KR20240050265A - Device for withstand pressure evaluation of secondary battery and method for withstand pressur evaluation - Google Patents

Abstract

The present invention relates to a device for evaluating the internal pressure of a secondary battery and a method for evaluating the internal pressure of a secondary battery using the same. The purpose of the present invention is to ensure the stability of the product by evaluating the internal pressure of the pouch constituting the secondary battery.
An apparatus for evaluating the internal pressure of a secondary battery according to the present invention includes a storage portion having a storage space in which the secondary battery is stored; a spacer that adsorbs one side of the secondary battery and then pulls it to form a space inside the secondary battery; an injection unit that pierces the secondary battery with a needle installed in the spaced portion and has an air injection passage formed therein, and injects air at positive pressure into the internal space of the secondary battery through the air injection passage; and a pressure measuring unit that measures air pressure in a space connected to the air injection path.
The device for evaluating the internal pressure of a secondary battery according to the present invention includes the steps of: (a) forming a space inside the secondary battery by adsorbing and pulling at least one side of the secondary battery stored in the storage unit; (b) punching the secondary battery with a needle having an air injection passage formed therein, and then having an air supply unit inject air into the interior of the secondary battery through the air injection passage; and (c) measuring the air pressure in the air injection passage using a pressure measuring unit.

Description

Secondary battery internal pressure evaluation device and secondary battery internal pressure evaluation method using the same {DEVICE FOR WITHSTAND PRESSURE EVALUATION OF SECONDARY BATTERY AND METHOD FOR WITHSTAND PRESSUR EVALUATION}

The present invention relates to a device for evaluating the withstand pressure of a secondary battery and a method for evaluating the withstand pressure of a secondary battery using the same. More specifically, it relates to a secondary battery that can ensure the stability of the product by evaluating the withstand pressure of the pouch constituting the secondary battery. It relates to an internal pressure evaluation device and a method for evaluating the internal pressure of a secondary battery using the same.

In general, secondary batteries refer to batteries that can be charged and discharged, unlike primary batteries that cannot be recharged, and are widely used in electronic devices such as mobile phones, laptop computers, camcorders, and electric vehicles.

In particular, lithium secondary batteries have a larger capacity than nickel-cadmium batteries or nickel-hydrogen batteries, which are widely used as power sources for electronic equipment, and their use is rapidly increasing due to their high energy density per unit weight. .

Lithium secondary batteries mainly use lithium-based oxide and carbon materials as positive and negative electrode active materials, respectively.

A lithium secondary battery includes an electrode assembly in which a positive electrode plate and a negative electrode plate each coated with a positive electrode active material and a negative electrode active material are disposed with a separator in between, and an exterior material, that is, a battery case, that seals and stores the electrode assembly together with an electrolyte solution.

Depending on the shape of the exterior material, these lithium secondary batteries can be classified into a can-type secondary battery in which the electrode assembly is built into a metal can, and a pouch-type secondary battery in which the electrode assembly is built into a pouch of an aluminum laminate sheet.

During the manufacturing process of a pouch-type secondary battery, an electrode assembly including a cathode, separator, and anode is placed into the pouch exterior material, electrolyte is injected, and the edges are sealed. Next, the battery is activated through several charge and discharge cycles.

During this process, gas is generated inside the cell. In order to collect the gas generated at this time, the size of the pouch exterior material of the pouch-type secondary battery before the activation process is formed to be larger than that of the final product.

A portion of the pouch exterior material that is larger than the portion where the electrode assembly is placed is referred to as a gas pocket portion, and gas generated during the activation process may be collected in this gas pocket portion.

After the activation process is completed, a hole is made in the gas pocket to remove the gas, then the gas pocket is cut and the pouch exterior material is resealed to meet the final product specifications.

Meanwhile, pouches for secondary batteries have different pressure resistance depending on their material, manufacturing size, etc. of the secondary battery. This internal pressure is proportional to the sealing force of the pouch.

And, in foreign batteries, sealing force is proportional to safety. If the sealing force is weak or defective, it can lead to a fire, resulting in property loss and casualties.

Public Patent Publication No. 10-2010-0118394

The present invention was developed to solve the problems of the prior art described above, and the sealing force can be confirmed by evaluating the internal pressure of the pouch constituting the secondary battery, thereby ensuring the stability of the product. The purpose is to provide a pressure evaluation device and a method for evaluating the internal pressure of a secondary battery using the same.

An apparatus for evaluating the internal pressure of a secondary battery according to the present invention includes a storage portion having a storage space in which the secondary battery is stored; a spacer that adsorbs one side of the secondary battery and then pulls it to form a space inside the secondary battery; an injection unit that pierces the secondary battery with a needle installed in the spaced portion and has an air injection passage formed therein, and injects air at positive pressure into the internal space of the secondary battery through the air injection passage; and a pressure measuring unit that measures air pressure in a space connected to the air injection path.

And, the storage unit is a storage body in which a first support plate supporting one side of the secondary battery and the storage space are formed, and first expansion allowance holes for allowing expansion of the secondary battery are formed on both sides of the first support plate, respectively. wealth; And a second support plate is formed to open and close the storage space of the storage body, and supports the secondary battery on the opposite side of the secondary battery to which the first support plate contacts, and the first expansion allowance hole is provided on both sides of the second support plate. They each include a cover portion that faces each other and has a second expansion-allowing hole that allows expansion of the secondary battery.

Additionally, a lifting hole through which the spaced portion is raised and lowered is formed in the cover portion.

And, the spacer includes a lifting block in which a moving guide hole guides the movement of the needle and at least one suction hole is formed to apply an adsorption force to the secondary battery; An adsorption unit coupled to the lifting block and facing the secondary battery, connected to the movement guide hole and including a first connection hole through which the needle passes and a second connection hole connected 1:1 with the intake hole; a moving drive unit that moves the lifting block so that the needle moves closer to or farther away from the secondary battery while allowing the adsorption unit to contact or separate from the secondary battery; and a suction control unit connected to the suction hole and adsorbing the secondary battery to the suction unit through air suction when the adsorption unit contacts the secondary battery.

Additionally, the suction unit may include a first suction ring coupled to the lifting block and having the first connection hole formed thereon; And it is coupled to the lifting block, is arranged to form a concentric circle with the first suction ring, and is formed to have a larger diameter than the first suction ring, so that the first suction ring is located in the internal space, and the second connection hole is It includes a second suction ring formed.

And, the injection unit includes a housing in which a predetermined area of the needle is accommodated and a third connection hole connected to the air injection path is formed; an air supply unit supplying air to the air injection passage through the third connection hole; and a needle driving unit that moves the housing in the direction of the secondary battery so that the needle pierces the secondary battery.

In addition, it is mounted on the outer periphery of the housing to be spaced apart from each other, and further includes a plurality of packing parts whose outer periphery is in close contact with the inner periphery of the spaced portion.

And, when the air supply unit is not in operation, the pressure in the space between the inside of the pouch, the outside of the needle, and the packing unit is maintained at atmospheric pressure.

In addition, it is installed in the storage unit and further includes an adsorption unit that adsorbs and fixes the secondary battery on the opposite side of the secondary battery that the spacer is in contact with.

A method for evaluating the withstand pressure of a secondary battery according to an embodiment of the present invention includes the steps of: (a) forming a space inside the secondary battery by adsorbing and pulling the spacer on at least one side of the secondary battery stored in the storage unit; (b) punching the secondary battery with a needle having an air injection passage formed therein, and then having an air supply unit inject air into the interior of the secondary battery through the air injection passage; and (c) measuring the air pressure in the air injection passage using a pressure measuring unit.

In addition, the method further includes the step of adsorbing the secondary battery on the opposite side of the secondary battery to which the spacer is in contact, with an adsorption unit installed in the receiving unit before or after step (a).

And, step (b) includes: (b1) moving the needle and inserting it into the secondary battery; and (b2) when the needle is inserted into the secondary battery, the air supply unit operates to inject air into the arch battery.

The device for evaluating the internal pressure of a secondary battery according to the present invention and the method for evaluating the internal pressure of a secondary battery using the same can confirm the sealing force by evaluating the internal pressure of the pouch constituting the secondary battery, thereby ensuring the stability of the product. There is a possible effect.

1 is a perspective view showing a device for evaluating the internal pressure of a secondary battery according to an embodiment of the present invention.
Figure 2 is a perspective view showing the cover portion in an open state in the device for evaluating the internal pressure of a secondary battery according to an embodiment of the present invention.
Figure 3 is a cross-sectional view showing a device for evaluating the internal pressure of a secondary battery according to an embodiment of the present invention.
4 to 8 are cross-sectional views showing step by step the process of evaluating the internal pressure of a secondary battery through an internal pressure evaluation device of a secondary battery according to an embodiment of the present invention.
Figure 9 is a graph measuring the internal pressure of a secondary battery using the internal pressure evaluation device of the secondary battery according to an embodiment of the present invention.

The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms. The present embodiments are merely provided to ensure that the disclosure of the present invention is complete and to be understood by those skilled in the art It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings so that those skilled in the art can easily implement the present invention. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein. Throughout the specification, similar parts are given the same reference numerals.

Figure 1 is a perspective view showing a device for evaluating the withstand pressure of a secondary battery according to an embodiment of the present invention, and Figure 2 is a perspective view showing a state in which the cover portion is open in the device for evaluating the withstand pressure of a secondary battery according to the present invention. Figure 3 is a cross-sectional view showing a device for evaluating the withstand pressure of a secondary battery according to the present invention, and Figures 4 to 8 show step-by-step the process of evaluating the withstand pressure of a secondary battery through the device for evaluating the withstand pressure of a secondary battery according to the present invention. It is a cross-sectional view shown as .

The internal pressure evaluation device 1 of a secondary battery according to the present invention is a product that can ensure the stability of the product by evaluating the internal pressure of the pouch 60 constituting the secondary battery.

At this time, the pouch 60 may largely include a cell body 61 and a cell pocket 62. The cell body 61 and the cell pocket 62 can be formed as one body by sealing the edges of the first surface 62a and the second surface 62b, which are formed of the same material and size.

Additionally, electrode tabs are coupled to one side and the other side of the cell body 61 through sealing, respectively.

Furthermore, the cell body 61 accommodates the electrode assembly and the electrolyte inside, and the cell pocket 62 is used to remove gas present inside the cell body 61.

In the present invention, the cell pocket 62 can also be used to inject air into the cell body 61.

In the present invention, the internal pressure can also be evaluated by injecting air into the cell body 61.

In this way, the internal pressure evaluation device of a secondary battery according to the present invention for evaluating the internal pressure of a secondary battery includes a receiving part 10, a spacing part 20, an injection part 30, and an adsorption part ( 113) and may include at least one of the pressure measuring unit 40.

The storage unit 10 may include at least one of the storage body 11 and the cover 12.

The upper surface of the storage body 11 is open and a storage space in which the secondary battery is stored is formed therein.

A first support plate 111 is formed in the storage space of the storage body 11 to jointly support the bottom of the cell body 61 and the cell pocket 62.

The first support plate 111 may form the bottom surface of the storage body 11.

The width of the first support plate 111 is formed to be shorter than the width of the storage body 11.

Accordingly, first expansion allowance holes 112 are formed on both sides of the first support plate 111 to allow expansion of the cell body 61 and the cell pocket 62, respectively.

At this time, both edge portions of the cell body 61 and the cell pocket 62 protrude to both sides of the first support plate 111 and are located above the first expansion allowance hole 112, respectively.

The cover portion 12 may be formed in a substantially rectangular frame shape.

The cover portion 12 is formed with a second support plate 121 that jointly presses and supports the upper surfaces of the cell body 61 and the cell pocket 62 on the opposite side of the pouch 60 where the first support plate 111 is in contact. do.

One edge of the cover part 12 is hinged to one edge of the storage body 11.

Accordingly, the cover portion 12 can be rotated in the up and down directions based on the hinge.

When the cover part 12 is rotated upward, the second support plate 121 opens the upper surface opening of the storage body 11, and when rotated downward, it is seated on the upper surface of the storage body 11. , Accordingly, the second support plate 121 jointly presses and supports the upper surfaces of the cell body 61 and the cell pocket 62.

At this time, the drawing shows an example in which the first surface 62a is seated on the upper surface of the first support plate 111 and the second surface 62b is pressed against the second support plate 121.

The width of the second support plate 121 is formed to be shorter than the width of the cover portion 12.

Accordingly, second expansion allowance holes 122 are formed on both sides of the second support plate 121 to allow expansion of the cell body 61 and the cell pocket 62, respectively.

When the cover part 12 is rotated downward and seated on the upper surface of the storage main body 11, the upper open portion of the storage main body 11 is closed.

And, when the cover portion 12 closes the open portion of the storage body portion 11, the second expansion allowance holes 122 are positioned above the first expansion allowance holes 112, respectively.

Accordingly, both edge portions of the cell body 61 and the cell pocket 62 are positioned between the first expansion permitting hole 112 and the second expansion permitting hole 122, and the electrode tab is also positioned between the first expansion permitting hole 122. It is located between (112) and the second expansion allowance hole (122), respectively.

Additionally, a lifting hole 123 through which the spaced part 20 is raised and lowered is formed in the cover part 12.

That is, the lifting hole 123 guides the lifting and lowering of the spaced part 20.

The above-described cover portion 12 can be maintained in close contact with the storage body portion 11 through a toggle clamp (not shown). Through this toggle clamp, it is possible to prevent the cover portion 12 from being artificially opened during the process of evaluating the internal pressure of the secondary battery pouch 60.

At this time, a plurality of toggle lamps may be applied to stably prevent artificial opening of the cover portion 12.

The spacer 20 is configured to adsorb one side of the pouch 60 and then pull it to form a space inside the pouch 60. At this time, the spacer 20 can pull the second side 62b of the cell body 61 or the cell pocket 62 from the pouch 60, and in the drawing, the second side 62b of the cell pocket 62 is shown. An example of application to the cover portion 12 to pull is shown.

This spacing unit 20 may include at least one of the lifting block 21, the adsorption unit, the movement driving unit 24, and the suction control unit 25.

The lower part of the lifting block 21 is accommodated in the lifting hole 123, and the remaining part protrudes upward from the cover part 12.

The lifting block 21 is raised and lowered on the lifting hole 123 by a moving drive unit 24, which will be described later.

A moving guide hole 211 is formed in approximately the center of the lifting block 21 to guide the lifting and lowering of the needle 34, which will be described later.

In addition, an intake hole 212 is formed in the lifting block 21 and is spaced apart from the moving guide hole 211 at a predetermined distance.

At least one intake hole 212 may be formed at regular intervals to sufficiently apply intake force to the second surface 62b.

On the bottom of the lifting block 21, a first fixing groove 213 and a second fixing groove 214, to which the first suction ring 22 and the second suction ring 23 are respectively fixed, are formed in spaces defined from each other. .

The first fixing groove 213 and the second fixing groove 214 are arranged in a concentric circle, and the diameter of the first fixing groove 213 is smaller than the diameter of the second fixing groove 214.

A lifting plate (26a) is coupled to the upper side of the lifting block (21).

The lifting plate 26a may include a hollow into which the upper part of the lifting block 21 is inserted.

Accordingly, the lifting plate 26a is coupled to surround the upper side of the lifting block 21.

Elevating bars 26b are disposed on one side and the other side of the elevating plate 26a, and at least one elevating body 26c is provided on the bottom of the elevating bar 26b, the upper and lower surfaces of which are open and an empty space is formed inside. is formed

The drawing shows an example in which two lifting bodies 26c are formed on each lifting bar 26b.

Additionally, a through hole (not shown) is formed in the lifting bar 26b, which is arranged perpendicular to the empty space inside the lifting body 26c.

Elevating guides 26d, which are each accommodated in empty spaces inside the elevating body 26c and are shaped like pins, are formed on the upper surface of the cover portion 12.

There are four lifting guides 26d and they are applied 1:1 to the lifting body 26c.

Accordingly, the lifting member 26c is guided by the lifting guide 26d and lifted up and down by the operation of the moving drive unit 24, which will be described later. Due to this, the lifting bar 26b, the lifting plate 26a, the lifting block 21, and the needle 34, which will be described later, are lifted together. At this time, the needle 34 pierces the second surface 62b of the pouch 60 when it is lowered, and is spaced upward from the second surface 62b when it rises.

Meanwhile, the adsorption unit is coupled to the lifting block 21 and faces the pouch 60.

The adsorption unit prevents air from leaking by adsorbing the second surface (62b) during the internal pressure measurement process of the pouch, and may include at least one of the first adsorption ring 22 and the second adsorption ring 23. there is.

The first suction ring 22 and the second suction ring 23 allow the second surface 62b to be adsorbed through interaction during the process of measuring the internal pressure of the pouch.

The first suction ring 22 is inserted into and fixed to the first fixing groove 213.

The lower portion of the first suction ring 22 may protrude out of the first fixing groove 213 and come into contact with the second surface 62b.

The first suction ring 22 is formed in a ring shape and is connected to the moving guide hole 211 in the center, and a first connection hole 221 through which the needle 34 passes is formed.

The second suction ring 23 is inserted into and fixed to the second fixing groove 214.

The lower part of the second suction ring 23 may protrude outside the second fixing groove 214 and come into contact with the second surface.

At this time, the second suction ring 23 may protrude to the same length as the first suction ring 22.

The second suction ring 23 is formed in a ring shape with a larger diameter than the first suction ring 22.

Accordingly, the first suction ring 22 is located inside the second suction ring 23, and the first suction ring 22 and the second suction ring 23 are arranged to form concentric circles with each other.

At this time, the inner periphery of the second suction ring 23 and the outer periphery of the first suction ring 22 are spaced apart from each other.

In addition, a second connection hole 231 connected to the above-described intake hole 212 is formed between the second suction ring 23 and the first suction ring 22, that is, inside the second suction ring 23. do.

At this time, although this is not necessarily the case, the width of the intake hole 212 may be formed to be smaller than the width of the second connection hole 231.

At this time, the device for evaluating the internal pressure of a secondary battery according to an embodiment of the present invention includes both the first suction ring 22 and the second suction ring 23, or the first suction ring 22 and the second suction ring 23. It can be manufactured in a form containing only one of (23).

In addition, when only one of the first suction ring 22 and the second suction ring 23 is included, a first connection hole is formed in the center of the first suction ring 22 or the second suction ring 23, A second connection hole is formed around the first connection hole.

At this time, the second connection holes are used in the same number as the intake holes and are located on a vertical line with the intake holes.

The moving drive unit 24 is fixed to the upper surface of the cover unit 12.

The moving drive unit 24 may be formed of any one selected from a pneumatic cylinder, a hydraulic cylinder, or a cam, and an example formed of a pneumatic cylinder is shown in the drawing.

The piston of the moving drive unit 24 is coupled to the bottom of the lifting plate 26a.

As pneumatic pressure is injected or discharged from the moving drive unit 24, the piston rises or falls.

When the piston of the moving drive unit 24 rises, the lifting plate 26a, the lifting bar 26b, the lifting body 26c, the lifting block 21, the first suction ring 22, and the second suction ring (23) is raised uniformly, and the first suction ring (22), the second suction ring (23), and the needle (34) move away from the second surface (62b).

And, when the piston of the moving drive unit 24 is lowered, the lifting plate 26a, the lifting bar 26b, the lifting body 26c, the lifting block 21, the first suction ring 22, and the 2 The suction ring (23) and needle (34) are lowered uniformly. At this time, the first suction ring 22, the second suction ring 23, and the needle 34 approach the second surface 62b when they are lowered.

The suction control unit 25 absorbs a certain area of the second surface 62b in the space between the first suction ring 22 and the second suction ring 23, and is a known product with a pump or air suction function. can be formed.

The suction control unit 25 has a pair of suction hoses 25a provided therein and are connected 1:1 to the intake holes 212 at the upper side of the lifting block 21. By the operation of the moving drive unit 24, the first suction ring 22 and the second suction ring 23 are lowered and come into contact with the second surface (62b), and the needle 34 pierces the second surface (62b). After this, air is injected into the inner space of the cell pocket 62 to expand it, and the suction control unit 25 operates to suction air.

When the suction control unit 25 operates to suction air, a certain area of the second surface 62b of the expanded cell pocket 62 is inserted into the connection hole of the first suction ring 22, and the area of the second surface 62b of the expanded cell pocket 62 is inserted into the connection hole of the first suction ring 22. Another certain area is inserted into the space between the first suction ring 22 and the second suction ring 23 and is adsorbed to maintain airtightness.

In addition, air may leak through the pierced portion of the second surface 62b, but the first suction ring 22 primarily prevents air leakage from the inside of the second suction ring 23 and (23) prevents secondary air leakage from the outside of the first suction ring (22).

At this time, when the second surface 62b is adsorbed in the space between the first suction ring 22 and the second suction ring 23, the piston of the moving drive unit 24 can be programmed to gradually rise. As a result, the lifting plate 26a, the lifting bar 26b, the lifting body 26c, the lifting block 21, the first suction ring 22, and the second suction ring 23 are raised simultaneously. The second side (62b) is spaced apart from the first side (62a).

Meanwhile, the injection unit 30 injects air into the inner space of the cell pocket 62 when the first surface 62a and the second surface 62b are separated by the spacer 20, and the needle ( 34), a housing 31, a needle drive unit 33, and an air supply unit 32.

The needle 34 is configured to pierce the second surface 62b. The needle 34 has a shape similar to a syringe needle, and its inner space is used as an air injection path for injecting air into the inner space of the cell pocket 62.

Packing parts 50 are installed on the outer periphery of the needle 34 at regular intervals to maintain airtightness.

The packing part 50 is accommodated in the moving guide hole 211 of the lifting block 21 and its peripheral surface is in close contact with the inner peripheral surface of the lifting block 21. As a result, even if the air injected into the cell pocket 62 leaks out and enters the moving guide hole of the lifting block 21, the packing part 50 blocks the air to prevent it from leaking out to the outside through the moving guide hole 211. can do.

At this time, the packing part 50 may be mounted on the outer periphery of the housing 31 instead of the needle 34, or may be mounted on the needle 34 and the housing 31, respectively.

The housing 31 is accommodated in the moving guide hole 211.

The housing 31 has an accommodating space inside which the upper portion of the needle 34 is accommodated.

Inside the housing 31, a third connection hole 311 connected to the air injection path is formed in the vertical direction.

Air can be injected into the air injection passage through the third connection hole 311.

The needle driving part 33 is fixed to the upper surface of the cover part 12.

The needle drive unit 33 may be formed of any one of a pneumatic cylinder, a hydraulic cylinder, and a cam, and an example formed of a pneumatic cylinder is shown in the drawing.

The piston of the needle drive unit 33 is coupled to the lifting plate 26a.

Accordingly, as pneumatic pressure is injected or discharged from the needle drive unit 33, the piston rises or falls, which causes the lifting block 21, the housing 31, and the needle 34 to rise or fall uniformly.

Also, when the needle 34 is lowered, it pierces the second surface 62b so that a portion of the lower area is accommodated in the inner space of the cell pocket 62.

The air supply unit 32 is installed on the upper surface of the cover unit 12.

The air supply unit 32 may be formed of a product such as a pump or an air compressor with an air injection function.

The air supply unit 32 has its own injection line 321 connected and installed on the upper side of the third connection hole 311, and pierces the second surface 62b of the needle 34 to form the cell pocket 62. Once accommodated inside, air is supplied to the injection line 321 at positive pressure.

At this time, the air supplied to the injection line 321 is injected into the space between the first surface 62a and the second surface 62b through the third connection hole 311 and the air injection path of the needle 34.

At this time, the injection line 321 may be formed of any one of a pipe, piping, or hose.

Additionally, a pneumatic regulator 2 may be installed in the injection line 321 to set and control the air pressure.

At this time, even if the spacer 20 separates the second surface 62b from the first surface 62a and the needle 34 pierces the second surface 62b, if the air supply unit 32 does not operate In the inner space of the pouch 60 and the space between the outside of the needle 34 and the packing part 50, atmospheric pressure is maintained so that gas, electrolyte, air, etc. inside the pouch 60 do not leak to the outside.

The adsorption unit 113 is embedded in the storage body 11, and its upper surface faces the bottom of the first surface 62a of the cell main body 61 or the cell pocket 62.

The suction part 113 has an upper-lower narrow shape like a general suction plate or hopper.

The upper and lower surfaces of the adsorption unit 113 are open and a suction space is formed inside.

The lower side of the adsorption portion 113 protrudes toward the lower side of the storage body portion 11.

At least one adsorption unit 113 may be applied, and one vacuum suction pipe 114 is connected to the bottom opening.

Additionally, a product such as a pump (not shown) or an air compressor with an air suction function (not shown) is connected to the vacuum suction pipe 114 via the suction pipe 114.

The adsorption portion 113 may be made of any one of silicone, rubber, and soft synthetic resin materials so that it can be adsorbed while being in close contact with the first surface 62a.

The pump or product performs a suction operation before the spacer 20 pulls the second side 62b so that the first side 62a is adsorbed on the adsorption section 113.

Accordingly, when the spacer 20 operates, the second surface 62b is spaced apart from the first surface 62a, thereby forming a space into which air can be injected into the pouch 60.

The pump, product, and vacuum suction pipe 114 may be moved up and down by a cylinder (not shown) or a cam.

Due to this, the adsorption unit 113 is also raised and lowered, and when the adsorption unit 113 is raised, the upper portion contacts and adsorbs the first surface 62a seated on the upper surface of the first support plate 111.

And, when the adsorption unit 113 is lowered, it is hidden in the internal space of the storage body 11 and is spaced apart from the first surface 62a.

The pressure measuring unit 40 is applied as a general product that can measure pressure, such as a pressure gauge.

The pressure measuring unit 40 is installed in the injection line 321 and measures the pressure of air flowing along the injection line 321 or the internal pressure of the injection line 321.

The injection line 321 is connected to the third connection hole 311, and the third connection hole 311 is connected to the air injection path of the needle 34, so that the pressure measuring unit 40 is a space connected to the air injection path. The pressure of air injected into the inside of the pouch 60 can be measured.

Next, a method for evaluating the withstand pressure of a secondary battery using the withstand pressure evaluation device 1 of the secondary battery described above will be described with reference to FIGS. 4 to 8 .

First, the pouch 60 is stored in the storage space of the storage body 11, and then the cover 12 is closed to close the storage space.

At this time, the first surface 62a is supported by the first support plate 111, and the second surface 62b faces the second support plate 121.

In addition, the edge of the cell body 61 and the edge of the cell pocket 62 and both electrode tabs installed on the edge are exposed and positioned on the first expansion allowance hole 112 and the second expansion allowance hole 122. This puts the injection unit 30 in a state where it can expand during operation.

At this time, the edge areas on both sides of the cell body 61 where the electrode tabs are located may be subject to a pressure resistance test because the sealing strength is weaker than other areas.

Afterwards, (a) the spacer 20 adsorbs one side of the pouch 60 stored in the storage unit 10 and then pulls it to form a space inside the pouch 60.

To explain this in more detail, the moving drive unit 24 lowers the lifting block 21 so that the first suction ring 22 and the second suction ring 23 contact the second surface 62b, as shown in FIG. I order it.

Subsequently, when the first suction ring 22 and the second suction ring 23 come into contact with the second surface 62b, the suction control unit 25 absorbs the second surface 62b to the suction ring through air suction. .

Afterwards, as shown in FIG. 6, the movement driving unit 24 raises the lifting block 21 to space the second surface 62b above the first surface 62a, thereby creating a space inside the pouch 60. is formed.

At this time, the suction part 113 is in a state of adsorbing the first surface (62a) before or after the first suction ring 22 and the second suction ring 23 are in contact with the second surface (62b). maintain

The suction part 113 adsorbs and supports the first surface (62a), so that when the first suction ring 22 and the second suction ring 23 rise after adsorbing the second surface (62b), It is possible to prevent the first side (62a) from rising.

Afterwards, (b) the second surface 62b is punched with the needle 34, and then air is supplied to the inner space of the cell pocket 62 and the cell body 61 through the air supply unit 32.

To explain this in more detail, the needle 34 is lowered by the needle driving unit 33 as shown in FIG. 7 and a portion of the needle 34 penetrates the second surface 62b and enters the inner space of the cell pocket 62.

And, at the same time, the air supply unit 32 operates. Air from the air supply unit 32 is sequentially injected into the interior of the cell pocket 62 through the third connection hole 311 and the air injection path.

At this time, the air supply unit 32 supplies air to the inside of the cell pocket 62 at a positive pressure.

Since the inner space of the cell pocket 62 and the inner space of the cell body 61 are connected to each other, the air supplied to the cell pocket 62 also fills the cell body 61. Accordingly, the cell body 61 and the cell pocket 62 are expanded as shown in FIG. 8.

At this time, the portion of the cell body 61 supported by the first support plate 111 and the second support plate 121 is expanded below a predetermined level or is not expanded, and the first expansion allowance hole 112 and the second expansion hole 112 are expanded. Only a certain area of the cell body 61 and the cell pocket 62 located on the acceptance hole 122 is expanded.

Afterwards, (c) when the air supply unit 32 operates, the pressure measuring unit 40 measures the air pressure in the air injection passage.

Specifically, as the air supply unit 32 supplies air at a positive pressure, the internal pressure of the pouch 60 increases linearly and steadily, and the first expansion allowance hole 112 and the second expansion allowance hole 122 A certain area of the cell body 61 and the cell pocket 62 located on the top gradually expands and bursts at a limit point.

When the pouch 60 bursts, the constantly rising pressure within the pouch 60 drops, and the pressure measuring unit 40 measures the point at which the pressure drops and the pressure at that point.

For example, the pressure measuring unit 40 may include a display window that displays the measured pressure in numbers or scales.

In addition, the pressure measuring unit 40 can be programmed to provide the measured pressure to a display unit provided in the manager PC.

The action of the pressure measuring unit 40 allows the manager to determine the internal pressure limit of the pouch 60.

As another example, the pressure change measured by the pressure measuring unit 40 may be transmitted to an electrically connected visualization unit (not shown). The visualization unit can be formed with software, and is programmed to graph the values measured by the pressure measuring unit 40 and provide them to the display unit provided in the touch panel device (P) or the administrator's PC.

At this time, the visualization unit may be installed in the touch panel device (P) or the administrator PC.

Additionally, the touch panel device 1 may be installed on the cover unit 12 or may be installed separately at a predetermined distance apart from one side of the storage unit 10 .

The visualization unit can convert the measured values of the pressure measuring unit 40 into a graph as shown in FIG. 9.

At this time, the visualization unit can convert the measured values into a graph including time on the horizontal axis and pressure on the vertical axis.

Additionally, the manager can determine the tendency of the pouch 60 to break through the graph.

Specifically, the pressure increase over time from the time of air injection and the pressure decrease after the maximum pressure are displayed in a graph, and the manager can identify the sealing breaking point of the cell body and cell pocket through the graph.

Then, the internal pressure of the pouch 60 can be evaluated by reducing the pressure at regular intervals from the determined breaking pressure and finding the optimal offset value.

At this time, the internal pressure evaluation device of the secondary battery according to an embodiment of the present invention sets the pressure of the air supplied to the pouch 60 and uses a pneumatic regulator installed in the injection line 321 to collect accurate pressure data. 2) may be further included.

Ultimately, the present invention measures the internal pressure of pouches 60 of various sizes and allows managers to refer to them when manufacturing secondary batteries.

A person skilled in the art to which the present invention pertains will understand that the present invention can be implemented in other specific forms without changing its technical idea or essential features. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive. The scope of the present invention is indicated by the scope of the claims described below rather than the detailed description above, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts are included in the scope of the present invention. must be interpreted.

1: Internal pressure evaluation device of secondary battery 10: Storage unit
11: Storage main body 111: First support plate
112: first expansion allowance hole 113: adsorption unit
114: Suction pipe 12: Cover part
121: second support plate 122: second expansion allowance hole
123: Elevating hole 114: Suction pipe
20: Separation part 21: Elevating block
211: moving guide hole 212: intake hole
213: first fixing groove 214: second fixing groove
22: first suction ring 221: first connection hole
23: second suction ring 231: second connection hole
24: moving driving unit 25: suction control unit
25a: Suction hose 26a: Elevating plate
26b: lifting bar 26c: lifting body
26d: Elevating guide 30: Injection part
31: Housing 311: Third connection hole
311a: Horizontal connection hole 32: Air supply unit
321: Injection line 33: Needle driving unit
34: Needle 40: Pressure measuring unit
50: Packing part 60: Pouch
61: Cell body 62: Cell pocket
62a: first side 62b: second side

Claims (12)

a storage unit having a storage space in which a secondary battery is stored;
a spacer that adsorbs one side of the secondary battery and then pulls it to form a space inside the secondary battery;
an injection unit that pierces the secondary battery with a needle installed in the spaced portion and has an air injection passage formed therein, and injects air at positive pressure into the internal space of the secondary battery through the air injection passage; and
An internal pressure evaluation device for a secondary battery including a pressure measuring unit that measures air pressure in a space connected to the air injection path.
According to paragraph 1,
The storage unit,
a storage body having a first support plate supporting one side of the secondary battery and the storage space, and first expansion-allowing holes for allowing expansion of the secondary battery on both sides of the first support plate; and
A second support plate is formed to open and close the storage space of the storage body, and supports the secondary battery on the opposite side of the secondary battery to which the first support plate is in contact, and the first expansion allowance hole is provided on both sides of the second support plate. An apparatus for evaluating the internal pressure of a secondary battery, including a cover portion facing the secondary battery and having a second expansion-allowing hole formed to allow expansion of the secondary battery.
According to paragraph 2,
An apparatus for evaluating the internal pressure of a secondary battery, wherein a lifting hole is formed in the cover part through which the spaced part is raised and lowered.
According to paragraph 1,
The separation part,
a lifting block formed with a moving guide hole for guiding the movement of the needle and at least one intake hole for applying an adsorption force to the secondary battery;
An adsorption unit coupled to the lifting block and facing the secondary battery, connected to the movement guide hole and including a first connection hole through which the needle passes and a second connection hole connected 1:1 with the intake hole;
a moving drive unit that moves the lifting block so that the needle moves closer to or farther away from the secondary battery while allowing the adsorption unit to contact or separate from the secondary battery; and
An apparatus for evaluating the internal pressure of a secondary battery, including a suction control unit that is connected to the intake hole and adsorbs the secondary battery to the adsorption unit through air suction when the adsorption unit contacts the secondary battery.
According to paragraph 4,
The adsorption unit,
a first suction ring coupled to the lifting block and having the first connection hole; and
It is coupled to the lifting block, is arranged to form a concentric circle with the first suction ring, and is formed to have a larger diameter than the first suction ring, so that the first suction ring is located in the internal space, and the second connection hole is formed. A device for evaluating the internal pressure of a secondary battery including a second suction ring.
According to paragraph 1,
The injection part,
a housing in which a predetermined area of the needle is accommodated and a third connection hole connected to the air injection path is formed;
an air supply unit supplying air to the air injection passage through the third connection hole; and
An apparatus for evaluating the internal pressure of a secondary battery, further comprising a needle drive unit that moves the housing in the direction of the secondary battery so that the needle pierces the secondary battery.
According to clause 6,
An apparatus for evaluating the internal pressure of a secondary battery, further comprising a plurality of packing parts mounted on the outer periphery of the housing to be spaced apart from each other, the outer periphery of which is in close contact with the inner periphery of the spaced portion.
According to clause 6,
When the air supply unit is not in operation, the pressure in the space between the inside of the pouch, the outside of the needle, and the packing part is maintained at atmospheric pressure.
According to paragraph 1,
An apparatus for evaluating the withstand pressure of a secondary battery, further comprising an adsorption unit installed in the storage unit and adsorbing and fixing the secondary battery on the opposite side of the secondary battery that is in contact with the separation unit.
(a) forming a space inside the secondary battery by adsorbing and pulling at least one side of the secondary battery stored in the storage unit by the spacer;
(b) punching the secondary battery with a needle having an air injection passage formed therein, and then having an air supply unit inject air into the interior of the secondary battery through the air injection passage; and
(c) A method of evaluating the internal pressure of a secondary battery including the step of measuring the air pressure in the air injection passage with a pressure measuring unit.
According to clause 10,
A method for evaluating the withstand pressure of a secondary battery, further comprising the step of adsorbing the secondary battery on the opposite side of the secondary battery where the spacer is in contact with the adsorption unit installed in the storage unit before or after step (a).
According to clause 10,
In step (b),
(b1) moving the needle and inserting it into the secondary battery; and
(b2) When the needle is inserted into the secondary battery, the air supply unit operates to inject air into the arch battery.

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