RU186174U1 - Device for rapid assessment of gas permeability of proton-conducting membrane of a fuel cell - Google Patents

Abstract

The utility model relates to the field of studies of proton-conducting membranes of fuel cells. Essence: the device includes a two-chamber housing with a connector for placement of the studied proton-conducting membrane (3) and an amperometric sensor (5). In this case, one of the chambers (2) is a purge chamber, and the other chamber (1) is a measurement chamber. A sealing gasket (4) is installed on the contour of the housing connector on each of the cameras. Amperometric sensor (5) is installed at the output of the measuring chamber (1). EFFECT: increased accuracy of express estimation of gas permeability of proton-conducting membrane of a fuel cell. 2 s.p. f-ly, 3 ill.

Description

The utility model relates to the field of hydrogen energy, in particular to studies regarding the quality of individual parts of fuel cells, namely proton-conducting membranes, and can be used to quickly check the gas permeability of proton-conducting membranes.

The main function of the proton-conducting membrane of a fuel cell is the transfer of a proton formed as a result of hydrogen ionization at the anode to the cathode region. Therefore, the membrane must have maximum conductivity. In addition, the proton-conducting membrane of the fuel cell must play the role of a gas separation: it must cut off the anode side, where hydrogen is contained, from the cathode side, through which air or oxygen is blown. To prevent direct chemical (non-electrochemical) reaction of reagents on one of the electrodes, it is necessary that the membrane is gas-tight. The penetration of hydrogen to the cathode side is equivalent to the leakage current (crossover), and should be minimized in order to increase the efficiency of the fuel cell.

In practice, proton-conducting membranes with a manufacturing defect, for example, having low gas density, are often found. To exclude the use of defective membranes in fuel cells, it is necessary to conduct an express assessment of their gas permeability.

A device is known for measuring the permeability of gas through a membrane (film), including a housing divided by a membrane into two sealed chambers, with corresponding nozzles for supplying and discharging gas, and a means for measuring the concentration of gas passing through the membrane (RU 2447424, April 10, 2012).

However, this device is unsuitable for determining the gas permeability of proton-conducting polymer membranes, since it uses the method of IR spectroscopy, which does not allow direct detection of hydrogen gas. The measurement results using an infrared sensor in a known device may be affected by the presence of foreign substances, namely water, other electrochemically active gases and organic compounds. In addition, the work of the design known from patent RU 2447424 is carried out under significant pressure (3-15 bar), which may be suitable for testing membranes (films) sufficiently strong, namely for polymer films from which containers for food, chemical, pharmaceutical, electronic products, but completely unsuitable for proton-conducting membranes that are sufficiently thin and studied at atmospheric pressure. Also, as follows from the description of the known design according to patent RU 2447424, the tightness between the purge chamber and the measuring chamber is provided by the membrane itself, which, given the thickness of the membrane (film), is clearly insufficient and negatively affects the evaluation results.

It is important that the presence of any foreign substances does not affect the measurement result.

The task to which the creation of the proposed utility model is aimed is to increase the accuracy of the express gas permeability assessment of proton-conducting membranes of the fuel cell, by eliminating the influence of extraneous factors on the measurement process. Such factors include leakage in the detachable case (at the junction of the chambers), as well as the possible presence of foreign substances, in particular water, other electrochemically active gases and organic compounds.

The solution to this problem is achieved by the fact that the claimed device for rapid assessment of gas permeability of the proton-conducting membrane includes a detachable housing, consisting of two parts. One part of the housing is a measuring chamber and has an output for connecting a gas analyzer (or amperometric sensor), and the other part of the housing is a purge chamber. An amperometric sensor is installed at the output of the measuring chamber. On the contour of the housing connector on each of the cameras installed gaskets. The studied proton-conducting membrane is placed between the sealing gaskets.

The amperometric sensor used in the proposed device is not affected by foreign substances in the analyzed medium, unlike optical sensors, the measurement results of which can be affected by the presence of foreign substances, such as water, other electrochemically active gases and organic compounds. The tightness of the chambers provided by the gaskets eliminates leaks in the housing, helping to increase the accuracy of the measurement.

The essence of the claimed utility model is illustrated by graphic materials, where in FIG. 1 shows a general view of a device for express gas permeability estimation of a proton-conducting membrane of a fuel cell; FIG. 2 - layout of the main components of the device, FIG. 3-graph of the concentration of hydrogen in the measuring chamber versus time.

The device comprises a detachable casing consisting of two chambers — a measuring chamber 1 and a gas purge chamber 2, between which an analyzed (studied) proton-conducting membrane 3 is installed. Hydrogen-tight gaskets 4 (mainly silicone) are installed on the casing connector on each chamber 1 and 2; . The device also contains an amperometric sensor (gas analyzer) 5 for determining the concentration of hydrogen. The device is mounted on a table 6. In addition, the device can be equipped with a spiral tube 7 to relieve excess pressure. The tube is made spiral in order to reduce its dimensions, since the length of the tube, as a rule, is not less than 5 cm.

The purge chamber 2 is attached, for example, by means of a screw connection to the stage 6. A hydrogen-tight gasket (for example, silicone) gasket 4 is located along the contour of the open part of the chamber 2, over which the test membrane 3 is placed. The dimensions of the membrane 3 must be such as to ensure the perimeter overlap gasket 4, this is necessary to ensure tightness and to prevent direct contact between the volumes of the chambers 1 and 2. On top of the membrane 3 is installed on the screw connections measuring chamber 1 with a gasket and with an amperometric sensor (gas analyzer) 5. The gasket on the measuring chamber 1 repeats the dimensions and location of the seal on the purge chamber 2. The fixing of the measuring chamber 1 is carried out, for example, by four couplings with a wing head. The spiral tube 7 in the measuring chamber is designed to relieve excess pressure at high gas permeability.

After installing the membrane 3 and fixing the measuring chamber 1, a constant flow of hydrogen is supplied through the purge chamber 2. It is also possible to create an adjustable overpressure in the purge chamber. The pressure should not exceed 1.9 bar in order to maintain the integrity of a thin (up to 100 μm) proton-conducting membrane.

As a rule, the proton-conducting membrane 3 has defects and part of the hydrogen molecules passes through the membrane, entering the measuring chamber 1. As a result, over time, the concentration of hydrogen in the measuring chamber 1 increases and is fixed by the gas analyzer 5. The rate of increase in the concentration in the measuring chamber can be estimated gas permeability value for a specific membrane. Measurement takes from 1 to 5 minutes.

The volume of the measuring chamber in the sample device is 3 ml. A small volume is selected to increase the sensitivity of the device.

Hydrogen crossover measurements were performed on samples of Nafion commercial proton-conducting membranes. The obtained dependences of the concentration of hydrogen in the measuring chamber on time are presented in FIG. 3.

The crossover value of the membrane (leakage current resulting from the gas permeability of the membrane) was calculated as follows. The linear part of the dependence, when the crossover reaches a stationary value, was approximated by a straight line, the angular coefficient of which determined the crossover speed u in units of% of the camera volume per second. Knowing the chamber volume V and the area of the studied sample S, we can find the specific hydrogen crossover rate in ml / (s * cm ² ) by the formula (1):

From the Faraday law it follows that the rate of hydrogen leakage into the chamber -ϑ - can be calculated as follows:

where m is the mass of the substance deposited on the electrode, M is the molar mass of the substance, Q = I * t is the total electric charge, z is the valence number of ions of the substance, F = 96,485.33 C / mol is the Faraday constant.

Then the specific leakage current i will leave:

where i is the specific crossover current of hydrogen in A / cm ² .

Studies on a commercial Nafion 212 membrane showed that the crossover speed was 1.04 * 10 ^-5 ml / (s * cm ² ) or the leakage current was 0.12 mA / cm ² . Within normal limits, that is, in order to consider the membrane suitable, the leakage current must be up to 2 mA / cm ² or up to 0.02 ml * min / cm ² [current landmark and world standard established by the US Department of Energy (Department Of Energy , Fuel Cell Technical Team Roadmap)].

Using the inventive device measure the crossover speed of hydrogen through the membrane and recalculate it according to the formulas in the leakage current. If an acceptable value is obtained (usually up to 2 mA / cm ² ), then the membrane is suitable for use in fuel cells, if more, the membrane is not suitable. However, it is possible not to recalculate into leakage current, but immediately compare by volumetric characteristic. If the measured value is less than 0.02 ml * min / cm ² , then the membrane is suitable, if more, then the membrane is not suitable.

Thus, the proposed device allows you to evaluate with a high degree of accuracy the quality of the proton-conducting membrane, which in the future (due to the rejection of non-conforming membranes) will increase the efficiency of the fuel cells in which these membranes will be used.

Claims (3)

1. A device for the rapid assessment of the gas permeability of the proton-conducting membrane of a fuel cell, including a two-chamber housing with a connector for accommodating the studied proton-conducting membrane and an amperometric sensor, while one of the chambers is a purge chamber and the other is a measuring chamber, moreover along the contour of the housing connector on each of the chambers a gasket is installed, and an amperometric sensor is installed at the output of the measuring chamber. 2. The device according to claim 1, characterized in that the gaskets are made of silicone. 3. The device according to claim 1, characterized in that the measuring chamber is equipped with a spiral tube.

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