EP2710660A1 - Method for selecting electrochemical cells during the production of a battery and battery having electrochemical cells - Google Patents

Abstract

The invention relates to a method for selecting electrochemical cells during the production of a battery that has a number of electrochemical cells, said method having the following steps: (S1) detecting the parameter data (D_Par.) of an individual cell that is to be analysed; (S2) transmitting the detected parameter data (D_par.) to a control unit; (S3) assigning the detected parameter data (D_Par.) to the electrochemical cell; and (S4) determining for the electrochemical cell that has been allocated the parameter data if a predefined relationship exists between the parameter data (D_Par.) and predefined parameter values (W_Par, W_par.1, W_Par.2, W_Par.3. W_{Par 4}, W_Par.5) by means of the control unit. The method can further have the following steps: (S5a) feeding the electrochemical cell that has been assigned the parameter data (D_Par.) to a first production line for producing a first type of battery, if in step (S4) the existence of a predefined relationship has been determined; or (S5b) feeding the electrochemical cell that has been assigned the parameter data (D_Par.) to a second production line for producing a second type of battery, if in step (S4) the non-existence of a predefined relationship has been determined.

Description

 Method for selecting electrochemical cells in the manufacture of a battery and battery having electrochemical cells

 Description

The invention relates to a method for selecting electrochemical cells in the manufacture of a battery having a number of electrochemical cells, and a battery produced by this method.

Electrochemical energy stores, also referred to below as electrochemical or galvanic cells, are often produced in the form of stackable units, from which by combining a plurality of such cells batteries for different applications, in particular for use in electrically powered vehicles can be produced. The invention will be described in relation to the use in a motor vehicle, although it should be pointed out that such a method and a correspondingly designed electrochemical cell also independent of motor vehicles z. B. can be operated in a stationary operation.

Hereby we the entire contents of the priority application DE 102011 101793 by reference part of the present application.

Various methods of manufacturing a battery having a number of electrochemical cells are known in the prior art. It is an object of the present invention to provide an improved method for selecting electrochemical cells in the manufacture of a battery, having a number of electrochemical cells, and to provide a corresponding battery.

This object is achieved by a method for selecting electrochemical cells in the manufacture of a battery according to claim 1 and by a battery according to claim 13. The dependent claims relate to advantageous developments of the invention.

According to a first aspect, in a method for selecting electrochemical cells in the manufacture of a battery having a number of electrochemical cells, this object is achieved in that the method comprises the steps of: acquiring parameter data of an individual electrochemical cell to be examined for assessing the quality the electrochemical cell, transmitting the acquired parameter data to a control unit, assigning the electrochemical cell to the parameter data, and determining by means of the control unit whether there is a predetermined relationship of the parameter data with respect to predetermined parameter values for the electrochemical cell assigned to the parameter data. An advantage of this method is that in view of an application of the batteries to be selected, the production yield can be increased from the point of view of cost, quality and design. In particular, the electrochemical cells for the battery or the battery assembly can be selected in a selectively predetermined quality. So z. As the batteries are used with a first, preferably increased quality for the original equipment, while the batteries can be used with a second, preferably normal quality for the aftermarket. Furthermore, z. B. the batteries are used with a third grade for stationary application.

In this context, an electrochemical cell is to be understood as meaning an electrochemical energy store, that is to say a device which stores energy in chemical form, delivers it in electrical form to a consumer and preferably also in electrical form from a charging device. can accommodate device. Important examples of such electrochemical energy stores are galvanic cells or fuel cells. The electrochemical cell has at least a first and a second device for storing electrically different charges, and a means for producing an electrical active connection of these two devices, wherein charge carriers can be moved 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.

In this context, parameter data should be understood to mean not only a plurality of parameter data, but possibly also a single parameter data. Accordingly, in this context, not only a number of predetermined parameter values but, if appropriate, also a single predetermined parameter value should be understood by predetermined parameter values. It has proved to be advantageous if the step of determining by means of the control unit has at least one of the following determining steps: determining whether the transmitted parameter data have predetermined first parameter values and / or determining whether the transmitted parameter data does not have predetermined second parameter values. Preferably, the step of determining by means of the control unit has at least one of the following determining steps: determining whether the transmitted parameter data exceed predetermined third parameter values and / or determining whether the transmitted parameter data falls below predetermined fourth parameter values. Furthermore, the method may include at least one of the supplying steps of: supplying the electrochemical cell assigned to the parameter data to a first production line for producing a first type of batteries when determining the presence of the predetermined relationship in the step of determining or supplying the parameter data assigned electrochemical cell to a second production line for producing a second type of batteries, if in the step of determining a non-existence of the predetermined relationship is determined.

In addition, the step of determining by means of the control unit may comprise the step of determining whether the parameter data is within at least one predetermined parameter value range by a predetermined fifth parameter value.

In the method, it has proven to be advantageous if, for the supply to a first production line for the production of hybrid cell batteries, a first parameter value range is 1.2%, preferably 0.6%.

Furthermore, it has proven to be advantageous if, for the supply to a second production line for the production of plug-in hybrid batteries, a second parameter value range is 3%, preferably 1.5%, whereby preferably the parameter data of the electrochemical cells which are the second production value. line are outside of, in particular outside the preferred parameter range of the aforementioned first embodiment.

Furthermore, it has proved to be advantageous if, for the supply to a third production line for the production of electric vehicle batteries or device batteries, a third parameter value range is 4.5%, preferably 2.2%, wherein preferably the parameter data of the electrochemical cells which supply the third production line are outside, in particular outside the preferred parameter range of the first embodiment mentioned above, and / or preferably the parameter data of the electrochemical cells, which are to be supplied to the third production line, outside of, in particular outside the preferred parameter range of the second embodiment mentioned above.

Furthermore, it has proved to be advantageous if for the supply to a fourth production line for the production of batteries for stationary applications a fourth parameter value range is 50%, preferably 25%, wherein preferably the parameter data of the electrochemical cells to be supplied to the fourth production line are outside of, in particular outside the preferred parameter range of the first aforementioned exemplary embodiment, and / or preferably the parameter data of electrochemical cells to be supplied to the fourth production line, outside the, in particular outside the preferred parameter range of the second aforementioned embodiment, and / or preferably the parameter data of the electrochemical cells to be supplied to the fourth production line, outside the, in particular outside the preferred parameter range of the third embodiment mentioned above.

Preferably, at least one of the parameter data of the electrochemical cell has been selected from a parameter group comprising at least one of the following parameters: quiescent voltage of the electrochemical cell, capacity of the electrochemical cell, internal resistance of the electrochemical cell, change of internal resistance of the electrochemical cell after application of a pressure, preferably on side surfaces of the electrochemical cell or internal pressure of the electrochemical cell. Particularly preferably, the internal resistance of the electrochemical cell is used during or after the finishing in particular applying a pressure across the side surfaces of the electrochemical cell as a parameter data, preferably at least three or more resistors are used. In this regard, the change in the internal resistance of the electrochemical cell upon application of pressure to side surfaces of the electrochemical cell has proven to be a preferred parameter for evaluating the quality of an electrochemical cell. When a pressure is applied to an electrochemical cell and the electrochemical cell yields, the internal resistance changes. Therefore, a pressure can be applied to the electrochemical cell and the change of the internal resistance can be measured. The electrochemical cells, which are relatively hard and their internal resistance After applying a pressure on the side surfaces little changed, no longer gase after closing. On the change of the internal resistance with respect to the pressure change can thus be a particularly simple assignment of the electrochemical cell to different types of quality and thus to corresponding production lines. As a result, the quality z. For example, with the following relationship, where dR, the change of the internal resistance and dF, the change of the applied force means:

quality parameters

 dF

According to a second aspect, this object is achieved in a battery having a number of electrochemical cell in that the battery has been manufactured according to one of the above-mentioned manufacturing method.

It has proved advantageous if the battery is designed into a battery which has been selected from a battery group comprising: plug-in hybrid batteries, hybrid cell batteries, electric vehicle batteries, device batteries or batteries for stationary applications.

In addition, the electrochemical cell of the battery may additionally have a storage device designed to store a quality value.

Furthermore, the present invention relates to a battery with electrochemical cells, which is designed for use in a motor vehicle.

In the following, advantages of the invention with reference to preferred embodiments and with the aid of figures will be described in more detail. Showing:

1 shows a flowchart for a method according to the invention for selecting electrochemical cells in the manufacture of a battery according to a first exemplary embodiment, a flow chart for an inventive method for selecting electrochemical cells in the manufacture of a battery according to a second embodiment,

 a flow chart for an inventive method for selecting electrochemical cells in the manufacture of a battery according to a third embodiment,

 a flow chart for an inventive method for selecting electrochemical cells in the manufacture of a battery according to a fourth embodiment,

 a flow chart for an inventive method for selecting electrochemical cells in the manufacture of a battery according to a fifth embodiment,

 a flowchart for a method according to the invention for producing a battery according to a sixth embodiment and a flow chart for a modification of the inventive method for selecting electrochemical cells in the manufacture of a battery.

1 shows a flowchart for a method according to the invention for selecting electrochemical cells in the manufacture of a battery according to a first exemplary embodiment. In a step S1, parameter data D _par . detected an electrochemical cell to be examined. In a step S2, the parameter data D _par . transmitted to a control unit and in a step S3 are assigned to this parameter data D _Par the electrochemical cell. By means of the control unit it is determined whether these parameter data Dpar. a predetermined relationship with respect to predetermined parameter values Wpar. exhibit. If the parameter data D _par . the predetermined relationship with respect to the predetermined parameter values W _Par . , the electrochemical cell is fed to a first production line for producing a first type of battery. Otherwise, if the parameter data D _par . the predetermined relationship with respect to the predetermined parameter values W _Par . do not have, the electrochemical cell is supplied to a second production line for producing a second type of batteries.

2 shows a flowchart for a method according to the invention for selecting electrochemical cells in the production of a battery according to a second embodiment, whose steps S1 to S3 correspond to those of the first embodiment, to which reference is made in order to avoid repetition.

By means of the control unit it is determined whether these parameter data D _Par . predetermined first parameter values W _Par .i. If the parameter data Dp _a r. the predetermined first parameter values Wp _ar .i, the electrochemical cell is fed to a first production line for producing a first type of battery. Otherwise, if the parameter data D _par . If the predetermined first parameter values W _Par. i do not exist, the electrochemical cell is supplied to a second production line for producing a second type of battery.

3 shows a flowchart for a method according to the invention for selecting electrochemical cells in the manufacture of a battery according to a third exemplary embodiment, whose steps S1 to S3 correspond to those of the first exemplary embodiment, to which reference is made in order to avoid repetitions.

By means of the control unit it is determined whether these parameter data D _Par . predetermined second parameter values W _Par . ₂ do not have. If the parameter data Dp _ar . the predetermined second parameter values W _Par . ₂ , the electrochemical cell is fed to a first production line for producing a first type of battery. Otherwise, if the parameter data Dp _ar . having the predetermined second parameter values W _Par .2, the electrochemical cell is supplied to a second production line for producing a second type of battery. Fig. 4 shows a flow chart for a method according to the invention for selecting electrochemical cells in the manufacture of a battery according to a fourth embodiment, whose steps S1 to S3 correspond to those of the first embodiment, to which reference is made to avoid repetition.

By means of the control unit, it is determined whether these parameter data D _Par exceed predetermined third parameter values W _{Par 3} . If the parameter data Dpar. the predetermined third parameter values Wp _ar . ₃ , the electrochemical cell is fed to a first production line for producing a first type of battery. Otherwise, if the parameter data D _par . the predetermined third parameter values Wp _ar . ₃ , the electrochemical cell is fed to a second production line for producing a second type of battery.

5 shows a flowchart for a method according to the invention for selecting electrochemical cells in the manufacture of a battery according to a fifth exemplary embodiment, whose steps S1 to S3 correspond to the first exemplary embodiment, to which reference is made in order to avoid repetitions.

By means of the control unit it is determined whether these parameter data D _Par. Predetermined fourth parameter values W _Par . ₄ do not exceed. If the parameter data D _Par falls below the predetermined fourth parameter values W _{Par 4} , the electrochemical cell is fed to a first production line for producing a first type of battery. Otherwise, if the parameter data D _par . If the predetermined fourth parameter values W _{Par are} not undershot, the electrochemical cell is fed to a second production line for producing a second type of battery.

6 shows a flow chart for a method according to the invention for selecting electrochemical cells in the manufacture of a battery according to a sixth exemplary embodiment, whose steps S1 to S3 correspond to those of the first embodiment. guide example, to which reference is made to avoid repetition.

By means of the control unit, it is determined whether these parameter data D _Par are within a predetermined parameter range by a predetermined fifth parameter value W _{Par 5} . If the parameter data D _Par is within the predetermined parameter range around the predetermined fifth parameter value W _Par .5, the electrochemical cell is fed to a first production line for producing a first type of battery. Otherwise, if the parameter data D _par . are not within the predetermined parameter range by the predetermined fifth parameter value W _Par .5, the electrochemical cell is supplied to a second production line for producing a second type of batteries.

Fig. 7 shows a flow chart for a modification of the above-mentioned method according to the invention for selecting electrochemical cells in the manufacture of a battery whose steps S1 to S3 correspond to those of the first embodiment, to which reference is made to avoid repetition, and with each of the first to sixth embodiments can be combined.

This modification has the additional steps S4.1 and S4.2 after the step S3. In step S4.1, by means of the parameter data D _Par . a quality value is formed, which is stored in a storage unit arranged in or on the electrochemical storage cell in a step S4.2. The quality value can z. B. are used for a classification of the electrochemical storage cells z. B. can be used for subsequent manufacturing steps or investigations of the battery.

The present invention further relates to a battery having these electrochemical cells, in particular a designed for use in a motor vehicle battery having these electrochemical cells. LIST OF REFERENCE NUMBERS

 Dpar. parameter data

WPAR. predetermined parameter value

Wpar.i first predetermined parameter value

Wpar.2 second predetermined parameter value

Wpar.3 third predetermined parameter value

Wpar.4 fourth predetermined parameter value

Wpar.5 fifth predetermined parameter value

S1 acquiring parameter data of the electrochemical cell

S2 transmitting the acquired parameter data to a control unit

 53 Assigning the electrochemical cell to the parameter data

 54 determining by the control unit whether a predetermined relationship of the parameter data with respect to predetermined parameter values exists

S4.1 Forming at least one quality value by means of the parameter data

S4.2 storing the quality value in a in or on the electrochemical

Cell arranged storage unit

S4a determining whether the parameter data has predetermined first parameter values

 S4b Determine whether the parameter data does not have predetermined second parameter values

 S4c Determine if the parameter data exceeds predetermined third parameter values

 S4d Determine whether the parameter data falls below predetermined fourth parameter values

S4e determining whether the parameter data is within a predetermined parameter value range by a predetermined fifth parameter value

S5a supplying the electrochemical cell to a first production line for producing a first type of batteries when a presence of the predetermined relationship is determined Supplying the electrochemical cell to a second production line for producing a second type of batteries when a non-existence of the predetermined relationship is determined

Claims

claims

A method of selecting electrochemical cells in the manufacture of a battery comprising a number of electrochemical cells, characterized in that the method comprises the steps of:

(51) acquiring parameter data (D _Par. ) Of an individual electrochemical cell to be examined for evaluating the quality of the electrochemical cell,

(52) transmitting the parameter data (D _Par .) To a control unit,

(53) assigning the electrochemical cell to the parameter data (Dpar), preferably storing the parameter data (Dp _a r.) To the electrochemical cell, and

(54) Determining by means of the control unit whether, for the electrochemical cell assigned to the parameter data, a predetermined relationship of the parameter data (D _Par .) With respect to predetermined parameter values (Wp _ar ., Wp _ar .

Wpar.2, Wpar.3, W _Pa r.4- Wpar.s).

Method according to Claim 1, characterized in that the step (S4) of determining by means of the control unit has at least one of the following determining steps:

(S4a) determining whether the transmitted parameter data (D _par .) Have predetermined first parameter values (W _Sw ti) or

(S4b) determining whether the transmitted parameter data (D _Par .) Do not have predetermined second parameter values (W _Sw t.2).

3. The method according to claim 1 or 2, characterized in that the step (S4) of determining by means of the control unit comprises at least one of the following determining steps: (S4c) determining whether the transmitted parameter data (D _par .) Exceeds predetermined third parameter values (W _Sw t.3) or

(S4d) determining whether the transmitted parameter data (D _Par .) Falls below predetermined fourth parameter values (Wswt.4).

Method according to one of claims 1 to 3, characterized in that the method comprises at least one of the feeding steps:

(S5a) supplying the electrochemical cell assigned to the parameter data (D _Par .) To a first production line for producing a first type of battery, when the presence of the predetermined relationship is determined in the step (S4) of determining, or

(S5b) supplying the electrochemical cell assigned to the parameter data (D _Par .) To a second production line for producing a second type of batteries when in step (S4) of determining a non-existence of the predetermined relationship is determined.

A method according to claim 4, characterized in that the step (S4) of determining by means of the control unit comprises a step:

(S4e) determining whether the transmitted parameter data (D _par .) Is within a predetermined parameter value range by a predetermined fifth parameter value (Wswt. ₅ ).

A method according to claim 5, characterized in that for the supply to a first production line for the production of hybrid cell batteries a first parameter value range is 1, 2%, preferably 0.6%. A method according to claim 5 or 6, characterized in that for the supply to a second production line for the production of plug-in hybrid batteries, a second parameter value range is 3%, preferably 1, 5%, wherein preferably the parameter data of the electrochemical cells, which be supplied to the second production line, outside the first, in particular outside the preferred first parameter range.

8. The method according to any one of claims 5 to 7, characterized in that for the supply to a third production line for the production of electric vehicle batteries or device batteries, a third parameter value range is 4.5%, preferably 2.2%, preferably the parameter data of the electrochemical cells which are to be supplied to the third production line, lie outside the first, in particular outside the preferred first parameter range, and / or preferably the parameter data of the electrochemical cells which are to be supplied to the third production line are outside the second, in particular outside the preferred second parameter range.

Method according to one of claims 6 to 8, characterized in that for the supply to a fourth production line for the production of batteries for stationary applications, a fourth parameter value range is 50%, preferably 25%, wherein preferably the parameter data of the electrochemical cells, that of the fourth production line are outside the first, in particular outside the first preferred parameter range, and / or preferably the parameter data of the electrochemical cells to be supplied to the fourth production line, outside the second, in particular outside the preferred second parameter range, and / or preferably the parameter data the electrochemical cells which are to be supplied to the fourth production line are outside the third, in particular outside the preferred third parameter range. Method according to one of the preceding claims, characterized in that at least one of the parameter data (D _Par .) Of the electrochemical cell has been selected from a parameter group comprising at least one of the following parameters:

 Open circuit of the electrochemical cell,

 Capacity of the electrochemical cell,

 Internal resistance of the electrochemical cell,

 Changing the internal resistance of the electrochemical cell after applying a pressure, preferably on side surfaces of the electrochemical cell or

 Internal pressure of the electrochemical cell.

Method according to one of the preceding claims, characterized in that the method comprises the step:

 (54.1) forming at least one quality value by means of

Parameter data (D _Par .).

The method of claim 1 1, characterized in that the method comprises the step:

 (54.2) storing the quality value in a in or on the

 electrochemical cell arranged storage unit, which preferably has a permanent memory, in particular a flash memory.

Battery having a number of electrochemical cells, characterized in that the battery has been manufactured according to one of the preceding claims.

A battery according to claim 13, characterized in that the battery is configured into a battery selected from a battery group comprising:

Plug-in hybrid batteries Hybrid cell batteries,

 Electric vehicle batteries, portable batteries or

 Batteries for stationary applications

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