JP7388627B2 - Hydrogen permeation device and method for manufacturing hydrogen permeation device - Google Patents

Description

The present disclosure relates to a hydrogen permeation device and a method of manufacturing the same.

In recent years, hydrogen has attracted attention and is playing an important role in various fields. For example, hydrogen is used as a new energy in household fuel cell cogeneration systems, fuel cell vehicles, and the like. Furthermore, high-purity hydrogen gas is used as a carrier gas in crystal growth and processing of Si wafer semiconductor materials using vapor phase epitaxial growth.

JP2016-59902A

In polymer electrolyte fuel cells, since the negative electrode catalyst is poisoned by impurity gases such as carbon monoxide, it is required to use highly purified hydrogen gas. For example, in fuel cell vehicles, it is necessary to supply high-purity hydrogen with an overall purity of 99.97% or higher, and there are strict regulations such as sulfur content being 4 ppb or less, formaldehyde being 10 ppb or less, and halogen being 50 ppb or less. Further, when hydrogen is used as a carrier gas in crystal growth and processing of semiconductor materials, ultra-high purity hydrogen gas of 99.9999999% or higher is required to avoid deterioration of semiconductor characteristics due to contamination with impurities. Furthermore, high-purity hydrogen is also required as a raw material for producing chemicals such as ammonia and methanol. Note that there is a need for a technology for separating and recovering high-purity hydrogen gas from a hydrogen mixed gas containing gaseous components other than hydrogen, such as by-product hydrogen and cracked gas from a hydrogen carrier. As the demand for high-purity hydrogen is increasing, there is a need for technology to supply high-purity hydrogen in a highly efficient and stable manner.

As a technique for separating hydrogen from a raw material gas containing hydrogen, there is Patent Document 1 by the present inventors. The present inventors further improved the invention described in Patent Document 1 and came up with the technology of the present disclosure.

The present disclosure has been made in view of such problems, and its purpose is to improve the performance of a hydrogen permeation device.

In order to solve the above problems, a hydrogen permeable device according to an embodiment of the present invention includes a hydrogen permeable membrane formed of a pure metal or an alloy, and a catalyst layer provided on the surface of the hydrogen permeable membrane. A predetermined ratio or more of the metal or alloy of the hydrogen permeable membrane at the interface with the catalyst layer is oriented in a specific crystal orientation.

Yet another aspect of the invention is also a hydrogen permeation device. This device includes a hydrogen permeable membrane made of pure metal or an alloy, and a catalyst layer provided on the surface of the hydrogen permeable membrane. In the metal or alloy of the hydrogen permeable membrane at the interface with the catalyst layer, the area oriented in the {110} plane is larger than the area oriented in other planes.

Yet another aspect of the invention is also a hydrogen permeation device. This device includes a hydrogen permeable membrane formed of pure metal or an alloy, and a catalyst layer formed of an alloy of palladium and silver on the surface of the hydrogen permeable membrane. The composition ratio of palladium and silver in the catalyst layer is the same as that immediately after the permeation flow rate starts when a hydrogen permeation test is conducted on the hydrogen permeable membrane under the conditions of the primary pressure of 400 kPa, the secondary pressure of 103 kPa, and the temperature of 450°C. The composition ratio is such that the 20% deterioration time t _0.2 , which is the time from the permeation flow rate to the point at which it decreases by 20%, is 40 hours or more.

Yet another aspect of the present invention is a method for manufacturing a hydrogen permeation device. This method includes the steps of forming a hydrogen permeable membrane using a pure metal or an alloy, and increasing a region of the pure metal or alloy oriented in a specific crystal orientation on the surface of the hydrogen permeable membrane.

According to the present disclosure, the performance of a hydrogen permeation device can be improved.

1 is a diagram showing the configuration of a hydrogen separator according to an embodiment. FIG. 2 is a diagram showing the time change in hydrogen permeability at 550° C. of a composite membrane in which a pure V hydrogen permeable membrane is coated with a pure Pd catalyst layer. FIG. 2 is a diagram showing the time change in hydrogen permeability at 300° C. of a composite membrane in which a hydrogen permeable membrane made of an alloy of V and Fe is coated with a catalyst layer of an alloy of Pd and Ag. FIG. 2 is a diagram showing the time change in hydrogen permeability at 550° C. of a composite membrane in which a hydrogen permeable membrane made of an alloy of V and Fe is coated with a catalyst layer made of an alloy of Pd and Ag. FIG. 3 is a diagram showing the relationship between the composition of a catalyst layer and deterioration time. FIG. 3 is a diagram showing deterioration time versus hydrogen permeation test temperature. FIG. 3 is a diagram showing the relationship between the composition of a catalyst layer and the change in permeation flow rate ratio over time. It is a SEM image of the surface of the composite membrane after heat treatment. 9 is a SEM image of positions (1) to (7) of the composite membrane shown in FIG. 8. 9 is an SEM image of a cross section of the composite membrane shown in FIG. 8 at positions (1) to (7). FIG. 2 is a diagram showing the analysis results of the composite film after heat treatment by Auger electron spectroscopy (AES) for each crystal orientation. FIG. 3 is a diagram showing the results of a continuous hydrogen permeation test using a pure V single crystal sample. These are SEM images of the surface of a pure V single crystal sample before and after a hydrogen permeation test. FIG. 3 is a diagram showing the X-ray diffraction results of a thin film manufactured by the first method according to the present disclosure. FIG. 7 is a diagram showing the X-ray diffraction results of a thin film manufactured by a second method according to the present disclosure. It is a figure which shows the X-ray diffraction result of the thin film manufactured by the 3rd method based on this indication.

As an embodiment of the present disclosure, non-palladium (Pd)-based metals, such as vanadium (V), niobium (Nb), tantalum (Ta), which are Group 5 elements, and alloys whose main metal is a non-Pd-based metal ( Hereinafter, a hydrogen separation device using a hydrogen permeable membrane formed from a material (also simply referred to as a "non-Pd alloy") will be described. The hydrogen separation device is an example of a hydrogen permeation device according to the present disclosure, and utilizes the property of a hydrogen permeable membrane to selectively permeate hydrogen to separate hydrogen from a fluid containing hydrogen. First, an overview of a hydrogen separation device according to an embodiment will be described, and then a hydrogen permeation device and a manufacturing method thereof according to the present disclosure will be described.

[Configuration of hydrogen separator]
FIG. 1 shows the configuration of a hydrogen separator according to an embodiment. This figure schematically shows a cross section of the hydrogen separator 10. The hydrogen separation device 10 supplies a hydrogen permeable membrane 50 formed of a non-Pd metal or a non-Pd alloy that selectively permeates hydrogen, and a raw material gas containing hydrogen to the primary side surface of the hydrogen permeable membrane 50. The primary side piping 20 is formed with a raw material gas supply flow path 26 for the hydrogen permeation membrane 50 and a raw material gas discharge flow path 28 for discharging the raw material gas that has not passed through the hydrogen permeable membrane 50, and the secondary side of the hydrogen permeable membrane 50. A hydrogen permeable membrane 50 is airtightly sandwiched between the primary pipe 20 and the secondary pipe 30. A primary side gasket 40 and a secondary side gasket 42 are provided. The primary side pipe 20 has a double structure of an outer pipe 22 and an inner pipe 24 arranged coaxially, and the inner side of the inner pipe 24 functions as a raw material gas supply flow path 26, and the outer pipe 22 and the inner pipe 24 The space between them functions as a raw material gas discharge channel 28. Note that the gas flow may be reversed.

The inner diameter of the raw material gas discharge passage 28 of the primary side piping 20 and the inner diameter of the hydrogen recovery passage 32 of the secondary side piping 30 are such that, in the portion far from the hydrogen permeable membrane 50, the primary side gasket 40 and the secondary side gasket 40 However, in the opening part where the primary side piping 20 and the secondary side piping 30 are connected via the hydrogen permeable membrane 50, the inside diameter is the same as the inside diameter of the primary side gasket 40 and the secondary side gasket 42. It has been expanded to. That is, a recessed portion having the same inner diameter as the inner diameter of the primary gasket 40 and the secondary gasket 42 is formed in both the opening of the primary piping 20 and the opening of the secondary piping 30. This makes it possible to efficiently utilize the entire hydrogen permeable membrane 50 to separate hydrogen.

The raw material gas supply channel 26 is connected to a gas generator that generates a hydrogen-containing raw material gas, a storage tank that stores a hydrogen-containing raw material gas, or the like via a regulator (not shown). The raw material gas containing hydrogen is adjusted to a predetermined pressure by a regulator, and is supplied from the raw material gas supply channel 26 to the primary side surface of the hydrogen permeable membrane 50. The hydrogen recovery channel 32 is connected to a configuration for recovering hydrogen that has passed through the hydrogen permeable membrane 50 and reached the hydrogen recovery channel 32 .

The hydrogen permeable membrane 50 is formed of a pure metal of group 5 elements such as V, Nb, and Ta, or an alloy of group 5 elements to which elements such as iron (Fe) and nickel (Ni) are added. Conventionally, research and development of Pd-based hydrogen permeable membranes formed from Pd or Pd alloys has been widely carried out, but in addition to being a rare and expensive metal, Pd has insufficient hydrogen permeability. Therefore, the present inventors have designed and developed a hydrogen-permeable membrane formed of a non-Pd-based metal such as a Group 5 element or a non-Pd-based alloy as an alternative material.

Compared to Pd, which has a face-centered cubic (fcc) lattice structure, V, Nb, and Ta, which have a body-centered cubic (bcc) lattice structure, have a smaller activation energy for hydrogen diffusion, so the hydrogen diffusion coefficient at low temperatures is lower. It has the characteristic of being large. Therefore, it is thought that by using a hydrogen permeable membrane formed of these metals or alloys, a high hydrogen permeation rate can be obtained even at relatively low temperatures. In particular, V has a low activation energy for hydrogen diffusion and is suitable as a material for a hydrogen permeable membrane. Furthermore, these metals and alloys are sufficiently inexpensive compared to Pd and Pd alloys, and therefore are suitable from the viewpoint of manufacturing costs.

It is known that Group 5 elements such as V and Nb cause hydrogen embrittlement, which is a significant deterioration of mechanical properties due to the solid solution of a large amount of hydrogen. Specifically, when the hydrogen concentration exceeds about 0.2 (H/M), a ductile-brittle transition occurs. Therefore, in order to avoid hydrogen brittle fracture of the hydrogen permeable membrane, it is necessary to control the solid solution hydrogen concentration to 0.2 (H/M) or less. According to the findings of the present inventors, elements that have a lower affinity for hydrogen than Group 5 elements, such as Fe, Ni, cobalt (Co), chromium (Cr), molybdenum (Mo), and tungsten (W), etc. and manganese (Mn), ruthenium (Ru), palladium (Pd), gold (Au), rhenium (Re), aluminum (Al), tin (Sn), and gallium (Ga), which have large solid solubility limits for Group 5 elements. By adding such as to the Group 5 element, the solid solution hydrogen concentration can be suppressed. Therefore, by forming the hydrogen permeable membrane 50 with an alloy in which the above-mentioned elements are added to group 5 elements, it is possible to avoid hydrogen embrittlement and breakage of the hydrogen permeable membrane 50 during use of the hydrogen separator 10. can.

On the other hand, when dissolving different elements in metal, the strength increases due to solid solution strengthening, and when the metal is rolled to form the hydrogen permeable membrane 50, the strength also increases due to work hardening. If the amount of the different element added is too large, it becomes difficult to form the hydrogen permeable membrane 50 by rolling the alloy. Therefore, the type and hydrogen content of the raw material gas, the pressure and temperature of the raw material gas, the required purity of hydrogen, the amount of hydrogen recovered per unit time, the service life of the hydrogen separation device 10, the manufacturing cost of the hydrogen separation device 10, etc. When operating conditions such as temperature, primary side pressure, and secondary side pressure when using the hydrogen separator 10 are determined according to the conditions, the composition of an alloy suitable for the determined operating conditions is determined. However, the hydrogen permeable membrane 50 may be formed of an alloy having a determined composition. The composition of the alloy forming the hydrogen permeable membrane 50 may be determined based on a pressure-composition-isotherm (PCT curve) representing the hydrogen dissolution characteristics of the alloy. For example, the hydrogen permeable membrane 50 may be formed of a V alloy containing 0 to 15% Fe in atomic percentage. By setting the content of Fe within the above range, the strength of the alloy can be made to a level that allows rolling processing, and the workability can be improved. When forming the hydrogen permeable membrane 50 by warm rolling (hot rolling), it is preferable that the content of Fe is 0 to 15% in atomic percentage, and when forming the hydrogen permeable membrane 50 by cold rolling. In this case, it is preferable that the Fe content is 0 to 12% in atomic percentage. From the viewpoint of making rolling easier, it is more preferable that the Fe content is 0 to 10% in atomic percentage.

Note that a catalyst is provided on both surfaces of the hydrogen permeable membrane 50 to promote a dissociation reaction from hydrogen molecules to hydrogen atoms on the primary side surface and a recombination reaction from hydrogen atoms to hydrogen molecules on the secondary side surface. Pd or a Pd-based alloy is coated as a layer. Thereby, the hydrogen permeation rate can be improved. Instead of coating with Pd or a Pd-based alloy, both surfaces of the hydrogen permeable membrane 50 may be subjected to oxidation treatment.

In the hydrogen separation apparatus 10 shown in FIG. 1, the raw material gas supply channel 26 and the hydrogen recovery channel 32 are provided perpendicularly to the hydrogen permeable membrane 50, but in another example, the raw material gas supply channel 26 or The hydrogen recovery channel 32 may be provided in parallel to the hydrogen permeable membrane 50 or may be provided in any direction. Further, in the hydrogen separation apparatus 10 shown in FIG. 1, the raw material gas discharge channel 28 is also provided perpendicularly to the hydrogen permeable membrane 50, but in another example, the raw material gas that has not passed through the hydrogen permeable membrane 50 may be may be discharged from an outlet provided near the outer periphery of the hydrogen permeable membrane 50.

[Technology for improving the durability of hydrogen permeable membranes]
Next, in a hydrogen permeation device that uses a hydrogen permeable membrane made of a non-Pd metal or non-Pd alloy (hereinafter also referred to as a "composite membrane") coated with a Pd alloy as a catalyst layer, we will discuss the hydrogen permeability performance of the composite membrane. and techniques for improving durability.

[Control of catalyst layer composition]
FIG. 2 shows the change in hydrogen permeability over time at 550° C. of a composite membrane in which a pure V hydrogen permeable membrane is coated with a pure Pd catalyst layer. The pressure on the primary side was 400 kPa, and the pressure on the secondary side was 200 kPa. Immediately after starting the hydrogen supply, the permeation flow rate began to decrease and reached almost zero in just 30 minutes. It is speculated that one of the main reasons for this rapid deterioration of hydrogen permeability is that V in the hydrogen permeable membrane and Pd in the catalyst layer interdiffused due to the use of the composite membrane at high temperatures. .

FIG. 3 shows the change in hydrogen permeability over time at 300° C. of a composite membrane in which a hydrogen permeable membrane made of an alloy of V and Fe is coated with a catalyst layer made of an alloy of Pd and Ag. The pressure on the primary side was 200 kPa, and the pressure on the secondary side was 10 kPa. The hydrogen permeable membrane is made of V containing 10% Fe in atomic percentage, and the catalyst layer is made of Pd containing 27% Ag in atomic percentage. The permeation flow rate hardly decreased even after 40 days or more, and it was found that it had much higher stability than the case shown in FIG. 2.

Based on the above results, lowering the operating temperature is one of the effective means to suppress the deterioration rate and improve the durability of composite membranes, but using a Pd-based alloy instead of pure Pd as the catalyst layer It is suggested that the use of this material also contributes to improved durability.

Therefore, the present inventors prepared multiple composite membrane samples with different compositions of Pd and Ag in the catalyst layer and conducted a hydrogen permeation test to determine the optimum content of Pd and Ag in the Pd-based alloy forming the catalyst layer. The composition was studied.

A hydrogen-permeable membrane (thickness: 100 μm) formed of a V alloy (V-10%Fe) containing 10% Fe in atomic percent was cleaned, heat-treated at 1000°C for 24 hours, and then a Pd alloy (V-10% Fe) was formed by RF sputtering. A composite film sample was prepared by coating both sides with approximately 200 nm of Pd-x%Ag). The composite membrane was installed as the hydrogen permeable membrane 50 of the hydrogen separation device 10, and operated under the conditions of a temperature of 350°C, a primary pressure of 400 kPa, and a secondary pressure of 103 kPa until the permeation flow rate became stable. Alternatively, the temperature was rapidly raised to 550° C., a hydrogen permeation test was conducted at a primary pressure of 400 kPa, and a secondary pressure of 103 kPa, and changes over time in the hydrogen permeation flow rate were recorded.

FIG. 4 shows the change in hydrogen permeability over time at 550° C. of a composite membrane in which a hydrogen permeable membrane made of an alloy of V and Fe is coated with a catalyst layer made of an alloy of Pd and Ag. When the composite membrane made by coating the V-10% Fe hydrogen permeable membrane with Pd-27%Ag prepared by the above procedure is used at 550°C, the permeation flow rate is faster than when it is used at 300°C as shown in Figure 3. However, the durability is higher than that in the case where the pure V film is coated with pure Pd as shown in FIG. Defining the time until the permeation flow rate decreases by 20% from the permeation flow rate immediately after the start as the 20% deterioration time t _0.2 , a composite membrane consisting of a V-10% Fe hydrogen permeable membrane coated with Pd-27%Ag. The 20% deterioration time t _0.2 when used at 550° C. is 3.3 hours, as shown in FIG. 4.

FIG. 5 shows the relationship between the composition of the catalyst layer and the deterioration time. In the hydrogen permeation test at 450° C., t _0.2 was maximum when the Ag concentration in the catalyst layer was about 20-30%. In the hydrogen permeation test at 500° C., t _0.2 was maximum when the concentration of Ag in the catalyst layer was about 10-30%. In the hydrogen permeation test at 550° C., t _0.2 was maximum when the concentration of Ag in the catalyst layer was about 10-25%.

From the above results, the optimal concentration of Ag in the Pd-based alloy forming the catalyst layer of the composite membrane is 5 to 40%, more preferably 5 to 30%, and still more preferably 10 to 30%. More specifically, when using a composite membrane at 450°C, the optimal concentration of Ag in the catalyst layer is 5 to 40% at which the deterioration time t _0.2 is 40 hours or more, and more preferably the deterioration time t 0.2 is 40 hours _or more. _.2 is 70 hours or more, and more preferably 10 to 35%, where the deterioration time t _0.2 is 100 hours or more. When using a composite membrane at 500°C, the optimal concentration of Ag in the catalyst layer is 2 to 40% at which the deterioration time t _0.2 is 2 hours or more, more preferably the deterioration time t _0.2 is 5 hours or more. 5 to 40% where the deterioration time t _0.2 is 10 hours or more, more preferably 10 to 40% where the deterioration time t _0.2 is 20 hours or more, and even more preferably 15 to 30% where the deterioration time t 0.2 is 20 hours or more. When using a composite membrane at 550°C, the optimal concentration of Ag in the catalyst layer is 5 to 40% at which the deterioration time t _0.2 is 0.8 hours or more, more preferably 5 to 40% when the deterioration time t _0.2 is 2 hours or more. It is 10 to 35% where the deterioration time is 3 hours or more, and more preferably 15 to 30% where the deterioration time t _0.2 is 3 hours or more.

FIG. 6 shows the change in deterioration time versus hydrogen permeation test temperature. The horizontal axis is the reciprocal of the hydrogen permeation test temperature, and the vertical axis is the reciprocal of the deterioration time plotted as the deterioration rate. When the 20% deterioration rate r _{deg — 0.2} (=1/t _0.2 ) is plotted against the reciprocal of temperature, it becomes almost a straight line. Therefore, the lifetime of the composite membrane can be estimated using the approximate formula. It can be seen that the composite membrane coated with a Pd alloy catalyst layer containing 5 to 40% Ag by atomic percentage has a slower deterioration rate and higher durability than the composite membrane coated with a pure Pd catalyst layer. Composite membranes coated with a catalyst layer of Pd alloy containing 10-20% Ag are particularly durable.

In the hydrogen permeation device according to the present disclosure, a Pd-based alloy containing a metal element other than Ag may be used as the catalyst layer. A Pd-based alloy containing both Ag and a metal element other than Ag may be used as the catalyst layer. The metal element other than Ag may be, for example, W.

FIG. 7 shows the relationship between the composition of the catalyst layer and the change in permeation flow rate ratio over time. A composite membrane in which a V-10% Fe hydrogen permeable membrane is coated with a Pd-based alloy containing 28% Ag and 0.8% W as a catalyst layer is a composite membrane in which a Pd-based alloy containing 27% Ag is coated as a catalyst layer. It has been shown to have even higher durability than membranes.

Therefore, the hydrogen permeation device according to the present disclosure includes a hydrogen permeation membrane formed of a pure metal or an alloy, and a catalyst layer formed of an alloy of palladium and silver on the surface of the hydrogen permeation membrane, and the catalyst layer The composition ratio of palladium to silver in The composition ratio is such that the 20% deterioration time t _0.2 , which is the time until the permeation flow rate decreases by 20% from the permeation flow rate immediately after the start, is in the range of the above-mentioned values from [0030] to [0031]. It is characterized by For example, when using an alloy of Pd and Ag, the content of Ag may be in the range of values mentioned above. According to this aspect, the durability of the hydrogen permeation device can be improved.

[Control of crystal orientation of hydrogen permeable membrane]
After conducting the hydrogen permeation test described above, the present inventors analyzed scanning electron microscopy (SEM) images of the surface of the composite membrane and conducted energy dispersive X-ray analysis (EDX). We found that the behavior is different. Therefore, we investigated the relationship between structural changes due to heat treatment of a composite film in which the surface of a V alloy film is coated with a Pd layer and the crystal orientation of the V alloy.

First, high-purity V was cold-forged and cut into a sample piece of 2 mm x 10 mm x 10 mm. This sample piece was heat treated at 5×10 ⁻³ Pa and 1000° C. for 30 minutes, then polished with a 1 μm diamond pad, buffed, and argon ion milled. The surface of the sample before heat treatment was observed using an optical microscope, and the crystal orientation was analyzed using an electron back scattering diffraction (EBSD) method. Subsequently, the surface of the sample piece was coated with a Pd-Ag alloy, and heat treated at 5×10 ⁻³ Pa and 500° C. for 24 hours. The surface of the sample after this heat treatment was observed using an optical microscope, and the crystal orientation was analyzed using the EBSD method.

FIG. 8 is a SEM image of the surface of the composite membrane after heat treatment. A plurality of crystal grains with different crystal orientations are formed on the surface of the composite film. The surface and cross-sectional structures were analyzed at positions (1) to (7) shown in FIG. (1) to (4) correspond to crystal grains whose crystal orientation is ( 111 ) , (5) and (6) correspond to crystal grains whose crystal orientation is ( 101 ) , and (7). ) corresponds to a grain boundary portion between a crystal grain whose crystal orientation is the ( 101 ) orientation and a crystal grain whose crystal orientation is another orientation. Note that V has a body-centered cubic lattice structure, and since orientations such as ( 110 ) , ( 101 ) , and ( 011 ) are crystallographically equivalent, they are represented as {101} .

FIG. 9 is a SEM image of the composite membrane shown in FIG. 8 at positions (1) to (7). It was shown that the surface of (5), whose crystal orientation was ( 101 ) , was flatter than other surfaces and was less likely to deteriorate due to heat treatment. Note that (6) also corresponds to a crystal grain having a crystal orientation of ( 101 ) , but it has irregularities that are thought to be caused by defects.

FIG. 10 is a SEM image of a cross section of the composite membrane shown in FIG. 8 at positions (1) to (7). In the cross section (5) where the crystal orientation is the ( 101 ) orientation, there is almost no mutual diffusion between the Pd layer and the V alloy film, and the structure of the catalyst layer and hydrogen permeable film is well maintained.

FIG. 11 shows the analysis results of the composite film after heat treatment by Auger electron spectroscopy (AES) for each crystal orientation. Even under the same oxygen partial pressure, the behavior of V differs depending on the crystal orientation. The mutual diffusion of Pd and V increases in the order of ( 101 ) orientation, ( 001 ) orientation, and ( 111 ) orientation.

From the above experimental results, when a composite film in which the surface of a V alloy is coated with a Pd-Ag alloy is heat-treated, the mutual diffusion of Pd and V differs depending on the crystal orientation, and there are three types: ( 101 ) orientation, ( 001 ) orientation, and ( 111 ) orientation. It was shown that the value increases in the order of direction. Therefore, it is considered that the durability of the composite film of V alloy and Pd--Ag alloy can be improved by using a V alloy whose crystal orientation is oriented in the {101} direction.

In order to confirm the above findings, continuous hydrogen permeation tests were performed at 400°C using samples in which the surfaces of pure V single crystals with (110), (111), and (100) plane orientations were coated with Pd-25Ag. was carried out to evaluate the durability of the composite membrane. The hydrogen pressure on the primary side was 20 kPa, and the pressure on the secondary side was vacuum. The thickness of the sample was 0.319 mm for the (110) orientation, 0.449 mm for the (111) orientation, and 0.568 mm for the (100) orientation.

FIG. 12 shows the results of a continuous hydrogen permeation test using a pure V single crystal sample. The hydrogen permeability after 168 hours from the start of the test differs significantly depending on the crystal orientation. In the sample with the (110) orientation, the hydrogen permeability hardly decreased even after 168 hours, indicating that it had high durability. The rate of deterioration of hydrogen permeability increases in the order of (110) orientation < (111) orientation < (100) orientation.

FIG. 13 shows SEM images of the surface of the pure V single crystal sample before and after the hydrogen permeation test. FIG. 13(a) is an SEM image immediately after sputtering Pd-25Ag on the surface of a pure V single crystal, and FIG. 13(b) is an SEM image after a continuous hydrogen permeation test. The (110) plane remains flat and in good condition even after continuous hydrogen permeation tests. After the continuous hydrogen permeation test, the (100) and (111) planes had irregularities on their surfaces, suggesting that Pd and V had interdiffused.

Therefore, the hydrogen permeation device according to the present disclosure includes a hydrogen permeation membrane formed of a pure metal or an alloy, and a catalyst layer provided on the surface of the hydrogen permeation membrane, and the hydrogen permeation device at the interface with the catalyst layer. It is characterized in that a predetermined ratio or more of the metal or alloy of the hydrogen permeable membrane is oriented in a specific crystal orientation. According to this aspect, characteristics such as durability of the hydrogen permeation device can be improved.

The hydrogen permeable membrane may be formed of a pure metal or an alloy of metal elements having a body-centered cubic lattice structure. The hydrogen permeable membrane may be formed of a pure metal of a Group 5 element or an alloy containing a Group 5 element as a main metal. The hydrogen permeable membrane may be formed of a pure V metal or an alloy of V and Fe.

The catalyst layer may be formed of pure Pd or an alloy containing Pd as the main metal. The catalyst layer may be formed of an alloy of Pd and one or both of Ag and W.

The composition ratio of Pd and metal elements other than Pd in the Pd-based alloy is determined by the hydrogen permeable membrane under the conditions of primary pressure of 400 kPa, secondary pressure of 103 kPa, and temperature of 450°C, 500°C, or 550°C. When a permeation test is performed, the 20% deterioration time t _0.2 , which is the time until the permeation flow rate decreases by 20% from the permeation flow rate immediately after the start, falls within the range of values described above in [0030] to [0031]. The composition ratio may be as follows. For example, when using an alloy of Pd and Ag, the content of Ag may be in the range of values described above in [0030] to [0032].

The specific crystal orientation may be the {101} orientation. According to this aspect, it is possible to suppress mutual diffusion between the metal atoms forming the hydrogen permeable membrane and the metal atoms forming the catalyst layer, thereby improving the durability of the hydrogen permeation device.

On the surface of the hydrogen permeable membrane, the ratio of regions oriented in a specific crystal orientation is, for example, 10% or more, 20% or more, 30% or more, 40% or more, 50% or more, 60% or more, 70% or more, 80% or more. % or more, and may be 90% or more. The region oriented in a specific crystal orientation may be larger than the region oriented in other crystal orientations. The ratio of crystal orientations can be calculated by analysis using the EBSD method described above.

As mentioned above, from the viewpoint of improving the durability of the hydrogen permeation device, it is preferable to orient the crystal orientation of the pure metal or alloy forming the hydrogen permeation membrane in the {101} direction, but from another viewpoint, Orientation in another direction may be preferred. For example, when using a hydrogen permeation device to remove hydrogen contained in a fluid, after the hydrogen contained in the fluid is selectively permeated through a hydrogen permeable membrane and removed, the hydrogen that has permeated through the hydrogen permeable membrane is It is preferable to prevent the pressure difference between the primary side pressure and the secondary side pressure from returning to the fluid side due to factors such as reversal. From this point of view, the crystal orientation of the pure metal or alloy forming the hydrogen permeable membrane should be oriented in the {100} direction or the {111} direction so that the hydrogen permeability is quickly deactivated after the hydrogen permeable membrane is used. You may let them.

[Method for controlling crystal orientation of thin film]
Any known technique can be used to produce a thin film of pure metal or alloy oriented in a particular crystal orientation, such as forming a metal single crystal. In the present disclosure, as a cheaper and easier method, a step of forming a hydrogen permeable membrane using a pure metal or an alloy, and a step of increasing a region oriented in a specific crystal orientation of the pure metal or alloy on the surface of the hydrogen permeable membrane. We propose a new manufacturing method that includes the following. The step of increasing the area oriented in a specific crystal orientation may include the step of performing a treatment to refine the crystal grain size of the pure metal or alloy on the surface of the hydrogen permeable membrane. Although any technique may be used for the treatment to refine the crystal grain size, there are, for example, the following four methods. The first method is to shot-blast the surface of the hydrogen permeable membrane. The second method is to deposit metal atoms on the surface of the hydrogen permeable membrane using an arc plasma method. The third method is to subject the hydrogen permeable membrane to high-pressure torsion (HPT) processing. The fourth method is to process the hydrogen permeable membrane using high-pressure sliding (HPS). Any known technique can be used for shot blasting, arc plasma deposition, high-pressure twisting, and high-pressure slide processing. Increasing the area oriented in a particular crystal orientation may include performing a heat treatment.

FIG. 14 shows the X-ray diffraction results of the thin film manufactured by the first method according to the present disclosure. The top row shows the X-ray diffraction results of the sample produced by rolling. By rolling, the peak of the (110) plane almost disappears, and the peaks of the (200) plane and (211) plane become predominant. The middle row shows the X-ray diffraction results of a sample obtained by shot blasting the surface of a rolled sample. Due to shot blasting, the peak of the (110) plane becomes predominant. This X-ray diffraction result is almost similar to that of a sample with randomly oriented crystals. That is, since the crystal grains on the surface can be randomly oriented by shot blasting, the crystal grains oriented in the (110) plane, which have almost disappeared by rolling, can be generated again and increased. The bottom row shows the X-ray diffraction results of a shot-blasted sample that was heat-treated at 800° C. and 5×10 ⁻³ Pa for 15 minutes. Each peak became steeper due to the heat treatment.

FIG. 15 shows the X-ray diffraction results of the thin film manufactured by the second method according to the present disclosure. The top row shows the X-ray diffraction results of the same rolled sample as the top row in FIG. The middle row shows the X-ray diffraction results of a sample in which Fe atoms were deposited on the surface of a rolled sample by arc plasma method. Fe coated on the surface of the thin film is mainly oriented in the (110) plane. Therefore, by depositing metal atoms on the surface of a sample using an arc plasma method, it is possible to increase the area oriented in a specific crystal orientation. The bottom row shows the X-ray diffraction results of a sample on which Fe atoms were deposited and heat-treated at 500° C. and 5×10 ⁻³ Pa or less for 1 hour. The peak of the (110) plane of Fe grows slightly due to the heat treatment. Therefore, by performing heat treatment after depositing metal atoms on the surface of the sample by an arc plasma method, it is possible to further increase the area oriented in a specific crystal orientation.

FIG. 16 shows the X-ray diffraction results of the thin film manufactured by the third method according to the present disclosure. The top row shows the X-ray diffraction results of the same rolled sample as the top row in FIG. The middle row shows the X-ray diffraction results of a sample obtained by subjecting the surface of a rolled sample to high-pressure twist processing. The peak of the (110) plane becomes predominant due to high-pressure twisting. Therefore, by subjecting the surface of the sample to high-pressure twisting processing, the area oriented in a specific crystal orientation can be increased. The bottom row shows the X-ray diffraction results of a sample subjected to high-pressure twisting and heat-treated at 800° C. and 5×10 ⁻³ Pa for 15 minutes. Due to the heat treatment, only the peak of the (110) plane and the peak of the (220) plane, which is equivalent to the (110) plane, remain, and the other peaks almost disappear. Therefore, by performing heat treatment after high-pressure twisting on the surface of the sample, it is possible to further increase the area oriented in a specific crystal orientation. According to the third method, a thin film in which almost all the metal on the surface is oriented in the {110} plane can be manufactured easily and inexpensively.

The present disclosure has been described above based on examples. Those skilled in the art will understand that this example is merely an example, and that various modifications can be made to the combinations of these components and processing processes, and that such modifications are also within the scope of the present disclosure. .

DESCRIPTION OF SYMBOLS 10... Hydrogen separation device, 20... Primary side piping, 22... Outer pipe, 24... Inner pipe, 26... Raw material gas supply channel, 28... Raw material gas discharge channel, 30...Secondary side piping, 32...Hydrogen recovery channel, 40...Primary side gasket, 42...Secondary side gasket, 50...Hydrogen permeable membrane.

Claims (5)

A hydrogen permeable membrane formed of a pure metal of Group 5 elements or an alloy containing Group 5 elements as the main metal having a body-centered cubic lattice structure ;
a catalyst layer provided on the surface of the hydrogen permeable membrane and formed of an alloy of palladium and one or both of silver and tungsten ;
Equipped with
40% or more of a pure metal of a group 5 element or an alloy containing a group 5 element as a main metal of the hydrogen permeable membrane at an interface with the catalyst layer is oriented in the {101} direction. The catalyst layer is formed of an alloy of palladium and silver , and the composition ratio of palladium and silver is determined by the hydrogen permeation test of the hydrogen permeable membrane under the conditions of a primary pressure of 400 kPa, a secondary pressure of 103 kPa, and a temperature of 450°C. The hydrogen permeation according to claim 1 , wherein the composition ratio is such that when the permeation flow rate decreases by 20% from the permeation flow rate immediately after the start, the 20% deterioration time t _0.2 is 40 hours or more. Device. 3. The hydrogen permeation device according to claim 1 , wherein the catalyst layer is formed of an alloy of palladium and silver, and the content of silver is 5 to 40% in atomic percentage. A hydrogen permeable membrane formed of a pure metal of Group 5 elements or an alloy containing Group 5 elements as the main metal having a body-centered cubic lattice structure ;
a catalyst layer provided on the surface of the hydrogen permeable membrane and formed of an alloy of palladium and one or both of silver and tungsten ;
Equipped with
In the hydrogen permeable membrane at the interface with the catalyst layer , the pure metal of group 5 elements or the alloy mainly composed of group 5 elements has an area oriented in the {110} plane that is larger than an area oriented in other planes. Hydrogen permeation device. forming a hydrogen permeable membrane using a pure metal of Group 5 elements having a body-centered cubic lattice structure or an alloy containing Group 5 elements as the main metal ;
increasing a region oriented in the {101} direction of a pure metal of a group 5 element or an alloy containing a group 5 element as a main metal on the surface of the hydrogen permeable membrane;
A method for manufacturing a hydrogen permeation device comprising:

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