KR20090017825A - The connect structure of end plate - Google Patents

Abstract

A coupling structure of an end plate is provided to prevent the leak of gas generated between an end plate and an insulating plate and to save the manufacturing costs by facilitating the assembly and analysis. In a coupling structure of an end plate of a fuel battery and an insulation fiber board, a coupling structure of an end plate blocks the outflow of air and hydrogen by coupling an end plate(10), insulating plate(20), gasket(30) and coupling unit. The end plate is a 4 angular flat plate made of metal and includes a pair of an inlet and outlet(11) formed at both right and left ends; a groove(12) with the constant depth from the outside of the inlet and outlet; and a plurality of though-holes(13) tapping-processed at right and left end of the plate. The Insulating plate comprises a pair of fiber inlet and outlet(21) formed at both right and left ends; and a plurality of though-holes(22) at right and left end of the plate.

Description

The connect structure of end plate}

The present invention relates to a fastening structure for coupling an end plate and an insulating plate in a stack of fuel cells. More specifically, the end plate made of metal forms grooves having a constant depth around the mouth and the outlet, joining the gasket coated with an adhesive therein, and bolting the insulation plate on top thereof. It is an end plate coupling structure that can prevent the leakage of gas generated in between.

The present invention relates to a method of coupling an end plate and an insulating plate installed at the outermost part of a stack of a fuel cell and a fastening structure thereof.

In general, fuel cells, unlike ordinary cells that use energy from reactions of chemicals accumulated inside, are continuously produced when electricity and hydrogen are supplied to the anode plate and oxygen is supplied to the anode plate. Device. The electricity generated from a single fuel cell separator produces a relatively low voltage of 0.7V, so to produce enough power to be used as a power, it must be composed of a stack of fuel cells. The plate is constructed by stacking dozens or hundreds or more. In the fuel cell stack, separator plates are stacked to produce an appropriate amount of power, and both ends are pushed at a constant pressure to fasten the separator plates of the fuel cell. The end plate is an inlet of fluid and gas into which oxidizing gas and fuel gas are injected. And the outlet, and the collector is the end plate installed on the left and right side, the power generated through hundreds of separator plates to collect the power in one place and output to the outside It is an element in the parts.

The design of these components has complex design specifications for electrical and chemical corrosion, airtight performance of gas and fluid inlets and outlets, and combines the components to form a stack. Looking at the components of the stack of the fuel cell as described above, as follows. The fuel cell is composed of a negative electrode plate and a positive electrode plate having different flow paths and shapes to form a separator plate, and a membrane electrode and a gas diffusion layer are sequentially stacked between the separator plate and the separator plate. do. In addition, an end plate, which is a protection device for safe power generation, and a stack of fastening bars (Fix Bands) for fastening and connecting the components to the cell, are configured as one stack.

The dual endplates are one of the key components of the fuel cell stack that are connected to the current collector (Current-Collector) and protects against external shocks to the component cells. It protects against external shocks and is located at the end of the fuel cell divider, and serves as an inlet and outlet of fuel gas, oxidizing gas and cooling water, and a collector plate for collecting electricity generated by chemical reaction of hundreds of separators and catalysts. It is composed of a support or an integral part of the collector.

By the way, in the conventional manufacturing method of the fuel cell stack end plate made in this way, the adhesive is applied to the upper end of the metal end plate, and the insulating plate is attached to the upper part, and then the collector is coupled to the upper part. do. In fact, the gases entering and exiting the inlet and outlet of the end plate are hydrogen and air. In other words, the hydrogen and air flow to the current collector plate, causing a chemical reaction, converting chemical energy into electrical energy and integrating it into the collector. Therefore, hydrogen and air entering the inlet of the end plate should not leak out. The reason is that hydrogen is highly explosive due to its chemical properties, and it is necessary to block the gas leak phenomenon because it may be exploded by friction with external air and a slight temperature change.

For this reason, in the conventional end plate manufacturing method, as shown in FIGS. 1 and 2, the adhesive 2 is applied to the surface of the end plate 1, and the insulating plate 3 is adhered to the upper end thereof. Therefore, it was structured such that hydrogen and air could not escape between the end plate 1 and the insulation plate 3. However, such a conventional production method causes the following problems. That is, a lot of effort and time are required for dismantling the end plate 1 and the insulating plate 3 due to the defect generated during the manufacture of the end plate 1. The disassembly is not easy because the adhesive 2 has to be removed, and even when the disassembly is completed, the surface is not smooth, thereby producing a large problem.

In addition, the end plate 1 is made of metal, and is processed or molded in accordance with its shape with precision processing and fluorine coating, and insulated parts or insulating materials surrounding the current collector 4, and within a tolerance range of ± 0.02 mm based on the adhesive surface. The flatness of the contact surface is very strong because it must be managed, and the manufacturing time of high temperature, heat curing adhesive, finishing time to remove adhesive residue, gas leak test, gas leak test, etc. This is very difficult to handle because it takes a lot of problems and a lot of problems in the airtight performance.

The present invention is formed between the end plate and the insulating plate in a manner that the end plate is made of metal to form a groove of a certain depth groove around the mouth, the outlet to join a gasket coated with an adhesive therein and bolt the insulating plate thereon It is an object of the present invention to provide an endplate coupling structure that can prevent the leakage of generated gas in advance.

In the combined structure of the end plate and the insulated fiberboard of the fuel cell, the present invention is a quadrangular flat plate made of metal, and has a mouth and an outlet 11 formed in pairs at both ends of the fuel cell and the outside of the mouth and the outlet 11. A groove 12 having grooves having a predetermined depth, and an end plate 10 having a plurality of fastening holes 13 tapping at left and right ends of the plate; An insulating plate 20 covering the end plate 10 and having a pair of fiber inlet / outlets 21 formed at both ends of the left and right ends, and a plurality of fastening holes 22 formed at the left and right ends of the plate; A gasket 30 attached to the groove 12 of the end plate 10 through an adhesive 40; Fastening means 50 fastened to the fastening holes 22 and 13 of the insulating plate 20 and the end plate 10; The present invention relates to an end plate coupling structure in which hydrogen and air are blocked by combining.

According to the present invention, the fastening means 50 may include a buried hole 61 formed around the fastening hole 22 formed in the insulating plate 20, and a fastening bolt fastened to the buried hole 61. 62 and the circular cap 64 having a circular fitting jaw 63 formed to cover the buried hole 61 are coupled to the insulating plate 20 and the end plate 10; The adhesive 40 is an epoxy-based, silicon-based resin, a polymerization reaction of an oxygen catalyst and an organic metal catalyst, or a silica-based Ag + SiO ₂ zirconia-based MgO + ZrO ₂ or alumina-based Al, which is a combination of a basic oxide and an acid oxide. ₂ O ₃ is used; The end plate 10 is an end plate coupling structure in which one of phosphor bronze, copper, and brass can be selectively used.

The present invention combines the end plate and the insulating plate to prevent the outflow of gas leaks between the active plate by using the groove and gasket to actively block the assembly, easy disassembly is easy to reduce the manufacturing cost.

The present invention solves the initial quality problem of the manufacturing process of the current collector plate and further solves the weakening of the gas tight performance by the generation of fine gaps due to vibration and banding moment after mounting, and reduce productivity, manufacturing cost and manufacturing time.

In the combined structure of the end plate and the insulated fiber board of the fuel cell, the present invention is a quadrilateral flat plate made of metal, and has a pair of mouths and outlets 11 formed at both ends of the fuel cell and the mouth and outlet 11. There is a groove 12 having a groove having a predetermined depth to the outside, and an end plate 10 having a plurality of fastening holes 13 tapping at left and right ends of the plate, and covered with the end plate 10, and at both left and right ends thereof. There is a fiber bar inlet and outlet 21 formed in pairs and an insulating plate 20 having a plurality of fastening holes 22 formed at left and right ends of the plate. In addition, there is a gasket 30 attached to the groove 12 of the end plate 10 through an adhesive 40, and fastening holes 22 and 13 of the insulating plate 20 and the end plate 10. The fastening means 50 is fastened to is formed. Therefore, the outflow of hydrogen and air is blocked.

That is, the inlet 11 and the outlet 11 are formed in the end plate 10 as shown in the figure. The inlet 11 and the outlet 11 are each formed of two holes, hydrogen is incident on one inlet 11 and air is incident on the other inlet 11. In addition, the outlet 11 is hydrogen and air to generate electrical energy and discharge the rest. Therefore, the end plate 10 should be made of a metal material, and fastening holes 11 for fastening with bolts 62 should be provided at both ends. Of course, the outside of the inlet 11 and the outlet 11 formed in the end plate 10 is dug a groove of a predetermined depth, is produced in a state in which the groove 12 is formed.

The gasket 30 or the packing of the same shape is buried in the groove part 12, and the adhesive 40 is applied to the gasket 30 or the packing 10 firmly by the adhesive 40. In this case, the upper end of the gasket 30 may be maintained at a somewhat higher level than the surface of the end plate 10. And the upper plate is coupled to the insulating plate 20 having the same shape as the end plate 10, it is careful not to form a gap between the end plate 10 and the insulating plate 20 firmly through the fastening means (50). Combine deeply.

Then the fastening means 50 for coupling the end plate 10 and the insulating plate 20 in the present invention is preferably manufactured in the following embodiment.

As shown in the figure, the fastening means 50, there is a buried hole 61 formed around the fastening hole 22 formed in the insulating plate 20, the fastening is fastened head buried in the buried hole 61 A bolt 62 is formed, and a circular cap 64 having a circular fitting jaw 63 is formed to cover the buried hole 61. Therefore, the insulating plate 20 and the end plate 10 are fastened by combining them. That is, the fastening hole 22 formed in the outer portion of the insulating plate 20 and the fastening hole 11 formed in the outer portion of the end plate 10 are formed at the same position so that the fastening hole 11 and the fastening hole ( 22) overlap. When passing through the fastening bolt 62 in the insulating plate 20, the end is to come out of the fastening hole 11 of the end plate (10). In this case, the tapping hole 11 of the end plate 10 is formed with a tapping screw. When the fastening bolt 62 is rotated, the insulating plate 20 is tightly coupled to the end plate 10. . At this time, the head of the fastening bolt 62 is buried in the buried hole 61 formed around the fastening hole 22 of the insulating plate 20, the upper end of the head of the buried hole 61, that is, the insulating plate ( 20) Do not climb to the surface. And the circular cap 64 shown to the top of the buried hole 61 is to cover the closing hole.

In this case, the cap 64 forms a circular fitting jaw 63, so that the cap 64 is not easily removed in the state of being inserted into the buried hole 61 of the insulating plate 20, and the outer circumferential surface thereof is firmly fixed to the inner circumferential surface of the buried hole 61. It is stuck to finish the surface.

On the other hand, the adhesive 40 is an epoxy-based, silicon-based resin, a polymerization reaction of an oxygen catalyst and an organic metal catalyst or a silica-based Ag + SiO ₂ zirconia-based MgO + ZrO ₂ or alumina-based combination of a basic oxide and an acid oxide. It is preferred that Al ₂ O ₃ be used. In other words, it must be resistant to some degree of heat, and the effect of watertightness and adhesion should be maximized.

Furthermore, the end plate 10 may be used by selectively adopting phosphor bronze, copper, brass.

Reference numeral 77 not described in the drawings refers to the connect collector.

1 is an exploded perspective view showing a conventional end plate,

Figure 2 is a cross-sectional view showing a cross section of a conventional end plate,

Figure 3 is an exploded view showing the end plate coupling structure of the present invention,

Figure 4 is a view showing a state coupled to the end plate coupling structure of the present invention,

5 is a cross-sectional view showing the end plate of the present invention;

6 is a cross-sectional view showing the end plate of the present invention cut in another direction,

7 is an enlarged view of the main portion of the coupling structure of the present invention.

<Brief description of the major symbols in the drawing shown>

10; Endplate 11; Inlet, outlet

12; Groove 13; Fastener

20; Insulating plate 21; Faiba Exit

22; Fastener 50; Fastening means

61; Burial hall 62; Tightening Bolt

63; Fitting chin 64; cap

Claims (4)

In the combined structure of the end plate of the fuel cell and the insulating bar plate, A quadrangular flat plate made of metal, having mouths and outlets 11 formed in pairs on both left and right ends, grooves 12 having grooves of a predetermined depth formed outside the mouths and outlets 11, and plate left and right ends. An end plate 10 having a plurality of tapping holes 13 formed therein; An insulating plate 20 covering the end plate 10 and having a pair of fiber inlet / outlets 21 formed at both ends of the left and right ends, and a plurality of fastening holes 22 formed at the left and right ends of the plate; A gasket 30 attached to the groove 12 of the end plate 10 through an adhesive 40; Fastening means 50 fastened to the fastening holes 22 and 13 of the insulating plate 20 and the end plate 10; End plate coupling structure characterized in that the coupling to block the outflow of hydrogen and air. The method of claim 1, The fastening means 50, A buried hole 61 formed around a fastening hole 22 formed in the insulating plate 20; A fastening bolt 62 fastened to the burial hole 61 to be buried therein; A circular cap 64 having a circular fitting jaw 63 formed to cover the buried hole 61; End plate coupling structure, characterized in that by coupling the insulating plate 20 and the end plate (10). The method of claim 1, The adhesive 40, MgO + ZrO ₂ based on silica, Ag + SiO ₂ zirconia based on epoxy resin, silicone resin, oxygen catalyst and organic metal catalyst or combination of basic oxide and acid oxide, and Al ₂ O ₃ based on alumina End plate coupling structure characterized in. The end plate 10, End plate coupling structure, characterized in that one of the phosphor bronze, copper, brass can be selectively used.

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