JPH09283168A - Gas permeation testing device of separator for high molecular solid electrolyte fuel cell - Google Patents

Abstract

PROBLEM TO BE SOLVED: To quickly and surely set a separator by pressurizing a separator, which is pinched by a pair of upper and lower dummy plates, on a positioning plate with the oil pressure. SOLUTION: A separator 6 is pinched by a pair of upper and lower dummy plates 9, 10, and set on a positioning plate 5, and thereafter, a hydraulic cylinder 12 is driven so as to push a press plate 11, and the dummy plates 9, 10 are pressurized so as to fasten the separator 6 for fixation. Thereafter, test gas is fed to the dummy plate 9 so as to test the permeation of gas. The separator 6 can be thereby quickly and securely set. Since the pressure is evenly applied to the surface of the dummy plates 9, 10 and a remarkably high pressure can be applied, generation of an unevenness of a fastening load in the surface of the separator 6 is prevented, and since a clearance is not generated between the dummy plates 9, 10 and the separator 6, generation of a leak of the gas from a boundary between them is prevented, and a leak of the gas in the plate thickness direction of the separator 6 can be accurately detected.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas permeation test apparatus for evaluating and selecting gas-impermeable treated separators used for manufacturing a polymer solid oxide fuel cell stack.

[0002]

2. Description of the Related Art As shown in FIG. 7, a conventional gas permeation test apparatus for a separator that has been subjected to a gas impermeable treatment is a dummy plate for each separator 31 used to manufacture a stack for a polymer electrolyte fuel cell. After sandwiching it between the tightening plates 33 and 33 ′ via the 32 and 32 ′ and tightening and fixing it with the bolts 34, one tightening plate 33 is used as in the stack operation.
A gas is supplied from a gas inlet 35 provided in the above, and a gas leaking from a gas outlet 36 provided in the other tightening plate 33 'is measured by a flow meter (not shown), and the gas that permeates to the opposite side of the separator 31 is measured. The separator 31
Was evaluated and selected.

By the way, in such a gas permeation test device, since the separator 31 is sandwiched by the bolts 34, it takes a lot of hand to tighten the bolts 34 at a minimum of eight places, and the tightening load easily varies within the plane. Inspection reliability is low. About 20% of the electrode separators actually tested are not the gas permeation in the thickness direction of the separator, but the dummy plates 32, 3
Due to the leak from the gap with 2 ', the leak in the plate thickness direction could not be detected, and the product was sometimes mistakenly determined to be defective.

[0004]

SUMMARY OF THE INVENTION Therefore, according to the present invention, a separator for detecting a gas leak can be set quickly and surely, and the tightening load in the plane does not vary.
An object of the present invention is to provide a gas permeation test device for a polymer electrolyte fuel cell separator that can detect only gas leaks in the plate thickness direction.

[0005]

A gas permeation test apparatus for a polymer electrolyte fuel cell separator according to the present invention for solving the above problems is a press in which upper and lower surface plates are connected by two columns. Positioning plate fixed on the surface plate under the frame and press frame, a pair of upper and lower gas supply paths sandwiching the separators set on the positioning plate, dummy plates with gas discharge paths, and positioning The upper dummy plate is composed of a press plate that presses a pair of upper and lower dummy plates sandwiching a separator on the plate, and a hydraulic cylinder that is erected on a surface plate above the press frame that presses the press plate. The gas supply line is connected to the gas supply path provided on the lower side and the gas discharge path provided on the lower dummy plate is equipped with a flow meter equipped with a flow meter. It is those formed by connecting the Klein.

The press plate pressed by the hydraulic cylinder is preferably connected to the tip of the piston rod at the center through a ball joint or a spring.

Further, it is preferable that the pair of upper and lower dummy plates sandwiching the separator interpose a buffer plate and that the O-ring seals the buffer plate to sandwich the separator.

In the gas permeation test apparatus for a polymer electrolyte fuel cell separator of the present invention, a press plate is pressed by driving a hydraulic cylinder, and a separator sandwiched by a pair of upper and lower dummy plates is pressed on a positioning plate. Therefore, the electrode separator for detecting gas leak can be set quickly and surely. In addition, even pressure is applied to the dummy plate evenly within the plane, and the pressure can be made extremely high.Therefore, there is no variation in the tightening load within the plane of the separator, and there is a gap between the dummy plate and the separator. Therefore, there is no gas leak from the boundary between the dummy plate and the separator, and only the gas leak in the plate thickness direction of the separator can be accurately detected.

In the gas permeation test apparatus of the present invention, when the press plate pressed by the hydraulic cylinder is connected to the tip of the piston rod at the center through a ball joint or a spring, the upper and lower It is possible to soften the impact when the separator sandwiched between the pair of dummy plates is pressed.

Further, in the gas permeation test apparatus of the present invention, a pair of upper and lower dummy plates sandwiching the separator respectively interpose a buffer plate, and the O-ring seals the buffer plate to sandwich the separator. In this case, it is possible to eliminate the warp and damage of the dummy plate due to the pressurized gas during the gas permeation test.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of a gas permeation test device for a polymer electrolyte fuel cell separator of the present invention will be described with reference to the drawing. In FIG.
A positioning frame 5 is fixed on a surface plate 3 below the pressing frame 1 by a pressing frame formed by connecting columns 3 at four corners. On this positioning plate 5, a pair of upper and lower gas supply paths 7 and a dummy plate 9 and 10 provided with a gas discharge path 8 sandwiching a separator 6 which is a sample for a gas permeation test are set. There is.
Reference numeral 11 is a press plate for pressing a pair of upper and lower dummy plates 9 and 10 sandwiching the separator 6 on the positioning plate 5, and the center of the press plate 11 is erected on the surface plate 2 above the press frame 1. Double-acting hydraulic cylinder
It is connected to the tip of a piston rod 13 of 12. The double-acting hydraulic cylinder 12 is connected to a manual hydraulic pump 17 by super high pressure hoses 16 and 16 'equipped with pressure gauges 14 and 14' and Shannet off valves 15 and 15 '. A gas supply line 18 is connected to the gas supply path 7 provided in the upper dummy plate 9 of the pair of upper and lower dummy plates 9 and 10.
A gas leak line 20 equipped with an integrated flow meter 19 is connected to the gas discharge passage 8 provided in the lower dummy plate 10. The gas supply line 18 is provided with a regulator 21, a stop valve 22, a regulator 21, a pressure gauge 27, and a thermometer 28, and a bypass tank 29 on the way is provided with a pressure tank 30 for humidification and warming. A gas supply line 18 'is separately connected to 29, and this gas supply line 18'
Is equipped with a stop valve 22.

As shown in FIGS. 2A, 2B and 2C, the upper dummy plate 9 is provided in a rectangular concave portion 7a provided on the surface where the gas supply passage 7 sandwiches the separator 6 and in a diagonal portion of the concave portion 7a. Positioning holes 9a through which guide rods are inserted at four corners.
As shown in FIGS. 3A, 3B and 3C, the lower dummy plate 10 has a large number of parallel recessed grooves 8b formed in a shallow recess 8a provided on the surface where the gas discharge passage 8 sandwiches the separator. The gas exhaust ports 8c are provided at the opposite ends of the recessed groove 8b at the outer end, and the positioning holes 10a into which the guide rods are inserted are formed at the four corners. Reference numeral 10b is an O-ring that seals the recess 8a with the separator 6.

A gas leak test of the electrode separator by the gas permeation test apparatus for the polymer electrolyte fuel cell separator of the embodiment thus constructed will be described.
As shown in FIG. 1, a gas impermeable (resin-sealed) carbon plate 250 mm × 250 mm × 6 mmt separator 6 is sandwiched by a pair of upper and lower dummy plates 9 and guided into the positioning holes 9a, 10a. After inserting the rod (not shown) and setting it on the positioning plate 5, the manual hydraulic pump 17 is operated, the double-acting hydraulic cylinder 12 is driven to press the press plate 11, and the dummy plate 9,
10 was pressurized to tighten the separator 6 with a tightening load of 1.4 tons and fixed. Then, N ₂ gas is supplied from the gas supply line 18 through the pressure tank 26 to the gas supply passage 7 of the upper dummy plate 9 at a gas pressure of 1.0 kgf / cm ² , and the N ₂ gas that permeates the separator 6 in the plate thickness direction is supplied. The amount of leak from the gas discharge passage 8 of the lower dummy plate 10 to the gas leak line
The N ₂ gas flowing through 20 was detected by measuring with an integrating flow meter 19.

In this way, a gas leak test was performed on 10 separators 6 and a separator 6 having a leak rate of 20 cc / min or more was obtained.
As a defective product, 4 out of 10 defective products were accurately detected.

On the other hand, a conventional gas permeation test apparatus for electrode separators shown in FIG.
20cc / min
When the separator 6 having the above leak amount is regarded as a defective product,
Only 2 out of 10 defective products can be detected, and the remaining 2 defective products, separator 6, are gas leaks from the gaps between the dummy plates 9 and 10, so the leakage amount of the 2 defective products is the integrated flow rate. It was not possible to accurately measure with a meter, and the result was that two defective products were mistakenly judged to be non-defective.

As described above, the gas permeation test apparatus of the embodiment can accurately detect only the gas leak in the plate thickness direction of the separator 6 by applying an even pressure within the plane to the dummy plates 9 and 10, and Because it can be extremely expensive,
There is no variation in the tightening load within the surface of the separator 6 and no gap is created between the dummy plates 9 and 10 and the separator 6, so that gas leaks from the boundary between the dummy plates 9 and 10 and the separator 6. Because there is no.

In the gas permeation test apparatus of the embodiment,
The press plate 11 pressed by the double-acting hydraulic cylinder 12 is inserted through the ball joint 23 at the center with the tip of the piston rod 13 as shown in FIG. 4 or the spring 24 as shown in FIG. When combined, the impact when the separator 6 sandwiched by the pair of upper and lower dummy plates 9 and 10 is pressed can be softened.

Further, in the gas permeation test apparatus of the embodiment, a pair of upper and lower dummy plates 9 sandwiching the separator 6,
10, as shown in FIG. 6, with a buffer plate 25 interposed therebetween,
Moreover, by sealing the buffer plate 25 with the O-ring 26 and sandwiching the separator 6, it is possible to eliminate the warp and damage of the dummy plates 9 and 10 due to the pressurized gas during the gas permeation test.

[0019]

As can be seen from the above description, according to the gas permeation test apparatus for polymer solid oxide fuel cell electrode separators of the present invention, a separator for detecting gas leak can be set quickly and reliably, and workability is improved. In addition, there is no variation in tightening load on the face plate, no gap is generated between the separator and the dummy plate, and therefore only the gas leak in the thickness direction of the separator can be accurately detected.

Further, in the gas permeation test apparatus of the present invention, the press plate pressed by the hydraulic cylinder is
When the tip of the piston rod is connected at the center through a ball joint or a spring, it is possible to soften the impact when the separator sandwiched by the pair of upper and lower dummy plates is pressed.

Further, in the gas permeation test apparatus of the present invention, when a buffer plate is interposed between a separator and a pair of upper and lower dummy plates sandwiching the separator and the buffer plate is sealed by an O-ring, the gas is not supplied. During the permeation test, it is possible to eliminate the warp and damage of the dummy plate due to the pressurized gas.

Further, according to the gas permeation test apparatus of the present invention, even if the in-plane size, thickness, etc. of the separator for detecting gas leak are different, it is possible to change the position and size of the O-ring of the dummy plate, that is, It can be done simply by changing the dummy plate according to the separator.

[Brief description of drawings]

FIG. 1 is a view showing a gas permeation test device for a polymer electrolyte fuel cell separator of the present invention.

FIG. 2 shows an upper dummy plate in the gas permeation test apparatus of FIG. 1, where a is a plan view, b is a front view, and c is a side view.

FIG. 3 shows a lower dummy plate in the gas permeation test apparatus of FIG. 1, where a is a plan view, b is a front view, and c is a side view.

FIG. 4 is a view showing one of modified examples of how to connect a hydraulic cylinder and a press plate in the gas permeation test apparatus of FIG. 1.

FIG. 5 is a diagram showing another example of modification of how to connect the hydraulic cylinder and the press plate in the gas permeation test apparatus of FIG. 1.

FIG. 6 is a diagram showing an example of changing the way the separator is clamped by a pair of upper and lower dummy plates in the gas permeation test apparatus of FIG.

FIG. 7 is a view showing a conventional gas permeation test device.

[Explanation of symbols]

 1 Press Frame 2, 3 Surface Plate 4 Column 5 Positioning Plate 6 Separator 7 Gas Supply Channel 8 Gas Discharge Channel 9, 10 Dummy Plate 11 Press Plate 12 Hydraulic Cylinder 18 Gas Supply Line 19 Cumulative Flow Meter 20 Gas Leak Line 23 Ball Joint 24 Spring 25 Buffer plate 26 O-ring

Claims (3)

[Claims] 1. A press frame formed by connecting upper and lower platens with two columns, a positioning plate fixed on the platen below the press frame, and a separator set on the positioning plate. A pair of upper and lower dummy plates each having a gas supply passage and a gas discharge passage, a press plate for pressing a pair of upper and lower dummy plates sandwiching a separator on a positioning plate, and a press frame for pressing the press plate. It consists of a hydraulic cylinder erected on the upper surface plate, the gas supply line is connected to the gas supply passage provided on the upper dummy plate, and the flow rate is supplied to the gas discharge passage provided on the lower dummy plate. A gas permeation test device for a polymer electrolyte fuel cell separator comprising a gas leak line equipped with a meter. 2. The polymer solid according to claim 1, wherein the press plate pressed by the hydraulic cylinder is connected to the tip of the piston rod at the center via a ball joint or a spring. Gas permeation test device for electrolyte fuel cell separators. 3. A pair of upper and lower dummy plates sandwiching the separator respectively interpose a buffer plate, and an O-ring seals the buffer plate to sandwich the separator. Gas permeation test device for polymer electrolyte fuel cell separator.