KR20230020771A - Apparatus for removing static elecitricity of paper for fuel cell stack manufacturing equipment - Google Patents

Abstract

The present invention relates to a device for removing static electricity of paper for a fuel cell stack manufacturing apparatus. The present invention provides a device for removing static electricity of paper for a fuel cell stack manufacturing apparatus, comprising: a paper storage part which is supported by a plurality of plates with a rectangular cross section to accommodate multiple sheets of paper and includes an opening in a surface corresponding to either side of the plates facing each other; ion-spray nozzle parts which are provided in the form of a rod with a predetermined height at regular intervals on one side of the opening, include a plurality of spray nozzles formed at regular intervals throughout the entire height of the paper storage part, and spray ion wind toward the opening of the paper storage part; and a vacuum absorption member which is in contact with the paper, applies vacuum, rises vertically while absorbing the paper, and moves to a sequential process. According to the present invention, static electricity generated between pieces of paper can be effectively neutralized and removed.

Description

Apparatus for removing static elecitricity of paper for fuel cell stack manufacturing equipment}

The present invention relates to a static electricity eliminator for a separator for a fuel cell stack manufacturing facility, and more particularly, to a separator for a fuel cell stack manufacturing facility capable of effectively removing static electricity generated between a separator and a separator during manufacturing a fuel cell stack. It is about an electrostatic eliminator.

In general, a fuel cell stack is a kind of power generation device that converts chemical energy of fuel into electrical energy by electrochemically reacting it within the stack, and supplies driving power for industrial use, household use and vehicles, as well as small electronic devices such as portable devices. It can be used for the power supply of products, and its use is gradually expanding as a high-efficiency clean energy source.

A fuel cell stack is formed by stacking a plurality of cells in series between end plates at both ends of the stack. At this time, each cell has a Membrane-Electrode Assembly (MEA) located at the innermost part. It is composed of a catalyst layer applied so that hydrogen and oxygen can react, that is, a cathode and an anode.

In addition, a gas diffusion layer (GDL) is stacked on one surface and the other surface of the membrane electrode assembly, that is, an outer portion where the air electrode and the fuel electrode are located, and a reaction gas is supplied to the outer surface of the gas diffusion layer, and cooling water generated by the reaction A separator for discharging is located.

The separator is divided into an anode separator and a cathode separator, and the anode separator and the cathode separator constitute a fuel cell stack as the anode separator and the cathode separator constituting adjacent cells come into contact with each other to form a pair. Here, the anode separator may have a shape of a separator in which a channel portion is formed, and the cathode separator may have a shape including a perforated plate.

In the process of manufacturing such a separator, a gasket is sealed between the cathode separator and anode separator for airtightness between the hydrogen, air, and cooling water passages, and the cathode separator and anode separator are clamped at the welding part of the separator. After laser welding, it is hardened at high temperature.

During the production process, when the separator plates are stacked on the cartridge, damage may occur if the separator plates come into contact with each other. Therefore, gaskets made of rubber are integrally molded on the upper and lower surfaces of the separator plate to maintain airtightness in the entire outer direction of the separator plate. In general, it serves to reduce damage and contact between the separation plates by inserting paper between the separation plates in order to minimize contact between the stacked gaskets.

Therefore, the slip sheet is taken out from the separate cartridge and moved to the cartridge on which the separator plates are stacked.

However, static electricity is generated due to friction with other separator sheets stacked in the cartridge, and when transported to the separator cartridge, several sheets are transferred in a state attached to each other at once, which causes a problem in the manufacturing process of the separator. will bring about

In other words, due to the static electricity generated between the slip sheets in the process of transporting the slip sheets, the subsequent process becomes defective, resulting in a high rate of equipment malfunction and defective products, resulting in a decrease in productivity.

Republic of Korea Patent Publication No. 2015-0026266 (2015.03.11)

Therefore, the present invention has been made to solve the above problems, and an object of the present invention is to uniformly spray ion wind to a spacer paper accommodating part to prevent the generation of static electricity between the papers. It is to provide a static electricity eliminator for a fuel cell stack manufacturing facility.

In order to achieve the above object, the present invention is supported by a plurality of plate bodies having a rectangular cross section so that several sheets of slip sheets are accommodated, and an opening is formed on either side of the corresponding surface of the plate body facing each other; It is formed in the shape of a rod having a predetermined height at intervals on one side of the opening, and a plurality of spray nozzles are formed at intervals over the entire height of the interleaving paper storage unit, so that ion wind blows toward the opening of the interleaving paper storage unit. an ion spray nozzle unit for spraying; and a vacuum adsorption member that comes into close contact with the slip sheet and applies a vacuum to vertically rise in a state in which the slip sheet is adsorbed and moves to a subsequent process. do.

According to an embodiment of the present invention, the interleaving storage unit may include a base plate having an opening formed therethrough; a front plate and a back plate supporting side surfaces of the interleaving sheets, which have a rectangular cross section on the base plate and are stacked on a lifting plate installed to be capable of lifting and moving; and a side plate through which the ion wind sprayed from the ion spray nozzle unit passes.

According to an embodiment of the present invention, the side plate has partial support plates formed at edges of both sides of the front plate and the rear plate, and the partial support plates are spaced apart from each other on both sides around the opening and are supported in a separated state.

According to an embodiment of the present invention, the front plate and the rear plate facing each other of the interleaving paper storage unit are fixed to the top surface of the front plate and the back plate and to both sides of the side plate in a direction crossing each other. A guide unit is installed.

According to an embodiment of the present invention, the fixed guide portion is made of a plastic material.

According to the electrostatic eliminator for interlayer paper for fuel cell stack manufacturing equipment according to the present invention having the configuration as described above, by supplying ion wind to the interleaf storage portion in which the interlayer paper is stored, static electricity that may occur between the interleaf sheets is effectively neutralized and removed. can do.

In addition, according to the present invention, as the anti-static effect is improved, correction work time required due to incorrect lamination can be reduced, and productivity degradation can be prevented in advance by minimizing the occurrence of defective products.

1 is a side view showing an electrostatic eliminator for a fuel cell stack manufacturing facility according to the present invention.
2 is a perspective view showing a slip sheet accommodating unit in which slip sheets are accommodated according to the present invention.
3 is a view showing a state in which an electrostatic eliminator for a fuel cell stack manufacturing facility according to the present invention is installed.
4 is a view showing an operating state of the static electricity eliminator of the interlayer for fuel cell stack manufacturing equipment according to the present invention.

Since the present invention can be applied with various changes and can have various forms, embodiments will be described in detail in the text. However, this is not intended to limit the present invention to the specific disclosure, and it should be understood to include all modifications, equivalents, and substitutes included in the spirit and technical scope of the present invention. Like reference numerals have been used for like elements throughout the description of each figure.

These terms are only used for the purpose of distinguishing one component from another. 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.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a side view showing an electrostatic eliminator for separators for a fuel cell stack manufacturing facility according to the present invention, FIG. 2 is a perspective view showing a separator containing separators according to the present invention, and FIG. 3 is a fuel cell according to the present invention. It is a view showing a state in which the static electricity eliminator of the interlayer for a stack manufacturing facility is installed, and FIG. 4 is a view showing an operating state of the static electricity eliminator of the interlayer for a fuel cell stack manufacturing facility according to the present invention.

As shown in FIG. 1, the device for removing static electricity between the slip sheets for fuel cell stack manufacturing equipment according to the present invention physically and chemically removes the static electricity between the slip sheets attached to each other, thereby removing the adhesion due to static electricity. am.

The present invention includes a slip sheet storage unit 100, a fixed guide unit 200, and an ion spray nozzle unit 300.

The slip sheet container 100 is a rectangular parallelepiped case for storing and storing several sheets of slip sheets, and includes an elevator plate 110 accommodated therein and movable up and down in a stacked state of several slip sheets.

Lifting means is installed on the lifting plate 110 so that the paper sheets stacked on the lifting plate 110 can move up and down in the vertical direction. It should be noted that the lifting means is a means for lifting and moving the lifting plate 110 in the height direction, and an air cylinder or the like may be used, and various types of lifting means may be adopted.

The slip sheet accommodating unit 100 includes a plate body 120 supported in a form surrounding the circumferential surface of the lift plate 110 so that the slip sheets do not escape to the outside while being stacked on the lift plate 110 .

Openings 125 are formed on corresponding surfaces of either side of the plate body 120 facing each other.

The plate body 120 is formed in a rectangular cross-section on the base plate 121 having an opening 121a formed therethrough, and is stacked on the side of the slip sheet stacked on the lift plate 110 installed on the base plate 121 to be able to move up and down. It includes a front plate 122 and a rear plate 123 supporting the ion spraying nozzle 300 and a side plate 124 through which ion wind sprayed from the ion spray nozzle unit 300 passes.

It is natural that the base plate 121 is formed with an opening 121a in terms of the layout of the lifting means for lifting and moving the lifting plate 110 .

In addition, the side plate 124 may be integrally formed with partial support plates 126 on both edges of the front plate 122 and the rear plate 123 or bonded to each other on both sides around the opening 125. It is supported in a spaced apart state.

According to the embodiment of the present invention, on the top surfaces of the front plate 122 and the rear plate 123 in a direction crossing between the front plate 122 and the rear plate 123 facing each other of the paper sheet storage unit 100. , Each fixed guide portion 200 is installed on both sides of the side plate 124.

The fixed guide part 200 is made of a length that matches the width between the front plate 122 and the rear plate 123, and the extension part 210 integrally extends downward from both ends of the fixed guide part 200 at a predetermined interval. ). Fastening parts 220 such as bolts and screws are installed in the extension part 210 so that it can be fastened and fixed to both the front plate 122 and the rear plate 123 of the slip sheet storage part 100 .

The fixed guide part 200 is made of a plastic material unrelated to the steel material so that the ions sprayed from the ion spray nozzle part 300 do not disappear in the ground form. Therefore, it is possible to continuously remove static electricity from the slip sheets stacked in the slip sheet storage unit 100 .

As shown in FIG. 4 , when the fixed guide part 200 adsorbs the interleaving sheets by the vacuum adsorption member 400 and moves up, at least two or more slip sheets are attached to each other and rise due to static electricity generated between the slip sheets. In this case, the slip sheets in the attached state are caught on the lower surface of the fixing guide part 200, and both ends of the slip sheets are deformed into a curved surface with a convex center as the both ends of the slip sheets go downward, so both ends of the slip sheets are forced downward and fall off, so that the slip sheets can be separated from each other.

In addition, since the fixing guide part 200 is fixed to the top surface of the plate body 120, that is, the top surface of the side plate 124 so that the upper side of the plate body 120 is not deformed, it can be bent in one direction without a support target. It is possible to support the top surfaces of the plate body 120, that is, the front plate 122 and the rear plate 123.

In addition, the fixing guide portion 200 fixed to the front plate 122 and the rear plate 123, respectively, is held in the gripping state when the paper sheet storage unit 100 is installed or separated in the fuel cell stack manufacturing facility ( 100) to function as a handle to move.

A vacuum adsorption member 400 that takes out and transfers the slip sheet from the slip sheet storage unit 100 in which the slip sheet is stored is installed above the slip sheet storage unit 100, adheres closely to the slip sheet, and applies vacuum to adsorb the slip sheet. will rise vertically.

At this time, ion wind is emitted from the ion spray nozzle unit 300 so that two or more slip sheets do not adhere to each other due to static electricity between the slip sheets.

Referring to the drawing, the ion spray nozzle unit 300 is spaced on one side of the opening 125 formed in the side plate 124 of the slip sheet storage unit 100 so as to face the slip sheets stored in the slip sheet storage unit 100. It is formed spaced apart from the side plate 124 in the shape of a rod having a predetermined height, and has a channel (not shown) through which ions emitted from the ion emission means (not shown) can move.

In the ion spray nozzle unit 300, a plurality of spray nozzles 310 connected to a flow path are formed at intervals in a direction toward the slip sheets accommodated in the slip sheet accommodating unit 100. The injection nozzle 310 is formed to inject at all heights from the bottom to the top of the paper sheet storage unit 100. Therefore, static electricity can be gradually removed from the paper sheet that is raised by the lifting means, and when the paper sheet storage unit 100 reaches the maximum height, almost no static electricity remains.

Here, as a configuration for discharging the ion wind, an ion releasing means (not shown) for discharging positive and negative ions when electricity is applied is provided, and when air of a certain pressure is supplied to the ions through a blower (not shown), the ions Positive ions and negative ions are contained in the air moving to the spray nozzle unit 300 to generate an ion wind, and the generated ion wind at a constant pressure is sprayed to the outside through the spray nozzle 310 . As the ion emission means, a generally known discharge needle or the like can be used.

Hereinafter, the operation of the static electricity eliminator of the interlayer for fuel cell stack manufacturing equipment according to the present invention will be described.

After the air supplied at a certain pressure from the blower is ionized by passing through the ion emission means, it passes through the opening 125 of the slip sheet storage part 100 by the spray nozzle 310 of the ion spray nozzle unit 300 to is sprayed At this time, electricity is applied to the ion emission means to emit ion wind.

At this time, the air supplied from the blower contains positive and negative ions and is ionized while passing through the ion discharging means, and the ionized air becomes ion wind at a constant pressure and is delivered to the flow path of the ion spray nozzle unit 300.

The ions that have moved through the flow path of the ion spray nozzle unit 300 are sprayed with ion wind at an appropriate pressure through the spray nozzle 310 and are evenly sprayed between the paper sheets to neutralize and remove static electricity generated between the paper sheets.

In this way, by preventing mutual adhesion between the slip sheets through the chemical removal of static electricity through the ion wind, the vacuum adsorption member 400 can adsorb and take out only the slip sheets when adsorbing the slip sheets from the slip sheet accommodating unit 100. be able to

In addition, when at least two or more slip sheets are attached to each other and rise due to static electricity generated between slip sheets when the slip sheets are moved upward using the vacuum adsorption member 400, on the plate body 120 of the slip paper storage unit 100. As the static electricity is physically removed by the fixing guide part 200 fixed thereto, the slip sheets can be separated one by one.

The separated paper sheets are adsorbed from the paper sheet storage unit 100 by the vacuum suction member 400 and moved to a subsequent assembly process.

The above description of the present invention is for illustrative purposes, and those skilled in the art can understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, the embodiments described above should be understood as illustrative in all respects and not limiting. The scope of the present invention is indicated by the following claims, and all changes or modifications derived from the meaning and scope of the claims and equivalent concepts should be interpreted as being included in the scope of the present invention.

100: slip sheet storage unit 110: lifting plate
120: plate body 121: base plate
122: front plate 123: rear plate
124: side plate 125: opening
126: partial support plate 200: fixed guide part
210: extension part 220: fastening part
300: ion spray nozzle unit 310: spray nozzle
400: vacuum adsorption member

Claims (5)

A slip sheet storage unit supported by a plurality of plate bodies having a rectangular cross-section so as to accommodate several sheets of slip sheets, and openings formed on corresponding surfaces of either side of the plate bodies facing each other;
It is formed in the shape of a rod having a predetermined height at intervals on one side of the opening, and a plurality of spray nozzles are formed at intervals over the entire height of the interleaving paper storage unit, so that ion wind blows toward the opening of the interleaving paper storage unit. an ion spray nozzle unit for spraying; and,
A vacuum adsorption member that adheres to the slip sheet and applies a vacuum to vertically rise in a state in which the slip sheet is adsorbed and moves to a subsequent process.
According to claim 1,
The interleaving storage unit,
a base plate having an opening formed therethrough;
a front plate and a back plate supporting side surfaces of the interleaving sheets, which have a rectangular cross section on the base plate and are stacked on a lifting plate installed to be capable of lifting and moving; and
The electrostatic eliminator of the interlayer for fuel cell stack manufacturing equipment, characterized in that it comprises a side plate through which the ion wind sprayed from the ion spray nozzle unit passes.
According to claim 2,
The side plate has partial support plates formed at edges of both sides of the front plate and the rear plate, and the partial support plates are spaced apart from each other on both sides around the opening and supported in a separated state. Static eliminator of dragon paper.
According to claim 3,
Characterized in that each fixing guide part is installed on the upper surface of the front plate and the rear plate and on both sides of the side plate in a direction crossing between the front plate and the rear plate facing each other of the interleaving paper storage unit Static electricity eliminator for slip sheets for fuel cell stack manufacturing facilities.
According to claim 4,
The static eliminator of the fuel cell stack manufacturing facility, characterized in that the fixed guide portion is made of plastic material.

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