KR20140121628A - Adhesive method of film - Google Patents

Abstract

The present invention provides an apparatus and method for bonding a sealing film to a lead line with a rotary method capable of continuously bonding the sealing film to the upper and lower sides of the lead line by performing a thermal bonding operation with a fusion roller when the sealing film is continuously supplied to the upper and lower sides of the lead line which is outputted with the rotary method.

Description

[0001] The present invention relates to an adhesive method for adhering a sealing film to a lead wire by a rotary method,

The present invention relates to an apparatus and a method for bonding a sealing film to a lead wire, and more particularly, to an apparatus and a method for bonding a sealing film to a lead wire, And more particularly, to a device and a method for bonding a sealing film to a lead wire by a rotary method in which an operation of bonding a sealing film to the upper and lower surfaces of the lead wire can be continuously performed.

2. Description of the Related Art In general, portable electronic devices such as a video camera, a portable telephone, a portable computer, and a digital camera have been made lighter and more sophisticated, so that secondary batteries used as a driving power source thereof are small and lightweight, have high energy density, Development of excellent secondary batteries has been desired.

Examples of such secondary batteries include a nickel cadmium battery, a nickel hydrogen battery, a nickel zinc battery, and a lithium secondary battery. Among them, lithium secondary battery has a long lifetime and high energy density. In addition, the lithium secondary battery can be classified into a lithium metal battery using a liquid electrolyte and a lithium polymer battery using a lithium ion battery and a polymer solid electrolyte depending on the type of electrolyte.

A general structure of a lithium secondary battery generally referred to as a lithium secondary battery includes an electrode assembly having an anode and a cathode, a casing enclosing the periphery of the electrode assembly and filled with an electrolytic solution, and a cathode Positive / negative lead wires.

The positive lead wire 130 is formed by coating a lithium composite oxide capable of charging and discharging lithium ions on the aluminum foil in the case of the positive lead wire 130. The positive and negative lead wires 130, In the case of the lead wire 140, a carbon material capable of absorbing and desorbing lithium ions is applied to a nickel foil.

A sealing film as an insulating material is thermally fused to the surface of the positive / negative lead wire (hereinafter referred to as a lead wire), and the sealing film shields the direct contact between the lead wire and the electrolyte filled in the casing, Is prevented from reaching the lead wire, so that the reaction of the electrolyte, such as a short circuit, is prevented.

On the other hand, as a general method of thermally fusing a sealing film to the upper and lower surfaces of a lead wire, a lead wire is placed on a die by using a press method, and then the sealing film is placed on the upper and lower surfaces of the lead wire, The sealing film is adhered to the upper and lower surfaces.

However, such a pressing method can not continuously carry out the work as the step of positioning the sealing film on the lead wire placed on the die and the step of pressing the sealing film and the lead wire with the press are separately performed, The time required for the operation is required to be about 5 seconds, which results in a decrease in work productivity due to the molding.

SUMMARY OF THE INVENTION Accordingly, 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 lead wire, And a method of adhering a sealing film to a lead wire by a rotary method in which an operation of bonding a sealing film to a lead wire can be continuously performed.

According to an aspect of the present invention, there is provided an apparatus for bonding a sealing film to a lead wire in a rotary manner, the apparatus comprising: a take-up roll around which a lead wire is wound; a lead wire wound around the take- A preheating means provided in the lead wire drawing means for preheating lead wires in a drawing direction, and a preheating means provided in the lead wire drawing means for drawing the lead wires wound on the drawing roll, A sealing film cutting means including a take-out roller for intermittently pulling out a sealing film wound on the sealing film by a predetermined length and a cutter for cutting a sealing film drawn out by a predetermined length by driving of the take-out roller; And the sealing film cutting means is located between the lead wire drawing means And an arm connected to the holder at one end and coupled to a rotating shaft rotated at the other end by the power of the motor to rotate the holder by the operation of the rotating shaft, A rotary sealing film feeding means for supplying a sealing film adsorbed on the upper and lower surfaces of the lead wires and fusing the sealing films to the upper and lower surfaces of the lead wires; And a fusing unit comprising first to third fusing rollers for fusing the sealing film, wherein the lead wire to which the sealing film is fused is wound on the winding roll in a natural cooling state.

The present invention also provides a method of bonding a sealing film to a lead wire in a rotary manner, the method comprising: a lead wire withdrawing step of withdrawing a lead wire by winding a lead wire wound around a take- A sealing film cutting step of cutting the sealing film wound on the drawing roll to a predetermined length so that the sealing film can be fused to the upper and lower surfaces of the lead wire having passed through the preheating step; A rotary sealing film feeding step of sucking and fixing the cut sealing film in the sealing film cutting step and supplying the sealing film to the upper and lower surfaces of the lead wire while rotating the sealing film about the rotation axis to be fused, A sealing step of successively fusing a sealing film welded to the upper and lower surfaces of the sealing film, And characterized in that it consists of a cooling step, which ever was the natural cooling of the group lead, kept in the wound up roll.

In the present invention, the sealing film is thermally fused to the upper and lower surfaces of the lead wire with the first to third fusing rollers while the sealing film is continuously supplied to the upper and lower surfaces of the lead wire during drawing, It is not necessary to press the sealing film one by one into the press as in the case of the first embodiment, so that the working time can be remarkably reduced, thereby realizing an action effect that can dramatically increase the productivity of the work.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a diagram showing the entire configuration of an apparatus for bonding a sealing film to a lead wire by a rotary method according to the present invention. Fig.
FIGS. 2A and 2B are views sequentially showing the operation of a device for bonding a sealing film to a lead wire by a rotary method shown in FIG. 1. FIG.
3 is a view showing a process flow for bonding a sealing film to a lead wire using the apparatus shown in Fig.

Hereinafter, an apparatus and method for bonding a sealing film to a lead wire by a rotary method according to the present invention will be described with reference to one embodiment. However, the embodiments described below describe the best mode for carrying out the features and technical ideas of the present invention, and thus the present invention is not limited by the following embodiments.

{Example 1}

FIG. 1 is a view showing the entire construction of an apparatus for bonding a sealing film to a lead wire by a rotary method according to the present invention. FIGS. 2A and 2B show a rotary method in which a sealing film is bonded FIG. 2 is a view showing the operation of the apparatus in order.

As shown in Figs. 1 to 2A, an apparatus for bonding a sealing film to a lead wire by a rotary method of the present invention includes lead wire drawing means 10, preheating means 20, sealing film cutting means 30, A sealing film feeding means 50 and a fusing means 70.

The lead wire drawing means (10) is located on the opposite side of the drawing roll on which the lead wire is wound and on the drawing roll

The lead wire 100 wound around the drawing roll 12 is pulled out to the fusing means 60 disposed at the back of the lead wire drawing means 10.

The preheating means 20 is disposed at the rear of the lead wire drawing means 10 and before the lead wire 100 is supplied from the lead wire drawing means 10 to the fusing means 70, So that the sealing film 200 seated on the upper and lower surfaces of the lead wire 100 can be welded.

The lead wire 100 wound on the drawing roll 12 may be made of either nickel or aluminum. For example, when the lead wire 100 is used as a cathode wire in a rechargeable battery, the lead wire 100 ) Is made of nickel, and when the lead wire (100) is used as a positive electrode, the lead wire (100) is made of aluminum.

The sealing film cutting means 30 is disposed at a predetermined distance away from the lead wires 100 drawn out to the fusing means 70 and has the same structure as the lead wires 100. The sealing film 200 has a predetermined size (A size to cover the upper and lower surfaces of the substrate 100).

The sealing film cutting means 30 has the same structure and is disposed above and below the lead wire feeding means. In the following description, the structure of one sealing film cutting means 30 will be representatively described.

The sealing film cutting means 30 is disposed on the sealing film 200 wound on the drawing roll 32 and is rotated by the power of the servo motor 36 to rotate the sealing film 200 on the drawing roll 32 A die 38 for supporting the sealing film 200 which is disposed in front of the drawing roller 34 and supports the drawing film 200; And a cutter 40 for cutting the sealing film 200 passing through the die 38 in a downwardly positioned state.

An air flow path 41 for sucking and exhausting air is formed in the bottom surface of the cutter 40. The air flow path 41 is formed in the bottom surface of the cutter 40 by inserting a sealing film 200 passing through the die 38, And the sealing film 200 cut by the operation of the cutter 40 is blown to be accurately seated in the catch groove 60 of the holder 58 which is a rotary sealing film feeding means 50 .

A rubber roller 42 is disposed in front of the cutter 40. The rubber roller 42 is fixed to the upper surface of the cutter 40 using a tension force of a spring 44, So that the sealing film 200 is prevented from flowing during the cutting process.

The rotary sealing film feeding means 50 is provided between the lead wire drawing means 10 and the sealing film feeding means 30 and vacuum-adsorbs the sealing film 200 cut by the sealing film cutting means 30, Is rotated by the rotation shaft 54 and then supplied to the upper and lower surfaces of the lead wire 100. [

The rotary sealing film supply means 50 is connected to the motor 52 and rotates intermittently when the rotary sealing film supply means 50 is disposed above the lead wire 100 in the drawing An arm 56 mounted on the outer surface of the rotary shaft 54 and a sealing film 200 formed on the front end of the arm 56 and cut on the sealing film cutting means 30, And a holder 58 in which the holder groove 60 is recessed so that the holder 60 can be seated.

A suction path 64 is formed in the bottom surface of the holder groove 58 of the holder 58. The suction path 64 is formed in the bottom surface of the holder groove 58, The sealing film 200 seated on the sealing member 60 is vacuum-adsorbed.

A protrusion 62 protrudes from one side of the holder groove 60 of the holder 58. The protrusion 62 contacts the bottom surface of the sealing film 200 absorbed by the holder groove 60 The sealing film 200 is pressed against the bottom of the sealing film 200 to prevent the sealing film 200 from flowing.

When the sealing film 200 is cut to a predetermined length by driving the sealing film cutting means 30, the cut sealing film 200 is fed to the rotary sealing film feeding means 50, The rotary shaft 54 is intermittently rotated by the power of the motor 52 and the holder 58 is rotated and moved so that the lead wire drawing means The holder 58 is positioned on one side of the lead wire 100 which is being drawn out from the holder 10. When the vacuum suction transmitted to the holder groove 60 of the holder 58 is released, The sealing film 200 is separated from the upper surface of the lead wire 100 and is then fused to one surface of the lead wire 100 that is drawn out in a preheated state at a predetermined temperature.

The rotary sealing film feeding means 50 disposed under the lead wire 100 in the drawing is also formed in the same structure as the rotary sealing film feeding means 50 described above and cut in the sealing film cutting means 30 When the sealing film 200 is supplied to the lower surface of the lead wire 100 at this time, the sealing film 200 does not fall on the lower surface of the lead wire 100 due to its own weight At this time, the air is discharged to the bottom surface of the inside groove 60 through the suction passage 64 formed on the bottom surface of the holder groove 60 of the holder 58, so that the sealing film 200 is connected to the lead wire 100). When the sealing film 200 contacts the lower surface of the lead wire 100, the sealing film 200 is welded to the lower surface of the lead wire 100 by the heat of the lead wire 100.

The fusing means 70 presses the lead wire 100 having the sealing film 200 fused on its upper and lower surfaces through the rotary sealing film feed means 50 three times to separate the sealing film 200 from the lead wires 100).

The fusing means 70 includes first to third fusing rollers 72, 74 and 76.

The first fusing roller 72 is composed of a pair of rollers arranged upward and downward as means for primarily fusing a sealing film 200 fused to the upper and lower surfaces of the lead wire 100 to form a sealing film 200 The first and the second fusing rollers 72 and 72 and the first and the second fusing rollers 72 and 72 are integrally formed with the first and second fusing rollers 72 and 72. In this state, The sealing film 200, which is fused to the upper and lower surfaces of the substrate 100, is thermally fused at a temperature of 130 ° C to 150 ° C.

The second fusing roller 74 is disposed on the rear side of the first fusing roller 72 and passes through the first fusing roller 72 and a sealing film 200 ) Is thermally fused again.

The second fusing roller 74 is composed of a pair of rollers arranged up and down so that the upper and lower surfaces of the lead wire 100 passing through the first fusing roller 72 are pressed, A heater is attached to the inside of the lead wire 74 so that the sealing film 200 primarily fused to the upper and lower surfaces of the lead wire 100 is thermally fused to the temperature of 200 ° C.

The third fusing roller 76 is disposed on the rear side of the second fusing roller 74 and passes through the second fusing roller 74 to the upper and lower surfaces of the lead 100, Is again thermally fused.

The third fusing roller 76 is constituted by a pair of rollers arranged up and down so that the upper and lower surfaces of the lead wire 100 passing through the second fusing roller 74 are pressed, A heater is attached to the inside of the lead wire 76 to heat-seal the sealing film 200, which is primarily fused to the upper and lower surfaces of the lead wire 100, at a temperature of 250 ° C.

After the sealing film 200 is thermally fused to the upper and lower surfaces of the lead wire 100 via the fusing means 70, the lead wire 100 is naturally cooled at room temperature, and then the lead wire drawing means 10, 14) to be used.

That is, in the present invention, the sealing film (200) is continuously fed to the upper and lower surfaces of the lead wire (100) while being drawn out by the first to third fusing rollers (72, 74, 76) 200 are thermally welded to the upper and lower surfaces of the lead wire 100, so that it is not necessary to press the sealing films 200 one by one and fuse them together as in the conventional pressing method, so that the working time can be remarkably reduced , Which can dramatically increase work productivity.

Hereinafter, a process of thermally fusing a sealing film to the upper and lower surfaces of a lead wire using a device for bonding a sealing film to a lead wire by a rotary method will be described with reference to FIG.

As shown in FIG. 2, the method of adhering the sealing film to the lead wire by the rotary method of the present invention includes a lead wire drawing step S1, a preheating step S2, a sealing film cutting step S3, a rotary sealing film feeding step (S4), a fusion step (S5), and a cooling step (S6).

A) lead wire withdrawing step (S1)

The lead wire 100 is pulled out by driving the winding roll 14 so as to wind the lead wire 100 wrapped around the drawing roll 12 on the front side.

B) Preheating step (S2)

The lead wire 100 being drawn out by driving the winding roll 14 is heated to a temperature of 250 ° C to 300 ° C to be preheated.

C) Sealing film cutting step (S3)

The lead wire 100 is pulled out in the lead wire drawing step S1 and the drawing roller 34 in the sealing film cutting step S3 is wound on the drawing roll 34 intermittently by the power of the servo motor 32 The sealing film 200 is drawn out. At this time, when the sealing film 200 is drawn out to a certain length, the cutter 40 descends and cuts the drawn sealing film 200.

D) Supplying rotary sealing film (S4)

After the sealing film 200 is cut in the cutting step S3, the cut sealing film 200 is seated in the catch groove 60 of the holder 58 located at the bottom, The rotary shaft 58 rotates about the rotary shaft 54 driven by the motor 52 and then supplies the sealing film 200 to the upper and lower surfaces of the lead wire 100 being drawn out.

The sealing film 200 supplied to the upper and lower surfaces of the lead wire 100 is welded to the upper and lower surfaces of the lead wire 100 by the self heat source of the lead wire 100.

E) Fusing step (S5)

The lead wire 100 to which the sealing film 200 is adhered to the upper and lower surfaces through the supplying step S4 is completely fused by sequentially passing through the first to third fusing rollers 72, 74 and 76 .

At this time, the sealing film 200 is fused to the first fusing roller 72 at a temperature of 130 ° C. to 150 ° C. and the sealing film 200 is fused to the second fusing roller 74 at a temperature of 200 ° C. , And the sealing film (200) is fused to the third fusing roller (76) at a temperature of 250 ° C.

F) Cooling step (S6)

After the fusing step S5, the lead wire 100 to which the sealing film 200 is adhered to the upper and lower surfaces is naturally cooled at room temperature and wound around the winding roll 14.

10: lead wire drawing means 20: preheating means
30: sealing film cutting means 40: cutter
50: Rotary sealing film supply means 54:
56: arm 58: holder
60: Anchor groove 70: Fusing means
72: first fusing roller 74: second fusing roller
76: third fusing roller

Claims (2)

An apparatus for bonding a sealing film (200) to a lead wire (100) by a rotary method,
A drawing roll (12) on which the lead wire (100) is wound;
A winding roll 14 positioned behind the drawing roll 12 and winding the lead wire 100 wound around the drawing roll 12 and pulling out the lead wire 100 wound around the drawing roll 12 A lead wire drawing means 10 constituted;
Preheating means (20) provided in the lead wire drawing means (10) and preheating the lead wire (10) being drawn out;
A drawing roller (34) installed above and below the lead wire drawing means (10) and intermittently pulling out the sealing film (200) wound around the drawing roll (32) by a predetermined length;
A sealing film cutting means (30) including a cutter (40) for cutting the sealing film (200) drawn out by a predetermined length by driving the drawing roller (34);
A holder 58 provided between the sealing film cutting means 30 and the lead wire drawing means 10 and provided with an inserting groove 60 for sucking and fixing the sealing film 200 cut by the sealing film cutting means 30; )Wow;
And an arm 56 connected to the holder 58 and coupled to a rotating shaft 54 that is rotated by the power of the motor 52 to rotate the holder by the operation of the rotating shaft 54, A rotary sealing film supply means 50 for supplying a sealing film 200 adsorbed in the holder groove 60 of the holder 58 to the upper and lower surfaces of the lead wire 100 and fusing the same;
And fusing means 72 comprising first to third fusing rollers 72, 74, and 76 for fusing a sealing film 200 welded to the upper and lower surfaces of the lead wire 100 at the rear of the lead wire drawing means 10, (70);
Wherein the lead wire (100) to which the sealing film (200) is fused is wound on the winding roll in a natural cooling state, thereby bonding the sealing film to the lead wire.
A method of bonding a sealing film to a lead wire by a rotary method,
A lead wire drawing step S1 of drawing the lead wire 100 by winding the lead wire 100 wound on the drawing roll 12 around the winding roll 14;
A preheating step (S2) of preheating the lead wire (100) drawn out in the lead wire drawing step (S1) to a temperature of 250 ° C to 300 ° C;
A sealing film 200 wound around the drawing roll 32 is cut to a predetermined length so that the sealing film 200 can be fused to the upper and lower surfaces of the lead wire 100 that has undergone the preheating step S2, A cutting step S3;
After the sealing film 200 cut in the sealing film cutting step S3 is sucked and fixed, the sealing film 200 is rotated around the rotating shaft to supply the sealing film 200 to the upper and lower surfaces of the lead wire 100 during drawing A rotary sealing film feeding step S4 for fusing the sealing film;
A fusing step (S5) of successively press-fusing the sealing film (200) welded on the upper and lower surfaces of the lead wire (100);
And a cooling step (S6) in which the lead wire (100) to which the sealing film (200) is fused is naturally cooled, and wound and stored in the winding roll (14) .

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