Dual coating method for electrode

Abstract

Provided is a dual coating method for an electrode, which coats the electrode of a battery. The dual coating method for an electrode includes transferring the electrode, coating the transferred electrode with a first coating solution, and coating the primarily-coated electrode with a second coating solution different from the first coating solution.

Claims

1. A dual coating method for an electrode, the method comprising: transferring the electrode, wherein the electrode has a surface which is formed of a metal material; coating the transferred electrode with a first coating solution to form a primarily-coated electrode; and then coating only a portion of the primarily-coated electrode with a second coating solution different from the first coating solution except for an area defining a curved surface, wherein the area defining the curved surface is coated with only the first coating solution to prevent cracking.

2. The dual coating method of claim 1, wherein the first coating solution has a slurry form and superior adhesion characteristics with respect to the metal material of the surface of the electrode when compared to those of the second coating solution.

3. The dual coating method of claim 1, wherein the first coating solution has porosity less than that of the second coating solution.

4. The dual coating method of claim 1, wherein the second coating solution is composed of an active material having a mean particle size greater than that of the first coating solution.

5. The dual coating method of claim 1, wherein the second coating solution comprises a rubber-based binder.

6. A dual coating method for an electrode, the method comprising: coating an electrode with a first coating solution to form a primarily-coated electrode with a first coated-region, wherein the electrode has a surface which is formed of a metal material; and coating only a portion of the first coated-region of the primarily-coated electrode with a second coating solution different from the first coating solution except for an area defining a curved surface, wherein the area defining the curved surface is coated with only the first coating solution.

7. The dual coating method of claim 6, wherein the first coating solution has a slurry form and superior adhesion characteristics with respect to the metal material of the surface of the electrode when compared to those of the second coating solution.

8. The dual coating method of claim 6, wherein the first coating solution has porosity less than that of the second coating solution.

9. The dual coating method of claim 6, wherein the second coating solution comprises an active material having a mean particle size greater than that of the first coating solution.

10. The dual coating method of claim 6, wherein the second coating solution comprises a rubber-based binder.

11. The dual coating method of claim 1, wherein the area defining the curved surface is a winding core.

12. The dual coating method of claim 6, wherein the area defining the curved surface is a winding core.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The above and other aspects, features and other advantages of the present invention will be more clearly understood from the following detailed description taken in conjunction with the accompanying drawings, in which:

(2) FIG. 1 is a flowchart of a dual coating method for an electrode according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

(3) Exemplary embodiments of the present invention will now be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the exemplary embodiments. Like reference numerals refer to like elements throughout.

(4) FIG. 1 is a flowchart of a dual coating method for an electrode according to an embodiment of the present invention.

(5) As shown in FIG. 1, the dual coating method for an electrode according to an embodiment of the present invention includes a transfer process (S1) of transferring an electrode, a first coating process (S2) of coating the transferred electrode with a first coating solution, and a second coating process (S3) of coating the primarily-coated electrode with a second coating solution that is prepared from a material different from the first coating solution.

(6) In general, the transfer process (S1) may be performed by using a conveyer or transfer belt which is used for transferring the electrode while the electrode of the secondarily battery is manufactured.

(7) The first coating process (S2) may be a process of coating the electrode transferred in the transfer process (S1) with the first coating solution. A material having superior adhesion characteristics with respect to a surface of a metal such as the electrode that is provided in the form of slurry may be used as the first coating solution.

(8) That is, the first coating solution may be prepared from a material that is capable of improving adhesion force with a surface of the electrode formed of a metal material. In the current embodiment, an active material such as lithium cobalt oxide (LCO) and nickel manganese cobalt oxide (NMC) is used as the first coating solution, but is not limited thereto.

(9) Also, a polyvinylidene difluoride (PVDF) binder having low electric resistance may be mixed in a binder that is used as the first coating solution so that the binder is physically attached to the surface of the metal such as the electrode.

(10) The second coating process (S3) may be a process of coating a portion of the electrode, which is coated with the first coating solution in the first coating process (S2), with a second coating solution different from the first coating solution.

(11) Here, the second coating solution is applied to only a portion of the electrode except for an area defining a curved surface such as a winding core. Thus, the area defining the curved surface may be coated with only the first coating solution.

(12) That is, the coating may be performed only once on the area defining the curved surface such as the winding core to minimize a thickness of the coated slurry, thereby previously preventing cracks from occurring in the curved surface that is formed when wound.

(13) This is done because tensile force applied to a surface of the coating layer increases to increase possibility of occurrence of the cracks when the coating layer increases in thickness on the curved area.

(14) Also, since adhesion force with respect to the first coating solution is required for the second coating solution, an active material having a specific surface area greater than that of the first coating solution may be used as the second coating solution. Thus, the first coating solution having a relatively small specific surface area may be filled into the second coating solution to increase a contact area of the active material, thereby improving the adhesion force.

(15) Although lithium iron phosphate (LFP) or lithium titanate (LTO) that is an active material having a relatively large specific surface area when compared to that of the first coating solution is used as the second coating solution in the current embodiment, the present invention is not limited thereto. For example, the material of the second coating solution may be determined in consideration of the specific surface area of the first coating solution.

(16) Also, BN-730H manufactured by Zeon Ltd., in which rubber-based butadiene is added to increase liquidity may be used as a binder of the second coating solution.

(17) The above-described first and second coating solutions may change in composition by using active materials different from each other or binders different from each other.

(18) Also, the second coating solution is composed of an active material having a mean particle size greater than that of the first coating solution to provide porosity greater than that of the first costing solution. Thus, a phenomenon in which higher compressive force is transmitted to the electrode by compression occurring when a rolling process is performed on the electrode may be offset to prevent the performance of the battery from being deteriorated.

(19) In the above-described dual coating method for the electrode according to the present invention, only the primary coater may be used for the coating of the winding core so that the electrode slurry is applied to a relatively low thickness when compared to those of other portions. In case of the portion having low possibility in occurrence of the cracks, the secondarily coater may be used to increase the coating amount of electrode slurry. Thus, when the battery is manufactured, all of the stability and performance of the battery may be satisfied. In addition, the primarily slurry having the good adhesion characteristics with respect to the surface of the metal that is a collector may be primarily applied, and then, the secondarily slurry having the good adhesion characteristics with respect to the slurry may be applied to the primarily slurry to efficiently utilize the characteristics of the battery.

(20) According to the present invention, only the primary coater may be used for the coating of the winding core so that the electrode slurry is applied to a relatively low thickness when compared to those of other portions. In case of the portion having low possibility in occurrence of the cracks, the secondarily coater may be used to increase the coating amount of electrode slurry. Thus, when the battery is manufactured, all of the stability and performance of the battery may be satisfied.

(21) According to the present invention, the primarily slurry having the good adhesion characteristics with respect to the surface of the metal that is the collector may be primarily applied, and then, the secondarily slurry having the good adhesion characteristics with respect to the slurry may be applied to the primarily slurry to efficiently utilize the characteristics of the battery.

(22) While the dual coating method for the electrode has been described with reference to the exemplary drawings, it will be apparent to those skilled in the art that modifications and variations can be made without departing from the spirit and scope of the invention as defined by the appended claims.