KR101217449B1 - Manufacturing Apparatus and Method For Battery Pack - Google Patents

Abstract

The present invention relates to a battery pack manufacturing apparatus and a method of manufacturing the same, and more particularly, the battery pack manufacturing apparatus is an adhesive bonding portion of the upper end of the insulating mounting member of the upper end of the battery cell through the adhesive nozzle and the insulating mounting member An apparatus for manufacturing a battery pack, which is applied to side pre-glued portions on both side surfaces of a lower side, and is compressed, wherein the battery pack includes an H-shaped skeleton holding an battery cap including an insulating cap fastened to surround the battery cell and the insulating mounting member on the battery cell. Crimp pads; A side press which presses the crimp pad of the H-shaped skeleton through a side press pin to press the side pre-glued portions of both sides of the battery pack; The side press pins attached to the side presses to press the upper portion of the compression pads of the H type skeletons to spread the H type skeletons from side to side; It relates to a battery pack manufacturing apparatus and a manufacturing method comprising a; and a top press for pressing the adhesive portion of the both ends of the upper portion of the battery pack. According to the present invention, the adhesion of the press for securing the adhesive strength is enhanced, the defect rate is drastically reduced, and the assembly durability through the twist test, the bending test, and the tumbling test, which is a mounting test, is excellent, and the side press and the top press are simultaneously disposed. The process cost is greatly reduced.

Side press, side press pin, crimp pad of H type skeleton, top press

Description

Battery pack manufacturing apparatus and manufacturing method {Manufacturing Apparatus and Method For Battery Pack}

The present invention relates to a battery pack manufacturing apparatus and a manufacturing method, and more particularly, the battery pack manufacturing apparatus is a point adhesive portion of the both ends of the upper end of the insulating mounting member of the upper side of the battery cell, and the side pre-adhesion of both sides of the lower side of the insulating mounting member While holding the H-shaped crimp pad while holding the battery pack including the battery cell coated with adhesive on the site and the insulating cap fastened to surround the insulating mounting member on the top of the battery cell, the H-shaped crimp pad of the side The battery cells are alternately compressed by side presses, which are spread from side to side through press pins, to press the side pre-adhesion sites on both sides of the battery pack, and to the top press presses the adhesive sites at both ends of the upper part of the battery pack. The present invention relates to a battery pack manufacturing apparatus and a manufacturing method for joining the insulating cap.

In general, lithium secondary batteries are used in mobile devices such as mobile phones, PDAs, portable game consoles, MP3s, and notebook computers, and are intended to be used for transportation of vehicles in the future. At present, the demand for lithium secondary batteries is exploding, and thus, there is a need for a technology for producing lithium secondary batteries accordingly in order to produce defects in a fast and practical test.

Since lithium secondary batteries have various combustible materials, there are problems such as overheating and explosion due to overcharging, overcurrent, and physical shock. Therefore, a lithium secondary battery has a protection circuit module (PCM) that can control abnormal conditions such as overcharging. It is mounted on an insulating mounting member and mounted in a state of being connected to a battery cell.

The battery pack is applied to the two-point adhesive portion of the both ends of the upper portion of the insulating mounting member on which the protective circuit module (PCM), and the four-point adhesive portion of both sides of the lower side of the insulating mounting member and then the battery cell and the battery cell It is completed by pressing an insulating cap fastened to surround the insulating mounting member of the upper portion by a press.

However, the method of manufacturing the battery pack has a problem that a defect occurs in the twist test, the bending test, and the tumbling test, which is a mounting test, and the two-point adhesive parts of both ends of the upper part of the insulating mounting member, and the four sides of the lower side of the insulating mounting member. There is a problem in that the process costs are added by placing the presses in order to compress the adhesive point.

 In order to solve such a problem, the technique regarding the packing machine (Japanese Patent Laid-Open No. 2000-211604) with the pressing material which can wrap a wrapping paper and a tired bag several times by semi-automatic operation is disclosed. However, since the packing machine presses only the pressing material in the lower direction, there is a problem that the side joining is not precise.

Moreover, the technique regarding the compressive packing machine (Japanese Patent Laid-Open No. 2007-190568) which can be packed with a packing tape in the state which pressed the tired package with the press body is known. However, the compression baler has a problem that it is difficult to apply to the side joining because the pressing body is compact and presses only in the lower direction.

Accordingly, an object of the present invention is to solve the problem that the failure in the twist test, bending test, tumbling test that is a mounting test of the conventional battery pack, the adhesive bonding portion of the both ends of the insulating mounting member upper part of the battery cell and the bottom of the insulating mounting member The H-shaped skeleton while holding a H-shaped pressure pad while holding a battery pack including an H-compression pad and an insulating cap fastened to surround the insulating mounting member on the upper side of the battery cell, wherein the battery cell is coated with adhesive on both sides of the side pre-glued portion. By pressing the side press pins of the side press pins on both sides of the battery pack to press the side presses on both sides of the battery pack and the top press presses the adhesive parts on both ends of the upper part of the battery pack. The battery cell by bonding the battery cell to the insulating cap to drastically reduce the defective rate. To provide an apparatus and method for producing it is an object.

The present invention to solve the above object

An apparatus for manufacturing a battery pack, wherein the adhesive is applied to a point-glued portion at both ends of an upper portion of an insulating mounting member on an upper portion of a battery cell through a nozzle, and applied to a side pre-glued portion at both sides of a lower side of the insulating mounting member.

A compression pad of an H-shaped skeleton holding a battery pack including an insulating cap fastened to surround the battery cell and the insulating mounting member on the battery cell;

A side press which presses the crimp pad of the H-shaped skeleton through a side press pin to press the side pre-glued portions of both sides of the battery pack;

The side press pins attached to the side presses to press the upper portion of the compression pads of the H type skeletons to spread the H type skeletons from side to side; And

It provides a battery pack manufacturing apparatus comprising a; top press for pressing the adhesive portion of the both ends of the battery pack upper portion.

In addition, the present invention is a battery pack manufacturing method for compressing the adhesive after applying the adhesive to the adhesive portion of the upper end of the upper end of the insulating mounting member of the upper portion of the battery cell through the nozzle, and the front adhesive portion of both sides of the lower side of the insulating mounting member,

Preparing a compression pad of an H-type skeleton holding a battery pack including an insulating cap fastened to surround the battery cell and the insulating mounting member on the battery cell;

Pressing the side pre-glued portions of both sides of the battery pack with a side press after applying the adhesive;

Pressing the upper side of the pressing pad of the H-type skeleton with the side press pin formed in the side press when the side press is pressed to spread the H-type skeleton to the left and right to compress the side pre-adhesion sites on both sides of the battery pack step; And

At the same time as pressing by the side press or by pressing the side pre-adhesion portion of the both sides of the battery pack with the side press, and then pressing the point adhesive portion at both ends of the upper part of the battery pack by a top press to the battery cell It provides a battery pack manufacturing method comprising a; bonding with the insulating cap.

Battery pack manufacturing apparatus and method of the present invention is the adhesive cell is applied to the adhesive bonding portion of the both ends of the upper end of the insulating mounting member of the upper portion of the battery cell, and the battery cell coated with the adhesive on the side of the side of the lower side of the insulating mounting member, and the battery While holding the battery pack including the insulating cap fastened to surround the insulating mounting member on the top of the cell with the H-shaped pressing pad, spread the pressing pad of the H-shaped frame from side to side through the side press pins of both sides of the battery pack. The side press for pressing the side pre-adhesion portion and the top press for pressing the adhesive portion at both ends of the upper part of the battery pack are alternately pressed to bond the battery cells to the insulating cap, so press adhesion for securing adhesion Remarkably reduced defective rate, and when mounted test, twist test, bending test, tumbling The assembly durability that passes the hum is excellent and the side press and the top press are disposed at the same time has an excellent effect of reducing the process cost.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are designated as much as possible even if displayed on different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

The present invention provides a battery pack manufacturing apparatus for compressing the adhesive after applying the adhesive to the point adhesive portion of the both ends of the upper portion of the insulating mounting member of the upper portion of the battery cell through the nozzle, and the side pre-glued portion of the both sides of the lower side of the insulating mounting member. And a H-shaped skeleton pressing pad holding the battery pack including an insulating cap fastened to surround the insulating mounting member on the battery cell. A side press which presses the crimp pad of the H-shaped skeleton through a side press pin to press the side pre-glued portions of both sides of the battery pack; The side press pins attached to the side presses to press the upper portion of the compression pads of the H type skeletons to spread the H type skeletons from side to side; And a top press that compresses the adhesive bonding portions at both ends of the upper part of the battery pack.

In detail, the battery pack manufacturing apparatus includes the battery cell in which an adhesive is applied to the side pre-glued portions of both side surfaces of the lower side of the insulating mounting member on the upper side of the battery cell and the point-glued portions of the upper ends of the insulating mounting member, and the battery. While holding the battery pack made of the insulating cap fastened to surround the insulating mounting member in the upper part of the cell with the compression pad of the H-shaped skeleton, the side pre-adhesion portions and both ends of both sides alternately with the side press and the top press. The battery cell is bonded to the insulating cap by pressing the adhesive point of the spot, thereby increasing the press-mill adhesion for securing the adhesive force, thereby drastically reducing the defective rate, and passing the mounting test, the twist test, the bending test, and the tumbling test. Excellent durability and the side press and the top press at the same time The process cost is reduced is provided.

Here, the side pre-glued portion of the lower side of the insulating mounting member on the upper side of the battery cell corresponds to a spot coating four points of adhesive on both sides of the lower surface of the conventional insulating mounting member in the present invention in a line on both sides of the lower side of the insulating mounting member in the present invention. The coating is long and is the same as the side pre-glued portion of both sides of the battery pack.

In addition, the point adhesive portion of the both ends of the upper portion of the insulating mounting member of the upper portion of the battery cell refers to the application of two spots of adhesive on both ends of the upper portion of the insulating mounting member and is the same as the point adhesive portion of both ends of the upper portion of the battery pack Do.

1 is a front view of a completed battery pack after pressing the battery pack of the present invention by the side press and the top press, Figure 2 is a view showing the structure of the battery pack side press and top press apparatus of the present invention.

Bonding between the insulating mounting member 150 and the insulating cap 180 coupled to the battery cell 100 is performed by attaching the adhesive to the insulating mounting member on which the protective circuit board 160 is mounted. 150 after application to the adhesive bonding portion 130 of the adhesive point of the both ends of the upper portion and the side pre-adhesion portion of the lower side of both sides to form a battery pack 200, and then the side press 210 to the battery pack ( 200 is a two-point adhesive and a two-sided pre-adhesion where the side pre-adhesion portion of 200 is pressed and the top-adhesion 250 presses the point-adhesion portions at both ends of the battery pack.

In addition, as shown in Figure 2, the battery pack including an insulating cap fastened to surround the insulating mounting member of the battery cell and the upper part of the battery cell, the adhesive is applied to the side pre-glued portion and the adhesive bonding portion ( 200 is pressed onto the compression pad 240 of the H-shaped skeleton, and the side pre-adhesion portions (not shown) on both sides of the battery pack 200 are compressed through the side press pin 230 of the H-shaped skeleton. Pressing the upper part of the pad 240 to press the side press 210 consisting of a side press upper mold 220 and a side press lower mold 225 to spread the H-shaped skeleton to the left and right, and to the side press 210 At the same time as pressing or pressing the side pre-adhesion portions (not shown) on both sides of the battery pack 200 with the side press 210, and then to the top press upper mold 260 and the top press lower mold 265 Consisting of the top press (2 50) the adhesive cell (not shown) at both ends of the upper part of the battery pack is pressed to bond the battery cell to the insulating cap.

Figure 3 is a photograph of the compression pad of the H-type skeleton of the present invention from the top, Figure 4 is a photograph of the compression pad of the H-type skeleton of the present invention from the side, Figure 5 is a photograph showing a side press pin of the present invention to be.

In the photograph of FIG. 3, the H type of the compression pad of the H type skeleton can be seen, and in the photograph of FIG. 4, the side pads of the lower side of the insulating mounting member can be compressed by spreading the compression pad of the H type skeleton from side to side. You can see the shape. In the picture of Figure 5 can see the downward movement of the side press pin.

The crimp pad of the H-shaped skeleton is formed of a plurality of H-shaped skeletons and a plurality of springs therebetween.

The compression pad of the H-shaped skeleton holds a battery pack consisting of the battery cell and the insulating cap fastened to the battery cell.

Here, when the side press presses the crimp pad of the H-shaped skeleton, the side press pin fastened to the side press spreads the H-shape of the crimp pad of the H-shaped skeleton to the left and right, and the side press of the battery pack. The side pre-adhesion sites on both sides are compressed.

The crimp pad of the H frame is made of any one or more of aluminum, stainless steel, copper, or zinc.

Since the crimp pad of the H-type skeleton is subjected to durability and pressure, it is formed of the metal material or the alloy of the metal material.

The shape of the upper die of the side press is rectangular, circular, rhombus, polygon, or three-dimensional shape thereof.

The side press is to press the pressing pad of the H-shaped skeleton to compress the side pre-adhesion sites on both sides of the battery pack, the shape of the side press prize die is rectangular, circular, rhombic, polygonal, or the three-dimensional shape of the Various forms are available to precisely press the crimp pad of the H-shaped skeleton.

In addition, the top press is a press longer than the side press, the shape of the upper die is rectangular, circular, rhombic, polygonal, or three-dimensional shape.

The top press is to compress the adhesive portion of the upper portion of the battery pack, the shape of the top press upper die is a square, round, rhombus, polygon, or a three-dimensional shape that can precisely press the battery pack Form is possible.

The lower die of the side press and the lower die of the top press have a rectangular bar shape.

The lower die of the side press and the lower die of the top press are connected to the upper die of the side press and the upper die of the top press to compress both sides and the upper surface of the battery pack, respectively. The lower die of the top press has a rectangular bar shape that can press the battery pack precisely.

The side press and the top press operate by pneumatic, hydraulic, or electro-pneumatic methods. The pneumatic method is operated by the pressure of the air and the hydraulic method is operated by the pressure of the liquid, the electro-pneumatic method is operated by using the power of the electric motor.

The side press and the top press alternately or simultaneously compress the battery packs.

After the side press presses the side pre-adhesion portions on both sides of the battery pack, the top press presses the point-adhesive portions at both ends of the upper part of the battery pack. Alternatively, the top press may press the top surface of the battery pack while the side press presses both sides of the battery pack.

Here, the side press may be crimped first, and the top press may be crimped first.

A sensor is built in to stop the operation of the device when an operator intervenes while the side press and the top press are pressed.

In terms of the safety of the operator, when the operator intervenes in the space where the side press and the top press are pressed, the built-in sensor for stopping the operation of the device can be used to promote the safety of the worker in an inadvertent work attitude or an unavoidable work situation. Can be.

The side press and the top press are formed of any one or more of aluminum, stainless steel, copper, or zinc.

The upper and lower molds of the side press and the upper and lower molds of the top press are formed of the metal material or the alloy of the metal material to withstand the pressure of the press and can be used in repeated press operations.

The side press pins open the H-shaped skeleton of the crimp pad of the H-shaped frame to the left and right to allow the side press to compress the side pre-adhesion portions on both sides of the battery pack.

The side press pin is formed in the lower die of the side press so that when the side press presses the crimp pad of the H-shaped skeleton, the side press pin is interposed between the H skeleton of the crimp pad of the H-shaped skeleton and the crimp pad of the H-shaped skeleton. Spread the H-shaped frame of the left and right to the side press to compress the side pre-adhesion sites on both sides of the battery pack.

The side press pin is formed of any one or more of aluminum, stainless steel, copper, or zinc.

The side press pin is formed of the metal material or the alloy of the metal material so that the side press can be used to repeatedly open the H-shaped frame of the crimp pad of the H-shaped frame to the left and right.

In addition, the nozzle is an automatic or manual nozzle equipped with an adhesive sprayer and the number of the nozzles includes at least one.

The automatic nozzle automatically sets a mechanism when spraying the adhesive, and simultaneously or at the same time sprays the adhesive to the adhesive bonding portion of the upper both ends of the insulating mounting member and the side pre-gluing portion of both sides.

The manual nozzle sprays the adhesive at the same time or at the same time on the adhesive agent portion of the upper both ends of the insulating mounting member and the side pre-adhesion portions on both sides by manual setting of the mechanical device during the adhesive spray.

Here, the number of the nozzles has at least one or more, and the adhesive is applied to the side pre-glued portion of both sides of the insulating mounting member with two nozzles at the same time and moved to the point adhesive of the upper ends of the insulating mounting member It can be applied to the site at the same time. Alternatively, four side nozzles may be applied simultaneously to the side pre-glued portions of both side surfaces of the insulating mounting member and the point-glued portions of the upper both ends.

The battery cell is a rectangular lithium secondary battery cell. However, the shape of the battery cell is not limited thereto.

In the battery cell, an electrode assembly having a cathode / separation membrane / cathode structure is sealed inside the battery case together with an electrolyte, and electrode terminals are formed on an upper end thereof.

Here, the lithium secondary battery cell is a lithium ion battery cell, a lithium ion polymer battery cell, or a lithium polymer cell.

The lithium ion battery cell uses lithium or a lithium-graphite compound as a positive electrode, and lithium cobalt oxide (LiCoO ₂ ), lithium iron phosphate (LiFePO ₄ ), or lithium manganese oxide (LiMnO ₄ ) as a negative electrode. As the electrolyte, lithium tetrafluorophosphate (LiPF ₄ ), lithium tetrafluoroborate (LiBF ₄ ), or lithium perchlorate (LiClO ₄ ) is used as a lithium salt dissolved in an organic solvent such as ether or tetrahydrofuran.

The lithium ion polymer cell uses lithium or a lithium-graphite compound as the positive electrode, and lithium cobalt oxide (LiCoO ₂ ), lithium iron phosphate (LiFePO ₄ ), or lithium manganese oxide (LiMnO ₄ ) as the negative electrode. The same as the lithium ion battery cell, except that a chain ester is added to an ethylene carbonate (Ethylen Carbonate) solvent as an electrolyte, and a lithium salt such as lithium hexafluorophosphate (LiPF ₆ ) is mixed.

The lithium polymer cell uses a lithium or a lithium-graphite compound as a positive electrode, and lithium cobalt oxide (LiCoO ₂ ), lithium iron phosphate (LiFePO ₄ ), or lithium manganese oxide (LiMnO ₄ ) as the negative electrode. It is the same as a lithium ion battery cell, but uses a conductive polymer electrolyte as an electrolyte and a separator. The polymer electrolyte is a mixture of an electrically conductive salt such as lithium hexafluorophosphate (LiPF ₆ ) or silicon dioxide in a solid polymer such as polyethylene oxide.

Here, the word "polymer" means a polymer electrolyte and a separator.

In addition, the insulating mounting member has an opening in which the electrode terminals can be exposed while maintaining the electrical insulating property of the battery cell as an insulating member.

The insulating cap protects the battery cell from the outside, and serves to maintain the electrical insulation while at the same time complementing the mechanical strength of the members mounted on the top of the battery cell.

In addition, the present invention provides a battery pack manufactured using the battery pack manufacturing apparatus.

In addition, the battery pack manufacturing method of the present invention by applying the adhesive to the adhesive bonding portion of the upper end of the upper end of the insulating mounting member of the upper part of the battery cell through the nozzle, and manufacturing the battery pack to compress after applying the adhesive line of the both sides of the lower side of the insulating mounting member A method, comprising: preparing a crimp pad of an H-type skeleton holding a battery pack including an insulating cap fastened to surround the battery cell and the insulating mounting member on the battery cell; Pressing the side pre-glued portions of both sides of the battery pack with a side press after applying the adhesive; Pressing the upper side of the pressing pad of the H-type skeleton with the side press pin formed in the side press when the side press is pressed to spread the H-type skeleton to the left and right to compress the side pre-adhesion sites on both sides of the battery pack step; And simultaneously pressing the side press adhesive portions of both side surfaces of the battery pack with the side press, and pressing the point adhesive portions at both ends of the upper part of the battery pack with a top press. Bonding the cell with the insulative cap.

In detail, the battery pack manufacturing method includes the battery cell in which an adhesive is applied to the side pre-glued portions of both side surfaces of the lower side of the insulating mounting member and the adhesive points of the upper ends of the insulating mounting member, and the battery. While holding the battery pack made of the insulating cap fastened to surround the insulating mounting member in the upper part of the cell with the compression pad of the H-shaped skeleton, the side pre-adhesion portions and both ends of both sides alternately with the side press and the top press. The adhesive bonding portion of the dot is pressed to bond the battery cell to the insulating cap. At this time, the side press pins open the H-shaped skeleton of the crimp pad of the H-shaped frame to the left and right to allow the side press to compress the side pre-adhesion sites on both sides of the battery pack.

The base material of the said battery cell, the said nozzle, the crimping pad of the said H frame | skeleton, the said side press, and the said top press uses the former base material.

In addition, the insulating mounting member has an opening in which the electrode terminals can be exposed while maintaining the electrical insulating property of the battery cell as an insulating member.

The insulating mounting member is formed of any one or more of thermosetting urethane, epoxy, thermosetting acrylic, melamine resin, phenol resin or alkyd resin.

Here, the resin for the insulating mounting member is a thermosetting resin that is hardened by a chemical reaction by applying heat, and is a resin that does not soften melt even after heating again after cooling.

In addition, the insulating cap protects the battery cell from the outside, and serves to maintain the electrical insulation while at the same time complementing the mechanical strength of the members mounted on the top of the battery cell.

The insulating cap is formed of any one or more of thermosetting urethane, epoxy, thermosetting acrylic, melamine resin, phenol resin or alkyd resin.

Here, the insulating cap resins are resins which harden by causing a chemical reaction by applying heat as a thermosetting resin and do not soften molten metal even when heated again after cooling.

In addition, the adhesive is a one-component or two-component adhesive, and includes an instant adhesive, an anaerobic adhesive, a urethane adhesive, an epoxy adhesive, or an acrylic adhesive.

Here, the one-component adhesive is an adhesive in which the main body and the curing agent are mixed, and the two-component adhesive is mixed when used as an adhesive provided with the main body and the curing agent separately.

Since the instant adhesive is hardened after being applied as a one-part type, the instant adhesive is pressed immediately after application to bond the insulating cap coupled to the upper end of the battery cell surrounding the insulating mounting member and the insulating mounting member.

The anaerobic adhesive is a one-component or two-component adhesive that is coated with an oxygen-free environment, that is, an adhesive that cures slowly in a closed place, and then immediately compresses or compresses after a predetermined time to wrap the insulating mounting member and the insulating mounting member. Bond the insulative cap bonded to the top of the cell.

The urethane adhesive is applied as a one-component or two-component thermosetting or photocurable adhesive and then immediately compressed or compressed after a predetermined time to bond the insulating cap coupled to the upper end of the battery cell surrounding the insulating mounting member and the insulating mounting member. .

The epoxy adhesive is applied as a one-component or two-component thermosetting or photocurable adhesive, and then immediately compressed or compressed after a predetermined time to bond the insulating cap coupled to the upper end of the battery cell surrounding the insulating mounting member and the insulating mounting member. .

The acrylic adhesive is applied as a one-component or two-component thermosetting or photocurable adhesive and then immediately compressed or pressed after a predetermined time to bond the insulating cap coupled to the upper end of the battery cell surrounding the insulating mounting member and the insulating mounting member. .

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

1 is a front view of a completed battery pack after pressing the battery pack of the present invention by a side press and a top press.

2 is a view showing the structure of the battery pack side press and top press apparatus of the present invention.

Figure 3 is a photograph of the compression pad of the H-type skeleton of the present invention from the top.

Figure 4 is a photograph of the side of the compression pad of the H-type skeleton of the present invention.

5 is a photograph showing a side press pin of the present invention.

Description of the Related Art [0002]

100: battery cell 130: adhesive coating site

150: insulating mounting member 160: protective circuit board

180: insulating cap 200: battery pack

210: side press 220: side press prize mold

225: side press lower mold 230: side press pin

240: mounting member of the H-shaped skeleton 250: top press

260: top press upper mold 265: top press lower mold

Claims (20)

An apparatus for manufacturing a battery pack, wherein the adhesive is applied to a point-glued portion at both ends of an upper portion of an insulating mounting member on an upper portion of a battery cell through a nozzle, and applied to a side pre-glued portion at both sides of a lower side of the insulating mounting member. A compression pad of an H-shaped skeleton holding a battery pack including an insulating cap fastened to surround the battery cell and the insulating mounting member on the battery cell; A side press which presses the crimp pad of the H-shaped skeleton through a side press pin to press the side pre-glued portions of both sides of the battery pack; The side press pins attached to the side presses to press the upper portion of the compression pads of the H type skeletons to spread the H type skeletons from side to side; And And a top press for pressing the adhesive bonding portions at both ends of the upper part of the battery pack. The apparatus of claim 1, wherein the H-shaped skeleton compression pad is formed of a plurality of H-shaped skeletons and a plurality of springs therebetween. The method of claim 1, wherein the compression pad of the H-type skeleton is a battery pack manufacturing apparatus, characterized in that formed of any one or more of aluminum, stainless steel, copper, or zinc. The apparatus of claim 1, wherein the shape of the upper die of the side press is a quadrangle, a circle, a rhombus, a polygon, or a three-dimensional shape thereof. The apparatus of claim 1, wherein the top press is longer than the side press, and the upper die is rectangular, circular, rhombic, polygonal, or three-dimensional. The apparatus of claim 1, wherein the lower die of the side press and the lower die of the top press have a rectangular bar shape. The apparatus of claim 1, wherein the side press and the top press operate by pneumatic, hydraulic, or electro-pneumatic methods. The apparatus of claim 1, wherein the side press and the top press alternately or simultaneously compress the battery packs. The battery pack manufacturing apparatus according to claim 1, wherein a sensor is mounted to stop the operation of the apparatus when an operator intervenes while the side press and the top press are pressed. The apparatus of claim 1, wherein the side press and the top press are formed of at least one of aluminum, stainless steel, copper, and zinc. The battery pack manufacturing according to claim 1, wherein the side press pins spread the H-shaped frame of the crimp pad of the H-shaped frame from side to side to allow the side press to compress pre-bonded portions of both sides of the battery pack. Device. The apparatus of claim 11, wherein the side press pin is formed of at least one of aluminum, stainless steel, copper, and zinc. The apparatus of claim 1, wherein the nozzle is an automatic or manual nozzle equipped with an adhesive injector, and the number of the nozzles includes at least one or more nozzles. The apparatus of claim 1, wherein the battery cell is a rectangular lithium secondary battery cell. The apparatus of claim 14, wherein the lithium secondary battery cell is a lithium ion battery cell, a lithium ion polymer battery cell, or a lithium polymer cell. The battery pack manufactured using the battery pack manufacturing apparatus as described in any one of Claims 1-15. A method of manufacturing a battery pack in which an adhesive is applied to a point adhesive portion at both ends of an upper portion of an insulating mounting member on an upper portion of a battery cell through a nozzle, and a line adhesive portion at both sides of a lower side of the insulating mounting member is pressed. Preparing a compression pad of an H-type skeleton holding a battery pack including an insulating cap fastened to surround the battery cell and the insulating mounting member on the battery cell; Pressing the side pre-glued portions of both sides of the battery pack with a side press after applying the adhesive; Pressing the upper side of the pressing pad of the H-type skeleton with the side press pin formed in the side press when the side press is pressed to spread the H-type skeleton to the left and right to compress the side pre-adhesion sites on both sides of the battery pack step; And At the same time as pressing by the side press or by pressing the side pre-adhesion portion of the both sides of the battery pack with the side press, and then pressing the point adhesive portion at both ends of the upper part of the battery pack by a top press to the battery cell And bonding the insulating cap to the insulating cap. 18. The method of claim 17, wherein the adhesive is a one-component or two-component adhesive including an instant adhesive, an anaerobic adhesive, a urethane adhesive, an epoxy adhesive, or an acrylic adhesive. 18. The method of claim 17, wherein the insulating mounting member is formed of any one or more of thermosetting urethane, epoxy, thermosetting acrylic, melamine resin, phenol resin, or alkyd resin. 18. The method of claim 17, wherein the insulating cap is formed of at least one of thermosetting urethane, epoxy, thermosetting acrylic, melamine resin, phenol resin, and alkyd resin.

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