KR20200006412A - Cell guide for secondary cell and cell tray having the same - Google Patents

Abstract

The present invention relates to a short test device of a secondary battery cell and, more specifically, to a short test device of a secondary battery cell and a short test system including the same which test whether a pouch-type secondary battery cell is shorted to select good pouch-type secondary battery cells. The short test device (100) for a secondary battery cell (40) comprises: an electrode assembly having first and second electrode sheets (12, 14) alternately laminated, and a separation membrane (16) positioned between the first and second electrode sheets (13, 14); a pouch (20) to seal the electrode assembly (10); and a lead tap (30) which is connected to the electrode assembly (10) and protrudes out of the pouch (20). The short test device (100) for a secondary battery cell (40) has a flat structure consisting of a pair of plate surfaces and a plurality of sides.

Description

Cell guide for secondary battery cell and cell tray comprising same {Cell guide for secondary cell and cell tray having the same}

The present invention relates to a cell guide for a secondary battery cell and a cell tray including the same, and more particularly, a cell guide installed in a cell tray for transporting a plate-shaped secondary battery cell to support a plate surface of a secondary battery cell and the same. It relates to a cell tray.

Generally, a chemical cell is composed of a pair of electrodes of a positive electrode and a negative electrode and an electrolyte, and the amount of energy that can be stored varies depending on the material of the electrode and the electrolyte.

These chemical cells are classified into a primary battery used only for one-time discharge because of a very slow charging reaction, and a secondary battery that can be reused through repeated charging and discharging.

Secondary batteries are applied to various technical fields throughout the industry. For example, secondary batteries are used as energy sources for advanced electronic devices such as wireless mobile devices, and air pollution of conventional gasoline and diesel internal combustion engines using fossil fuels. It is also attracting attention as an energy source for hybrid electric vehicles, which is being proposed as a solution for this.

Secondary batteries are manufactured in various ways depending on the shape of the case housing the electrode assembly, and typical shapes include cylindrical, rectangular, and pouch types.

In general, the cylindrical secondary battery uses a cylindrical aluminum can, the rectangular secondary battery uses a rectangular aluminum can, and the pouch type secondary battery is sealed with a pouch in which a thin aluminum laminate film made of a material such as aluminum is packed in a pack form. It is relatively light in weight and excellent in stability and is widely used in recent years.

For example, a configuration of a pouch-type secondary battery cell includes a stack, which is an electrode assembly formed by interposing a separator, which is a separator between a negative electrode and a positive electrode, and an aluminum-laminated film by sealingly accommodating the stack therein. Pouch consisting of, and one end is connected to the stack and the other end is exposed to the outside of the pouch is composed of a plate-shaped negative electrode lead tab for inducing current to the outside.

The secondary battery cell is generally completed by injecting an electrolyte into a pouch containing an electrode assembly composed of a negative electrode, a positive electrode, and a separator interposed therebetween, and then sealing it.

An object of the present invention, by providing a cell guide for supporting the plate surface of the pouch-type secondary battery cell, the plate surface of the pouch-type secondary battery cell can be transported in a stable supported state perpendicular to the ground and thus The present invention provides a cell guide and a cell tray including the same, which can more efficiently and easily perform a process and logistics such as electrolyte injection, sealing, and degassing, in which a plate-shaped secondary battery cell should be performed in a vertical state.

In particular, the present invention by forming the cell guide supporting the plate surface of the secondary battery cell integrally through the injection mold of the engineering plastic, while ensuring the insulation, secondary battery cell scratch and pollution prevention function and quality uniformity, while the manufacturing process is simple The present invention provides a cell guide and a cell tray including the same, which can greatly reduce manufacturing time and manufacturing cost.

The present invention has been created to achieve the object of the present invention as described above, the first electrode sheet 12 and the second electrode sheet 14 are alternately stacked with each other and the first electrode sheet 13 and the second The plate surface of the secondary battery cell 40 having a plate-like structure including an electrode assembly 10 in which the separator 16 is positioned between the electrode sheets 14 and a pouch 20 for sealing the electrode assembly 10. Disclosed is a cell guide 100 for supporting.

The cell guide 100 includes a coupling part 110 fixed to the base plate 200 for supporting the secondary battery cell 40, and extends in a vertical direction from the coupling part 110. It may include a support pillar 120 for guiding the plate surface of the secondary battery cell 40 so that the normal line of the plate surface of the 40 is parallel to the horizontal plane.

The support pillar 120 may include a lower vertical portion 121 vertically extending from the coupling portion 110 and a first slope inclined in the direction toward the secondary battery cell 40 from the lower vertical portion 121. The unit 122 may include a central vertical portion 123 extending perpendicular to the ground from the first inclined portion 122.

The support pillar 120 may include a second inclined portion formed to be inclined in a direction toward the outside of the plate surface of the secondary battery cell 40 on which the opposite end of the coupling portion 110 is supported. 124) may be further included.

The coupling part 110 may be formed with a bolt coupling hole 112 for bolt coupling with the base plate 200.

The cell guide 100 may be integrally formed by an injection mold.

The cell guide 100 may be made of an engineering plastic material.

The coupling part 110 and the support pillar 120 may be made of a metal material and may be coupled to each other by welding.

The cell guide 100 may further include an insulating tube member 130 in which the support pillar 120 is inserted to surround the outer surface of the support pillar 120.

In another aspect of the present invention, the first electrode sheet 12 and the second electrode sheet 14 are alternately stacked with each other and the separator 16 between the first electrode sheet 13 and the second electrode sheet 14. The cell guide 100 for supporting the plate surface of the secondary battery cell 40 having a plate-like structure including an electrode assembly 10 is positioned, a pouch 20 for sealing the electrode assembly 10, and a secondary, secondary The cell tray 1 supports a lower portion of the battery cell 40 and includes a base plate 200 on which the cell guide 100 is fixedly installed.

The cell tray 1 may include at least one pair of cell guides 100 installed to face the pair of plate surfaces of the secondary battery cell 40, respectively.

The cell tray 1 further includes a lower support member 300 installed on the base plate 200 to support a lower portion of the secondary battery cell 40 between the pair of cell guides 100. can do.

The cell tray 1 may further include a cell detecting unit 400 that detects whether the secondary battery cell 40 is positioned between the pair of cell guides 100.

The cell guide according to the present invention and the cell tray including the same, by installing the cell guide for supporting the plate surface of the pouch-type secondary battery cell, the plate surface of the pouch-type secondary battery cell is stably supported in a state perpendicular to the ground There is an advantage that can be carried out in a state that the plate-shaped secondary battery cell to be carried out in a vertical state to perform the process and logistics, such as electrolyte injection, sealing, degassing more efficiently and easily.

In addition, the present invention, by forming the cell guide for supporting the plate surface of the secondary battery cell integrally through the injection mold of engineering plastics, the manufacturing process is simple while ensuring insulation, secondary battery cell scratch and contamination prevention function and quality uniformity And there is an advantage that can greatly reduce the manufacturing time and manufacturing cost.

1A is a plan view illustrating a secondary battery cell supported by a cell tray according to the present invention.
FIG. 1B is a II-II cross-sectional view of the secondary battery cell of FIG. 1A.
2 is a side view illustrating a cell tray and a secondary battery cell supported by the cell tray according to an embodiment of the present invention.
3 is a perspective view illustrating a part of a configuration of the cell tray of FIG. 2.
4A and 4B are perspective and side views illustrating a cell guide installed in the cell tray of FIG. 2.
FIG. 5A is a cross-sectional view taken along the line III-III of FIG. 4A.
FIG. 5B is a cross-sectional view taken along the IV-IV direction of FIG. 4B.
6 is an exploded perspective view showing a cell guide according to another embodiment of the present invention.

Hereinafter, a cell guide and a cell tray including the same according to the present invention will be described with reference to the accompanying drawings.

The cell tray 1 according to the present invention, as shown in Figs. 2 and 3, is a configuration in which one or more, preferably a plurality of secondary battery cells 40 is loaded and loaded or unloaded It is a device for supporting the secondary battery cell 40, the process is made in a state supporting the secondary battery cell 40, or to transfer the secondary battery cell 40 to another process line.

For example, the cell tray 1 performs a supporting function of the secondary battery cell 40 when the secondary battery cell 40 is transported in the secondary battery manufacturing facility (logistics), and is applied to a logistics conveyor for electrolyte injection. Alternatively, the secondary battery cell 40 may be coupled to an oscillator, a liquid weight measurement device, a gas discharge device, a V-sealing vacuum chamber, and the like so that the secondary battery cell 40 is supported during the process.

In the secondary battery cell 40 supported by the cell tray 1 according to the present invention, as shown in Figure 1a and 1b, the first electrode sheet 12 and the second electrode sheet 14 are mutually Alternately stacked alternately, the electrode assembly 10 having the separator 16 positioned between the first electrode sheet 12 and the second electrode sheet 14, and a pouch 20 for sealing the electrode assembly 10; The lead tab 30 may be connected to the electrode assembly 10 and protrude out of the pouch 20. 1A is a plan view of the rectangular plate-shaped pouch type secondary battery cell 40 viewed in a normal direction perpendicular to the plate surface.

The first electrode sheet 12 and the second electrode sheet 14 are stacked alternately with each other and are separated by the separator 16 therebetween, and form positive and negative electrodes of the secondary battery cell 40, respectively. The member may be formed of a metal sheet according to electrode characteristics.

Electrode tabs (not shown) extend from each electrode sheet in the first electrode sheet 12 and the second electrode sheet 14.

The separator 16 is a member interposed between the first electrode sheet 12 and the second electrode sheet 14, and preferably has a material having high wettability to the electrolyte and high chemical resistance.

The separator 16 may have various materials according to materials of the first electrode sheet 12 and the second electrode sheet 14 constituting the secondary battery cell 40, physical properties of the electrolyte, and the like.

The pouch 20 is a member for sealing the electrode assembly 10 impregnated with the electrolyte and may have various materials according to the materials of the first electrode sheet 12 and the second electrode sheet 14, the properties of the electrolyte, and the like. .

For example, the pouch 20 may be formed by laminating a nylon layer on one surface of the aluminum layer and a P.P layer on the other surface.

The lead tab 30 is composed of a pair of positive and negative electrodes, one end of which is connected to the electrode assembly 10 and the other end of which protrudes out of the pouch 20.

The lead tab 30 may be electrically connected to the plurality of electrode tabs extending from the electrode sheets 12 and 14 by welding.

In addition, at least part of the upper and lower surfaces of the lead tab 30 may be attached with a lead film 31 for increasing the sealing degree with the pouch 20 and at the same time ensuring an electrical insulation state.

As shown in FIG. 2, the cell tray 1 according to the present invention supports the one or more secondary battery cells 40 in a state in which the normal of the plate surface of the secondary battery cell 40 of FIG. 1 is parallel to the horizontal plane. Can be configured.

In one embodiment, the cell tray 1, the cell guide 100 for supporting the plate surface of the secondary battery cell 40, and supports the lower portion of the secondary battery cell 40, the cell guide 100 is It may include a fixed base plate 200.

First, the cell guide 100 will be described later after describing the base plate 200.

The base plate 200 may be formed in various shapes and materials as long as it is formed in a plate shape as a body that is a base on which other components of the cell tray 1 are installed.

For example, the base plate 200 may provide an installation surface on which the cell guide 100, the lower support member 300, and the cell detecting unit 400, which will be described later, are installed. It may be provided with a coupling means coupled to the guide (not shown) or other process equipment coupled to the logistics line.

The cell guide 100 may be configured to support a plate surface of the secondary battery cell 40 in which the plate surface is perpendicular to the ground.

In this case, the cell tray 1 preferably includes at least one pair of cell guides 100 installed to face the pair of plate surfaces of the secondary battery cell 40, respectively.

In particular, the cell tray 1, as shown in Figure 3, so that the plate surface of the secondary battery cell 40 is preferably two pairs of cell guides 100 in one secondary battery cell 40 ) May include a plurality of pairs of cell guides (100).

As shown in FIG. 2, the plurality of pairs of cell guides 100 may be arranged at predetermined intervals along an arrangement direction (reference X axis direction of FIG. 2) of the secondary battery cell 40.

For example, as illustrated in FIGS. 2 to 6, the cell guide 100 includes a coupling part 110 fixedly coupled to the base plate 200 for supporting the secondary battery cell 40, and a coupling part. It may include a support pillar 120 extending in the vertical direction from the 110 and guides the plate surface of the secondary battery cell 40 so that the normal of the plate surface of the secondary battery cell 40 is parallel to the horizontal plane.

The coupling part 110 is a cell guide 100 is fixed to the base plate 200 to be fixed to the base plate 200 in a variety of configurations and coupling means is possible.

For example, the coupling part 110 may be fixed to the base plate 200 through bolt coupling. In this case, the coupling part 110 may have a bolt coupling hole 112 for bolt coupling with the base plate 200. ) May be formed.

The support pillar 120 extends in the vertical direction from the coupling portion 110 and guides the plate surface of the secondary battery cell 40 so that the normal of the plate surface of the secondary battery cell 40 is parallel to the horizontal plane. Configuration is possible.

For example, as shown in FIGS. 4A to 4B, the support pillar 120 includes a lower vertical portion 121 extending vertically from the coupling portion 110 and a secondary battery cell at the lower vertical portion 121. Second battery cell 40 in the first inclined portion 122 inclined in the direction toward 40, the central vertical portion 123 and the central vertical portion 123 extending perpendicular to the ground in the first inclined portion 122 It may include a second inclined portion 124 inclined outward with respect to).

The lower vertical portion 121 may be formed at various heights according to the size of the secondary battery cell 40 to be guided.

By the lower vertical portion 121, the entire support pillar 120 may maintain rigidity without excessive bending.

The first inclined portion 122 may be formed to be inclined toward the plate surface of the secondary battery cell 40, and the central vertical portion 123 to be described later may be in close contact with the plate surface of the secondary battery cell 40. Thereby, the position guide and pressure for the secondary battery cell 40 can be made sufficiently.

The central vertical portion 123 may protrude in a direction toward the plate surface of the secondary battery cell 40 at the central portion of the support pillar 120 through the first slope portion 122 and the second slope portion 124. Can be.

The plate surface of the secondary battery cell 40 and the support pillar 120 may be in close contact with each other through the central vertical portion 123, so that the secondary battery cell 40 may be more stably supported without shaking.

In particular, when the pair of cell guides 100 are configured to support the pair of plate surfaces of the secondary battery cell 40 to face each other, the center vertical portions 123 of the pair of support pillars 120 corresponding to each other Since it protrudes toward the plate surface of the secondary battery cell 40 inserted and supported between the pair of support pillars 120 may be guided more stably.

The second inclined portion 124 may be formed to be inclined in a direction toward the outer side of the plate surface of the secondary battery cell 40 on which the opposite end portion of the coupling portion 110 of the support pillar 120 is supported. That is, the second inclined portion 124 may be formed to be inclined in a direction opposite to the first inclined portion 122.

As a result, as shown in FIG. 3, when the secondary battery cell 40 enters between the pair of support pillars 120, the end of the support pillar 120 is in contact with the secondary battery cell 40. Scratching or damage can be effectively prevented.

Meanwhile, the support pillar 120 may have a V-shaped or U-shaped cross section facing the secondary battery cell 40 as shown in FIG. 5B for cost reduction and light weight. By processing a portion that does not directly support the secondary battery cell 40 to an empty space, it is possible to minimize the raw materials required to manufacture the support pillar 120.

At this time, as shown in Figure 5a, both side end 126 of the support pillar 120 is inward to prevent the secondary battery cell 40 is damaged when contacting the secondary battery cell 40. It may be rounded, the central portion of the V-shaped or U-shaped in direct contact with the secondary battery cell 40 may be formed to form a plane for the pressure effect, the guide performance and damage to the secondary battery cell 40.

In addition, the support pillars 120 are spaced at predetermined intervals along the longitudinal direction of the support pillars 120 inside the V or U shapes for rigidity (structural reinforcement) of the support pillars 120. It may include multiple ribs 125 that are disposed.

Meanwhile, the cell tray 1 may further include a lower support member 300 installed on the base plate 200 to support the lower portion of the secondary battery cell 40 between the pair of cell guides 100. Can be.

The lower support member 300 is installed between a pair of cell guides 100 supporting a pair of plate surfaces of the secondary battery cell 40 to support a lower portion of the secondary battery cell 40. This is possible.

For example, as shown in FIGS. 2 and 3, the lower support member 300 has a slot in which a sealing portion of the pouch 20 of the secondary battery cell 40 can be inserted in a central portion thereof. ) May be formed in a longitudinal direction (a reference to the Y-axis direction), and a support for supporting the secondary battery cell 40 may be formed at both sides of the slot.

In addition, the cell tray 1 may further include a cell detecting unit 400 that detects whether the secondary battery cell 40 is positioned between the pair of cell guides 100.

The cell detecting unit 400 detects whether the secondary battery cell 40 is positioned between the pair of cell guides 100 supporting the pair of plate surfaces of the secondary battery cell 40 in a contact or non-contact manner. Various configurations are possible with the configuration.

For example, the cell detection unit 400 may be a non-contact detection sensor, and specifically, may be an infrared detection sensor including an infrared light emitting unit and a light receiving unit installed in a pair of cell guides 100, but is not limited thereto. .

On the other hand, the above-described cell guide 100, the secondary battery cell 40 and the insulating property is ensured and can be made of a variety of materials if it does not cause damage, such as scratches on the secondary battery cell 40, various processing methods It can be implemented through.

In one embodiment, the cell guide 100 may be integrally formed by an injection mold. In this case, the cell guide 100 may be made of an engineering plastic material such as polyetherether ketone (PEEK).

In this case, the manufacturing process is simplified due to the characteristics of the injection mold, it is possible to greatly reduce the assembly labor for the actual application to the facility, the uniformity of the quality is improved, the production volume is greatly improved.

In particular, since the cell guide 100 has the characteristics of consumables installed in large quantities in a facility, the effect of simplifying the manufacturing process and reducing the manufacturing cost may have a great influence on the cost of the entire facility.

In addition, in the case of engineering plastics such as polyetherether ketone (PEEK), it is an insulating material and has excellent durability and resilience. There is an advantage that can have insulation function without the means.

In another embodiment, the coupling part 110 and the support pillar 120 constituting the cell guide 100 may be made of a metal material such as SUS.

At this time, the coupling portion 110 and the support pillar 120 may be composed of different members, not integral to the characteristics made of a metal material, as shown in Figure 6, may be coupled to each other by welding. .

When the support pillar 120 is made of a metal material, the first inclined portion 122 and the second inclined portion 124 of the support pillar 120 may be implemented by venting a straight metal pillar. .

In addition, the support pillar 120 is made of a metal material for the insulation with the secondary battery cell 40, the cell guide 100, the support pillar 120 is inserted into the support pillar 120 It may further include an insulating tube member 130 surrounding the outer surface of the.

The tube member 130 may be made of a flexible engineering plastic material to be in close contact with the outer surface of the support pillar 120 formed by venting, preferably Teflon (PTFE, Polytetrafluoroethylene) It may be made of a material, but is not limited thereto.

Since the above has just been described with respect to some of the preferred embodiments that can be implemented by the present invention, as is well known the scope of the present invention should not be construed as limited to the above embodiments, the present invention described above It will be said that both the technical idea and the technical idea which together with the base are included in the scope of the present invention.

40: Secondary battery cell 100: Cell Guide

Claims (12)

The electrode assembly 10 in which the first electrode sheet 12 and the second electrode sheet 14 are alternately stacked with each other, and the separator 16 is positioned between the first electrode sheet 13 and the second electrode sheet 14. And, as a cell guide 100 for supporting the plate surface of the secondary battery cell 40 having a plate-like structure comprising a pouch 20 for sealing the electrode assembly 10,
The cell guide 100,
The coupling part 110 is fixedly coupled to the base plate 200 for supporting the secondary battery cell 40, and extends in a vertical direction from the coupling part 110, the normal of the plate surface of the secondary battery cell 40 Cell guide 100, characterized in that it comprises a support pillar 120 for guiding the plate surface of the secondary battery cell 40 to be parallel to the horizontal plane. The method according to claim 1,
The support pillar 120 may include a lower vertical portion 121 vertically extending from the coupling portion 110 and a first slope inclined in the direction toward the secondary battery cell 40 from the lower vertical portion 121. Cell guide 100, characterized in that it comprises a portion (122), the central vertical portion (123) extending perpendicular to the ground in the first inclined portion (122). The method according to claim 2,
The support pillar 120 may include a second inclined portion formed to be inclined in a direction toward the outside of the plate surface of the secondary battery cell 40 on which the opposite end of the coupling portion 110 is supported. Cell guide 100, characterized in that it further comprises. The method according to claim 1,
Cell coupling 100, characterized in that the coupling portion 110 is formed with a bolt coupling hole 112 for bolt coupling with the base plate 200. The method according to claim 1,
The cell guide 100, the cell guide 100, characterized in that formed integrally by the injection mold. The method according to claim 5,
The cell guide 100, the cell guide 100, characterized in that made of an engineering plastics material. The method according to claim 1,
The coupling portion 110 and the support pillar 120 is made of a metal material and the cell guide (100), characterized in that coupled to each other by welding. The method according to claim 7,
The cell guide 100 further includes an insulating tube member 130 in which the support pillar 120 is inserted to surround the outer surface of the support pillar 120. 100). The electrode assembly 10 in which the first electrode sheet 12 and the second electrode sheet 14 are alternately stacked with each other, and the separator 16 is positioned between the first electrode sheet 13 and the second electrode sheet 14. And a pouch 20 for sealing the electrode assembly 10 and supporting the plate surface of the secondary battery cell 40 having a plate-like structure according to any one of claims 1 to 8. Cell guide 100,
Supporting the lower portion of the secondary battery cell 40, the cell tray 100, characterized in that it comprises a base plate 200 is fixedly installed. The method according to claim 9,
The cell tray (1), the cell tray (1) characterized in that it comprises at least a pair of cell guides (100) which are installed to face each other so that a pair of plate surfaces of the secondary battery cell (40). The method according to claim 10,
The cell tray 1 further includes a lower support member 300 installed on the base plate 200 to support a lower portion of the secondary battery cell 40 between the pair of cell guides 100. Cell tray (1) characterized in that. The method according to claim 10,
The cell tray 1 further includes a cell tray 400 which detects whether the secondary battery cell 40 is positioned between the pair of cell guides 100. One).

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