DE102014215031A1 - Novel sealing flange for HV storage with integrated EMC seal - Google Patents

Abstract

Housing device (G) for an electrochemical energy storage device, in particular for use in a motor vehicle, having a first and a second housing component (1, 2), wherein these two housing components (1, 2) are connectable to each other and, wherein the first housing components (1) a contacting region (1.3) and the second housing component (2) has a mating contact region (2.3) and wherein the contacting region (1.3) and the mating contact region (2.3) are adapted to contact each other at least along a contact line (KL) and extending, in each case starting from a cross-sectional area (Q.1, Q.2), which is arranged orthogonal to the contact line (KL), along the contact line (KL), characterized in that the contacting region (1.3) and the mating contact region (2.3 ) in the direction normal to a tangential plane to these areas, at least to a portion of the contact line (KL), a rigidity difference that the stiffness difference is at least 10%.

Description

The present invention relates to a housing according to the preamble of patent claim 1 and a method for producing such a housing according to the preamble of patent claim 9.

Such a housing or a method for its production is known from DE 10 2008 059 956 A1 known.

The invention will be described below with reference to an electrochemical energy storage device for a motor vehicle, this is not to be understood as a restriction. Electrochemical energy storage devices typically have reactive components and it is therefore necessary to protect these ingredients from interactions, particularly from the uncontrolled leakage of these into the environment and from the entry of foreign matter into the electrochemical energy storage device. Further, it is desirable to shield such devices electromagnetically to reduce interference, the like measures are known under the heading of electromagnetic compatibility (EMC). Electrochemical energy storage devices have housings, which also fulfill the task of protecting this device from mechanical influences.

From the DE 10 2008 059 956 A1 a device is known in which a plurality of electrochemical energy storage cells is surrounded by a housing. This housing prevents the uncontrolled and unplanned discharge of ingredients of the electrochemical storage cells.

It is an object of the invention to provide a housing for an electrochemical energy storage device with increased reliability and a manufacturing method for such a housing.

For the purposes of the invention, a housing device is to be understood as a device which completely, but at least partially, surrounds an electrochemical energy storage device, preferably a large number of electrochemical energy storage devices. In this case, such a housing device is in particular adapted to keep mechanical influences, such as pressure or impact loads, vibrations and the like away from the electrochemical energy storage device, or at least to reduce their influence. Furthermore, the housing device is also set up to reduce or prevent the unplanned discharge of ingredients from the housing interior into the environment surrounding the housing device or the entry of foreign substances from this environment into the housing device.

Electrochemical energy storage devices typically have highly reactive ingredients, so this prevention of unscheduled leakage or ingress of materials is safety relevant to the operation of the electrochemical energy storage device. In particular in order to achieve good mountability of the electrochemical energy storage device, a housing device often has at least two housing components, but these two housing components can also be connected in one piece by means of a hinge device.

For the purposes of the invention, a housing component is to be understood as a section of this housing device, in particular a thin-walled, three-dimensional component. In particular, the housing device has at least two housing components, while these housing components bear in a first, so-called. Unmounted, state and can be transferred by a mounting method in a second, so-called. Assembled state. In particular, in the assembled state, the housing components surround the electrochemically active section, preferably at least one or a plurality of lithium ion storage cells, partially or preferably completely.

For the purposes of the invention, an electrochemical energy storage device is a device in which energy can be stored in chemically bound form. Furthermore, this chemically bound energy can be converted and emitted by the electrochemical energy storage device into electrical energy (voltage, current). In particular, an electrochemical energy storage device is to be understood as meaning a lithium-ion accumulator and has a plurality of memory cells, in particular interconnected with one another. An electrochemical energy storage device is preferably a so-called high-voltage accumulator, in particular for use in a motor vehicle. For the purposes of the invention, a high-voltage storage means an electrochemical energy storage device which provides at its connection terminals a voltage of at least 48 volts, preferably of at least 100 volts and more preferably of at least several 100 volts. Further preferably, this high-voltage accumulator is used to supply energy to an electric drive motor for a traction drive of a motor vehicle. For the purposes of the invention, a motor vehicle is preferably a Road-bound vehicle, particularly preferred to understand a passenger car.

The first and the second housing component have a contacting region and a mating contact region. For the purposes of the invention, such areas are to be understood as areas of the housing components which are adapted to touch, in particular in the mounted state, of these, or to contact one another. Preferably, the contacting and the mating contact area touch at least along a contact line, more preferably, these areas touch each other in a contact surface. More preferably, the contact line is to be understood as a closed around the housing means line, particularly preferably the contact surface is to be understood as a closed around the housing means circulating belt or a circumferential strip around the housing means.

Preferably, the contacting and the mating contact area are to be understood as a three-dimensional section of the respective housing component, and these areas have a cross-sectional area which is arranged orthogonal to the contact line. Preferably, the contacting and mating contact areas are formed as an extrusion when the cross-sectional area is displaced along the line of contact. The contacting region and additionally or alternatively the mating contact region along the contact line preferably has a variable cross-sectional area.

According to the invention, the contacting region and the mating contact region touch along at least the contact line. If a contact plane is arranged in the region of the contact line which is tangential to the surface of the contacting region and tangent to the surface of the mating contact region, then the contacting region and the mating contact region have a stiffness difference in the direction normal to this surface. In particular, this stiffness difference, at least substantially, only one of the two areas during assembly of the two housing components, ie when transferring the unmounted in the assembled state, deformed. In contrast, the other of the two areas is at least less strongly or substantially not deformed.

By this difference in stiffness, it is particularly achievable that the more easily deformable region adapts to the more rigid region and thus a particularly secure contact of the two regions is guaran teed together. According to the invention, this difference in stiffness is at least 10%.

For the purposes of the invention, a difference in stiffness of at least 10% is understood to mean that one of the two regions acts under a contact force acting on the contact line, ie a force acting on the contact line normal to the surfaces of the contacting region and the mating contact region Direction of the force effect deformed by 10% more than the stiffer each of the two Kontaktierungsbereiche. More preferably, the stiffness difference is at least 15%, preferably at least 20%, and most preferably at least 25%.

In particular, by such a stiffness difference, it is possible on the one hand, that one of the two areas (contact area, mating contact area) on the other, ie on the stiffer of the two adapts, and further leads the choice of stiffness difference, as proposed, to a sufficiently large contacting force is present and the housing device is therefore particularly secure closed.

In a preferred embodiment, the inside and more preferably the contacting and mating contact area of at least one of the two housing components, preferably both housing components, an electrically conductive surface. Preferably, the two housing components, at least substantially, completely coated with an electrically conductive coating. In a preferred embodiment, at least one of the housing components, preferably both, on the inside and more preferably in the contacting and mating contact area, a metallic coating with a metal foil. Further preferably, at least one housing component, preferably both housing components, is vapor-deposited with a metal vapor in said regions, and therefore have a metallically conductive inner surface. In particular, by this electrically conductive surface on the housing components on the one hand an improvement in the sealing effect of the housing device can be achieved and further is an improved electromagnetic shielding of the housing device, increasing the EMC, representable. In this case, this electromagnetic shield is further improved, in particular by the contacting region according to the invention.

In a preferred embodiment, the first housing component has a sealing area and the second housing component has a counter-sealing area, and these areas are preferably designed, at least in sections, according to the tongue and groove principle. The spring area is preferably arranged on the first housing component and the groove area is arranged on the second housing component. To a sealing effect between the first housing part and the second To improve housing component, preferably engages the spring portion in the groove area. Preferably, the sealing area and the counter-sealing area are arranged on the side facing away from the inside of the housing components side. Further preferably, the sealing area and the counter-sealing area extend in the same direction as the contacting area and the mating contact area. Further preferably, the seal and the counter-sealing area are designed as an area surrounding the housing device. The tongue and groove principle is a frequently used principle in the connection of components and in particular a particularly good sealing effect can be achieved with this connection principle, and thus an improved housing device can be provided.

In a preferred embodiment, a sealing element is arranged in the counter-sealing area. Preferably, the counter-sealing area is arranged on the second housing component. Further preferably, the counter-sealing area is designed according to the groove principle. Preferably, a sealing element is to be understood as a rubber or rubber sealing element. Further preferably, such a sealing element as at least one component to an elastomer. Further preferably, the sealing element in liquid or viscous state in the counter-sealing area can be introduced. Further preferably, the sealing element is designed as, in particular initially liquid, sealing foam. Further preferably, a liquid or viscous sealing element hardens under the influence of atmospheric oxygen, UV light, heat or due to a chemical reaction. In particular, by the arrangement of a sealing element at least in the counter-sealing area, a further increase in the sealing effect of the housing device can be achieved, and so an improved housing device can be displayed.

In a preferred embodiment, the first housing component has a first connection element and the second housing component has a second connection element. Preferably, the two housing components can be connected to one another by means of these connecting elements. Further preferably, the housing device has at least a third connecting element. For the purposes of the invention, a third connecting element is preferably to be understood as meaning a screw, preferably a rivet or, more preferably, a pin. Further preferably, the first connecting element is designed as a first latching element and the second connecting element as a second latching element. Further preferably, the first connection element is designed as a latching hook and the second connection element as a recess which is adapted to receive the first connection element. In particular, by connecting the two housing components by means of a latching and counter-latching element (Rasstverbindung) is a particularly secure connection of the two housing components can be achieved with each other and thus an improved housing device can be displayed.

In a preferred embodiment, the first housing component has a first connection element and the second housing component has a second connection element. Preferably, these connecting elements are designed as a recess, preferably as an at least partially groove-shaped recess. Further preferably, a third connecting element for contacting the first and second connecting element is set up. The third connecting element is preferably as an elastically deformable connecting element, preferably as a connecting element with a partially or completely C-shaped configuration. Preferably, this third connection element is adapted to contact the ends of the C-shaped section of the first and second connection element. In particular, the third connecting element contacts the first and second housing component such that a normal force, in particular orthogonal to a parting plane between the first and second housing component, can be transmitted by the latter. The third connecting element has as a component preferably in sections or preferably completely preferably a metallic material, preferably a steel material and particularly preferably a spring steel, or preferably consists of this. In particular, by a third connecting element is a particularly secure holding the first and second housing component can be displayed to each other and thus an improved housing device can be reached.

Preferably, the first and the second housing component is pressed together by the latching connection or by the third connecting element with the normal force, this normal force is preferably orthogonal to a parting plane between the first and second housing component.

In a preferred embodiment, a normal force can be transferred between the first and the second housing component in order to securely fix these components to one another in the mounted state. Preferably, this normal force can be applied by one or more of said connecting elements. Preferably, a smaller part of this normal force is proportionally transmitted via the sealing element and a larger part can be transferred by further housing sections. Preferably, a further housing section means a shoulder, a step, a projection, an extension or the like. Preferably, the transferable via the sealing element share of Normal force less than 50%, preferably less than 35%, more preferably less than 25% and most preferably less than 10%. In particular, by this smaller, transferable by the sealing element portion of the normal force, the tendency to set this and a loosening of the connection between the first and second housing member is reduced.

In a preferred embodiment, the first housing component has a higher rigidity in the region of at least the contact lines than the second housing component. In this case, the first housing component in the region of this contact line at least one, but preferably a plurality of, stiffening ribs. These stiffening ribs extend at least on the outer surface of the first housing device and at least up to the level of the contact line or the contact surface. In particular stiffening ribs lead to an increase in rigidity with low material usage and so is a particularly rigid and lightweight housing component can be displayed and thus an improved housing device achievable.

In a preferred embodiment, a tangential plane to the surface of the second housing component at the location of the contact line in the unmounted state, a first inclination α, with respect to an imaginary vertical plane. Next, this tangential plane has a second inclination β in the mounted state of the two housing components. The inclination difference Δ of these two inclinations α and β is selected according to the invention from a certain angular range. For this angular range, Δ> 0.5 °, preferably> 1 °, preferably> 2 ° and particularly preferably> 5 ° and further Δ <45 °, preferably <15 °, preferably <10 ° and particularly preferably <7, 5 °. Investigations have shown that, in particular, such a difference in inclination enables secure contacting of the contacting and mating contact regions on the one hand and, on the other hand, ensures easy mounting of the two housing components. In particular, by the choice of the angular difference Δ thus an improved housing device can be displayed.

• – Bereitstellen des ersten und des zweiten Gehäusebauteils,
• – Zusammenfügen des ersten und zweiten Gehäusebauteils, so dass sich zwischen diesen wenigstens eine Kontaktlinie ausbildet.

A manufacturing method for a housing device according to the invention comprises at least the steps

• Providing the first and second housing components,
• - Assembling the first and second housing component, so that forms at least one contact line between them.

Preferably, the first and second housing component are joined together in such a way that the second housing component is arranged at least in sections, preferably in the region of the mating contact area within the first housing component. Preferably, the contact line or the contact surface encloses a parting plane between the first and second housing component.

When the housing components are assembled, these first and second housing components are moved relative to one another in a direction that is oriented orthogonally to the parting plane. In particular, by this type of assembly of the first and second housing component is a particularly simple and thus error-prone in particular mounting manner achievable and thus an improved housing device can be displayed.

In a preferred embodiment of the method for producing the sealing element is introduced in one of the housing components. Preferably, this sealing element is introduced before joining the first and the second housing component. Further preferably, this sealing element is received in the second housing component, particularly preferably in the counter-sealing area, in particular in a groove in the counter-sealing area. Further preferably, the sealing element is introduced as a liquid or viscous sealant in this housing component. Preferably, the sealing element is inserted as a sealing ring or sealing cord in the second housing component. In particular, by the introduction of the sealing element, a particularly high quality of the connection between the first and second housing component and thus an improved housing device can be achieved.

The figure with the partially schematized figures will be explained in more detail below. Show it:

1 a perspective sectional view of the connection area between the first and second housing component,

2 a partial section of this connection area with surface coating,

3 perspective partial sections of the connection area,

4 Partial sections of the housing components in the unmounted and assembled state.

1 shows a three-dimensional section of the housing device G. In this case, the housing device G has a first housing component 1 and a second housing component 2 on. The two housing components 1 and 2 touch each other in a contacting area 10 , In this case, the first housing component 1 a contacting area 1.3 and the second housing component 2 a mating contact area 2.3 on. Next points the first housing component 1 a sealing hole 1.4 and the second housing component 2 a mating area 2.4 on. In the mision area 2.4 is a sealing element, in this case a permanently elastic sealing cord 3 inserted. The first housing component 1 has a stiffening rib in the area or at the level of the contacting area 1.2 on. The two housing components 1 . 2 are with snap connections 20 connected with each other. In this case, the housing component 1 latch hook 1.1 and the housing component 2 Counter-locking elements 2.1 on. The latching connection is designed such that on the sealing element 3 through the housing component 1 , in particular with its sealing area 1.4 a permanent pressure is exerted. In the contact area between the housing component 1 and 2 is also a contact line not shown arranged. The cross-sectional areas Q.1 and Q.2 of the first and second housing component 1 . 2 describe the cross-section of the housing components at least in the region of the contacting region 10 , Also the second housing component 2 has a stiffening rib 2.5 , similar to the stiffening rib 1.2 on. Here is the stiffening rib 2.5 not in the area of contacting 10 arranged, but serves to support the counter seal area 2.4 The marked D area of the two housing components 1 . 2 is in 2 further illustrated.

2 shows the cross-sectional area Q1 and Q2 of the two housing parts 1 . 2 , Next is the sealing element 3 shown. The contacting area 1.3 of the housing component 1 exerts a contact force FK on the mating contact area 2.3 of the housing component 2 and causes an equal reaction force FK. The mating contact area 2.3 has a lower rigidity in the direction of force FK than the contacting area 1.3 of the first housing component 1 , This lower rigidity, or this stiffness difference, leads to a deformation D.2 of the second housing component 2 , The contact line KL may be any line within the contact area between the first housing component 1 and the second housing component 2 be understood. The arrows marked I and A point once inwards (I) and once outwards (A) with respect to the housing means. The electrochemical energy storage device (not shown) is located in the housing, ie in the direction I. The sealing area 1.4 of the first housing component 1 contacted to seal the housing, the sealing element 3 , The first housing component has a coating L.1 and the second housing component has a coating L.2. The coatings L.1 and L.2 are designed as electrically conductive coatings, in particular as metal vapor deposition of the first and second housing component. The coatings L.1 and L.2 extend on the housing components 1 . 2 at least up to the contacting area between these two components. In particular, by the stiffness difference of the two housing components 1 . 2 in the contact area between the areas 1.3 and 2.3 leads to a particularly good EMC shielding.

In 3a is a perspective view of the section with the contacting area 1.3 and the mating contact area 2.3 the first and second housing component 1 . 2 shown. In this case, the first housing component 1 a sealing area 1.4 on and the second housing component 2 a mating area 2.4 , The mating area 2.4 is configured groove-shaped, and for receiving the sealing element 3 set up. The sealing element 3 is as a liquid foam seal in the groove 2.4 brought in. By contacting the sealing element 3 by means of the sealing area 1.4 this will be in the groove 2.4 pressed in and achieved a particularly good sealing effect. The second housing component has on its surface at least in sections the coating L.2. Also, the first housing component has a coating, this is not shown in the view shown.

3 shows a perspective sectional view of the housing components 1 . 2 , These housing components are connected to each other by means of a screw V.1. The first housing component 1 has a sealing area 1.4 up, this protrudes into the groove 2.4 of the second housing component 2 and thereby contacts the sealing element 3 , The insides of the first and second housing components 1 . 2 each have a coating L.1 and a coating L.2. In this case, the coatings L.1 and L.2 each extend into the contacting region between the components 1 . 2 and thus achieve a particularly good EMC shielding.

3c shows a perspective sectional view of the housing components 1 . 2 , these housing components 1 . 2 are connected to each other by means of a clamping connection with a third connecting element V.2. The housing components 1 . 2 are designed so that in the assembled state for connecting the first and second housing component 1 . 2 applied normal force is transmitted in different areas. A first part of the normal force is via the sealing element 3 and the contacting this housing sections 1.4 . 2.4 transferred and another part, wherein this further part of the normal force is more than 50% of the normal force, which in this further section 30 the housing components 1 . 2 is transmitted (main power flow). In this case, the main power flow HF occurs via the further housing sections 30 , Due to this low load on the sealing element 3 is the tendency of setting the sealing element 3 reduces and it is thus a nearly constant secure connection of the housing components 1 . 2 reached.

In particular, this avoids that sets over life, the seal and the clamp connection is loosened. The first housing component 1 has a sealing area 1.4 up, this protrudes into the groove 2.4 of the second housing component 2 and thereby contacts the sealing element 3 , The insides of the first and second housing components 1 . 2 each have a coating L.1 and a coating L2. In this case, the coatings L.1 and L.2 each extend into the contacting region between the components 1 . 2 and thus achieve a particularly good EMC shielding.

In 3d is a perspective view of in 3c shown connection shown. It can be seen as the C-shaped bracket V.2 housing components 1 . 2 contacted and how thereby one hand, the sealing element 3 compressed and the other housing sections 30 pressed on each other.

4a) shows a partial section of the first and second housing component ( 1 . 2 ) in the unmounted state and 4b) in the assembled state. It shows 4 Housing components like these in the 1 - 3 are shown and it will be discussed below mainly differences and in particular the angles α and β.

Through the stiffening rib 1.2 has the first housing component 1 a higher rigidity than the second housing component 2 in the same place in the assembled state. The second housing component 2 , but especially its section 2.3 , In the unassembled state has an inclination α. In assembled condition ( 4b ) increases this inclination to the angle β, this is due to the stiffness difference of the two housing components 1 . 2 justified in this area. The elasticity of the second housing component 2 in the area 2.3 calls a contact force in the area 10 resulting in the formation of a contact line or area. Due to the conductive coating of the housing components in this area and the described secure pressing a particularly good EMC shielding is achieved.

In 5 is a full section of the housing device with first and second housing component 1 . 2 shown in perspective view. On the one hand, the fundamental mode of action RHV of the transmitted normal force between the first and second housing components is shown. And it is the location VB of in 1 to 4 illustrated connection areas between the housing components 1 . 2 shown. Next is the location of the sealing element 3 and the connecting element V.2 and the other housing sections 30 recognizable.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been 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.

Cited patent literature

• DE 102008059956 A1 [0002, 0004]

Claims (12)

Housing device (G) for an electrochemical energy storage device, in particular for use in a motor vehicle, having a first and a second housing component ( 1 . 2 ), these two housing components ( 1 . 2 ) are connectable to each other and, wherein the first housing components ( 1 ) a contacting area ( 1.3 ) and the second housing component ( 2 ) a mating contact area ( 2.3 ) and wherein the contacting region ( 1.3 ) and the mating contact area ( 2.3 ) are arranged to contact each other, at least along a line of contact (KL), and, in each case starting from a cross-sectional area (Q.1, Q.2), which is arranged orthogonal to the contact line (KL), along the contact line (KL), characterized in that the contacting region (KL) 1.3 ) and the mating contact area ( 2.3 ) in the direction normal to a tangential plane to these regions, at least to a portion of the contact line (KL), have a stiffness difference such that the stiffness difference is at least 10%. Housing device according to claim 1, characterized in that at least the inside of the first and second housing component ( 1 . 2 ), at least in sections, an electrically conductive surface (L.1, L.2) have. Housing device according to one of the preceding claims, characterized in that the first housing component ( 1 ) a sealing area ( 1.4 ) and the second housing component ( 2 ) a mating area ( 2.4 ) that these areas ( 1.4 . 2.4 ), at least in sections, are designed according to the tongue and groove principle. Housing device according to claim 3, characterized in that in the counter-sealing area ( 2.4 ) a sealing element ( 3 ) is arranged, that this sealing element ( 3 ) from the sealing area ( 1.4 ) is contactable. Housing device according to one of the preceding claims, characterized in that the first housing component ( 1 ) a first connecting element ( 1.1 ), that the second housing component ( 2 ) a second connecting element ( 2.1 ) having. Housing device according to claim 5, characterized in that the first and second connecting element ( 1.1 . 2.1 ) are formed as latching and counter-latching element and by this a latching connection ( 20 ) can be formed, which is applied by this latching connection, a normal force on the first and second housing component. Housing device according to claim 5, characterized in that a third connecting element is arranged for contacting the first and second connecting element, that in the assembled state by this third connecting element, a normal force on the first and second housing component can be applied. Housing device according to one of claims 6 or 7, characterized in that the transmitted by the sealing elements proportion is less than 50% of this normal force. Housing device according to one of the preceding claims, characterized in that the first housing component ( 1 ) has a higher rigidity in the region of at least the contact line (KL) than the second housing component, and in that the first housing component ( 1 ) at least one, preferably a plurality of, stiffening ribs ( 1.2 ) and that they extend at least up to the level or up to the region of the contact line (KL). Housing device according to one of the preceding claims, characterized in that the one tangential plane to the surface of the second housing component ( 2 ) at the location of the contact line (KL) in the unassembled state, having a first inclination α and that this tangential plane to the surface in the assembled state of the two housing components has a second inclination β and that the inclination difference Δ = β - α from a certain Range is selected for which applies Δ> 0.5 °, preferably Δ> 1 °, preferably> 2 ° and more preferably Δ> 5 ° and further Δ <45 °, preferably Δ <15 °, preferably Δ <10 ° and more preferably Δ <7.5 °. A method of manufacturing a housing device according to any preceding claim, said method comprising the steps of: Providing the first and second housing components, - Assembling the first and second housing member, so that forms at least one contact line between them. Manufacturing method according to claim 11, characterized in that in one of the housing component, a sealing element is introduced.

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