KR20160019150A - The electrode tabs film fusion device of secondary batterycells and method - Google Patents

Abstract

The present invention relates to a device and a method to fuse an electrode tab film of a secondary battery and, more specifically, to a device to fuse an electrode tab film of a secondary battery, capable of thermally fusing upper and lower surfaces of a metal, having predetermined thickness and width, with a film at regular intervals. Since the present invention is formed by including a vacuum inductive heating part, forming a film part on the upper and lower surfaces of the metal into vacuum and removing, heating, and fusing microbubbles between the metal and the film of the metal through the vacuum, the film is attached to the metal by using an electric inductive heating body, surroundings, to which the film is attached, are made vacuum to absorb and remove the bubbles, and then the metal is induced and heated to be fused, and therefore, an electrolyte of the secondary battery is prevented from being leaked by a pouch sealing fault, caused by the microbubbles between the film and an electrode tab.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a film fusing device,

The present invention relates to an apparatus and a method for heating and fusing a film on a metal surface of an electrode tab in order to mount an electrode tab provided in a secondary battery to a secondary battery housing such as a pouch. More particularly, By absorbing bubbles between the film and the metal attached to the surface of the secondary battery and heating and fusing the film, it is possible to prevent the leakage of electrolyte solution in the secondary battery by preventing the occurrence of leakage of the electrode tab attaching portion due to fusion of bubbles. The present invention relates to an electrode tap film fusing apparatus and method for a secondary battery.

Generally, there are various kinds of batteries such as nickel-cadmium, lithium ion, nickel-hydrogen, lithium polymer and the like which are used semi-permanently by charging the secondary battery. The electric current supplied from the external power source causes oxidation / reduction reaction And it is made up of core materials such as a separator, a cathode material, an anode material, and an electrolyte, and can be used not only as a portable electronic device such as a notebook computer, a mobile phone, a camcorder, Is known to be widely used.

Among these secondary batteries, Korean Patent Registration No. 10-1090076 discloses an electrode tap film heat-sealing apparatus for a secondary battery, which is a prior art lithium-polymer secondary battery. In this prior art, 1, the battery unit 100 includes a battery unit 100 and a pouch 105 that houses the battery unit 100. The battery unit 100 includes a unit cell, a separator, Or a bi-cell arrayed in the order of a positive electrode plate, a separator, a negative electrode plate, a separator, a positive electrode plate, a separator and a negative electrode plate is wound in a jelly-roll type in accordance with the capacity of a battery, or a plurality of laminated layers are laminated.

One end of the positive electrode terminal 101 and one end of the negative electrode terminal 102 which are electrode terminals are connected to the electrode section and are drawn out to the respective electrode plates of the battery section 100. The positive electrode terminal 101 and the negative electrode terminal 102 The lead tab 103 is exposed from the sealing portion 106 of the pouch 105 for connection to an external device and the lead tab 103 is exposed from the sealing portion 106 of the pouch 105, The film 104 is attached to a certain area on both sides of the portion to be bonded to the sealing portion 106 of the pouch 105 and the film and the pouch sealing portion are sealed and bonded so that the electrolyte filled in the pouch 105 is not leaked, And a negative terminal is prevented from being short-circuited.

That is, by adhering a film to the portion of the lead tab 103 that is in contact with the pouch-sealing portion of the secondary battery, the film and the pouch-sealing portion are adhered to prevent the electrolyte filled in the pouch from leaking through the region of the lead tab 103 So that external moisture is prevented from flowing into the pouch 105 through the lead tab portion and a shorting phenomenon that may occur between the lead tabs 103 through the sealing portion of the pouch 105 is prevented.

2 and 3, the technique of attaching a film to the lead tab in the above-described conventional technique is a technique in which a film supplied from a film transfer section 111 in a film cut transfer section 112 is vacuum-adsorbed and a predetermined length And the cut film is transferred and attached to the upper and lower surfaces of the lead tabs supplied from the lead tabs 107. The films 104 attached to the upper and lower surfaces of the lead tabs 103 are attached to the first, 2, and 3, and fusion welding members 108, 109, and 110 at temperatures of 2, 3, and 1, respectively.

As described above, in the prior art, in attaching the film to the lead tab, the film is vacuum-sucked and supplied, the cut film is cut to a predetermined length, and the cut film is transferred to the upper and lower surfaces of the lead tab, The bonding strength of the film to the lead taps is increased by fusion bonding over the third tier to prevent the occurrence of bubbles in the bonding portion, So that the quality of the lead tab is improved.

That is, according to the above-mentioned prior art, it is necessary to use a complicated and large number of components which are required to use a fusing member having a high temperature for three times in order to attach a film to the lead taps. Therefore, frequent failures of the fusing device, In particular, the film is merely vacuum-adsorbed for transferring the film to the upper and lower surfaces of the lead tab, and the film is heated and fused only three times at the time of fusing with the fusing member, The film is fused in the remaining state, so that an electrolyte leakage is caused when the secondary battery is used due to the poor sealing of the pouch.

In order to solve this problem, as shown in FIGS. 4 and 5, in attaching the film 104 to the metal M of the electrode tab, the metal is preheated and supplied by the metal preheater 115 , A film is adhered to a preheated metal film by first heat-welding and a cut-away portion 117 by first heat-welding, then contacted by a second heat-welding at the film-touching portion 118 to improve the reliability of the product, In order to adhere the film to the metal, the metal is preheated and the film must be heat-welded two times. Therefore, the structure of attaching the film to the metal is complicated, The bubbles are not removed and the bubbles are left intact. Thus, when the secondary battery is used, an electrolyte leak may occur due to poor sealing of the pouch. There.

Reference numeral 113 denotes a metal supply unit, 121 denotes a metal pressing support, 116 denotes a film supply unit, 121 denotes a metal alignment unit, 119 denotes a plastic cutting unit, 122 denotes a metal alignment unit Reference numeral 123 denotes a first film supply reel, reference numeral 124 denotes a second film supply reel, reference numeral 125 denotes a film discharge guide, reference numeral 120 denotes a transfer chuck, and reference numeral 114 denotes a metal winding assembly. Reference numeral 126 denotes a film transfer guide, and 127 denotes a film distribution guide.

Disclosure of Invention Technical Problem [8] In order to solve the above-described problems, the present invention provides a method for fusing a film to a metal of an electrode tab included in a secondary battery, wherein the film is pressed and adhered to the metal using an electric induction heating body, And the metal is fused to the metal by heating the metal through the electric induction heating part in the state where the bubbles are removed so that the electrode tap sealing portion of the secondary battery pouch is present between the electrode tab and the film The leakage of the electrolyte of the secondary battery due to the poor sealing of the pouches due to the microcapsule.

According to an aspect of the present invention, there is provided an electrode tap film fusing apparatus for a secondary battery in which a film is thermally fused to an upper surface and a lower surface of a metal having a predetermined thickness and a predetermined width at regular intervals, And a vacuum induction heating part for forming a film part located on a surface and a lower surface in a vacuum and removing fine bubbles existing between the metal film and the metal in which the film is adhered through vacuum, An electrode tap film fusing device for a secondary battery is provided.

The vacuum induction heating unit is installed inside a vacuum chamber and a vacuum chamber that forms a vacuum with respect to a certain region of the metal region where the film is pressed. While the film is pressurized with a constant pressure, the metal is induction- An electric induction heating device for heating the vacuum chamber and an electric switch for opening and closing the vacuum chamber are provided outside the vacuum chamber.

The electric induction heater is formed in a pair so as to correspond to the upper and lower portions of the metal so that the film located on the upper and lower surfaces of the metal can be pressurized or depressurized and the metal can be inductively heated, And a cylinder driven by pressure is provided.

The vacuum chamber is formed in a pair in correspondence with the upper surface and the lower surface of the metal so that the vacuum region is formed around the upper and lower surfaces of the metal on which the film is placed in a state that the film is pressed on the upper and lower surfaces of the metal by electric induction heating A vacuum port and an actuator driven by a cylinder are provided in each of the vacuum chambers, and a pair of vacuum chambers are simultaneously evacuated to induce heating of the metal by electric induction heating so that the film is melted between the film and the metal So that it can absorb the bubbles present in the air.

A cutter for cutting a film, which is press-fixed to the upper surface of the metal by electric induction heating, is formed on one side of the vacuum chamber, and the film is simultaneously pressed and fixed to the upper and lower surfaces of the metal by electric induction heating When the cutter is lowered and contacts the film, the cutter is cut off. When the cutting is completed, the cutter is elevated. The vacuum induction is cut at the heat part, and the metal film is heat- The film is cut to a size such that the film can be fused to the sealing portion.

According to another aspect of the present invention, there is provided a method of fusing an electrode tap film of a secondary battery, comprising: a metal supplying step of supplying metal from a metal supplying roll; A metal transfer step of transferring the metal to the vacuum induction heating part at a pitch shifted by a predetermined distance; A metal supporting step of pressing and supporting the other side of the metal having one side entered into the vacuum induction heating part by the metal supporting part; A film feeding step of feeding the film from the upper film winding roll and the lower film winding roll while vertically crossing the upper and lower surfaces of the metal in the longitudinal direction; A film fixing step of pressing and fixing the film supplied to the upper and lower surfaces of the metal by the electric induction heater of the vacuum induction heating unit at a constant pressure; A vacuum forming step of evacuating a predetermined portion where the metal and the film are pressed and fixed through the vacuum chamber; A film cutting step of cutting the film by the cutter when the pressing and fixing of the film is completed; A film fusing step for fusing the film to the upper and lower surfaces of the metal by pressurizing and fixing the metal by induction heating of the metal by applying electric power to the electric induction heating; A film cleaning step of releasing the vacuum and transferring the metal to which the film is adhered by pitch, and re-cutting the film in the film cleaning part to arrange the film; And a metal winding step of winding a metal on the metal winding roll by fusing the film and arranging the metal on the metal winding roll.

The present invention does not use a structure in which a film is fused to a metal of an electrode tab included in a secondary battery, the metal is not preheated, and the film is fused at various temperatures by increasing the temperature, The film is brought into close contact with the film through induction heating of the metal by using hot air, and the surrounding of the film is vacuumed to adsorb and remove the bubbles, and then fused to cause defective sealing of the pouch due to the microbubbles existing between the electrode tab and the film. The electrolyte solution is prevented from leaking, and the effect of improving the quality by firmly and uniformly fusing the film occurs.

1 to 5 are diagrams showing a conventional technique.
FIG. 6 is a conceptual view illustrating a metal supply flow of a lead-tap film heat-seal apparatus of a secondary battery according to the present invention.
FIG. 7 is a view conceptually showing a film supply flow of the lead taps film thermal fusing device of the secondary battery according to the present invention.
FIG. 8 is a view showing a vacuum induction heating unit of a lead-tap film heat-seal apparatus of a secondary battery according to the present invention.
9 is a block diagram showing a method of heat-sealing a lead-tap film of a secondary battery according to the present invention.

The embodiments described in the specification of the present invention and the configurations shown in the drawings correspond to a preferred embodiment of the present invention and do not represent all the technical ideas of the present invention, It should be understood that various equivalents and modifications are encompassed.

The apparatus for thermally fusing an electrode tap film of a secondary battery according to the present invention comprises an upper surface and a lower surface of a metal (1) forming an electrode tab of a battery (10) sealed and embedded in a pouch (20) As shown in Fig. 6, a metal supply roll 1 for winding and feeding a metal 1 made of a metal plate having a predetermined thickness and a constant width in the form of a roll, A metal winding roll 4 for winding up a metal film 1 with a film attached thereon is spaced apart by a predetermined distance and a film 2 having a predetermined width and thickness is placed on the upper surface of the metal 1 The upper film winding rolls 9 and the lower film winding rolls 10 are arranged to be spaced apart from each other by a predetermined distance, (1) in which a vacuum is formed on the film portion and the film (2) (6) for removing the bubbles from the upper surface and the lower surface of the vacuum induction heating furnace.

6, a film 2 is attached to the metal 1 between the metal supply roll 3 and the vacuum induction heating portion 6, A metal supporting portion 5 for pressing and supporting the metal 1 is disposed so that the operation for fusing and cutting the fused film can be easily performed.

Between the vacuum induction heating part 6 and the metal winding roll 4, a vacuum inducing film is formed by cutting the periphery of the film fused to the upper and lower surfaces of the metal 1 while passing through the heating part 6, And a metal transfer section 8 for transferring and winding the metal 1 to the metal winding roll 4 at a constant pitch is disposed.

The metal support portion 5 and the film awnings 7 and the metal transfer portion 8 provided between the heating portion 6 and the metal winding roll 4 are basically provided for supplying the metal 1 (Not shown) for aligning the metal pieces 1 to which the film 2 is adhered and guiding the film to the film arranging part 7, in addition to these components.

7, the film 2 is supplied to the upper surface and the lower surface of the metal 1 so as to cross each other in the longitudinal direction, The upper film take-up roll 9 and the lower film take-up roll 10 are provided at upper and lower portions at regular intervals so as to be spaced apart from each other.

The film 2 drawn out from the upper film take-up roll 9 and the lower film take-up roll 10 is placed on the upper and lower surfaces of the metal 1 fed in the direction perpendicular to the feed direction of the film, A distribution guide 15 for distributing the film 2 in the direction of the heating part 6 from the upper and lower film winding rolls 9 and 10 so that the vacuum induction can be transferred to the heating part 6, And a film discharging guide 17 for guiding the film to be fed to the upper and lower portions of the metal 1 are provided.

As shown in Fig. 8, the vacuum induction heating part 6 is supplied with the metal 1 by the metal supply structure and the film 2 is supplied to the upper and lower surfaces of the metal 1 by the film supply structure. The film 2 is pressurized with a predetermined pressure to be brought into close contact with it, and an electric induction heater 13 is formed by induction heating the metal to supply the pressurized film to the metal, A vacuum chamber 12 for forming a vacuum with respect to a predetermined region of the metal 1 and a switch 14 installed outside the vacuum chamber 12 for opening and closing the vacuum chamber.

The electric induction heater 13 is connected to an upper portion and a lower portion of the metal 1 so as to be able to pressurize or release the film 2 positioned on the upper and lower surfaces of the metal 1, And a cylinder in which each electric induction heater is driven by fluid pressure, so that a pair of electric induction heater 13 can simultaneously perform pressurization and depressurization of the film 2.

In the vacuum chamber 12, the film is pressed on the upper and lower surfaces of the metal 1 by the electric induction heater 13, and a vacuum region is formed around the upper and lower surfaces of the metal, And the vacuum chamber 12 is provided with a pair of vacuum chambers 12 for controlling the opening and closing operations of the vacuum chambers by a vacuum port and a cylinder, Simultaneously vacuum is applied so that the metal is induction heated by the electric induction heater 13 to absorb bubbles existing between the film and the metal before the film adhered to the metal is fused.

8, a cutter 11 for cutting the film 2, which is pressed and fixed to the upper surface of the metal 1 by means of an electric induction heater 13, is provided at one side of the vacuum chamber 12 When the film 2 is simultaneously pressed and fixed to the upper and lower surfaces of the metal 1 by the electric induction heater 13, the cutter 11 descends and contacts the film 2, And is raised when the cutting is completed.

As shown in Fig. 7, the distribution guide 15 for distributing the film 2 is arranged so that the upper film 2a and the lower film 2b supplied from the upper and lower film winding rolls 9, And a guide hole 15a for vertically separating the upper film 2a and the lower film 2b so as to be supplied in a spaced apart state.

The film transfer rolls 16 are arranged in pairs so that they can be positioned at the top and bottom of the film 2 and can be operated simultaneously as shown in Fig. The upper and lower films 2a and 2b are clamped and transported while being transferred between the upper film 2a and the lower film 2b through the distribution guide 15, A spacer plate 16a having a thickness corresponding to the interval is provided so that the film can be transported at a constant pitch while maintaining a spacing distance from the distribution guide 15.

The metal and the film supplied by the above-described supply structure of the metal (1) and the supply structure of the film (2) are heat-welded while the bubble is removed in the heat part (6) As shown in the figure, the film arranging part 7 included in the metal supplying structure cuts the film into a size that can be fused to the secondary battery pouch sealing part, and arranges the metal films wound on the metal winding roll 4.

A method of fusing an electrode tap film of a secondary battery according to the present invention having the above-described configuration is a metal fusing method in which a metal (1) constituting an electrode tab is supplied from a metal supply roll (3) S1); A metal transfer step (S2) of moving the metal (1) at a pitch a predetermined distance toward the vacuum part (6); A metal supporting step (S3) for pressing and supporting the other side of the metal (1) having the vacuum induction heating part (6) on one side thereof by the metal supporting part (5); A film supply step S4 for supplying the film 2 from the upper film winding roll 9 and the lower film winding roll 10 to the upper and lower surfaces of the metal 1 while crossing the longitudinal direction at right angles; A film fixing step (S5) of fixing the film supplied by the electric induction heater (13) of the vacuum induction heating part (6) to the upper and lower surfaces of the metal by a predetermined pressure; A vacuum forming step (S6) of evacuating a predetermined portion where the metal and the film are pressed and fixed through the vacuum chamber (12); A film cutting step (S7) for cutting the film by the cutter (11) when the pressing and fixing of the film is completed; A film fusing step (S8) of applying electric power to the electric induction heater (13) to induction-heat the metal by electric induction heating to fuse the press-fixed film to the upper and lower surfaces of the metal; A film arranging step (S9) of releasing the vacuum, transferring the pitch of the metal to which the film is adhered, and reorganizing the film in the film arranging part (7) to arrange it; And a metal winding step (S10) of winding the metal on which the film is fused and gathered to the metal winding roll (4).

The steps S1 to S10 of the film fusing method using the electrode tap film fusing apparatus of the secondary battery described above are repeatedly carried out to induce heating of the metal 1 constituting the electrode tab so that the film 2 is vacuum- An excellent effect of preventing the leakage of the electrolyte due to the poor sealing of the secondary battery pouch can be obtained by removing all the minute bubbles existing between the metal 1 and the film 2 through the through holes.

1: metal 2: film
2a: Upper film 2b: Lower film
3: metal supply roll 4: metal winding roll
5: metal support part 6: vibration induction heating part
7: Film Rearing Section 8: Metal Transfer
9: Upper film take-up roll 10: Lower film take-up roll
11: Cutter 12: Vacuum chamber
13: Electric induction heating 14: Actuator
15: Distribution guide 15a: Guide hole
16: Film is transferred 16a: Spacer plate

Claims (7)

An electrode tap film fusing device for a secondary battery in which a film is thermally fused to an upper surface and a lower surface of a metal having a predetermined thickness and a predetermined width at regular intervals,
Vacuum induction heating, which forms the film part located on the upper and lower surfaces of the electrode tap metal in a vacuum, removes minute bubbles between the metal film and the metal that are in close contact with the film through vacuum, and fuses the film to the metal Wherein the electrode tap film fusing unit is formed to include a plurality of electrode fingers. The method according to claim 1,
Wherein the vacuum induction heating unit comprises: a vacuum chamber in which the film forms a vacuum with respect to a certain region of the pressed metal region;
An electric induction heater installed inside the vacuum chamber and applying electricity to the metal while pressurizing the film with a constant pressure to induce heating of the metal to melt the film;
And an opening / closing unit installed on the outside of the vacuum chamber to open / close the vacuum chamber. 3. The method of claim 2,
The electric induction heater is formed in a pair so as to correspond to the upper and lower portions of the metal so that the film located on the upper and lower surfaces of the metal can be pressurized or depressurized and the metal can be inductively heated, And a cylinder driven by pressure, wherein the cylinder is driven by pressure. The method of claim 3,
The vacuum chamber is formed in a pair in correspondence with the upper surface and the lower surface of the metal so that the vacuum region is formed around the upper and lower surfaces of the metal on which the film is placed in a state that the film is pressed on the upper and lower surfaces of the metal by electric induction heating A vacuum port and an actuator driven by a cylinder are provided in each of the vacuum chambers, and a pair of vacuum chambers are simultaneously evacuated to induce heating of the metal by electric induction heating so that the film is melted between the film and the metal So as to absorb bubbles existing in the electrode tap film fusing device. 5. The method of claim 4,
A cutter for cutting a film, which is press-fixed to the upper surface of the metal by electric induction heating, is formed on one side of the vacuum chamber, and the film is simultaneously pressed and fixed to the upper and lower surfaces of the metal by electric induction heating When the cutter is completed, the cutter is cut while the cutter is in contact with the film, and the cutter is raised when the cutter is completed. 6. The method of claim 5,
Wherein the vacuum induction is cut at a heating portion and the metal is thermally fused in a state in which bubbles are removed, and the film is cut to a size such that the metal can be fused to the secondary battery pouch sealing portion in the film filing portion. Electrode tap film fusing device. In an electrode tap film fusing method of a secondary battery,
A metal supply step of supplying metal from a metal supply roll;
A metal transfer step of transferring the metal to the vacuum induction heating part at a pitch shifted by a predetermined distance;
A metal supporting step of pressing and supporting the other side of the metal having one side entered into the vacuum induction heating part by the metal supporting part;
A film feeding step of feeding the film from the upper film winding roll and the lower film winding roll while vertically crossing the upper and lower surfaces of the metal in the longitudinal direction;
A film fixing step of pressing and fixing the film supplied to the upper and lower surfaces of the metal by the electric induction heater of the vacuum induction heating unit at a constant pressure;
A vacuum forming step of evacuating a predetermined portion where the metal and the film are pressed and fixed through the vacuum chamber;
A film cutting step of cutting the film by the cutter when the pressing and fixing of the film is completed;
A film fusing step for fusing the film to the upper and lower surfaces of the metal by pressurizing and fixing the metal by induction heating of the metal by applying electric power to the electric induction heating;
A film cleaning step of releasing the vacuum and transferring the metal to which the film is adhered by pitch, and re-cutting the film in the film cleaning part to arrange the film;
And a metal winding step of winding a metal on which the film is fused and arranged to a metal winding roll.

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