KR102535823B1 - Battery degassing device - Google Patents

Abstract

Disclosed is a device for removing gas in charging and discharging secondary battery cells which comprises: a base frame supporting a plurality of batteries; a charging unit disposed on an upper part of the base frame to fix the plurality of batteries and charge the plurality of batteries; and a gas removal unit disposed on the upper part of the base frame to remove gas inside the plurality of batteries. The gas removal unit comprises: a vacuum frame integrally formed along a first direction and having a vacuum flow path disposed inside along the first direction; and a vacuum unit connected to the vacuum frame to be movable vertically, selectively contacting the plurality of batteries to remove the gas from the plurality of batteries, and having a vacuum opening disposed on a side surface. In addition, the vacuum unit moves to a first position in which the vacuum opening and the vacuum flow path are spaced apart and a second position in which the vacuum opening and the vacuum flow path face each other. Accordingly, efficiency in removing gas generated while manufacturing batteries is improved.

Description

Secondary battery cell charge/discharge gas removal device {BATTERY DEGASSING DEVICE}

The present disclosure relates to a secondary battery cell charge/discharge gas removal device with improved removal efficiency of gas generated during battery manufacturing.

As technology develops, portable and high-performance electronic devices such as mobile phones and eco-friendly electric vehicles are being developed for people's convenience, and the demand for batteries for operating electronic devices is also greatly increasing.

The battery is also called a secondary battery, and as a lithium polymer battery, a pouch-type secondary battery has been widely used. Pouch-type secondary batteries have high energy density per unit weight and volume, and are easily used to make battery cells thinner and lighter.

In manufacturing such a battery, an electrode assembly is manufactured by manufacturing a positive electrode plate and a negative electrode plate, and then stacking them after interposing a separator therebetween.

Thereafter, a plasticizer (DBP) is extracted from the electrode assembly manufactured as described above, and an electrode tab is welded to an electrode lead of the electrode assembly to be embedded inside the pouch case. After the electrode assembly is embedded in the pouch case, the electrolyte solution is injected into the pouch case so that the electrode assembly is impregnated with the electrolyte solution. When the electrolyte solution is injected as described above, the edge of the pouch case is joined by thermal fusion to seal the pouch case. Thereafter, an aging process is performed to stabilize the assembled battery cell as described above, and then a charge/discharge process is performed to activate the battery cell. However, during the charging and discharging process, an irreversible reaction between the electrolyte and additives occurs due to the formation of an SEI layer, and gas is generated at this time.

When the gas generated inside the battery in the manufacturing process is continuously present inside the battery, there is a problem in that battery performance is deteriorated or a safety accident occurs.

Therefore, removing the gas generated during charging and discharging of the battery is an essential process, and in order to remove the gas generated in the battery, a method of discharging the gas in a vacuum around the battery is used.

However, as in Patent Document 1, in the case of creating a vacuum state by wrapping around the battery in the form of a chamber, there is a problem in that a lot of time and money are consumed to maintain a vacuum in the chamber space.

In addition, as in Patent Document 2, in the case of a method of turning on and off the vacuum by contacting a battery, the structure of turning on and off is complex due to a combination of a number of structures such as the coupling bar 71, the cover 73, and the opening and closing opening 77. There was a problem.

Specifically, when the vacuum is not easily turned on or off due to poor contact with the openings 77 when the vacuum is turned on or off or the openings 77 are damaged due to friction, replacement of the openings 77 is difficult or impossible, resulting in substantial process efficiency. , there was a problem of poor maintenance efficiency.

Patent Document 1: Korean Registered Patent Publication No. 10-0433836 (registration date 2004.5.20) Patent Document 2: Korean Registered Patent Publication No. 10-1957503 (registration date 2019.3.6)

An object of the present disclosure is to provide a secondary battery cell charge/discharge gas removal device with improved removal efficiency of gas generated during battery manufacturing.

The present disclosure for achieving the above object is a base frame for supporting a plurality of batteries, a charging unit disposed on top of the base frame to fix a plurality of batteries and charging a plurality of batteries, and a plurality of batteries disposed on top of the base frame. A gas removal unit for removing internal gas, wherein the gas removal unit is integrally formed along a first direction and is movable up and down between a vacuum frame having a vacuum flow path disposed therein along the first direction and the vacuum frame. and a vacuum unit connected to and selectively contacting a plurality of batteries to remove gas from the plurality of batteries and having a vacuum opening disposed on a side surface, wherein the vacuum unit includes a first position and a vacuum opening in which the vacuum opening and the vacuum flow path are spaced apart. and a vacuum flow path are moved to a second position facing each other, and a secondary battery cell charge/discharge gas removal device is provided in which the gas of the battery is sucked in at the second position.

The vacuum unit includes a body extending in a second direction perpendicular to the first direction, an insertion portion disposed at one end of the body and connected to a battery, and a fixing protrusion protruding along an outer circumferential surface of the body, wherein the body includes a first inflow passage formed with a first diameter along the longitudinal direction of the body, and a second inflow passage disposed above the first inflow passage and formed with a second diameter smaller than the first diameter, and the vacuum opening is It is connected to the second inflow passage, and the vacuum passage may have a third diameter smaller than the second diameter.

The body includes a first body disposed in the insertion groove of the vacuum frame, a second body disposed under the first body and disposed outside the vacuum frame, and disposed between the first body and the second body. An interference portion may be included, an outer diameter of the first body may be larger than an outer diameter of the second body, and the vacuum frame may include a guide member contacting the interference portion and supporting the first body to be disposed inside the vacuum frame. can

The guide member includes a pair of guide protrusions protruding toward the second body, the second body includes a pair of guide grooves formed along an outer circumferential surface of the second body in a longitudinal direction, and the pair Each of the guide protrusions may be inserted into each of the pair of guide grooves to prevent rotation of the vacuum unit.

The vacuum unit may further include an elastic member disposed between the fixing protrusion and the guide member, and the pair of guide grooves may be disposed between the fixing protrusion and the guide member.

The vacuum frame includes a guide frame for stably guiding the vertical movement of the vacuum unit into which the second body of the vacuum unit is inserted, and a guide frame disposed at one end of the vacuum channel to keep the inside of the vacuum channel in a vacuum state at the second position. Further comprising a vacuum connection portion maintained as, wherein the vacuum portion is disposed at one end of the insertion portion of the vacuum portion and the other end opposite to the one end may be blocked.

A first frame, a second frame disposed above the first frame and connected to the first frame, a support frame disposed to be movable between the first frame and the second frame, and the second frame and the support frame It further includes a movement unit disposed between the support frame and moving the support frame up and down, wherein the charging unit and the gas removal unit are connected to the second frame, and the base frame is supported by the support frame according to the vertical movement of the support frame. can move up and down.

1 is a perspective view illustrating a secondary battery cell charge/discharge gas removal device according to an embodiment of the present disclosure.
2 is a perspective view illustrating a charging unit and a vacuum unit according to an embodiment of the present disclosure.
Figure 3 is a side view of Figure 2;
4 is a front view showing a charging unit according to an embodiment of the present disclosure.
5 is a front view showing a gas removal unit according to an embodiment of the present disclosure.
6 is a cross-sectional view showing a gas removal unit according to an embodiment of the present disclosure.
7 is a perspective view illustrating a vacuum unit according to an embodiment of the present disclosure.
8 is an enlarged perspective view of part A of FIG. 7 .
9 is a top view illustrating a body of a vacuum unit and a guide member according to an embodiment of the present disclosure.
10 is a cross-sectional view showing a first position of a vacuum unit according to an embodiment of the present disclosure.
11 is a cross-sectional view showing a second position of a vacuum unit according to an embodiment of the present disclosure.

In order to fully understand the configuration and effects of the present disclosure, preferred embodiments of the present disclosure will be described with reference to the accompanying drawings. However, the present disclosure is not limited to the embodiments disclosed below, and may be implemented in various forms and various changes may be made. However, the description of the present embodiments is provided to complete the disclosure of the present disclosure and to completely inform those skilled in the art of the scope of the invention to which the present disclosure belongs. In the accompanying drawings, the size of the components is enlarged from the actual size for convenience of description, and the ratio of each component may be exaggerated or reduced.

It should be understood that when an element is described as being “on” or “adjacent to” another element, it may be in direct contact with or connected to the other element, but another element may exist in the middle. something to do. On the other hand, when a component is described as “directly on” or “directly in contact with” another component, it may be understood that another component does not exist in the middle. Other expressions describing the relationship between components, such as "between" and "directly between" can be interpreted similarly.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. The terms may only be used for the purpose of distinguishing one component from another. For example, a first element may be termed a second element, and similarly, a second element may be termed a first element, without departing from the scope of the present disclosure.

Singular expressions include plural expressions unless the context clearly dictates otherwise. The terms "include" or "has" are used to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, and includes one or more other features or numbers, It can be interpreted that steps, actions, components, parts, or combinations thereof may be added.

Terms used in the embodiments of the present disclosure may be interpreted as meanings commonly known to those skilled in the art unless otherwise defined.

Hereinafter, a structure of a secondary battery cell charge/discharge gas removal device 1 according to an embodiment of the present disclosure will be described with reference to FIGS. 1 to 9 .

1 is a perspective view showing a secondary battery cell charge/discharge gas removal device 1 according to an embodiment of the present disclosure, and FIG. 2 shows a charging unit 100 and a vacuum unit 220 according to an embodiment of the present disclosure. A perspective view, Figure 3 is a side view of Figure 2, Figure 4 is a front view showing the charging unit 100 according to an embodiment of the present disclosure, Figure 5 is a gas removal unit 200 according to an embodiment of the present disclosure It is a front view shown, Figure 6 is a cross-sectional view showing a gas removal unit 200 according to an embodiment of the present disclosure, Figure 7 is a perspective view showing a vacuum unit 220 according to an embodiment of the present disclosure, Figure 8 is 7 is an enlarged perspective view of part A, and FIG. 9 is a top view showing the body 221 and the guide member 214 of the vacuum unit 220 according to an embodiment of the present disclosure.

The secondary battery cell charge/discharge gas removal device 1 is a device for removing gas generated during charging and discharging of a plurality of manufactured batteries B.

Specifically, the secondary battery cell charging and discharging gas removal device 1 includes a first frame 11, a second frame 12 disposed above the first frame 11 and connected to the first frame 11, A support frame 13 disposed to be movable between the first frame 11 and the second frame 12 and disposed between the second frame 12 and the support frame 13 to vertically move the support frame 13 A moving unit 15, a base frame 14 supporting a plurality of batteries B, and a charging unit disposed above the base frame 14 to fix the plurality of batteries B and to charge the plurality of batteries B 100 and a gas removal unit 200 disposed above the base frame 14 to remove gas inside the plurality of batteries B.

The first frame 11 supports the secondary battery cell charge/discharge gas removal device 1 and may be fixed on the ground. The first frame 11 may be disposed in a flat structure and may be connected to the second frame 12 disposed above the first frame 11 through a support shaft 13a.

For example, the first frame 11 may have a rectangular cross section.

Here, the support shaft 13a may be composed of a plurality of shafts disposed between the first frame 11 and the second frame 12 to connect the first frame 11 and the second frame 12 .

The second frame 12 is disposed to face the first frame 11, and the charging unit 100 and the gas agent disposed between the first frame 11 and the second frame 12 together with the first frame 11 Rejection 200 can be stably protected and supported.

In addition, the second frame 12 is disposed above the secondary battery cell charge/discharge gas removal device 1, and is connected to the charging unit 100 and the gas removal unit 200 so that the charging unit 100 and the gas removal unit 200 ) can be stably fixed.

The support frame 13 may move up and down between the first frame 11 and the second frame 12 while being disposed between the first frame 11 and the second frame 12 . The support frame 13 may be connected to the base frame 14 supporting the plurality of batteries B manufactured to support the plurality of batteries B and the base frame 14 .

In addition, a first cooling unit 16 for cooling the battery B may be disposed on one surface of the support frame 13 . Here, the first cooling unit 16 may be configured in plural and may include a circulation fan.

The movable part 15 is disposed between the second frame 12 and the support frame 13 so that the support frame 13 and the second frame 12 are connected and the support frame moves according to the movement of the movable part 15. (13) can be moved up and down.

Specifically, the moving part 15 is connected to the driving part 15a connected to the lower part of the second frame 12 and the driving part 15a and the support frame 13, and the length is adjusted to support the first frame 11. A moving shaft 15b for vertically moving the frame 13 may be included.

The driving unit 15a may be connected to the moving shaft 15b to provide power for adjusting the length of the moving shaft 15b. For example, the drive unit 15a may include an electric motor or a hydraulic pump. The length of the moving shaft 15b may be adjusted with power to be transmitted from the driving unit 15a.

The moving unit 15 may be composed of a plurality of pieces.

The base frame 14 may be connected to the support frame 13 while supporting the plurality of batteries B and disposed on the upper portion of the support frame 13 . Accordingly, the base frame 14 may also move up and down in association with the up and down movement of the support frame 13 .

For example, when the support frame 13 moves upward, the base frame 14 and the plurality of batteries B supported by the base frame 14 can move upward. Similarly, when the support frame 13 moves downward, the base frame 14 and the plurality of batteries B supported by the base frame 14 can move downward.

Here, when the support frame 13 moves upward, the plurality of batteries B come into contact with the charging unit 100 and the gas removal unit 200 to charge and discharge the battery B and the battery B. gas can be removed.

Similarly, when the support frame 13 is moved downward, the battery B from which charging/discharging and degassing has been performed is moved, and a new battery B for processing may be disposed on the base frame 14 .

The base frame 14 may have various structures for supporting a plurality of batteries (B).

Referring to FIGS. 3 and 4 , the charging unit 100 may be connected to the lower surface of the second frame 12 and disposed between the base frame 14 and the second frame 12 .

When the base frame 14 moves upward, the charging unit 100 may contact a plurality of batteries B supported by the base frame 14 to fix and charge/discharge each of the plurality of batteries B. there is.

The charging unit 100 may be configured as a pair disposed at a predetermined interval in the width direction (W) of the battery (B).

Specifically, the charging unit 100 is connected to the fixing member 140 for fixing the plurality of batteries (B) in contact with each of the plurality of batteries (B), and is connected to the fixing member 140 to support the fixing member 140. The frame 120, the fixing frame 110 that forms the outer shape of the charging unit 100 and supports the connection frame 120, and is disposed below the fixing frame 110 to charge and discharge each of the plurality of batteries (B). It may include a charging probe 150 that performs.

The fixing member 140 may stably fix the battery (B) by contacting the battery (B) for each of the plurality of batteries (B). For example, two fixing members 140 may be connected to one battery B.

In addition, the fixing member 140 may inject electrolyte into the battery B through an internal space. The fixing member 140 may be stably supported by being connected to the connecting frame 120 . In addition, the fixing member 140 may be composed of a plurality of pieces.

The connection frame 120 is supported by the fixing frame 110 and is connected to the fixing member 140 at the same time to stably support the fixing member 140 . Specifically, the connecting frame 120 is disposed in the vertical direction and connected to the first connecting frame 121 connected to the fixing member 140 and the horizontal direction perpendicular to the vertical direction and connected to the second connecting frame 122 and is fixed. It may include a second connecting frame 122 fixed to the frame 110 .

Accordingly, stable support of the fixing member 140 can be implemented through the sequential connection structure of the fixing member 140 , the first connecting frame 121 and the second connecting frame 122 .

The fixing frame 110 may form the outer shape of the charging unit 100 and fix the charging unit 100 to the second support frame. The fixed frame 110 may include a grid frame 130 in which a plurality of grid spheres 131 into which the second connection frame 122 is inserted are formed.

In addition, the fixing frame 110 is fastened to the second frame 12 in a sliding manner so that the position thereof may be fixed. Accordingly, the operator inserts and fixes the fixing frame 110 to the second frame 12 in a slide insertion manner, thereby adding convenience in assembling the charging unit 100 .

The grid frame 130 has a shape of a flat plate disposed in a vertical direction, and a plurality of grid spheres 131 arranged in a grid may be formed therein.

One second connection frame 122 may be inserted and supported in each of the plurality of grid spheres 131 .

The charging probe 150 may be disposed under the fixed frame 110 along the length direction of the fixed frame 110 . Specifically, the charging probe 150 supplies charging and discharging power and controls the charging probe 150, and a battery extending downward from the substrate 151 and fixed by the fixing member 140 ( B) may include a probe unit 152 inserted therein to charge and discharge the battery B.

The gas removal unit 200 is disposed between the pair of charging units 100 and selectively contacts the battery B fixed by the charging unit 100 to remove gas generated inside the battery B.

Specifically, when the support frame 13 rises, the gas removal unit 200 contacts the battery B supported by the base frame 14 to vacuum the inside of the battery B and the vacuum unit 220. The gas can be removed by inhalation.

The gas removal unit 200 is integrally formed along the first direction R1 and includes a vacuum frame 210 and a vacuum frame 210 having a vacuum passage 211 disposed therein along the first direction R1. It is connected to be movable up and down and selectively contacts the plurality of batteries (B) to remove gas from the plurality of batteries (B) and includes a vacuum unit 220 having a vacuum opening 225 disposed on the side. can

Here, the first direction R1 may be referred to as a longitudinal direction, and the second direction R2 may refer to a direction perpendicular to the first direction R1.

The vacuum frame 210 may be integrally formed by casting or forging, and may include a plurality of insertion grooves 213 formed in the second direction R2 so that the plurality of vacuum units 220 may slide. .

Accordingly, since the vacuum frame 210 does not require a separate configuration for assembling the vacuum frame 210 , a stable vacuum state of the vacuum passage 211 can be maintained.

That is, when the vacuum frame 210 is formed by assembling various parts, the vacuum is not maintained due to the space between the parts of the vacuum frame 210 or the cost of using or maintaining additional shielding parts to maintain the vacuum. In contrast to this additional requirement, since the vacuum frame 210 according to an embodiment of the present disclosure is integrally formed, manufacturing and maintenance costs can be greatly reduced and a stable vacuum state can be maintained.

In addition, the vacuum frame 210 is fastened to the second frame 12 in a sliding manner so that the position thereof may be fixed. Accordingly, by inserting and fixing the vacuum frame 210 to the second frame 12 in a sliding manner, the operator can add convenience in assembling the gas removing unit 200 .

A plurality of insertion grooves 213 may be formed in the lower portion of the vacuum frame 210 at predetermined intervals in the first direction R1. In each of the plurality of insertion grooves 213, one vacuum unit 220 may be inserted and arranged to be movable up and down.

Specifically, the plurality of insertion grooves 213 may have a cylindrical shape, and each diameter of the plurality of insertion grooves 213 may be equal to or greater than the outer diameter of the first body 221-1 of the vacuum unit 220. .

In addition, the plurality of insertion grooves 213 may be spatially connected to each other by a vacuum passage 211 formed in the first direction R1.

The vacuum frame 210 may have a rectangular shape extending long in the first direction R1 and may be stably fixed to the lower surface of the upper second frame 12 .

Referring to FIG. 10 , the vacuum passage 211 may be formed to extend in the first direction R1 inside the vacuum frame 210 and may connect a plurality of insertion grooves 213 to each other. A vacuum connector 212 connected to the vacuum frame 210 may be connected to and disposed at one end of the vacuum passage 211 .

Here, the vacuum connection unit 212 may be connected to the vacuum pump through a separate nozzle. Accordingly, through the operation of the vacuum pump, the gas generated inside the battery B is removed through the vacuum connection part 212, the vacuum passage 211, the vacuum opening 225 of the vacuum part 220, and the insertion part 222. It can be removed by inhalation.

The diameter of the vacuum passage 211 may be smaller than that of the vacuum opening 225 .

Accordingly, even when the vacuum part 220 rises in contact with the battery B and a part of the vacuum opening 225 is disposed to face the vacuum passage 211 and is spatially connected, the vacuum passage 211 and the vacuum section Gas generated inside the battery B may be suctioned and removed through the vacuum opening 225 and the insertion portion 222 of the 220 .

In addition, the vacuum frame 210 comes in contact with the interference portion 211-3 of the vacuum unit 220 to be described later, and is a guide member that supports the first body 221-1 to be continuously disposed inside the vacuum frame 210. (214).

The guide member 214 may be stably fixed through a lower surface of the vacuum frame 210 and a fastening member.

The guide member 214 may be formed as a circular plate, and a vacuum unit 220 may be inserted and disposed therein. The guide member 214 interferes with the interference portion 211-3 formed between the first body 221-1 and the second body 221-2 to move the first body 221-1 to the vacuum frame 210. Can be continuously placed inside the insertion groove 213 of.

Accordingly, the vacuum part 220 can be prevented from being separated from the outside of the vacuum frame 210 by its own weight. In addition, since the vacuum frame 210 is formed in a single structure, each vacuum unit 220 is inserted into the insertion groove 213 of the vacuum frame 210 and the guide member 214 is fixed to the vacuum frame 210. It is possible to prevent the vacuum unit 220 from being separated from the vacuum frame 210 in a simple manner.

That is, a simple assembly and stable structure of the vacuum unit 220 may be implemented through the shape of the vacuum unit 220 and the guide member 214 according to an embodiment of the present disclosure.

The vacuum unit 220 may be composed of a plurality, and one vacuum unit 220 may be inserted into and disposed in one insertion groove 213 of the vacuum frame 210 . Accordingly, the vacuum unit 220 may be disposed under the vacuum frame 210 at predetermined intervals in the first direction R1.

Here, one vacuum unit 220 may come into contact with one battery (B) to suction and remove gas generated from one battery (B).

Specifically, the vacuum unit 220 is a body 221 formed extending in a second direction R2 perpendicular to the first direction R1, and an insertion disposed at one end of the body 221 and connected to the battery B. It may include a fixed protrusion 223 protruding along the outer circumferential surface of the portion 222 and the body 221 .

The body 221 may form the outer shape of the vacuum unit 220 and may be integrally formed by elongating in the second direction R2. The body 221 can slide up and down with respect to the vacuum frame 210 in direct contact with the battery B.

For example, the vacuum unit 220 may move to a first position where the vacuum opening 225 and the vacuum passage 211 are separated from each other and a second position where the vacuum opening 225 and the vacuum passage 211 face each other. there is.

Here, the first position may be a state in which the body 221 of the vacuum unit 220 and the battery B are spaced apart, and the second position may mean a state in which the vacuum unit 220 and the body 221 are in contact. can

Specifically, the body 221 is disposed below the first body 221-1 disposed in the insertion groove 213 of the vacuum frame 210 and the first body 221-1, and is disposed outside the vacuum frame 210. It may include a second body 221-2 disposed on and an interference portion 211-3 disposed between the first body 221-1 and the second body 221-2.

Here, the outer diameter of the first body 221-1 is formed larger than the outer diameter of the second body 221-2 due to the difference between the outer diameters of the first body 221-1 and the second body 221-2. An interference portion 211-3 may be formed.

Accordingly, the interference portion 211-3 may interfere with the guide member 214 to prevent the first body 221-1 from escaping to the outside of the guide member 214.

The first body 221-1 may be continuously disposed inside the insertion groove 213, and a vacuum opening 225 may be formed on a side surface of the first body 221-1. In addition, a second inflow passage 227-2 having a second diameter D2 may be formed in the first body 221-1, and the vacuum opening 225 is formed with the second inflow passage 227-2. can be spatially linked.

In addition, a plurality of O-rings 218 for shielding the insertion groove 213 may be disposed on the outer circumferential surface of the first body 221-1.

Also, the upper end of the first body 221-1 may have a closed structure. Accordingly, the gas introduced through the second inflow passage 227-2 can move to the vacuum passage 211 only through the vacuum opening 225 formed on the side of the first body 221-1.

That is, the vacuum unit 220 may have a structure in which the insertion unit 222 is disposed at one end of the vacuum unit 220 and the other end opposite to the one end is blocked.

The second body 221-2 is disposed under the first body 221-1 and may be integrally formed with the first body 221-1. A first inflow passage 227-1 having a first diameter D1 may be formed inside the second body 221-2.

Accordingly, the second body 221-2 may transfer the gas sucked from the battery B to the second inflow passage 227-2 through the first inflow passage 227-1.

In addition, when referring to FIGS. 8 to 9, the second body 221-2 may include a pair of guide grooves 226 formed along the longitudinal direction on the outer circumferential surface of the second body 221-2. . For example, a pair of guide grooves 226 may be arranged to face each other with an interval of 180 degrees.

In addition, the pair of guide grooves 226 may have a shape of a long hole extending in the second direction R2, and the vacuum opening 225 formed in the first body 221-1 of the vacuum unit 220 It may be arranged on a straight line in two directions (R2).

A pair of guide grooves 226 may be coupled to a pair of guide protrusions 214a of the guide member 214, respectively.

Accordingly, the pair of guide protrusions 214a are disposed inside the pair of guide grooves 226, and the pair of guide protrusions 214a are disposed in the pair of guide grooves 226 as the vacuum unit 220 moves up and down. (214a) In the inserted state, the vacuum unit 220 may move up and down.

Here, the pair of guide protrusions 214a may be disposed to protrude from the inner circumferential surface of the guide member 214, and may be disposed to face each other at an interval of 180 degrees. The pair of guide protrusions 214a may be integrally formed with the pair of guide members 214 .

Therefore, the pair of guide projections 214a of the guide member 214 and the pair of guide grooves 226 of the second body 221-2 are continuously coupled to each other, and the vacuum unit 220 It can move up and down, and since the pair of guide protrusions 214a are formed in the second direction R2, rotation of the vacuum unit 220 can be prevented.

That is, each of the pair of guide protrusions 214a may be inserted into each of the pair of guide grooves 226 to prevent the vacuum unit 220 from rotating.

In addition, since the vacuum openings 225 of the vacuum unit 220 are formed to face each other at an interval of 180 degrees, when the operator assembles the vacuum unit 220 to the vacuum frame 210, the vacuum opening 225 at the second position ( 225) and the vacuum passage 211 must be assembled in a direction facing each other.

Accordingly, since the pair of guide grooves 226 of the second body 221-2 are disposed on the extension line in the downward direction of the vacuum opening 225, the operator inserts the pair of guide grooves 226 into the guide member ( 214), the vacuum opening 225 and the vacuum passage 211 can be easily assembled in a direction facing each other in the second position.

In addition, a pair of guide grooves 226 may be disposed between the fixing protrusion 223 and the guide member 214 .

Accordingly, since a pair of guide grooves 226 are disposed at a position corresponding to the position where the elastic member 224 is disposed, the rotational force generated from the elastic force of the elastic member 224 is directly limited, and thus the vacuum unit 220 Rotation can be prevented effectively.

In addition, the body 221 is disposed above the first inflow passage 227-1 formed with the first diameter D1 along the longitudinal direction of the body 221 and the first inflow passage 227-1, A second inflow passage 227-2 formed with a second diameter D2 smaller than (D1) may be included, and the vacuum opening 225 may be connected to the second inflow passage 227-2.

Here, the third diameter D3 that is the diameter of the vacuum passage 211 may be smaller than the second diameter D2 of the second inflow passage 227-2.

That is, the gas inside the battery B flows through the first inflow passage 227-1 of the first diameter D1 of the vacuum part 220 and the second inflow passage 227-2 of the second diameter D2. , the vacuum opening 225 and the vacuum passage 211 of the third diameter D3 may move sequentially.

Accordingly, as the gas introduced from the battery B moves along the passage structure of which the diameter is sequentially reduced, the vacuum force sucked from the vacuum connector 212 can efficiently suck gas through the sequential structure.

The insertion part 222 is located below the vacuum part 220 and can contact the battery B to suck in gas therein. The insertion part 222 may be made of an elastic material to prevent damage to the battery B and the insertion part 222 due to contact between the batteries B.

A portion of the insertion portion 222 may be opened and may be spatially connected to the first inflow passage 227-1. Accordingly, when the insertion portion 222 is inserted into the battery B, gas inside the battery B may pass through the insertion portion 222 and move to the first inflow passage 227-1.

For example, the insert 222 may include rubber.

The fixing protrusion 223 may be formed on the outer circumferential surface of the second body 221-2, and the position of the elastic member 224 may be stably fixed. Accordingly, the position of the elastic member 224 may be fixed by the lower surface of the vacuum frame 210 and the fixing protrusion 223 .

Meanwhile, the vacuum unit 220 may include an elastic member 224 disposed between the fixing protrusion 223 and the guide member 214 . The elastic member 224 may limit a position at which the vacuum unit 220 rises when the vacuum unit 220 moves upward due to interference with the battery B.

Accordingly, it is possible to prevent the upper end of the vacuum unit 220 from being damaged due to an impact with the vacuum frame 210 due to the rapid rise of the vacuum unit 220 .

Meanwhile, referring to FIG. 6 , the vacuum frame 210 may include a guide frame 230 into which the second body 221-2 is inserted and which stably guides the vertical movement of the vacuum unit 220.

The guide frame 230 may be spaced apart from the lower surface of the vacuum frame 210 and may include arrayed grooves into which each of the vacuum units 220 may be inserted. Accordingly, the vacuum unit 220 may move up and down by interfering with the battery B while being inserted into the array grooves of the guide frame 230, respectively.

Therefore, considering that the vacuum part 220 is formed long in the second direction R2, the entire vacuum part 220 can be moved stably up and down.

Hereinafter, an operation of the secondary battery cell charge/discharge gas removal device 1 according to an embodiment of the present disclosure will be described with reference to FIGS. 10 and 11 .

First, a plurality of batteries B may be seated in the base frame 14 . At this time, the battery B, the charging unit 100, and the gas removal unit 200 may be in a spaced state.

Specifically, as shown in FIG. 10, since the vacuum unit 220 and the battery B are spaced apart, the vacuum opening 225 and the vacuum passage 211 of the first body 221-1 are spaced apart. It may be in the first position.

At this time, the interference part 211-3 disposed between the first body 221-1 and the second body 221-2 interferes with the guide member 214 of the vacuum frame 210, so that the first body 221 -1) may be prevented from escaping to the outside of the vacuum frame 210 .

Thereafter, it can rise to the top of the support frame 13 by the moving power of the moving unit 15, and the battery B can come into contact with the charging unit 100 and the gas removing unit 200. That is, the battery (B) is fixed by the fixing member 140 of the charging unit 100, and the probe unit 152 can be inserted into the battery (B). At the same time, the battery B may contact the vacuum unit 220 .

At this time, the vacuum unit 220 may continuously move upward in contact with the battery B. At the same time, the second body 221-2 of the vacuum unit 220 can be stably moved upward by the guide frame 230, and the pair of guide protrusions 214a of the guide member 214 In a state of being inserted into the guide groove 226, the vacuum unit 220 may move upward without being rotated.

Next, the vacuum unit 220 may move to a second position where the vacuum opening 225 and the vacuum passage 211 are spatially connected to each other. Accordingly, the vacuum passage 211, the second inlet passage 227-2, and the first inflow passage 227-1 may be sequentially brought into a vacuum state due to the suction force generated by the vacuum pump.

Thereafter, the probe unit 152 may perform charging and discharging of the connected battery B, and gas generated from the battery B during the charging and discharging process flows through the first inlet 227-1 and the second inlet 227-1. (227-2), the vacuum opening 225, it can be discharged to the outside through the vacuum flow path (211).

Here, the first inflow passage 227-1 of the first diameter D1, the inflow passage of the second diameter D2 smaller than the first diameter D1, and the third diameter D3 smaller than the second diameter D2 ), the gas of the battery B can be efficiently discharged to the outside.

In addition, an intuitive vacuum state can be determined through a simple structure of a first position where the vacuum opening 225 and the vacuum passage 211 are spaced apart from a second position facing each other, and at the same time, a simple structure, a vacuum frame integrally formed ( 210), it is possible to greatly improve the efficiency of degassing of the battery B by maintaining a stable vacuum state.

In the above, various embodiments of the present disclosure have been individually described, but each embodiment is not necessarily implemented alone, and the configuration and operation of each embodiment may be implemented in combination with at least one other embodiment. .

In addition, although the preferred embodiments of the present disclosure have been shown and described above, the present disclosure is not limited to the specific embodiments described above, and the technical field to which the disclosure belongs without departing from the subject matter of the present disclosure claimed in the claims. Of course, various modifications are possible by those skilled in the art, and these modifications should not be individually understood from the technical spirit or perspective of the present disclosure.

1: Secondary battery cell charging/discharging gas removal device 11: 1st frame
12: second frame 100: charging unit
200: gas removal unit 210: vacuum frame
211: vacuum flow path 212: vacuum connection
213: insertion groove 214: guide member
220: vacuum part

Claims (7)

A base frame supporting a plurality of batteries;
a charging unit disposed above the base frame to fix the plurality of batteries and to charge the plurality of batteries; and
A gas removal unit disposed above the base frame to remove gas inside the plurality of batteries; includes,
The gas removal unit,
a vacuum frame integrally formed along a first direction and having a vacuum flow path disposed therein along the first direction; and
A vacuum unit connected to the vacuum frame to be movable up and down, selectively contacting a plurality of batteries to remove gas from the plurality of batteries, and having a vacuum opening disposed on a side surface;
The vacuum part,
a first position at which the vacuum opening and the vacuum passage are spaced apart; and
Move to a second position where the vacuum opening and the vacuum passage face each other;
inhaling the gas of the battery in the second position;
The vacuum part,
a body extending in a second direction perpendicular to the first direction;
an insertion part disposed at one end of the body and connected to a battery; and
Including; fixing protrusions protruding along the outer circumferential surface of the body,
the body,
a first body disposed in the insertion groove of the vacuum frame;
a second body disposed below the first body and disposed outside the vacuum frame; and
Including; an interference portion disposed between the first body and the second body,
The outer diameter of the first body is larger than the outer diameter of the second body,
The vacuum frame includes a guide member contacting the interference portion and supporting the first body to be disposed inside the vacuum frame,
The guide member includes a pair of guide protrusions protruding toward the second body,
The second body includes a pair of guide grooves formed along the longitudinal direction on the outer circumferential surface of the second body,
Each of the pair of guide protrusions is inserted into each of the pair of guide grooves to prevent the vacuum unit from rotating;
At the first position, the first body is disposed to directly face the vacuum frame. According to claim 1,
the body,
a first inflow passage formed with a first diameter along the longitudinal direction of the body; and
A second inlet passage disposed above the first inlet passage and formed with a second diameter smaller than the first diameter;
The vacuum opening is connected to the second inflow passage,
The vacuum passage has a secondary battery cell charging and discharging gas removal device having a third diameter smaller than the second diameter. delete delete According to claim 2,
The vacuum unit further includes an elastic member disposed between the fixing protrusion and the guide member,
The pair of guide grooves are disposed between the fixing protrusion and the guide member. According to claim 5,
The vacuum frame,
a guide frame into which the second body of the vacuum unit is inserted to stably guide the vertical movement of the vacuum unit; and
A vacuum connection part disposed at one end of the vacuum passage to maintain the inside of the vacuum passage in a vacuum state at the second position; further comprising,
The vacuum unit is a secondary battery cell charging and discharging gas removal device in which the insertion unit is disposed at one end of the vacuum unit and the other end opposite to the one end is blocked. According to claim 6,
a first frame;
a second frame disposed above the first frame and connected to the first frame;
a support frame disposed to be movable between the first frame and the second frame; and
A moving unit disposed between the second frame and the support frame to vertically move the support frame; further comprising,
The charging unit and the gas removal unit are connected to the second frame,
The base frame is supported on the support frame and moves up and down according to the up and down movement of the support frame.

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