DE102020101017A1 - Electronic functional unit with a liquid binding element - Google Patents

Abstract

The invention relates to an electronic functional unit, in particular a high-voltage battery (1), with a housing (3), in the housing interior (9) of which electrical components (15, 17) are arranged, and with at least one liquid-binding element (29) whose liquid-binding material ( 37) binds a liquid (31) present in the housing interior (9), for example condensation water or cooling liquid entering the housing interior (9) due to a leak. According to the invention, the liquid-binding material (37) is arranged in a chamber (33) of a container (35) which electrically isolates the liquid-binding material (37) from the electrical components (15, 17) in the housing interior (9).

Description

The invention relates to an electronic functional unit according to the preamble of claim 1 and a liquid binding element for an electronic functional unit according to claim 10.
A generic electronic functional unit, for example a generic electronic functional unit, for example a traction battery for an electrically operated vehicle, has a housing which delimits a housing interior. In the interior of the housing, electrical components are arranged which are to be protected against liquid, such as condensation water or cooling liquid entering the interior of the housing due to leaks. For this purpose, a liquid binding element that binds the liquid is arranged in the interior of the housing.

This has the disadvantage that although the liquid is bound in the liquid binding element, additional measures are required to electrically isolate the liquid binding element with the bound liquid from the electrical components, that is to say for example battery cells.

From the DE 10 2017 105 444 A1 battery pack systems are known which contain a polymer. the WO 2016/128435 A1 discloses a reusable protection device against water leakage. From the WO 2018/001896 A1 a seal against water drainage is known.

The object of the invention is therefore to provide an electronic functional unit in which the operational reliability is increased in a simple manner.

The object is achieved by the features of claim 1 or 10. Preferred developments of the invention are disclosed in the subclaims.

According to claim 1, an electronic functional unit, in particular a high-voltage battery, is provided with a housing, in the interior of which electrical components are arranged, and with at least one liquid-binding element, the liquid-binding material of which binds a liquid present in the interior of the housing, such as condensation or due to leakage cooling liquid entering the interior of the housing. According to the characterizing part of claim 1, the liquid-binding material is arranged in a chamber of a container which electrically isolates the liquid-binding material from the electrical components in the interior of the housing. There is therefore no electrical contact between the liquid-binding material and the liquid bound therein, on the one hand, and the electrical components, on the other hand, so that the operational reliability of the electronic functional unit is increased.

In a preferred embodiment, the liquid-binding material, similar to the function of a diaper or a wound pad, can be a cellulose enriched with polymer salts which is absorbent and superabsorbent with respect to the liquid. This has the advantage that, in relation to the volume of the liquid-binding material, large amounts of liquid can also be absorbed.

The container can preferably have a liquid-retaining effect and / or have at least one liquid inlet, via which the liquid present in the interior of the housing can be fluidically connected to the liquid-binding material. This has the advantage that the liquid does not have to be conveyed to the liquid-binding material, for example by means of a pump, but instead comes into contact with the liquid-binding material without additional energy having to be supplied, for example via the pump.

The liquid present in the interior of the housing collects, in particular due to gravity, on a housing bottom with a liquid level, and in particular the liquid inlet can have a particularly bottom-side container opening, which can preferably be arranged at a height offset at least partially below the liquid level, and / or the container can be arranged at least partially above the liquid level. This advantageously enables vertical installation, in particular in a vertical gap in the interior of the housing, so that the housing, viewed in the vertical axis direction, can be designed in a space-saving manner.

In one embodiment, the liquid inlet can have a suction line which connects to the container opening, with an opening of the suction line in particular dipping into the liquid level. The provision of the suction line has the advantage that the liquid-binding element, in particular the container and the liquid-binding material, can be arranged independently of the liquid level, in particular at a distance from the liquid level and / or outside the interior of the housing, and nevertheless a flow connection via the suction line can be produced between the liquid and the liquid-binding material. The suction line can particularly preferably be a flexible plastic hose. As a result, the suction line can easily be used even in confined spaces laid and, in particular, it must be ensured that the mouth of the suction line reliably protrudes into the liquid.

The liquid inlet can preferably have a flow guiding element, in particular a wick, via which the liquid can be brought into flow connection with the liquid-binding material, the flow guiding element in particular being laid through the container opening and possibly through the suction line. The wick has the advantage that the fluidic connection is additionally optimized due to capillary forces in the wick, so that the flow of the liquid to the liquid-binding material is supported.

Particularly preferably, when it is not in use, the chamber can be subjected to a negative pressure and the liquid inlet can be closed in a pressure-tight manner with a liquid-soluble closure element. In this way, the negative pressure can be used to suck in the liquid located in the interior of the housing.

In a preferred embodiment, the liquid-soluble closure element can be dissolvable on contact with liquid, to be precise with the opening of the liquid inlet, so that the liquid present in the interior of the housing can be sucked into the chamber. This advantageously ensures that no additional measures have to be taken to open the closure element and instead the closure element opens solely through contact with the liquid. In a particularly preferred embodiment, the closure element can be a water-soluble film, such as, for example, a polyvinyl alcohol film.

The liquid-soluble closure element can preferably be arranged directly at the mouth of the suction line. As a result, it is achieved in an advantageous manner that the closure element comes into contact with the liquid and is dissolved by it even with small amounts of liquid on the housing base.

Particularly preferably, the container wall can be formed from at least one pliable and / or elastically flexible film layer. Alternatively or optionally, the liquid-binding material can absorb liquid from the interior of the housing with spatial expansion. In contrast to a rigid container with a higher inherent rigidity than the film layer, the provision of the film layer has the advantage that the container, including the liquid-binding material, when not in use, requires less space than a rigid container and is therefore easy, especially in the interior of the housing, can be brought in.

In a particularly preferred embodiment, the film layer can be produced from an electrically insulating polyethylene film. This has the advantage that the electrical insulation is not achieved by a specific arrangement of the container with respect to the electronic components, but instead additionally or instead by the material of the film layers.

A sufficiently large clearance can preferably be assigned to the container in the interior of the housing, into which the container expands when it absorbs liquid. A sufficiently large clearance is understood in particular to mean that the container can expand to a predefined, maximum extent without coming into contact with other components in the interior of the housing, such as a battery module. The maximum expansion corresponds to the state in which the liquid-binding material is completely saturated and can therefore no longer bind any further liquid. The sufficiently large clearance has the advantage that the spatial expansion of the liquid-binding material is not hindered by neighboring components, in particular not by live components.

Furthermore, a liquid binding element is provided for an electronic functional unit.

• 1 in einer perspektivischen Ansicht eine Hochvoltbatterie mit darin angeordneten Flüssigkeitsbindeelementen in zwei Ausführungsformen;
• 2 in einer perspektivischen Ansicht ein Flüssigkeitsbindeelement;
• 3 in einer Schnittansicht B-B das Flüssigkeitsbindeelement der 2;
• 4 in einer Schnittansicht A-A das in der Hochvoltbatterie vorgesehen Flüssigkeitsbindeelement der 3 in einem Nichtgebrauchszustand ;
• 5 das Flüssigkeitsbindeelement der 4 in einem Gebrauchszustand;
• 6 in einer Schnittansicht gemäß dem Schnitt B-B ein Flüssigkeitsbindeelement gemäß einer weiteren Ausführungsform;
• 7 in einer Schnittansicht gemäß dem Schnitt A-A das in der Hochvoltbatterie vorgesehen Flüssigkeitsbindeelement der 6 im Gebrauchszustand.

An exemplary embodiment of the invention is described below with reference to the accompanying figures. Show it:

• 1 a perspective view of a high-voltage battery with liquid binding elements arranged therein in two embodiments;
• 2 a liquid binding element in a perspective view;
• 3 in a sectional view BB the liquid binding element of 2 ;
• 4th in a sectional view AA the liquid-binding element provided in the high-voltage battery of FIG 3 in a non-use state;
• 5 the liquid binding element of 4th in a use state;
• 6th in a sectional view according to section BB, a liquid binding element according to a further embodiment;
• 7th in a sectional view according to section AA, the liquid-binding element provided in the high-voltage battery of FIG 6th in the state of use.

In the 1 is a high-voltage battery 1 shown. The high-voltage battery 1 has a cuboid housing 3 from a trough-shaped lower part of the housing 5 and a housing cover 7th on which together a housing interior 9 limit. The lower part of the housing 5 has a case back 11 and from it, in the vertical direction of the housing z considered, raised housing side walls 13th on.

Inside the case 9 are made up of several battery cells 15th assembled, cuboid battery modules 17th arranged, of which in the 1 only one is shown as an example. Near the case back 11 is a radiator plate 21 of a cooling system, through which a cooling liquid flows (flow indicated through into the cooler plate 21 arrows leading in and out PF ) and dissipates waste heat in a manner not described in detail that occurs during operation of the battery modules 17th occurs. The radiator plate 21 is over a crack 23 with a gap width a from the case back 11 spaced and via screw connections 25th on the side walls of the housing 13th screwed.

In addition, there are inside the housing 9 Liquid binding elements 29 on the side walls of the housing 13th arranged in the housing interior 9 existing liquid 31 (please refer 5 and 7th ) tie. The liquid 31 can for example be condensation that is in the housing interior 9 forms or be coolant that in the event of a fault from the cooling system, in particular the radiator plate 21 , exit.

In the 2 is the liquid binding element 29 shown. The liquid binding element 29 has a chamber 31 (please refer 3 ) enclosing container 35 and in the chamber 33 arranged liquid-binding material 37 on. The liquid binding element 29 is in a non-use state NZ shown, in which there is still no liquid 31 of the liquid-binding material 37 is bound.

In the 3 is the liquid binding element 29 corresponding to a section BB (see 2 ) shown. The container 35 is made of pliable and resilient film layers 39 , 41 formed in foil edges 43 , 45 are joined together. The film layers 39 , 41 surround that in the chamber 33 arranged liquid-binding material 37 and electrically isolate it from the electrical components 15th , 17th in the housing interior 9 . The container 35 has a liquid-retaining effect and shows in the film layer 41 one of several container openings 47 formed liquid inlet 49 on over which the liquid 31 in fluidic connection with the liquid-binding material 37 occurs and is bound by it.

Based on 4th and 5 is the function of the liquid binding element 29 in a specific installation situation in the high-voltage battery 1 described. The battery module 17th is across a vertical gap VS from the housing side wall 13th spaced, in which the liquid-binding element 29 arranged and on the housing side wall 13th is attached.

the 4th shows the liquid binding element 29 according to section AA (see 1 ) when not in use NZ . When not in use NZ is in the interior of the housing 9 no liquid to bind 31 present and in the liquid-binding material 37 is therefore not a liquid 31 bound.

In the 5 is the liquid binding element 29 is in a state of use GZ shown in which part of the is already on the case back 11 forming a liquid level FS collecting liquid 31 in the liquid-binding material 37 is bound. When binding the liquid 31 the fluid element expands 29 compared to when not in use NZ spatially. So that the liquid-binding material 37 the liquid 31 can bind, the container openings are located 47 in terms of the liquid level FS by a height offset HV partially below and the container 35 partially above the liquid level FS . This causes the liquid to enter 31 via the liquid inlet 49 in fluidic connection with the liquid-binding material 37 and is bound by this. When binding the liquid 31 the liquid-binding element expands 29 in a sufficiently large clearance FG into it, which is located in the interior of the housing 9 is located.

In the 6th Figure 3 is a sectional view of the liquid binding element 29 shown in a further embodiment. The sectional view corresponds to the cutting course of the section BB (see 2 ). The liquid inlet 49 of the liquid binding element 29 is from a container opening 47 and one to the container opening 47 subsequent suction line 55 with a suction line mouth 57 educated. As part of the liquid inlet 49 is also a wick 59 provided within the suction line 55 runs and extends from the suction line mouth 57 up to the chamber 33 extends into it.

In the in 6th shown non-use state NZ of the liquid binding element 29 is the liquid inlet 49 with a liquid soluble film 61 sealed pressure-tight, which is directly at the suction line mouth 57 is arranged. In addition is the chamber 33 with a negative pressure P _u applied.

In the 7th is the liquid binding element 29 in the vertical gap VS arranged and in the state of use GZ shown. The mouth of the suction line 57 is in the liquid level FS immersed so the slide 61 in contact with the liquid 31 is. By contact with the liquid 31 the film comes off 61 on and the liquid inlet 49 is released. After releasing the liquid inlet 49 the negative pressure builds up P _u in the chamber 33 starting, making the liquid 31 into the chamber 33 sucked and from the liquid-binding material 37 is bound.

List of reference symbols

1

High voltage battery

3

casing

5

tub-shaped lower part of the housing

7th

Housing cover

9

Housing interior

11

Case back

13th

Housing side wall

15th

Battery cell

17th

Battery module

21

Radiator plate

23

gap

25th

Screw connection

29

Liquid binding element

31

liquid

33

chamber

35

container

37

liquid-binding material

39, 41

Film layers

43, 45

Foil edges

47

Container opening

49

Liquid inlet

55

Suction line

57

Suction line mouth

59

wick

61

foil

a

Gap width

FG

Clearance

FS

Liquid level

GZ

Usage condition

HV

Height offset

NZ

Not in use condition

PF

Arrows for coolant flowing in and out

Pooh

negative pressure

VS

Vertical gap

z

Housing vertical direction

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 102017105444 A1 [0003]
• WO 2016/128435 A1 [0003]
• WO 2018/001896 A1 [0003]

Claims (10)

Electronic functional unit, in particular high-voltage battery (1), with a housing (3), in the housing interior (9) of which electrical components (15, 17) are arranged, and with at least one liquid-binding element (29) whose liquid-binding material (37) has a liquid (31) present in the housing interior (9) binds, for example condensation water or cooling liquid entering the housing interior (9) due to leakage, characterized in that the liquid-binding material (37) is in a chamber (33) of a container (35) is arranged, which electrically isolates the liquid-binding material (37) from the electrical components (15, 17) in the housing interior (9). Electronic functional unit according to Claim 1 , characterized in that the container (35) has a liquid-retaining effect and / or that the container (35) has at least one liquid inlet (49) via which the liquid (31) present in the housing interior (9) flows with the liquid-binding material (37) is connectable. Electronic functional unit according to Claim 1 or 2 , characterized in that the liquid (37) present in the housing interior (9) collects on a housing base (11) with a liquid level (FS), and that in particular the liquid inlet (49) has a particularly bottom-side container opening (47) which is preferably arranged at least partially below the liquid level (FS) by a height offset (HV), and / or that the container (35) is arranged at least partially above the liquid level (FS). Electronic functional unit according to Claim 3 , characterized in that the liquid inlet (49) has a suction line (55) which connects to the container opening (47), and that in particular a suction line opening (57) of the suction line (55) is immersed in the liquid level (FS) . Electronic functional unit according to Claim 3 or 4th , characterized in that the liquid inlet (49) has a flow guiding element, in particular a wick (59), via which the liquid (31) can be brought into flow connection with the liquid-binding material (37), and in particular the flow guiding element through the container opening ( 47) and, if necessary, is routed through the suction line (55). Electronic functional unit according to Claim 2 until 5 , characterized in that in a non-use state (NZ) the chamber (33) _{is subjected to a negative pressure (P u} ), and that the liquid inlet (49) is sealed pressure-tight with a liquid-soluble closure element (61). Electronic functional unit according to Claim 6 , characterized in that the liquid-soluble closure element (61) is dissolvable on contact with liquid (31), namely by releasing the liquid inlet (49), so that the liquid (31) present in the housing interior (9) into the chamber ( 33) is suckable. Electronic functional unit according to Claim 6 or 7th , characterized in that the liquid-soluble closure element (61) is arranged directly at the suction line mouth (57). Electronic functional unit according to one of the preceding claims, characterized in that the container wall is formed from at least one pliable and / or elastically flexible film layer (39, 41), and / or that the liquid-binding material (37) expands liquid (31) with spatial expansion the housing interior (9), and that in particular the container (35) in the housing interior (9) is assigned a sufficiently large clearance (FG) into which the container (35) expands when liquid is absorbed. Liquid-binding element for an electronic functional unit according to one of the preceding claims.

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