Reverse Water-Gas Shift Catalyst, Electrolytic Reaction System, Hydrocarbon Production System, and Production Method and Use Method Therefor

Information

  • Patent Application
  • 20230111972
  • Publication Number
    20230111972
  • Date Filed
    March 31, 2021
    3 years ago
  • Date Published
    April 13, 2023
    a year ago
Abstract
A reverse water-gas shift catalyst that can be used at a high temperature is obtained, and a production method thereof is obtained. The reverse water-gas shift catalyst is obtained by at least supporting one or both of nickel and iron as a catalytically active component on a carrier containing a ceria-based metal oxide or a zirconia-based metal oxide as a main component, and a ratio of the carrier to the entire catalyst is 55% by weight or more.
Description
BACKGROUND OF THE INVENTION
Field of the Invention

The present invention relates to a reverse water-gas shift catalyst and a production method for the same, and also relates to an electrolytic (electrolysis) reaction system and a hydrocarbon production system including a catalytic reaction unit using this kind of reverse water-gas shift catalyst.


Description of Related Art

In the production of hydrocarbons, a technique is known in which carbon monoxide and hydrogen are used as raw material gases and methane gas is obtained from these gases.


JP-A-2019-35102 discloses a production system of the carbon monoxide which is one of the raw material gases.


The system disclosed in JP-A-2019-35102 includes an electrolytic device (corresponding to an electrolytic reaction unit of the present invention) that performs electrolysis treatment, supplies carbon dioxide and water to a cathode of this device, and generates hydrogen and carbon monoxide by electrolysis. In this reaction, unreacted water and carbon dioxide remain. Therefore, hydrogen, carbon monoxide, unreacted water, and carbon dioxide sent from the electrolytic device are sent to a reverse shift reactor (corresponding to a reverse water-gas shift reaction unit of the present invention) to react carbon dioxide with hydrogen and generate water and carbon monoxide.


The electrolytic device operates at about 700 to 900° C., the reverse shift reactor operates at about 600 to 950° C., and copper (Cu), nickel (Ni), or the like can be used as the catalyst (paragraph [0029] of the specification).


The catalyst used here is also called a reverse shift catalyst, and is a catalyst which performs a reverse reaction (reaction that generates carbon monoxide and water from carbon dioxide and hydrogen) of the following water-gas shift reaction (reaction that generates carbon dioxide and hydrogen from carbon monoxide and water), that is, a reverse water-gas shift reaction.





CO+H2O→CO2+H2ΔH=−41 kJ/mol


The former water-gas shift reaction is a reaction widely used in hydrogen production processes and the like, and is a reaction in which carbon monoxide is reacted with water to convert into carbon dioxide and hydrogen. However, since the reaction is an exothermic reaction, equilibrium shifts to a carbon dioxide generation side as the reaction is performed at a lower temperature. Therefore, in the related art, a catalyst having high low temperature activity has been developed. Generally, iron-chromium catalysts used at about 300 to 450° C. and copper-zinc catalysts used at about 200° C. are known.


Meanwhile, since there are not many applications that require the reverse reaction of the water-gas shift reaction (reverse water-gas shift reaction), development of a catalyst suitable for the reverse water-gas shift reaction has not been carried out so far.


The reverse water-gas shift reaction is a reaction in which carbon dioxide is reacted with hydrogen to convert into carbon monoxide and water. However, this reaction is an endothermic reaction, and in order to move the equilibrium to the carbon monoxide generation side, unlike the water-gas shift reaction, a high temperature is required, and thus, there is a need for a catalyst that can be used at as high a temperature as possible. However, from this point of view, development of high-performance catalysts suitable for the reverse water-gas shift reaction has not been carried out much.


SUMMARY OF THE INVENTION

An object of the present invention is to obtain a reverse water-gas shift catalyst that can be used at a high temperature and to obtain a method for producing the same. Further, it is an object of the present invention to provide a hydrocarbon production system capable of producing a hydrocarbon by using a reverse water-gas shift reaction together with an electrolytic (electrolysis) reaction.


According to a first characteristic configuration of the present invention, there is provided a reverse water-gas shift catalyst obtained by at least supporting one or both of nickel and iron as a catalytically active component on a carrier containing a ceria-based metal oxide or a zirconia-based metal oxide as a main component. This catalytically active component is a metal catalyst and is supported on the carrier as a metal or a metal oxide thereof.


According to this characteristic configuration, by supporting one or both of nickel and iron as the catalytically active component on the carrier containing the ceria-based metal oxide or the zirconia-based metal oxide as a main component, as described later with reference to Table 1, Table 2, Table 3, and Table 4, the catalyst is highly active on a relatively high temperature side.


In this respect, the inventors also examined alumina as the carrier, but when a calcination temperature was about 450° C., only inferior results were obtained.


The performance of the catalyst having this configuration was also compared with the example of using platinum, which is an expensive precious metal, as the catalytically active component, but the catalyst according to the present invention showed an activity comparable to that of the catalyst using platinum.


When one or both of nickel and iron is used as the catalytically active component, a cost per unit weight can be reduced to 1/1000 or less as compared with platinum, and when the cost is reduced or the same cost is applied, an amount of catalyst used can be increased to each stage, which is preferable.


Further, by using a ceria-based metal oxide or a zirconia-based metal oxide as the carrier, resistance in a high temperature range can be ensured.


In the present invention, the reverse water-gas shift reaction unit is provided on a downstream side (side to which gas generated in electrolytic reaction unit flows) of an electrolytic reaction unit. However, the carrier of the reverse water-gas shift catalyst is formed of the ceria-based metal oxide or the zirconia-based metal oxide, and thus, a thermal expansion coefficient of the reverse water-gas shift catalyst can be made close to that of a material constituting the electrolytic reaction unit, so that the reaction at both units can be satisfactorily generated in almost the same high temperature range.


When this reverse water-gas shift catalyst is obtained, as described in a twelfth characteristic configuration of the present invention,


by executing at least an impregnation-supporting step of adding a carrier containing a ceria-based metal oxide or a zirconia-based metal oxide as a main component to a solution containing one or both of nickel and iron, and impregnating the carrier with at least one or both of nickel and iron to be supported on the carrier, it is possible to produce a reverse water-gas shift catalyst.


When this reverse water-gas shift catalyst is obtained, as described in the thirteenth characteristic configuration of the present invention,


it is preferable to have at least a calcination step of at least supporting one or both of nickel and iron as a catalytically active component on a carrier containing a ceria-based metal oxide or a zirconia-based metal oxide as a main component, and performing calcination at a temperature of 450° C. or higher.


When the reverse water-gas shift catalyst is used, in order to cause a desired reverse water-gas shift reaction, it is necessary to set the reaction temperature range to a relatively high temperature range, but when the catalyst is obtained by calcination in this temperature range, the catalyst can be used stably. The temperature is preferably 450° C. or higher, but more preferably 600° C. or higher and 800° C. or higher because stability in a high temperature range can be improved. For example, the catalyst can be used stably even when combined with a solid oxide type electrolytic cell used in a relatively high temperature range (for example, 600° C. to 800° C.). Further, when the calcination temperature is set too high, a cost required for the calcination step becomes too high, and thus, an upper limit is about 1200° C.


When using this reverse water-gas shift catalyst, it is preferable that the reverse water-gas shift catalyst is subjected to a reaction after being subjected to a reduction pretreatment, as described in the fifteenth characteristic configuration of the present invention.


In many cases, at least a portion of the catalytically active component contained in the reverse water-gas shift catalyst is a metal oxide in the calcination step, but the reduction pretreatment (a treatment for performing a reduction treatment before use) is performed, and thus, the catalytically active component in an oxidized state is reduced and catalytic activity can be satisfactorily exhibited.


In a second characteristic configuration of the present invention,


a ratio of the carrier to the entire catalyst is 55% by weight or more.


% by weight is synonymous with % by mass. The same is applied to below.


According to this characteristic configuration, strength of the catalyst can be increased by increasing the weight ratio of the carrier. Therefore, the ratio of the carrier is preferably 55% by weight or more, more preferably 60% by weight or more, and further preferably 65% by weight or more. Further, for example, an upper limit of this ratio can be 99.5% by weight, but when the upper limit is more than this, the catalytically active component cannot be sufficiently supported, and thus, it may be difficult to obtain the effect as the reverse water-gas shift catalyst.


In a third characteristic configuration of the present invention,


the ceria-based metal oxide is ceria doped with at least one of gadolinium, samarium, and yttrium.


By performing a doping treatment as described later, activity as a catalyst can be improved.


In a fourth characteristic configuration of the present invention,


the zirconia-based metal oxide is zirconia stabilized by at least one of yttria and scandia.


By using the stabilized zirconia as described later, the activity as a catalyst can be improved.


In a fifth characteristic configuration of the present invention,


a supported amount of the catalytically active component is 0.5% by weight or more.


By adopting this configuration, since the reverse water-gas shift reaction can proceed satisfactorily, the supported amount of the catalytically active component is preferably 0.5% by weight or more, more preferably 1% by weight or more, and further preferably 5% by weight or more. Further, when the supported amount of the catalytically active component is increased too much, it becomes difficult to support the catalytically active component in a high dispersion, it is difficult to obtain a significant improvement in the catalytic activity, and the catalyst cost also increases. Accordingly, the supported amount of the catalytically active component is preferably 35% by weight or less, more preferably 30% by weight or less, and further preferably 25% by weight or less.


In a sixth characteristic configuration of the present invention,


copper is supported in addition to the catalytically active component.


According to this characteristic configuration, the activity as the reverse water-gas shift catalyst can be enhanced.


In a seventh characteristic configuration of the present invention,


a supported amount of the copper is equal to or less than a supported amount of the catalytically active component.


As described above, since the main catalytic activity of the reverse water-gas shift catalyst according to the present invention is one or both of nickel and iron, effects of supporting copper can be obtained without interfering with effects exerted by these components.


In an eighth characteristic configuration of the present invention,


there is provided an electrolytic reaction system including at least a reverse water-gas shift reaction unit including at least the reverse water-gas shift catalyst as described above and an electrolytic reaction unit.


According to this characteristic configuration, at least water is electrolyzed by the electrolytic reaction unit, and using the generated hydrogen, carbon dioxide can be converted into carbon monoxide by the reverse water-gas shift catalyst according to the present invention, and a raw material (at least hydrogen and carbon monoxide) used in hydrocarbon synthesis can be obtained.


In this configuration, by adopting the reverse water-gas shift catalyst according to the present invention, which can obtain sufficient activity on a high temperature side, for the reverse water-gas shift reaction unit, for example, hydrocarbons can be efficiently generated by producing hydrogen and carbon monoxide necessary for hydrocarbon synthesis. As will be described later, it is particularly preferable that a ratio of hydrogen and carbon monoxide can be adjusted by a reverse water-gas shift reaction.


Further, the heat (energy) of the electrolytic reaction unit can be effectively used in the reverse water-gas shift reaction unit.


Therefore, as described in an eleventh characteristic configuration of the present invention, when the hydrocarbon synthesis reaction unit is provided in addition to the electrolytic reaction unit and the reverse water-gas shift reaction unit, it is possible to construct a hydrocarbon production system that synthesizes a hydrocarbon using the generated hydrogen and carbon monoxide.


In a ninth characteristic configuration of the present invention,


the electrolytic reaction unit has an electrolytic cell unit in which at least an electrode layer, an electrolyte layer, and a counter electrode layer are formed on a support.


According to this characteristic configuration, as the electrolytic cell used in the electrolytic reaction unit, for example, the thin-film electrode layer, electrolyte layer, and counter electrode layer are provided on a robust support having sufficient strength even if the support is thin. Therefore, the electrolytic reaction can be effectively caused while reducing the amount of the material used to form these layers to be the electrolytic cell. As a result, it is possible to configure an electrolytic cell unit that is compact, has high performance, and has excellent strength and reliability. Metals and ceramics can be selected as constituent materials of this type of support.


Further, as described in a fourteenth characteristic configuration of the present invention, when adopting a configuration of disposing an impregnated supported product, which is obtained through an impregnation-supporting step of impregnating the carrier with at least one or both of nickel and iron to be supported on the carrier, in at least a portion of the support to form a reverse water-gas shift reaction unit, both the electrolytic reaction unit and the reverse water-gas shift reaction unit are formed on the support, and thus, it is possible to obtain an electrolytic cell unit that is compact, has high performance, and has excellent strength and reliability, and further, a hydrocarbon production system having this type of electrolytic cell unit.


In a tenth characteristic configuration of the present invention, the support is a metal.


By adopting a metal as the support, a material cost is suppressed by ensuring the strength with an inexpensive metal material, and it is easier to process than ceramics.





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1 is a diagram illustrating the configuration of a hydrocarbon production system.



FIG. 2 is a schematic diagram illustrating a configuration of an electrolytic reaction unit.



FIG. 3 is a diagram illustrating the configuration of a system in which the electrolytic reaction unit and a reverse water-gas shift reaction unit are integrated.



FIG. 4 is a schematic diagram of an electrolytic cell unit including the electrolytic reaction unit and the reverse water-gas shift reaction unit.



FIG. 5 is a cross-sectional view of an electrolytic cell unit used in a comparative experiment in which an electrode layer-side gas supply path is used as the reverse water-gas shift reaction unit.



FIG. 6 is a configuration diagram of a system equipped with a heat exchanger between the electrolytic reaction unit and the reverse water-gas shift reaction unit.



FIG. 7 is a diagram illustrating another configuration of a hydrocarbon production system that guides CO2 to the reverse water-gas shift reaction unit.



FIG. 8 is a diagram illustrating another configuration of the hydrocarbon production system equipped with the hydrogen separation unit.



FIG. 9 is a diagram illustrating still another configuration of a hydrocarbon production system equipped with the water separation unit in front of a hydrocarbon synthesis reaction unit.



FIG. 10 is a diagram illustrating still another configuration of a hydrocarbon production system in which only water is introduced into the electrolytic reaction unit.



FIGS. 11(a)-(c) are explanatory diagrams illustrating a preparation state of a catalyst.



FIGS. 12(a) and (b) are explanatory diagrams illustrating a coating/calcination state and reduction pretreatment of a catalyst.



FIG. 13 is a schematic diagram of an electrolytic cell unit including the electrolytic reaction unit, the reverse water-gas shift reaction unit, and the hydrocarbon synthesis reaction unit.





DESCRIPTION OF THE INVENTION

An embodiment of the present invention will be described with reference to the drawings.



FIG. 1 illustrates a configuration of one form of a hydrocarbon production system 100 proposed by the inventors.


As illustrated in the figure, the hydrocarbon production system 100 includes an electrolytic reaction unit 10, a first catalytic reaction unit 20, a second catalytic reaction unit 30, a heavy hydrocarbon separation unit 35 (illustrated as a CnHm separation unit), a water separation unit 40 (illustrated as an H2O separation unit), and a carbon dioxide separation unit 50 (illustrated as a CO2 separation unit) in this order.


The electrolytic reaction unit 10 is a unit that electrolyzes at least a portion of an inflowing gas, the first catalytic reaction unit 20 is a reverse water-gas shift reaction unit that carries out a reverse water-gas shift reaction of at least a portion of the inflowing gas, and the second catalytic reaction unit 30 is configured to act as a hydrocarbon synthesis reaction unit that synthesizes at least a portion of the inflowing gas into hydrocarbon. Here, the hydrocarbon synthesized is mainly CH4 (hydrocarbon having one carbon atom), but also includes other lower saturated hydrocarbons having two to four carbon atoms and the like. Further, as will be illustrated later, by appropriately selecting a catalyst used for the second catalytic reaction unit 30, heavy hydrocarbons having a larger number of carbon atoms than the lower saturated hydrocarbons, unsaturated hydrocarbons, oxygen-containing hydrocarbons, or the like can also be synthesized. Therefore, in the present specification, the hydrocarbon is a concept including all of them, and is also collectively referred to as hydrocarbons.


The heavy hydrocarbon separation unit 35, the water separation unit 40, and the carbon dioxide separation unit 50 are units for removing at least a portion of predetermined components (CnHm, H2O, and CO2 in the order of description) from the gas flowing inside. As illustrated in FIG. 1, the components removed and recovered by the water separation unit 40 and the carbon dioxide separation unit 50 are returned to a predetermined unit of the system via a water return path 41 and a carbon dioxide return path 51 and are reused. It is illustrated by H2O and CO2 returned via both return paths 41 and 51, respectively.


As a result, the hydrocarbon production system 100 is established as a carbon closed system that does not substantially release CO2 to the outside of the system.


In the drawings, the gas flowing into each unit is illustrated in front of each unit, and the gas released from the unit is illustrated after each unit.


In the electrolytic reaction unit 10, H2O and CO2 as starting materials flow in and are electrolyzed internally, H2O is decomposed into H2 and O2, and some CO2 is decomposed into CO and O2 and released.


The reaction is described as follows.





2H2O→2H2+O2   (Formula 1)





2CO2→2CO+O2   (Formula 2)


The formulas 1 and 2 are also illustrated in a box illustrating the electrolytic reaction unit 10 of FIG. 1.


In the first catalytic reaction unit 20 (reverse water-gas shift reaction unit), H2 and CO2 flow in, a reverse water-gas shift reaction occurs inside, CO2 becomes CO, H2 becomes H2O, and CO and H2O are released.


The reaction is described as the following equilibrium reaction, but the reverse water-gas shift reaction is a reaction (reaction proceeding in a direction in which CO2 and H2 react to generate CO and H2O) in which the reaction described by the following formula 3 proceeds to the right.





CO2+H2⇔CO+H2O   (Formula 3)


This formula 3 is also illustrated in a box illustrating the first catalytic reaction unit 20 (reverse water-gas shift reaction unit) in FIG. 1. A reverse water-gas shift catalyst cat1 used in the reaction is also schematically illustrated in this box.


In the second catalytic reaction unit 30 (hydrocarbon synthesis reaction unit), H2 and CO flow in, and hydrocarbon is synthesized by a catalytic reaction. For example, the reaction in which CH4 is synthesized from CO and H2 is described as the following equilibrium reaction, but the reaction in which CH4 is synthesized from CO and H2 is a reaction (reaction proceeding in a direction in which CO and H2 react to generate CH4 and H2O) in which the reaction described by the following formula 4 proceeds to the right.





CO+3H2⇔CH4+H2O   (Formula 4)


This formula 4 is also illustrated in a box illustrating the second catalytic reaction unit 30 (hydrocarbon synthesis reaction unit) in FIG. 1. A hydrocarbon synthesis catalyst cat2 used in the reaction is also schematically illustrated in this box.


Furthermore, the equilibrium reaction of (Formula 3) also occurs at this unit.


Further, depending on the type of catalyst used in the second catalytic reaction unit 30, it is possible to proceed with a Fischer-Tropsch (FT) synthesis reaction or the like. Therefore, various hydrocarbons such as ethane, propane, butane, pentane, hexane, paraffin, and olefinic hydrocarbons can be synthesized from CO and H2.


As will be described later, the inventors have illustrated an example of a catalyst using ruthenium as a catalytically active component of the hydrocarbon synthesis catalyst cat2 disposed in the second catalytic reaction unit 30, but heavy hydrocarbons are also synthesized in a catalyst containing iron, cobalt, or the like as the catalytically active component, and this type of heavy hydrocarbon can be condensed and separated from a transport gas as the temperature decreases. Therefore, the above-mentioned heavy hydrocarbon separation unit 35 separates the hydrocarbon component separated in this manner.


The generated H2O is separated in the water separation unit 40 and returned to the upstream side of the electrolytic reaction unit 10 via the water return path 41 (water recycle line).


The generated CO2 is separated in the carbon dioxide separation unit 50 and returned to the upstream side of the electrolytic reaction unit 10 via the carbon dioxide return path 51 (carbon dioxide recycle line).


As a result, in this hydrocarbon production system 100, the hydrocarbon is finally synthesized and can be supplied to the outside.


The above is the outline of the above-mentioned hydrocarbon production system 100, and a configuration of each unit and a role thereof will be described below.


Electrolytic Reaction Unit

As illustrated above, the electrolytic reaction unit 10 decomposes H2O and CO2 that flow in by consuming electric power supplied according to the above formulas 1 and 2.



FIG. 2 schematically illustrates a cross-sectional structure of the electrolytic reaction unit 10.



FIG. 2 illustrates an electrolytic cell unit U which is stacked in multiple to form an electrolytic stack (not illustrated). The electrolytic cell unit U includes an electrolytic (electrolysis) cell 1, and the electrolytic cell 1 includes an electrode layer 2 on one surface of an electrolyte layer 1a and a counter electrode layer 3 on the other surface thereof.


The electrode layer 2 serves as a cathode in the electrolytic cell 1, and the counter electrode layer 3 serves as an anode. Incidentally, this electrolytic cell unit U is supported by a metal support 4. Here, a case where a solid oxide type electrolytic cell is used as the electrolytic cell 1 is illustrated.


The electrolyte layer 1a can be formed in the state of a thin film having a thickness of 10 μm or less. As a constituent material of the electrolyte layer 1a, YSZ (yttria-stabilized zirconia), SSZ (scandia-stabilized zirconia), GDC (gadolinium-doped ceria), YDC (yttrium-doped ceria), SDC (samarium-doped ceria), and LSGM (strontium/magnesium-added lanthanum gallate), or the like can be used. In particular, zirconia-based ceramics are preferably used.


Preferably, the electrolyte layer 1a is formed by a low-temperature calcination method (for example, a wet method using a calcination treatment in a low temperature range that does not carry out a calcination treatment in a high temperature range exceeding 1100° C.), a spray coating method (thermal spraying method, aerosol deposition method, aerosol gas deposition method, a powder jet deposition method, particle jet deposition method, cold spray method, or the like), a PVD method (sputtering method, a pulse laser deposition method, or the like), a CVD method, or the like. These film forming processes that can be used in a low temperature range provide an electrolyte layer 1a that is dense and has high gastightness and gas barrier properties without using calcination in a high temperature range exceeding, for example, 1100° C. Therefore, damage to the metal support 4 can be suppressed, element mutual diffusion between the metal support 4 and the electrode layer 2 can be suppressed, and an electrolytic cell unit U having excellent performance and durability can be realized. In particular, it is preferable to use the low-temperature calcination method, the spray coating method, or the like because a low-cost element can be realized. Further, it is more preferable to use the spray coating method because the electrolyte layer 1a, which is dense and has high gastightness and gas barrier property, can be easily obtained in a low temperature range.


Further, the electrolyte layer 1a is densely configured in order to prevent the gas leak and exhibit high ionic conductivity. A density of the electrolyte layer 1a is preferably 90% or more, more preferably 95% or more, and further preferably 98% or more. When the electrolyte layer 1a is a uniform layer, the density is preferably 95% or more, and more preferably 98% or more. When the electrolyte layer 1a includes a plurality of layers, it is preferable that at least a portion of the electrolyte layer 1a includes a layer (dense electrolyte layer) having a density of 98% or more, and it is more preferable to include a layer (dense electrolyte layer) having a density of 99% or more. In a case where the dense electrolyte layer is included in a portion of the electrolyte layer 1a, even when the electrolyte layer 1a includes a plurality of layers, it is possible to easily form the electrolyte layer 1a that is dense and has high gastightness and gas barrier property.


The electrode layer 2 can be provided in a thin layer on the front surface of the metal support 4 and in a region larger than a region where holes 4a are provided. In the case of a thin layer, a thickness thereof can be, for example, about 1 μm to 100 μm, preferably 5 μm to 50 μm. With such a thickness, it is possible to secure sufficient electrode performance while reducing the amount of expensive electrode layer material used to reduce costs. The entire region provided with the holes (through holes) 4a is covered with the electrode layer 2. That is, the hole 4a is formed inside the region of the metal support 4 where the electrode layer 2 is formed. In other words, all the holes 4a are provided facing the electrode layer 2.


As the constituent material of the electrode layer 2, for example, a composite material such as NiO-GDC, Ni-GDC, NiO—YSZ, Ni—YSZ, CuO—CeO2, Cu—CeO2 can be used. In these examples, GDC, YSZ, and CeO2 can be referred to as aggregates of the composite material. Preferably, the electrode layer 2 is formed by a low-temperature calcination method (for example, a wet method using a calcination treatment in a low temperature range that does not carry out a calcination treatment in a high temperature range exceeding 1100° C.), a spray coating method (thermal spraying method, aerosol deposition method, aerosol gas deposition method, a powder jet deposition method, particle jet deposition method, cold spray method, or the like), a PVD method (sputtering method, a pulse laser deposition method, or the like), a CVD method, or the like. These processes that can be used in the low temperature range provide an improved electrode layer 2 without using, for example, calcination in a high temperature range higher than 1100° C. Therefore, the metal support 4 is not damaged, element mutual diffusion between the metal support 4 and the electrode layer 2 can be suppressed, and an electrochemical element having excellent durability can be realized. Further, it is more preferable to use the low-temperature calcination method because the handling of the raw material becomes easy.


The counter electrode layer 3 can be formed in a thin layer on the surface of the electrolyte layer 1a opposite to the electrode layer 2. In the case of a thin layer, a thickness thereof can be, for example, about 1 μm to 100 μm, preferably 5 μm to 50 μm. With such a thickness, it is possible to secure sufficient electrode performance while reducing the amount of expensive counter electrode layer material used to reduce costs. As the material of the counter electrode layer 3, for example, a composite oxide such as LSCF or LSM, a ceria-based oxide, or a mixture thereof can be used. In particular, it is preferable that the counter electrode layer 3 contains a perovskite-type oxide containing two or more kinds of elements selected from the group consisting of La, Sr, Sm, Mn, Co, and Fe.


The electrolyte layer 1a, the electrode layer 2, and the counter electrode layer 3 are formed as a thin film as described later, and the inventor calls this thin layer forming.


As illustrated above, the electrolytic cell unit U has a metal support type, includes a metal support 4 as a support for the electrode layer 2, and a supply path forming member 5 for forming a U-shaped electrode layer-side gas supply path 5a is provided on a side opposite to the electrode layer 2 in a state where the metal support 4 is interposed therebetween. Further, the metal support 4 is provided with a large number of holes 4a penetrating the front and back surfaces. The gas (H2O and CO2) supplied through the electrode layer-side gas supply path 5a is subject to electrolysis and is supplied to the electrode layer 2 through a large number of holes 4a. Further, the generated gas (H2, CO) is discharged from the hole 4a.


Meanwhile, also on the counter electrode layer 3 side, a supply path forming member 6 for forming a counter electrode layer-side gas supply path 6a is provided. As illustrated in FIG. 2, the supply path forming member 6 is provided with many grooves on the counter electrode layer 3 side and is configured to supply a transport gas g2 (for example, air) to the counter electrode layer-side gas supply path 6a.


The metal support 4 supports the electrode layer 2, the electrolyte layer 1a, and the counter electrode layer 3 and serves as a support for maintaining the strength of the electrolytic cell 1 and the electrolytic cell unit U as a whole. In this example, the plate-shaped metal support 4 is used as the metal support, but other shapes such as a box shape and a cylindrical shape are also possible.


The metal support 4 may have sufficient strength to form the electrolytic cell unit U as a support, and for example, can use a support having a thickness of about 0.1 mm to 2 mm, preferably about 0.1 mm to 1 mm, and more preferably about 0.1 mm to 0.5 mm. In the present embodiment, the support is made of metal, but ceramics can also be used, for example.


The metal support 4 has, for example, the plurality of holes 4a provided so as to penetrate the front surface and the back surface of the metal plate. For example, the hole 4a can be provided in the metal support 4 by mechanical, chemical, or optical drilling. The hole 4a has a function of allowing gas to pass from the back surface to the front surface of the metal support 4. The hole 4a may be provided so as to be inclined in a gas flow direction (the front and back directions of the paper surface in FIG. 2).


By using a ferrite-based stainless steel material (an example of an Fe—Cr-based alloy) as a material of a base material of the metal support 4, a thermal expansion coefficient of the metal support 4 can be made close to those of YSZ (yttria-stabilized zirconia), GDC (gadolinium-doped ceria, also referred to as CGO), and the like used as materials for the electrode layer 2 and the electrolyte layer 1a. Therefore, the electrolytic cell unit U is less likely to be damaged even when the low temperature and high temperature cycles are repeated. Therefore, it is preferable because the electrolytic cell unit U having excellent long-term durability can be realized.


The same material as that of the metal support 4 can be used for the supply path forming members 5 and 6 of the electrolytic cell unit U, and the thickness thereof can be substantially the same.


Although the metal support 4 and both supply path forming members 5 and 6 have conductivity, they are gas-tightly configured to function as a separator for separating the supply paths 5a and 6a.


In the electrolytic cell unit U having the above configuration, in an electrolysis operation, DC power is supplied between the pair of electrode layers 2 and 3 provided with the electrolyte layer 1a interposed therebetween. In the present embodiment, as illustrated in FIG. 2, the case where the electrode layer 2 side is negative and the counter electrode layer 3 side is positive is illustrated. Depending on the configuration of the electrolytic cell unit U, the electrode layer 2 side may be positive and the counter electrode layer 3 side may be negative.


Then, H2O and CO2, which are gases to be electrolyzed, are supplied to the electrode layer 2, and the transport gas g2 is supplied to the counter electrode layer side. Therefore, the reactions illustrated in the formulas 1 and 2 can be caused in the electrolytic cell 1 and the decomposed gas can be taken out. Here, regarding the supply of H2O, either water or steam may be used, or both of them may be used. Therefore, in the present invention, an electrolytic cell device is constructed which includes at least the electrolytic cell unit U, the electrolytic raw material supply unit that supplies water and/or steam and carbon dioxide to the electrolytic cell unit U, and the power supply unit that supplies electric power.


The supplied gas (H2O, CO2) and the released gas (H2O, H2, CO, O2, CO2) in the electrolytic reaction are illustrated above and below the electrolytic cell unit U in FIG. 2. However, this is for ease of understanding, and in fact, the above-mentioned electrode layer-side gas supply path 5a and counter electrode layer-side gas supply path 6a are formed so as to extend in the front and back directions of the paper surface of FIG. 2, and for example, the gas (H2O, CO2) on the supply side described on an upper side of the electrolytic cell unit U in FIG. 2 can be recovered from the front side of the paper surface, and the gas (H2O, H2, CO, O2, CO2) on the release side described on the lower side of the electrolytic cell 1 can be recovered from the back side of the paper surface (refer to FIG. 4 described later). In addition, in order to smoothly perform the discharge of O2 generated in the electrolytic reaction, for example, the transport gas g2 such as air can flow through the electrolytic cell unit U.


When H2O and CO2 are supplied to the electrolytic reaction unit 10 to carry out the electrolysis, H2O has a lower electrolytic voltage than CO2 and is easily electrolyzed. Therefore, when H2O and CO2 having the same amount are temporarily supplied to the electrolytic reaction unit 10 and the electrolytic reaction is carried out, the H2 concentration tends to be higher than the CO concentration at the outlet of the electrolytic reaction unit 10, and unreacted CO2 tends to remain.


First Catalytic Reaction Unit (Reverse Water-Gas Shift Reaction Unit)

As illustrated above, the first catalytic reaction unit 20 (reverse water-gas shift reaction unit) causes a reverse water-gas shift reaction, converts CO2 into CO using the supplied H2, and converts H2 into H2O. That is, in the electrolytic reaction unit 10 that supplies H2O and CO2 to electrolyze, the remaining CO2 that is not decomposed is converted into CO.


The reaction here is as illustrated by the formula 3, but this reaction is an endothermic reaction and is an equilibrium reaction according to the reaction temperature conditions. As a result, it is preferable that the catalyst is capable of causing the reaction represented by the formula 3 on the high temperature side (for example, 600° C. to 800° C.) as much as possible.


In the description of the catalyst in the present specification, a component having activity as a catalyst may be referred to as a “catalytically active component”, and a carrying body carrying the catalytically active component may be referred to as a “carrier (catalyst support)”.


The inventors examined various combinations of catalytically active components and carriers as described later, and found that a specific combination was suitable.


In a production of this type of catalyst, by executing an impregnation-supporting step of immersing the carrier (metal oxide) in a solution containing a catalytically active component (metal component), taking out the carrier, drying and heat-treating the carrier, it is possible to easily obtain a carrier-support catalyst (impregnated supported product) in which the catalytically active component is distributed on the surface of the carrier. This heat treatment is a calcination treatment. The preparation and use of the catalyst will be described with reference to FIGS. 11(a)-(c) and 12(a) and (b).


A preparation method described here is the same except that the starting material is different in the combination of various catalytically active components and carriers. FIGS. 11(a)-(c) illustrate examples of the reverse water-gas shift catalyst cat1 and the hydrocarbon synthesis catalyst cat2 according to the present invention. In FIGS. 11(a)-(c), the catalytically active component of the reverse water-gas shift catalyst cat1 is referred to as ca1, and the carrier thereof is referred to as cb1. Meanwhile, regarding the hydrocarbon synthesis catalyst cat2, the catalytically active component thereof is ca2 and the carrier thereof is cb2.


As illustrated in FIGS. 11(a)-(c), in the catalyst preparation, after an impregnation-supporting step (a) of obtaining an aqueous solution of a compound containing a metal component (which is a metal catalyst) to be the catalytically active components ca1 and ca2, inputting the carriers cb1 and cb2 into the aqueous solution, and carrying out stirring and impregnation is executed, a drying/crushing/molding step (b) of carrying out evaporative drying, drying, and crushing and molding is executed, and thereafter, a calcination step (c) of calcinating an obtained molded product in the air is executed, and thus, the target product (cat1, cat2) can be obtained. Therefore, this form of catalyst is also referred to as an impregnation-supported catalyst.


In this case, as illustrated in the example of the reverse water-gas shift catalyst cat1 in FIGS. 12(a) and (b), the catalyst can be applied to a portion where the catalyst is used and calcinated. FIG. 12(a) illustrates a coating/calcination step in which the reverse water-gas shift catalyst cat1 is applied to the metal support 4 in which the holes 4a are perforated to form a coating layer 20a, and the coating layer 20a is calcinated. FIG. 12(b) illustrates a reduction pretreatment step in which H2 flows to carry out a reduction pretreatment before using the reverse water-gas shift catalyst cat1.


When the calcination treatment is carried out in air, the supported catalytically active components ca1 and ca2 are in a state where a part or all of them are oxidized. Before using the catalyst, a so-called reduction pretreatment may be carried out to reduce the catalytically active component in an oxidized state to sufficiently enhance the activity. FIG. 12(b) illustrates a state in which a reducing gas (typically H2) is circulated on the surface of the catalyst to carry out the reduction pretreatment.


(Catalyst Used)

As the reverse water-gas shift catalyst cat1 which is a catalyst used for the first catalytic reaction unit 20, the inventors have selected a catalyst that satisfies the following requirements.


A catalyst composed by supporting at least one or both of nickel and iron as the catalytically active component ca1 on the carrier cb1 containing a ceria-based metal oxide or a zirconia-based metal oxide as a main component. Here, since the strength of the catalyst cat1 can be increased, a ratio of the carrier cb1 to the entire catalyst is preferably 55% by weight or more, more preferably 60% by weight or more, and further preferably 65% by weight or more. Further, an upper limit of this ratio can be, for example, 99.5% by weight, but when the upper limit is more than this, the catalytically active component ca1 cannot be sufficiently supported, and it may be difficult to obtain the effect as the reverse water-gas shift catalyst.


Further, as the ceria-based metal oxide, ceria doped with at least one of gadolinium, samarium, and yttrium can also be used.


Further, as the zirconia-based metal oxide, zirconia stabilized by at least one of yttria and scandia can also be used.


Since the reverse water-gas shift reaction can proceed satisfactorily, a supported amount of the catalytically active component ca1 is preferably 0.5% by weight or more, more preferably 1% by weight or more, and further preferably 5% by weight or more. Further, when the supported amount of the catalytically active component ca1 is increased too much, it becomes difficult to support the catalytically active component ca1 in a high dispersion, it is difficult to obtain a significant improvement in the catalytic activity, and the catalyst cost also increases. Accordingly, the supported amount of the catalytically active component ca1 is preferably 35% by weight or less, more preferably 30% by weight or less, and further preferably 25% by weight or less.


Further, it is also preferable to add either one or both of nickel and iron to the catalytically active component ca1 to support copper as a further catalytically active component ca1. In this configuration, the supported amount of copper is equal to or less than the supported amount of the catalytically active component ca1 with either one or both of nickel and iron as a main catalytically active component ca1.


Hereinafter, test results of Examples and Comparative Examples in the case where the catalytically active component ca1 and the carrier cb1 are variously changed as the reverse water-gas shift catalyst cat1 used for the first catalytic reaction unit 20 will be described.


As the catalytically active component ca1, Ni and Fe were examined and compared with Pt (platinum).


As the carrier cb1, ZrO2 (zirconia), YSZ (yttria-stabilized zirconia), GDC (gadolinium-doped ceria), CeO2 (ceria), and Al2O3 (alumina) was examined.


In the following description, Test 1 and Test 2 will be introduced, but a difference between the two tests is that in the calcination of the reverse water-gas shift catalyst cat1, the calcination temperature of Test 1 is set to 450° C., and the calcination temperature of Test 2 is set to a high temperature side of 600° C. to 1000° C.


(Test 1)

The test results of Examples (1 to 12) and Comparative Examples (1 to 7) when the carrier is variously changed as the catalyst used for the first catalytic reaction unit 20 will be described.


As the catalytically active component, Ni and Fe were examined and compared with Pt (platinum).


As the carrier, ZrO2 (zirconia), YSZ (yttria-stabilized zirconia), GDC (gadolinium-doped ceria), and CeO2 (ceria) were used as Examples, and Al2O3 (alumina) was used as Comparative Examples.


(Catalyst Preparation)

In preparing the reverse water-gas shift catalyst cat1, an aqueous solution is obtained by quantifying and dissolving any one or both of a water-soluble nickel compound (nickel nitrate, nickel chloride, nickel sulfate, nickel ammonium sulfate, nickel acetate, nickel oxalate, nickel citrate, or the like) and a water-soluble iron compound (iron nitrate, iron chloride, iron sulfate, ammonium iron sulfate, iron acetate, iron oxalate, iron citrate, or the like) according to the composition of the target catalyst. Further, when supporting copper as another catalytically active component ca1, an aqueous solution is obtained by similarly quantifying and dissolving a water-soluble copper compound (copper nitrate, copper chloride, copper sulfate, ammonium copper sulfate, copper acetate, copper oxalate, copper citrate, or the like). A predetermined amount of carrier powder (ceria, zirconia, GDC, YSZ, Al2O3 ) is added to the aqueous solution, stirred and impregnated, then evaporated to dryness, dried, then crushed and molded, and then calcinated in air. This impregnation is the “impregnation-supporting step” referred to in the present invention, and the result is the “impregnated supported product”.


The catalysts of the following Examples and Comparative Examples were prepared using nickel nitrate hexahydrate, iron nitrate nonahydrate, and copper nitrate trihydrate, respectively. The catalyst using Pt in the following Comparative Examples was prepared using tetraammine platinum hydroxide.


In the above catalyst preparation, temperatures of evaporation to dryness, drying, and calcination could be carried out in a generally used temperature range, but in Test 1, the catalysts of the following Examples and Comparative Examples were each prepared at 80° C., 80° C., and 450° C.


Table 1 shows the reverse water-gas shift catalysts cat1 of Examples (1 to 12) and Comparative Examples (1 to 7) prepared.


A horizontal axis represents the type of carrier cb1, a metal supported amount (% by weight; expressed as wt. % in the table) as the catalytically active component, a CO adsorption amount (ml/g), and a BET surface area (m2/g).


Regarding the CO adsorption amount, the CO adsorption amount was measured after the catalyst was subjected to a reduction pretreatment at 350° C. for 1 hour under a hydrogen atmosphere.













TABLE 1







Metal supported
CO adsorption
BET surface


Catalyst
Carrier
amount (wt. %)
amount (Nml/g)
area (m2/g)




















Example 1
Ni/ZrO2
ZrO2
Ni: 9.5
1.48
11.1


Example 2
Ni/8YSZ
8YSZ
Ni: 9.5
1.97
11.3


Example 3
Ni/GDC
GDC
Ni: 9.1
3.61
14.3


Example 4
Ni/CeO2
CeO2
Ni: 14
0.47
9.4


Example 5
Ni—Fe/CeO2
CeO2
Ni: 9.1 Fe: 0.46
0.45
8.9


Example 6
Ni—Cu/CeO2
CeO2
Ni: 9.2 Cu: 0.49
0.78
10.6


Comparative
Ni/Al2O3
Al2O3
Ni: 8.9
0.65
90.7


Example 1


Example 7
Fe/ZrO2
ZrO2
Fe: 9.6
0.88
12.0


Example 8
Fe/8YSZ
8YSZ
Fe: 9.5
0.22
7.5


Example 9
Fe/GDC
GDC
Fe: 9.2
0.30
15.2


Example 10
Fe/CeO2
CeO2
Fe: 9.3
0.53
10.3


Example 11
Fe—Ni/ZrO2
ZrO2
Fe: 9.7 Ni: 0.49
0.52
13.0


Example 12
Fe—Cu/ZrO2
ZrO2
Fe: 9.7 Cu: 0.50
0.21
10.5


Comparative
Fe/Al2O3
Al2O3
Fe: 8.8
0.31
82.8


Example 2


Comparative
Pt/ZrO2
ZrO2
Pt: 0.95
0.95
11.2


Example 3


Comparative
Pt/8YSZ
8YSZ
Pt: 0.92
1.18
4.8


Example 4


Comparative

custom-character  t/GDC

GDC
Pt: 0.96
1.10
10.0


Example 5


Comparative
Pt/CeO2
CeO2
Pt: 0.95
1.17
7.9


Example 6


Comparative
Pt/Al2O3
Al2O3
Pt: 0.95
1.85
97.8


Example 7









(Catalytic Activity Test)

In the catalytic activity test, a mixed gas of 50% H2-50% CO2 (a mixed gas containing H2 and CO2 in a ratio of 1:1 (volume ratio)) was used as a reaction gas, and the reaction temperature was changed from 600° C. to 800° C. in increments of 50° C. under the conditions in which a Gas Hourly Space Velocity (GHSV) was 10000/h.


Before conducting the catalytic activity test, the reduction pretreatment of the catalyst was carried out at 600° C. while flowing a hydrogen gas through the catalyst layer.


As the test results, the CO2 conversion rate (%), the CO concentration (%) at the outlet of the reaction unit, and the CH4 concentration (%) are illustrated in Table 2.


The CO2 conversion rate (%) was calculated according to the following formula based on a gas analysis result at the outlet of the catalyst layer.





[CH4 concentration]+[CO concentration]/([CH4 concentration]+[CO concentration]+[CO2 concentration])


As illustrated above, in the reverse water-gas shift catalyst cat1 used in the first catalytic reaction unit 20 (reverse water-gas shift reaction unit), it is desirable that the CO2 conversion rate (%) on the high temperature side (for example, around 600 to 800° C.) is high.











TABLE 2









Reaction temperature (° C.)













Catalyst

600
650
700
750
800

















Example 1
Ni/ZrO2
CO2 conversion rate (%)
31.8
37.6
41.6
44.0
46.1




Outlet CO concentration (%)
17.9
23.1
25.8
28.0
29.7




Outlet CH4 concentration (%)
3.7
0.9
0.3
0.1
0.1


Example 2
Ni/8YSZ
CO2 conversion rate (%)
32.7
36.4
37.5
39.3
40.7




Outlet CO concentration (%)
16.9
21.1
22.7
23.7
24.8




Outlet CH4 concentration (%)
4.0
1.3
0.6
0.4
0.2


Example 3
Ni/GDC
CO2 conversion rate (%)
29.9
33.8
36.2
38.5
39.6




Outlet CO concentration (%)
14.3
18.8
21.1
22.8
24.3




Outlet CH4 concentration (%)
5.1
2.0
0.9
0.4
0.2


Example 4
Ni/CeO2
CO2 conversion rate (%)
34.5
38.9
41.9
44.7
47.4




Outlet CO concentration (%)
18.4
23.3
25.8
27.9
30.2




Outlet CH4 concentration (%)
3.4
0.8
0.2
0.1
0.0


Example 5
Ni—Fe/CeO2
CO2 conversion rate (%)
34.1
40.0
42.0
45.6
47.7




Outlet CO concentration (%)
18.6
23.6
27.3
29.0
30.5




Outlet CH4 concentration (%)
3.4
0.8
0.2
0.1
0.0


Example 6
Ni—Cu/CeO2
CO2 conversion rate (%)
35.2
41.0
44.2
46.9
48.6




Outlet CO concentration (%)
19.2
24.4
27.3
29.1
31.0




Outlet CH4 concentration (%)
3.3
0.8
0.2
0.1
0.0


Comparative
Ni/Al2O3
CO2 conversion rate (%)
28.5
33.6
35.9
37.4
39.5


Example 1

Outlet CO concentration (%)
15.4
19.3
21.6
23.2
23.9




Outlet CH4 concentration (%)
4.6
1.8
0.8
0.6
0.4


Example 7
Fe/ZrO2
CO2 conversion rate (%)
39.7
42.3
45.1
47.5
49.6




Outlet CO concentration (%)
23.0
25.4
27.2
29.3
31.2




Outlet CH4 concentration (%)
0.0
0.0
0.0
0.0
0.0


Example 8
Fe/8YSZ
CO2 conversion rate (%)
36.3
40.4
43.1
45.9
47.5




Outlet CO concentration (%)
22.5
25.4
27.6
29.3
31.2




Outlet CH4 concentration (%)
0.0
0.0
0.0
0.0
0.0


Example 9
Fe/GDC
CO2 conversion rate (%)
35.8
40.2
42.5
44.6
46.8




Outlet CO concentration (%)
21.9
25.2
27.0
28.6
30.4




Outlet CH4 concentration (%)
0.0
0.0
0.0
0.0
0.0


Example 10
Fe/CeO2
CO2 conversion rate (%)
37.2
40.9
43.5
45.4
48.3




Outlet CO concentration (%)
22.9
25.3
27.6
29.6
31.4




Outlet CH4 concentration (%)
0.0
0.0
0.0
0.0
0.0


Example 11
Fe—Ni/ZrO2
CO2 conversion rate (%)
38.1
41.6
44.0
46.8
48.3




Outlet CO concentration (%)
23.3
25.4
27.6
29.6
31.5




Outlet CH4 concentration (%)
0.1
0.0
0.0
0.0
0.0


Example 12
Ni—Cu/CeO2
CO2 conversion rate (%)
36.5
41.3
45.1
47.3
49.2




Outlet CO concentration (%)
22.9
25.3
27.5
29.6
31.4




Outlet CH4 concentration (%)
0.3
0.1
0.0
0.0
0.0


Comparative
Fe/Al2O3
CO2 conversion rate (%)
22.5
27.6
33.7
40.0
45.0


Example 2

Outlet CO concentration (%)
12.7
15.8
20.1
24.5
28.6




Outlet CH4 concentration (%)
0.1
0.0
0.0
0.0
0.0


Comparative
Pt/ZrO2
CO2 conversion rate (%)
34.0
39.8
43.0
45.7
48.2


Example 3

Outlet CO concentration (%)
19.0
24.4
27.0
29.2
31.3




Outlet CH4 concentration (%)
3.2
0.7
0.2
0.1
0.0


Comparative
Pt/8YSZ
CO2 conversion rate (%)
35.1
40.7
44.1
46.4
48.8


Example 4

Outlet CO concentration (%)
19.3
24.5
27.3
29.4
31.3




Outlet CH4 concentration (%)
3.2
0.7
0.2
0.1
0.0


Comparative
Pt/GDC
CO2 conversion rate (%)
32.9
38.6
42.5
45.2
47.8


Example 5

Outlet CO concentration (%)
18.6
23.5
26.4
28.8
30.6




Outlet CH4 concentration (%)
3.3
0.8
0.2
0.1
0.0


Comparative
Pt/CeO2
CO2 conversion rate (%)
34.9
39.4
43.1
45.6
48.3


Example 6

Outlet CO concentration (%)
19.7
24.1
26.5
29.4
31.4




Outlet CH4 concentration (%)
2.7
0.8
0.2
0.1
0.0


Comparative
Pt/Al2O3
CO2 conversion rate (%)
35.5
41.1
44.7
47.5
49.6


Example 7

Outlet CO concentration (%)
19.4
24.6
27.6
29.7
31.2




Outlet CH4 concentration (%)
3.2
0.8
0.2
0.1
0.0









(Test 2)

Hereinafter, the test results of Examples (13 to 20) and Comparative Examples (8 and 9) of Test 2 will be described. Even in this test,


Ni and Fe were examined as catalytically active components, and the addition of Cu was also examined.


As the carrier, CeO2 (ceria) and ZrO2 (zirconia) are used as Examples, and Al2O3 (alumina) are used as Comparative Examples.


(Catalyst Preparation)

The reverse water-gas shift catalyst cat1 used in Test 2 was prepared in the same manner as in Test 1 except that the calcination temperatures were changed to 600° C., 800° C., and 1000° C.


Table 3 illustrates the catalyst of each of Examples (13 to 20) and Comparative Examples (8 and 9) prepared.













TABLE 3







Calcination
CO adsorption
BET surface


Catalyst
Carrier
temperature (° C.)
amount (Nml/g)
area (m2/g)




















Example 13
Ni/CeO2
CeO2
600
0.9
8.9


Example 14
Ni—Cu/CeO2
CeO2
600
0.53
9.1


Example 15
Fe/ZrO2
ZrO2
600
0.27
13.4


Comparative
Fe/Al2O3
Al2O3
600
0.15
96.0


Example 8


Example 16
Ni/CeO2
CeO2
800
0.26
7.6


Example 17
Ni—Cu/CeO2
CeO2
800
0.51
7.6


Example 18
Fe/ZrO2
ZrO2
800
0.16
10.1


Comparative
Fe/Al2O3
Al2O3
800
0.14
83.5


Example 9


Example 19
Ni/CeO2
CeO2
1000
0.08
5.2


Example 20
Fe/ZrO2
ZrO2
1000
0.29
8.1









(Catalytic Activity Test)

In the catalytic activity test, a mixed gas containing H2 and CO2 in a ratio of 1:1 (volume ratio) was used as a reaction gas, and the reaction temperature was changed from 600° C. to 800° C. in increments of 50° C. under the conditions in which GHSV was 10000/h.


Before conducting the catalytic activity test, the reduction pretreatment of the catalyst was carried out at 600° C. while flowing a hydrogen gas through the catalyst layer.


As the test results, the CO2 conversion rate (%), the CO concentration (%) at the outlet of the reaction unit, and the CH4 concentration (%) are illustrated in Table 4.











TABLE 4









Reaction temperature (° C.)













Catalyst

600
650
700
750
800

















Example 13
Ni/CeO2
CO2 conversion rate (%)
33.8
39.5
42.8
45.7
48.1




Outlet CO concentration (%)
18.8
24.2
27.4
29.6
31.4




Outlet CH4 concentration (%)
3.3
0.8
0.2
0.0
0.0


Example 14
Ni—Cu/CeO2
CO2 conversion rate (%)
34.7
40.4
42.9
44.6
46.7




Outlet CO concentration (%)
19.1
24.4
27.0
28.6
29.9




Outlet CH4 concentration (%)
3.7
0.9
0.2
0.1
0.0


Example 15
Fe/ZrO2
CO2 conversion rate (%)
38.1
40.4
43.1
45.7
48.2




Outlet CO concentration (%)
23.3
25.8
28.0
30.2
31.8




Outlet CH4 concentration (%)
0.0
0.0
0.0
0.0
0.0


Comparative
Fe/Al2O3
CO2 conversion rate (%)
24.8
29.0
35.3
40.6
45.3


Example 8

Outlet CO concentration (%)
14.0
16.8
20.8
25.3
29.5




Outlet CH4 concentration (%)
0.0
0.0
0.0
0.0
0.0


Example 16
Ni/CeO2
CO2 conversion rate (%)
33.9
39.2
42.7
45.6
47.1




Outlet CO concentration (%)
19.2
24.6
27.4
29.5
31.7




Outlet CH4 concentration (%)
3.3
0.7
0.2
0.0
0.0


Example 17
Ni—Cu/CeO2
CO2 conversion rate (%)
34.2
39.3
41.9
44.3
46.6




Outlet CO concentration (%)
18.5
23.9
26.0
28.7
30.7




Outlet CH4 concentration (%)
3.6
0.9
0.1
0.1
0.0


Example 18
Fe/ZrO2
CO2 conversion rate (%)
38.1
41.2
43.7
46.2
48.4




Outlet CO concentration (%)
23.5
25.7
28.1
30.0
31.9




Outlet CH4 concentration (%)
0.0
0.0
0.0
0.0
0.0


Comparative
Fe/Al2O3
CO2 conversion rate (%)
22.2
25.2
32.7
38.9
43.9


Example 9

Outlet CO concentration (%)
13.4
15.1
20.0
24.5
29.1




Outlet CH4 concentration (%)
0.0
0.0
0.0
0.0
0.0


Example 19
Ni/CeO2
CO2 conversion rate (%)
34.5
40.6
44.5
46.3
48.7




Outlet CO concentration (%)
19.1
24.6
28.6
30.4
31.8




Outlet CH4 concentration (%)
3.5
0.8
0.2
0.1
0.0


Example 20
Fe/ZrO2
CO2 conversion rate (%)
37.8
41.2
44.5
46.0
48.1




Outlet CO concentration (%)
22.6
25.5
27.6
29.5
31.3




Outlet CH4 concentration (%)
0.0
0.0
0.0
0.0
0.0













Reference
CO2 conversion rate (%)
34.6
39.9
43.6
46.4
49.0


(equilibrium value)









For reference, an equilibrium value (calculated value) of the CO2 conversion rate under the experimental conditions is illustrated in Table 4.


Iron/Zirconia Catalyst and Iron/Alumina Catalyst

For the iron/zirconia catalyst, the test results when the calcination temperatures are 450° C., 600° C., 800° C., and 1000° C. are illustrated in Example 7, Example 15, Example 18, and Example 20, respectively. Meanwhile, for the iron/alumina catalyst, the test results when the calcination temperatures are 450° C., 600° C., and 800° C. are illustrated in Comparative Example 2, Comparative Example 8, and Comparative Example 9, respectively. As can be seen from these results, although the metal supported amount is slightly different, the iron/zirconia catalyst is superior to the iron/alumina catalyst in the activity in carrying out the reverse water-gas shift reaction. Further, the iron/zirconia catalyst has extremely high catalytic activity not only when the calcination temperature is 450° C. but also when the calcination temperature is as high as 600° C., 800° C., and 1000° C., and regardless of the calcination temperature, the CO2 conversion rate of the iron/zirconia catalyst reaches the vicinity of the equilibrium value.


Nickel/Ceria Catalyst

The test results when the calcination temperatures are 450° C., 600° C., 800° C., and 1000° C. are illustrated in Example 4, Example 13, Example 16, and Example 19, respectively. As can be seen from these results, the nickel/ceria catalyst has extremely high catalytic activity not only when the calcination temperature is 450° C. but also when the calcination temperature is as high as 600° C., 800° C., and 1000° C., and regardless of the calcination temperature, the CO2 conversion rate of nickel/ceria catalyst reaches the vicinity of the equilibrium value.


Nickel/Alumina Catalyst

Comparative Example 1 illustrates the test results when the calcination temperature is 450° C. As a result, the nickel/alumina catalyst had a lower CO2 conversion rate than the nickel/ceria catalyst described above.


Nickel/Copper/Ceria Catalyst

The test results when the calcination temperatures are 450° C., 600° C., and 800° C. are illustrated in Example 6, Example 14, and Example 17, respectively. From these results, it can be seen that the CO2 conversion rate of the nickel/copper/ceria catalysts tends to decrease slightly when the calcination temperature thereof is as high as 600° C. or 800° C., but the calcination temperature conditions described above are superior to those of the similar iron/alumina catalyst. Further, in the nickel/copper/ceria catalyst having the calcination temperature of 450° C., the CO2 conversion rate reaches the vicinity of the equilibrium value.


Usefulness as Reverse Water-Gas Shift Catalyst

As illustrated above, the iron/zirconia-based catalysts and the nickel/ceria-based catalysts exhibit extremely high reverse water-gas shift catalytic activity even when the calcination temperature is variously changed to 450° C. to 1000° C., and thus, for example, even when used in combination with a solid oxide type electrolytic cell used in a high temperature range of around 600° C. to 800° C., it is easy to secure high performance and durability, which is useful.


From the above results, as illustrated above, as the reverse water-gas shift catalyst cat1 used for the first catalytic reaction unit 20, the catalyst obtained by supporting at least one or both of nickel and iron as the catalytically active component ca1 on the carrier cb1 containing the ceria-based metal oxide or the zirconia-based metal oxide as a main component can be used.


Further, as the ceria-based metal oxide as the carrier cb1, ceria doped with at least one of gadolinium, samarium, and yttrium can also be used.


Further, the zirconia-based metal oxide as the carrier cb1 can be zirconia stabilized by at least one of yttria and scandia.


Further, it is also preferable to add either one or both of nickel and iron to the catalytically active component ca1 to support copper as a further catalytically active component ca1.


By using the reverse water-gas shift catalyst cat1 in the first catalytic reaction unit 20 (reverse water-gas shift reaction unit), the reverse water-gas shift reaction can be carried out at around 600 to 1000° C. with the CO2 conversion rate (%) equal to or higher than that of the Pt catalyst, which is highly active but very expensive.


Since the test of this example was carried out under a very high GHSV condition of 10000/h, by reducing the GHSV to less than 10000/h, that is, by increasing the amount of catalyst used with respect to the amount of gas to be treated, it is possible to carry out the reverse water-gas shift reaction at a higher CO2 conversion rate (%).


Combination of Electrolytic Reaction Unit and Reverse Water-Gas Shift Reaction Unit

In the description so far, according to the system configuration illustrated in FIG. 1, the electrolytic reaction unit 10 and the reverse water-gas shift reaction unit 20 are individually provided in the order described along the flow direction of the gas.


The reaction of the electrolytic reaction unit 10 is an exothermic reaction depending on the reaction conditions, and the reaction of the reverse water-gas shift reaction unit 20 is an endothermic reaction. Therefore, thermal efficiency of the system can be improved by integrating the two reaction units 10 and 20. In this way, FIG. 3 illustrates a configuration in which the two reaction units 10 and 20 are combined and integrated, and the integration is illustrated to surround both units. In addition, a reaction when integrated in the same box in this way is illustrated. Basically, the above-mentioned formulas 1, 2, and 3 are carried out. In a case where the electrolytic reaction unit 10 and the reverse water-gas shift reaction unit 20 are combined and integrated, preferably, when the units are surrounded together by a heat insulating member, heat can be efficiently transferred between the electrolytic reaction unit 10 and the reverse water-gas shift reaction unit 20. Further, in order to transfer the heat generated in the electrolytic reaction unit 10 to the reverse water-gas shift reaction unit 20, the electrolytic reaction unit 10 and the reverse water-gas shift reaction unit 20 may be connected using a heat transfer member.


Electrolytic Cell Unit Equipped with Both Electrolytic Reaction Unit and Reverse Water-Gas Shift Reaction Unit

Based on the above concept, it is preferable to provide the reverse water-gas shift reaction unit 20 in the electrolytic cell unit U which is the electrolytic reaction unit 10. This is because when a solid oxide type electrolytic cell that operates at around 600 to 800° C. is used as the electrolytic cell 1, in the reverse water-gas shift catalyst cat1 of the present application which can obtain high activity at around 600 to 800° C., the electrolytic reaction unit 10 and the reverse water-gas shift reaction unit 20 can be used in the same temperature range.


In this case as well, it is sufficient that the gas that has passed through the electrolytic reaction unit 10 is guided to the reverse water-gas shift reaction unit 20 to generate the reverse water-gas shift reaction.



FIG. 4 illustrates an electrolytic cell unit U provided with such a reverse water-gas shift reaction unit 20. FIG. 4 is a diagram illustrating the electrolytic cell unit U illustrated in cross section in FIG. 2 including the flow direction of the gas.


As illustrated in FIG. 4, the cross sections of the electrolytic cell unit U are basically the same.


That is, the electrolytic cell unit U also includes the electrolytic cell 1 in which the electrode layer 2 and the counter electrode layer 3 are formed with the electrolyte layer 1a interposed therebetween, the metal support 4 which functions as a support thereof and also acts as a separator, and the supply path forming members 5 and 6, and the electrode layer-side gas supply path 5a and the counter electrode layer-side gas supply path 6a are formed in the electrolytic cell unit U. More specifically, as can be seen from FIG. 4, when the metal support 4 is viewed in the flow direction of gas, the holes 4a are provided in the portion corresponding to the electrolytic cell 1, but the hole is not provided on the downstream side of the electrode layer 2. Therefore, the metal support 4 is a separator which effectively separates the gas which is supplied to the electrode layer 2 and released from the electrode layer 2, and the gas which is supplied to the counter electrode layer 3 gas and is released from the counter electrode layer 3.


However, in this example, the reverse water-gas shift catalyst cat1 described above is applied to an inner surface (supply path-side inner surface of supply path forming member 5, surface of the metal support 4 opposite to surface on which electrode layer 2 is formed, and surfaces of the plurality of holes 4a) of the electrode layer-side gas supply path 5a. A coating layer 20a is illustrated by a thick solid line. Further, the electrode layer-side gas supply path 5a extends beyond the electrolytic reaction unit 10, and the coating layer 20a is also provided on the extension side.


As a result, the electrode layer-side gas supply path 5a of the electrolytic cell unit U is a discharge path for discharging at least H2 generated in the electrode layer 2, and the electrolytic cell unit U is integrally provided with the electrolytic reaction unit 10 and the reverse water-gas shift reaction unit 20.


In this configuration, the metal support 4 acts as a separator that separates H2 generated in the electrode layer 2 and O2 generated in the counter electrode layer 3, and at least a portion of the separator on the discharge path side of H2 is reverse water-gas shift reaction unit 20.


By stacking the electrolytic cell units U configured in this way in a right-left direction of FIGS. 2 and 4, a large number of electrolytic cell units U are stacked, and it is possible to form a so-called electrolytic cell module (not illustrated) in which the electrolytic cell units are electrically connected to each other. Of course, a useful gas generated can be obtained over multiple layers.


The inventors have stored a granular reverse water-gas shift catalyst cat1 in the electrode layer-side gas supply path 5a and conducted an experiment under a concept in which the electrolytic reaction unit 10 and the reverse water-gas shift reaction unit 20 are combined with each other (the electrode layer-side gas supply path 5a of the electrolytic reaction unit 10 is the reverse water-gas shift reaction unit 20).



FIG. 5 illustrates a cross section of the electrolytic cell unit U used in this experiment.


Hereinafter, a specific description will be given with reference to FIG. 5. FIG. 5 illustrates a cross-sectional view of the electrolytic cell unit U.


Here, as the electrolytic cell 1, a metal-supported solid oxide type electrolytic cell was used. As the metal support 4, a metal substrate was prepared by providing a plurality of through holes (which become holes 4a) by applying laser processing to a ferritic stainless steel metal plate having a thickness of 0.3 mm The electrode layer 2 and an intermediate layer 2a were formed in this order on the metal substrate, and the electrolyte layer 1a was formed on the intermediate layer 2a of the metal substrate so as to cover the intermediate layer 2a. Further, a reaction prevention layer 7 and the counter electrode layer 3 were sequentially formed on the electrolyte layer 1a to prepare the electrolytic cell 1. A mixture of NiO powder and GDC powder was used as the material for forming the electrode layer 2, GDC powder was used as the material for forming the intermediate layer 2a, 8YSZ (8 mol % yttria-stabilized zirconia) powder was used as the material for forming the electrolyte layer 1a, GDC powder was used as the material for forming the reaction prevention layer 7, and a mixture of and GDC powder and LSCF powder was used as the material for forming the counter electrode layer 3. Further, the thicknesses of the electrode layer 2, the intermediate layer 2a, the electrolyte layer 1a, the reaction prevention layer 7, and the counter electrode layer 3 were about 25 μm, about 10 μm, about 5 μm, about 5 μm, and about 20 μm, respectively. By providing the intermediate layer 2a between the electrode layer 2 and the electrolyte layer 1a and providing the reaction prevention layer 7 between the electrolyte layer 1a and the counter electrode layer 3, the performance and durability of the electrolytic cell 1 can be improved. Moreover, preferably, the intermediate layer 2a and the reaction prevention layer 7 are formed by a low-temperature calcination method (for example, a wet method using a calcination treatment in a low temperature range that does not carry out a calcination treatment in a high temperature range exceeding 1100° C.), a spray coating method (thermal spraying method, aerosol deposition method, aerosol gas deposition method, a powder jet deposition method, particle jet deposition method, cold spray method, or the like), a PVD method (sputtering method, a pulse laser deposition method, or the like), a CVD method, or the like. These processes that can be used in the low temperature range provide the improved intermediate layer 2a and reaction prevention layer 7 without using, for example, calcination in a high temperature range higher than 1100° C. Therefore, it is preferable because the electrolytic cell 1 having excellent performance and durability can be realized without damaging the metal support 4. Further, it is more preferable to use the low-temperature calcination method because the handling of the raw material becomes easy.


Regarding the electrolytic cell unit U obtained as described above, the performance improvement in the case where the reverse water-gas shift catalyst cat1 formed in the form of particles was stored in the electrode layer-side gas supply path 5a (which also serves as the discharge path of the gas electrolyzed by the electrolytic reaction unit 10) was examined.


Results When Reverse Water-Gas Shift Catalyst cat1 is Not Stored


An electrolytic reaction was carried out while supplying a gas containing H2O and CO2 to the electrolytic cell unit U, and a ratio of H2 to CO of an outlet gas of the electrolytic cell unit U was measured using a gas chromatograph. The results are illustrated in Table 5 below. The experimental results are described as Comparative Examples A1 and A2.














TABLE 5








Electrolytic
Reaction
Ratio of H2/



Inlet gas
voltage (V)
temperature (° C.)
CO of outlet gas




















Comparative
52%H2O—13%CO2—N2
1.2
700
14.2


Example A1
balance


Comparative
49%H2O—17%CO2—N2
1.2
700
9.9


Example A2
balance










Results When the Reverse Water-Gas Shift Catalyst cat1 is Stored


As the reverse water-gas shift catalyst cat1, a granular catalyst obtained by supporting about 10% of Ni on the 8YSZ carrier similar to in Example 2 was stored, an electrolytic reaction was carried out while supplying a gas containing H2O and CO2 to the electrolytic cell unit U, and the ratio of H2 to CO of the outlet gas of the electrolytic cell unit U was measured using a gas chromatograph. The results are illustrated in Table 6. The experimental result is described as Example A1.














TABLE 6








Electrolytic
Reaction
Ratio of H2/



Inlet gas
voltage (V)
temperature (° C.)
CO of outlet gas




















Example A1
51%H2O—16%CO2—N2
1.15
700
5.4



balance










By the above comparative experiment, in the electrolytic cell unit U in which the electrolytic cell 1 was formed in a thin layer on the metal support 4, and the reverse water-gas shift reaction unit 20 generating CO by using CO2 and H2 by the reverse water-gas shift reaction was provided in the electrode layer-side gas supply path 5a which was the discharge path of the electrolyzed gas, it was possible to increase a composition ratio of CO to H2 generated by electrolysis.


In the comparison between the electrolytic cell unit U in which the reverse water-gas shift catalyst cat1 is not stored in the electrode layer-side gas supply path 5a (which is the discharge path for the electrolyzed gas) and the electrolytic cell unit U in which the reverse water-gas shift catalyst cat1 is stored, the hydrogen/carbon monoxide ([H2/CO]) ratio changes from about 10 or more to about 5 at the outlet, and by combining the reaction of the electrolytic reaction unit 10 and the reaction of the reverse water-gas shift reaction unit 20, the amount of CO that is advantageous for various hydrocarbon syntheses can be secured, which is preferable. In addition, since thermal efficiency of the hydrocarbon production system 100 can be improved by adopting a methanation reaction of CO rather than a methanation reaction of CO2, by combining the reaction of the electrolytic reaction unit 10 and the reaction of the reverse water-gas shift reaction unit 20, the amount of CO can be secured, which is preferable. This is because 2 mol of H2O is generated when 1 mol of CO2 is methanized, whereas 1 mol of H2O is generated when 1 mol of CO is methanized, and thus, the hydrocarbon production system 100 that employs the methanation reaction of CO can suppress latent heat and sensible heat loss of 1 mol of H2O as a whole system.


By appropriately adjusting the ratio of H2O and CO2 introduced into the electrolytic reaction unit 10, the reaction conditions electrolytic (electrolysis) voltage, reaction temperature, or the like) of the electrolytic reaction unit 10, the reaction conditions (amount of catalyst used, GHSV, reaction temperature, or the like) of the reverse water-gas shift reaction unit 20, or the like, the hydrogen/carbon monoxide ([H2/CO]) ratio at the outlet of the reverse water-gas shift reaction unit 20 can be adjusted to a value (for example, H2/CO=3 which is the equivalent ratio of the methanation reaction of CO, or the like) suitable for the second catalytic reaction unit 30 (hydrocarbon synthesis reaction unit) in the subsequent stage.


Install Heat Exchanger between Electrolytic Reaction Unit and Reverse Water-Gas Shift Reaction Unit

In the descriptions so far, the example in which the electrolytic reaction unit 10 and the first catalytic reaction unit (reverse water-gas shift reaction unit) 20 are integrated has been mainly described, however, it is possible to adopt a configuration in which both units 10 and 20 are set as separate units and a heat exchanger 11 is provided between both units 10 and 20 so that heat can be exchanged between both units. This configuration is illustrated in FIG. 6 corresponding to FIG. 1. A hollow double line illustrates the heat transfer between both units. In this configuration, the temperature of each of the units 10 and 20 can be appropriately controlled.


The inventors have called the system including the electrolytic reaction unit 10 and the reverse water-gas shift reaction unit 20 described so far as an “electrolytic reaction system”.


Second Catalytic Reaction Unit (Hydrocarbon Synthesis Reaction Unit)

At least H2 and CO flow into the second catalytic reaction unit 30 (hydrocarbon synthesis reaction unit), and hydrocarbons (methane and various hydrocarbons having two or more carbon atoms) and the like are generated by the catalytic reaction.


(Example Of Hydrocarbon Synthesis Catalyst)

As an activity test of the catalyst (hydrocarbon synthesis catalyst cat2) used in the second catalytic reaction unit 30, the inventors conducted the following evaluation test 1, evaluation test 2, and evaluation test 3.


As an example of the hydrocarbon synthesis catalyst cat2, a catalyst was prepared by variously changing the carrier and the catalytically active component. As the catalytically active component ca2, those obtained by adding Mo, V, Fe, Co, and the like to Ru and Ru, and Ni were examined. As the carrier cb2, ZrO2, Al2O3, SiO2, MgO, and TiO2 were examined.


(Catalyst Preparation)

The preparation of the hydrocarbon synthesis catalyst cat2 was also the method adopted as described with reference to FIGS. 11(a)-(c) and 12(a) and (b).


That is, a water-soluble ruthenium compound (ruthenium nitrate, ruthenium chloride, ruthenium sulfate, ruthenium ammonium sulfate, ruthenium acetate, ruthenium oxalate, ruthenium citrate, or the like) is quantified and dissolved according to the composition of the target catalyst to obtain an aqueous solution. Further, when molybdenum, vanadium, iron, and cobalt are supported as further catalytically active components, these water-soluble metal compounds are similarly quantified to obtain a dissolved aqueous solution. Using the aqueous solution, for example, by impregnating and supporting the catalytically active component on carrier particles (ZrO2, Al2O3, SiO2, MgO, TiO2) having a predetermined amount, and carrying out necessary treatment steps such as a drying treatment, a calcination treatment, and a reduction treatment, the hydrocarbon synthesis catalyst cat2 can be obtained.


Using ruthenium chloride aqueous solution, ammonium molybdate aqueous solution, vanadyl oxalate aqueous solution, iron nitrate aqueous solution, and cobalt nitrate aqueous solution, respectively, and when both ruthenium and catalytically active components other than ruthenium are supported, the catalysts of the following examples were prepared using a sequential carrier method (a two-step carrier method in which a catalytically active component other than ruthenium is first supported on a carrier and then ruthenium is supported).


(Evaluation Test 1)

In the evaluation test 1, a mixed gas containing 12.4% CO, 24.8% CO2, 37.2% H2, 12.4% H2O and the balance being N2 was used as the reaction gas, GHSV was set to 4000/h (WET base), and the activity test of the hydrocarbon synthesis catalyst cat2 was carried out at a reaction temperature of 275° C. to 360° C. In this case, the reaction gas is an example obtained by assuming a model in which a co-electrolysis reaction between water and carbon dioxide in the electrolytic reaction unit 10 is carried out under the conditions that an electrolytic reaction rate of carbon dioxide is low, and a mixed gas of CO, CO2, H2, and H2O after the reverse water-gas shift reaction of carbon dioxide is carried out in the reverse water-gas shift reaction unit 20 installed in the subsequent stage is introduced into the hydrocarbon synthesis reaction unit 30 to carry out the hydrocarbon synthesis reaction.


The following two indicators were adopted when organizing the test results.


1. CO2 removal assumed hydrocarbon conversion rate=[number of carbons in hydrocarbons in outlet gas]/[number of carbons in outlet gas−number of carbons in outlet CO2]


This indicator is an indicator illustrating the conversion rate to hydrocarbons when CO2 is removed from the outlet gas of the hydrocarbon synthesis reaction unit 30 obtained by the catalytic reaction, and it is preferable that this indicator is high.


2. C1-C4 calorific value (MJ/Nm3)=/(Nn×HN)/ΣNn


Nn [mol]: number of moles of Cn hydrocarbon in gas of catalytic reaction unit (n=1 to 4)


HN [MJ/m3(N)]: calorific value of Cn hydrocarbon in gas of catalytic reaction unit


[H1=39.8, H2=69.7, H3=99.1, H4=128.5]


This indicator is an indicator illustrating amounts of C1 to C4 components contained in the outlet gas of the hydrocarbon synthesis reaction unit 30 obtained by the catalytic reaction, and when this value exceeds 39.8, it can be confirmed that hydrocarbons such as ethane, propane, and butane are generated in addition to methane.


Regarding the evaluation test 1, Tables 7 and 8 illustrated below illustrate Examples B1 to B3 of the hydrocarbon synthesis catalyst cat2 in the present invention.















TABLE 7









Active component
BET surface
CO adsorption



Catalyst
Carrier
supported amount (wt. %)
area (m2/g)
amount (ml/g)





















Example B1
Ru/Al2O3
Al2O3
Ru: 0.4
87.4
0.66


Example B2
Ru/Mo/Al2O3
Al2O3
Ru: 0.6, Mo: 0.7
88.2
1.06


Example B3
Ru/V/Al2O3
Al2O3
Ru: 0.7, V: 1.2
91.1
1.20


















TABLE 8









Reaction temperature (° C.)














Catalyst
Indicator
275
310
335
360

















Example B1
Ru/Al2O3
CO2 removal assumed hydrocarbon conversion rate (%)
12.4


100.0




C1-C4 calorific value (MJ/Nm3)
44.9


39.8


Example B2
Ru/Mo/Al2O3
CO2 removal assumed hydrocarbon conversion rate (%)


99.8




C1-C4 calorific value (MJ/Nm3)


39.9


Example B3
Ru/V/Al2O3
CO2 removal assumed hydrocarbon conversion rate (%)

90.0




C1-C4 calorific value (MJ/Nm3)

42.1









As illustrated in Tables 7 and 8, it was confirmed that hydrocarbons could be synthesized using a catalyst in which ruthenium was supported on an alumina carrier or a catalyst in which molybdenum or vanadium was supported in addition to ruthenium as a hydrocarbon synthesis catalyst cat2 from the mixed gas of CO, CO2, H2, and H2O.


From the above results, it was confirmed that the above-mentioned hydrocarbon production system 100 could generate a high-calorie gas having a C1-C4 calorific value of 39 MJ/Nm3 or more.


(Evaluation Test 2)

In the evaluation test 2, a mixed gas containing 0.45% CO, 18.0% CO2, 71.55% H2, and 10.0% H2O was used as the reaction gas, GHSV was set to 5000/h (DRY base), and the activity test of the hydrocarbon synthesis catalyst cat2 was carried out at a reaction temperature of about 230° C. to about 330° C. In this case, the reaction gas is an example obtained by assuming a model in which the mixed gas obtained when the co-electrolysis reaction of water and carbon dioxide is carried out in the electrolytic reaction unit 10 under the conditions that the electrolytic reaction rate of carbon dioxide is low is introduced into the hydrocarbon synthesis reaction unit 30 to carry out a hydrocarbon synthesis reaction.


The following two indicators were adopted when organizing the test results.


1. hydrocarbon conversion rate=[number of carbons in hydrocarbons in outlet gas]/[number of carbons in outlet gas]


This indicator is an indicator illustrating the ratio of the number of carbons converted into hydrocarbons without being converted into CO2 among the total carbons flowing in, and it is preferable that this indicator is high.


2. CO2 removal assumed hydrocarbon conversion rate=[number of carbons in hydrocarbons in outlet gas]/[number of carbons in outlet gas−number of carbons in outlet CO2]


This indicator is an indicator illustrating the conversion rate to hydrocarbons when CO2 is removed from the outlet gas of the hydrocarbon synthesis reaction unit obtained by the catalytic reaction, and it is preferable that this indicator is also high.


For the evaluation test 2, the used catalysts (Examples B4 to B16) are illustrated in Table 9, and the test results are illustrated in Table 10.















TABLE 9









Active component
BET surface
CO adsorption



Catalyst
Carrier
supported amount (wt. %)
area (m2/g)
amount (ml/g)





















Example B4
Ru/Al2O3
Al2O3
Ru: 1.3
109.8
0.47


Example B5
Ru/SiO2
SiO2
Ru: 1.0
212.3
0.13


Example B6
Ru/MgO
MgO
Ru: 1.3
24.7
0.15


Example B7
Ru/TiO2
TiO2
Ru: 1.2
64.7
0.71


Example B8
Ru/Al2O3
Al2O3
Ru: 2.3
114.5
0.97


Example B9
Ru/MO/Al2O3
Al2O3
Ru: 1.4, Mo: 1.5
131.4
0.47


Example B10
Ru/V/Al2O3
Al2O3
Ru: 1.2, V: 2.1
108.3
0.45


Example B11
Ru/Mo/Al2O3
Al2O3
Ru: 2.5, Mo: 1.7
115.5
1.24


Example B12
Ru/V/ZrO2
ZrO2
Ru: 1.1, V: 1.4
46.4
0.62


Example B13
Ru/V/Al2O3
Al2O3
Ru: 1.2, V: 3.9
118.0
0.63


Example B14
Ru/V/TiO2
TiO2
Ru: 1.2, V: 1.4
57.2
1.19


Example B15
Ru/Mo/TiO2
TiO2
Ru: 1.2, Mo: 1.2
58.1
1.21


Example B16
Ni/Al2O3
Al2O3
Ni: 13.0
95.7
0.01


















TABLE 10









Reaction temperature (° C.)















Catalyst
Indicator
233
249
257
273
274





Example
Ru/Al2O3
Hydrocarbon conversion rate (%)


B4

CO2 removal assumed hydrocarbon




conversion rate (%)


Example
Ru/SiO2
Hydrocarbon conversion rate (%)


B5

CO2 removal assumed hydrocarbon




conversion rate (%)


Example
Ru/MgO
Hydrocarbon conversion rate (%)


B6

CO2 removal assumed hydrocarbon




conversion rate (%)


Example
Ru/TiO2
Hydrocarbon conversion rate (%)


B7

CO2 removal assumed hydrocarbon




conversion rate


Example
Ru/Al2O3
Hydrocarbon conversion rate (%)


B8

CO2 removal assumed hydrocarbon




conversion rate (%)


Example
Ru/Mo/Al2O3
Hydrocarbon conversion rate (%)
14.2


74.6


B9

CO2 removal assumed hydrocarbon
99.8


100.0




conversion rate (%)


Example
Ru/V/Al2O3
Hydrocarbon conversion rate (%)


74.4


B10

CO2 removal assumed hydrocarbon


100.0




conversion rate (%)


Example
Ru/Mo/Al2O3
Hydrocarbon conversion rate (%)

87.1


B11

CO2 removal assumed hydrocarbon

100.0




conversion rate (%)


Example
Ru/V/ZrO2
Hydrocarbon conversion rate (%)


B12

CO2 removal assumed hydrocarbon




conversion rate (%)


Example
Ru/V/Al2O3
Hydrocarbon conversion rate (%)




78.8


B13

CO2 removal assumed hydrocarbon




99.9




conversion rate (%)


Example
Ru/V/TiO2
Hydrocarbon conversion rate (%)


B14

CO2 removal assumed hydrocarbon




conversion rate (%)


Example
Ru/Mo/TiO2
Hydrocarbon conversion rate (%)


B15

CO2 removal assumed hydrocarbon




conversion rate (%)


Example
Ni/Al2O3
Hydrocarbon conversion rate (%)


B16

CO2 removal assumed hydrocarbon




conversion rate (%)












Reaction temperature (° C.)





















276
277
278
287
289
299
302
308
309
317
331







Example





78.6


80.8

82.0



B4





99.9


99.9

99.9



Example






3.7



B5






46.9



Example


4.2



B6


78.0



Example
64.2



B7
99.9



Example



88.4



B8



100.0



Example



B9



Example



B10



Example



B11



Example

87.8



B12

100.0



Example



B13



Example







81.7



B14







99.9



Example




75.2



B15




99.8



Example









26.7



B16









96.2










(Evaluation Test 3)

In the evaluation test 3, a mixed gas (H2/CO=3) containing H2 and CO in a ratio of 3:1 (volume ratio) was used as the reaction gas, the GHSV was set to 2000/h, and the activity test of the hydrocarbon synthesis catalyst cat2 was carried out at the reaction temperature of 235° C. to about 330° C. In this activity test, a catalyst (Examples B17 and B18) in which iron or cobalt was supported on a titania carrier in addition to ruthenium was used. In this case, the reaction gas is an example obtained by assuming a model in which a mixed gas obtained by adding carbon monoxide to hydrogen obtained by electrolyzing water in the electrolytic reaction unit 10, and a mixed gas of hydrogen and carbon monoxide obtained by separating water and carbon dioxide as needed from the gas obtained by carrying out a co-electrolysis reaction of water and carbon dioxide are introduced into the hydrocarbon synthesis reaction unit 30 to carry out the hydrocarbon synthesis reaction.


The results of the evaluation test 3 are illustrated in Table 11.











TABLE 11









Reaction temperature (° C.)














Catalyst
Indicator
235
250
278
327

















Example
2 wt. % Ru/2
CO2 removal assumed hydrocarbon conversion rate (%)
11.6

99.9
99.9


B17
wt. % Fe/TiO2
C1-C4 calorific value (MJ/Nm3)
59.0

47.1
42.16


Example
2 wt. % Ru/2
CO2 removal assumed hydrocarbon conversion rate (%)

99.0


B18
wt. % Co/TiO2
C1-C4 calorific value (MJ/Nm3)

46









As illustrated in Table 11, it was confirmed that hydrocarbons can be synthesized from a mixed gas containing H2 and CO using a catalyst in which ruthenium and iron or cobalt are supported on a titania carrier as a hydrocarbon synthesis catalyst cat2.


It was confirmed that the above-mentioned hydrocarbon production system 100 can generate a high-calorie gas having a C1-C4 calorific value of 39 MJ/Nm3 or more.


From the above results, as illustrated above, a catalyst in which at least ruthenium is supported as the catalytically active component ca2 on the metal oxide carrier cb2 can be used in the second catalytic reaction unit 30 (hydrocarbon synthesis reaction unit). Further, it is preferable to support at least one of molybdenum, vanadium, iron, and cobalt as the catalytically active component ca2.


It was found that, preferably, the hydrocarbon synthesis catalyst cat2 was a catalyst in which at least ruthenium was supported on the metal oxide carrier cb2, the supported amount of ruthenium was 0.1% by weight or more and 5% by weight or less, and at least one of molybdenum, vanadium, iron, and cobalt as the catalytically active component ca2 was supported on the metal oxide carrier cb2 in addition to ruthenium.


Here, the supported amount of at least one of the molybdenum, vanadium, iron, and cobalt can be 0.2% by weight or more and 6% by weight or less.


Further, in hydrocarbon synthesis catalysts cat2, the adsorption amount of carbon monoxide of the highly active catalyst was 0.4 ml/g or more.


Heavy Hydrocarbon Separation Unit

When the gas reaching the heavy hydrocarbon separation unit 35 is cooled, the heavy hydrocarbons contained in the gas released from the hydrocarbon synthesis reaction unit 30 are condensed and the heavy hydrocarbons can be taken out to the outside. For example, in the hydrocarbon synthesis reaction unit 30 using the 2wt. % Ru/2wt. % Fe/TiO2 catalyst described in Example B17, when a mixed gas (H2/CO=3) containing H2 and CO in a ratio of 3:1 (volume ratio) was introduced and the reaction was carried out at 275° C., a linear higher aliphatic hydrocarbon having an average chain length of 26 carbon atoms could be extracted from the heavy hydrocarbon separation unit 35. Moreover, when the reaction was carried out at 325° C., a linear higher aliphatic hydrocarbon having an average chain length of 18 carbon atoms could be extracted from the heavy hydrocarbon separation unit 35.


Water Separation Unit

A condenser is arranged in the water separation unit 40, and the gas containing H2O flowing in is adjusted to a predetermined temperature and pressure to be condensed and water is taken out to the outside.


Carbon Dioxide Separation Unit

For example, PSA is arranged in this unit 50, and the gas containing CO2 flowing in is adsorbed to the adsorbent under a predetermined temperature and pressure to separate CO2, the separated CO2 is separated from the adsorbent, and thus, CO2 is favorably separated. The separated CO2 can be returned to the front of the electrolytic reaction unit 10 and reused via the carbon dioxide return path 51.


It is also possible to use PSA or the like to make the carbon dioxide separation unit and the water separation unit the same separation unit.


Another Embodiment

(1) In the above embodiment, CO2 separated in the carbon dioxide separation unit 50 is returned to the front of the electrolytic reaction unit 10. However, in the hydrocarbon production system 100 according to the present invention, since the conversion of CO2 to CO is mainly performed by the reverse water-gas shift reaction unit 20, a return destination of CO2 may be in front of the reverse water-gas shift reaction unit 20. This configuration is illustrated in FIG. 7.


(2) In the above embodiment, H2 in the gas obtained from the hydrocarbon synthesis reaction unit 30 is not particularly described. However, a hydrogen separation unit (described as H2 separation unit in the drawing) 60 that separates H2 using a hydrogen separation membrane or the like may be provided to separate H2 and use H2 separately. This configuration is illustrated in FIG. 8. In this example, the return destination of H2 separated by the hydrogen separation unit 60 may be provided in front of the reverse water-gas shift reaction unit 20 so that H2 is used for the reverse water-gas shift reaction.


(3) In the above embodiment, the water separation unit 40 is provided on the lower side of the hydrocarbon synthesis reaction unit 30. However, as illustrated in FIG. 9, the water separation unit 40 may be provided between the reverse water-gas shift reaction unit 20 and the hydrocarbon synthesis reaction unit 30. The main function of the water separation unit 40 is to facilitate the hydrocarbon synthesis reaction.


(4) In the above embodiment, an example in which both H2O and CO2 are supplied to the electrolytic reaction unit 10 and subjected to the electrolysis reaction is illustrated. However, as illustrated in FIG. 10, a system may be used in which only H2O is supplied to the electrolytic reaction unit 10 to be subjected to the electrolysis reaction. In this case, the carbon consumed in the hydrocarbon synthesis is input to the reverse water-gas shift reaction unit 20 as carbon dioxide.


(5) In the above embodiment, an example in which a solid oxide type electrolytic cell is used as the electrolytic cell 1 in the electrolytic reaction unit 10 is illustrated. However, as the electrolytic cell 1, an alkaline type electrolytic cell, a polymer film type electrolytic cell, or the like may be used.


(6) In the above embodiment, the electrolytic reaction unit 10 and the first catalytic reaction unit 20 are integrated. However, in addition to the reaction units 10.20, the second catalytic reaction unit 30 may be integrated. A configuration example in this case is illustrated in FIG. 13. Incidentally, in FIG. 13, a reference numeral 30a indicates a coating layer of the hydrocarbon synthesis catalyst cat2.


Also, in the case of this configuration, each of the reaction units 10, 20, and 30 can be configured on the metal support 4 and the supply path forming member 5, and the metal support 4 is supposed to act as a separator for separating the generated hydrocarbon and oxygen.


(7) In the above embodiment, an example of synthesizing a hydrocarbon such as methane in the hydrocarbon synthesis reaction unit 30 is illustrated. However, depending on how the hydrocarbon synthesis catalyst used in the hydrocarbon synthesis reaction unit 30 is selected, it is also possible to synthesize a chemical raw material from hydrogen and carbon monoxide introduced into the hydrocarbon synthesis reaction unit 30.


REFERENCE SIGNS LIST


1: Electrolytic cell



1
a: Electrolyte layer



2: Electrode layer



3: Counter electrode layer



4: Metal support (support/separator)



4
a Hole (through hole)



5: Supply path forming member (separator)



6: Supply path forming member (separator)



10: Electrolytic reaction unit



20: First catalytic reaction unit (reverse water-gas shift reaction unit)



20
a: Coating layer



30: Second catalytic reaction unit (hydrocarbon synthesis reaction unit)



40: Water separation unit



50: Carbon dioxide separation unit



60: Hydrogen separation unit


U: Electrolytic cell unit


cat1: Reverse water-gas shift catalyst


ca1: Catalytically active component (metal component)


cb1: Carrier (metal oxide)


cat2: Hydrocarbon synthesis catalyst


ca2: Catalytically active component (metal component)


cb2: Carrier (metal oxide)

Claims
  • 1. A reverse water-gas shift catalyst obtained by at least supporting one or both of nickel and iron as a catalytically active component on a carrier containing a ceria-based metal oxide or a zirconia-based metal oxide as a main component.
  • 2. The reverse water-gas shift catalyst according to claim 1, wherein a ratio of the carrier to the entire catalyst is 55% by weight or more.
  • 3. The reverse water-gas shift catalyst according to claim 1, wherein the ceria-based metal oxide is ceria doped with at least one of gadolinium, samarium, and yttrium.
  • 4. The reverse water-gas shift catalyst according to claim 1, wherein the zirconia-based metal oxide is zirconia stabilized by at least one of yttria and scandia.
  • 5. The reverse water-gas shift catalyst according to claim 1, wherein a supported amount of the catalytically active component is 0.5% by weight or more.
  • 6. The reverse water-gas shift catalyst according to claim 1, wherein copper is supported in addition to the catalytically active component.
  • 7. The reverse water-gas shift catalyst according to claim 6, wherein a supported amount of the copper is equal to or less than a supported amount of the catalytically active component.
  • 8. An electrolytic reaction system comprising at least a reverse water-gas shift reaction unit comprising at least the reverse water-gas shift catalyst according to claim 1 and an electrolytic reaction unit.
  • 9. The electrolytic reaction system according to claim 8, wherein the electrolytic reaction unit has an electrolytic cell unit in which at least an electrode layer, an electrolyte layer, and a counter electrode layer are formed on a support.
  • 10. The electrolytic reaction system according to claim 9, wherein the support is a metal.
  • 11. A hydrocarbon production system for producing hydrocarbon from water and carbon dioxide, the hydrocarbon production system comprising at least a reverse water-gas shift reaction unit including at least the reverse water-gas shift catalyst according to claim 1, an electrolytic reaction unit, and a hydrocarbon synthesis reaction unit.
  • 12. A production method of a reverse water-gas shift catalyst, the production method comprising at least an impregnation-supporting step of adding a carrier containing a ceria-based metal oxide or a zirconia-based metal oxide as a main component to a solution containing one or both of nickel and iron, and impregnating the carrier with at least one or both of nickel and iron to be supported on the carrier.
  • 13. A production method of a reverse water-gas shift catalyst, the production method comprising at least a calcination step of at least supporting one or both of nickel and iron as a catalytically active component on a carrier containing a ceria-based metal oxide or a zirconia-based metal oxide as a main component, and performing calcination at a temperature of 450° C. or higher.
  • 14. A production method of the electrolytic reaction system according to claim 8, the production method comprising disposing an impregnated supported product, which is obtained through an impregnation-supporting step of impregnating the carrier with at least one or both of nickel and iron to be supported on the carrier, in at least a portion of the support to form a reverse water-gas shift reaction unit.
  • 15. A method of using a reverse water-gas shift catalyst, the method comprising performing reduction pretreatment on a reverse water-gas shift catalyst, which is obtained by at least supporting one or both of nickel and iron as a catalytically active component on a carrier containing a ceria-based metal oxide or a zirconia-based metal oxide as a main component, and thereafter, subjecting the reverse water-gas shift catalyst to a reaction.
  • 16. A production method of the hydrocarbon production system according to claim 11, the production method comprising disposing an impregnated supported product, which is obtained through an impregnation-supporting step of impregnating the carrier with at least one or both of nickel and iron to be supported on the carrier, in at least a portion of the support to form a reverse water-gas shift reaction unit.
Priority Claims (1)
Number Date Country Kind
2020-065253 Mar 2020 JP national
CROSS-REFERENCE TO RELATED APPLICATIONS

This application is the United States national phase of International Application No. PCT/JP2021/014081 filed Mar. 31, 2021, and claims priority to Japanese Patent Application No. 2020-065253 filed Mar. 31, 2020, the disclosures of which are hereby incorporated by reference in their entirety.

PCT Information
Filing Document Filing Date Country Kind
PCT/JP2021/014081 3/31/2021 WO