KR100445091B1 - A lithium battery's cathode insertion mechanism and method - Google Patents

Abstract

The present invention relates to a device and an insertion method used in the cathode insertion process when assembling a barbin type lithium battery, and more particularly, a plurality of compression jig in the process of inserting the cathode inside the battery case when assembling the barbin type lithium battery. It relates to a cathode insertion mechanism and an insertion method of the barbin type lithium battery that can reduce the incidence of defective products due to breakage of the separator by minimizing the friction with the cathode by fixing the separator in the outward direction.

Description

A lithium battery's cathode insertion mechanism and method

The present invention relates to a device for use in the cathode insertion process when assembling the barbin-type lithium battery, and more particularly, using a plurality of pressing jig in the process of inserting the cathode inside the battery case during assembly of the barbin-type lithium battery. The present invention relates to a cathode insertion mechanism and an insertion method of a barbin type lithium battery capable of reducing the incidence of defective products due to breakage of the separator by minimizing friction with the cathode by fixing the separator outward.

In general, in accordance with the trend of small size and light weight due to the convenience of portable electronic and electronic devices, the technology of the battery field has been remarkably developed, and high-energy high-density type batteries are absolutely necessary to achieve light and small shortness of electrical and electronic equipment.

Proposed in accordance with this trend is a lithium battery, the energy density of a lithium battery using lithium as a negative electrode largely depends on the positive electrode active material. As an example, lithium batteries are used as power supply means for supplying current in radios, computers and consumer electronics, and in many electronic equipment having data backup functions.

The lithium battery is used in many electronic devices because of the advantage that it can supply a constant current for a long time despite the small size, such a lithium battery is assembled in the following way.

FIG. 1 is a view illustrating an assembly process of an existing barbin type lithium battery, and as shown in the drawing, a lithium battery device 2 having a terminal piece connected to a cylindrical battery case 1 having an open upper surface. Insert it into position.

A thin plate-like separator 3 is inserted into the lithium battery device 2 in a vacuum state.

At this time, the separator 3 is difficult to be inserted in a perfect circle for physical properties.

After mounting the separator 3 inside the lithium battery device 2, the lower insulating film 4 is punched out and inserted into the lower surface of the battery case 1.

The separator 3 serves to prevent the cathode 5 from contacting the battery case 1, and the lower insulating layer 4 must be fixed without damage because it prevents a short circuit of the lithium battery device 2. .

After the separator 3 and the lower insulating film 4 are inserted and fixed, the cylindrical shaped cathode 5 is inserted on the central axis of the battery case 1.

In the case of manufacturing a lithium battery by the above-described process, when the cathode is inserted in a state in which the separator is not fixed after the insertion of the separator inside the battery case is completed, the separator may be damaged due to friction between the lower surface of the cathode and the upper end of the separator. There is a problem that a defective product is generated by damage, to solve this problem it was required to assemble a lithium battery by manual.

However, the completeness of lithium battery assembly changes according to the skill of the operator, and the number of assembly personnel must be increased to increase production, but it is not easy to train a worker with the required skill for assembly in a short time. There is a problem that the construction of a dry room is expensive.

An object of the present invention devised to solve the above problems is to minimize the friction between the separator and the cathode that is inserted and fixed in the battery case in the insertion process for inserting the cathode inside the battery case during the assembly process for manufacturing a lithium battery It is intended to reduce the incidence of defective products due to damage to the separator.

In order to achieve the object of the present invention as described above, when the cathode is inserted, the cathode is pressed upwards and downwards to closely contact the upper spindle and the upper end of the separator and the lower spindle on which the battery case is supported. Provided is a cathode insertion mechanism of a barbin type lithium battery comprising a pressing jig and a table on which a pressing jig upper and lower sliders for moving the pressing jig outward are provided.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view showing an assembling process of a conventional barbin type lithium battery.

2 is a view showing an assembly process of a lithium battery using a cathode insertion mechanism according to an embodiment of the present invention.

3 is a flow chart showing an assembling process of a barbin type lithium battery.

4 is a cross-sectional view illustrating a cathode insertion mechanism of a barbin type lithium battery according to an embodiment of the present invention;

5A is a sectional view of the structure of the upper slider;

Fig. 5B is a sectional view showing the structure of a crimping jig.

5C is a cross-sectional view illustrating a structure of a lower slider.

<Brief description of symbols for the main parts of the drawings>

10: battery case 20: lithium battery element

30: lower insulating film 40: isolation film

50: cathode 100: cathode insertion mechanism

200: upper spindle 210: cathode compression

220: cathode carrier compression unit 300: table

310: compression jig 312: lip

314: first side bolt hole 320: upper slider

322: upper through hole 324: upper protrusion

326: support portion 328: upper bolt hole

330: lower slider 332: lower through hole

334: lower protrusion 336: lower bolt hole

338: second side bolt hole 340: cathode carrier

350: horizontal axis elastic bolt 360: longitudinal axis elastic bolt

400: lower spindle 410: cell carrier

Hereinafter, a cathode insertion mechanism and an insertion method of a barbin type lithium battery according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is a view showing an assembly process of a lithium battery using a cathode insertion mechanism according to an embodiment of the present invention, Figure 3 is a flow chart showing an assembly process of a barbin type lithium battery.

As shown in the drawing, the lithium battery element 20 having the terminal piece connected to the inside of the battery case 10 is inserted and positioned. (ST 10)

The lower insulating film 30 is punched and inserted into the lower surface of the battery case 10 having the lithium battery device 20 inserted therein. (ST 20)

The lower insulating film 30 is inserted to insert a thin separator 40 in a vacuum state inside the battery case 10 fixed to the lower surface in a vacuum state. (ST 30)

After inserting the separator 40, the upper end portion of the separator 40 may be adhered to the outside using the pressing jig 310 having the ′ -shaped bent shaped lips 312. (ST 40)

The cylindrical cathode 50 is inserted onto the central axis of the battery case 10 in a state where the upper end of the separator 40 is in close contact with the outside by the pressing jig 310. (ST 50)

The crimping jig 310 primarily serves to fix the separator 40 to the outside. The crimping jig 310 is mounted in a divided state at an angle of 120 degrees. Secondly, the crimping jig 310 serves as a guide guide. By minimizing friction with the separator 40 during insertion, problems such as breakage of the separator 40 and poor assembly appearance are prevented from occurring.

4 is a cross-sectional view showing a cathode insertion mechanism of a barbin type lithium battery according to an embodiment of the present invention, Figure 5a is a cross-sectional view showing the structure of the upper slider, Figure 5b is a cross-sectional view showing the structure of the crimping jig. 5C is a cross-sectional view illustrating the structure of a lower slider.

As shown in the figure, the cathode insertion mechanism 100 presses the cathode 50 upwards and downwards to insert the upper spindle 200 and the cathode 50 into the inside of the battery case 10. Compression jig 310 for contacting the lower spindle 400 and the separator 40 supporting the battery case 10 and upper and lower sliders 320 and 330 for moving the compression jig 310 in a left and right direction are provided. The table 300 is mounted.

The upper spindle 200 is formed in a cylindrical shape and the cathode compression unit 210 for pressing the cathode 50 inserted into the inside of the cathode carrier 340 from the upper direction to the lower direction ' It is formed of a carrier compression unit 220 that has a cross-sectional shape of 'shape and presses the upper surface of the cathode carrier 340 from the upper direction to the lower direction.

The cathode carrier 340 is formed in the upper surface of the table 300 is formed in a cylindrical shape, the hole 50 is inserted into the central axis, the upper slider 320 is located below the cathode carrier 340 The upper slider 320 is fastened up and down reciprocatingly to the lower slider 330 fixed to the table 300 by using a transverse elastic fastening bolt 350, and the upper slider 320 and the lower part. When the cathode 50 is inserted between the slider 330, the pressing jig 310 for tightly contacting the upper end of the separator 40 in the left and right directions allows the left and right reciprocating movement to be performed using the longitudinal axis elastic fastening bolt 360. It is installed.

The upper slider 320 has a cross-sectional shape having a 'TT' shape, and an upper protrusion 324 having an upper through hole 322 through which the cathode 50 passes through is formed in a central portion of a lower side thereof. At one side portion, the support portion 326 having a square cross-sectional shape is formed symmetrically with respect to the central axis, and at one side, an upper bolt hole 328 into which the coupling portion of the longitudinal elastic bolt 360 is inserted is formed. .

The inclined surface of the upper protrusion 324 is in contact with the upper edge surface of the pressing jig 310 is formed.

The lower slider 330 is' A lower protrusion 334 having a lower through hole 332 through which the cathode 50 penetrates is formed at a central portion of the lower portion of the lower through hole 332. The inclined portion having a gradient is formed, and the lower side bolt hole 336 into which the body portion of the longitudinal elastic bolt 360 is inserted is formed on one side of the lower surface, and the second side bolt hole into which the transverse elastic bolt 350 is inserted. 338 is formed.

One side surface of the pressing jig 310 is formed with a lip 312 having a cross-sectional shape bent in a '-' shape, the inclined surface in contact with the edge surface of the upper protrusion 324 is formed on the upper side corner. On the other side, a first side bolt hole 314 into which the fastening portion of the transverse elastic bolt 350 is inserted is formed.

The upper side of the lower spindle 400 is a cell carrier 410 is formed in a cylindrical shape formed with a hole through which the battery case 10 passes through the central axis.

Referring to the operation of the cathode insertion mechanism of the barbin-type lithium battery according to an embodiment of the present invention having the configuration as described above, the upper slider 320 in the state that the cathode 50 is inserted into the cathode carrier 340. When positioned on the upper surface of the cathode carrier compression unit 220 of the upper spindle 200 is lowered downward to press the upper surface of the cathode carrier 340.

Then, the cathode carrier 340 is pushed in the upper slider 320 which is in contact with the lower side while moving downward, the upper slider 320 is in contact with the upper protrusion 324 while moving in the downward direction The pressing jig 310 is moved in the left and right direction to closely contact the separator 40 inserted into the battery case 10 with the inclined portion of the lower slider 330.

In addition, when the cathode compression unit 210 of the upper spindle 200 starts to descend, pressing the cathode 50 inserted into the cathode carrier 340 in the downward direction, the cathode 50 increases the inner diameter of the upper slider 320. While passing, the pressing jig 310 is inserted into the battery case 10 using the guide guide as a guide.

The present invention having the configuration described above can reduce the damage of the separator generated during the insertion of the cathode in the assembly process of the barbin type lithium battery can reduce the incidence of defective products, the role of six skilled workers as a machine It can be carried out has the effect of improving the work productivity.

Claims (2)

In the cathode insertion mechanism used in the process of inserting the cathode inside the battery case when assembling the barbine-type lithium battery, the cathode compression unit 210 and ' An upper spindle 200 formed of a carrier compression unit 220 that presses an upper surface of the cathode carrier 340 downwardly while having a cross-sectional shape of a 'shape'; The upper surface of the cathode carrier is inserted into the cathode 50 is inserted on the central axis, the lower side of the cathode carrier using the transverse elastic fastening bolt 350 is located in the upper slider to be able to reciprocate vertically downward movement Table 300, the pressing jig is mounted between the upper slider and the lower slider to enable the left and right reciprocating movement; A lip 312 having a cross-sectional shape bent in a 'b' shape is formed on one side, and an inclined surface in contact with a corner surface of the upper protrusion 324 is formed on an upper side corner, and a horizontal axis on the other side. A compression jig 310 having a first side bolt hole 314 into which the fastening portion of the elastic bolt 350 is inserted; The upper projection 324 is formed at the center of the lower side while having a 'TT' shaped cross section, and the support 326 having a square cross section at one side of the lower side is formed symmetrically about the central axis. An upper slider 320 formed at one side thereof with an upper bolt hole 328 into which the coupling portion of the longitudinal elastic bolt 360 is inserted; An upper through hole 322 is formed in the center of the upper slider 320 and passes through the cathode 50 on a central axis. An inclined surface in contact with an upper edge of the pressing jig 310 is formed at a corner thereof. An upper protrusion 324 formed; ' A lower protrusion 334 having a lower through hole 332 through which the cathode 50 penetrates is formed at a central portion of the lower portion of the lower through hole 332. The inclined portion having a gradient is formed, and the lower side bolt hole 336 into which the body portion of the longitudinal elastic bolt 360 is inserted is formed on one side of the lower surface, and the second side bolt hole into which the transverse elastic bolt 350 is inserted. A lower slider 330 on which 338 is formed; A cathode carrier 340 formed in a cylindrical shape and having a hole in which a cathode 50 is inserted on a central axis thereof, the cathode carrier 340 being located on an upper surface of the table 300; A lower spindle 400 supporting the battery case 10 when the cathode 50 is inserted; It is formed into a cylindrical cylindrical hole on the center axis through which the battery case 10 passes through, the barbin-type lithium battery, characterized in that consisting of the cell carrier 410 located on the upper side of the lower spindle 400 Cathode insertion mechanism. A method of installing a cathode in which a cathode is inserted into a battery case by using a cathode insertion mechanism when assembling a barbine-type lithium battery, wherein the battery case 10 into which the lithium battery element 20 to which the terminal pieces are connected is inserted is positioned. Step (ST 10); Inserting the lower insulating film 30 into the lower surface of the battery case 10 in which the lithium battery device 20 is inserted inside (ST 20); Inserting the lower insulating film 30 in a vacuum state in a state in which a thin separator 40 is wound inside the battery case 10 in a state where the lower insulating film 30 is fixed to the lower surface (ST 30); Inserting the separator 40 and then pressing the upper end of the separator 40 outwardly using a pressing jig 310 (ST 40); And inserting the cylindrical cathode 50 into the inside of the battery case 10 in a state in which the upper end of the separator 40 is in close contact with the outside by the pressing jig 310 (ST 50). The cathode insertion method of a barbine-type lithium battery.