KR20180053447A - Bi-polar plate inspection apparatus for fuel cell stack - Google Patents

Abstract

The present invention relates to a bipolar plate inspecting device for fuel cell stacks. The present invention includes: a supply member supplying one specimen selected from among gas and liquid; a plurality of fuel cell stack bipolar plates stacked to form a passage in which gas or liquid is able to flow; a fixing member supporting and fixing the bipolar plates sequentially stacked; and a pressing member pressing the upper part of the bipolar plates stacked on the fixing member by dropping an elevation plate combined with a rotary shaft through screws. The supply member supplies the specimen through a pipe connected to the fixing member and includes a measurement display unit measuring pressure or flow rates of the specimen stored in the passage of the bipolar plates. The fixing member includes: an inlet connected to the pipe of the supply member to deliver the specimen from the supply member to the passage; and an outlet discharging the specimen stored in the passage.

Description

TECHNICAL FIELD [0001] The present invention relates to a fuel cell stack inspection apparatus,

The present invention relates to a separator plate inspecting apparatus for a fuel cell stack.

Generally, a fuel cell module has a fuel cell stack in which a fuel cell that generates electric energy by reacting hydrogen (H ₂ ) and oxygen (O ₂ ) is stacked, and generates electricity using supplied fuel (hydrogen) do.

The fuel cell is fabricated from a polymer electrolyte fuel cell type or a direct fuel cell type fuel cell stack.

The fuel cell stack thus fabricated has a membrane electrode assembly (MEA) that generates electricity of 0.5 to 0.9 V in series to connect a plurality of membrane electrode assemblies (MEAs) to generate a desired voltage.

Briefly, the fuel is supplied to an anode (also referred to as an 'anode' or 'oxidation electrode') and air (oxygen) is supplied to a cathode (cathode, Quot; electrode " or " reduction electrode ").

As described above, the fuel supplied to the anode is decomposed into hydrogen ions (Proton, P ⁺ ) and electrons (Electron, E ^- ) by the catalyst of the electrode layer formed on both sides of the electrolyte membrane, and hydrogen ions are selectively decomposed into cation exchange membranes The electrons are transferred to the cathode through a gas diffusion layer (GDL) and a bi-polar plate, which are conductors.

In the cathode, the hydrogen ions supplied through the electrolyte membrane and the electrons transferred through the separator meet with oxygen in the air supplied to the cathode by the air supplier to generate water. Due to the movement of the hydrogen ions generated in this process, And the heat is generated incidentally from the water production reaction.

In such a fuel cell stack, separators for guiding air and fuel to the anode and cathode sides are laminated. At this time, the efficiency and safety of the fuel cell are ensured only when the separators are completely sealed so that the air and the fuel that are transferred through the flow path formed in the inside are not leaked. Therefore, the pre-inspection of the separation plate constituting the fuel cell stack as described above must be completed.

However, in the past, a device for inspecting the separator for the fuel cell stack has not been proposed. Therefore, the inspection is performed manually and requires a long time, and manpower is added.

Korean Patent Publication No. 10-20112-0053881 (May 29, 2012) Korean Patent Registration No. 10-1643905 (Jul. 25, 2016)

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in view of the above problems, and it is an object of the present invention to provide a separator plate inspecting apparatus for a fuel cell stack that can check whether a separator for a fuel cell stack is leaked in advance.

In order to achieve the above object, the present invention can provide the following embodiments.

A preferred embodiment of the apparatus for inspecting a separator for a fuel cell stack according to the present invention is characterized by comprising a supply member for supplying a sample, A separating plate for fuel cell stack, a fixing member for supporting and fixing the separating plates sequentially stacked, and a pressing member for pressing the upper side of the separating plates stacked on the fixing member by lowering the rotating shaft and the ascending / And the supply member includes measurement display means for supplying the sample through the pipe connected to the fixing member and measuring the pressure or flow rate of the sample filled in the flow path of the separation plates, An injection port through which the pipe of the supply member is connected so as to be able to be transferred by the flow path, It is possible to provide a separate board inspection apparatus for a fuel cell stack including a discharge port for discharging.

Therefore, the present invention can preliminarily inspect the leakage of the separator for a fuel cell stack, thereby preventing product failure and improving reliability.

In addition, the present invention is capable of simultaneously conducting leakage of a large number of separators at a time, thereby greatly reducing inspection time.

1 is a front view showing a separator plate inspecting apparatus for a fuel cell stack according to the present invention.
2 is a side view showing a separator plate inspecting apparatus for a fuel cell stack according to the present invention.
3 is a simplified view of a supply member of a separator plate inspecting apparatus for a fuel cell stack according to the present invention.
4A and 4B are views showing a fixed end plate.
5A to 5C are views showing the sealing plate.
6A and 6C are views showing a cover plate.
7 is a view for explaining an example of a lamination process of the separator.

For a better understanding of the present invention, a preferred embodiment of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified into various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. The present embodiments are provided to enable those skilled in the art to more fully understand the present invention.

Therefore, the shapes and the like of the elements in the drawings can be exaggerated to emphasize a clear explanation. It should be noted that in the drawings, the same members are denoted by the same reference numerals. Further, detailed descriptions of well-known functions and configurations that may be unnecessarily obscured by the gist of the present invention are omitted.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a separator inspection apparatus for a fuel cell stack according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a front view showing a separator plate inspecting apparatus for a fuel cell stack according to the present invention, and FIG. 2 is a side view thereof.

1 and 2, an apparatus for inspecting a separator 400 for a fuel cell stack according to the present invention includes a fixture 300 for securing a separator 400 for a fuel cell stack in a closed state, A supporting member 200 for supporting the pressing member 100, a supplying member 600 for supplying gas to the fixing member 300, and a holding member 300 for holding the pressing member 100, And a support plate 500 for supporting the support member 200.

The pressing member 100 includes a lifting plate 120 which is lifted and lowered, a pressing block 130 fixed to the lower surface of the lifting plate 120 to press the separating plate 400, A rotating shaft 140 for moving the lifting plate 120 upward and downward and a plurality of guide rods 150 for supporting and guiding the lifting plate 120. [

The guide rod 150 is fixed to the upper surface of the support plate 500 so that a plurality of the guide rods are erected.

The lifting plate 120 is moved up and down according to the rotation of the rotating shaft 140. Here, the lifting plate 120 is coupled to the center portion of the rotating shaft 140 so that the rotating shaft 140 is communicated with the center of the lifting plate 120, and a plurality of guide rods 150 are communicated about the rotating shaft 140. Therefore, the lifting plate 120 is lifted and lowered in the vertical direction by the rotation shaft 140 in accordance with the guide of the guide rod 150 by the rotational force.

The rotating shaft 140 is formed with a screw to be coupled to the inner surface of the lifting plate 120 at an outer surface communicating with the lifting plate 120 and integrally connected to the handle 110 at an upper end thereof, Respectively. Accordingly, the rotating shaft 140 is rotated in the rotating direction of the handle 110 to move the lifting plate 120 up and down.

Here, the lifting plate 120 is rotated by the rotation of the handle 110 Interlocking  But the present invention is not limited thereto, and it is also possible to provide a lifting structure using a hydraulic system such as a hydraulic cylinder (not shown).

For example, in another embodiment of the present invention, Follow the instructions on the guide rod 150 and a lift plate 120 so that the elevating, implemented such that the lifting plate by a hydraulic cylinder rather than above the rotating shaft 140 may be elevating along the outer surface of the rotation axis (or the supporting bar) . At this time, the lifting and lowering of the lifting plate 120 by the hydraulic pressure includes a sensor for sensing the position of the lifting plate 120 instead of the handle 110, a plurality of switches for setting the operation of the hydraulic cylinder on and off, / or a lever or the like can be further included.

The pressing block 130 presses the separating plates 400 stacked by the fixing member 300, which are composed of downward blocks (for example, a flat bottom flat structure) at one side of the lifting plate 120 . Here, the pressing block 130 may be provided with an elastic material 131 at a contact portion to absorb an impact upon contacting and pressing.

The supporting member 200 includes a fixing plate 210 to which upper ends of the guide bars 150 are connected and fixed and a vertical plate 220 connected to be erected at one side of the fixing plate 210.

The upper end of the guide rod 150 is fixed to the lower surface of the fixed plate 210, and the rotating shaft 140 is connected to the handle 110 from the lower side. That is, the guide plate 150 is rotatably installed on the upper surface of the fixed plate 210, and a plurality of guide rods 150, which are erected from the support plate 500, are connected to the lower surface.

The vertical plate 220 supports a measurement display means 650, which will be described later, as a plate material that is vertically upright on one side of the fixed plate 210.

The supply member 600 will be described with reference to Fig. Fig. 3 is a simplified view of the supply member 600 in the present invention.

3, the supply member 600 includes a supply pipe 610 through which a sample is injected from an external supply device (not numbered) to the stationary member 300, A switch for opening and closing the supply pipe 610 and the branch pipe 640 and a switch for switching the pressure of the supply pipe 610 and the branch pipe 640 And a measurement display means 650 for measuring and displaying the measurement result.

The supply pipe 610 opens the first switch 631 and transfers the sample delivered from the external supply device to the branch pipe 640. Here, the sample can be arbitrarily selected by the user as a gas or a liquid. Hereinafter, the samples are collectively referred to as a gas.

The branch pipe 640 branches at least two from the supply pipe 610 and transfers the gas to the fixing member 300. The branch pipe 640 may be connected to the injection pipe of the fixing member 300 and the second switch 632 may be provided to open and close the pipe.

The measurement display means 650 corresponds to, for example, a pressure gauge (or flow meter) that displays an internal pressure (or flow rate) as a long hand and a short hand as a dial gauge. That is, the measurement display means 650 can be variously selected depending on the type of the sample. Hereinafter, the sample to be supplied to the fixing member 300 is limited to a gas, but the invention is not limited thereto. A liquid having a color of oil may also be used as a sample.

The filter 620 removes foreign matter (dust or moisture) contained in the gas initially supplied from the supply pipe 610. The filter 620 in the supply pipe 610 is not described in detail as it is generally known in the art.

The fixing member 300 includes a fixed end plate 310 fixed to the upper surface of the support plate 500, a sealing plate 320 supported between the separation plate 400 and the separation plate 400 to prevent leakage , A cover plate 330 for sealing the sealing plate 320 and the separating plates 400 stacked on the uppermost side and a cover plate 330 for supporting the separating plate 400 and the sealing plate 320 in a standing And alignment pins 340 and fixing pins 350 that are erected on the fixed end plate 310 and fix the separation plate 400 and the sealing plate 320 to each other.

The alignment pins 340 are erected on the upper surface of the plurality of fixed end plates 310. Here, the alignment pins 340 are spaced apart from each other to guide the region where the separation plate 400 and the sealing plate 320 are stacked. That is, a plurality of alignment pins 340 may be formed to have a width and a width of the separation plate 400 and the sealing plate 320 so that the separation plate 400 and the sealing plate 320 can be stacked in the area shown by a dotted line in FIG. They are spaced apart considering the length.

The fixing pins 350 are each formed as a pair standing upright on both sides of the upper surface of the fixed end plate 310. Here, the fixing pin 350 communicates through holes formed in the separating plate 400, the sealing plate 320, and the cover plate 330, respectively. That is, the separation plate 400, the sealing plate 320, and the cover plate 330 are connected to the fixing pin 350, and are sequentially stacked on the upper surface of the final end plate.

The fixed end plate 310, the sealing plate 320, and the cover plate 330 will be described with reference to FIGS.

4A is a plan view of the fixed end plate 310, and FIG. 4B is a sectional view taken along line A-A 'of the fixed end plate 310. FIG.

4A and 4B, the fixed end plate 310 includes a fixed body 311 fixed on the upper surface of the support plate 500, and an injection port 310 connecting the branch pipe 640 from one side of the fixed body 311. [ A first flow path groove 310 connected to the injection port 310a and a second flow path groove 313 connected to the discharge port 310b; A fixed inner groove 314 which is turned inward so that the fine flow path of the plate 400 is positioned and a fixed O-ring 315 which seals the fixed inner groove 314.

The fixing body 311 is fixed on the upper surface of the support plate 500 and the alignment pin 340 and the fixing pin 350 described above are fixed on the upper surface in an upright state. Here, the separation plate 400 and the sealing plate 320 are fastened to and stacked on the fixing pin 350 in the region (a) spaced apart from the alignment pins 340.

The injection port 310a transfers the gas supplied to the branch pipe 640 to the first flow path groove 312 and the discharge port 310b transfers the gas discharged through the second flow path groove 313 to the connected discharge pipe do.

Here, the discharge port 310b may further include a third switch 633 capable of opening and closing the pipeline.

The third switch 633 is interrupted when the first switch 631 and the second switch 632 are opened and then the internal pressure is increased.

The first flow path groove 312 is formed downward from the upper surface of the fixed body 311, and the flow path is connected to the injection port 310a inwardly. The first flow path groove 312 transmits the gas supplied through the injection port 310a to the flow path formed by the separator plate 400, the sealing plate 320 and the cover plate 330 stacked on the upper surface.

The second flow path groove 313 is formed downward from the upper surface of the fixed body 311, and the flow path is connected inward to the discharge port 310b. Therefore, the second flow path groove 313 transfers the gas transferred to the flow path formed by the separator plate 400 and the sealing plate 320 stacked on the upper surface to the discharge port 310b.

Here, the first flow grooves 312 and the second flow grooves 313 may be provided in pairs as a pair aligned in the same direction. Further, the shape may be provided so as to coincide with the flow path shape of the separator plate 400.

In addition, the discharge port 310b is opened and closed by the third switch 633. The gas introduced through the first flow path groove 312 is discharged to the discharge port 310b through the second flow path groove 313 when the third switch 633 is rotated and the discharge port 310b is opened.

The fixed inner grooves 314 are formed so as to be inwardly inward from the upper surface of the fixed body 311 as areas where fine flow paths respectively formed on the upper surface and / or lower surface of the separation plate 400 are located.

The fixed O-ring 315 is fixed at a boundary point between the upper surface of the fixed body 311 and the fixed inner groove 314 to seal the spaced space between the fixed inner groove 315 and the separation plate 400.

Here, the separator plate 400 is a separator plate 400 generally applied to the fuel cell stack. The separator plate 400 is connected to the first and second flow grooves 312 and 313, And a plurality of micro flow passages (not shown) are formed to be inwardly inwardly of a region corresponding to the fixed inner groove 314 of the fixed body 311. [

In summary, the separator plate 400 has a flow path structure that can communicate with the fixed end plate 310, the cover plate 330, and the sealing plate 320. This is because the separator plate 400 for a fuel cell stack according to the present invention is applied to the separator plate 400 for the fuel cell stack, which is well known to those skilled in the art. Therefore, the configuration of the separation plate 400 is not described and the detailed configuration is omitted.

Fig. 5A is a plan view showing the sealing plate, and Fig. 5B is a bottom view showing the sealing plate.

5A and 5B, the sealing plate 320 may be made of a rigid plastic material or metal to protect the separation plate 400 from the pressure applied from the upper side by being stacked on the upper surface of the separation plate 400 . It is preferable that the sealing plate 320 is formed with a separation plate 400 and a flow path structure through which the gas is transferred so as to be connected to the fixed end plate 310 and the cover plate 330.

More specifically, the sealing plate 320 includes a reinforcing main body 321 having the same shape as the separating plate 400, a reinforcing inner groove 325 which is inwardly directed from the central region of the reinforcing main body 321, A reinforcing O-ring 326 which seals between the first and second flow grooves 312 and 325 and the separating plate 400 and a reinforcing O-ring 326 formed at both sides of the reinforcing inner groove 325 at the same positions as the first flow grooves 312 and the second flow grooves 313 And a reinforcing through hole 324 formed so as to communicate with the first reinforcing flow hole 322, the second reinforcing flow hole 323, and the fixing pin 350.

The reinforcement main body 321 has the same shape and size as the separation plate 400 so as to be stacked on the upper surface of the separation plate 400 and is pressed onto the separation plate 400 by the pressurized pressure, (400).

The reinforcing inner groove 325 is formed to be inwardly in a region where one side or both sides of the reinforcing main body 321 coincides with a region where the microchannel of the separating plate 400 is formed. The reinforced inner groove 325 may form a space separated from the micro flow path of the separation plate 400 to impart the directionality of the injected gas.

The reinforcing O-ring 326 is fixed in the form of surrounding the reinforcing inner groove 325 on one side of the reinforcing main body 321 to closely contact the reinforcing inner groove 325 and the separating plate 400. Here, the reinforcing O-ring 326 can be fastened and fixed to the adhesive or reinforcing main body 321 in an insertion groove which is separately inward.

The first reinforcement flow hole 322 is formed at a position corresponding to the first flow groove 312 to transmit the gas supplied from the supply member 600 and the second reinforcement flow hole 323 is communicated with the second flow passage 322, And is formed at a position coincident with the groove 313 to transfer the supplied gas. Here, the first reinforcing passage hole 322 and the second reinforcing passage hole 323 are formed to be positioned diagonally with respect to each other with the reinforcing inner groove 325 interposed therebetween, and this is not limitative.

The reinforcing through holes 324 are formed at both sides of the reinforcing inner groove 325, and the fixing pins 350 are communicated with each other. That is, in the reinforcing through hole 324, for example, the sealing plate 320 is laminated with the separating plate 400 interposed therebetween. At this time, the sealing plate 320 is stacked on the upper surface of the separating plate 400 by connecting the fixing pin 350 to the reinforcing through hole 324. That is, the reinforcing through hole 324 allows the position of the sealing plate 320 to be set and fixed by the fixing pin 350.

6A is a plan view of the cover plate, and FIG. 6B is a bottom view of the cover plate.

6A and 6B, the cover plate 330 seals a flow path formed by the separating plate 400 and the sealing plate 320, which are installed on the uppermost side of the laminated separation plates 400 and stacked on the lower side . The cover plate 330 includes a cover main body 331 and a cover inner groove 335 which is inwardly directed from the lower surface of the cover main body 331 in a region opposed to the micro flow path of the separation plate 400, A first cover channel groove 332 communicating with the flow path of the separation plate 400 and the sealing plate 320 and a second cover channel groove 332 communicating with the channel of the separation plate 400 and the sealing plate 320, 333, and a cover through hole 334 through which the fixing pin 350 communicates.

The cover body 331 is formed in the same shape and size as the separating plate 400 and the sealing plate 320 and stacked on the upper surface of the separating plate 400 positioned on the uppermost side. The cover body 331 is made of a plastic or metal material having a predetermined thickness so as to prevent damage due to the pressure applied by the pressing block 130 due to the direct descent of the lifting plate 120 .

The cover inner groove 335 is formed inward as a region opposed to the micro flow path of the separator plate 400 on one side of the cover body 331. Therefore, the groove 335 in the cover forms a space by forming a spaced space between the separation plates 400.

The first cover channel grooves 332 may be formed in pairs on the lower surface of the cover body 331 in the diagonal direction with the cover inner groove 335 interposed therebetween. It is possible to deform according to the shape of the protrusion. The first cover flow path groove 332 is formed by a groove which is inwardly directed from the lower surface of the cover plate 330 and passes through the flow path formed in the separation plate 400 and the sealing plate 320, And is connected to the flow path groove 312.

The second cover channel grooves 333 may be formed on the lower surface of the cover body 331 in a pair of diagonally opposite directions with the cover inner groove 335 interposed therebetween. The second cover flow path groove 333 is connected to the flow path communicating with the sealing plate 320 and the separation plate 400 from the second flow path groove 313 of the fixed end plate 310.

The cover through hole 334 is formed through the cover inner groove 335 and is formed so as to communicate with the fixing pin 350.

7 is a view showing an example of a lamination process of the fixed end plate, the separating plate, the sealing plate and the cover plate.

7, the separation plate 400 is connected to the fixing pin 350 so as to be stacked in an area defined by the alignment pins 340 erected on the upper surface of the fixed end plate 310. [ Then, the sealing plate 320 is lowered after the fixing pin 350 is connected to the reinforcing through hole 324, and is stacked on the upper surface of the separating plate 400. The other separating plate 400 is stacked on the upper surface of the sealing plate 320 while communicating with the fixing pin 350.

In this manner, when the separating plate 400 and the sealing plate 320 are alternately stacked on the upper surface of the lowermost fixed end plate 310 and the set height or the set number of the separating plates 400 are stacked, The cover plate 330 is laminated. The cover plate 330 is stacked on the upper surface of the separating plate 400 located at the uppermost position after the fixing pin 350 is communicated with the cover through hole 334 and then downward.

The fixed end plate 310 and the separator plate 400 are separated from each other by the spaced space between the fixed inner groove 314 and the separating plate 400 through the fixed O-ring 315 surrounding the fixed inner groove 314, The sealing plate 320 and the separating plate 400 are sealed by the reinforcing O ring 326 enclosing the outside of the reinforcing inner groove 325 and the cover plate 330 and the separating plate 400 And is sealed by the O-ring surrounding the cover inner groove 335.

The present invention includes the above-described configuration. Hereinafter, operations achieved through the above-described configuration will be described in more detail with reference to FIGS. 1 to 7.

First, the worker stacks the separating plate 400 and the sealing plate 320 alternately on the upper surface of the fixed end plate 310, and then stacks the cover plate 330 on the uppermost layer. At this time, the stacked separation plates 400 to 320 are located in the region (a) defined by the alignment pins 340 spaced apart from each other in the front-rear direction, and each of the pair of fixing pins 350 are connected to each other.

Thereafter, when the stacking of the separation plate 400 is completed in the above-described manner, the operator rotates the handle 110 to lower the lifting plate 120. Here, the lifting plate 120 is screwed to the rotating shaft 140 connected to the handle 110 and fastened to a plurality of guide rods 150. The lifting plate 120 is lowered along the outer surface of the guide rod 150 when the rotating shaft 140 is rotated according to the rotating direction of the handle 110. [

Here, the worker presses the handle 110 until the lower surface of the pressing block 130 fixed on the lower surface of the lifting plate 120 comes into contact with the upper surface and the handle 110 is not rotated or it is determined that a proper pressure is applied. .

In addition, the lower surface of the pressing block 130 may be further provided with an elastic material 131 to prevent damage when the lower surface of the pressing block 130 contacts the cover plate 330.

Accordingly, the plurality of separation plates 400 and the sealing plate 320 stacked on the upper surface of the fixed end plate 310 are pressed by the pressure applied from the upper side. At this time, as the sealing plate 320 is positioned between the separation plates 400, the separation plate 400 is supported from the pressure applied from the upper side. Therefore, the separation plates 400 can be prevented from being damaged in the inspection process.

In addition, as described above, the present invention is not limited to the above-described lifting plate 120 that is manually implemented by the handle 110, and the lifting plate 120 Up and down  The structure is also within the scope of the technical idea of the present invention Applicable  will be.

Then, the operator  The external supply device and / or the piping connected thereto are connected to the supply pipe 610 Connected  After the first switch 631 and the second switch 632 are opened, Third switch The tooth 633 is cut off.

In addition, the operator confirms the pressure of the gas injected through the external supply device through the measurement display means 650 to check whether the internal pressure of the separation plates 400 reaches the set pressure, and when the set pressure is reached, The switch 631 and the second switch 632 are rotated to cut off the supply gas. At this time, the filter 620 rings the filter 620 with foreign substances contained in the gas.

Then, the operator continuously confirms the measurement display means 650 and confirms whether or not the separation plates 400 are defective by confirming whether or not the set pressure is maintained for the set time. For example, if the pressure measured by the measurement display means 650 is gradually lowered than the initially set pressure, it means that leakage has occurred from the stacked separators 400.

Accordingly, when a pressure change occurs through the measurement display means 650, the operator removes one of the stacked separating plates 400 from the upper side one by one and conducts the measurement again as described above, ) Can be finally detected.

That is, in order to release the uppermost separator plate 400, the operator rotates the third switch 633 to open the discharge port 310b to discharge all of the internal gas. Then, the separation plate 400 positioned on the uppermost side is separated from the fixing pin 350, and then the cover plate 330 is stacked again, and the pressure is measured by supplying the gas through the above-described process. Therefore, the operator can repeat the above process to finally confirm the broken plate 400 that has failed.

As described above, when the gas supplied to the separation plates 400 is used as an oil-colored liquid, a color sample can be confirmed on the outside in the separation plate 400 where leakage occurs. Therefore, Can be omitted. At this time, the measurement display means 650 can be replaced as a flow meter capable of measuring and displaying the internal flow rate.

As described above, according to the present invention, it is possible to check the leakage of the fuel in the separating plates 400 for the fuel cell stack in advance, thereby preventing the defects of the products in advance. Particularly, Safe inspection can be performed, and a large number of separators can be inspected at the same time.

The embodiments of the separator inspection apparatus for a fuel cell stack of the present invention described above are merely illustrative and those skilled in the art can make various modifications and equivalent other embodiments You can see that it is.

Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

100: pressing member 110: handle
120: lift plate `130: pressure block
131 elastic material 140 rotational axis
150: guide rod 200: support member
210: stationary plate 220: vertical plate
300: Fixing member 310: Fixed end plate
310a: Inlet port 310b: Outlet port
311: Fixing body 312: First flow groove
313: second flow channel groove 314: fixed inner groove
315: fixed O-ring 320: sealing plate
321: reinforcing main body 322: first reinforcing channel ball
323: second reinforcing flow hole 324: reinforcing through hole
325: reinforcement inner groove 326: reinforcing o-ring
330: cover plate 331: cover body
332: first cover channel groove 333: second cover channel groove
334: cover through hole 335: cover inner groove
336: cover o-ring 340: alignment pin
350: fixing pin 400: separating plate
500: support plate 600: supply member
610: Supply piping 620: Filter
631: first switch 632: second switch
633: third switch 640: branch piping
650: Measurement display means

Claims (7)

A supply member (600) for supplying a sample, which is either gas or liquid, selected;
A separation plate 400 for a plurality of fuel cell stacks stacked so as to form a flow path through which gas or liquid can flow;
A fixing member 300 for supporting and fixing the separation plates 400 sequentially stacked; And
And a pressing member 100 for pressing the upper side of the separating plates 400 stacked on the fixing member 300 by lowering the lifting plate 120 screwed with the rotating shaft 140,
The supply member 600 includes a measurement display unit 650 for supplying a sample through a pipe connected to the fixing member 300 and measuring a pressure or a flow rate of the sample filled in the flow path of the separation plates 400 and,
The fixing member 300 includes an injection port 310a through which the piping of the supply member 600 is connected so as to transfer the sample supplied from the supply member 600 to the flow path, And a discharge port (310b) for discharging the filled sample.
2. The apparatus of claim 1, wherein the fixing member (300)
A fixed end plate 310 having a plurality of flow grooves communicating with the flow paths of the injection port 310a and the separation plates 400 and transferring the sample to the flow channels of the separation plates 400 sequentially stacked on the upper surface );
A plurality of sealing plates 320 stacked between the separation plates 400 to support a pressure applied from the pressing member 100; And
And a cover plate 330 laminated on the upper surface of the separating plate 400 located at the uppermost one of the separating plates 400,
Wherein the fixed end plate (310), the sealing plate (320), and the cover plate (330) are formed with a flow path connected to the flow paths of the separation plates (400).
3. The apparatus of claim 2, wherein the fixed end plate (310)
A fixing body fixed to the upper surface of the support plate 500;
A flow groove connected to the injection port (310a) to the inside of the fixed body and formed at a position corresponding to the flow path of the separation plate (400) with its top surface opened;
A fixed inner groove (314) formed as an inwardly directed groove on one surface of the fixing body (311) so as to form a space separated from the separating plate (400) to be stacked; And
And a stationary O-ring (315) fixed to an outer side of the fixed inner groove (314) to seal a bonding site with the separating plate (400).
2. The apparatus of claim 1, wherein the fixing member (300)
And an alignment pin (340) for setting and guiding an area where the plurality of separation plates (400) are stacked upright so as to be spaced apart from each other.
The apparatus of claim 1, wherein the separation plates (400)
At least one through-hole communicating with each other is formed,
The fixing member 300 further includes at least one fixing pin 350 that is erected upright so as to communicate with the through holes of the separating plates 400 to fix the separating plates 400. [ Plate inspection device.
3. The apparatus of claim 2, wherein the sealing plate (320)
A plurality of reinforcement channel holes formed so as to be connected to the flow channels of the separation plates 400;
A reinforcing inner groove (325) made of an inwardly grooved surface on one side in contact with the separating plates (400); And
And a reinforcing O-ring (326) fixed along the edge of the reinforcing inner groove (325) to seal the spaced space between one side of the separating plate (400) and the reinforcing inner groove (325) Plate inspection device.
3. The apparatus of claim 2, wherein the cover plate (330)
At least one channel groove connected to a channel of the separation plates 400 as an inwardly grooved groove at a lower surface thereof;
A cover inner groove (335) formed as an inwardly grooved groove on one side of the separating plate (400) and spaced apart from the separating plate (400); And
And a cover O-ring (336) fixed along an edge of the cover inner groove (335).

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