EP2883264A1

EP2883264A1 - Method for forming an electrochemical cell, electrochemical cell and battery

Info

Publication number: EP2883264A1
Application number: EP13741679.8A
Authority: EP
Inventors: Magnus Mickel; Markus Wohnig; Iris Stiebert; Tim Schaefer
Original assignee: Li Tec Battery GmbH
Current assignee: Li Tec Battery GmbH
Priority date: 2012-08-07
Filing date: 2013-07-25
Publication date: 2015-06-17
Also published as: WO2014023396A1; US20150228999A1; US20140045030A1; JP2015528626A

Abstract

The method for forming an electrochemical cell having a first outgoing conductor and a second outgoing conductor for a battery, preferably configured for application in motor vehicles, by means of a forming unit having a first contact element and a second contact element, wherein the first outgoing conductor has a first forming contact-making section embodied in a separable fashion and the second outgoing conductor has a second forming contact-making section embodied in a separable fashion, comprises the following steps: (S1a) pressing the first contact element of the forming unit onto the first forming contact-making section of the first outgoing conductor, (S1b) pressing the second contact element of the forming unit onto the second forming contact-making section of the second outgoing conductor, (S5) carrying out a forming treatment, (S6a) separating the first forming contact-making section from the first outgoing conductor, and (S6b) separating the second forming contact-making section from the second outgoing conductor.

Description

Method for forming an electrochemical cell, electrochemical cell and battery

Description

The invention relates to a method for forming an electrochemical cell for a preferably designed for use in motor vehicles battery and correspondingly formed electrochemical cells and a

Battery with these electrochemical cells.

Hereby, the entire content of the priority applications DE 10 2012 015 575 and DE 10 2012 017 829 by reference is part of the present application.

It is known in the manufacture of electrochemical cells to improve the intrinsic shadow, to subject the cells of a formation. The formation comprises, preferably multiple charging and discharging of the electrochemical cells. Various methods for the formation of electrochemical cells and correspondingly formed electrochemical cells and batteries with these electrochemical cells are known from the prior art. Especially for applications in motor vehicles, improved methods for forming electrochemical cells are desired.

It is an object of the present invention to provide an improved process for the formation of electrochemical cells and correspondingly formed electrochemical cells or batteries. This object is achieved by a method for forming electrochemical cells according to claim 1, an electrochemical cell according to claim 11 and a battery according to claim 13 solved. The dependent claims relate to advantageous developments of the invention.

This object is achieved in a method for forming a first cell having a first Abieiter and a second Abieiter electrochemical cell for a preferably designed for use in motor vehicles battery by means of a first contact element and a second contact element having forming unit, wherein the first Abieiter a first, detachably formed Formierungskontaktierungsabschnitt and the second conductor has a second detachably formed forming contacting portion, characterized in that the method comprises the steps of: a step of pressing the first contact element of the forming unit onto the first forming contacting section of the first conductor, a step of pressing the second contact element of the forming unit to the second forming contacting portion of the second discharger, a step of performing a forming treatment, a step of separating ns of the first forming-contacting portion of the first absorber and a step of

Separating the second forming contacting portion from the second absorber. An advantage of this embodiment is that the contacting of the forming unit with the electrochemical cell and, consequently, their formation can be improved. Another advantage of this embodiment is that the formation can be carried out accelerated, since - without adversely affecting the final state of the first Abieiters and the final state of the second Abieiters - when forming the Formierungs- contacting sections can be optionally more heavily loaded.

An electrochemical cell is understood to mean an electrochemical energy store for the present invention, that is to say a device which stores energy in chemical form, delivers it in electrical form to a consumer and preferably can also receive it in electrical form from a charging device. Important examples of such electrochemical energy Memories are galvanic cells or fuel cells. The electrochemical cell has at least a first and a second device for storing electrically different charges, which are configured as an electrode arrangement, as well as a means for establishing an electrically operative connection of both said devices, wherein charge carriers can be displaced between these two devices. Under the means for producing an electrical active compound z. B. to understand an electrolyte, which acts as an ion conductor.

Preferably, in the method, the step of pressing the first contact member is performed such that surface layers of the first formation contacting portion are pierced. Further preferably, in the method, the step of pressing the second contact element is performed such that surface layers of the second

Formierungskontaktierungsabschnittes are pierced. An advantage of these embodiments is that the contact resistance is reduced and as a result the contacting and the formation can be improved.

In the method, the first contact element of the forming unit preferably has at least one tip. Further preferred in the

Process the second contact element of the forming unit at least one tip. An advantage of these embodiments is that the contact can be particularly easily improved.

In the method, the first contact element is preferably designed as a first number of first contact pins, with the first contact element particularly preferably having three first contact pins. According to a further preferred embodiment, only a first contact pin is formed in the first contact element. Further preferred in the method is the second

Contact element formed as a second number of second contact pins, wherein more preferably, the second contact element has three second contact pins. According to a further preferred embodiment, only a second contact pin is formed in the second contact element. In the method, the first contact pins are preferably mounted individually. Further preferably, in the method, the second contact pins are mounted individually. An advantage of this embodiment is that for further

Reducing the contact resistance of the pressure can be adjusted particularly well.

In the method, the first contact element preferably has at its contact end at least one crown having contact points, with the first contact element particularly preferably having three crowns with preferably four contact prongs. Further preferably, the second contact element has on its contacting end at least one contact prongs crown, wherein particularly preferably the second contact element has three crowns with preferably four contact prongs. An advantage of these embodiments is that the contacting can be improved particularly effectively. Preferably, after the step of pressing the first contact element, the method further comprises the following steps: a step of acquiring first parameter data of the first contact of the first contact element of the forming unit with the first forming contact section of the first conductor, a step of supplying the detected first parameter data to a controller and a step of performing a first contacting change in response to the detected first parameter data when the detected first parameter data has a predetermined first threshold.

Further preferably, after the step of pressing the second contact element, the method further comprises the following steps: a step of acquiring second parameter data of the second contacting of the second contact element of the forming unit with the second one

Formierungskontaktierungsabschnitt of the second Abieiters, a step of supplying the detected second parameter data to a controller and a step of performing a second Kontaktierungsveränderung in Dependency of the detected second parameter data when the detected second parameter data has a predetermined second threshold value. An advantage of these embodiments is that the contacting in desired quality during the formation can be maintained more easily.

Preferably, in the method, the step of detecting first

Parameter data of the contacting at least one of the following steps: a step of detecting a first transition resistance of the first contact of the first contact element of the forming unit with the first Formierungskontaktierungsabschnitt the first Abieiters and / or a step of detecting a first temperature of the first contact of the first contact element of the forming unit with the first forming-contacting portion of the first Abieiters. Further preferably, in the method, the step of acquiring second parameter data comprises

Contacting at least one of the following steps: a step of detecting a second transition resistance of the second contacting of the second contact element of the forming unit with the second

Formierungskontaktierungsabschnitt of the second Abieiters and / or a step of detecting a second temperature of the second contact of the second contact element of the forming unit with the second

Formierungskontaktierungsabschnitt the second Abieiters.

Preferably, in the method, the step of performing a first contacting change comprises the step of: increasing a first pressure with which the first contact element contacts the first one

Formierungskontaktierungsabschnitt the first Abieiters is pressed.

Further preferably, in the method, the step of performing a second contacting change comprises the step of: increasing a second pressure with which the second contact element is pressed against the second forming contacting portion of the second conductor. Preferably, in the method, the step of performing a

Forming process comprising the steps of: a step of performing a first forming of the electrochemical cell in a range of 25 to 40% of the rated capacity, a step of performing a second forming of the electrochemical cell in a range of 75 to 90% of the rated capacity and a step of Performing a third forming of the electrochemical cell at 100% of the rated capacity. An advantage of this embodiment is that the capacity of the formatted electrochemical cell can be increased. Furthermore, this object is achieved in the case of an electrochemical cell having a first arrester having a separably formed first forming contacting section and a second arrester having a second separable formed contacting section, characterized in that the electrochemical cell has been formed by a method as described above.

Preferably, in the electrochemical cell, the first formation-contacting portion is disposed at an outer end of the first Abieiters. Further preferably, the second Formierungskontaktierungsabschnitt is disposed at an outer end of the second Abieiters. An advantage of this embodiment is that after the forming treatment, the separation of the first Formierungskontaktierungsabschnittes from the first arrester and the separation of the second Formierungskontaktierungsabschnittes from the second arrester can be performed better.

Furthermore, this object is achieved in a battery with an electrochemical cell, characterized in that the electrochemical cells of the battery has been formed with a method described above.

Aspects of the invention will be described in more detail below with reference to preferred embodiments and with the aid of the figures. Showing: 1 is a flowchart of a method for forming electrochemical cells according to an embodiment,

2a is a first detail view of the flowchart shown in FIG. 1 with regard to the acquisition of first parameter data, FIG.

FIG. 2b shows a second detailed representation of the flow chart shown in FIG. 1 with regard to the acquisition of second parameter data and FIG

Fig. 3 is a third detail view of the flowchart shown in Fig. 1 with respect to the execution of a forming treatment according to a preferred embodiment. Fig. 1 shows a flow chart of a method for forming an electrochemical cell according to an embodiment of the present invention. The electrochemical cell has a first conductor having a first forming contacting section and a second conductor having a second forming contacting section. The forming unit has a first contact element for the first Formierungskontaktierungs- section of the first Abieiters and a second contact element for the second Formierungskontaktierungsabschnitt of the second Abieiters.

In a step S1 a, the first contact element of the forming unit is pressed against the first forming contacting section of the first conductor. In a step S1 b, the second contact element of the forming unit is pressed onto the second Formierungskontaktierungsabschnitt the second Abieiters, wherein the steps S1a and S1 b can be performed simultaneously or in an arbitrary order to each other.

According to a preferred embodiment, first parameter data of the first contacting of the first contact element of the forming unit with the first forming contacting section of the first conductor is detected in a step S2a.

As can be seen from FIG. 2a, the step S2a of acquiring the first parameter data may comprise a step 2a 'of detecting a first transition Resistance of the first contacting of the first contact element of the forming unit with the first Formierungskontaktierungsabschnitt the first Abieiters and / or a step 2a "of detecting a first temperature of the first contact of the first contact element of the forming unit with the first Formierungskontaktierungsabschnitt the first Abieiters.

Furthermore, according to the preferred exemplary embodiment, second parameter data of the second contacting of the second contact element of the forming unit with the second forming contacting section of the second conductor can be detected in a step 2b, wherein steps S2a and S2b can be performed simultaneously or in an arbitrary order.

As can be seen from FIG. 2b, the step S2b of acquiring the second parameter data may comprise a step 2b 'of detecting a second transition resistance of the second contacting of the second contact element of the forming unit with the second forming contacting section of the second conductor and / or one step 2b "of detecting a second temperature of the second contacting of the second contact element of the forming unit with the second Formierungskontaktierungsabschnitt of the second Abieiters.

As can also be seen from FIG. 1, in a preferred exemplary embodiment, the detected first parameter data can be fed to a controller in a step S3a and the detected second parameter data can be fed to a controller in a step S3b, the steps S3a and S3b simultaneously or in a freely selectable order can be performed.

In these exemplary embodiments, in a step S4a, a change in the first contact can be carried out as a function of the detected first parameter data if the acquired first parameter data is a have the first threshold. Furthermore, in a step S4b, a change in the second contact can be carried out as a function of the detected second parameter data if the detected second parameter data have a predetermined second threshold value, wherein the steps S4a and S4b can be performed simultaneously or in an arbitrary order.

According to an embodiment, not shown in the figures, the step S4a of performing a change of the first contacting a step S4a 'of increasing a first pressure, with the first contact element is pressed onto the first Formierungskontaktierungsabschnitt the first Abieiters have. Further, the step S4b of performing a change of the second contacting may include a step S4b 'of increasing a second pressure with which the second contact member is pressed onto the second forming contacting portion of the second conductor.

Fig. 1 shows that in the method of the present invention, a forming treatment of the electrochemical cell is performed in a step S5, and Fig. 3 shows a flow chart of a preferred embodiment for carrying out the forming treatment of electrochemical cells. In a step S5a, a first formation of the electrochemical cell, preferably in a range of 25 to 40% of the rated capacity is performed, and in a step S5b, a second forming of the electrochemical cell, preferably in a range of 75 to 90% of the rated capacity is performed, and in a step S5c, a third forming of the precursor of the electrochemical cell, preferably to 100% of the rated capacity is performed.

In the method of the present invention, after the step S5 of performing a forming treatment of the electrochemical cell, the first forming contacting portion is separated in a step S6a, and the second forming contacting portion is formed in a step S6b separated, wherein the steps S6a and S6b can be performed simultaneously or in an arbitrary order arbitrary order.

LIST OF REFERENCE NUMBERS

S1a pressing the first contact element of the forming unit onto the first forming contacting section of the first

Abieiters

S1 b pressing the second contact element of the forming unit on the second Formierungskontaktierungsabschnitt second Abieiters

S2a detecting first parameter data of the first contacting of the first contact element of the forming unit with the first Formierungskontaktierungsabschnitt the first Abieiters

S2a 'detecting a first transition resistance of the first

Contacting the first contact element of the forming unit with the first Formierungskontaktierungsabschnitt the first Abieiters

S2a "detecting a first temperature of the first contact of the first contact element of the forming unit with the first Formierungskontaktierungsabschnitt the first Abieiters

S2b detecting second parameter data of the second contacting of the second contact element of the forming unit with the second forming contacting section of the second

Abieiters

S2b 'detecting a second transition resistance of the second

Contacting the second contact element of the forming unit with the second Formierungskontaktierungsabschnitt of the second Abieiters

S2b "detecting a second temperature of the second contacting of the second contact element of the forming unit with the second Formierungskontaktierungsabschnitt the second

Abieiters Supplying the acquired first parameter data to a controller supplying the acquired second parameter data to a controller

control

Performing a first contacting change in

Dependency of the detected first parameter data when the detected first parameter data has a predetermined first threshold value

Increasing a first pressure with which the first contact element is pressed onto the first Formierungskontaktierungsabschnitt the first Abieiters

Performing a second contacting change in

Dependency of the detected second parameter data when the detected second parameter data has a predetermined second threshold value

Increasing a second pressure with which the second contact element is pressed onto the second Formierungskontaktierungsabschnitt the second Abieiters

Performing a Forming Treatment

Performing a first forming of the electrochemical cell in a range of 25 to 40% of the rated capacity

Performing a second forming of the electrochemical cell in a range of 75 to 90% of the rated capacity, performing a third forming of the electrochemical cell to 100% of the rated capacity

Separating the first forming contacting portion separating the second forming contacting portion

Claims

claims

A method for forming a first Abieiter and a second Abieiter having electrochemical cell for a preferably designed for use in motor vehicles battery by means of a first contact element and a second contact element having forming unit, wherein the first Abieiter a first, separable Formierungskontaktierungsabschnitt and the second Abieiter a second, detachably formed Formierungs- contacting section, characterized in that the method comprises the following steps:

(S1 a) pressing the first contact element of the forming unit onto the first forming contacting section of the first conductor,

(S1 b) pressing the second contact element of the forming unit onto the second forming contacting section of the second conductor,

(S5) performing a forming treatment

(S6a) separating the first forming contacting portion from the first absorber and

(S6b) separating the second forming contacting portion from the second absorber.

A method according to claim 1, characterized in that the step (S1a) of pressing the first contact element is performed such that surface layers of the first Formierungskontaktierungs- section are pierced and / or that the step (S1 b) of pressing the second contact element is carried out in such a way in that surface layers of the second formation-contacting section are pierced. A method according to claim 1 or 2, characterized in that the first contact element of the forming unit has at least one tip and that the second contact element of the forming unit has at least one tip.

Method according to one of claims 1 to 3, characterized in that the first contact element is designed as a first number of first contact pins and / or that the second contact element is formed as a second number of second contact pins.

A method according to claim 4, characterized in that the first contact pins are mounted individually and / or that the second contact pins are mounted individually.

Method according to one of claims 1 to 5, characterized in that the first contact element has at its contacting end at least one contact prongs having crown and / or that the second contact element has at its contacting end at least one contact prongs having crown.

Method according to one of claims 1 to 6, characterized in that after the step (S1a) of pressing the first contact element, the method further comprises the following steps:

(S2a) acquiring first parameter data of the first contacting of the first contact element of the forming unit with the first forming contacting section of the first conductor,

(S3a) supplying the acquired first parameter data to a controller and

(S4a) performing a first contacting change in

Dependency of the acquired first parameter data when the detected first parameter data a predetermined first

Have threshold,

and / or that after the step (S1 b) of the pressing of the second contact element, the method further comprises the following steps:

(S2b) detecting second parameter data of the second contacting of the second contact element of the forming unit with the second forming contacting section of the second

Abieiters,

(S3b) supplying the acquired second parameter data to a

Control and

(S4b) performing a second contacting change in

Dependency of the detected second parameter data when the detected second parameter data has a predetermined second threshold value.

A method according to claim 7, characterized in that the step (S2a) of acquiring first parameter data of the contacting comprises at least one of the following steps:

(S2a ') detecting a first transition resistance of the first

Contacting the first contact element of

Forming unit with the first forming-contacting section of the first Abieiters and / or,

(S2a ") detecting a first temperature of the first contact of the first contact element of the forming unit with the first Formierungskontaktierungsabschnitt the first Abieiters and / or that the step (S2b) of detecting second parameter data of the contacting at least one of the following steps:

(S2b ') detecting a second transition resistance of the second

Contacting the second contact element of

Forming unit with the second Formierungs- contacting section of the second Abieiters and / or (S2b ") detecting a second temperature of the second contact of the second contact element of the forming unit with the second Formierungskontaktierungsabschnitt the second

Abieiters.

Method according to Claim 7 or 8, characterized in that the step (S4a) of carrying out a first contacting change comprises the following step:

(S4a ') increasing a first pressure with which the first contact element is pressed onto the first forming contacting section of the first conductor,

and / or that the step (S4b) of performing a second

Contacting change comprises the following step:

(S4b ') increasing a second pressure with the second one

Contact element is pressed onto the second Formierungskontaktierungs- section of the second Abieiters.

Method according to one of claims 1 to 9, characterized in that the step (S5) of carrying out a forming treatment comprises the following steps:

(S5a) performing a first forming of the electrochemical cell in a range of 25 to 40% of the rated capacity,

(S5b) performing a second forming of the electrochemical cell in a range of 75 to 90% of the rated capacity and

(S5c) Performing a third forming of the electrochemical cell at 100% of the rated capacity.

Electrochemical cell having a first collector having a separably formed first forming contacting section and a second collector having a second separable forming contacting section, characterized indicates that the electrochemical cell has been formed by a method according to one of the preceding claims.

Electrochemical cell according to claim 1 1, characterized in that the first Formierungskontaktierungsabschnitt is disposed at an outer end of the first Abieiters and / or that the second Formierungskontaktierungsabschnitt is disposed at an outer end of the second Abieiters.

Battery having at least one electrochemical cell, characterized in that the electrochemical cell has been formed according to one of the methods 1 to 10.