exemplary embodiment according to 2 until 7 Two sealing lips 38, 40 inclined to the base body 32 protrude from an inside 34 and an outside 36 of the cylindrical base body 32.

The sealing lips 38, 40 are in particular inclined in such a way that the free ends of the sealing lips 38, 40 are directed towards a bottom of the socket part 26.

The base body 32 of the sealing ring 30 has a support section 37 on one end face, which is designed to be supported axially on the socket part 26, as shown in FIGS 2 until 4 and 7 is illustrated.

In the exemplary embodiment, the support section 37 is widened compared to the base body 32, which results in an enlarged support area.

On an end face opposite the support section 37, the base body 32 has an insertion bevel 42 which merges linearly into the inclined sealing lip 38 on the inside 34 of the sealing ring 30.

The profile of the sealing ring 30 is asymmetrical. In particular, the sealing lips 40 projecting outwards from the base body 32 are longer than the sealing lips 40 which project inwards from the base body 32.

The sealing ring 30 is made of an elastic material, for example EPDM.

2 illustrates an assembly step when assembling the battery module 10, in particular the insertion of the plug part 28 into the socket part 26.

In this state, the sealing ring 30 is already pre-assembled on the socket part 26 and axially fixed on the socket part 26.

In the exemplary embodiment, the axial fixation takes place by means of a fixing element 44 which is plugged onto the socket part 26.

The fixing element 44 has a stop surface 46, which is formed by a collar projecting radially inwards from an annular base body 48 of the fixing element 44.

The stop surface 46 is in particular radially further inward than the inner circumference of the socket part 26.

In the exemplary embodiment, the fixing element 44 has integrally shaped locking elements 50, by means of which the fixing element 44 is locked on the socket part 26.

When the plug part 28 is inserted into the socket part 26, as in the 2 and 3 is illustrated, the sealing lips 40 of the sealing ring 30 are deformed and thus ensure a reliable seal of the line sections 22, 24.

The insertion bevel 42 supports the insertion of the plug part 28.

The asymmetrical design of the profile of the sealing ring 30 also prevents the sealing ring 30 from tilting when the plug part 28 is inserted.

If the plug part 28 is inserted into the in 3 has been moved to the position shown, assembly is complete.

To optimize the sealing effect of the sealing ring 30, several, in particular four, channels 52 are provided, which extend from the inside 34 to the outside 36 of the base body 32 (see 6 ).

In the exemplary embodiment, the channels 52 are each formed by a recess 54 in the support section 37.

However, the channels 52 can also be at a different position between the end face of the base body 32, which rests on the socket part 26, and a sealing lip 38, 40 closest to the end face.

As in 7 As illustrated by arrows, fluid flows through the channels 52 from the inside 34 to the outside 36 of the sealing ring 30, with the fluid pressure self-reinforcing the sealing effect.

Because of the fluid pressure, the sealing lips 38, 40 tend to stand up. Since this is not possible due to the space available, the sealing lips 38, 40 are pressed even more strongly against the socket part 26 or the plug part 28 by the fluid pressure than is the case due to the elastic deformation of the sealing ring 30 during assembly.

Claims (10)

Fluid line (20), in particular cooling fluid line for a battery module (10), with at least a first and a second line section (22, 24), which are plugged into one another, one end of a line section (22) having a socket part (26) and one end of a This coupled line section (24) is a plug part (28) which is inserted into the socket part (26), a sealing ring (30) with a cylindrical base body (32) being arranged radially between the socket part (26) and the plug part (28). is, wherein at least one sealing lip (38, 40) which is inclined to the base body (32) protrudes from an inside (34) and an outside (36) of the cylindrical base body (32), and wherein the base body (32) of the sealing ring (30) has a support section (37) on one end face, which is designed to be supported axially on the socket part (26), between the end face of the base body (32), which rests on the socket part (26), and a sealing lip closest to the end face (38, 40) at least one channel (52) is formed, which extends from the inside (34) to the outside (36) of the base body (32). Fluid line (20). Claim 1 , characterized in that the at least one channel (52) is formed by a recess (54) in the support section (37). Fluid line (20) according to one of the preceding claims, characterized in that the sealing ring (30) is axially fixed on the socket part (26). Fluid line (20). Claim 3 , characterized in that a fixing element (44) is plugged onto the socket part (26), which has at least one stop surface (46) which is located radially further inwards than the inner circumference of the socket part (26). Fluid line (20). Claim 4 , characterized in that the fixing element (44) is locked on the socket part (26). Fluid line (20) according to one of the preceding claims, characterized in that exactly one sealing lip (38) projects from the inside (34) of the base body (32) and exactly two sealing lips (40) protrude from the outside (36) of the base body (32). stand out. Fluid line (20) according to one of the preceding claims, characterized in that the base body (32) has an insertion bevel (42) on one end face, which merges linearly into the inclined sealing lip (38) on the inside (34) of the sealing ring (30). . Fluid line (20) according to one of the preceding claims, characterized in that the sealing ring (30) is formed from an elastic material and a reinforcing element (56) which has a higher rigidity than the elastic material is embedded in the base body (32) of the sealing ring . Fluid line (20) according to one of the preceding claims, characterized in that the profile of the sealing ring (30) is asymmetrical, in particular wherein the at least one sealing lip (40) projecting outwards from the base body (32) is longer than that of the base body (32). inwardly projecting sealing lip (38). Battery module (10) with a plurality of battery cells (12), a cooling system which has a plurality of actively cooled cooling plates (14) on which battery cells (12) rest on both sides and which have a fluid inlet (16) and one concentric to the fluid inlet (16 ) arranged fluid outlet (18), wherein between two adjacent cooling plates (14) a fluid line (20) according to one of the preceding claims is arranged, such that the socket part (26) at the fluid inlet (16) or at the fluid outlet (18). Cooling plate (14) is fastened in a fluid-tight manner and the plug part (28) of the fluid line (20) is fastened in a fluid-tight manner at the opposite fluid inlet (16) or fluid outlet (18) of the adjacent cooling plate (14).

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