DE102018008613A1 - Apparatus and method for the electrochemical incorporation or deposition of alkali metals in an electrode - Google Patents

Abstract

The invention relates to a device (1) for the electrochemical incorporation or deposition of alkali metals in at least one electrode (2) for lithium-sulfur battery cells. The device (1) according to the invention comprises at least one receiving unit (3). The receiving unit (3) comprises two mutually attachable alkali metal clamping frame (3.1, 3.2) for clamping each at least one alkali metal body (5) and at least one between in the attached state of the alkali metal clamping frame (3.1, 3.2) between the alkali metal bodies (5) formed receiving space for receiving an electrode (2) and at least two nonwoven layers. Furthermore, at least two nonwoven layers are provided, wherein a first nonwoven layer is provided for an arrangement between the electrode (2) and a first alkali metal body (5) in the receiving space and a second nonwoven layer to an arrangement between the electrode (2) and a second alkali metal body in the receiving space , In addition, an electrolyte bath (6) with an electrolyte liquid for receiving the electrode (2) and the at least two nonwoven layers filled receiving unit (3) and for immersing the filled receiving unit (3) is provided in the electrolyte liquid, and at least one energy source for applying the alkali metal body (5) and the electrode (2) with electric current.
The invention further relates to a method for the electrochemical incorporation or deposition of alkali metals in at least one electrode (2) for lithium-sulfur battery cells.

Description

The invention relates to a device for the electrochemical incorporation or deposition of alkali metals in at least one electrode for lithium-sulfur battery cells.

The invention further relates to a process for the electrochemical incorporation or deposition of alkali metals in at least one electrode for lithium-sulfur battery cells. The JP 2016 139624 A discloses an electrode laminate body for an energy storage device manufactured by an electrolytic treatment step for doping lithium into an active material of an electrode body having an active material pattern on its surface to obtain a doped electrode body. A lamination of the doped electrode body, a counter electrode and a separator are described. In the electrolytic treatment step, the electrode body, a lithium electrode facing the active material pattern and having a wider area than the active material pattern, and a rectifier plate having an electrically insulating frame portion disposed between the electrode body and the lithium electrode and the peripheral edge portion of the Active material pattern covered and obscured, infiltrated in electrolyte solution. The electrode body and the lithium electrode are connected to each other via an external circuit, for example, a DC power source, to dope lithium into the active material of the electrode body.

In the EP 3 086 386 A1 For example, an intercalation of lithium ions into an electrode material of silicate powder in an electrolyte bath is described. In this case, a spacer for receiving and holding the electrode material and for immersing it in the electrolyte bath is provided.

The invention is based on the object to provide a comparison with the prior art improved device and an improved method for the electrochemical incorporation or deposition of alkali metals in at least one electrode for lithium-sulfur battery cells.

With regard to the device, the object is achieved by the features specified in claim 1 and in terms of the method by the features specified in claim 3.

The device is designed for the electrochemical storage or deposition of alkali metals in at least one electrode for lithium-sulfur battery cells, wherein the electrode is in particular a lithium-containing anode and / or a sulfur-carbon cathode. The device according to the invention comprises at least one receiving unit. The receiving unit comprises two mutually attachable alkali metal clamping frames for clamping each of at least one alkali metal body and at least one formed between in the attached state of the alkali metal clamping frame between the alkali metal bodies receiving space for receiving an electrode and at least two nonwoven layers. Furthermore, at least two nonwoven layers are provided, wherein a first nonwoven layer is provided for an arrangement between the electrode and a first alkali metal body in the receiving space and a second nonwoven layer to an arrangement between the electrode and a second alkali metal body in the receiving space. In addition, an electrolyte bath with an electrolyte liquid for receiving the filled with the electrode and the at least two nonwoven layers receiving unit and for immersing the filled receiving unit is provided in the electrolyte liquid, and at least one energy source for charging the alkali metal body and the electrode with electric current.

By the device it is possible to achieve a homogeneous intercalation of alkali metals over the entire surface of an electrode for lithium-sulfur battery cells. Likewise, a loading of the electrode with different alkali metals is controllable.

In the method for the electrochemical incorporation or deposition of alkali metals in at least one electrode, for example in a lithium-containing anode and / or in a sulfur-carbon cathode, for lithium-sulfur battery cells is according to the invention in two attachable to each other alkali metal clamping frame of a receiving unit at least one alkali metal body clamped. In addition, a first nonwoven layer is applied to a first alkali metal body, the electrode is applied to the first nonwoven layer, a second nonwoven layer is applied to the electrode and the alkali metal clamping frame with a second alkali metal body is applied to the second nonwoven layer. In addition, the alkali metal tenter with a second alkali metal body is attached to the other alkali metal tenter with the first alkali metal body. In addition, the accommodating unit filled with the electrode and the at least two nonwoven layers is introduced into an electrolyte bath with electrolytic liquid and immersed in the electrolytic liquid, and electric current is applied to the alkali metal bodies and the electrode so that alkali metal ions are leached out of the alkali metal bodies and intercalated into the electrode ,

By this method, it is possible that a homogeneous intercalation of alkali metals over the entire surface of an electrode, as well as a loading with different alkali metals is controllable.

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

• 1 schematisch eine Darstellung einer ersten Ausführungsform einer Vorrichtung zur elektrochemischen Einlagerung oder Abscheidung von Alkalimetallen in zumindest eine Elektrode,
• 2 schematisch eine Darstellung einer weiteren Ausführungsform einer Vorrichtung zur elektrochemischen Einlagerung oder Abscheidung von Alkalimetallen in zumindest eine Elektrode und
• 3 schematisch eine Darstellung einer Elektroden-Aufnahmeeinheit einer Vorrichtung gemäß 2.

Showing:

• 1 1 is a schematic representation of a first embodiment of a device for the electrochemical incorporation or deposition of alkali metals into at least one electrode;
• 2 schematically a representation of another embodiment of a device for electrochemical incorporation or deposition of alkali metals in at least one electrode and
• 3 schematically a representation of an electrode-receiving unit of a device according to 2 ,

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

In 1 is a possible embodiment of a device according to the invention 1 for electrochemical incorporation or deposition of alkali metals in at least one electrode 2 for lithium-sulfur battery cells shown schematically. The device 1 includes a receiving unit 3 containing a first alkali metal tenter 3.1 and a second alkali metal tenter 3.2 includes. An alkali metal tenter 3.1 . 3.2 is planar and includes projections 4 ,

In addition, on the alkali metal tenter 3.1 laterally a device 1 for fixing the second alkali metal tensioning frame 3.2 educated. Between the alkali metal clamping frames 3.1 . 3.2 is formed a receiving space. On the first alkali metal tenter 3.1 is a planar alkali metal body 5 arranged. A second alkali metal body lying on the second alkali metal tenter 3.2 is arranged, is not shown in detail.

An electrode 2 is between two nonwoven layers in the receiving space between the alkali metal tenter 3.1 . 3.2 arranged. The electrode 2 and the two nonwoven layers are not shown in detail. At the electrode 2 this is, for example, a lithium-containing anode. The lithium-containing anode may be formed as a metal-containing electrode, preferably of a silicon material. In addition, it is possible that the electrode 2 is designed as a sulfur-carbon cathode.

In addition, there is an electrolyte bath 6 provided, which can be filled with an electrolyte fluid, not shown. The electrolyte bath 6 includes a valve 7 for filling or emptying the electrolyte bath 6 ,

The electrode 2 is in the assembled state of the device 1 formed by the application of an electric current through a power source, not shown, as a negative electrical pole or as an electrical positive pole. The alkali metal tenter 3.1 . 3.2 with the alkali metal bodies 5 are designed as an electrical positive pole or as an electrical negative pole. Is a positive pole to the Alkalispannrahmen 3.1 . 3.2 and the alkali metal bodies 5 applied, so become alkali metal atoms of the alkali metal body 5 Removed electrons, whereby alkali metal ions are formed. These alkali metal ions can move freely dissolved in the electrolyte liquid. At the electrode 2 These alkali metal ions receive electrons, resulting in a homogeneous intercalation of alkali metal ions over the entire surface of the electrode 2 comes. In a reverse polarity takes place on the electrode doped with alkali metal atoms 2 a formation of alkali metal ions instead of and on the alkali metal bodies 5 the alkali metal tensioning frame 3.1 . 3.2 a formation of alkali metal atoms.

The between the alkali metal body 5 of the first alkali metal tenter 3.1 and the electrode 2 arranged nonwoven layer, as well as between the electrode 2 and the alkali metal body 5 of the second alkali metal tenter 3.2 arranged nonwoven layer are formed as spacers which a spatial distance between the alkali metal tenter 3.1 . 3.2 and the electrode 2 form. The nonwoven layers are permeable to the electrolyte liquid.

By a fixing device, the two alkali metal tenter 3.1 . 3.2 the nonwoven layers and the electrode 2 in the recording room. As a result, a fixation of the nonwoven layers and the electrode 2 given. By means of the projections 4 is a hanging of the receiving unit 3 into the electrolyte bath 6 and thus a storage thereof in the electrolyte liquid of the electrolyte bath 6 possible.

The electrolyte bath 6 is designed as a trough, which for uniform distribution of the electrolyte fluid and the inclusion of the receiving unit 3 serves. This makes it possible for the alkali metal ions to move in the electrolyte liquid when subjected to electric current.

In 2 schematically is another embodiment of a device 1 for the electrochemical incorporation or deposition of alkali metals in at least one electrode 2 for lithium-sulfur battery cells shown.

In the illustrated embodiment, multiple alkali metal tenter frames are used 17 , as well as several electrode recording units 8th as they are in 3 are shown in more detail, alternately in an electrolyte bath 6 arranged. The electrolyte bath 6 includes a valve 7 , an electrolyte fluid, not shown, and one in the electrolyte bath 6 inserted bracket 9 , where the holder 9 two flat, arranged on opposite sides of the tub spring devices 10 includes. Additionally are at the electrolyte bath 6 connections 11 arranged for applying an electric current through a power source, not shown.

In 3 is an electrode-receiving unit 8th a device 1 according to 2 displayed. The electrode receiving unit 8th includes a U-shaped lower frame part 12 , a middle connecting bridge 13 and an upper frame part 14 with side connection hooks 15 , In addition, in the two vertical sides of the electrode receiving unit 8th two connecting rods each 16 in the lower frame part 12 , the middle connecting bridge 13 and the upper frame part 14 integrated.

In the electrode receiving unit 8th is an electrode 2 insertable and fixable, wherein it is at the electrode 2 For example, it may be a lithium-containing anode and / or a sulfur-carbon cathode. Through the connection hooks 15 of the upper frame part 14 becomes the electrode receiving unit 8th in the holder 9 of the electrolyte bath 6 attached.

In the in 2 illustrated alkali metal clamping frame 17 is a planar alkali metal body 5 fixable. Several alkali metal tenter frames 17 and electrode receiving units 8th are in changing order in the holder 9 inserted. In this case, at least one electrode receiving unit 8th between two alkali metal tenter frames 17 arranged. Thereby, it is possible that by applying an electric current to the power source in the electrolytic liquid in the electrolytic bath 6 to a homogeneous intercalation of alkali metal ions over the entire surface of the electrode 2 comes.

Through the connections 11 at the electrolyte bath 6 is on the bracket 9 an application of an electric current possible. This will be a positive electrical pole or a negative negative pole to the alkali metal clamping frame 17 and the alkali metal bodies 5 generated.

The spring devices 10 allow for fixation of the alkali metal tenter 17 and the electrode receiving units 8th in the holder 9 provided a capacity of the device 1 with alkali metal tenter 17 and electrode receiving units 8th not completely filled.

LIST OF REFERENCE NUMBERS

1

device

2

electrode

3

recording unit

3.1

Alkali metal clamping frame

3.2

Alkali metal clamping frame

4

head Start

5

Alkali metal body

6

electrolyte

7

Valve

8th

Electrode receiving units

9

holder

10

spring device

11

connection

12

frame part

13

connecting web

14

frame part

15

connecting hook

16

connecting rods

17

Alkali metal clamping frame

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been 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.

Cited patent literature

• JP 2016139624 A [0002]
• EP 3086386 A1 [0003]

Claims (3)

Device (1) for the electrochemical storage or deposition of alkali metals in at least one electrode (2) for lithium-sulfur battery cells, characterized by - at least one receiving unit (3), comprising two attachable to each other alkali metal clamping frame (3.1, 3.2) for clamping each at least an alkali metal body (5) and comprising at least one receiving space formed between the alkali metal bodies (5) between the alkali metal bodies (5) for receiving an electrode (2) and at least two nonwoven layers, at least two nonwoven layers, wherein a first Nonwoven layer is provided for an arrangement between the electrode (2) and a first alkali metal body (5) in the receiving space and a second nonwoven layer for an arrangement between the electrode (2) and a second alkali metal body in the receiving space, - an electrolyte bath (6) with an electrolyte liquid for holding with the electrode (2) and the at least two nonwoven layers filled receiving unit (3) and for immersing the filled receiving unit (3) in the electrolyte liquid and - at least one energy source for acting on the alkali metal body (5) and the electrode (2) with electric current. Device (1) according to Claim 1 , characterized in that the at least one electrode (2) is formed as a lithium-containing anode and / or sulfur-carbon cathode. Process for the electrochemical incorporation or deposition of alkali metals in at least one electrode (2) for lithium-sulfur battery cells, characterized in that - in each case at least one alkali metal body (5) clamped in two attachable to each other alkali metal clamping frame (3.1, 3.2) of a receiving unit (3) a first nonwoven layer is applied to a first alkali metal body (5), the electrode (2) is applied to the first nonwoven layer, a second nonwoven layer is applied to the electrode (2), the alkali metal clamping frame (3.2) is provided with a second alkali metal body is applied to the second nonwoven layer and is attached to the further alkali metal clamping frame (3.1) with the first alkali metal body 5, - with the electrode (2) and the at least two nonwoven layers filled receiving unit (3) in an electrolyte bath (6) with a Electrolyte fluid is introduced and immersed in the electrolyte liquid and - the Alkalimeta Electric body (5) and the electrode (2) are subjected to electric current such that alkali metal ions are dissolved out of the alkali metal bodies (5) and intercalated into the electrode (2).

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