KR100837929B1 - Assembling device for a stack of a fuel-cell - Google Patents

Abstract

A fastener for a fuel cell stack is provided to allow the fastening force of a fuel cell stack to be maintained to be constant by controlling the tension of a strip automatically even if the fastening force is changed. A fastener for a fuel cell stack comprises a plurality of strips(210) whose one end is fixed to one side of a pair of end plates(110,120) of a stack(100) and surrounds the outer circumference of the stack, and whose the other end is fixed to the other side of the end plates; a plurality of support members(220) which are installed so as to face to the both corners of the other end plate of the pair of end plates and is installed at the position where the strips pass by so as to support the strips; and a tension control member(230) which is installed on the end plate where the support members are installed and between the support members facing each other and controls the tension of the strips so as to allow the pressurization to the strip to increase if the tension weakens.

Description

Assembling device for a stack of a fuel-cell

1 is a cross-sectional view showing a band strip for fastening a conventional fuel cell stack.

Figure 2 is a cross-sectional view showing a tie bolt for fastening a conventional fuel cell stack.

Figure 3 is a perspective view showing a stack fastening mechanism of the fuel cell according to the present invention.

Figure 4 is a perspective view showing a tension adjusting member of the stack fastening mechanism according to the present invention.

5 is a perspective view showing a supporting member of the stack fastening mechanism according to the present invention.

Figure 6 is a schematic diagram showing the operating principle of the stack fastening mechanism according to the present invention.

Figure 7 is a graph showing the spring reaction force according to the tension adjusting member of the stack fastening mechanism according to the present invention.

* Explanation of symbols for the main parts of the drawings

100: fuel cell stack 200: stack fastening mechanism

210: strip 220: support member

222: roller portion 224: roller support portion

230: tension adjusting member 232: spring

234: strip pressing portion 234: spring support

240: volts

The present invention relates to a stack fastening mechanism of a fuel cell, and more particularly, to a stack fastening mechanism of a fuel cell capable of automatically adjusting and maintaining a fastening force of a stack.

In general, a fuel cell stack has several tens to hundreds of unit cells stacked on both sides of the fuel cell stack, and end plates are supported at both ends thereof. The unit cell has a gas diffusion layer coupled to both sides of the polymer electrolyte membrane and separated from the gasket. The plates are each composed of a combination.

As one method of evaluating the efficiency of such a fuel cell stack, the strength of the current output through the electrodes formed at both ends of the separator may be used, and the surface pressure between the separator and the separator affects the strength of the current.

If the surface pressure is too small, the contact resistance between the separators may increase, so that no current flows. If the surface pressure is excessive, the gas diffusion layer may be compressed and gas diffusion may not occur efficiently. Therefore, there is a predetermined surface pressure with the highest generated current strength, and a fastening device is mechanically provided outside the fuel cell stack to adjust the surface pressure.

1 and 2, in the related art, the end plates 3 located at both ends of the fuel cell stack 1 are fastened with a band strip 5 or a long tie bolt 7 or the like.

By the way, since the gasket is made of rubber material among the components constituting the fuel cell stack, there is a Visco-Elastic (viscoelastic) characteristic, the initial tightening force tends to decrease over time. In addition, since the gasket has a different characteristic depending on the temperature at which the fuel cell stack operates, there is a problem in maintaining a uniform clamping force by affecting the clamping force of the band strip or tie bolt fastened with an appropriate clamping force during initial tightening.

SUMMARY OF THE INVENTION An object of the present invention is to provide a stack fastening mechanism of a fuel cell which can automatically adjust and uniformly maintain a fastening force of a fuel cell stack.

In order to achieve the above object, the present invention is a fuel cell stack having a pair of end plates for supporting a plurality of unit cells, one end is fixed to one side of the pair of end plates and the fuel cell A plurality of strips of which the other end is fixed to the other side of the end plate after being enclosed along the outer circumferential surface of the stack; A plurality of support members, each of which is installed at both corners of the other of the pair of end plates so as to face each other, and are installed at a position where the strip passes, and supports the strip; And a support member installed on an end plate on which the support member is installed, and between the support members facing each other. When the tension of the strip is weakened, the force to press the strip increases, and when the tension of the strip is strong, the strip is increased. It provides a stack fastening mechanism of the fuel cell, characterized in that it comprises a tension adjusting member for adjusting the tension of the strip by elastically pressing the strip so as to reduce the pressing force.

The support member includes a cylindrical roller portion that contacts the strip and supports the strip, and a roller support portion that is rotatably supported at right angles corresponding to the edge shape to rotatably support the roller portion and to be tightly coupled to the edge of the end plate. Characterized in that.

The tension adjusting member is coupled to the spring and the strip pressing portion which is mounted on the lower portion of the spring to press the strip along the direction of movement of the spring, the restoring force acts in the direction to press the strip, It characterized in that it comprises a spring support for fixing and supporting the upper end of the spring.

The spring is characterized in that the coil spring is installed close to the right angle with respect to the tension direction of the strip.

The strip, the supporting member and the tension adjusting member are fixed to the end plate by bolts, respectively.

Hereinafter, a stack fastening mechanism of a fuel cell according to an exemplary embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Attached Figure 3 is a perspective view showing a stack fastening mechanism of the fuel cell according to the present invention, Figure 4 is a perspective view showing a tension adjusting member of the stack fastening mechanism according to the present invention, Figure 5 is a stack fastening according to the present invention A perspective view showing a support member of the mechanism.

As shown in Figures 3 to 5, the stack fastening mechanism 200 of the fuel cell according to the present invention is fixed to both ends of the lower end plate 120 of the fuel cell stack 100 and the fuel cell stack 100 A plurality of strips 210 to be tied and fixed, the support member 220 for supporting the strip 210, the tension adjusting member 230 for adjusting the tension of the strip 210, the strip 210 and the support member 220 and a plurality of bolts 240 for fixing the tension adjusting member 230.

The strip 210 has one end fixed to the lower end plate 120 coupled to the lower side of the pair of end plates 110 and 120 of the fuel cell stack 100 with bolts 240, and the fuel cell stack 100. The other end is fixed to the lower end plate 120 along the outer circumferential surface of the fuel cell stack 100 and then bolted to the upper end plate 110 along the outer circumferential surface thereof.

Strip 210 is provided in plurality as needed, but is made of stainless steel or glass fiber reinforced plastic of 1 to 2mm in thickness, 2 to 4cm in width, but is not limited to these materials.

The strip 210 serves to fix the upper end plate 110 and the lower end plate 120 coupled to both ends of the fuel cell stack 100, respectively, and presses the end plates 110 and 120 to provide proper surface pressure. To be maintained.

As shown in FIG. 5, a plurality of supporting members 220 are installed to face each other at longitudinal edges of the upper end plate 110 through which the strip 210 passes. It reduces the resistance. Therefore, when one strip 210 passes through the upper end plate 110, each one is installed at each corner of the upper end plate 110 to support the strip 210 so that twice as much as the strip 210 used is used. . That is, when three strips 210 are used, a total of six support members 220 are required.

The support member 220 includes a cylindrical roller portion 222 that directly contacts the strip 210 to support the strip 210, and a roller support 224 that rotatably supports the roller portion 222.

Since the roller portion 222 is cylindrical and rotatably coupled to the roller support 224, the frictional resistance generated when the strip 210 is pressed and moved when the strip 210 is pressed for tension control can be effectively reduced.

The roller support part 224 is bent at right angles to correspond to the corner shape of the lower side of the portion that is coupled to the roller portion 222 so as to be in close contact with the edge of the upper end plate 110. That is, the roller support 224 has a '-' shape. The roller support 224 is fixed to the upper end plate 110 by bolts 240.

As shown in FIG. 4, the tension adjusting member 230 is installed on the upper end plate 110 to be positioned between the support members 220 facing each other to adjust the tension of the strip 210. .

The tension adjusting member 230 includes a spring 232 elastically pressing the strip 210, a strip pressing portion 234 mounted on the lower end of the spring 232 to directly press the strip 210, and a spring 232. It is composed of a spring support 236 for fixing and supporting.

The spring 232 is a compression coil spring is installed perpendicular to or perpendicular to the tension direction of the strip 210, the pressure to the strip 210 is installed so that the direction in which the restoring force of the spring 232 acts the strip ( 210 is elastically pressed. When the tension of the strip 210 decreases, the reaction force of the spring 232 increases, which pushes the strip 210 further, and when the tension of the strip 210 increases, the spring 232 is pushed by the strip 210. Compression reduces the reaction force of the spring 232, thereby reducing the force for pressing the strip 210. By this principle, the tension of the strip 210 is automatically adjusted.

The strip pressing portion 234 is mounted on the bottom of the spring 232 to press the strip 210, it is preferable that the length is slightly longer than the width of the strip 210 in order to easily press the strip 210. The strip pressing portion 234 moves along the compression and tension direction of the spring 232, which is indicated by arrows in FIG. 4.

The spring support 236 has a '┏┓' shape, and fixes the upper end of the spring 232 to the inner side of the downward opening. The spring support part 236 is fixed to the upper end plate 110 by inserting a bolt 240 into the upper surface of which the upper end of the spring 232 is fixed.

In the stack fastening mechanism of a fuel cell according to an embodiment of the present invention having such a configuration, the principle of adjusting tension is briefly described as follows.

6 is a schematic view showing the operating principle of the stack fastening mechanism according to the present invention, Figure 7 is a graph showing the spring reaction force according to the tension adjusting member of the stack fastening mechanism according to the present invention.

The strip 210 fastened to the fuel cell stack 100 has a shape as shown in FIG. 6 by the support member 220 and the tension adjusting member 230.

For example, as shown in the figure, if using the three strips 210 to maintain the fastening force of 3000kg _f , each of the strips 210 is applied to the tension of 500kg _f each. If the tension is T = 500kg _f , the reaction force R = 2 × T × cos (π / 4-θ / 2) of the roller, and the reaction force F of the spring 232 is a function of θF _y = 0 = -2 × T + 4 × T × cos ² (π / 4-θ / 2) -F, and F = -2 × T + 4 × T × cos ² (π / 4-θ / 2). Therefore, the reaction force F of the spring 232 is 0 when θ = 0, and as the θ increases, the spring reaction force F also increases, but at a small θ value, the spring reaction force F also has a very small value.

That is, the spring 232 can adjust the large tension by only a small force to press the strip 210 has the effect of reducing the volume or weight of the tension adjusting member 230, including the spring 232.

FIG. 7 illustrates the reaction force F of the spring 232 according to the angle θ at which the spring 232 presses the strip 210, for example, when θ, the first value A of FIG. 7, is 0.7 degrees. This means that a 10kg _f spring reaction force can give a 500kg _f strip tension.

According to this principle, even if the clamping force of the strip varies depending on the operating temperature of the fuel cell stack, the tension adjusting mechanism automatically adjusts and maintains the tension of the strip to maintain the clamping force of the fuel cell stack uniformly and maintain proper surface pressure. It works.

Meanwhile, the present invention is not limited to the above-described embodiments, and any person having ordinary skill in the art to which the present invention pertains may make various modifications without departing from the gist of the present invention as claimed in the claims. Of course, such changes will fall within the scope of the claims set forth.

As described above, the stack fastening mechanism of the fuel cell according to an embodiment of the present invention is a tension control mechanism automatically adjusts and maintains the strip tension of the fuel cell stack even if the fastening force required to fasten the fuel cell stack is changed. There is an effect that can maintain a fastening force uniformly.

Claims (5)

In the fuel cell stack 100 is provided with a pair of end plates (110, 120) for supporting a plurality of unit cells, A plurality of strips, one end of which is fixed to one side of the pair of end plates 110 and 120 and is enclosed along the outer circumferential surface of the fuel cell stack 100, and the other end of which is fixed to the other side of the end plate 110. 210; A plurality of support members 220 are installed at both corners of the other end of the pair of end plates 110 and 120 so as to face each other, but are installed at a position where the strip 210 passes, and support the strip 210. ; And The support member 220 is installed on the end plate 110 is installed between the support member 220 facing each other, when the tension of the strip 210 is weakened to press the strip 210 When the force is increased and the tension of the strip 210 is increased, the tension adjusting member for elastically pressing the strip 210 to adjust the tension of the strip 210 so that the force for pressing the strip 210 is reduced ( Stack fastening mechanism of the fuel cell comprising a. The method of claim 1, The support member 220 is in contact with the strip 210 and the cylindrical roller portion 222 for supporting the strip 210, the roller portion 222 rotatably supports the end plate 110 The stack fastening mechanism of the fuel cell, characterized in that it comprises a roller support portion 224 bent at a right angle corresponding to the corner shape to be closely coupled to the edge of the. The method of claim 1, The tension adjusting member 230 is a spring 232 to which the restoring force acts in the direction of pressing the strip 210, and is mounted to the lower portion of the spring 232 to the strip along the direction of movement of the spring 232 A fuel cell comprising a strip pressing portion 234 for pressing 210 and a spring support portion 236 coupled to the end plate 110 to fix and support an upper end of the spring 232. Stack fasteners. The method of claim 3, The spring (232) is a stack fastening mechanism of the fuel cell, characterized in that the coil spring is installed close to the right angle with respect to the tension direction of the strip (210). The method according to any one of claims 1 to 4, The strip 210, the support member 220, and the tension adjusting member 230 are fastened to the end plates 110 and 120 by bolts 240, respectively.

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