KR102851285B1 - Secondary battery and method for manufacturing the same - Google Patents

Abstract

The secondary battery of the present invention comprises an electrode assembly and a pouch having a cylindrical shape for accommodating the electrode assembly, wherein the pouch comprises a receiving portion having a one-sided receiving box provided on one surface for accommodating one side of the electrode assembly and a other-sided receiving box provided on the other surface for accommodating the other side of the electrode assembly; a connecting portion integrally connected to both sides in the full width direction of the one-sided receiving box and the other-sided receiving box; and a sealing portion sealing both sides in the full length direction of the one-sided receiving box and the other-sided receiving box, wherein the pouch has a cylindrical shape with the one-sided receiving box, the other-sided receiving box, and the connecting portion integrally connected.

Description

Secondary battery and manufacturing method thereof {SECONDARY BATTERY AND METHOD FOR MANUFACTURING THE SAME}

The present invention relates to a secondary battery including a cylindrical pouch and a method for manufacturing the same.

In general, a secondary battery is a battery that can be charged and discharged, unlike a primary battery that cannot be recharged. These secondary batteries are widely used in advanced electronic devices such as phones, laptop computers, and camcorders.

The above secondary battery is classified into a can-type secondary battery in which the electrode assembly is built into a metal can, and a pouch-type secondary battery in which the electrode assembly is built into a pouch. The pouch-type secondary battery includes an electrode assembly in which electrodes and a separator are alternately laminated, a pouch that accommodates the electrode assembly, and an electrode lead that is coupled to an electrode tab provided in the electrode assembly.

Meanwhile, the pouch of the above-mentioned secondary battery has a structure in which an upper case and a lower case are combined, and the upper and lower cases are manufactured from a pouch film in which a protective layer, a metal layer, and a protective layer are sequentially laminated.

However, the above pouch had a problem in that the four sides were formed as cut surfaces, so the metal layer on the four edges of the pouch was exposed to the outside, and thus the withstand voltage was greatly increased.

Patent Publication No. 10-2019-0134201

The present invention was invented to solve the above problems, and the present invention can minimize the cut surface of the pouch by forming the pouch in a cylindrical shape, thereby greatly reducing the external exposure of the metal layer included in the pouch, thereby greatly lowering the withstand voltage, and in particular, it is an object of the present invention to provide a secondary battery and a manufacturing method thereof capable of implementing a pouch having a new structure.

In order to achieve the above object, the secondary battery of the present invention includes an electrode assembly and a pouch having a cylindrical shape for accommodating the electrode assembly, wherein the pouch includes a receiving portion having a one-sided receiving box provided on one surface for accommodating one side of the electrode assembly, and a other-sided receiving box provided on the other surface for accommodating the other side of the electrode assembly; a connecting portion integrally connected to both sides in the full width direction of the one-sided receiving box and the other-sided receiving box; and a sealing portion sealing both sides in the full length direction of the one-sided receiving box and the other-sided receiving box, wherein the pouch has a cylindrical shape while the one-sided receiving box, the other-sided receiving box, and the connecting portion are integrally connected, and the connecting portion can be pressed so as to be folded in half to closely connect the one-sided receiving box and the other-sided receiving box.

Meanwhile, the secondary battery of the present invention includes an electrode assembly and a pouch having a cylindrical shape for accommodating the electrode assembly, wherein the pouch includes a receiving portion having a one-sided receiving box for accommodating the electrode assembly on one side and a cover surface provided on the other side and closing the one-sided receiving box while being in close contact with the one-sided receiving box; a connecting portion integrally connected to both sides of the one-sided receiving box and the cover surface in the full width direction; and a sealing portion sealing both sides of the one-sided receiving box and the cover surface in the full length direction, wherein the pouch has a cylindrical shape while the one-sided receiving box, the cover surface, and the connecting portion are integrally connected, and the connecting portion can be pressed so as to be folded in half and be in close contact so as to connect the one-sided receiving box and the cover surface.

The above connecting portion can be pressed flat to connect one side of the receiving box and the other side of the receiving box.

The above connecting portion can be pressed flat to connect one side of the receiving container and the cover surface.

The above connecting portion can be joined in a flat pressed state.

A gas pocket portion may further be included between the above-mentioned receiving portion and the above-mentioned connecting portion.

The above-mentioned one-side receiving box may have a box shape in which a one-side receiving groove for receiving one side of the electrode assembly is formed, and the other-side receiving box may have a box shape in which a other-side receiving groove for receiving the other side of the electrode assembly is formed.

The above-mentioned one-sided receiving box may have a box shape in which a one-sided receiving groove is formed to receive the entire electrode assembly.

The inside of the fold of the flat pressed joint may further include a finishing agent.

Meanwhile, the secondary battery manufacturing method of the present invention comprises: a cylindrical pouch film preparation step (S10) in which a hollow is formed in the longitudinal direction, the cylindrical pouch film including one side and the other side receiving surfaces for forming one side and the other side receiving containers, a connecting surface connected to both sides in the longitudinal direction of the one side and the other receiving surfaces, and a sealing surface connected to both sides in the longitudinal direction of the one side and the other receiving surfaces; a receiving portion forming step (S20) in which one side and the other receiving surfaces of the cylindrical pouch film are formed to form a receiving portion having one side and the other receiving containers; an electrode assembly arranging step (S30) in which an electrode assembly is arranged between the one side and the other receiving containers; a connecting portion forming step (S40) in which the connecting surface is pressed flat to connect the one side and the other receiving containers, thereby accommodating the electrode assembly between the one side and the other receiving containers; And it includes a sealing portion forming step (S50) of pressing and sealing the sealing surfaces provided on both sides of the one side and the other side receiving box in the full length direction, and when the sealing portion forming step (S50) is completed, a secondary battery is manufactured, and in the connecting portion forming step (S40), a connecting portion is formed by pressing the connecting surface so that it is folded in half, and the one side receiving box and the other side receiving box can be tightly connected through the connecting portion.

The above-mentioned connecting portion forming step (S40) may further include a joining process of applying heat to the flat pressed connecting portion to join it.

In the above-mentioned cylindrical pouch film preparation step (S10), the pouch film may further include a gas pocket surface between one side and the other side receiving surface and the connecting surface, and the sealing portion forming step (S50) may further include a process of forming a gas pocket portion by sealing between the one side and the other side receiving surface and the gas pocket surface, and between the gas pocket surface and the connecting surface.

After the sealing portion forming step (S50), the method may further include a charging/discharging step (S70) for charging/discharging the secondary battery, a resealing step (S80) for sealing the space between the receiving portion of the pouch and the gas pocket portion, and a gas pocket portion removing step for cutting and removing the gas pocket portion connected to the receiving portion of the pouch.

In the above sealing portion forming step (S50), a gas passage can be formed in the sealing portion between the one-side and the other-side receiving container and the gas pocket surface.

The secondary battery of the present invention comprises a pouch having a cylindrical shape for accommodating an electrode assembly, wherein the pouch is characterized by including a receiving portion having one side and the other side receiving compartments, a connecting portion, and a sealing portion. In particular, the pouch has a cylindrical shape in which the one side receiving compartment, the other side receiving compartment, and the connecting portion are integrally connected, thereby reducing the cross-section of the pouch to two sides, thereby minimizing the metal layer exposed to the outside of the pouch, thereby reducing the withstand voltage. In particular, a pouch having a new structure can be manufactured, and the process can be simplified and the sealing property can be improved.

In addition, in the secondary battery of the present invention, the connecting portion has the characteristic of being pressed flat, and due to this characteristic, one side receiving box and the other side receiving box provided in the pouch can be closely connected and thus the electrode assembly can be stably accommodated. That is, when the connecting portion has an arc shape, the one side and the other side receiving boxes are spaced apart from each other, so that the electrode assembly can be easily accommodated between the one side and the other receiving boxes, and when the connecting portion is pressed flat, the one side and the other side receiving boxes are connected, so that the electrode assembly arranged therebetween can be accommodated.

Additionally, the secondary battery of the present invention is characterized by having a connection portion that is pressed flat. This characteristic prevents separation of one and the other housings when the connection portion is restored, thereby stably housing the electrode assembly between the one and the other housings.

Meanwhile, the secondary battery of the present invention is characterized in that a finishing agent is further included on the inside of the folded portion of the flattened connection. This finishing agent can increase the adhesive strength of the inside of the folded portion of the connection and prevent the formation of a gap on the inside of the folded portion of the flattened connection. That is, the inside of the folded portion of the flattened connection may form a gap due to the restoring force, which may weaken the sealing strength and cause the inflow of foreign substances. To prevent this, before the connection is flattened, a finishing agent having adhesive strength is additionally placed on the inside of the folded portion of the connection, so that when the connection is flattened, the inside of the folded portion of the connection can be bonded by the finishing agent without forming a gap.

In addition, the secondary battery of the present invention is characterized in that a gas pocket part is further included between the receiving part and the connecting part, and due to this characteristic, a cylindrical pouch including the gas pocket part can be implemented.

FIG. 1 is a perspective view illustrating a secondary battery according to a first embodiment of the present invention.
Figure 2 is a front view of Figure 1.
Figure 3 is a side view of Figure 1.
Figure 4 is a plan view of Figure 1.
Figure 5 is a perspective view showing a pouch of a secondary battery according to the first embodiment of the present invention.
Figure 6 is a cross-sectional view of Figure 5.
Figure 7 is a flowchart showing a method for manufacturing a secondary battery according to the first embodiment of the present invention.
Figure 8 is a process diagram showing a cylindrical pouch film preparation step of a secondary battery manufacturing method according to the first embodiment of the present invention.
Figure 9 is a process diagram showing the receiving portion forming step and electrode assembly arrangement step of the secondary battery manufacturing method according to the first embodiment of the present invention.
Figure 10 is a process diagram showing a connecting part forming step of a secondary battery manufacturing method according to the first embodiment of the present invention.
Figure 11 is a process diagram showing a sealing part forming step of a secondary battery manufacturing method according to the first embodiment of the present invention.
Fig. 12 is a perspective view illustrating a secondary battery according to a second embodiment of the present invention.
Figure 13 is a front view of Figure 12.
Figure 14 is a plan view showing the gas pocket part forming step and the charging/discharging step of the secondary battery manufacturing method according to the second embodiment of the present invention.
Figure 15 is a plan view showing the resealing step and the gas pocket cutting step of the secondary battery manufacturing method according to the second embodiment of the present invention.
Fig. 16 is a front perspective view illustrating a secondary battery according to a third embodiment of the present invention.
Fig. 17 is a rear perspective view illustrating a secondary battery according to a third embodiment of the present invention.
Fig. 18 is a front view showing a secondary battery according to the fourth embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings so that those skilled in the art can easily implement the present invention. However, the present invention may be implemented in various different forms and is not limited to the embodiments described herein. In addition, in the drawings, parts irrelevant to the description have been omitted to clearly explain the present invention, and similar parts have been designated with similar reference numerals throughout the specification.

[Secondary battery according to the first embodiment of the present invention]

A secondary battery (100) according to a first embodiment of the present invention includes, as illustrated in FIGS. 1 to 6, an electrode assembly (110), an electrode lead (120) coupled to an electrode tab of the electrode assembly (110), and a pouch (130) that accommodates the electrode assembly (110) with the tip of the electrode lead (120) extended outward. In addition, the pouch (130) is manufactured using a protective film laminated with a protective layer, a metal layer, and a protective layer.

Here, the pouch (130) of the secondary battery (100) according to the first embodiment of the present invention has a cylindrical shape in order to minimize external exposure of the metal layer. That is, the pouch (130) having a cylindrical shape has cut surfaces only on the front and back of the pouch as seen in FIG. 1, and thus, since the metal layer is exposed to the outside only on the front and back of the pouch, external exposure of the metal layer can be minimized, and as a result, withstand voltage can be reduced.

For example, the pouch (130) includes a receiving portion (131) having a one-side receiving portion (131a) provided on one side and receiving one side of an electrode assembly (110) and a other-side receiving portion (131b) provided on the other side and receiving the other side of the electrode assembly (110), a connecting portion (132) integrally connected on both sides in the full-width direction of the one-side receiving portion (131a) and the other-side receiving portion (131b), and a sealing portion (133) sealing both sides in the full-length direction of the one-side receiving portion (131a) and the other-side receiving portion (131b).

The above-mentioned receiving portion (131) includes a receiving box (131a) having a receiving groove formed on one side for receiving one side of the electrode assembly (110) (the upper side of the electrode assembly as seen in FIG. 1), and a receiving box (131b) having a receiving groove formed on the other side for receiving the other side of the electrode assembly (110) (the lower side of the electrode assembly as seen in FIG. 1). When the receiving box (131a) and the receiving box (131b) are in close contact, the receiving groove on the one side and the receiving groove on the other side are connected to form a receiving space for sealingly receiving the electrode assembly.

Here, the one-side receiving box (131a) has a box shape that protrudes in the upper direction of the pouch as seen in Fig. 1, and thus a one-side receiving groove for receiving one side of the electrode assembly (110) is formed. In addition, the other-side receiving box (131b) has a box shape that protrudes in the lower direction of the pouch as seen in Fig. 1, and thus a receiving groove for receiving the other side of the electrode assembly (110) is formed.

The above connecting portion (132) is provided on both sides of the one-side receiving box (131a) and the other-side receiving box (131b) in the full width direction, and integrally connects both sides of the one-side receiving box (131a) and the other-side receiving box (131b) in the full width direction. Accordingly, the pouch (130) takes the shape of a cylinder when the one-side receiving box (131a), the other-side receiving box (131b) and the connecting portion (132) are connected.

The above sealing portion (133) is provided with sealing surfaces on both sides in the longitudinal direction of the one-side receiving box (131a) and the other-side receiving box (131b), and is formed by thermally bonding the sealing surfaces of the one-side receiving box (131a) and the other-side receiving box (131b). In particular, the sealing portion (133) seals both sides in the longitudinal direction of the pouch.

The pouch (130) having such a structure can have a tubular shape as the one-sided receiving box (131a), the other-sided receiving box (131b), and the connecting portion (132) are integrally connected as shown in FIG. 1, thereby obtaining a pouch of a new shape. In particular, the cross-section of the pouch can be minimized, thereby significantly reducing the withstand voltage.

Meanwhile, the connecting portion (132) is pressed flat with respect to a center line having equal vertical lengths as seen in FIG. 1, so as to connect and closely contact one side receiving box (131a) and the other side receiving box (131b). Accordingly, when the connecting portion (132) maintains an arc shape, the one side receiving box (131a) and the other side receiving box (11b) are positioned separately, so that the electrode assembly (110) can be easily placed between the one side receiving box (131a) and the other side receiving box (131b). In addition, when the connecting portion (132) is pressed flat, the one side receiving box (131a) and the other side receiving box (131b) are pressed closely, so that the electrode assembly can be accommodated between the one side receiving box (131a) and the other side receiving box (131b).

Meanwhile, the connecting portion (132) can be joined in a flat pressed state. That is, the connecting portion (132) is joined so as not to return to the original position in a flat pressed state, thereby maintaining the connected state of one side receiving box (131a) and the other side receiving box (131b), and as a result, the electrode assembly can be hermetically accommodated between the one side receiving box (131a) and the other side receiving box (131b). That is, the connecting portion (132) can be thermally bonded by applying heat while in a flat pressed state.

Meanwhile, the connecting portion (132) can be pressed flat while containing adhesive inside, thereby increasing the fixing strength of the connecting portion.

Meanwhile, the inside of the folded portion (132a) of the flattened connecting portion (132) may have a hole (132b) (or gap) formed by the restoring force, which may cause weakening of the sealing force and inflow of foreign substances. In order to close the hole, the connecting portion (132) additionally has a finishing agent (132c) placed on the inside of the flattened folded portion (132a). That is, when the connecting portion (132) is flattened while the finishing agent (132c) is included, the hole (132b) formed in the folded portion of the connecting portion can be closed by the finishing agent (132c). In particular, the finishing agent (132c) has insulating and adhesive properties, and thus can increase the bonding strength of the connecting portion (132).

Therefore, the secondary battery (100) according to the first embodiment of the present invention has a feature of including a pouch having a cylindrical shape, and due to this feature, a pouch with a minimized cross-section can be implemented, and accordingly, the metal layer exposed to the outside of the pouch can be minimized, thereby reducing the withstand voltage, and in particular, a newly designed secondary battery can be obtained.

Hereinafter, a method for manufacturing a secondary battery according to the first embodiment of the present application will be described.

[Method for manufacturing a secondary battery according to the first embodiment of the present invention]

The secondary battery manufacturing method according to the first embodiment of the present invention includes a cylindrical pouch film preparation step (S10), a receiving portion forming step (S20), an electrode assembly arrangement step (S30), a connecting portion forming step (S40), and a sealing portion forming step (S50), as illustrated in FIGS. 7 to 11.

Preparing the tubular pouch film

In the cylindrical pouch film preparation step (S10), referring to FIG. 8, a cylindrical pouch film (130a) having a hollow formed in the longitudinal direction (front-back direction when viewed in FIG. 8) is prepared. Here, the cylindrical pouch film (130a) is provided with a one-side receiving surface (130b) for forming a one-side receiving compartment on one side (the upper surface when viewed in FIG. 8), a other-side receiving surface (130c) for forming the other-side receiving compartment on the other side (the lower surface when viewed in FIG. 8), a connecting surface (130d) for forming a connecting portion on both sides in the longitudinal direction (left-right direction when viewed in FIG. 9), and a sealing surface (130e) for forming a sealing portion on both sides in the longitudinal direction (front-back direction when viewed in FIG. 8).

Receptacle forming stage

Referring to FIG. 9, the receiving portion forming step (S20) forms one side receiving surface (130b) and the other side receiving surface (130c) of the cylindrical pouch film (130a) so that they protrude outwardly from the cylindrical pouch film (130a) to form one side receiving box (131a) and the other side receiving box (131b). At this time, the one side receiving box (131a) and the other side receiving box (131b) have corresponding shapes. In addition, a one side receiving groove for receiving one side of the electrode assembly is formed on the inside of the one side receiving box (131a), and a other side receiving groove for receiving the other side of the electrode assembly is formed on the inside of the other side receiving box (131b).

In particular, the one-sided receiving box (131a) and the other-sided receiving box (131b) are positioned separately from each other because the pouch film has a tubular shape.

Electrode assembly placement stage

The electrode assembly arrangement step (S30) arranges the electrode assembly (110) between one side receiving box (131a) and the other side receiving box (131b). At this time, the electrode assembly (110) can be arranged easily because the one side receiving box (131a) and the other side receiving box (131b) are separated.

Connection formation stage

Referring to FIG. 10, the connection portion forming step (S40) presses the connection surface (130d) provided on the cylindrical pouch film (130a) flat using a pressing device (10). Then, the connection surface (130d) is pressed so as to be folded in half, thereby forming the connection portion (132). In particular, as the entire cylindrical pouch film (130a) is pressed flat, one side receiving box (131a) and the other side receiving box (131b) are brought into close contact, and thus the electrode assembly (110) can be received inside the receiving box (131). That is, one side of the electrode assembly is received in the one side receiving box (131a), and the other side of the electrode assembly is received in the other side receiving box (131b).

Meanwhile, the connecting portion forming step (S40) further includes a joining process of applying heat to the flatly pressed connecting portion (132) to join it. That is, heat is applied to the connecting portion (132) to join it so that the flatly pressed connecting portion (132) does not return to its original state.

Sealing part formation stage

Referring to Fig. 11, the sealing portion forming step (S50) seals the sealing surfaces (131e) connected to the one-side and the other-side receiving boxes (131a) (131b) using a sealing device (20). Then, the sealing portion (133) is formed as both sides of the one-side and the other-side receiving boxes (131a) (131b) in the longitudinal direction are sealed.

When the sealing portion forming step (S50) is completed as described above, a finished secondary battery (100) having a cylinder shape can be manufactured.

Hereinafter, in describing other embodiments of the present application, the same component symbols are used for components having the same functions as the above-described embodiments, and redundant descriptions are omitted.

[Secondary battery according to the second embodiment of the present invention]

A secondary battery (100) according to a second embodiment of the present invention has the same structure as the secondary battery according to the first embodiment described above, but has a structure that further includes a gas pocket portion (134) that captures gas generated from the electrode assembly.

That is, the secondary battery (100) according to the second embodiment of the present invention includes, as illustrated in FIGS. 12 and 13, an electrode assembly (110), an electrode lead (120) coupled to an electrode tab of the electrode assembly (110), and a pouch (130) that accommodates the electrode assembly (110) with the tip of the electrode lead (120) extended outward.

And the above pouch (130) includes a receiving portion (131) having a one-side receiving portion (131a) and an other-side receiving portion (131b), a connecting portion (132), and a sealing portion (133).

Here, the secondary battery (100) according to the second embodiment of the present invention further includes a gas pocket portion (134) between the receiving portion (131) and the connecting portion (132).

That is, the gas pocket portion (134) includes a gas pocket surface (134a) formed between one side receiving container (131a) and the connecting portion (132), and between the other side receiving container (131b) and the connecting portion (132). That is, the gas pocket portion (134) is formed by sealing between the one side and the other side receiving containers and the gas pocket surface, and between the gas pocket surface and the connecting portion. In particular, a gas passage (134b) is formed in the sealing portion between the one side and the other side receiving containers and the gas pocket surface so that gas generated in the receiving portion (131) flows into the gas pocket portion (134).

Therefore, the secondary battery (100) according to the second embodiment of the present invention can implement a pouch having a tubular shape including a gas pocket portion (134).

Hereinafter, a method for manufacturing a secondary battery according to a second embodiment of the present invention will be described.

[Method for manufacturing a secondary battery according to the second embodiment of the present invention]

The secondary battery manufacturing method according to the second embodiment of the present invention manufactures a secondary battery in the same manner as the secondary battery manufacturing method according to the first embodiment described above, as illustrated in FIGS. 14 and 15.

However, the secondary battery manufacturing method according to the second embodiment of the present invention additionally secures an area for forming a gas pocket portion in the cylindrical pouch film preparation step (S10). That is, the cylindrical pouch film further includes a gas pocket surface (134a) between one side and the other side receiving surface (130b) (130c) and the connecting surface (130d), thereby additionally securing an area for forming a gas pocket portion.

And the sealing portion forming step (S50) further includes a process of forming a gas pocket portion by sealing between the one-side and the other-side receiving containers (131a) (131b) and the gas pocket surface (134a), and between the gas pocket surface (134a) and the connecting portion (132). Here, a gas passage (134b) connecting the receiving portion and the gas pocket portion is secured in the sealing portion between the one-side and the other-side receiving containers and the gas pocket surface.

Therefore, the secondary battery manufacturing method according to the second embodiment of the present invention can manufacture a cylindrical pouch including a gas pocket portion, and can manufacture a secondary battery including a cylindrical pouch.

Meanwhile, the secondary battery manufacturing method according to the second embodiment of the present invention further includes, after the sealing portion forming step (S50), a charging/discharging step of charging/discharging the secondary battery, a re-sealing step of sealing the space between the receiving portion and the gas pocket portion of the pouch, and a gas pocket portion removing step of cutting and removing the gas pocket portion connected to the receiving portion of the pouch. At this time, before cutting the gas pocket portion, a re-sealing process of sealing the gas passage (134b) connecting the receiving portion and the gas pocket portion is further performed.

The above charging and discharging step activates the finished secondary battery (100). At this time, gas is generated inside the pouch (130) of the secondary battery (100). The gas generated inside the pouch (130) is captured in the gas pocket part (134) through the gas passage (134b), and the gas captured in the gas pocket part (134) is released to the outside.

The above resealing step reseales the gas passage (134b) connecting the receiving portion (131) and the gas pocket portion (134) so that it is sealed.

The above gas pocket part removal step is performed by cutting and removing the gas pocket part (134) from the receiving part (131) while leaving a portion of the sealing part between the receiving part (131) and the gas pocket part (134). When the above gas pocket part removal step is completed, the secondary battery according to the second embodiment of the present invention is completed.

[Secondary battery according to the third embodiment of the present invention]

A secondary battery (100) according to a third embodiment of the present invention includes, as illustrated in FIGS. 16 and 17, an electrode assembly (110), an electrode lead (120) coupled to the electrode assembly (110), and a pouch (130) having a tubular shape that accommodates the electrode assembly (110) with the tip of the electrode lead (120) extended outward.

The above pouch (130) includes a receiving portion (131), a connecting portion (132), and a sealing portion (133).

The above-mentioned receiving portion (131) includes a one-sided receiving box (131a) provided on one side (the upper side when viewed in FIG. 16) and accommodating the entire electrode assembly (110), and a cover surface (131c) provided on the other side (the lower side when viewed in FIG. 16) and closing the one-sided receiving box (131a) while being in close contact with the one-sided receiving box (131a).

The above connecting portion (132) is integrally connected to both sides of the one-sided receiving box (131a) and the cover surface (131c) in the full width direction (left-right direction when viewed in FIG. 16).

The above sealing portion (133) is provided in the full-length direction (front-back direction when viewed in FIG. 16) of the one-side receiving box and the cover surface, and seals both sides of the receiving box in the full-length direction.

Therefore, the secondary battery (100) according to the third embodiment of the present invention can implement a pouch having a tubular shape by integrally connecting the one-side receiving compartment, the cover surface, and the connecting portion.

In particular, the above-mentioned connecting portion is pressed flat to connect one side of the receiving container and the cover surface, and the flat-pressed connecting portion can be prevented from being restored while being bonded.

[Secondary battery according to the fourth embodiment of the present invention]

A secondary battery (100) according to a fourth embodiment of the present invention has the same structure as the secondary battery (100) according to the third embodiment of the present invention, as illustrated in FIG. 18, but has a structure that further includes a gas pocket portion (134) that captures gas generated from the electrode assembly.

That is, the secondary battery (100) according to the fourth embodiment of the present invention further includes a gas pocket portion (134) between the receiving portion (131) and the connecting portion (132).

The above gas pocket portion (134) includes a gas pocket surface (134a) formed between a one-sided receiving portion (131a) and a connecting portion (132), and between a cover surface (131c) and a connecting portion (132), and is formed by sealing between the receiving portion and the gas pocket surface, and between the gas pocket surface and the connecting portion. In particular, a gas passage (134b) is formed in the sealing portion between the receiving portion (131) and the gas pocket surface (134a) so that gas generated in the receiving portion flows into the gas pocket portion.

Therefore, the secondary battery (100) according to the fourth embodiment of the present invention can implement a cylindrical pouch including a gas pocket portion.

The scope of the present invention is indicated by the claims described below rather than the detailed description above, and various embodiments are possible derived from the meaning and scope of the claims and their equivalent concepts.

100: Secondary battery
110: Electrode assembly
120: Electrode lead
130: Pouch
131: Reception area
131a: One-sided acceptance
131b: Other side reception
132: Connection
133: Sealing
134: Gas pocket section

Claims (14)

Electrode assembly, and
A pouch having a tubular shape that accommodates the electrode assembly is included.
The above pouch is,
A receiving unit having a one-sided receiving box provided on one side and receiving one side of an electrode assembly, and an other-sided receiving box provided on the other side and receiving the other side of the electrode assembly;
A connecting portion integrally connected to both sides of the one-sided receiving box and the other-sided receiving box in the full width direction; and
It includes a sealing part that seals both sides of the one-sided receiving box and the other-sided receiving box in the full-length direction,
The above pouch has a tubular shape with the one-sided receiving compartment, the other-sided receiving compartment, and the connecting portion being connected as one piece.
The above connecting portion is a secondary battery that is compressed so as to be folded in half and connects one side of the receiving box and the other side of the receiving box. Electrode assembly, and
A pouch having a tubular shape that accommodates the electrode assembly is included.
The above pouch is,
A receiving portion having a one-sided receiving box that is provided on one side and accommodates the electrode assembly, and a cover surface that is provided on the other side and is in close contact with the one-sided receiving box to close the one-sided receiving box;
A connecting portion integrally connected to both sides of the above-mentioned one-sided receiving box and the full width direction of the above-mentioned cover surface; and
It includes a sealing portion that seals both sides of the above-mentioned one-sided receiving box and the cover surface in the full-length direction,
The above pouch has a tubular shape with the one-sided receiving compartment, the cover surface and the connecting portion being connected as one piece,
The above connecting portion is a secondary battery that is compressed so as to be folded in half and is tightly connected to one side of the receiving container and the cover surface. delete delete In claim 1 or claim 2,
The above connecting portion is a secondary battery that is joined in a flat, pressed state. In claim 1 or claim 2,
A secondary battery further comprising a gas pocket portion between the receiving portion and the connecting portion. In claim 1,
The above one-sided receiving box has a box shape in which a one-sided receiving groove for receiving one side of the electrode assembly is formed,
The above-mentioned other-side receiving box is a secondary battery having a box shape in which a other-side receiving groove for receiving the other side of the national assembly is formed. In claim 2,
A secondary battery having a box shape in which a one-sided receiving groove is formed to receive the entire electrode assembly. In claim 1 or claim 2,
A secondary battery further including a finishing agent inside the folded portion of the flattened connecting portion. A cylindrical pouch film preparation step (S10) in which a hollow is formed in the longitudinal direction, the cylindrical pouch film including one side and the other side receiving surfaces for forming one side and the other side receiving compartments, a connecting surface connected to both sides in the longitudinal direction of the one side and the other side receiving surfaces, and a sealing surface connected to both sides in the longitudinal direction of the one side and the other side receiving surfaces;
A receiving portion forming step (S20) in which one side and the other side receiving surfaces of a cylindrical pouch film are formed to form a receiving portion having one side and the other side receiving containers;
An electrode assembly arrangement step (S30) of arranging an electrode assembly between the one-side and the other-side receiving boxes;
A step (S40) of forming a connection portion that accommodates an electrode assembly between the one-side and the other-side receiving boxes by pressing the above connecting surface flatly to connect the one-side and the other-side receiving boxes; and
It includes a sealing part forming step (S50) for sealing by pressing the sealing surfaces provided on both sides of the front direction of the one-side and the other-side receiving containers,
When the above sealing part forming step (S50) is completed, a secondary battery is manufactured.
A secondary battery manufacturing method in which a connection is formed by pressing the connection surface so that it is folded in half in the above connection forming step (S40), and a one-sided receiving box and an other-sided receiving box are connected and tightly connected through the connection. In claim 10,
A secondary battery manufacturing method, wherein the above-mentioned connecting portion forming step (S40) further includes a bonding process of applying heat to the flatly pressed connecting portion to bond it. In claim 10,
In the above-mentioned cylindrical pouch film preparation step (S10), the pouch film further includes a gas pocket surface between one side and the other side receiving surface and the connecting surface,
The above sealing portion forming step (S50) is a secondary battery manufacturing method further including a process of forming a gas pocket portion by sealing between one side and the other side receiving container and the gas pocket surface, and between the gas pocket surface and the connecting surface. In claim 12,
A secondary battery manufacturing method further comprising, after the sealing portion forming step (S50), a charging/discharging step (S70) of charging/discharging the secondary battery, a resealing step (S80) of sealing the space between the receiving portion of the pouch and the gas pocket portion, and a gas pocket portion removing step of cutting and removing the gas pocket portion connected to the receiving portion of the pouch. In claim 12,
A secondary battery manufacturing method in which a gas passage is formed in the sealing portion between the one-side and the other-side receiving containers and the gas pocket surface in the sealing portion forming step (S50).