EP3853939A1

EP3853939A1 - Device for testing an insulating layer

Info

Publication number: EP3853939A1
Application number: EP19769814.5A
Authority: EP
Inventors: Philipp Miska; Daniel WERNEBURG; Gerd Schollenberger
Original assignee: Berghof Automation GmbH
Current assignee: Berghof Automation GmbH
Priority date: 2018-09-20
Filing date: 2019-09-20
Publication date: 2021-07-28
Also published as: EP3627612A1; WO2020058498A1

Abstract

The invention relates to a device for testing an insulating layer (in particular an insulating layer of a battery cell having a metallic housing) by applying high voltage, characterized in that the device comprises an electrically conductive PTFE film.

Description

Device for testing an insulation layer

The present invention relates to a device for testing an insulation layer (in particular a lacquer layer), in particular battery cells (for example lithium-ion battery cells or lithium cells).

In practice, lithium-ion battery cells e.g. a housing with a metallic part. For example, these housings can largely consist of deep-drawn aluminum sheet. One speaks here of a so-called hard shell housing or a hard case. For example, lithium-ion battery cells exist in the prior art which have such a, mostly prismatic, shaped hard case housing. In addition, there are, for example, lithium-ion battery cells with a cylindrical hard case. Such battery cells, also called round cells, are used, for example, in handicraft devices. Due to their metallic nature, the hardcase housings are electrically conductive, which can lead to problems, in particular when using the battery cell in a battery module comprising several battery cells.

The battery cells are therefore insulated. In addition to foils, coatings (for example painting) are also used, which, however, can have imperfections and / or damage. Insulation lacquers of this type can be produced, for example, on the basis of polyurethane or epoxy.

There is therefore an interest in checking the integrity of the insulation layer (in particular a lacquer layer) of a battery cell (e.g. a lithium cell), preferably already during production (especially at the start of production). The particularly critical points of a battery cell are the edges and the corners of the cell.

In such a test, the insulation layer of the battery cell is brought into contact with an electrically conductive material (contact material). A high voltage (HV) is then applied, ie an electrical voltage above 1,000 Volts (1kV). The contact material forms the one pole (or the one electrode) in the high voltage test (ie the breakdown test). The metallic housing of the battery cell forms the opposite pole (or the counter electrode) for the high voltage test. If the insulation layer is too thin or defective, an electrical breakdown occurs in such a high voltage test.

Alternatively, it is possible to increase the applied high voltage up to a breakdown during the test. The high voltage value required for the breakdown serves as a measure of the quality of the coating.

The amount of high voltage applied (test voltage) depends in individual cases preferably on the degree of the quality of the layer to be tested to be ensured.

In the context of the present invention, the terms “insulation layer” or “insulation layer” refer to an electrically insulating layer.

The contact material should preferably have the following properties:

It must be electrically conductive;

it should be resistant to punctures;

it should be flexible;

it should be gentle on the insulation layer, i.e. do not damage them when contacting;

it should not react chemically with the paint layer;

it should be reversibly deformable; and

it should be mechanically resilient and wear-resistant.

The integrity of an insulation layer (in particular a lacquer layer) of other objects that have such an insulation layer (in particular such a lacquer layer) can also be checked in an analogous manner, in particular of objects in which electrical insulation over an area is important (e.g. for Function test, device or personal protection). Examples of such others Objects are cables, housings of electrical devices of all kinds such as industrial components (e.g. control cabinet housings), household electronics (from washing machines to boilers), consumer electronics and automotive components (e.g. from ignition cables to alternators).

It was the object of the present invention to provide a device for testing an insulation layer (in particular a lacquer layer), in particular battery cells (e.g. lithium-ion battery cells or lithium cells).

The present invention relates to a device for testing an insulation layer, in particular an insulation layer of a battery cell with a metallic housing, which is characterized in that the device comprises an electrically conductive PTFE film.

Furthermore, the present invention relates to the use of an electrically conductive PTFE film for testing an insulation layer, in particular an insulation layer of a battery cell with a metallic housing.

Furthermore, the present invention relates to the use of an electrically conductive PTFE film for the breakdown test of an electrically insulating layer on an electrically conductive component by exposure to a high voltage.

Furthermore, the present invention relates to a method for testing an insulation layer, in particular an insulation layer of a battery cell with a metallic housing, by applying a high voltage, which is characterized in that an electrically conductive PTFE film is used to contact the insulation layer.

Furthermore, the present invention relates to a method for the breakdown test of an electrically insulating layer on an electrically conductive component by applying a high voltage, characterized in that for surface contacting of the electrically insulating layer, an electrically conductive PTFE film is used.

Furthermore, the present invention relates to a device for the breakdown test of an electrically insulating layer on an electrically conductive component by applying a high voltage, characterized in that it comprises an electrically conductive PTFE film for the area-to-surface contacting of the electrically insulating layer.

In the context of the present invention, the term “flat contacting” relates in particular to the contacting of a surface, wherein the surface can be flat or uneven.

According to the invention, electrically conductive PTFE (polytetrafluoroethylene) is used as the contact material, i.e. PTFE modified or mixed with an electrically conductive material (e.g. with conductive particles).

In the context of the present invention, the term “conductive” or “conductive” refers to the electrical conductivity. The term "electrically conductive" preferably refers to a conductivity of> 10 ^"8 S / m; preferably> 10 ⁶ S / m; in particular> 10 ³ S / m. Furthermore, the surface resistance of the electrically conductive PTFE film is preferably a maximum of 100 kOhm ; preferably a maximum of 75 kOhm (e.g. approx. 50 kOhm).

The PTFE film used according to the invention is preferably porous.

The PTFE (polytetrafluoroethylene) film used according to the invention is preferably an HV-PTFE film (such as a modified permeaflon film). The conductive PTFE film preferably used according to the invention preferably contains or consists of pure, porous PTFE which is modified with an electrically conductive material.

A preferred PTFE film used according to the invention is described in EP 2 857 438 A1.

Examples of electrically conductive materials that can be used to modify the PTFE are: soot particles, graphite, stainless steel fibers and aluminum particles.

The PTFE preferably used according to the invention is preferably characterized by the following properties:

it is electrically conductive;

it is HV-resistant;

it has excellent sliding properties;

it has a high flame resistance;

it is dimensionally stable;

it is temperature resistant in the range from -200 ° C to 250 ° C;

it is highly resistant to chemicals; and

it is physiologically harmless.

Preferably, a PTFE film with a thickness of 0.1 to 1.0 mm, preferably with a thickness of 0.2 to 0.5 mm (e.g. with a thickness of 0.3 to 0.35 mm) is used.

The device according to the invention preferably has one or more (in particular several) surfaces with contact material (contact surfaces) which at least partially enclose the object to be tested (e.g. the battery cell to be tested).

A contact surface preferably comprises an electrically conductive PTFE film (1), which is preferably coated with an electrically conductive adhesive film (2) on a filling material (in particular a foam) (3) is applied, which in turn is applied to a carrier material (4). 1 shows a cross section of such a preferred contact surface.

In the present invention, the foam acts as a cushion or cushion and ensures that the PTFE film is pressed optimally onto the insulating layer of the object to be tested (e.g. the battery cell to be tested). Furthermore, the foam compensates for unevenness on the surface of the object to be tested, as a result of which the contact material lies against the insulating layer to be tested without gaps. The contact material is flexibly and flexibly supported by the foam.

A commercial foam can be used in the present invention. The foam is preferably characterized by flexibility and dimensional stability. The foam is preferably open-pore and therefore resilient. The foam particularly preferably has a compression hardness at 40% of less than 300 kPa, preferably from 1 to 250 kPa, in particular from 5 to 200 (e.g. about 135 kPa).

Preferred materials of the foam used according to the invention are polyurethane (PU), ethylene-propylene-diene rubber (EPDM) and polyvinyl chloride (PVC); especially PU.

The thickness of the foam layer is preferably selected so that it can yield sufficiently to compensate for unevenness on the surface of the object to be tested. For example, it is preferred if the foam layer can yield at least 1 mm. The thickness of the foam layer is preferably from 3 to 10 mm; in particular from 4 to 7 mm (e.g. approx. 5 or approx. 6 mm).

An electrically conductive adhesive film made of an adhesive with electrically conductive particles and / or fibers is preferably used. The adhesive includes preferably an acrylate with electrically conductive particles and / or fibers as filler. An electrically conductive adhesive film is described, for example, in WO 2018/022840.

The three-dimensional (XYZ axis) electrically conductive adhesive film 9713 from 3M is particularly preferably used as the conductive adhesive film. This adhesive film is an isotropically conductive, pressure-sensitive adhesive tape. It conducts the current through the thickness (z-axis) and across the surface of the adhesive (x, y planes).

The conductive adhesive film is used in particular to optimize the conductivity. By using a conductive adhesive film, the total resistance of the contact surface is significantly reduced. The point-to-point resistance is therefore approximately constant over the entire contact area.

The thickness of the adhesive film is preferably 0.05 to 0.15 mm.

Plastics such as PLA (polylactide), ABS (acrylonitrile butadiene styrene copolymer), POM (polyoxymethylene) or FR4 can be used as the carrier material.

According to a preferred embodiment, a body is formed from the carrier material, which is preferably designed so that it can accommodate or at least partially encloses the object to be tested (for example the battery cell to be tested). This body is preferably designed such that it has a shape that is complementary to the shape of the object to be tested (for example the battery cell to be tested) and the PTFE film is pressed against the insulating layer of the object to be tested. This shape of the body is referred to below as the "shell". Such a shell can be produced, for example, by 3D printing. The shell preferably does not extend over the contacts of the battery cell or over the surface of the battery cell on which the contacts are arranged.

The thickness of the carrier material of the shell is preferably selected so that it remains mechanically stable when it is put on and that there is no twisting or bending. The thickness of the carrier material is preferably from 2 to 20 mm; especially from 3 to 15 mm (e.g. about 4 or about 10 mm).

If the object to be tested (e.g. the battery cell) is, for example, in the form of a cuboid with two wider side walls and two narrower side walls, an upper surface and a bottom surface, the shell is designed in such a way that it can accommodate such a cuboid.

If the object to be tested is a cuboid battery cell with contacts on the upper surface, the shell is preferably designed such that the side surfaces and the bottom surface of the cuboid in the finished device are at least partially brought into contact with the electrically conductive PTFE film the top surface on which the contacts are arranged.

According to a preferred embodiment, the device according to the invention is characterized in that it has a shape which is complementary to the shape of the object with the insulation layer to be tested.

An example of a preferred embodiment is shown in FIGS. 2 to 4 using the example of a cuboid battery cell. FIG. 2 shows a device according to the invention with the corresponding shell made of the carrier material (4) with filler material (3) and conductive PTFE film (1). The cuboid battery cell is shown schematically in FIG. FIG. 4 shows the device according to the invention from FIG. 2 with the battery cell from FIG. 3 incorporated therein. The shell has a U-shaped profile, which in turn is formed in a U-shape such that the shell can accommodate the cuboid battery cell so that the edges of the battery cell, which the Connect the side surfaces of the battery cell to each other, and the edges of the battery cell, which connect the side surfaces to the bottom surface, are brought into contact with the electrically conductive PTFE film.

If the object to be tested (e.g. the battery cell) is in the form of a cylinder, the shell is also made cylindrical so that it can hold the object to be tested. In the case of such a cylindrical battery cell, if the contacts are arranged on the upper surface, the shell is preferably designed such that it encloses the base surface and the outer surface.

The device according to the invention can optionally be in several parts in the form of segments which can be moved relative to one another in order to enlarge the space for accommodating the object to be tested (e.g. the battery cell). Such a structure offers the advantage that the friction when the object to be tested comes into contact with the device according to the invention is reduced. The device according to the invention is preferably divided into two or four segments. Examples of corresponding embodiments of the invention are shown in FIGS. 5, 6 and 7.

After the segments have been brought into contact with the object to be inspected and put together, they are fixed in place using conventional means. The segments can be brought into contact and fixed, for example, by pressing with a pneumatic cylinder, by means of hydraulics or with linear motors, or by manual application with the object to be tested.

In order to close the joints between the individual segments and to ensure continuous contact, the PTFE film can protrude on one or more segments. This leads to an overlap of the film and thus to a closed contact. An advantage of segmentation into several partial shells is that a fault in the lacquer layer of the battery cell can be assigned to a segment and thus an improved localization of the fault can take place, since it is possible to carry out a separate HV test with each individual segment in the event of a fault.

The breakdown test can be carried out with a test device known per se for high voltage testing, e.g. the DC high voltage and insulation tester DH-110.01 B from Stahl GmbH, Crailsheim. The one high-voltage connection of the device mentioned is e.g. in the case of testing a battery cell connected to the housing of the battery cell. The other high voltage connection of the device is e.g. on a protruding tab of the PTFE film e.g. connected using a conventional screw terminal.

Embodiment

A device for testing the lacquer layer of cuboid battery cells was produced. The external dimensions of the device produced were approx. 200 x 70 x 100 mm (L x W x H). The device has the structure shown in Figure 2, i.e. the shell has a U-shaped profile, which in turn is formed in a U-shape such that the shell can accommodate a cuboid battery cell in such a way that the edges of the cell, which connect the side faces of the cell to one another, and the edges of the cell, which connect the side surfaces with the bottom surface, are brought into contact with the PTFE film.

The shell is dimensioned so that the battery cell is easily jammed in the device. The foam yields approx. 1 mm and presses the PTFE film against the lacquer layer of the battery cell in such a way that there is no air gap to ensure optimal contact. The shell made of the carrier material was 3D printed with the

Melt layer process (FDM / FFF) manufactured. The wall thickness of the bowl is 4 mm.

The inside of the bowl was covered with a self-adhesive PU

Foam tape lined with a thickness of 5 mm.

The electrically conductive PTFE film (thickness: 0.3 mm) was attached to the foam layer with a conductive adhesive film (3M 9713) with a thickness of 0.0889 mm.

In a further embodiment, the electrically conductive PTFE film (thickness: 0.3 mm) was attached to the foam layer with a conventional adhesive.

The electrical contact with an HV test device (steel DH-110.01 B) was made on a protruding tab of the PTFE film using a conventional screw connection.

The functionality of the devices described above (with conductive adhesive film and with conventional adhesive) was demonstrated in the experiment. Under real test conditions, it was possible to check real battery cells for paint defects.

In long-term tests (50 x breakdown in the same place and 200 x breakdown in the same place with increased test current), the PTFE film proved to be robust against breakdowns with both devices.

Furthermore, a device was produced which, as shown in FIG. 7, is segmented into four partial shells. This is pressed onto the four corners of the battery cell to be checked. With a protrusion of the PTFE film of a few mm, an overlap of the film guarantees that there will be continuous contact. One advantage of segmentation into four partial shells is that a defect in the lacquer layer of the battery cell can be assigned to a segment and thus an improved localization of the defect can take place, since it is possible to carry out a separate HV test with each individual segment in the event of a fault .

Claims

Expectations

1. Device for the breakdown test of an electrically insulating layer on an electrically conductive component by exposure to a high voltage, characterized in that it comprises an electrically conductive PTFE film for the area contacting of the electrically insulating layer.

2. Device for testing an insulation layer, characterized in that it comprises an electrically conductive PTFE film.

3. Device according to claim 1 or 2, characterized in that the electrically conductive PTFE film is applied to a filling material, which in turn is applied to a carrier material.

4. The device according to claim 3, characterized in that the filling material is a foam.

5. The device according to claim 3 or 4, characterized in that the electrically conductive PTFE film is applied with an electrically conductive adhesive film on the filling material.

6. Device according to one of the preceding claims, characterized in that the electrically conductive PTFE film consists of pure, porous PTFE, which is modified with an electrically conductive material.

7. Device according to one of the preceding claims, characterized in that it has one or more surfaces with the electrically conductive PTFE film.

8. Device according to one of the preceding claims, characterized in that it has a cuboid shape with a bottom surface and has four side walls, the upper surface being open, the corners and the edges preferably being rounded.

9. Device according to one of the preceding claims, characterized in that it has a U-shaped profile, which in turn is formed in a U-shape such that the device can accommodate a cuboid battery cell with contacts on the upper surface so that the edges the battery cell, which connect the side surfaces of the battery cell to one another, and the edges of the battery cell, which connect the side surfaces to the bottom surface, are brought into contact with the electrically conductive PTFE film.

10. Device according to one of the preceding claims, characterized in that it is in the form of segments which are movable relative to each other.

11. A method for testing an insulation layer by applying a high voltage, characterized in that a device according to one of claims 1 to 10 is used.

12. Method for the breakdown test of an electrically insulating layer on an electrically conductive component by exposure to a high voltage, characterized in that an electrically conductive PTFE film is used for the area-to-surface contacting of the electrically insulating layer.

13. The method according to claim 11 or 12 for testing an insulation layer of a battery cell with a metallic housing.

14. Use an electrically conductive PTFE film to test an insulation layer.

15. Use of an electrically conductive PTFE film for the breakdown test of an electrically insulating layer on an electrically conductive component by applying a flock voltage.