DE102022122104A1 - Method for preparing a short-circuit test of a battery cell of an energy storage device and an energy storage device - Google Patents

Abstract

In the method for preparing a short-circuit test of a battery cell (30) of an energy storage device (10), an opening (40) is created in a housing (20) of the energy storage device (10) to the battery cell (30). Furthermore, a guide shaft (70) is inserted into the opening (40) and clamped to the housing (20) of the energy storage device (10), the guide shaft (70) being designed as an elongated hollow body in order to hold a nail (100) for short-circuit testing outside the housing (20) of the energy storage (10) to the battery cell (30).

Description

The invention relates to a method for preparing a short-circuit test of a battery cell of an energy storage device. The invention further relates to an energy storage device on which the method was carried out.

Modern battery cells are characterized by high achievable energy densities. Energy density refers to the distribution of energy over a certain size, for example a volume. Due to the high energy density, in the event of a short circuit within the battery cell, the battery cell can thermally propagate and self-ignite. In order to represent a cell defect as realistically as possible in a test, a short-circuit test is carried out, among other things, in which an electrically conductive nail penetrates the battery cell in order to cause thermal propagation within the battery cell.

The task on which the invention is based is to prepare a safe and efficient short-circuit test.

The task is solved by the features of the independent patent claims. Advantageous refinements are characterized in the subclaims.

The invention is characterized by a method and a corresponding energy storage device for preparing a short-circuit test of a battery cell.

In the method, an opening is created in a housing of the energy storage device to the battery cell and a guide shaft is inserted into the opening. Furthermore, during the process, the guide shaft is clamped to the housing of the energy storage device. The guide shaft is designed as an elongated hollow body in order to guide a nail for short-circuit testing from outside the housing of the energy storage device to the battery cell.

Due to the provision of the guide shaft, the nail to the battery cell can be guided through the guide shaft during the short-circuit test, thus reducing the risk of an incorrect short-circuit test.

The guide shaft can counteract incorrect short-circuit testing, such as bending or breaking of the nail. Furthermore, the nail is stabilized by the guide shaft and guided to the battery cell at a certain angle, thereby preventing unwanted penetration of more than one battery cell. Accordingly, the safety and efficiency of short-circuit testing are increased by management.

According to an advantageous embodiment, a screw-on plate is attached to the inside of the housing of the energy storage device and the guide shaft is attached to the screw-on plate. For example, the screw-on plate is glued into the housing of the energy storage device. For example, the guide shaft is screwed to the screw-on plate.

By means of the screw-on plate attached to the inside of the housing of the energy storage device, a connecting element to the guide shaft is placed in the housing of the energy storage device in a space-saving manner.

According to an advantageous embodiment, the guide shaft has a thread on an outer wall, the thread of the guide shaft being screwed to the screw-on plate within the housing of the energy storage device.

Thanks to the thread on the outer wall of the guide shaft, the guide shaft can be screwed to the screw-on plate particularly efficiently and in a space-saving manner through the opening in the housing of the energy storage device.

According to an advantageous embodiment, the guide shaft has a seal on an inner wall, the seal being designed to seal the guide shaft in the event of an inserted nail.

For example, the seal on the inner wall of the guide shaft is designed as a temperature-resistant sealing element, such as an O-ring.

The seal within the guide shaft seals the guide shaft airtight in the event of a nail being inserted, whereby the seal acts as thermal insulation during a short-circuit test with heat development in order to concentrate the heat within the energy storage device. This precisely simulates the event of a short circuit within the battery cell.

According to an advantageous embodiment, a sealing plate is arranged around the guide shaft outside the housing of the energy storage device, wherein the sealing plate is clamped against the outside of the housing of the energy storage device and the sealing plate is designed to seal the opening on the housing of the energy storage device.

The sealing plate outside the energy storage serves to stabilize the guide shaft. In addition, the opening in the housing of the energy storage and the guide shaft is sealed airtight by the sealing plate outside the energy storage, whereby the sealing plate acts as thermal insulation during a short-circuit test with heat development in order to concentrate the heat within the energy storage. The sealing plate also serves to precisely simulate a short circuit within the battery cell.

According to an advantageous embodiment, the sealing plate is clamped to the housing of the energy storage device by means of a first fastening element which is attached to the guide shaft.

For example, the sealing plate is clamped using a screw nut. The screw nut, for example, forms a screw connection with the guide shaft and braces the sealing plate with the housing of the energy storage device.

The first fastening element ensures that the sealing plate is clamped tightly between the guide shaft and the housing of the energy storage device.

According to an advantageous embodiment, the first fastening element is secured by a second and a third fastening element.

For example, the second and third fastening elements are also designed as screw nuts and serve to secure the first fastening element.

According to an advantageous embodiment, the opening in the housing of the energy storage is created by a hole.

The hole makes it particularly easy to create an opening in the housing of the energy storage device.

According to an advantageous embodiment, the screw-on plate and the guide shaft are made of a metal material.

During short-circuit testing, high temperatures can occur within the battery cell, even causing spontaneous combustion. Due to the metal material, for example steel, the screw-on plate and the guide shaft are temperature-resistant. For example, the nail is also made of and/or has a metal material.

The invention is further characterized by an energy storage device on which the method for preparing a short-circuit test of a battery cell of an energy storage device was carried out.

Accordingly, the features are described in connection with the method and also in connection with the energy storage and vice versa.

• 1 bis 5 Verfahrensschritte bei einem Verfahren zum Vorbereiten einer Kurzschlussprüfung einer Batteriezelle eines Energiespeichers und
• 6 Ausführungsbeispiel eines in einen Führungsschaft eingesetzten Nagels.

Exemplary embodiments of the invention are explained in more detail below with reference to the schematic drawings. Show it:

• 1 to 5 Method steps in a method for preparing a short-circuit test of a battery cell of an energy storage device and
• 6 Embodiment of a nail inserted into a guide shaft.

Elements of the same construction or function are marked with the same reference numerals across the figures.

A method for preparing a short-circuit test of a battery cell of an energy storage device is explained below.

According to an exemplary embodiment, in a first method step according to 1 First an opening 40 is created in a housing 20 of an energy storage device 10. For example, the opening 40 is drilled into the housing 20 of the energy storage device 10. Alternatively, the opening 40 can be cut or punched, for example, into the housing 20 of the energy storage device 10.

The opening 40 has, for example, a hole with a diameter of 25 millimeters.

The energy storage 10 includes, for example, a plurality of battery cells 30, which are arranged in battery modules within a battery module housing 50.

For example, the battery module housing 50 is removed from the energy storage 10 before the opening 40 is drilled into the housing 20 of the energy storage 10.

In a second process step according to 2 a screw plate 60 is glued into the housing 20 of the energy storage 10.

For example, the screw-on plate 60 has a cylindrical cavity with an internal thread on the inner wall and is glued via the opening 40 within the housing 20 of the energy storage device 10.

For example, the screw-on plate 60 has a total diameter of 50 millimeters, with the cylindrical cavity having essentially the same diameter as the opening 40 on the housing 20 of the energy storage 10, for example 25 millimeters.

In a third process step according to 3 a guide shaft 70 is inserted into the opening 40 of the housing 20 of the energy storage 10 and screwed to the screw-on plate 60.

The guide shaft 70 is designed as an elongated, cylindrical hollow body and has a thread on an outer wall. The guide shaft 70 is screwed to the screw-on plate 60 within the housing 20 of the energy storage 10.

For example, the guide shaft 70 has a length between 50 millimeters and 100 millimeters, in particular 70 millimeters. Furthermore, the outer diameter of the guide shaft 70 essentially corresponds to the dimensions of the opening 40 in the housing 20 of the energy storage 10, for example 25 millimeters. For example, the guide shaft 70 has an inner diameter of 12 millimeters.

Within the leadership shaft 70, the leadership shaft 70 has seals 71 on an inner wall. For example, the seals 71 within the guide shaft 70 are designed as annular sealing elements. For example, the sealing elements are designed as temperature-resistant O-rings.

The seals 71 within the guide shaft 70 are designed to seal the interior and exterior of the housing 20 of the energy storage 10 once a nail 100 has been inserted into the guide shaft 70.

In a fourth procedural step according to 4 a sealing plate 80 with a seal 81 is attached to the sealing plate 80 outside the housing 20 of the energy storage 10. The sealing plate 80 is arranged, for example, around the guide shaft 70, wherein the sealing plate 80 is clamped against the outside of the housing 20 of the energy storage 10 and is designed to seal the opening 40 on the housing 20 of the energy storage 10 and the guide shaft 70.

The seal 81 on the sealing plate 80 is also designed, for example, as an annular sealing element. For example, the seal 81 is also designed as a temperature-resistant O-ring.

The sealing plate 80 is clamped to the housing 20 of the energy storage device 10, for example by means of a first fastening element 90 which is attached to the guide shaft 70. The first fastening element 90 is, for example, designed such that the first fastening element 90 has an internal thread and is screwed to the guide shaft 70. The first fastening element 90 is designed, for example, as a screw nut.

In a fifth procedural step according to 5 a nail 100 is inserted into the guide shaft 70 from outside the housing 20 of the energy storage device 10.

Beforehand, the first fastening element 90 is secured, for example, by a second and a third fastening element 91, 92. The second and third fastening elements 91, 92 have, for example, the same features as the first fastening element 90 and are also designed, for example, as screw nuts.

For example, the nail 100 includes a nail shaft and a nail tip, the nail shaft having, for example, a diameter of 10 millimeters. The nail tip can vary depending on the short-circuit test requirements or depending on the type of battery cell 30. For example, the tip of the nail, as in 5 shown, from which nail shaft tapers or as in 6 shown, for example, be designed as a wire pin with a diameter of 3 millimeters and with a countersunk head.

Reference symbol list

10

Energy storage

20

Housing

30

Battery cell

40

opening

50

Battery module housing

60

screw plate

70

Leadership

71

poetry

80

sealing plate

81

poetry

90

first fastener

91

second fastener

92

third fastener

100

nail

Claims (10)

Method for preparing a short-circuit test of a battery cell (30) of an energy storage device (10), in which - an opening (40) is created in a housing (20) of the energy storage (10) to the battery cell (30), - a guide shaft (70) is inserted into the opening (40) and clamped to the housing (20) of the energy storage (10), whereby - The guide shaft (70) is designed as an elongated hollow body in order to guide a nail (100) for the short-circuit test from outside the housing (20) of the energy storage device (10) to the battery cell (30). Procedure according to Claim 1 , wherein a screw-on plate (60) is attached to an inside of the housing (20) of the energy storage (10) and the guide shaft (70) is attached to the screw-on plate (60). Procedure according to Claim 2 , wherein the guide shaft (70) has a thread on an outer wall, and the thread of the guide shaft (70) is screwed to the screw-on plate (60). Method according to one of the preceding claims, wherein the guide shaft (70) has a seal (71) on an inner wall, the seal (71) being adapted to seal the guide shaft (70) when the nail (100) is inserted. Method according to one of the preceding claims, wherein a sealing plate (80) is arranged around the guide shaft (70) outside the housing (20) of the energy storage device (10), the sealing plate (80) being against an outside of the housing (20) of the energy storage device (10) is clamped and the sealing plate (80) is designed to seal the opening (40) on the housing (20) of the energy storage (10). Procedure according to Claim 5 , wherein the sealing plate (80) is clamped to the housing (20) of the energy storage (10) by means of a first fastening element (90) which is attached to the guide shaft (70). Procedure according to Claim 6 , wherein the first fastening element (90) is secured by a second and a third fastening element (91, 92). Method according to one of the preceding claims, wherein the opening (40) in the housing (20) of the energy storage (10) is created by a bore. Method according to one of the preceding claims, wherein the screw plate (60) and the guide shaft (70) are formed from a metal material. Energy storage (10), on which the method according to one of the Claims 1 until 9 was carried out.

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