KR102496786B1 - Gas removal device for secondary battery cell - Google Patents

Abstract

The present invention is a degassing device for a secondary battery cell, comprising: a battery-side opening at one side for inhaling electrolyte and electrolyte gas from a battery and injecting the degassed electrolyte; and a hollow pipe-type vacuum negative pressure nozzle including a first side opening connected to the hollow from the side on the other side thereof; and a hollow hole having a size and shape corresponding to the other side of the first side opening of the vacuum negative pressure nozzle, into which the other side of the first side opening of the vacuum nozzle is inserted to reciprocate. and a chamber including a second side opening formed on a side surface connected to the first side opening so as to be in fluid communication with the vacuum negative pressure nozzle in a state in which it is inserted into the hollow hole. do.

Description

Secondary battery cell gas removal device {GAS REMOVAL DEVICE FOR SECONDARY BATTERY CELL}

The present invention relates to a degassing device for a secondary battery cell, and more particularly, to a degassing device for a secondary battery cell capable of quickly and simply removing gas from a secondary battery cell.

Recently, interest in energy storage technology is increasing. As the field of application expands to mobile phones, camcorders, notebook PCs, and even medium-large sized batteries of electric vehicles, the demand for high energy density of batteries used as power sources for these electronic devices is increasing. A lithium secondary battery is a battery that can best satisfy these demands, and research on this is being actively conducted.

However, such a lithium secondary battery has safety problems such as ignition and explosion due to the use of an organic electrolyte, and has disadvantages in that manufacturing is difficult. In particular, recently, as the utilization range of lithium secondary batteries has been dramatically expanded, lithium secondary batteries have been used in various conditions and environments, and accordingly, the demand for higher capacity lithium secondary batteries is gradually increasing. In order to provide a high-capacity lithium secondary battery, the operating range of the electrode is gradually expanding, and moving to a high voltage can obtain benefits in terms of capacity, but safety issues have also been highlighted more than before.

In general, a lithium secondary battery is manufactured by performing an activation process in which a battery in a discharged state is initially charged. During the activation process, gas is generated inside the battery due to the generation of a passivation film on the surface of the negative electrode and the decomposition of moisture inside the battery. The gas generated in this way remains inside the battery and adversely affects the lifespan of the battery, such as generating lithium plating (Li plating). Therefore, the degassing process is performed during the activation process or after completion of the activation step.

A degassing device for a secondary battery cell is used to remove gas from a lithium secondary battery.

As such a device, Korean Patent Registration No. 10-0433836 and Korean Patent Publication No. 10-2018-0062835 have been filed. However, in these patents, the configuration of the device is complicated, and in removing the gas, the chamber is vacuumed to remove the gas, so the time to make the chamber vacuum and the vacuum state inside the chamber by injecting air after removing the gas There was a time-consuming problem to turn off.

Therefore, the problem to be solved by the present invention is to provide a degassing device for a secondary battery cell in which gas can be quickly and simply removed from a battery, the device can be simplified to make it easy to manufacture, and furthermore, the manufacturing cost of the device can be lowered. is in providing

Another object of the present invention is to provide a device for degassing a secondary battery cell in which a degassing process of an electrolyte solution of an individual vacuum negative pressure nozzle in an array of a plurality of vacuum negative pressure nozzles can be stably performed.

The present invention is a degassing device for a secondary battery cell, comprising: a battery-side opening at one side for inhaling electrolyte and electrolyte gas from a battery and injecting the degassed electrolyte; and a hollow pipe-type vacuum negative pressure nozzle including a first side opening connected to the hollow from the side on the other side thereof; and a hollow hole having a size and shape corresponding to the other side of the first side opening of the vacuum negative pressure nozzle, into which the other side of the first side opening of the vacuum nozzle is inserted to reciprocate. and a chamber including a second side opening formed on a side surface connected to the first side opening so as to be in fluid communication with the vacuum negative pressure nozzle in a state in which it is inserted into the hollow hole. do.

The vacuum negative pressure nozzle is inserted into the hollow hole and performs a reciprocating motion, wherein the first side opening and the second side opening are fluidly connected at one position of the reciprocating motion, and at another position of the reciprocating motion, the first side opening and the second side opening are fluidly connected. The first side opening and the second side opening have a release state in which the connection is released. In the connected state, negative pressure or positive pressure may be formed in the vacuum negative pressure nozzle through the second side opening, and pressure communication with the second side opening may be disconnected in the released state.

The battery-side opening is closely connected to the battery to suck the electrolyte inside the battery into the vacuum negative pressure nozzle or insert it into the battery from the vacuum negative pressure nozzle. After being in close contact with the battery through the opening, when the negative pressure is formed in the vacuum negative pressure nozzle through a pump or the like after the vacuum negative pressure nozzle is connected, the electrolyte of the battery is sucked into the vacuum negative pressure nozzle. At this time, the gas in the lighter battery is vented. Then, the degassed battery electrolyte is injected into the battery by positive pressure to the vacuum negative pressure nozzle.

The vacuum negative pressure nozzle may include: a first O-ring wound around an outer circumference of the first side opening; including a second O-ring wound around the inside of the first side opening, in the connected state, only fluid communication is possible between the second side opening and the vacuum negative pressure nozzle, and in the released state, the vacuum negative pressure nozzle and It is possible to completely block fluid communication with the inner hole in the chamber, which is the outside thereof.

The O-ring is characterized by a quarter ring and provides a positive sealing effect in reciprocating motion.

In the apparatus of the present invention, a circumference of the inlet of the hollow hole includes an annular jaw extending inwardly thereof, and an outer diameter of one side of the battery-side opening of the vacuum negative pressure nozzle has a size corresponding to an inner diameter of the annular jaw, An outer diameter of the other side of the first side opening of the vacuum negative pressure nozzle corresponds to an inner diameter of the hollow hole larger than an inner diameter of the annular jaw. According to this configuration, the one side is caught on the annular jaw and does not escape from the inner hole of the chamber.

And the length of the other side of the vacuum negative pressure nozzle having the outer diameter of the other side is shorter than the length from the inner side of the annular jaw to the second side opening, so that the release state is not hindered by the annular jaw and in the release state It can be caught on the annular jaw.

and an annular stop block on an outer surface of one side of the battery-side opening of the vacuum negative pressure nozzle. and a spring between the stop block and an outer surface of the annular jaw of the chamber. In a state in which the spring is not compressed, the other side of the vacuum negative pressure nozzle is caught on the annular jaw and placed in a release state. In a state in which the spring is compressed, the one side of the vacuum negative pressure nozzle is inserted into the inner hole and placed in a connected state.

A length from the other end of the vacuum negative pressure nozzle to the first side opening to be placed in a connected state is a length from a bottom surface of the hollow hole to the second side opening.

The battery-side opening includes a contact pad for adhering to the battery, so that the battery-side opening firmly adheres to the battery, and allows the electrolyte and gas of the electrolyte to be easily absorbed.

and a vacuum pump installed in the second side opening and generating negative pressure and positive pressure in the vacuum negative pressure nozzle through the second side opening and the first side opening connected thereto.

In one embodiment, the chamber has a long length in one direction, the hollow hole and the second side opening are arranged in plurality along the longitudinal direction of the chamber, and the vacuum negative pressure nozzle is inserted into each hollow hole and arranged; Each second side opening may be branched from and fluidly connected to a pipe or hose having a length equal to or greater than the length of the chamber, and each vacuum negative pressure nozzle may be configured to reciprocate individually.

According to the device for removing gas from a secondary battery cell according to the present invention, gas removal from a battery can be performed quickly and simply, the device is simplified to be easily manufactured, and furthermore, the manufacturing cost of the device can be reduced.

In addition, there is an advantage in that degassing of the electrolyte solution of individual vacuum negative pressure nozzles can stably proceed in an arrangement of a plurality of vacuum negative pressure nozzles.

1 is a perspective view for explaining the configuration of a degassing device of a secondary battery cell according to an embodiment of the present invention.
FIG. 2 is an enlarged perspective view of the vacuum negative pressure nozzle shown in FIG. 1 .
FIG. 3 is a partially enlarged view illustrating a state in which the vacuum negative pressure nozzle shown in FIG. 1 is in close contact with a battery.
FIG. 4 is a partially enlarged view of the vacuum negative pressure nozzle shown in FIG. 1 before rising.
FIG. 5 is a partially enlarged view showing a state of the vacuum negative pressure nozzle shown in FIG. 1 after being raised.
6 is a perspective view illustrating a state in which a plurality of vacuum negative pressure nozzles shown in FIG. 1 are arranged;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a degassing device of a secondary battery cell according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. Since the present invention can have various changes and various forms, specific embodiments will be illustrated in the drawings and described in detail in the text. However, it should be understood that this is not intended to limit the present invention to the specific disclosed form, and includes all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. Like reference numerals have been used for like elements throughout the description of each figure. In the accompanying drawings, the dimensions of the structures are shown enlarged than actual for clarity of the present invention.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. These terms are only 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 invention.

Terms used in this application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, terms such as "comprise" or "have" are intended to designate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, but one or more other features It should be understood that it does not preclude the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in the present application, they should not be interpreted in an ideal or excessively formal meaning. don't

1 is a perspective view for explaining the configuration of a degassing device of a secondary battery cell according to an embodiment of the present invention.

Referring to FIG. 1 , an apparatus for degassing a secondary battery cell according to an embodiment of the present invention may include a vacuum negative pressure nozzle 100 and a chamber 200 .

The vacuum negative pressure nozzle 100 is a component for substantially sucking an electrolyte and gas of the electrolyte from a battery, that is, a secondary battery cell.

The vacuum negative pressure nozzle 100 is provided in the form of a hollow pipe having a certain length and having a hollow 101 formed therein to accommodate the injected electrolyte and the gas of the electrolyte, and discharges the electrolyte and the gas of the electrolyte from the battery through the lower end. It may be configured to inject the suctioned and degassed electrolyte into the battery and discharge the gas of the suctioned electrolyte through the upper end. To this end, the vacuum negative pressure nozzle 100 may include a battery-side opening 111 and a first side opening 121 .

The battery-side opening 111 is a lower opening of the hollow 101 formed at the lower end of the hollow pipe, and is in close contact with one surface of the battery 10 to suck the electrolyte and the gas of the electrolyte from the battery 10, and After inhalation, the electrolyte from which the gas has been removed may be reinjected into the battery 10 .

The first side opening 121 is disposed on the other side of the battery side opening 111, that is, on the upper end side of the vacuum negative pressure nozzle 100, and may be connected to the hollow 101 from the side of the vacuum negative pressure nozzle 100. The first side opening 121 provides a passage for discharging the electrolyte and gas lighter than the electrolyte among gases sucked into the hollow 101 through the battery-side opening 111 to the outside of the hollow 101. can

The vacuum negative pressure nozzle 100 reciprocates up and down with the upper end, that is, the side of the first side opening 121 inserted into the chamber 200, so that the electrolyte and the gas of the electrolyte solution are injected and the gas is discharged. can be configured.

To operate the vacuum negative pressure nozzle 100, the chamber 200 may include a hollow hole 201 and a second side opening 202.

The hollow hole 201 may be configured to reciprocate the length of the first side opening 121 side of the vacuum negative pressure nozzle 100 while accommodating the length of the first side opening 121 side.

To this end, the length of the hollow hole 201 is longer than the length of the first side opening 121 side of the vacuum negative pressure nozzle 100, and the length of the first side opening 121 side of the vacuum negative pressure nozzle 100 may have a length capable of reciprocating up and down inside the hollow hole 201 .

Specifically, the circumference of the inlet of the hollow hole 201 may include the first annular jaw 203 extending inwardly thereof, and the outer diameter of the battery-side opening 111 side of the vacuum negative pressure nozzle 100. has a size corresponding to the first annular jaw 203, and the outer diameter of the length of the vacuum negative pressure nozzle 100 on the side of the first side opening 121 is larger than the inner diameter of the first annular jaw 203. It may have a size corresponding to the inner diameter of the hole 201 . Accordingly, an annular border is formed between the length of the first side opening 121 side and the length of the battery side opening 111 side, and the annular border can be caught and seated on the first annular jaw 203. .

Hereinafter, for convenience of explanation, the length portion on the side of the first side opening 121 is called "valve part 120", and the length on the side of the battery side opening 111 is called "nozzle part 110". , and the annular border will be described by naming the “second annular jaw 130”.

As each of these parts is named, in other words, the valve part 120 of the vacuum negative pressure nozzle 100 is fitted into the hollow hole 201 of the chamber 200 and inserted into the hollow hole 201. , It can reciprocate downward, and when the valve unit 120 is lowered, the second annular jaw 130 between the valve unit 120 and the nozzle unit 110 is caught on the first annular jaw 203 so that the valve unit 120 ) may be located in the hollow hole 201 without leaving the hollow hole 201.

Meanwhile, the chamber 200 may include a second side opening 202 penetrating the hollow hole 201 from the side of the chamber 200 .

The second side opening 202 is fluidly connected to the first side opening 121 at one position during the upward and downward reciprocating motion of the valve unit 120 of the vacuum negative pressure nozzle 100, thereby forming the vacuum negative pressure nozzle 100. It is possible to provide a passage through which gas of the electrolyte solution sucked in can be discharged.

To this end, the second side opening 202 is spaced apart from the first annular jaw 203 by a predetermined length. At this time, the length from the first annular jaw 203 to the second side opening 202 is from the second annular jaw 130 of the valve unit 120 of the vacuum negative pressure nozzle 100 to the first side opening 121. It can be set longer than the length of . For example, the length from the first annular jaw 203 to the second side opening 202 is from the second annular jaw 130 of the valve unit 120 of the vacuum negative pressure nozzle 100 to the end of the valve unit 120. It can be set longer than the length to. Accordingly, when the valve unit 120 of the vacuum negative pressure nozzle 100 descends in the hollow hole 201 so that the first annular jaw 203 and the second annular jaw 130 come into contact with each other, the first side opening 121 opens. can provide and secure an effective distance at which the fluid communication connection between the second side openings 202 can be released and the connection can be maintained even if the vacuum negative pressure nozzle 100 rises slightly.

In addition, the length from the bottom surface of the hollow hole 201, that is, the bottom surface on the opposite side of the first annular jaw 203 to the second side opening 202, is the length of the valve unit 120 of the vacuum negative pressure nozzle 100. It may have a length greater than or equal to the length from the opposite end of the second annular jaw 130 to the first side opening 121 . For example, the length from the bottom surface of the hollow hole 201 to the second side opening 202 is greater than the length from the end of the valve unit 120 of the vacuum negative pressure nozzle 100 to the first side opening 121. can be long

Meanwhile, the device for removing gas from a secondary battery cell according to an embodiment of the present invention may further include a first O-ring 301 and a second O-ring 302 .

The first O-ring 301 may be provided to wind around the valve part 120 between the outer side of the first side opening 121, that is, between the end of the valve part 120 and the first side opening 121. . The first O-ring 301 may be a quarter ring.

The second O-ring 302 may be provided to wind the circumference of the valve unit 120 between the inner side of the first side opening 121, that is, between the second annular jaw 130 and the first side opening 121. The second O-ring 302 may be a quarter ring.

Accordingly, the first O-ring 301 and the second O-ring 302 are disposed in the upper and lower directions of the first side opening 121 with the first side opening 121 interposed therebetween, and the first side opening ( 121) is connected to the second side opening 202 in fluid communication, it adheres to the inner surface of the hollow hole 201 and prevents gas leakage from the first side opening 121 and the second side opening 202. can be maintained

Meanwhile, the device for removing gas from a secondary battery cell according to an embodiment of the present invention may further include an annular stop block 400 and a spring 500.

The annular stop block 400 may be provided on one side of the battery-side opening 111 of the vacuum negative pressure nozzle 100 . That is, the annular stop block 400 may be disposed at one point of the nozzle unit 110 of the vacuum negative pressure nozzle 100 . For example, the annular stop block 400 may be an annular detachable block surrounding the circumference of the nozzle unit 110, and may be disposed close to the valve unit 120 and spaced apart from the chamber 200 by a predetermined distance. there is.

The spring 500 may be provided between the outer surface of the stop block 400 and the first annular jaw 203 of the chamber 200 facing the stop block 400 . The spring 500 is compressed when the vacuum negative pressure nozzle 100 is raised, and can return the raised vacuum negative pressure nozzle 100 to descend.

Meanwhile, the device for degassing a secondary battery cell according to an embodiment of the present invention may further include a vacuum pump 600, and the battery-side opening 111 of the vacuum negative pressure nozzle 100 may include a contact pad 140. can

The contact pad 140 may be coupled around the outer surface of the battery-side opening 111 of the vacuum negative pressure nozzle 100 and may include a suction port 141 coaxial with the battery-side opening 111 .

The vacuum pump 600 may be installed in the second side opening 202, and generates negative and positive pressure in the vacuum negative pressure nozzle 100 through the second side opening 202 and the first side opening 121 connected thereto. can form The vacuum pump 600 may be installed by connecting a pipe or hose so as to be in fluid communication with the second side opening 202 .

Hereinafter, a process of injecting the electrolyte solution after suctioning and removing the gas from the electrolyte solution and the electrolyte solution of the secondary battery cell using the degassing device of the secondary battery cell according to an embodiment of the present invention will be described.

To remove gas from the electrolyte, the valve unit 120 of the vacuum negative pressure nozzle 100 reciprocates up and down in the hollow hole 201 of the chamber 200, and at one position of the reciprocating movement, the first side opening ( 121) and the second side opening 202 are in a connected state in which fluid communication is possible, and in a disengaged state in which the first side opening 121 and the second side opening 202 are disconnected at different positions of the reciprocating motion becomes In the connected state, negative pressure or positive pressure may be formed in the vacuum negative pressure nozzle 100 through the second side opening 202, and pressure communication with the second side opening 202 may be disconnected in the released state.

Operation of the connection state

The battery-side opening 111 of the vacuum negative pressure nozzle 100 is closely connected to the battery 10 through the contact pad 140, and in this state, the vacuum pump 600 is driven to form negative pressure, and the battery 10 and the vacuum negative pressure nozzle 100 is raised. At this time, the spring 500 between the chamber 200 and the stop block 400 is compressed.

When the vacuum negative pressure nozzle 100 rises, the valve unit 120 of the vacuum negative pressure nozzle 100 inserted into the hollow hole 201 of the chamber 200 rises within the hollow hole 201 .

As the valve part 120 rises, the first side opening 121 of the valve part 120 opens at the position of the second side opening 202 of the hollow hole 201 of the chamber 200. ) and is fluidly connected to, and at this time, negative pressure is formed in the hollow 101 of the vacuum negative pressure nozzle 100 by the vacuum pump 600, and the first side opening 121 and the second side opening 202 The connection state is airtight by the first O-ring 301 and the second O-ring 302 having the first side opening 121 interposed therebetween.

When negative pressure is formed in the hollow 101 of the vacuum negative pressure nozzle 100, the electrolyte inside the battery 10 is sucked through the battery-side opening 111 of the vacuum negative pressure nozzle 100, and at this time, the gas of the electrolyte is also sucked. , Since the gas of the electrolyte is lighter than the electrolyte, it is sucked in faster than the electrolyte, and the gas of the inhaled electrolyte is discharged through the first side opening 121 and the second side opening 202 in a connected state.

When the gas of the electrolyte solution is discharged, a positive pressure is formed in the hollow 101 of the vacuum negative pressure nozzle 100 through the vacuum pump 600, and the positive pressure is formed to form a positive pressure in the hollow 101 of the vacuum negative pressure nozzle 100 from which the gas is removed. The electrolyte in ) is inserted into the battery 10.

Operation in the disconnected state

After degassing the electrolyte and inserting the electrolyte into the battery 10, the battery 10 and the vacuum negative pressure nozzle 100 are lowered. At this time, the compressed spring 500 is restored and pushes the stop block 400 so that the vacuum negative pressure nozzle 100 is lowered.

As the vacuum negative pressure nozzle 100 descends, the valve unit 120 descends in the hollow hole 201 of the chamber 200, and at this time, the first side opening 121 moves downward from the second side opening 202. Spaced apart, the first side opening 121 and the second side opening 202 are disconnected, and the second annular jaw 130 of the vacuum negative pressure nozzle 100 is connected to the first annular jaw 203 of the hollow hole 201. It descends to the position where it is caught in the valve part 120, and the end of the valve part 120 is located below the second side opening 202.

In this way, the entire length of the valve part 120 of the vacuum negative pressure nozzle 100 is located below the second side opening 202 in the hollow hole 201 of the chamber 200, so that the first side opening 121 ) and the second side opening 202 are disconnected, the pressure communication between the first side opening 121 and the second side opening 202 is disconnected, and in this state, the spring 500 moves the chamber 200 and It is located between the stop blocks 400 and can be maintained by pressing the vacuum negative pressure nozzle 100 downward.

Meanwhile, a degassing device for a secondary battery cell according to an embodiment of the present invention may be configured such that a plurality of vacuum negative pressure nozzles 100 are arranged along one direction.

That is, the chamber 200 has a long length in one direction, the hollow hole 201 and the second side opening 202 are arranged in plurality along the longitudinal direction of the chamber 200, and the vacuum negative pressure nozzle 100 is each Arranged to be inserted into the hollow hole 201, each second side opening 202 is branched from a pipe or hose having a length equal to or longer than the length of the chamber 200 and is fluidly connected, and each vacuum negative pressure nozzle 100 ) may be configured to individually reciprocate.

The device for degassing a secondary battery cell according to an embodiment of the present invention reciprocates the vacuum negative pressure nozzle 100 up and down, and at this time, the negative pressure and the positive pressure are applied to remove gas from the electrolyte and inject the electrolyte into the battery. Therefore, there is an advantage in that gas removal from the battery is performed quickly and simply.

In addition, in addition to the chamber 200 and the vacuum negative pressure nozzle 100, a separate valve-shaped structure for opening and closing the hollow 101 of the vacuum negative pressure nozzle 100 accommodating the electrolyte from the battery 10 and the gas of the electrolyte solution is provided. Since the hollow 101 of the vacuum negative pressure nozzle 100 is opened and closed by the connection of the first side opening 121 and the second side opening 202, the device is simplified and manufacturing is easy, furthermore, the manufacturing cost of the device is reduced. There is an advantage that can be lowered.

In addition, even if the vacuum negative pressure nozzle 100 rises slightly, an effective distance at which disconnection can be maintained is provided and secured, so that the vacuum negative pressure nozzle 100 is easily affected by an external impact applied from the bottom to the top of the vacuum negative pressure nozzle 100. This has the advantage of not being opened, and furthermore, in the process of degassing the electrolyte of the battery 10 by individually operating one of the plurality of vacuum negative pressure nozzles 100, another vacuum negative pressure nozzle 100 is opened due to an error. There is an advantage in that the degassing process of the electrolyte solution of the individual vacuum negative pressure nozzle 100 can be stably performed without problems such as a decrease in negative pressure.

The description of the presented embodiments is provided to enable any person skilled in the art to use or practice the present invention. Various modifications to these embodiments will be apparent to those skilled in the art, and the general principles defined herein may be applied to other embodiments without departing from the scope of the present invention. Thus, the present invention is not to be limited to the embodiments presented herein, but is to be construed in the widest scope consistent with the principles and novel features presented herein.

Claims (10)

On one side, a battery-side opening for inhaling electrolyte and electrolyte gas from the battery and injecting the electrolyte from which the gas has been removed; and a hollow pipe-type vacuum negative pressure nozzle including a first side opening connected to the hollow from the side on the other side thereof; and
a hollow hole having a size and shape corresponding to the other side of the first side opening of the vacuum negative pressure nozzle; And a chamber including a second side opening formed on the side,
The other side of the vacuum negative pressure nozzle is fitted and inserted into the hollow hole to reciprocate,
At a position during the reciprocating motion of the vacuum negative pressure nozzle, the second side opening is connected in fluid communication with the first side opening.
Degassing device of secondary battery cell. According to claim 1,
The vacuum negative pressure nozzle may include: a first O-ring wound around an outer circumference of the first side opening; And characterized in that it comprises a second O-ring wound around the inside of the first side opening,
Degassing device of secondary battery cell. According to claim 2,
Characterized in that the O-ring is a quarter ring,
Degassing device of secondary battery cell. According to claim 1,
The circumference of the inlet of the hollow hole includes an annular jaw extending inwardly thereof,
An outer diameter of one side of the battery-side opening of the vacuum negative pressure nozzle has a size corresponding to an inner diameter of the annular jaw,
An outer diameter of the other side of the side opening of the vacuum negative pressure nozzle corresponds to an inner diameter of the hollow hole larger than an inner diameter of the annular jaw,
Degassing device of secondary battery cell. According to claim 4,
Characterized in that the length from the border between the inside and the other side of the vacuum negative pressure nozzle to the first side opening is shorter than the length from the inside of the annular jaw to the second side opening.
Degassing device of secondary battery cell. According to claim 5,
an annular stop block on an outer surface of one side of the battery-side opening of the vacuum negative pressure nozzle; and
Including a spring between the stop block and the outer surface of the annular jaw of the chamber,
Degassing device of secondary battery cell. According to claim 1,
Characterized in that the length from the other end of the vacuum negative pressure nozzle to the first side opening is the length from the bottom surface of the hollow hole to the second side opening,
Degassing device of secondary battery cell. According to claim 1,
The battery-side opening includes a contact pad for contact with the battery.
Degassing device of secondary battery cell. According to claim 1,
A vacuum pump installed in the second side opening and forming negative pressure and positive pressure in the vacuum negative pressure nozzle through the second side opening and the first side opening connected thereto,
Degassing device of secondary battery cell. According to claim 1,
The chamber has a long length in one direction,
The hollow hole and the second side opening are arranged in plurality along the longitudinal direction of the chamber,
The vacuum negative pressure nozzles are inserted and arranged in each hollow hole,
each second side opening is connected in fluid communication with a branch from a pipe or hose having a length greater than or equal to the length of the chamber;
Characterized in that each vacuum negative pressure nozzle is configured to reciprocate individually,
Degassing device of secondary battery cell.

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