KR101021135B1 - Gas permeability measurement apparatus and method for gas diffusion layer of pemfc under cell operation condition - Google Patents

Abstract

The present invention relates to a gas permeability measuring device and a measuring method which can measure the gas permeability of the gas diffusion layer of the polymer electrolyte fuel cell under actual operating conditions, and more specifically, a gas supply unit; A first chamber connected to the gas supply part; A second chamber connected to the first chamber through a gas passage; A membrane cell installed in a gas passage communicating the first chamber and the second chamber with a gas diffusion layer sheet interposed therebetween; And a pressure measuring unit for measuring a pressure difference between the first chamber and the second chamber, wherein the membrane cell is composed of a pair of clamping members to interpose a gas diffusion layer sheet, and each of the clamping members is formed of the gas. Polymer electrolyte fuel cell under actual operating conditions, characterized in that the hollow portion in the center so that the gas flows in communication with the passage, the mesh is applied to the gas diffusion layer sheet to apply the same pressure as the actual operating conditions An apparatus for measuring gas permeability of a gas diffusion layer and a method for measuring gas permeability using the same.

Polymer electrolyte fuel cell, gas diffusion layer, gas permeability, actual operating conditions, membrane cell, mesh

Description

GAS PERMEABILITY MEASUREMENT APPARATUS AND METHOD FOR GAS DIFFUSION LAYER OF PEMFC UNDER CELL OPERATION CONDITION}

The present invention relates to an apparatus for measuring gas permeability of a gas diffusion layer of a polymer electrolyte fuel cell and a method of measuring the same, and more specifically, to a gas permeability in a state in which the same pressure as the actual operating condition of the polymer electrolyte fuel cell is applied. The present invention relates to a measuring device capable of measuring gas permeability of a polymer electrolyte fuel cell gas diffusion layer that can be measured, and a measuring method thereof.

Polymer Electrolyte Membrane Fuel Cells (PEMFCs) have superior output characteristics compared to other fuel cells, have a low operating temperature, fast start-up and response characteristics, as well as mobile power sources such as automobiles, homes, public buildings, Applications such as distributed power supplies and small power supplies such as for electronics have wide advantages. Such polymer electrolyte fuel cells have been widely studied as electrochemical devices for convenient and efficient power resources.

The polymer electrolyte fuel cell is divided into two components, one of which is the cell stack part and the other is the system and operation part. The cell stack is the part that ultimately produces electricity. Specifically, a membrane-electrode assembly (MEA) in which an electrolyte is inserted between an anode / cathode electrode catalyst, an electrolyte and a cathode / cathode electrode catalyst supplied with fuel and an oxidizing gas (MEA) The fuel cell consists of multiple membrane-electrode assemblies, a separator separating the multiple membrane-electrode assemblies from each other, a gas diffusion layer that distributes the supplied fuel and oxidant gas evenly to the electrode catalyst. The MEA, the separator, the gas diffusion layer, and the like are classified into the final stacked stack. The system and operating element parts include a fuel supply unit, an oxidant gas supply unit, a heat-water management unit for controlling heat generated from a fuel cell, a power conversion unit, a control unit and the fuel / oxidant gas supply unit, heat-water management unit, It is classified into a system composed by finally connecting power conversion and control devices.

When the polymer electrolyte fuel cell is formed of a cell stack, the membrane-electrode assembly, the separator separating the membrane-electrode assembly, and the gas diffusion layer for evenly dispersing the supplied fuel and the oxidant gas in the electrode catalyst are pressed and combined.

Since the gas permeability of the gas diffusion layer directly affects the performance of the polymer electrolyte fuel cell, an apparatus for measuring the gas diffusion layer is required. The gas permeability measurement of the gas diffusion layer to date has been made without considering the actual operating conditions of the fuel cell. However, as described above, since the gas diffusion layer is compressed under a certain pressure under actual operating conditions, it is necessary to more accurately measure the gas permeability in consideration of this.

Therefore, the inventors of the present invention intensively studied the gas permeability of the gas diffusion layer of the polymer electrolyte fuel cell, and a device and a measuring method for measuring the gas permeability of the gas diffusion layer under the actual operating conditions of the polymer electrolyte fuel cell, that is, pressurized. The invention has been completed.

An object of the present invention is to provide a gas permeability measuring device that can measure the gas permeability of the gas diffusion layer which is one component of the polymer electrolyte fuel cell under actual operating conditions of the fuel cell.

Another object of the present invention is to provide a measuring method for measuring the gas permeability of the gas diffusion layer which is one component of the polymer electrolyte fuel cell under actual operating conditions of the fuel cell.

In order to achieve the above object, the present invention is a gas supply unit; A first chamber connected to the gas supply part; A second chamber connected to the first chamber through a gas passage; A membrane cell installed in a gas passage communicating the first chamber and the second chamber with a gas diffusion layer sheet interposed therebetween; And a pressure measuring unit for measuring a pressure difference between the first chamber and the second chamber, wherein the membrane cell is composed of a pair of clamping members to interpose a gas diffusion layer sheet, and each of the clamping members is formed of the gas. Polymer electrolyte fuel cell under actual operating conditions, characterized in that the hollow portion in the center so that the gas flows in communication with the passage, the mesh is applied to the gas diffusion layer sheet to apply the same pressure as the actual operating conditions Provided is a gas permeability measuring device for a gas diffusion layer.

The membrane cell is preferably sealed after being pressurized by the actual operating pressure of the polymer electrolyte fuel cell gas diffusion layer through the gas diffusion layer sheet.

As the pressure measuring unit, a manometer or a digital manometer may be used.

The present invention provides a gas permeability measuring device and a method for measuring the gas permeability of a gas diffusion layer, which is a component of a polymer electrolyte fuel cell, under actual operating conditions of a fuel cell, thereby providing a gas permeability of the gas diffusion layer and a polymer electrolyte fuel cell. It can be used for research to improve the performance of polyelectrolyte fuel cell by providing accurate information in identifying the correlation between

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated in detail.

The present invention gas supply unit; A first chamber connected to the gas supply part; A second chamber connected to the first chamber through a gas passage; A membrane cell installed in a gas passage communicating the first chamber and the second chamber with a gas diffusion layer sheet interposed therebetween; And a pressure measuring unit for measuring a pressure difference between the first chamber and the second chamber, wherein the membrane cell is composed of a pair of clamping members to interpose a gas diffusion layer sheet, and each of the clamping members is formed of the gas. Polymer electrolyte fuel cell under actual operating conditions, characterized in that the hollow portion in the center so that the gas flows in communication with the passage, the mesh is applied to the gas diffusion layer sheet to apply the same pressure as the actual operating conditions Provided is a gas permeability measuring device for a gas diffusion layer.

Hereinafter, an apparatus for measuring gas permeability of a polymer electrolyte fuel cell gas diffusion layer according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a side view of a gas permeability measuring device of the polymer electrolyte fuel cell gas diffusion layer of the present invention, Figure 2 is a cross-sectional view of the gas permeability measuring device of the polymer electrolyte fuel cell gas diffusion layer of the present invention, Figure 3 is a polymer electrolyte of the present invention It is a perspective view of the gas permeability measuring apparatus of a fuel cell gas diffusion layer.

1 and 3, the gas permeability measuring apparatus 100 of the polymer electrolyte fuel cell gas diffusion layer according to the present invention includes a gas supply unit 105 for supplying gas into the gas permeability measuring apparatus; A gas inlet 104 connected to the gas supply part 105 to introduce gas into a gas permeability measuring device; A first chamber (101) for storing and flowing the gas introduced from the gas inlet (104); A second chamber (102) communicating with the gas to allow the gas to flow through the first chamber (101); A membrane cell 400 installed between the first chamber 101 and the second chamber 102; And a pressure measuring unit 103 measuring a pressure difference between the first chamber and the second chamber.

2 is a cross-sectional view of a gas permeability measuring device of a polymer electrolyte fuel cell gas diffusion layer according to an embodiment of the present invention. As shown in FIG. 2, the nitrogen gas introduced through the gas inlet 104 passes through the membrane chamber 400 installed between the first chamber 101 and the second chamber 102 via the first chamber 101. Flow to the second chamber 102. At this time, nitrogen gas passes through the gas diffusion layer sheet 106 interposed between the membrane cells 400 in which the hollow part is formed, and the penetrated gas is moved to the second chamber 102 so that the first chamber 102 and the first chamber 102 are formed. The pressure difference is formed between the two chambers 103, and the gas permeability can be calculated by measuring the pressure difference using the pressure measuring unit 103.

In measuring the gas permeability of the gas diffusion layer of the polymer electrolyte fuel cell described above, a key component for measuring the gas permeability of the gas diffusion layer under actual operating conditions is the membrane cell 400.

The membrane cell 400 corresponds to a key component capable of measuring the gas permeability of the gas diffusion layer under actual operating conditions, and the membrane cell 400 will be described in detail below with reference to the accompanying drawings.

4 is a diagram illustrating a membrane cell 400 installed in a gas passage between the first chamber 101 and the second chamber 102. 4A is a plan view of the membrane cell 400, and FIG. 4B is a perspective view of the membrane cell 400.

FIG. 5 is a view schematically showing how a gas diffusion layer sheet of a polymer electrolyte fuel cell to measure gas permeability between membrane cells is interposed.

4 and 5, the membrane cell 400 is composed of a pair of holding member (402 and 403), the gas diffusion layer sheet 106 of the polymer electrolyte fuel cell for measuring the gas permeability It is interposed between the clamping members 402 and 403. The membrane cell 400 has a hollow portion formed to allow gas to flow between the first chamber 101 and the second chamber 102, and the gas diffusion layer sheet 106 may be pressurized to the hollow portion. The mesh 401 is formed to flow. Therefore, when the gas diffusion layer sheet 106 is interposed on the inner surfaces of the pair of sandwiching members 402 and 403 and then fixed with a screw formed on the sandwiching members 402 and 403, a predetermined pressure is applied to the gas diffusion layers. In order to apply a predetermined pressure to the gas diffusion layer sheet 106, the gas diffusion layer sheet 106 is interposed on the inner surfaces of the holding members 402 and 403, and then a torque applied to the screw portion is adjusted by using a torque wrench. However, the method of applying a predetermined pressure to the gas diffusion layer sheet is not limited thereto, and various methods may be used according to a method of fixing the holding members 402 and 403. As such, by adjusting the bonding strength of the membrane cell 400 via the gas diffusion layer sheet 106 to be equal to the pressure applied to the gas diffusion layer during the actual operation of the polymer electrolyte fuel cell, the gas during the actual operation of the polymer electrolyte fuel cell. Gas permeability can be measured under the same conditions as the pressure applied to the diffusion layer.

As described above, the membrane cell 400 is adjusted between the first chamber 101 and the second chamber 102 so that the same pressure applied to the gas diffusion layer is applied during the actual operation of the polymer electrolyte fuel cell. After the installation in the fixed portion is coupled to the first chamber 101 and the second chamber 102 and sealed, the gas permeability measurement experiment is performed. As such, the method of sealing the chamber is easy for those skilled in the art to which the present invention pertains, and thus detailed description thereof will be omitted.

Gas permeability measuring device 100 of the polymer electrolyte fuel cell gas diffusion layer according to the present invention is nitrogen, oxygen, argon, helium to measure the gas permeability Although gases such as these may be used, there is no explosive or toxic and a gas having a known viscosity at room temperature may be used without limitation.

Gases such as nitrogen, oxygen, argon, helium and the like are supplied through the gas source 105 and introduced into the first chamber 101 through the gas inlet 104. At this time, the gas is preferably introduced into the first chamber 101 at a flow rate of 100 ml / min to 900 ml / min.

The gas introduced into the first chamber 101 flows through the membrane cell 400 interposed between the first chamber 101 and the second chamber 102 to the second chamber 102.

As described above, after the gas is moved to the second chamber 102, the pressure difference between the two chambers is calculated by the pressure measuring unit 103 installed in the first chamber 101 and the second chamber 102, so that the gas of the gas diffusion layer Permeability can be measured. A manometer or a digital manometer may be used as the pressure measuring unit 103 installed between the first chamber 101 and the second chamber 102 to measure the pressure.

Gas permeability diagram of the present invention In the case of measuring the gas permeability of the gas diffusion layer using the measuring device 100, the measured gas permeability includes the gas permeability of the gas diffusion layer and the gas permeability of the two meshes that apply pressure to the gas diffusion layer. In order to calculate, it is necessary to correct the gas permeability of the two meshes. As described above, the method of calculating the gas permeability of only the gas diffusion layer by correcting the gas permeability of the two meshes will be described in detail in the gas permeability measurement method of the polymer electrolyte fuel cell gas diffusion layer under the following actual operating conditions.

In addition, the present invention,

A gas permeability measurement method of a gas diffusion layer of a polymer electrolyte fuel cell using a gas permeability measuring device,

Interposing the gas diffusion layer sheet in the membrane cell in which the mesh is formed in the hollow portion (step 1);

Applying the same pressure as the actual operating state of the polymer electrolyte fuel cell to the membrane cell via the gas diffusion layer sheet and fixing the same to a gas permeation measuring apparatus (step 2); And

Adding gas to the gas permeability measuring device to measure gas permeability of the gas diffusion layer sheet (step 3),

The gas permeability of the gas diffusion layer sheet measured in the step 3 is calculated by correcting the gas permeability of the mesh formed in the hollow portion of the membrane cell by the following equation 1 of the polymer electrolyte fuel cell gas diffusion layer under the actual operating conditions Provides a gas permeability measurement method.

[Equation 1]

V is the volumetric flow rate of the gas, A is the cross-sectional area of the hollow part of the membrane cell, μ is the viscosity of the gas, L _m is the thickness of the mesh, L _g is the thickness of the gas diffusion layer, K _m is the gas permeability of the mesh, K _g is the gas diffusion layer The gas permeability of, ΔP is the pressure difference seen on the manometer.

Gas permeability measurement method of the polymer electrolyte fuel cell gas diffusion layer under the actual operating conditions according to the present invention can be used a general gas permeability device, as described above, the membrane cell via the gas diffusion layer as described above the hollow portion to press the gas diffusion layer It is used that the mesh is formed (see Fig. 5).

Gas permeability measurement method of the polymer electrolyte fuel cell gas diffusion layer under the actual operating conditions according to the present invention can apply the same pressure as the actual operating state of the polymer fuel cell to the gas diffusion layer using a membrane cell formed mesh, thereby real operating conditions The gas permeability of the polymer electrolyte fuel cell gas diffusion layer is characterized in that it can be measured under.

Since the gas permeability is measured by pressurizing the gas diffusion layer using a mesh formed in the membrane cell, the calculated gas permeability includes the values of the gas permeability of the two meshes and the gas diffusion layer, and therefore, in order to measure the gas permeability of only the gas diffusion layer, A process of correcting two mesh values is required, and Equation 1 may be used to correct the calculated gas permeability.

Equation 1 is derived by the inventor using Darcy's law and Ohm's law of Equation 2 below.

[Equation 2]

V is the volumetric flow rate of the gas, A is the cross-sectional area of the medium, μ is the viscosity of the gas, L is the thickness of the medium, K is the permeability coefficient of the medium, and ΔP is the pressure difference across the membrane.

In the method of calculating the gas permeability by a general gas permeability measuring device, the gas permeability of the sheet can be measured by substituting the measured volume flow rate and the pressure difference into Darcy's law of Equation 2 above, but according to the present invention. When the gas permeability is calculated using the device, the gas permeability of only the gas diffusion layer may be calculated by correcting the values of the two meshes that pressurize the gas diffusion layer. Therefore, the present inventors earnestly studied a calculation method for correcting the values of two meshes, and as a result, gas permeability can be thought of as electrical resistance, current can be thought of as volumetric flow rate, and voltage difference that causes current to flow is Considering that it can be thought of as a pressure difference, which is a driving force for flowing a gas, Equation 1 can be derived by applying an equation for calculating current by connecting electrical resistance in series. In order to verify Equation 1 derived above, the gas permeability of the multilayer material was measured by manufacturing a multilayer material by superposing a sheet-shaped material which already knows the gas permeability, and as a result, Equation 1 was validated.

Hereinafter, a method of measuring the gas permeability of the gas diffusion layer according to the present invention using Equation 1 will be described in detail.

에 해당한다. 메쉬의 기체투과도 값(K_m)과 메쉬의 두께(L_m)는 미리 알고 있는 값이며, 또한 흐르는 기체의 점도(μ)도 용이하게 알 수 있고, 기체확산층의 두께(L_g)는 측정이 용이하므로 위의 얻어진 기울기에 알고 있는 물성치를 대입하면 남는 기체확산층의 기체투과도(K_g)를 계산할 수 있다.According to the gas permeability measurement method of the gas diffusion layer of the polymer electrolyte fuel cell under the actual operating conditions of the present invention through the gas diffusion layer sheet in the membrane cell having a mesh formed in the hollow portion, the polymer electrolyte fuel cell in the membrane cell via the gas diffusion layer sheet After fixing by applying the same pressure as the actual operating state of the gas permeability measuring device, by applying a gas to the gas permeability measuring device to measure the pressure difference between both ends of the gas diffusion layer sheet. The slope can be obtained by plotting the difference between the volume flow rate and the manometer pressure, and the slope value is

Corresponds to The gas permeability value (K _m ) of the mesh and the thickness (L _m ) of the mesh are known values in advance, and the viscosity (μ) of the flowing gas can be easily known, and the thickness (L _g ) of the gas diffusion layer is measured. Since it is easy to substitute the known physical properties to the obtained slope, the gas permeability (K _g ) of the remaining gas diffusion layer can be calculated.

Since the mesh does not change the gas permeability due to compression, it has a unique gas permeability. Therefore, the gas permeability of the mesh is measured in advance and the gas permeability of the polymer electrolyte fuel cell gas diffusion layer is measured under the actual operating conditions according to the above-described method. can do.

As described above, when the gas permeability of the gas diffusion layer is measured using the gas permeability measuring device and the gas permeability measuring method of the polymer electrolyte fuel cell gas diffusion layer under the actual operating conditions of the present invention, that is, the actual operating conditions of the polymer electrolyte fuel cell It is possible to measure the gas permeability of the gas diffusion layer under the actual pressure applied, and thereby to find a more accurate correlation between the gas permeability of the gas diffusion layer and the performance of the polymer electrolyte fuel cell, thereby improving the performance of the polymer electrolyte fuel cell. It can be used for research.

1 is a side view of a gas permeability measuring device of the polymer electrolyte fuel cell gas diffusion layer of the present invention.

2 is a cross-sectional view of an apparatus for measuring gas permeability of a gas diffusion layer of a polymer electrolyte fuel cell of the present invention.

3 is a perspective view of an apparatus for measuring gas permeability of a gas diffusion layer of a polymer electrolyte fuel cell of the present invention.

4 is a diagram illustrating a membrane cell installed between a first chamber and a second chamber. FIG. 4A is a plan view of the membrane cell, and FIG. 4B is a perspective view of the membrane cell.

FIG. 5 is a view schematically showing how a gas diffusion layer sheet of a polymer electrolyte fuel cell to measure gas permeability between membrane cells is interposed.

Explanation of symbols on the main parts of the drawings

100: gas permeability measuring device 101: first chamber

102: second chamber 103: pressure measuring unit

104: gas inlet 105: gas supply

110: support 106: gas diffusion layer sheet

400: membrane cell 401: mesh

402, 403: missing member

Claims (9)

Gas supply section; A first chamber connected to the gas supply part; A second chamber connected to the first chamber through a gas passage; A membrane cell installed in a gas passage communicating the first chamber and the second chamber with a gas diffusion layer sheet interposed therebetween; And It includes a pressure measuring unit for measuring the pressure difference between the first chamber and the second chamber, The membrane cell is composed of a pair of holding members to interpose a gas diffusion layer sheet, each holding member is in communication with the gas passage has a hollow portion in the center for the gas flow, the hollow portion gas diffusion layer Gas permeability measuring device of the polymer electrolyte fuel cell gas diffusion layer under the actual operating conditions, characterized in that the sheet is placed on the sheet to apply the same pressure as the actual operating conditions. The method of claim 1, The gas supply unit is a gas permeability measuring device of a polymer electrolyte fuel cell gas diffusion layer under actual operating conditions, characterized in that for supplying a gas selected from the group consisting of nitrogen, oxygen, argon and helium. The method of claim 1, The membrane cell is a gas permeability measuring device of the polymer electrolyte fuel cell gas diffusion layer under the actual operating conditions, characterized in that the pressure is fixed to the same pressure as the actual operating pressure of the gas diffusion layer of the polymer electrolyte fuel cell through the gas diffusion layer sheet. The method of claim 3, The membrane cell is a gas permeability measuring device of the polymer electrolyte fuel cell gas diffusion layer under the actual operating conditions, characterized in that the sealing through the gas diffusion layer sheet and fixed by pressing the same pressure as the actual operating pressure of the gas diffusion layer of the polymer electrolyte fuel cell. . The method of claim 1, The pressure measuring unit gas permeability measuring device of the polymer electrolyte fuel cell gas diffusion layer under the actual operating conditions, characterized in that the manometer or digital manometer. The method of claim 1, And the membrane cell is installed in a gas passage between the first chamber and the second chamber, and then sealed by a sealing member. A gas permeability measurement method of a gas diffusion layer of a polymer electrolyte fuel cell using a gas permeability measuring device, Interposing the gas diffusion layer sheet in the membrane cell in which the mesh is formed in the hollow portion (step 1); Applying the same pressure as the actual operating state of the polymer electrolyte fuel cell to the membrane cell via the gas diffusion layer sheet and fixing the same to a gas permeation measuring apparatus (step 2); And Adding a gas to the gas permeability measuring device to measure gas permeability (step 3), The gas permeability measured in step 3 is a gas permeability measurement method of the polymer electrolyte fuel cell gas diffusion layer under the actual operating conditions, characterized in that calculated by the gas permeability of the mesh formed in the hollow portion of the membrane cell by the following equation (1): : [Equation 1]

V is the volumetric flow rate of the gas, A is the cross-sectional area of the hollow part of the membrane cell, μ is the viscosity of the gas, L _m is the thickness of the mesh, L _g is the thickness of the gas diffusion layer, K _m is the gas permeability of the mesh, K _g is the gas diffusion layer The gas permeability of, ΔP is the pressure difference seen on the manometer. The method of claim 7, wherein The gas is gas permeability measurement method of the polymer electrolyte fuel cell gas diffusion layer under the actual operating conditions, characterized in that selected from the group consisting of nitrogen, oxygen, argon and helium. The method of claim 7, wherein The membrane cell is a gas permeability measurement method of the polymer electrolyte fuel cell gas diffusion layer under the actual operating conditions, characterized in that the sealing through the gas diffusion layer sheet through the gas diffusion layer of the polymer electrolyte fuel cell is fixed after being sealed.

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