KR101435752B1 - Fixing Mould Of Lithium Battery and Sealing Method By Using the Same - Google Patents

Abstract

The present invention relates to an anode bar fixing mold of a lithium battery and a method for a sealing anode bar of a lithium battery header using the same. The purpose of the present invention is to form the fixing mold using a material with a coefficient of expansion identical or similar to the header and to construct a housing block in which a molten insulating member is not attached to a portion where an insulating layer is formed such that the header and the fixing mold can be expanded or contracted identically or similarly in heating and cooling processes, thereby maintaining a concentric state between a seating hole of the header and the anode bar. To this end, the present invention provides a fixing mold to form an insulating layer between a header and anode bars. The fixing mold (20) includes one or more block insert grooves (26) at points where the anode bars (11) are positioned, and includes housing blocks (30) inserted into the block insert grooves (26), each having a second insert groove (32) where one end of the anode bar (11) is inserted to be fixed, and configured to support an insulating member forming an insulating layer (12); the fixing mold (20) is made of a material with a coefficient of expansion identical or similar to the header (10); and the housing block (30) is made of a material which is not fused when the insulating member is molten by heating.

Description

Technical Field [0001] The present invention relates to a positive electrode rod fixing method for a lithium battery, and a method for sealing a positive electrode of a lithium battery header using the fixed die,

The present invention relates to a positive electrode rod fixing method of a lithium battery and a method of sealing a positive electrode rod of a lithium battery header using the same, and more particularly, to a method of sealing a positive electrode rod of a lithium battery using a fixed mold, The header and the stationary mold having the same thermal expansion coefficient are expanded and contracted in the same manner during the heating and cooling processes by constituting the housing block in which the insulating member dissolved in the insulating layer is not formed, The present invention relates to a positive electrode rod fixing die of a lithium battery and a method of sealing a positive electrode of a lithium battery header using the same.

Generally, a battery is composed of an anode (+ pole), a cathode (- pole), and an electrolyte, and is classified into various kinds depending on what materials are used for the anode and cathode. A battery using lithium as a cathode is called a lithium battery, and electric energy is generated by the flow of electrons generated by the oxidation reaction of lithium.

The lithium battery has been widely used in a variety of fields from general households such as portable electronic devices such as mobile phones and portable notebooks to high-precision electronic devices for military use such as tanks and missiles because of its large charging capacity and miniaturization.

Meanwhile, the lithium battery includes a header formed in the battery body, at least one or more anode rods provided in the header, and an insulation layer for insulating the header and the anode rods.

As described above, a method of forming the insulating layer between the header and the anode rod will be described as follows.

First, as shown in FIG. 1, the header 10 is seated on a stationary mold 20.

The stationary mold 20 is provided with a seating groove 22 in which the header 10 is seated. Also, the stationary mold 20 is provided with an insertion groove 24 having a predetermined depth so that one end of the anode rod 11 is inserted and fixed in position.

That is, after the header 10 is seated in the seating groove 22 of the stationary mold 20, the anode rod 11 is inserted into the insertion groove 24 and fixed.

When the insulating member 12 is inserted between the inner hole 13 of the header 10 and the anode rod 11, the insulating member 12 is inserted into the hole 13 of the header 10 and the electrode rod 11 11). The insulating member is glass.

Thereafter, when the stationary mold 20 is placed in a continuous hydrogen furnace and heated in the continuous hydrogen furnace at 1000 to 1050 DEG C for about 30 minutes, the glass insulating member is melted and the head 10 and the anode bar 11 are formed.

After completion of heating in the continuous hydrogen furnace, the stationary mold is cooled to about one hour by water cooling, and the process of inspecting the anode rod 11 in the header 10 is completed through a cleaning process and a quality inspection process.

However, since the coefficient of thermal expansion is different due to the difference of the material forming the fixed mold and the header, the cathode rod 11 can not maintain a concentric circle state in the air hole 13 of the header 10 during the heating and cooling process , There is a problem that the insulating layer 12 which is eccentrically eccentric to one side is defective.

That is, as shown in FIG. 2, the stationary mold 20 is made of carbon, and the header 10 is made of stainless steel (SUS). The coefficient of thermal expansion is about 4 for carbon and about 13.2 for stainless steel and has a distinct difference of about 3 times from the coefficient of thermal expansion.

As a result, stainless steel reacts more sensitively than carbon during heating and cooling, while carbon reacts dull.

The header 10 is placed in the seating groove 22 of the stationary mold 20 made of carbon and the center of the fixed mold 20 located in the center of the seat hole 13 of the header 10 The anode rod 11 is inserted and fixed in the insertion groove 24 to maintain a concentric state between the air hole 13 and the anode rod 11. [

Thereafter, due to the heating with the continuous hydrogen, the header 10 made of stainless steel sensitively expands and the position of the above-mentioned air hole 13 is changed. On the other hand, the fixed mold 20 of the carbon is hardly inflated The position of the positive electrode rod 11 fixed to the insertion groove 24 is not changed.

Further, in the cooling process, the expanded header 10 shrinks, but the shrinkage action does not occur by compensating for the expansion due to heat, and the amount of shrinkage varies depending on the surrounding environment. On the other hand, The anode rod 11 is insulated to the header 10 in a state eccentric to either one of them without maintaining the concentric state between the air hole 13 of the header 10 and the anode rod 11. Therefore, The insulating layer 12 that maintains the state is defective.

Such defective insulation layer has a problem that the function of the lithium battery is disrupted by the breakage of the insulation layer 12 by weakening the fixation force of the anode rod 11 due to the deflection.

On the other hand, since the glass is excellent in affinity with metals, it is used as a material for securing the anode rod 11 to the header 10 while insulating it.

Accordingly, when a fixed mold is formed of the same material as the header 10 so as to achieve the same thermal expansion and contraction in order to solve the above-described problem of insulation layer failure, There arises a problem that it is adhered not only to the rod 11 but also to the stationary metal mold 20.

As a result, the fixed mold is formed of carbon which is not adhered to the molten glass.

However, the above-described carbon fixed die has a problem that it is difficult to form a uniform insulating layer 12 between the header 10 and the anode bar 11 due to the difference in thermal expansion coefficient.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems, and it is an object of the present invention to provide a method of manufacturing a semiconductor device, in which a fixed mold is formed of a material having the same or similar thermal expansion coefficient as a header, The positive electrode rod fixing die of the lithium battery which maintains the concentric state of the seating hole and the positive electrode of the header by expanding and contracting the same header and the fixed die having the same thermal expansion coefficient during the heating and cooling process by constituting the housing block, And a method of sealing the anode of a lithium battery header using a fixed mold.

According to an aspect of the present invention, there is provided a stationary mold for forming an insulating layer between a header and a cathode bar, wherein the stationary mold includes one or more block insertion grooves Being; And a housing block inserted in the block insertion groove and formed with a second insertion groove into which the one end of the anode rod is inserted and fixed and supporting the insulation member forming the insulation layer; The fixed die is made of a material having the same or similar thermal expansion coefficient as the header; And the housing block is formed of a material that is not fused when the insulating member is dissolved by heating.

In the present invention, it is preferable that the stationary die is stainless steel having the same material as the header.

In the present invention, it is preferable that the housing block is carbon.

A method of sealing a cathode of a lithium cell header in which an insulating layer is formed between a header and a cathode rod, comprising the steps of: placing a header in a seating groove of a stationary mold formed with the same or similar thermal expansion coefficient; Inserting and fixing one end of a positive electrode into a second inserting groove of a housing block provided in the stationary mold in a state where a header is seated on the stationary mold through the header seating step; Inserting an insulating member so that an insulating layer is formed between the header and the anode bar in a state where the anode bar is inserted through the anode bar inserting step; The insulating member is inserted between the header and the anode bar through the insulating member inserting step, the insulating member is heated by heating the stationary mold having the header mounted thereon, and the heated stationary mold and the header have the same or similar thermal expansion coefficient So that the same or similar expansion action is caused by the heating member; And cooling the fixed mold and the header with the same or similar contraction action by the same or similar thermal expansion coefficient by cooling in a state where the insulating member is melted through the insulating member heating step, The insulating layer being in a state of being in contact with the insulating layer.

According to the present invention, a stationary mold is formed of a material having the same or similar thermal expansion coefficient as that of the header, and the housing block in which the insulating member dissolved in the insulating layer is formed is formed, The header having the coefficient and the fixed die expand and contract in the same manner, so that the concentric state of the seat and the anode bar of the header can be maintained.

1 is an exploded perspective view and a partially enlarged cross-sectional view of a conventional header and a fixed mold;
2 is a plan view showing a state of expansion and contraction between a conventional header and a fixed die;
3 is an exploded perspective view of a header and a stationary mold according to the present invention.
4 is a sectional view of a stationary mold according to the present invention;
5 is a plan view showing a state of expansion and contraction between a header and a stationary die according to the present invention;
6 is a process diagram of forming an insulating layer between a header and a cathode rod according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. (The same reference numerals are used for the same components as the conventional ones, and a detailed description thereof will be omitted).

As shown in Fig. 3, the stationary metal mold 20 of the present invention is formed with a seating groove 22 in which a header 10 is seated inside, and one or more The block seating groove 26 is formed.

Also, a housing block 30 is inserted and fixed in the block seating groove 26.

In the housing block 30, a second insertion groove 32 is formed so that one end of the anode rod 11 is inserted and fixed.

The stationary mold 20 is formed of a material having the same or similar thermal expansion coefficient as the header 10 and the housing block 30 is formed of a material in which an insulating member forming the insulating layer 12 is not fused do.

That is, the stationary mold 20 is formed of the same stainless steel as the header 10, and the housing block 30 is carbon.

A sealing method for inserting the anode bar into the header by the above-described stationary metal mold is as follows.

6, in the header seating step S1, the header 10 is seated in the seating groove 22 of the stationary metal mold 20.

In the step of inserting the positive electrode bar (S2), the header (10) is placed on the stationary mold (20) through the header seating step (S1) One end of the positive electrode rod 11 is inserted and fixed to the second insertion groove 32 of the block 30.

The insulating member inserting step S3 is a step of inserting the anode bar 11 into the second inserting groove 32 of the housing block 30 through the inserting step S2, An insulating member for forming the insulating layer 12 is inserted between the grounding electrode 13 and the electrode rod 11.

At this time, the insulating member remains in a state of being seated on the upper end of the housing block 30 fixed to the stationary metal mold 20.

The insulating member heating step S4 may be performed by inserting one end of the anode rod 11 into the second insertion groove 32 of the housing block 30 through the inserting member inserting step S3, The fixed mold 20 which is made of the same material as that of the header 10 expands as shown in Fig. 5 and the same thermal expansion Expansion works equally due to the coefficient.

The expansion of the stationary mold 20 causes the housing block 30 inserted and fixed in the stationary mold 20 to move in the expansion direction, The expanding action is performed while maintaining the concentric circles 11 in the circumferential direction.

In the insulation member cooling step S5, when the heating process is completed through the insulation member heating step S4, the cooling process is performed. In this case, too, the header 10 and the stationary metal mold 20, The same shrinking action is performed with the same thermal expansion coefficient and the housing block 30 inserted and fixed to the stationary mold 20 is moved along the shrinking direction of the stationary mold 20, (13) and the anode rod (11) are kept in a concentric state while a contracting action is performed.

Since the housing block 30 is made of carbon, the insulating member of the insulating layer 12 dissolved by the continuous heating furnace is prevented from being welded to the stationary mold 20, The header 10 is easily removed.

Accordingly, the stationary mold is formed of a material having the same or similar thermal expansion coefficient as the header, and the housing block is configured to prevent fusion of the insulating member to the stationary mold due to dissolution, So that a uniform insulating layer is formed.

The above description is only one embodiment for carrying out the method of sealing the anode of the lithium cell header using the anode rod fixing die of the lithium battery and the fixing die, and the present invention is not limited to the above embodiment. It will be understood by those skilled in the art that various changes may be made without departing from the spirit of the invention.

10: Header 11: Bipolar rod
12: insulation layer 13:
20: stationary mold 22: seat groove
24: insertion groove 26: block seating groove
30: housing block 32: second insertion groove

Claims (4)

An insulative layer is formed between a header and a positive electrode rod. The stationary mold (20)
One or more block insertion grooves 26 are formed at a position where the anode rods 11 are located;
A housing block 30 (not shown) which is inserted into the block inserting groove 26 and in which a second inserting groove 32 is formed in which one end of the anode rod 11 is inserted and fixed, );
The stationary mold 20 is made of a material having the same or similar thermal expansion coefficient as the header 10;
The housing block 30 is formed of a material that is not fused when the insulating member is dissolved by heating;
Wherein the positive electrode rod-fixing metal mold of the lithium battery comprises:
The method according to claim 1,
The stationary mold 20 is made of stainless steel having the same material as the header 10;
Wherein the positive electrode rod fixing die of the lithium battery is characterized in that
The method according to claim 1 or 2,
The housing block 30 may include carbon;
Wherein the positive electrode rod fixing die of the lithium battery is characterized in that
A method for sealing a cathode of a lithium battery header in which an insulating layer is formed between a header and a cathode rod,
A step (S1) of placing a header in a seating groove of a stationary mold formed with the same or similar thermal expansion coefficient;
(S2) for inserting and fixing one end of a positive electrode into a second inserting groove of a housing block provided in the stationary mold with a header mounted on the stationary mold through the header seating step (S1);
Inserting an insulating member (S3) for inserting an insulating layer between the header and the anode bar in a state where the anode bar is inserted through the anode bar inserting step (S2);
In the inserting step (S3), the insulating member is inserted between the header and the anode bar, and the insulating member is heated by heating the stationary mold having the header mounted thereon. An insulating member heating step (S4) for causing the same or similar expansion action to occur by a similar thermal expansion coefficient; And
The fixing mold and the header are cooled by the same or similar thermal expansion coefficient by the same or similar thermal expansion coefficient by cooling in a state where the insulating member is melted through the insulation member heating step (S4) An insulating member cooling step (S5) for forming an insulating layer in a concentric circular state;
The method of claim 1,

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