KR20210120294A - Pressure Activation Device - Google Patents

Abstract

The present invention relates to a pressing activation device and, more specifically, to a pressing activation device, in which an electrode lead gripper is installed to move in the longitudinal direction of a pressing plate to perform a pressing activation process including charging/discharging and voltage measurement for pouch-type battery cells of various sizes through the same pressing activation device, thereby reducing time, effort, and cost required for a pressing activation process for the pouch-type battery cells of various sizes. According to the present invention, the pressing activation device comprises: a main body on which a large number of pouch-type battery cells are mounted; a pressing jig interposed between interfaces of the pouch-type battery cells; a pressing jig driving means moving the pressing jig to press the pouch-type battery cell; and an electrode lead gripper mounted on at least one of both sides of the pressing plate forming the pressing jig to elastically grip an electrode lead of the pouch-type battery cell through a pressing process, wherein the electrode lead gripper is mounted to move in the longitudinal direction of the pressing plate.

Description

Pressure Activation Device

The present invention relates to a pressure activation device, and in particular, by mounting an electrode lead gripper to be movable in the longitudinal direction of a pressure plate, the same pressure activation device for charging/discharging and voltage measurement for pouch-type battery cells of various sizes through the same pressure activation device. It relates to a pressurization activation device that enables the activation process to be performed, thereby reducing the time, effort, and cost required for the pressure activation process for pouch-type battery cells of various sizes.

Recently, with the rapid development of electricity, electronics, communication and computer industries, the demand for high-performance and high-safety batteries is gradually increasing. The demand for thinning is increasing day by day. In response to these demands, lithium secondary batteries with high energy density are receiving the most attention recently.

Lithium secondary batteries have the advantages of long lifespan and large capacity, and are widely used in portable electronic devices in recent years. and lithium polymer batteries using batteries. In addition, the lithium secondary battery is classified into a prismatic battery in which a prismatic can is used, a cylindrical battery in which a cylindrical can is used, and a pouch-type battery in which a pouch is used according to the type of the exterior material for sealing the electrode assembly.

Among them, the pouch-type battery has many advantages such as higher energy density per unit weight and volume, thinner and lighter battery, and lower material cost as an exterior material.

In the method of manufacturing such a pouch-type battery, first, a positive electrode plate and a negative electrode plate are prepared, a separator is interposed therebetween, and then laminated to prepare an electrode assembly. The electrode assembly manufactured as described above is embedded in a pouch case, an electrode lead is electrically connected to the electrode assembly, and the electrode lead is formed to protrude outside the pouch case. After the electrode assembly is embedded in the pouch case, the electrolyte is injected into the pouch so that the electrode assembly is impregnated with the electrolyte. When the electrolyte is injected as described above, the edges of the pouch are joined by thermal fusion to seal the pouch.

The pouch-type battery assembled as described above has a pressurization activation process (pre-formation process) in which the pouch is activated by pressing in order to evenly spread the electrolyte filled inside the pouch, and aging (pre-formation process) to stabilize the battery. Aging) process and a charging/discharging process (formation process) for activating the battery are performed.

In the case of the pouch-type battery cell, when the electrolyte is filled inside the pouch case, that is, when the electrolyte is filled in the pouch case when the electrolyte is impregnated, the pouch case may be convex. The capacity of the pouch-type battery cell can be increased only when the electrolyte is evenly distributed inside the pouch case, so a process of pressurizing the pouch case to a constant temperature is required so that the electrolyte filled inside the pouch case is evenly spread. A pressure activation device for activating by pressing is used.

A conventional general pressurization activation device performs only a pressurization process on the pouch-type battery cell, and then, charges/discharges and voltage measurement on the pouch-type battery cells are performed through a separate additional process, resulting in a problem of poor process efficiency. do.

In order to solve this problem, Korean Patent Application Laid-Open No. 10-2017-0068145 (hereinafter referred to as "prior art literature") can increase the electrolyte impregnation efficiency inside battery cells, and charge/discharge and voltage when the battery cells are pressurized. A pressure tray capable of simultaneously performing measurements is disclosed.

However, the prior art document only discloses that the pressurizing unit has a contact terminal part capable of contacting the electrode lead of each battery cell when the respective battery cells are pressurized using the pressurizing unit, and the size of the battery cell is changed. However, it does not provide a specific method for performing the pressurization activation process through the same pressurization tray.

Republic of Korea Patent Publication No. 10-2017-0068145 (published date: June 19, 2017, title of invention: pressure tray)

The present invention has been devised to solve the problems of the prior art as described above, and by mounting the electrode lead gripper to be movable in the longitudinal direction of the pressure plate, it is possible to charge the pouch-type battery cells of various sizes through the same pressure activation device. To provide a pressurization activation device that enables the pressurization activation process including discharge and voltage measurement to be performed, thereby reducing the time, effort, and cost required for the pressure activation process for pouch-type battery cells of various sizes to do that for that purpose.

The constituent means constituting the pressurization activation device of the present invention proposed to solve the above problems is a body in which a plurality of pouch-type battery cells are mounted and pressurized interposed at the interface of each pouch-type battery cell in the pressure activation apparatus. A jig, a pressurizing jig driving means for moving the pressurizing jig to pressurize the pouch-type battery cell, is mounted on at least one side of both sides of the pressurizing plate constituting the pressurizing jig, and an electrode lead gripper for elastically gripping the electrode lead of

Here, gripper guide rails are installed in the front and rear directions of the main body, and the electrode lead gripper includes a gripper guide that can be slidably guided by the gripper guide rail.

Here, the gripper position adjusting means for moving the gripper guide rail in the longitudinal direction of the pressure plate in a horizontal state is further included.

Here, the gripper position adjusting means includes a rotating screw rotatably mounted to a fixed body fixed to the main body and the rotating screw through-coupled to move in the longitudinal direction of the pressing plate according to the rotation of the rotating screw. , characterized in that it is configured to include a movable body coupled to the gripper guide rail.

According to the present invention pressurization activation device having the above problems and solutions, since the electrode lead gripper is mounted so as to be movable in the longitudinal direction of the pressure plate, it is possible to charge pouch-type battery cells of various sizes through the same pressure activation device. It enables the pressurization activation process including discharge and voltage measurement to be performed, thereby reducing the time, effort, and cost required for the pressurization activation process for pouch-type battery cells of various sizes.

1 is a plan view of a pressure activation device according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along line A - A' of FIG. 1 .
FIG. 3 is a cross-sectional view taken along line B - B' of FIG. 1 .
FIG. 4 is an enlarged view of FIG. 3 .
5 is a perspective view of a pressure jig constituting a pressure activation device according to an embodiment of the present invention.
6 is a perspective view of an electrode lead gripper constituting a pressure activation device according to an embodiment of the present invention as viewed from the rear side.
7 is a schematic diagram for explaining the position adjustment according to the pouch-type battery cell size of the electrode lead gripper constituting the pressurization activation device according to the embodiment of the present invention.
8 is a partially enlarged view of a pressure activation device according to an embodiment of the present invention.
9 is a perspective view for explaining the coupling configuration of the gripper position adjusting means constituting the pressure activation device according to the embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the present invention, a pressurization activation device having the above problems, solutions and effects will be described in detail.

Since the present invention can apply various transformations and can have various embodiments, specific embodiments are illustrated in the drawings and described in detail in the detailed description. Effects and features of the present invention, and a method of achieving them, will become apparent with reference to the embodiments described below in detail in conjunction with the drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various forms.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, and when described with reference to the drawings, the same or corresponding components are given the same reference numerals, and the overlapping description thereof will be omitted. .

In the following embodiments, terms such as include or have means that the features or components described in the specification are present, and the possibility of adding one or more other features or components is not excluded in advance.

In the drawings, the size of the components may be exaggerated or reduced for convenience of description. For example, since the size and thickness of each component shown in the drawings are arbitrarily indicated for convenience of description, the present invention is not necessarily limited to the illustrated bar.

In cases where certain embodiments may be implemented differently, a specific order of operations may be performed differently from the described order. For example, two operations described in succession may be performed substantially simultaneously, or may be performed in an order opposite to the order described.

1 is a plan view of a pressurization activation device according to an embodiment of the present invention, FIG. 2 is a cross-sectional view taken along line A-A' of FIG. 1, FIG. 3 is a cross-sectional view taken along line B-B' of FIG. 1, and FIG. 4 is an enlarged view of FIG. It is also

1 to 4, the pressure activation device 100 according to an embodiment of the present invention includes a main body 70 in which a plurality of pouch-type battery cells 1 are mounted, each pouch-type battery cell ( 1) a pressure jig 60 interposed in the interface, a pressure jig driving means 80 for moving the pressure jig 60 to pressurize the pouch-type battery cell 1 , and a pressure constituting the pressure jig 60 and an electrode lead gripper 50 mounted on at least one side of both sides of the plate and elastically gripping the electrode lead 5 of the pouch-type battery cell 1 through a pressing process.

The main body 70 forms the exterior of the pressure activation device 100 according to the present invention, and has a structure capable of accommodating the plurality of pouch-type battery cells 1 . The main body 70 may basically include a lower frame, an upper frame, and a pair of connecting frames disposed on both sides to connect the lower and upper frames to form a solid shape.

The pressing jig 60 is provided in the main body 70 so as to be configured in plurality and disposed between the plurality of pouch-type battery cells 1 to face the front and rear surfaces of the plurality of pouch-type battery cells 1 . can be Here, the electrode leads 5 of the plurality of pouch-type battery cells 1 are perpendicular to the front-rear direction of the main body 70 (the pressing direction of the pressing jig 60, the left-right direction in FIGS. 1 to 4). It may be disposed along the lateral direction of the plurality of pressing jigs (60). That is, as shown in FIG. 5 , the electrode leads 5 of the plurality of pouch-type battery cells 1 applied to the present invention are in the lateral direction (with respect to the pressing direction) between the plurality of pressing jigs 60 . It may be arranged to protrude along a vertical lateral direction).

The pressing jig driving means 80 drives the plurality of pressing jigs 60 so that the plurality of pressing jigs 60 can press the front and rear surfaces of the plurality of pouch-type battery cells 1 in the surface direction. It can slide along the front-back direction (pressure direction) of the main body 70 .

To this end, the pressing jig driving means 80 may include a driving source 81 , a driving plate 83 , a driving shaft 85 , and a jig guide rail 87 . The driving plate 83 may be provided in the main body 70 to face the pressing jig 60 disposed at the outermost side at one side of the plurality of pressing jigs 60 .

The driving shaft 85 is connected to the driving plate 83 , and the driving source 81 is configured to slide the plurality of pressing jigs 60 in the front-rear direction (pressing direction) of the main body 70 . According to the driving, the driving plate 83 may be slid along the front-rear direction (pressure direction) of the main body 70 .

The jig guide rail 87 may be fixedly disposed between a pair of connection frames of the main body 70 along the front-rear direction (pressing direction) of the main body 70 . The jig guide rail 87 may be connected to penetrate through the plurality of pressing jigs 60 and the driving plate 83 to guide sliding of the plurality of pressing jigs 60 and the driving plate 83 . have. As will be described later, in order to be slidingly guided by the jig guide rail 87 , the pressure jig 60 includes a jig guide 63 as shown in FIG. 5 .

Meanwhile, although not shown in FIGS. 1 to 4 , a gripper guide rail (indicated by reference numeral 98 in FIGS. 7 to 9 ) may be installed on the main body 70 separately from the jig guide rail 87 . That is, the gripper guide rail 98 may be additionally installed in the pressure activation device 100 according to the present invention. Specifically, as shown in FIG. 8 , the gripper guide rail 98 is the jig guide rail. Similarly to (87), it may be installed between a pair of connecting frames of the main body 70 along the front-rear direction (pressing direction) of the main body 70 .

The gripper guide rail 98 slides and guides a jig guide (indicated by reference numeral 43 in FIGS. 5 to 7 ) provided in the electrode lead gripper 50 in the pressing direction of the pressing jig 60 . According to the sliding movement, the electrode lead gripper 50 can also slide stably without being separated. However, the gripper guide rail 98 employed in the present invention is not fixedly installed unlike the jig guide rail 87, but rather in the lateral direction of the pressing jig 60 perpendicular to the pressing direction, that is, the pressing jig ( 60) may be installed to be movable in the longitudinal direction. This will be discussed later.

As shown in FIG. 5 , the electrode lead gripper 50 is mounted on at least one side of both sides of the pressing plate 61 constituting the pressing jig 60 , so that the pressing jig 60 is As it is pressed, it is moved by the pressing plate 61, and through this pressing process, the electrode lead 5 of the pouch-type battery cell 1 is elastically gripped so that the pouch-type battery cell 1 is charged and discharged. and make it possible to measure the voltage.

Looking at the operation of the pressure activation device 100 configured in this way, the pouch type battery cell 1 is inserted between the pressure jigs 60 arranged at regular intervals on the main body 70, and the inserted pouch type battery cell 1 is inserted. The battery cell 1 is supported by the intervening paper 71 interposed between the pressing jigs 60 .

In the state in which the pouch-type battery cell 1 is inserted as described above, the pressing jig 60 presses the pouch-type battery cell 1 by the pressing jig driving means 80, and then, the pressing jig ( 60) by operating a heating pad (indicated by reference numeral 62 in FIG. 5) to apply a high temperature while pressurizing the pouch-type battery cell 1, at this time, the electrode moved together with the pressing jig 60 The lead gripper 50 elastically faces the electrode lead 5 of the pouch-type battery cell 1 .

That is, when the pressure jig 60 moves to press the pouch-type battery cell 1 , the electrode lead gripper 50 for the pressure activation device installed in the pressure jig 60 is also moved and the pouch-type battery cell 1 is moved. It is elastically abutted with the electrode lead 5 of the battery cell 1 . As described above, since the electrode lead 5 of the pouch-type battery cell 1 can be elastically gripped through the pressing process, the pouch-type battery cell 1 can be charged and discharged and the voltage can also be measured. have.

However, if the electrode lead gripper 50 is fixed, the pressure activation process including charging/discharging and voltage measurement can be performed only for the pouch-type battery cell 1 of a specific size, and the pouch-type battery cell of a different size can be performed. Regarding (1), since the electrode lead gripper 50 cannot electrically contact the electrode lead 5 of the pouch-type battery cell 1 of the different size, a pressure activation process including charging and discharging can be performed. none.

In order to solve this problem, the electrode lead gripper 50 constituting the pressure activation device 100 according to the embodiment of the present invention is mounted movably in the longitudinal direction of the pressure plate 61 . As a result, it is possible to perform a pressure activation process including charging/discharging and voltage measurement for the pouch-type battery cells 1 of various sizes through the same pressure activation device 100 . Through this, it is possible to exhibit the advantage of reducing the time, effort, and cost required for the pressurization activation process for pouch-type battery cells of various sizes.

The electrode lead gripper 50 is movably mounted on the side of the pressing jig 60 and the pressing plate 61 of the pressing jig 60 constituting the pressing activating device 100 according to the embodiment of the present invention. Here is a more detailed explanation of

5 is a perspective view of the pressing jig 60 applied to the present invention, and FIG. 6 is a perspective view looking at the rear side of the electrode lead gripper 50 applied to the present invention.

The pressure jig 60 applied to the present invention is mounted on the pressure plate 61 and the pressure plate 61 for pressing the pouch-type battery cell 1, as shown in FIG. and an electrode lead gripper 50 for a pressure activation device that elastically clamps the electrode lead 5 of the pouch-type battery cell 1 pressed by the .

The pressurizing plate 61 performs an operation of pressurizing the pouch-type battery cell 1 subjected to the pressurization activation process, and also allows the pouch-type battery cell 1 to be subjected to the pressurization activation process at a constant temperature. To this end, a heating pad 62 is attached to one side of both sides of the pressure plate 61 .

In addition, the pressure jig 60 according to the present invention is provided with a jig guide 63 integrally or detachably coupled to both sides of the pressure plate 61 . As described above, the jig guide 63 is guided by the jig guide rail 87 while the pressing plate 61 is pressed and slid so that it can be moved stably. A jig guide hole 64 is formed in the jig guide 63 so that the jig guide rail 87 can be disposed therethrough.

On the other hand, it is preferable that the cell entry guide 65 is formed on the upper portion of the pressure plate 61 . The pouch-type battery cell 1 to be subjected to the pressure activation process through the pressure activation device 100 according to the present invention is drawn in from the upper side of the pressure plate 61 by pick and place. In this process, the cell entry guide 65 may guide the pouch-type battery cell 1 so that it can be stably entered between the pressing plates 61 to be mounted.

As shown in FIG. 5 , the electrode lead gripper 50 applied to the present invention is provided on the pressure jig 60 . Specifically, the electrode lead gripper 50 is movably mounted by being inserted into at least one side of both sides of the pressing plate 61 of the pressing jig 60 .

As shown in FIGS. 5 and 6, the electrode lead gripper 50 applied to the present invention includes a mounting frame 10 mounted on the pressing plate 61 for pressing the pouch-type battery cell 1; A support plate 20 for supporting the electrode lead 5 of the pouch-type battery cell 1 coupled to the other side of the mounting frame 10 and being pressed, and a pouch coupled to one side of the mounting frame 10 and pressed and an electrode terminal assembly 30 for charging and discharging the pouch type battery cell 10 by blotting the electrode lead 5 of the type battery cell 10 .

The mounting frame 10 may be configured in various forms as long as it can be mounted on the pressure plate 61 . However, in order to facilitate the mounting and disassembly of the pressure plate 61 and to be movable in the longitudinal direction of the mounting plate 51 at the same time, the mounting frame 10 is disposed in the lateral direction of the pressure plate 61 . It is preferable to have a shape that can be fitted in and moveable in the longitudinal direction of the pressing plate 61 in the fitted state.

To this end, the mounting frame 10 applied to the present invention may be configured to have a rectangular frame shape penetrating in one direction. Specifically, the mounting frame 10 includes a lower mounting block 11 constituting a lower side, an upper mounting block 13 constituting an upper side, and one side of the lower mounting block 11 and the upper mounting block 13 vertically One side mounting plate 15 for connecting in the direction and the other side of the lower mounting block 11 and the upper mounting block 13 are connected in a vertical direction, but the other side mounting plate 17 disposed opposite to the one side mounting plate 15 ) is included.

Since the mounting frame 10 configured as described above has a perforated rectangular frame shape, it can be movably mounted while being fitted in the pressure plate 61 by being fitted in the lateral direction of the pressure plate 61 . Since it has such a shape, there is an advantage in that it is not necessary to take a separate coupling structure for coupling the electrode lead gripper 50 according to the present invention to the pressure jig 60 .

In addition, since the electrode lead gripper 50 is preferably moved while being guided stably as the pressing plate 61 moves in the pressing direction, the electrode lead gripper 50 is installed in the front-rear direction (pressing direction) of the main body 70 . Preferably, a gripper guide 43 that can be slidably guided by a gripper guide rail 98 is added to the mounting frame 10 .

That is, the pressure activation device 100 according to the embodiment of the present invention includes a gripper guide rail 98 disposed and installed in the front and rear directions of the main body 70 , and the electrode lead gripper 50 is the gripper guide. A gripper guide 43 that can be slidably guided by a rail 98 is provided. Accordingly, the electrode lead gripper 50 moves in the pressing direction together with the movement of the pressing plate 61 , but can be stably moved while the gripper guide 43 is guided to the gripper guide rail 98 . .

Since the mounting frame 10 having the above structure is mounted while being fitted to the pressure plate 61, the one side mounting plate 15 faces the other adjacent pressure plate in one direction, and the other mounting plate 17 is It faces another adjacent pressure plate in the other direction.

A support plate 20 for supporting the electrode lead 5 of the pouch-type battery cell 1 to be pressed is coupled to the other side of the mounting frame 10 . That is, the support plate 20 is coupled to the other mounting plate 17 of the mounting frame 10 . However, in order to simplify the structure, in some cases, the other mounting plate 17 may serve as the support plate 20 .

The support plate 20 is elastically attached to the other mounting plate 17 of the mounting frame 10 so that the electrode lead 50 of the pressed pouch-type battery cell 1 can be elastically supported. It is preferable to combine with That is, the support plate 20 may be elastically coupled to the other mounting plate 17 with an elastic member (not shown) interposed therebetween. On the other hand, when the other mounting plate 17 is applied as the support plate 20 , the other mounting plate 17 is elastically elastic to the other side of the lower mounting block 11 and the upper mounting block 13 . It is preferable to combine.

On one side of the mounting frame 10, an electrode terminal assembly ( 30) is combined. That is, the electrode terminal assembly 30 is coupled and mounted to one side mounting plate 15 of the mounting frame 10 .

The electrode lead gripper 50 for the pressure activation device configured as described above does not clamp the electrode lead 5 of the pouch-type battery cell 1 that is pressed alone, but is applied to a pair of pressure plates 61 disposed adjacently. It is clamped by a pair of electrode lead grippers 50 respectively mounted.

Specifically, in a state in which the pouch-type battery cell 1 is pressed by a pair of adjacent pressure plates 61 , the electrode leads 5 of the pouch-type battery cell 1 are attached to the pressure plate 61 . A support coupled to the other side of the electrode terminal assembly 30 coupled to one side of the mounting frame 10 to be mounted and the other side of the mounting frame 10 mounted to the pressure plate 61 disposed adjacent to and facing the pressure plate 61 . It is elastically pressed between the plates 20 .

In a state in which the electrode lead 5 of the pouch-type battery cell 1 is elastically gripped by the adjacent electrode lead gripper 50, charging and discharging can be performed and the voltage can be measured. To this end, the electrode terminal assembly 50 must include a voltage electrode terminal and a current electrode terminal. The structure of the electrode terminal assembly 50 including the voltage electrode terminal and the current electrode terminal may be configured in various forms.

On the other hand, as shown in FIG. 7 , the electrode lead gripper 50 constituting the pressurization activation device 100 according to the embodiment of the present invention can respond to the pouch-type battery cells 1 of various sizes. To be movable in the longitudinal direction of the pressure plate 61, that is, in the lateral direction of the pressure plate 61 (arrangement direction of the electrode leads 5 of the pouch-type battery cell 1) in a state mounted on the pressure plate 61 It is preferable that the gripper guide rail 98 that is mounted and guides the gripper guide 63 in order to enable movement is driven to be horizontally movable in the lateral direction of the pressing plate 61 .

To this end, the pressure activating device 100 according to the embodiment of the present invention includes a gripper position adjusting means (FIG. 8) capable of moving the gripper guide rail 98 in the longitudinal direction of the pressure plate 61 in a horizontal state. and (indicated by reference numeral 90 in FIG. 9 ).

As a result, the electrode lead gripper 50 according to the present invention is mounted movably along the longitudinal direction (left and right direction (arrow direction) in FIG. 7) of the pressure plate 61 through the mounting frame 10, As the gripper guide rail 98 moves in the longitudinal direction of the pressure plate 61 in the horizontal direction by the gripper position adjusting means 90 , the position at which it is mounted on the pressure plate 61 may be adjusted. As a result, through the operation of the gripper position adjusting means 90 in one pressurization activation equipment, without the need for a pressure activation equipment corresponding to each size, the pressure on the pouch-type battery cells 1 of various sizes A great advantage arises from being able to carry out the activation process.

More specifically, as shown in FIG. 7 , a pouch-type battery cell mounted between the pressure plates 61 ( For 1), there may be a case where the pressurization activation process cannot be performed immediately. That is, as a result of mounting the small-sized pouch-type battery cell 1 , a state in which the electrode lead 5 of the pouch-type battery cell 1 cannot be gripped by the electrode lead gripper 50 may occur. For reference, in the pouch-type battery cell 1 applied to the present invention, the electrode assembly 2 is embedded in the pouch 3 , and a pair of electrode leads (positive electrode lead and negative electrode lead) protrudes one by one.

In the state of FIG. 7 , the electrode lead grippers 50 respectively mounted on both sides of the pressure plate 61 are horizontally moved inward, that is, in the direction in which the pouch-type battery cells 1 are mounted, and respectively adjacent pouch-type batteries. It is moved to a position where it can be gripped by the electrode lead 50 of the cell. To this end, the gripper position adjusting means 90 is operated to drive the gripper guide rail 98 inserted and mounted in the gripper guide 43 of the electrode lead gripper 50 to horizontally move inward. Movement of the gripper guide rail 98 in the horizontal direction (longitudinal direction of the pressure plate) may be enabled by the gripper position adjusting means 90 installed in the pressure activation device 100 .

To enable such an operation, the electrode lead gripper 50 applied to the present invention is not fixedly mounted on the pressing plate 61, but is movably mounted while being inserted into the pressing plate 61. It needs to be mounted so that it does not deviate from the pressure sliding process. That is, the above-described mounting frame 10 is mounted without being fixed while being inserted into the pressure plate 61 , and the gripper guide 43 is coupled to be slidably guided by the gripper guide rail 89 . do.

In this way, the mounting frame 10 is mounted to be movable along the longitudinal direction of the pressure plate 61, and the gripper guide rail 98 inserted into the gripper guide 43 is provided with the gripper position adjusting means ( 90), it is possible to adjust the mounting position of the electrode lead gripper 50 on the pressure plate 61 because it is configured to move horizontally along the longitudinal direction of the pressure plate 61, and through this, various sizes of the electrode lead gripper 50 can be adjusted. A pressure activation process including charging/discharging and voltage measurement may be performed on the pouch-type battery cell 1 .

The gripper position adjusting means 90 may be configured in various ways as long as it can stably move the gripper guide rail 98 in the horizontal direction in the longitudinal direction of the pressing plate 61 .

As shown in FIGS. 8 and 9 , the gripper position adjusting means 90 is mounted on the main body 70 to horizontally move the gripper guide rail 98 in the longitudinal direction of the pressing plate 61 . mounted so as to be arranged.

For this purpose, the gripper position adjusting means 90 includes a rotating screw 96 that is rotatably mounted to a fixed body 95 fixed to the main body 70 and the rotating screw 96 through-coupled to the rotating screw ( 96) is mounted to move in the longitudinal direction of the pressure plate 61 according to the rotation, and includes a movable body 97 coupled to the gripper guide rail 98, and additionally a handle 91, rotation It is preferable to further include a bar 92 , a first gear 93 , a second gear 94 and a guide bar 99 .

The handle 91 has a structure that can be turned clockwise or counterclockwise by an operator. The rotating bar 92 is connected to the handle 91 and mounted on the main body 70 so as to be rotated according to the manipulation of the handle 91 . It is preferable that the rotating bar 92 is rotatably mounted while passing through a pair of connecting frames constituting the main body 70 .

The first gear 93 is coupled to the rotation bar 92 . The first gear 93 is preferably a bevel gear. The first gear 93 is engaged with the second gear 94 . The second gear 94 is also preferably a bevel gear.

The fixing body 95 is fixedly mounted to the connection frame of the main body 70 so that the rotating screw 95 can be rotated in a stably mounted state. The fixing body 95 is composed of a pair of fixing bodies 95 spaced apart from each other and disposed to face each other, and each of both sides of the rotating screw 96 is rotatable while being penetrated by the corresponding fixing body 96 . it is installed

The second gear 94 is coupled to one side of the rotating screw 96 . Therefore, when the operator turns the handle 91, the rotary bar 92 is rotated, and the second gear 94 meshed with the first gear 93 according to the rotation of the rotary bar 92 is The first gear 93 rotates based on a rotation axis orthogonal to the rotation axis, and as a result, the rotation screw 96 rotates in a state in which it is mounted on the fixing body 95 so as to be orthogonal to the rotation bar 92 . can be

The movable body 97 is disposed such that the rotating screw 96 is coupled therethrough. Accordingly, the movable body 97 may be moved along the longitudinal direction of the pressing plate 61 according to the rotation of the rotating screw 96 . Since the gripper guide rail 98 is coupled to the movable body 97 , as the movable body 97 moves in the longitudinal direction of the pressing plate 61 , the gripper guide rail 98 is also the pressing plate 61 . ) and, as a result, the electrode lead gripper 50 having the gripper guide 43 mounted to fit the gripper guide rail 98 in the longitudinal direction of the pressing plate 61 . can be moved to

Guide the movement of the movable body 97 for stable movement of the movable body 97 in the process of moving the movable body 97 in the longitudinal direction of the pressing plate 61 according to the rotation of the rotating screw 96 It is preferable to further include a guide bar (99). Both sides of the guide bar 99 are fixedly coupled to the pair of fixed bodies 95 while passing through the movable body 97 .

The electrode lead gripper 50 needs to be moved more stably by the gripper position adjusting means 90 having the above-described configuration. To this end, the gripper position adjusting means 90 preferably has a structure capable of simultaneously moving the upper and lower sides of the electrode lead gripper 50 .

To this end, the electrode lead gripper 50 includes the gripper guide 43 on the upper and lower sides, respectively, and the gripper guide rail 98 fitted to the gripper guide 43 is also disposed on the upper and lower sides. It consists of a pair that becomes An end of the gripper guide rail 98 disposed on the upper side is coupled to an upper side of the movable body 97 , and an end of the gripper guide rail 98 disposed at the lower side is coupled to a lower side of the movable body 97 .

Accordingly, when the movable body 97 is operated to move horizontally in the longitudinal direction of the pressing plate 61 , the pair of gripper guide rails 98 are simultaneously horizontally moved in the longitudinal direction of the pressing plate 61 . and, as a result, the electrode lead gripper 50 can be moved horizontally in the longitudinal direction of the pressure plate 61 more stably.

Meanwhile, although FIG. 8 shows the gripper position adjusting means 90 disposed on one side of the connecting frame among the pair of connecting frames constituting the main body 70, the same and similar gripper position adjustment on the other connecting frame on the opposite side. Preferably means 90 are arranged. Specifically, on the other side of the connection frame side, the rotation bar 92 extended from the side of the one side connection frame, the first gear 93 coupled to the rotation bar 92, and the first gear 93 are engaged. The second gear 94, the fixing body 95 fixed to the other connecting frame, the rotating screw 96 rotatably mounted to the fixing body, and the pressing plate 61 according to the rotation of the rotating screw 96 A movable body 97 that moves in the longitudinal direction of the gripper guide rail 98 and is coupled to the other side opposite to the gripper guide rail 98 , and a guide bar 99 that guides the movement of the movable body 97 may also be disposed.

In summary, an interlocking gripper position adjusting means composed of components other than the handle 91 among the gripper position adjusting means 90 disposed on the one connecting frame side is disposed on the other connecting frame side, the one side It operates in conjunction with the operation of the gripper position adjusting means 90 disposed on the side of the connection frame.

Specifically, when the handle 91 of the gripper position adjusting means 90 disposed on the side of the one connection frame is turned, the rotation bar 92 is rotated, and the rotation bar 92 is connected to the other side of the connection frame on the one side. Since it extends to the frame, as a result, the rotation screw 96 disposed on one side of the connection frame and the rotation screw 96 disposed on the side of the other side of the connection frame interlock and rotate at the same time. Accordingly, since the pair of movable bodies 97 disposed on each of the one connection frame and the other connection frame move in association with each other, the gripper guide rail 98, which both sides are coupled to the pair of movable bodies one by one, stably and horizontally The pressure plate 61 may be moved in the longitudinal direction.

Although the above-described gripper position adjusting means 90 has been described as moving the electrode lead gripper 50 fitted by being fitted on one side of the pressure plate 61 , it is fitted and mounted on the other side of the pressure plate 61 . It goes without saying that it may be additionally configured to move the electrode lead gripper 50 to be used.

Meanwhile, as described above, the electrode lead gripper 50 applied to the present invention includes a gripper guide 43 that can be slidably guided by the gripper guide rail 98 . That is, the gripper guide 43 is provided on the upper and lower sides of the mounting frame 10 according to the present invention to be slidably guided by the gripper guide rail 98 , respectively.

The gripper guide rail 98 is installed in the front-rear direction (pressing direction) of the main body 70 in the same manner as the jig guide rail 87 installed on the main body 70 . The electrode lead gripper 50 is mounted while being inserted into the pressure plate 61 , and the gripper guide 43 is inserted into the gripper guide rail 98 to be guided therebetween.

Accordingly, when the pressing plates 61 are pressed in the pressing direction, the pressing plates 61 are moved by pressing the jig guide (indicated by reference numeral 63 in FIG. 5 ) is slidingly guided by the jig guide rail 87 . The electrode lead grippers 50 mounted on each of the pressing plates 61 also move in the pressing direction according to the pressing movement of the pressing plate 61 , but the gripper guide 43 is the gripper. It can be moved while slidingly guided by the guide rail 98 . Therefore, in the process of the pressing plate 61 being pressed and slid, it is possible to slide stably without departing from the current mounting position, thereby preventing contact failure and errors with the electrode lead 5 of the pouch-type battery cell 1 . can be prevented

The gripper guide 43 may be configured in various forms as long as it can be slidably guided by the gripper guide rail 98 . For example, as shown in FIG. 7 , the gripper guide 43 preferably includes a gripper guide hole 44 through which the gripper guide rail 98 can be disposed. Similarly, as shown in FIG. 7 , the jig guide 63 also preferably includes a jig guide hole 64 through which the jig guide rail 87 can be disposed. When the pressure plate 61 is pressed through such a structure, the pressure plate 61 may be stably slidably moved, and the electrode lead gripper 50 may also be slidably moved without being separated.

Although the embodiments according to the present invention have been described above, these are merely exemplary, and those of ordinary skill in the art will understand that various modifications and equivalent ranges of embodiments are possible therefrom. Accordingly, the true technical protection scope of the present invention should be defined by the following claims.

1: pouch-type battery cell 2: electrode assembly
3: pouch 4: pouch border
5: electrode lead 10: mounting frame
11: lower mounting block 13: upper mounting block
15: one side mounting plate 17: the other side mounting plate
20: support plate 30: electrode terminal assembly
43: gripper guide 44: gripper guide hole
50: electrode lead gripper 60: pressure jig
61: pressure plate 62: heating pad
63: jig guide 64: jig guide hole
65: cell entry guide 70: body
71: interleaving paper 80: pressure jig driving means
81: drive source 83: drive plate
85: drive shaft 87: jig guide rail
90: gripper position adjusting means 91: handle
92: rotation bar 93: first gear
94: second gear 95: fixed body
96: rotating screw 97: moving body
98: gripper guide rail 99: guide bar
100: pressurization activation device

Claims (4)

A pressurized activation device comprising:
a main body on which a plurality of pouch-type battery cells are mounted;
a pressure jig interposed between each pouch-type battery cell interface;
a pressurizing jig driving means for moving the pressurizing jig to pressurize the pouch-type battery cell;
Doedoe comprising an electrode lead gripper mounted on at least one side of both sides of the pressing plate constituting the pressing jig and elastically gripping the electrode lead of the pouch-type battery cell through a pressing process,
The electrode lead gripper is a pressure activation device, characterized in that mounted movably in the longitudinal direction of the pressure plate.
The method according to claim 1,
A gripper guide rail is installed in the front and rear direction of the main body,
and the electrode lead gripper includes a gripper guide that can be slidably guided by the gripper guide rail.
3. The method according to claim 2,
and a gripper position adjusting means capable of moving the gripper guide rail in the longitudinal direction of the pressure plate in a horizontal state.
4. The method according to claim 3,
The gripper position adjusting means includes a rotation screw rotatably mounted to a fixed body fixed to the main body and a rotation screw through which the rotation screw is coupled to move in the longitudinal direction of the pressing plate according to the rotation of the rotation screw, A pressure activation device comprising a movable body coupled to the gripper guide rail.

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