DE202022100053U1 - Press trough and activation device for activating battery cells - Google Patents

Abstract

Press trough characterized by:
a frame accommodating multiple battery cells;
a first main plate and a second main plate which are arranged on respective outermost sides of the battery cells and compress the battery cells accommodated in the frame; and
a drive axis that fixes the first main board and the second main board and moves them in a horizontal direction,
wherein the drive shaft has a structure in which a first screw unit is formed in a region where the first main plate is fixed and a second screw unit is formed in a region where the second main plate is fixed, and
wherein the first screw unit and the second screw unit have threads formed in directions opposite to each other, and the first main plate and the second main plate are moved toward or away from each other by rotation of the drive shaft.

Description

AREA OF EXPERTISE

The present application claims priority to the Korean patent application filed on Jan. 11, 2021 10-2021-0003108 and the entire contents of this Korean patent application are incorporated herein by reference.

The present utility model relates to a press trough (which can also be referred to as a press tub or press bowl) and a device for activating battery cells, which comprises the press trough.

BACKGROUND TECHNOLOGY OF THE UTILITY MODEL

A secondary battery is a battery that can be used repeatedly by being charged and discharged. These secondary batteries are widely used in modern electronic devices such as smartphones, laptops and electric vehicles. In particular, since the energy density per unit mass and charging speed of lithium secondary batteries are higher than those of other secondary batteries such as nickel-cadmium, nickel-hydrogen and nickel-zinc batteries, lithium secondary batteries are widely used these days.

Such a secondary battery includes: an electrode assembly including a positive electrode plate, a negative electrode plate, and a separator; a pocket case accommodating the electrode assembly; and an electrode lead protruding from the bag body and electrically connected to the electrode assembly. The secondary battery can also be provided in the form of a battery module that includes multiple battery cells, and in the form of a battery pack that includes multiple battery modules.

A battery cell is manufactured by: filling an electrolytic solution into a bag case accommodating an electrode assembly; Carrying out loading/unloading and then sealing the bag body. In battery cells, when an electrolytic solution is filled in a bag case, namely, during impregnation with the electrolytic solution, the bag case may become convex. The battery cell capacity can increase if the electrolyte solution is evenly distributed in the bag case. Therefore, an operation of squeezing the bag body is required to disperse the electrolytic solution filled in the bag body evenly. For this purpose, a press trough is used to press battery cells together.

1 FIG. 14 is a perspective view of a conventional press tub of Patent Documents 1 and 2 is a side view of 1 . As in 1 and 2 As shown, a conventional press trough 10 has a plurality of press plates 11 and battery cells are arranged between the press plates 11 . In addition, the pressing plates 11 are arranged in an x-direction, and the battery cells are compressed or unloaded when the pressing plates 11 are moved in the x-direction, so a separation distance may decrease or increase.

Further, a main plate 12 is arranged to face a surface on the front side of the plurality of pressing plates 11 , and drive shafts 13 are provided in a corner portion of the main plate 12 . When the drive shafts 13 are rotated, the pressing plates 11 are pushed in the x-direction as the main plate 12 is advanced. As a result, the battery cells are pressed together by the distance between the pressing plates 11 becoming smaller.

However, if the main plate 12 is pressed in only one direction, there may be a pressure deviation according to the different distances from a motor M, and in this case, there may be a deviation in the pressure applied respectively to battery cells, thereby reducing the quality of the manufactured ones Battery cells is reduced.

PRIOR ART DOCUMENTS

PATENT DOCUMENTS

Patent Document 1: Korean Patent Publication No. 2020-0042801

DESCRIPTION OF THE UTILITY MODEL

TECHNICAL TASK

The present utility model intends to solve at least some of the above problems. For example, the present utility model provides a squeeze trough capable of squeezing a plurality of battery cells from two directions, and a battery cell activating device having the squeeze trough.

TECHNICAL SOLUTION

The present utility model provides a press trough that can press multiple battery cells from two directions. In In one example, the press trough according to the present utility model includes: a frame accommodating a plurality of battery cells; a first main plate and a second main plate which are arranged on respective outermost sides of the battery cells and compress the battery cells accommodated in the frame; and a driving axis that fixes the first main board and the second main board and moves them in a horizontal direction. In a specific example, the drive shaft has a structure in which a first screw unit is made in an area where the first main plate is fixed, and a second screw unit is made in an area where the second main plate is fixed. In addition, the first screw unit and the second screw unit have threads made in directions opposite to each other, and the first main plate and the second main plate are moved toward or away from each other by rotation of the drive shaft.

In another example, the press tub according to the present utility model further includes sub-plates between the battery cells accommodated in the frame, the sub-plates being arranged to be movable along the drive axis.

Here, the sub-plates each have an attachment hole in a portion attached to the drive shaft, and a diameter of the attachment hole is larger than a diameter of the drive shaft.

In a further example, the press trough also has a fastening plate which is arranged in a central area of the control axis. In addition, a first pressure sensor and a second pressure sensor can be arranged on a respective side of the mounting plate.

In yet another example, a first center plate and a second center plate are arranged on a respective side of the mounting plate so as to be movable along the respective drive axis. In a specific example, the first pressure sensor and the second pressure sensor are arranged between the first center plate and the mounting plate and between the second center plate and the mounting plate, respectively.

Here, the first center plate and the second center plate each have a mounting hole in a portion fixed to the drive shaft, and a diameter of the mounting hole may be larger than that of the drive shaft.

The press trough may further include a power generation unit connected to an end of the drive axle and providing rotational power to the drive axle.

The present utility model further provides a device for activating battery cells, which has the press trough described above. In one example, the device may further include a charging and discharging unit electrically connected to battery cells housed in a frame.

BENEFICIAL EFFECTS

In a press vat and a battery cell activating device including the press vat according to the present utility model, a moving distance of each plate can be shortened by pressing a plurality of battery cells from both directions, and thereby the pressure deviation between respective battery cells can be reduced.

character list

• 1 Fig. 14 is a perspective view of a conventional press vat.
• 2 is a side view of 1 .
• 3 12 is a perspective view of a press vat according to an embodiment of the present utility model.
• 4 Fig. 12 is a plan view of a press tub according to an embodiment of the present utility model.
• 5 12 is a diagram showing an operation of a drive shaft of a press vat according to an embodiment of the present utility model.
• 6 Fig. 12 is a plan view of a press tub according to another embodiment of the present utility model.
• 7 12 is a diagram showing an operation of a drive shaft of a press vat according to another embodiment of the present utility model.
• 8th 12 is a diagram showing an operation of a drive shaft of a press vat according to another embodiment of the present utility model.
• 9 12 is a diagram showing an operation of a drive shaft of a press vat according to another embodiment of the present utility model.

BEST MODE TO RUN THE UTILIZATION PATTERN

Because the inventive concept encompasses various modifications and numerous embodiments, specific embodiments are illustrated in the drawings and described in detail in the specification. However, this is not intended to limit the present utility model to the particular embodiments disclosed, and it should be understood that all changes, equivalents, and substitutions are within the spirit and scope of the present utility model.

It is to be understood that herein, terms such as "comprising," "including," "having," or "having" are intended to indicate that there is an element, number, step, operation, component, portion, or combination thereof described in the specification and that such terms do not inherently exclude the possibility of the presence or addition of one or more other elements or numbers, steps, operations, components, parts, or combinations thereof. And when a part, such as a layer, film, region, plate, etc., is referred to as being "on" another part, this does not just include the case where the part is placed "directly on" the other part , but possibly also the case that another part is in between. Conversely, when a part, such as a layer, film, region, plate, etc., is referred to as being "beneath" another part, this does not just include the case where the part is "directly beneath" the other part , but possibly also the case that another part is in between. Also, the wording “arranged on” in the present application may include the case where the element is arranged on the bottom and the top.

The present utility model relates to a press trough and a device for activating battery cells, which has the press trough.

In general, a pocket battery cell (pouch-type battery cell, pouch battery cell) is produced in that an electrode assembly, which includes a negative electrode, a separator and a positive electrode, is inserted into a pocket case, an electrolytic solution is injected into the case and the edge portion is sealed. The batteries are then activated through several charging and discharging cycles. Gas is generated in this process, and a sealing unit of the bag body is partially opened to perform degassing, and then resealing is performed. At this time, if an electrolytic solution is filled in the pocket case of the pocket battery cell, the two sides of the pocket case will bulge, and accordingly, squeezing on both sides of the battery cells (squeezing) is required to increase the capacity of the battery. A press trough is used to press the battery cells together.

The conventional press tub has a main plate that moves multiple battery cells and presses the main plate from only one side in a direction in which the multiple battery cells are arranged. However, if the main plate is pressed in only one direction, the pressure applied to the respective battery cells will deviate, thereby degrading the quality of the manufactured battery cells.

Therefore, the present utility model provides a squeeze trough capable of squeezing a plurality of battery cells from both sides, and a battery cell activating device having the squeeze trough. In particular, in the present utility model, a moving distance of each plate can be shortened by pressing the plural battery cells from both directions, and therefore a pressure deviation between respective battery cells can be reduced.

A press vat according to the present utility model and a battery cell activating device having the press vat will be described in detail below.

In one example, the press trough according to the present utility model includes: a frame accommodating a plurality of battery cells; a first main plate and a second main plate which are arranged on respective outermost sides of the battery cells and compress the battery cells accommodated in the frame; and a driving axis that fixes the first main board and the second main board and moves them in a horizontal direction. Here, the drive axis may have a structure such that a first screw unit is made in a portion where the first main plate is fixed, and a second screw unit is made in a portion where the second main plate is fixed. In addition, the first screw unit and the second screw unit may have threads made in directions opposite to each other, and the first main plate and the second main plate are moved toward or away from each other.

Battery cells accommodated in a press trough according to the present utility model are, can be pocket battery cells. For example, the battery cell is a pocket battery cell, and an electrode assembly having a positive electrode/separator/negative electrode structure is embedded in an outer material of the laminate layer in a state of being connected to electrode leads made outside the outer material. The electrode lines can be drawn to the outside of the layer and can be extended in the same or in opposite directions.

The frame forms a specific space for accommodating a plurality of pocket battery cells in a longitudinal direction and has a hexahedral shape. The frame can be configured to have side walls on either side of the bottom to support the battery cells. The side walls may have a structure such that they are formed on one side and the other side along the direction in which the battery cells are accommodated. In addition, it may have a structure in which an upper portion is opened to take out and mount the battery cells.

In one example, the first main plate and the second main plate compress a plurality of battery cells accommodated in the frame, with the first main plate and the second main plate being arranged at the outermost parts of the battery cells. For example, when 36 battery cells are arranged in a frame, the first main plate may be arranged on the front of the first battery cell, and the second main plate may be arranged on the front of the 36th battery cell. In addition, the first main board and the second main board press both surfaces of the plurality of battery cells by the operation of the drive axis.

The first main plate and the second main plate can be made of a metallic material with a high mechanical rigidity. The first main plate and the second main plate can also be made of reinforced plastic, reinforced ceramic, or toughened glass, etc. as long as they have excellent mechanical rigidity.

In one example, the first main board and the second main board are fixed to the drive axle. In a specific example, drive axes are connected to an edge portion of the first main board and the second main board. The drive shafts have a structure such that they extend along a direction in which the battery cells are accommodated, and the drive shafts can be fixed to the side wall of the frame. Since one end of each of the drive shafts is connected to gears (G) which are rotated back and forth with a motor, the drive shafts can also be rotated back and forth. There can be four drive axes in total, located on the right side, left side, top and bottom of the frame. However, the present utility model is not limited to this. The press trough according to the present utility model has a plurality of drive axes, but the operation of only one drive axis is described herein for the sake of easy explanation.

In one example, the drive axis has a structure such that a first screw unit is made in an area where the first main plate is fixed, and a second screw unit is made in an area where the second main plate is fixed.

Here, the first screw unit and the second screw unit may have a structure such that screw threads are provided in directions opposite to each other. Thus, the first main plate and the second main plate, which are fixed to the first screw unit and the second screw unit, can be moved toward or away from each other by the rotation of the drive shaft. For example, when the drive shaft is rotated in a forward direction, the first main plate and the second main plate can be moved toward each other to thereby compress a plurality of battery cells arranged between the first main plate and the second main plate. On the other hand, when the drive shaft is rotated in the reverse direction, the first main board and the second main board can be moved to move away from each other.

In addition, insertion holes into which the drive shafts are inserted may be formed in the first main board and the second main board. Specifically, the insertion hole of the first main plate may have a thread corresponding to the screw thread of the first screw unit, and the insertion hole (not shown) of the second main plate may have a thread corresponding to the screw thread of the second screw unit.

With the configuration described above, the press vat according to the present utility model can press a plurality of battery cells from two directions, and thereby the pressure deviation between the battery cells can be reduced.

In another example, the press trough according to the present utility model fer Ner sub-plates, which are arranged between the battery cells, which are accommodated in the frame. In a specific example, the sub-plates are arranged between multiple battery cells so as to face front and back sides of the multiple battery cells, and are arranged on the upper portion of the bottom of the frame. In addition, the sub-plates can support the battery cells while contacting both side faces of the battery cells, so that the battery cells can stand still when inserted into the frame. In addition, the partial plates can be spaced apart from one another by a thickness of the pocket battery cell.

The partial plates are plates which are not deformed by high temperature and high pressure and have high mechanical rigidity. Pocket battery cells are placed between the sub-plates to press both sides together.

In addition, the sub-plates may have a structure such that they are movable in a horizontal direction along the drive axis. However, the sub-plates are not moved by the rotation of the drive shaft but are moved by the pressure of the first main plate and the second main plate arranged at the outermost parts of the plurality of battery cells.

Here, the sub-plates each have a fastening hole in a region that is fastened to the drive shaft, and a diameter of the fastening hole can be larger than a diameter of the drive shaft. The sub-plates are shown herein as being attached to the drive axle, but they may also be attached to an additional guide rail or guide bar.

The multiple battery cells can be moved in a horizontal direction in a standing state and the. Battery cells can be compressed more stably.

In a further example, the pressing plate according to the present utility model has a fixing plate which is arranged in a central area of the drive axis.

In a specific example, the mounting plate is mounted in the middle portion of the drive shaft. Alternatively, the mounting plate can be attached to the underside of the frame. In the press tub according to the present utility model, an area where the first main panel is arranged and an area where the second main panel is arranged can be distinguished as a first area and a second area with respect to the mounting plate. Thereby, the moving distance of the divisional plates and the battery cells arranged in each area can be shortened, and the pressure deviation between the battery cells can be reduced.

In still another example, the press trough according to the present utility model includes a first pressure sensor and a second pressure sensor disposed on respective sides of the mounting plate.

In a specific example, the first pressure sensor and the second pressure sensor are load cells, where the first pressure sensor and the second pressure sensor measure a pressure generated in the first area when the first main panel is moved toward the mounting panel. In addition, the second pressure sensor measures a pressure generated in the second area when the second main board is moved toward the mounting board. When the battery cells are pressed from both directions, the pressure applied to the battery cells can be easily measured by using the first pressure sensor and the second pressure sensor in each area. Then the values measured with the first pressure sensor and the second pressure sensor can be compared.

In still another example, a first center plate and a second center plate of the pressing plate according to the present utility model are arranged on respective sides of the mounting plate so as to be movable along the drive axis. Here, the first pressure sensor and the second pressure sensor can be arranged between the first middle plate and the fastening plate and between the second middle plate and the fastening plate.

Here, the first sub-plate and the second sub-plate may each have an attachment hole in a portion attached to the drive shaft, and a diameter of the attachment hole may be larger than that of the drive shaft. The first center plate and the second center plate have a structure such that they are freely movable along the drive axis.

Specifically, the first middle plate can be moved to the first pressure sensor side by the pressure of the first main plate. In addition, the first pressure sensor can easily measure the pressure generated in the first area. Moreover, the second middle plate can be moved to the second pressure sensor side by the pressure of the second main plate. In addition, the second pressure sensor can easily measure the pressure generated in the second area.

In one example, the press vat according to the present utility model has a power generation unit that is connected to an end of the drive axle and provides a rotating force for the drive axle. In a specific example, the power generation unit applies rotational force to the drive shaft using a hand lever, but a motor or the like may be installed in some cases. The first main plate and the second main plate can be moved towards or away from each other when the drive shaft is rotated.

In addition, the present utility model provides a device for activating battery cells, which has the press trough described above. In a specific example, the device for activating battery cells according to the present utility model can further comprise a charging and discharging unit which is electrically connected to the battery cells.

The charge and discharge unit can activate the battery cells through a charge/discharge line electrically connected to the electrode assembly of the battery cells. The charging and discharging unit is electrically connected to the electrode line of the battery cell via the charging/discharging line. The charging and discharging unit can supply power to the secondary battery for charging or can receive discharge power from the secondary battery. Here, the power supplied to the secondary battery is not limited to supplying power sufficient for fully charging the secondary battery. Supplying power to the secondary battery may also mean supplying power, which may be sufficient for measuring voltages of the first electrode line and the second electrode line to evaluate the performance of the secondary battery. This can also apply to receiving discharge energy from the secondary battery, and therefore the description is not repeated here.

Various forms of the press trough according to the present utility model will be described below with reference to the drawings.

FIRST EMBODIMENT

3 12 is a perspective view of a press vat according to an embodiment of the present utility model and 4 Fig. 12 is a plan view of a press tub according to an embodiment of the present utility model.

In 3 and 4 A press plate 100 according to the present utility model includes: a frame 110 accommodating a plurality of battery cells; a first main plate 120 and a second main plate 130 which are arranged on respective outermost sides of the battery cells and compress the battery cells accommodated in the frame 110; and a drive shaft 140 which holds and moves the first main board 120 and the second main board 130 in a horizontal direction.

The frame 110 forms a specific space for accommodating a plurality of pocket battery cells in a longitudinal direction and has a hexahedral shape. The frame 110 may be configured to have side walls 112 on either side of a bottom 111 to support the battery cells. The side walls 112 may have a structure such that they are made on one side and the other side along the direction in which the battery cells are accommodated. In addition, the frame 110 may have a structure such that an upper portion is opened to take out and mount the battery cells.

The first main plate 120 and the second main plate 130 are arranged at the outermost part of the battery cells and compress a plurality of battery cells accommodated in the frame 110 . For example, when 36 battery cells are arranged in a frame 110, the first main plate 120 may be arranged on the front of the first battery cell, and the second main plate 130 may be arranged on the front of the 36th battery cell. In addition, the main plate 120 compresses the first and second main plates 130 both surfaces of the battery cells by the operation of the drive shaft 140 as described below.

In addition, the first main plate 120 and the second main plate 130 are fixed to the drive shaft 140 . In particular, the control axes 140 are arranged in an edge area of the first main plate 120 and the second main plate 130 . The drive shafts 140 have a structure such that they extend along a direction in which the battery cells are accommodated, and they can be fixed to the side wall of the frame 110 . Since one end of each of the drive shafts 140 is connected to gears (G) rotated back and forth with a motor (M), the drive shafts 140 can also be rotated back and forth. There may be a total of four drive axes 140 located on the right side, left side, top, and bottom of the frame 110 . However, the present utility model is not on it limited. In addition, 3 and 4 the representation of the control axes 140 is partially omitted.

5 12 is a diagram showing an operation of a drive axis of a press vat according to an embodiment of the utility model. In 5 For example, the drive axis 140 is configured such that a first screw unit 141 is made in an area where the first main plate 120 is fixed, and a second screw unit 142 is made in an area where the second main plate 130 is fixed.

At this time, the first screw unit 141 and the second screw unit 142 can be screw-threaded in directions opposite to each other. Therefore, the first main plate 120 and the second main plate 130 fixed to the first screw unit 141 and the second screw unit 142 can be moved toward or away from each other by the rotation of the drive shaft 140 . For example, when the drive shaft 140 is rotated in a forward direction, the first main plate 120 and the second main plate 130 can be moved toward each other to thereby compress a plurality of battery cells arranged between the first main plate 120 and the second main plate 130. On the other hand, when the drive shaft 140 is rotated in the reverse direction, the first main board 120 and the second main board 130 can be moved to move away from each other.

Although not shown in the drawings, the first main board 120 and the second main board 130 may have insertion holes (not shown) into which the drive shaft 140 is inserted. Specifically, the insertion hole of the first main plate 120 may have a thread corresponding to the screw thread of the first screw unit 141 and the insertion hole (not shown) of the second main plate 130 may have a thread corresponding to the screw thread of the second screw unit 142 .

With the configuration described above, the press tub 100 according to the present utility model can press a plurality of battery cells from two directions, and thereby the pressure deviation between the battery cells can be reduced.

SECOND EMBODIMENT

6 Fig. 12 is a plan view of a press tub according to another embodiment of the present utility model. In 6 A press trough 200 according to the present utility model has partial plates 250 which are arranged between battery cells which are accommodated in a frame 210 .

The sub-plates 250 are arranged between multiple battery cells so as to face front and back sides of the multiple battery cells, and are arranged on an upper portion of a bottom of the frame 210 . In particular, the sub-plates 250 support the battery cells while contacting both side faces of the battery cells, so that the battery cells can stand still when inserted into the frame 210 . The sub-plates 250 may be spaced apart by a thickness of the pocket battery cell.

In addition, the sub-plates 250 may have a structure such that they are movable in a horizontal direction along a drive axis 240 . However, the sub-plates 250 are not moved by the rotation of the drive shaft 240 but are moved by the pressure of a first main plate 220 and a second main plate 230 arranged at the outermost part of the plurality of battery cells.

Although not illustrated in the drawings, the plurality of sub-plates 250 each have an attachment hole (not illustrated) in a portion attached to the drive shaft 240 , and a diameter of the attachment hole is larger than a diameter of the drive shaft 240 .

The multiple battery cells can be moved standing in a horizontal direction due to the division plates 250, and the battery cells can be pressed together more stably.

The configuration of the press tub of the present utility model is described above, and each component will not be described in detail here.

THIRD EMBODIMENT

7 12 is a diagram showing an operation of a drive shaft of a press vat according to another embodiment of the present utility model. In 7 the press trough according to the present utility model has a fastening plate 360 which is arranged in a central area of a drive axis 340 .

The fixing plate 360 is fixed in the middle area of the drive shaft 340 . Although not shown in the drawings, the mounting plate 360 can also be attached to the underside of the frame. An area where a first main board 320 is arranged and an area where a second main board 330 is arranged are distinguished from each other with respect to the mounting board 360 as a first area and a second area. Thereby, the moving distance of the divisional plates and the battery cells arranged in each area can be shortened, and the pressure deviation between the battery cells can be reduced.

Since the configuration of the press vat of the present utility model has been described above, each component will not be described in detail here.

FOURTH EMBODIMENT

8th 12 is a diagram showing an operation of a drive shaft of a press vat according to another embodiment of the present utility model. In 8th the press trough according to the present utility model has a fastening plate 460 which is arranged in a central area of a drive axis 440 . In addition, a first pressure sensor 471 and a second pressure sensor 472 are arranged on respective sides of the mounting plate 460 .

In a specific example, the first pressure sensor 471 and the second pressure sensor 472 are load cells, where the first pressure sensor measures a pressure generated in the first area when a first main plate 420 is moved toward the mounting plate 460 . In addition, the second pressure sensor 472 measures a pressure generated in the second area when a second main board 430 is moved toward the attachment board 460 . When the battery cells are pressed together from both directions, the pressure applied to the battery cells can be easily measured by using the first 471 and 472 second pressure sensors in each area. Then the values measured with the first pressure sensor 471 and the second pressure sensor 472 can be compared.

Since the configuration of the press vat of the present utility model has been described above, each component will not be described in detail here.

FIFTH EMBODIMENT

9 12 is a diagram showing an operation of a drive shaft of a press vat according to another embodiment of the present utility model. In 9 a press trough 500 according to the present utility model has a mounting plate 560 which is arranged in a central area of a drive shaft 540 .

In addition, a first center plate 581 and a second center plate 582 are arranged to be movable along the driving axis 540 on either side of the mounting plate 560 . In this case, the first pressure sensor 571 and the second pressure sensor 572 can be arranged between the first middle plate 581 and the fastening plate 560 or between the second middle plate 582 and the fastening plate 560 .

Although not shown in the drawings, the first center plate 581 and the second center plate 582 each have a mounting hole (not shown) in a portion that is fixed to the drive shaft 540, and a diameter of the mounting hole is larger than that of the drive shaft 540 is. The first center plate 581 and the second center plate 582 may have a structure such that they are freely movable along the driving axis 540 .

The first middle plate 581 is moved to the first pressure sensor 571 by the pressure of a first main plate 520 . This allows the first pressure sensor 571 to easily measure the pressure generated in the first area. In addition, the second middle plate 582 can be moved to the second pressure sensor 572 by the pressure of a second main plate 530 . This allows the second pressure sensor 572 to easily measure the pressure generated in the second area.

Since the configuration of the press vat of the present utility model has been described above, each component will not be described in detail here.

Although preferred examples of the present utility model have been described with reference to the drawings, it should be understood that those skilled in the art can make various modifications and changes to the present utility model without departing from the spirit and scope of the utility model set forth in the claims below.

Therefore, the technical scope of the present utility model should not be limited to the content presented in the detailed description but should be defined by the claims.

Reference List

1

battery cell

10

press trough

11

press plate

12

main plate

13

control axis

100, 200, 300, 400, 500

press trough

110, 210

frame

111

bottom

112

Side wall

120, 220, 320, 420, 520

First main plate

130, 230, 330, 430, 530

Second main plate

140, 240, 340, 440, 540

control axis

141

First screw unit

142

Second screw unit

250, 550

part plate

360, 460, 560

mounting plate

471, 571

First pressure sensor

472, 572

Second pressure sensor

581

First middle plate

582 -

Second center panel

M

engine

G

gear

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• KR 1020210003108 [0001]
• KR 20200042801 [0009]

Claims (10)

Press trough characterized by: a frame accommodating multiple battery cells; a first main plate and a second main plate which are arranged on respective outermost sides of the battery cells and compress the battery cells accommodated in the frame; and a drive axis that fixes the first main board and the second main board and moves them in a horizontal direction, wherein the drive shaft has a structure in which a first screw unit is formed in a region where the first main plate is fixed and a second screw unit is formed in a region where the second main plate is fixed, and wherein the first screw unit and the second screw unit have threads formed in directions opposite to each other, and the first main plate and the second main plate are moved toward or away from each other by rotation of the drive shaft. Press trough after claim 1 , further comprising: sub-plates between the battery cells accommodated in the frame, the sub-plates being arranged to be movable along the drive axis. Press trough after claim 2 , wherein the sub-plates each have an attachment hole in a portion attached to the drive shaft, wherein a diameter of the attachment hole is larger than a diameter of the drive shaft. Press trough after claim 1 , further comprising: a mounting plate disposed at a center portion of the drive axis. Press trough after claim 4 , wherein a first pressure sensor and a second pressure sensor are arranged on respective sides of the mounting plate. Press trough after claim 4 , wherein a first center plate and a second center plate are arranged on both sides of the mounting plate so that they are movable along the drive axis, and the first pressure sensor and the second pressure sensor between the first center plate and the mounting plate and between the second center plate and the mounting plate, respectively are arranged. Press trough after claim 6 , wherein the first center plate and the second center plate each have a mounting hole in a portion fixed to the drive shaft, wherein a diameter of the mounting hole is larger than that of the drive shaft. Press trough after claim 1 , further comprising: a power generation unit that is connected to one end of the drive axle and transmits a rotational force to the drive axle. Device for activating battery cells, wherein the device for activating battery cells the press trough according to one of Claims 1 until 8th having. device after claim 9 further comprising a charging and discharging unit electrically connected to the battery cells accommodated in a frame.

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