Patent Description:
Secondary batteries may be recharged and miniaturized and it is possible to increase the capacity. Secondary batteries may be classified into can-type or pouch-type secondary batteries according to the shape of the outer case, and the pouch-type secondary battery consists of a battery cell in which an electrode tab is formed on one side of the electrode plate, and a pouch enclosing and sealing the electrode plate so that the electrode tab is drawn out. The battery cell has a separator interposed between a plurality of positive and negative electrode plates, and the battery cell is sealed in a pouch, and the electrode tab on one side of the battery cell is drawn out to the outside of the pouch. A battery cell in which such a battery cell is embedded in a pouch is referred to as a pouch-type secondary battery.

Here, when forming a pouch in which the battery cells are embedded, the middle portion of the pouch sheet having a half-fold battery cell accommodating part is folded to embed the battery cells in the battery cell accommodating part inside the pouch.

However, there is a problem in that the bending side of the pouch <NUM> is concavely deformed inward as the middle portion of the pouch sheet is pushed in during the bending operation of folding the middle portion of the pouch sheet. In other words, when the pouch sheet is folded, the bending side of the pouch falls into the inside and there is a problem such as being concavely crushed.

In the case of a battery without a bottom, when the pouch is bent, the pouch <NUM> enters the main room, resulting in a smaller size of the main room. The fact that the pouch enters the main room means that the bending side of one side of the pouch is pushed into the inside of the pouch when the pouch sheet is folded to form a pouch, and as such, when the pouch is bent, a problem that the size of the main room of the pouch
becomes smaller due to the pouch being brought into the main room occurs.

In addition, if the bending side of the pouch is concavely deformed inward, heat generated during the charging/discharging operation of the secondary battery battery cell is not properly discharged. A plurality of pouches with built-in battery cells (hereinafter, referred to as pouches for convenience) are placed side by side on the hanger frame and mounted, and the bending side of the pouch conducts and discharges the heat generated in the pouch during the battery cell charging/discharging operation from the bending side to the heat sink, in a state in contact with the heat sink (a metal plate with high thermal conductivity, which may be, for example, an aluminum plate) provided at the bottom of the hanger frame, and if there is a concave deformed part in which the bending side of the pouch is concave inward, since the concave deformed part does not properly contact the heat sink, there is a problem in that the heat generated in the pouch during the battery cell charging/discharging operation cannot be properly transferred to the heat sink from the bending side, so that the heat generated inside the pouch cannot be properly dissipated during the battery cell charging/discharging operation, and if the heat dissipation from the pouch is not properly done, there is also a problem that the battery cells are deteriorated or burned by heat.

Document <CIT> discloses a secondary battery manufacturing device comprising a first folding jig and a second folding jig whose lower ends on both sides are rotatably connected to a base frame via hinge brackets, respectively. The first folding jig and the second folding jig are configured to fold a pouch disposed between them. However, any means to prevent a bent side of the pouch from being pushed into the pouch is not installed in the first folding jig or the second folding jig.

<CIT> relates to a battery case sealing device with a wrinkle removal function and discloses the configuration of a battery case sealing device including a nest, a sealing tool, and a pusher. The nest is configured to fold a pouch disposed therebetween. However, any means is not installed in the nest to prevent a bent side of the pouch from being pushed into the pouch.

The present disclosure has been proposed to solve the problems of the related art as described above, and an object of the present disclosure is to provide a pouch bending guide apparatus and a pouch bending method for a secondary battery packaging system using a stopping means of a new configuration which may prevent the bending side of the pouch from being concavely deformed in the bending process of disposing the battery cell on the pouch sheet and folding the base jig and the bending jig, and smoothly dissipate heat generated during charging/discharging of secondary batteries from the pouch. In other words, the main object of the present disclosure is to prevent the bending side of the pouch from entering the inside in the process of bending the pouch sheet to embed the battery cell in the pouch.

According to the present disclosure to solve the problems as described above, there is provided a pouch bending guide apparatus of a secondary battery packaging system using a stopping means, which folds a pouch sheet while a bending jig is folded toward a base jig in a state where the pouch sheet is disposed on the base jig and the bending jig, wherein a stopping means for preventing a bending side of a pouch from being pushed into the pouch by supporting at least one side of the pouch formed when the pouch sheet is folded by the bending jig is included, the stopping means being formed of a pad provided on an inner surface of the bending jig.

The present disclosure is effective in solving the problem that the bending side of the pouch is concavely deformed inward by preventing the case in which the middle portion of the pouch sheet is pushed in during the bending operation of folding the middle portion of the pouch sheet.

In addition, the appearance quality of the pouch is improved and the reliability of the pouch is improved because the bending side of the pouch is not pushed inward.

The present disclosure is a pouch bending guide apparatus of a secondary battery packaging system which folds a pouch sheet while a bending jig is folded toward a base jig in a state where the pouch sheet is disposed on the base jig and the bending jig, including a stopping means for preventing a bending side 2BS of a pouch from being pushed into the pouch by supporting at least one side of the pouch <NUM> formed when the pouch sheet is folded by the bending jig, the stopping means being formed by a pad provided on the inner surface of the bending jig.

The present disclosure is a pouch bending guide apparatus of a secondary battery packaging system using a stopping means for preventing a bending side 2BS of a pouch <NUM> from being pushed into the pouch <NUM> when the pouch sheet 2A is folded by the bending jig <NUM> being folded toward a base jig <NUM> in a state where the pouch sheet 2A is disposed on the base jig <NUM> and the bending jig <NUM>. The present disclosure is provided with a stopping means <NUM> as a main part. The stopping means <NUM> provided at least in the inside of the bending jig <NUM>. The main feature is to prevent the bending side 2BS of the pouch <NUM> from being pushed into the pouch <NUM> by supporting the outer surface of the pouch <NUM> by the stopping means <NUM> when the pouch <NUM> is formed by a bending operation. In the present disclosure, when the pouch <NUM> is formed by bending the pouch sheet 2A, the stopping means <NUM> supports the battery cell accommodating part of the pouch <NUM> from the outside to prevent the bending side 2BS of the pouch <NUM> from being pushed into the pouch <NUM>, and since the battery cell accommodating part of the pouch <NUM> is a configuration of the pouch <NUM>, it will be understood that the stopping means <NUM> supports the pouch <NUM> from the outside.

The bending jig <NUM> is supported by the support frame and at the same time is folded into the inner surface of the base jig <NUM> by a bending driving unit and unfolded outward from the inner surface of the base jig <NUM>. A concave half-fold pouch battery cell accommodating part seating groove is also provided on the inner surface of the bending jig <NUM>. The pouch battery cell accommodating part seating groove of the bending jig <NUM> also has a rectangular groove shape.

The base jig <NUM> is mounted on a support frame, and one side wall of the base jig <NUM> and the bending jig <NUM> is connected to each other by a hinge part. The bending jig <NUM> is folded toward the inner surface of the base jig <NUM> so that the inner surface of the base jig <NUM> and the bending jig <NUM> face each other, and the bending jig <NUM> is unfolded outward from the inner surface of the base jig <NUM>. The base jig <NUM> and the bending jig <NUM> are configured in a plate shape having a pouch battery cell accommodating part seating groove therein. Based on the hinge portion, the bending jig <NUM> is folded toward the base jig <NUM> and unfolded from the base jig <NUM>.

In a state where the bending jig <NUM> is unfolded from the base jig <NUM>, the inner surface of the bending jig <NUM> faces upward.

Preferably, a vacuum suction passage is provided inside the base jig <NUM> and the bending jig <NUM>, and a plurality of vacuum suction holes communicating with the vacuum suction passage are provided on inner surfaces of the base jig <NUM> and the bending jig <NUM> facing each other. The vacuum suction hole of the base jig <NUM> is opened to the inner surface of the base jig <NUM> while being connected to the internal vacuum suction passage of the base jig <NUM>. In addition, the vacuum suction hole of the bending jig <NUM> is also opened to the inner surface of the bending jig <NUM> while being connected to the internal vacuum suction passage of the bending jig <NUM>.

The base jig <NUM> and the outer surface of the pouch sheet 2A placed on the inner surface of the bending jig <NUM> are disposed to face the vacuum suction hole of the base jig <NUM> and the vacuum suction hole of the bending jig <NUM>.

The vacuum suction passage and the vacuum suction hole inside the base jig <NUM> and the vacuum suction passage and the vacuum suction hole inside the bending jig <NUM> are connected to a vacuum device (not shown) by a connecting hose, a vacuum connection block <NUM> and a vacuum pressure filling block <NUM>. By sucking air through the vacuum suction hole on the inner surface of the base jig <NUM> and the vacuum suction hole on the inner surface of the bending jig <NUM> by a vacuum device, the pouch sheet 2A can be closely adhered to the inner surface of the base jig <NUM> and the inner surface of the bending jig <NUM> by vacuum.

A vacuum device is connected to the vacuum suction passage of the base jig <NUM> and the bending jig <NUM> by a connecting means such as a hose not shown, so that the bending jig <NUM> is configured to fold toward the base jig <NUM> based on the hinge part or unfold based on the hinge part in a state where the base jig <NUM> and the bending jig <NUM> adsorb the pouch sheet 2A by the operation of the vacuum device. The operation of folding or unfolding the bending jig <NUM> on the base jig <NUM> may be performed by a bending operation means not shown. Since the bending operation means may use a known device such as a cylinder, a detailed description thereof will be omitted.

A pouch sheet 2A is disposed on the base jig <NUM> and the bending jig <NUM>, a battery cell is accommodated in a half-fold battery cell accommodating part disposed on the base jig <NUM> among a pair of half-fold battery cell accommodating parts of the pouch sheet 2A, and in a state where the two half-fold battery cell accommodating parts of the pouch sheet 2A are seated in the pouch battery cell accommodating part seating groove inside each base jig <NUM> and the pouch battery cell accommodating part seating groove of the bending jig <NUM>, as the bending jig <NUM> is folded toward the base jig <NUM>, the pouch sheet 2A is folded, and the pouch sheet 2A is folded to form a pouch <NUM> in which a battery cell is embedded in an internal battery cell accommodating part.

One side walls of the base jig <NUM> and the bending jig <NUM> are connected to each other by a hinge part, and a bending guide opening part OP communicating with the inner and outer surfaces are formed on one sidewalls of the base jig <NUM> and the bending jig <NUM>. The bending guide opening part OP is also formed on one side wall of the base jig <NUM>, and is also formed on one side wall of the bending jig <NUM>. In other words, the bending guide opening part PO formed on one side walls of the base jig <NUM> and the bending jig <NUM> communicates with one side wall of the base jig <NUM> and one side wall of the bending jig <NUM> from one side of the pouch battery cell accommodating part seating groove formed in the base jig <NUM> and the bending jig <NUM>, respectively. The bending guide opening part OP guides the bending side 2BS of the pouch <NUM> to be pushed out when the stopping means <NUM> pushes the pouch <NUM> from the outside, and may be referred to as a guide hole for preventing the bending side 2BS of the pouch <NUM> from being pushed concavely into the pouch <NUM>.

The stopping means <NUM> supports at least one side of the pouch <NUM> formed when the pouch sheet 2A is folded by the bending jig <NUM> so as to prevent the bending side 2BS of the pouch <NUM> from being pushed into the pouch <NUM>. The stopping means <NUM> is formed of a pad provided on the inner surface of the bending jig <NUM>. The stopping means <NUM> is formed of an elastic material such as a foamed urethane pad.

The stopping means <NUM> is configured in the shape of a square pad. The width between the left and right side ends of the stopping means <NUM> is equal to or slightly smaller than the width between the left and right side ends of the bending guide opening part OP.

A half-fold pouch battery cell accommodating part seating groove is provided inside the bending jig <NUM>, and a pad-shaped stopping means <NUM> is provided at the inner bottom part of the half-fold pouch battery cell accommodating part seating groove.

The base jig <NUM> is also provided with a half-fold pouch battery cell accommodating part seating groove therein.

When the bending jig <NUM> is folded toward the base jig <NUM> based on the hinge part of one side, the half-fold pouch battery cell accommodating part seating groove inside the bending jig <NUM> and the half-fold pouch battery cell accommodating part seating groove inside the base jig <NUM> face each other, and the pad-shaped stopping means <NUM> is disposed on the inner inner surface of the half-fold pouch battery cell accommodating part seating groove of the bending jig <NUM>, and in a state where the bending jig <NUM> is folded toward the base jig <NUM>, the stopping means <NUM> is disposed at a position facing the internal inner surface of the half-fold pouch battery cell accommodating part seating groove of the base jig <NUM>.

In addition, the present disclosure provide a pouch bending method for a secondary battery packaging system using a stopping means including a pouch bending operation for folding a pouch sheet 2A while a bending jig <NUM> is folded toward a base jig <NUM> in a state where the pouch sheet 2A is disposed on the base jig <NUM> and the bending jig <NUM>, and a pouch support operation for preventing a bending side 2BS of a pouch <NUM> formed during the bending operation of the pouch sheet 2A from being pushed into the pouch <NUM>, by a stopping means pushing at least one side of the pouch <NUM> from outside when the pouch sheet 2A is folded by the bending jig <NUM>, the stopping means being formed of a pad provided on an inner surface of the bending jig <NUM>.

According to the present disclosure having the above configuration, at least the bending jig <NUM> is provided with the stopping means <NUM>, and when the pouch sheet 2A is folded by the bending jig <NUM>, by supporting at least one side of the pouch <NUM> from the outside by the stopping means <NUM>, the bending side 2BS of the pouch <NUM> is prevented from being pushed into the inside of the pouch <NUM>.

Here, the stopping means <NUM> is formed of a pad of elasticity having a certain area, and the physical properties of the stopping means <NUM> are configured to have elasticity to the extent that it is not deformed when the pouch <NUM> is bent and can be contracted when the jelly roll is put into the pouch <NUM>.

In the present disclosure, the function of the stopping means <NUM> is to prevent the pouch <NUM> from being pushed into the inside of the bending side 2BS by pressing the pouch <NUM> when only the pouch <NUM> is bent.

However, in a state where the battery cell (jelly roll) is put into the pouch <NUM>, the pouch <NUM> and the battery cell are subjected to force in the thickness direction by the stopping means <NUM>, so that the pouch <NUM> is crushed or marks are formed.

Therefore, in the case of bending only the pouch <NUM> in order to properly stop, the stopping means <NUM> protrudes from the inner surfaces of the base jig <NUM> and the bending jig <NUM>, and when the battery cell is put into the pouch <NUM>, the stopping means <NUM> has a function of retracting inward. In the present disclosure, when the pouch <NUM> is bent when the battery cells are put into the pouch <NUM>, a spring SP or a cylinder <NUM> is employed to prevent the pouch <NUM> from press marks or being crushed. This will be described later.

The base jig <NUM> and the bending jig <NUM> are unfolded based on the hinge part connected to each other, an on the inner surface of the base jig <NUM> and the bending jig <NUM>, the pouch sheet 2A is unfolded, and each half-fold battery cell accommodating part of the pouch sheet 2A is seated in the half-fold pouch battery cell accommodating part seating groove inside the bending jig <NUM> and at the same time the stopping means <NUM> is interposed between the outer surface of the half-fold battery cell accommodating part of the pouch sheet 2A and the internal inner surface of the half-fold pouch battery cell accommodating seating groove inside the bending jig <NUM>, and at the same time, the remaining half-fold battery cell accommodating part of the pouch sheet 2A is seated in the half-fold pouch battery cell accommodating part seating groove inside the base jig <NUM>, and in this state, when the bending jig <NUM> is folded toward the base jig <NUM> based on the hinge part, the pouch sheet 2A is also folded in half from the unfolded state. This is the pouch bending operation.

In a state in which the bending jig <NUM> and the half-fold pouch sheet 2A are folded toward the base jig <NUM> and the other half-fold pouch sheet 2A, the stopping means <NUM> provided in the bending jig <NUM> is supporting the half-fold battery cell accommodating part of the pouch <NUM> from the outside, and at the same time, the internal inner surface of the half-fold pouch battery cell accommodating part seating groove of the base jig <NUM> supports the other half pouch battery cell accommodation part of the pouch <NUM> from the outside.

Accordingly, since the stopping means <NUM> supports at least one side of the pouch <NUM> (i.e., at least one side among both sides of the battery cell accommodating part of the pouch <NUM>) from the outside, the bending side 2BS of the pouch <NUM> is not pushed inward. Here, the bending guide opening part OP communicating with the inner and outer surfaces are formed on one side walls of the base jig <NUM> and the bending jig <NUM>, and since the stopping means <NUM> supports at least one side of the pouch <NUM> (i.e., at least one side among both sides of the battery cell accommodating part of the pouch <NUM>), a case in which the bending side 2BS of the pouch <NUM> is pushed inward can be prevented while a force to unfold outwardly of the pouch <NUM> acts through the bending guide opening part OP. In other words, since the stopping means <NUM> supports at least one side of the pouch <NUM> from the outside, the pouch <NUM> is formed in a state where the bending side 2BS of the pouch <NUM> is not pushed inward. The bending jig <NUM> and the half-fold pouch sheet 2A are completely folded toward the base jig <NUM> and the other half-fold pouch sheet 2A, so that the pouch <NUM> in which the two half-fold pouch sheets 2A are overlapped can be formed.

Therefore, the present disclosure prevents the case where the middle portion of the pouch sheet 2A is pushed inward during the bending operation of folding the middle portion of the pouch sheet 2A so as to solve the problem that the bending side 2BS of the pouch <NUM> is deformed concavely inward. In other words, it solves a problem such as when the pouch sheet 2A is folded, the bending side surface 2BS of the pouch <NUM> goes inside and is concavely crushed.

Conventionally, in the case of a battery without a bottom, when the pouch <NUM> is bent, the pouch <NUM> enters the main room, resulting in a smaller size of the main room.

However, in the present disclosure, the pouch <NUM> is folded in half with the pouch sheet 2A in a state (in the present invention, a state where two stopping means <NUM> support both sides of the pouch <NUM>) where at least one side of the pouch <NUM> is supported by the stopping means <NUM> with an adequate elastic force (adequate elastic force of the spring <NUM>) to prevent the pouch <NUM> from entering the main room. The fact that the pouch <NUM> enters the main room means that when the pouch sheet 2A is folded to form the pouch <NUM>, the bending side 2BS of one side of the pouch <NUM> is pushed into the interior of the pouch <NUM>, and the present disclosure solves the problem that the main room size of the pouch <NUM> becomes smaller by preventing the pouch <NUM> from entering the main room during bending of the pouch <NUM> as described above.

Since the bending side 2BS of the pouch <NUM> is not pushed in, the external quality of the pouch <NUM> is improved and the reliability of the pouch <NUM> is improved.

In addition, when the bending side 2BS of the pouch <NUM> with built in battery cells is deformed to be concave inward, the problem that the heat generated during the charging/discharging operation of the secondary battery is not properly discharged is also solved. A plurality of pouches <NUM> with built in battery cells (hereinafter, referred to as pouch <NUM> for convenience) are placed side by side on a hanger frame and mounted, and the bending side 2BS of the pouch <NUM> is in contact with the heat sink provided at the bottom of the hanger frame, and the heat generated in the pouch <NUM> during the battery cell charging/discharging operation is conducted from the bending side 2BS to the heat sink, and discharged, wherein the bending side 2BS of the pouch <NUM> does not have a concave deformed part that is concave inward, so it is not that the concave deformed part of the pouch <NUM> does not properly contact the heat sink, but rather because the bending side 2BS of the pouch <NUM> protrudes more or is formed flat at least from the side of the pouch <NUM>, the bending side 2BS of the pouch <NUM> is firmly in contact with the heat sink, resulting in the effect of properly dissipating the heat generated inside the pouch <NUM> during the battery cell charging/discharging operation by properly transferring the heat generated in the pouch <NUM> from the bending side 2BS to the heat sink during the battery cell charging/discharging operation.

In addition, as heat is properly dissipated from the pouch <NUM>, there is an effect of solving the problem that the battery cells are deteriorated or burned out due to heat.

Meanwhile, <FIG> and <FIG> show another embodiment of the present disclosure. In another embodiment of the present disclosure illustrated in <FIG> and <FIG>, the stopping means <NUM> is also provided inside the base jig <NUM> to which the bending jig <NUM> is connected via a hinge part. A pad-shaped stopping means <NUM> is also provided on the internal inner surface of the pouch battery cell accommodating part seating groove inside the base jig <NUM>. In a state in which the bending jig <NUM> is folded toward the base jig <NUM> based on the hinge part, two pad-shaped stopping means <NUM> are disposed at positions facing each other.

According to another embodiment of the present disclosure, both the bending jig <NUM> and the base jig <NUM> are provided with the stopping means <NUM>, and by supporting both sides of the pouch <NUM> from the outside by the two stopping means <NUM> when the pouch sheet 2A is folded by the bending jig <NUM>, the bending side 2BS of the pouch <NUM> is prevented from being pushed into the inside of the pouch <NUM>.

When the bending jig <NUM> is folded toward the base jig <NUM> based on the hinge part, the pouch sheet 2A is also folded in half from the unfolded state, and the stopping means <NUM> provided in the bending jig <NUM> is supporting the half-fold battery cell accommodating part of the pouch <NUM> from the outside in a state where the bending jig <NUM> and the half-fold pouch sheet 2A are folded toward the base jig <NUM> and the other half-fold pouch sheet 2A, and at the same time, the other stopping means <NUM> provided on the internal inner surface of the seating groove of the half-fold pouch battery cell accommodating part of the base jig <NUM> also supports the other half-fold pouch battery cell accommodating part of the pouch <NUM> from the outside.

Therefore, since the stopping means <NUM> supports both sides of the pouch <NUM> (i.e., both sides of the battery cell accommodating part of the pouch <NUM>) from the outside, the bending side 2BS of the pouch <NUM> is not pushed inward. Here, the bending guide opening part OP communicating with the inner and outer surfaces are formed on one side walls of the base jig <NUM> and the bending jig <NUM>, and since the stopping means <NUM> supports both sides of the pouch <NUM> (i.e., both sides of the battery cell accommodating part of the pouch <NUM>), a case in which the bending side 2BS of the pouch <NUM> is pushed inward can be prevented while a force to unfold outwardly of the pouch <NUM> acts through the bending guide opening part OP. In other words, since the stopping means <NUM> supports both sides of the pouch <NUM> from the outside, the pouch <NUM> is formed in a state where the bending side 2BS of the pouch <NUM> is not pushed inward.

Since the effects of other embodiments of the present disclosure are the same as the effects of the above-described embodiments of the present disclosure, redundant descriptions thereof will be omitted. However, in another embodiment of the present disclosure, since the two stopping means <NUM> support both sides of the pouch <NUM> from the outside, there is an effect of more reliably preventing the case where the bending side of the pouch <NUM> is pushed into the inner surface of the pouch <NUM>.

In the above embodiment, only the pouch <NUM> is bent in a state where the battery cell (jelly roll) is not put into the pouch <NUM>, when only the pouch <NUM> is bent, the stopping means <NUM> presses the pouch <NUM> to prevent it from being pushed into the inside of the bending side 2BS of the pouch <NUM>. Refer to <FIG>.

On the other hand, in the present disclosure, when the battery cells are put into the pouch <NUM>, the stopping means <NUM> is configured to have a function of retracting inward. In the present disclosure, a spring SP or a cylinder <NUM> is employed so that the stopping means <NUM> has a function of retracting inward.

<FIG> and <FIG> illustrate an embodiment in which a spring SP is employed to prevent the pouch <NUM> from press marks or the pouch from being crushed when the pouch <NUM> is bent in a state where the battery cell (jelly roll) is put in the pouch <NUM> in the present disclosure.

According to the present disclosure illustrated in <FIG> and <FIG>, the stopping means <NUM> is slidably embedded in the push operation hole formed in the bending jig <NUM>, and a spring SP is interposed between the push operation hole and the stopping means <NUM>, and it is configured such that the stopping means <NUM> can be retracted inward from the pouch <NUM> while the spring SP is supporting the stopping means <NUM>.

When forming the pouch <NUM> by folding the bending jig <NUM> toward the base jig <NUM> in a state where the battery cell is built in the pouch <NUM>, as the stopping means <NUM> is pushed into the inside of the bending jig <NUM> and the base jig <NUM> from the pouch <NUM>, the spring SP is pressed, and since the force pressing in the thickness direction of the pouch <NUM> does not act and a pair of stopping means <NUM> support both sides of the pouch <NUM> from the outside, in the process of bending the pouch <NUM>, the bending side 2BS is prevented from being pushed into the inside of the pouch <NUM>, and at the same time, the pouch <NUM> is prevented from press marks or the pouch <NUM> is prevented from being crushed.

In other words, in the embodiment employing the spring SP in the present disclosure, when the pouch <NUM> is bent in the state where the battery cell (jelly roll) is put in the pouch <NUM>, the stopping means <NUM> is pushed in from the pouch <NUM> so as to prevent the bending side 2BS of the pouch <NUM> from being pushed into the inside of the pouch <NUM> as well as to prevent the pouch <NUM> from press marks or the pouch <NUM> being crushed. In other words, the embodiment of the present disclosure illustrated in <FIG> and <FIG> employs a spring SP so that proper stopping occurs when the pouch <NUM> is bent in a state where the battery cells are put into the pouch <NUM>.

In addition, <FIG> illustrate an embodiment in which the cylinder <NUM> is employed to prevent the pouch <NUM> from press marks or the pouch <NUM> from being crushed when the pouch <NUM> is bent in a state where a battery cell (jelly roll) is put into the pouch <NUM> in the present disclosure.

In the present invention illustrated in <FIG>, at least the bending jig <NUM> between the base jig <NUM> and the bending jig <NUM> is provided with the stopping means <NUM>, and the stopping means <NUM> supports at least one side of the pouch <NUM> from the outside, and the stopping means <NUM> is configured to be connected to the cylinder rod of the cylinder <NUM>. In the present disclosure, two pad-shaped stopping means <NUM> are disposed on the internal inner surface of the half-fold pouch battery cell accommodating part seating groove inside the base jig <NUM> and the bending jig <NUM>, and the two stopping means <NUM> are configured to be connected to the cylinder rods of the two cylinders <NUM>.

Among the base jig <NUM> and the bending jig <NUM>, at least the bending jig <NUM> is provided with the cylinder <NUM>. The cylinder <NUM> is mounted on the outer surface of the bending jig <NUM>. The inside of the bending jig <NUM> is provided with a push operation hole. The push operation hole may be configured to communicate from the inner surface to the outer surface of the bending jig <NUM>. The push operation hole may be configured in a cross-sectional rectangular hole shape. In the present disclosure, a cylinder <NUM> is provided in each of the base jig <NUM> and the bending jig <NUM>, and a push operation hole is provided in the base jig <NUM> and the bending jig <NUM>. The push operation hole on the base jig <NUM> side communicates with the inner surface from the inside of the base jig <NUM>, and the push operation hole on the bending jig <NUM> side communicates with the inner surface from the inside of the bending jig <NUM>.

The stopping means <NUM> is coupled to the push operation hole of the base jig <NUM> and the bending jig <NUM> so as to move forward and backward. The stopping means <NUM> are configured to move forward toward the inner surface of the base jig <NUM> and the inner surface of the bending jig <NUM> in each push operation hole. The stopping means <NUM> is formed in a plate shape. When the push operation hole has a cross-sectional square hole shape, the stopping means <NUM> is configured in a square plate shape.

A guide bar <NUM> is built in the push operation hole. A plurality of guide bars <NUM> are disposed in the push operation hole.

A push operation plate <NUM> is connected to the cylinder rod provided in the cylinder <NUM> on the base jig <NUM> side and the cylinder rod provided in the cylinder <NUM> on the bending jig <NUM> side, respectively, and the push operation plate <NUM> is slidably coupled to the guide bar <NUM>. The push operation plate <NUM> is disposed at a position facing the stopping means <NUM>.

The cylinder rods of the cylinders <NUM> provided in the base jig <NUM> and the bending jig <NUM> are connected to the push operation plate <NUM>.

The stopping means <NUM> is connected to the push operation plate <NUM>. The stopping means <NUM> is connected to the push operation plate <NUM> via a connecting means such as a connecting bar (not shown).

A spring <NUM> is interposed between the push operation plate <NUM> and the stopping means <NUM>. The spring <NUM> is interposed between the push operation plate <NUM> and the stopping means <NUM> in a state of being coupled to the outer circumferential surface of the guide bar <NUM>. A spring <NUM> is interposed between the bottom surface of the push operation plate <NUM> and the top surface of the stopping means <NUM>. When the cylinder rod of the cylinder <NUM> moves forward, the push operation plate <NUM> and the stopping means <NUM> move forward, and when the cylinder rod of the cylinder <NUM> moves backward, the push operation plate <NUM> and the stopping means <NUM> moves backward. In a state in which the push operation plate <NUM> and the stopping means <NUM> are moved forward, the spring <NUM> is compressed to retain elastic restoring force, and in a state where the push operation plate <NUM> and the stopping means <NUM> are moved backward, the spring <NUM> is unfolded.

According to another embodiment of the present disclosure illustrated in <FIG>, at least the bending jig <NUM> is provided with the stopping means <NUM>, and when the pouch sheet 2A is folded by the bending jig <NUM>, by supporting at least one side of the pouch <NUM> from the outside by the stopping means <NUM>, the bending side 2BS of the pouch <NUM> is prevented from being pushed into the inside of the pouch <NUM>. In the present disclosure, each of the base jig <NUM> and the bending jig <NUM> is provided with the stopping means <NUM>, and the two stopping means <NUM> are configured to support both sides of the pouch <NUM> from the outside.

Specifically, the base jig <NUM> and the bending jig <NUM> are unfolded based on the hinge part connected to each other, and on the inner surface of the base jig <NUM> and the bending jig <NUM>, the pouch sheet 2A is unfolded, and in such a state, when the bending jig <NUM> is folded toward the base jig <NUM> based on the hinge part, the pouch sheet 2A is also folded in half from the unfolded state.

In a state in which the bending jig <NUM> and the half-fold pouch sheet 2A are folded toward the base jig <NUM> and the other half-fold pouch sheet 2A, the cylinder rods of the cylinder <NUM> provided in the base jig <NUM> and the bending jig <NUM> move forward and the push operation plate <NUM> and the stopping means <NUM> move forward, so that the two stopping means <NUM> support both sides of the pouch <NUM> from the outside. Here, the spring <NUM> is compressed to have an elastic restoring force.

Then, since the stopping means <NUM> support both sides of the pouch <NUM> from the outside, the bending side 2BS of the pouch <NUM> is not pushed inward. Here, a bending guide opening part OP communicating with the inner and outer surfaces is formed on one side walls of the base jig <NUM> and the bending jig <NUM>, and since the stopping means <NUM> support both sides of the pouch <NUM>, a case in which the bending side 2BS of the pouch <NUM> is pushed inward can be prevented while a force to unfold outwardly of the pouch <NUM> acts through the bending guide opening part OP. Since the stopping means <NUM> supports both sides of the pouch <NUM> from the outside, the pouch <NUM> is formed in a state where the bending side 2BS of the pouch <NUM> is not pushed inward. The bending jig <NUM> and the half-fold pouch sheet 2A are completely folded toward the base jig <NUM> and the other half-fold pouch sheet 2A, so that the pouch <NUM> in which the two half-fold pouch sheets 2A are overlapped can be formed.

On the other hand, while the spring <NUM> is compressed to retain elastic restoring force, the elastic restoring force of the spring <NUM> is such that the force of the stopping means <NUM> pressing the pouch <NUM> inward is not applied and in a state where the stopping means <NUM> elastically holds the elastic restoring force enough to support both sides of the pouch <NUM> from the outside, when the stopping means <NUM> presses both sides of the pouch <NUM> with excessive force, it is possible to prevent the pouch <NUM> from being press marks or the pouch <NUM> from being crushed.

As illustrated in <FIG>, even in the present disclosure employing the cylinder <NUM>, since the stopping means <NUM> is pushed inward from the pouch <NUM> and the force pressed by the stopping means <NUM> in the thickness direction of the pouch <NUM> does not act in the state in which the battery cell (jelly roll) is put in the pouch <NUM>, the pouch <NUM> is prevented from press marks or being crushed. The embodiment of the present disclosure illustrated in <FIG> also employs a cylinder <NUM> to properly stop the pouch <NUM> when bending the pouch <NUM> in a state where the battery cells are put into.

On the other hand, since the force of supporting the pouch <NUM> from the outside by stopping means <NUM> can be adjusted by adjusting the force of the cylinder rod of the cylinder <NUM> to move forward, there is an effect of more reliably preventing the pouch <NUM> from getting press marks by the stopping means or the pouch <NUM> from being crushed, and there is an effect that the clearance of the stopping means <NUM> can be easily and quickly adjusted by the cylinder <NUM> in response to the thickness of the pouch <NUM>. By adjusting the clearance of the stopping means <NUM> corresponding to the thickness of the pouch <NUM>, there is an effect that it can be used interchangeably even if the thickness of the pouch <NUM> is different.

Claim 1:
A pouch bending guide apparatus of a secondary battery packaging system using a stopping means (<NUM>), which folds a pouch sheet (2A) while a bending jig (<NUM>) is folded toward a base jig (<NUM>) in a state where the pouch sheet (2A) is disposed on the base jig (<NUM>) and the bending jig (<NUM>), the pouch bending guide apparatus comprising:
a stopping means (<NUM>) for preventing a bending side (2BS) of a pouch (<NUM>) from being pushed into the pouch (<NUM>) by supporting at least one side of the pouch (<NUM>) formed when the pouch sheet (2A) is folded by the bending jig (<NUM>),
characterized in that the stopping means (<NUM>) is formed of a pad provided on an inner surface of the bending jig (<NUM>).