DE102020004101A1 - Method for repairing an electrical energy store - Google Patents

Abstract

The invention relates to a method for repairing an electrical energy store having a plurality of individual cells (E1, E2) electrically connected in series with one another and a cell monitoring unit for monitoring the individual cells (E1, E2). According to the invention, when the cell monitoring unit detects an individual cell (E1, E2) which has reduced electrical output, the individual cell (E1, E2) is electrically connected in parallel with a repair cell (E3) by using current collectors ( 2) the cables (3) connected to the repair cell (E3) are connected to current conductors (2) of the individual cell (E1).

Description

The invention relates to a method for repairing an electrical energy store having a plurality of individual cells electrically connected in series with one another and a cell monitoring unit for monitoring the individual cells.

From the EP 3 080 854 B1 methods for maintaining, repairing and optimizing a battery and a battery are known. The battery comprises as components a number of serially and/or parallel interconnected individual cells with electrical pole contacts, which are positively and/or cohesively connected to each other for the electrical interconnection directly or by means of cell connectors to form an overlapping area, and optionally a battery monitoring unit with a number of Connection elements which are connected to the electrical pole contacts and/or to the cell connectors in a form-fitting and/or material-locking manner, forming a further overlapping area. The method provides that, in order to replace a component, the form-fitting and/or material-locking connection of the components to be replaced with at least one component that is not to be replaced is separated immediately next to the overlapping area and a replacement component by means of its electrical pole contacts or its connection elements with the overlapping areas of the at least one is not component to be replaced is positively and / or cohesively connected to form a new overlapping area.

The invention is based on the object of specifying a method for repairing an electrical energy store having a plurality of individual cells electrically connected in series with one another.

The object is achieved according to the invention by a method which has the features specified in claim 1.

Advantageous configurations of the invention are the subject matter of the dependent claims.

According to the invention, a method for repairing an electrical energy store having a plurality of individual cells electrically connected in series with one another and a cell monitoring unit for monitoring the individual cells provides that if the cell monitoring unit is used to determine an individual cell which has a reduced electrical output, this individual cell is connected to a repair cell is electrically connected in parallel by connecting cables connected to current collectors of the repair cell to current collectors of the individual cell.

By using the method, it is possible to increase the performance of the electrical energy store and to start operating it again. For repairs, it is therefore not necessary to dismantle the electrical energy storage device in order to remove the individual cell with reduced power, replace it with a new individual cell if necessary and reassemble the electrical energy storage device.

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

• 1 schematisch eine Draufsicht eines Zellverbundes mit einer eine verminderte elektrische Leistung aufweisenden Einzelzelle,
• 2 schematisch eine Seitenansicht des Zellverbundes gemäß 1,
• 3 schematisch eine Draufsicht des Zellverbundes mit einer mit der Einzelzelle elektrisch verbundenen Reparaturzelle,
• 4 schematisch eine Seitenansicht des Zellverbundes mit der mit der Einzelzelle elektrisch verbundenen Reparaturzelle,
• 5 schematisch eine Draufsicht des Zellverbundes und der elektrisch verbundenen Reparaturzelle in einem Zellgehäuse,
• 6 schematisch eine Seitenansicht des Zellverbundes und der elektrisch verbundenen Reparaturzelle in dem Zellgehäuse und
• 7 schematisch eine Vorrichtung zur Verbindung mittels Kontaktdornen.

show:

• 1 a schematic plan view of a cell assembly with an individual cell having a reduced electrical output,
• 2 schematically shows a side view of the cell assembly according to FIG 1 ,
• 3 a schematic plan view of the cell assembly with a repair cell electrically connected to the individual cell,
• 4 a schematic side view of the cell assembly with the repair cell electrically connected to the individual cell,
• 5 a schematic top view of the cell assembly and the electrically connected repair cell in a cell housing,
• 6 schematically a side view of the cell assembly and the electrically connected repair cell in the cell housing and
• 7 schematically a device for connection by means of contact pins.

Corresponding parts are provided with the same reference symbols in all figures.

the 1 and 2 show a cell assembly 1 with five individual cells E1, E2 electrically connected in series with one another, with an individual cell E1 having a reduced electrical output, for example due to aging, and being shown highlighted. In particular, the individual cells E1, E2 are electrically interconnected by means of their current conductors 2. For this purpose, the current conductors 2 of adjacent individual cells E1, E2 are placed one on top of the other and fastened to one another in a materially bonded manner, in particular welded. while showing 1 a plan view of the cell assembly 1 and 2 a side view of the cell assembly 1.

The number of individual cells E1, E2 is selected as an example, with a cell assembly 1 being able to have a much higher number of individual cells E1, E2.

The cell assembly 1 is part of an electrical energy store in the form of a vehicle battery, in particular for an electric vehicle, a hybrid vehicle or a vehicle operated with fuel cells.

The electrical energy store usually has a cell monitoring unit for monitoring the individual cells E1, E2, it being determined on the basis of detected signals from the cell monitoring unit that the electrical power of the individual cell E1 is reduced.

In order to achieve an electrical voltage required to drive the corresponding vehicle, the individual cells E1, E2 are electrically connected in series. If, on the other hand, the individual cells E1, E2 are electrically connected to one another in parallel, a load is divided between the individual cells E1, E2, with a current distribution between the individual cells E1, E2 connected in parallel then being dependent on the electrical resistance and a charge level of the individual cells E1, E2.

In the case of a purely electrical serial connection of the individual cells E1 to E5, the electrical performance of the connection is determined by the individual cell E1 whose electrical output is the lowest. This is the cell with increased electrical resistance and/or reduced capacity. For example, the electrical power is reduced due to aging of the individual cell E1.

The service life and aging of the individual individual cells E1, E2 depends on a comparatively large number of influencing factors, it being possible for an individual cell E1 to age faster than the remaining individual cells E2 of the cell assembly 1 due to production variances and/or production errors.

Comparatively severe aging of an individual cell E1 in a cell assembly 1 electrically connected in series leads to the electrical energy storage device losing a considerable amount of usable electrical energy, since the same current flows through all individual cells E1, E2 of the cell assembly 1.

Usually, when it is determined that a cell assembly 1 has such an individual cell E1 with reduced electrical power and the electrical performance of the electrical energy store is significantly reduced as a result, the latter is dismantled, the individual cell E1 replaced and the electrical energy store reassembled. Since an electrical energy store has a relatively large number of components that are connected to one another, in particular electrically, this is a relatively complex process.

In order to be able to prevent dismantling of the electrical energy store as far as possible, provision is made for the individual cell E1 with electrically reduced power to be electrically connected in parallel with a repair cell E3. As a result, the electrical current is divided between the individual cell E1 and the repair cell E3, so that the electrical output of the cell assembly 1 and thus of the electrical energy store is no longer limited by the reduced electrical output of the individual cell E1.

For electrical parallel connection of the individual cell E1 with the repair cell E3, it is necessary to connect the current collector 2 of the repair cell E3 to the current collector 2 of the individual cell E1, as in FIGS 3 and 4 is shown.

The current arresters 2 of the repair cell E3 are connected by means of cables 3 to the current arresters 2 of the individual cell E1, with a possible embodiment of the repair cell E3 in FIGS 5 and 6 is shown. where is in 5 a plan view of the cell assembly 1 with the repair cell E3 in a cell housing 4 and in 6 a side view of the cell assembly 1 with the repair cell E3 arranged in the cell housing 4 is shown.

In this in 5 and 6 In the embodiment shown, the repair cell E3 is arranged in a cell housing 4, from which the cables 3 for the electrical connection of the repair cell E3 are led out.

For example, the cables 3 are welded, screwed and/or penetrated into 7 shown contact mandrels 5 connected to the respective current arrester 2.

In particular, the cables 3 led out of the cell housing 4 are connected to current collectors 2 of the individual cell E1, which are connected to current collectors 2 of a respective neighboring individual cell E2.

7 shows a device 6 for contacting the current collector 2 with the cables 3 by means of contact spikes 5.

The device 6 comprises a counterpart 7 with a counterplate 8, a guide 9, a plurality of contact spikes 5 and a metal plate 10 with an electrical connection, in particular the cables 3, wherein the electrical connection can alternatively be designed as a conductor rail.

The connected conductor 2 of the single cell E1 and the respective adjacent single cell E2 between the back plate 8 and the Metal plate 10 is arranged and the counterpart 7 is moved in the direction of the metal plate 10 by means of the guide 9 .

In particular, the counterpart 7 is pressed onto the metal plate 10 , as a result of which the contact spikes 5 are pressed through the current collector 2 into the counterplate 8 . As a result, the metal plate 10 is connected to the current conductors 2 fastened to one another, and electrical contact is made with the repair cell E3 via the cables 3.

The same process is also possible with plug connections between the individual cells E1, E2. It is also conceivable that a plate with plug-in options is attached, this being particularly suitable for so-called second-life applications. As a result, individual cells E1 with reduced electrical power can increasingly be connected to a repair cell E3. The individual cell E1 with the lowest capacity is then electrically connected in parallel with such a repair cell E3, as a result of which a proportion of usable electrical energy in the electrical energy storage device is increased.

Reference List

1

cell network

2

current collector

3

cable

4

cell case

5

contact mandrel

6

contraption

7

counterpart

8th

counter plate

9

guide

10

metal plate

E1, E2

single cell

E3

repair cell

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited 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

• EP 3080854 B1 [0002]

Claims (3)

Method for repairing an electrical energy store with a plurality of individual cells (E1, E2) electrically connected in series with one another and a cell monitoring unit for monitoring the individual cells (E1, E2), characterized in that when the cell monitoring unit determines an individual cell (E1, E2). which has a reduced electrical output, the individual cell (E1, E2) is electrically connected in parallel with a repair cell (E3) by cables (3) connected to current collectors (2) of the repair cell (E3) with current collectors (2) of the individual cell (E1) are connected. procedure after claim 1 , characterized in that the repair cell (E3) is arranged in a cell housing (4) from which the cables (3) connected to the current collectors (2) of the repair cell (E3) are led out, which are connected to the current collectors (2) of the individual cell (E1) are connected. procedure after claim 1 or 2 , characterized in that the cables (3) leading out of the cell housing (4) are connected to the respective current conductors (2) in a materially, form-fitting and/or non-positive manner.

Images