The present invention relates to a process for synthesis of methanol from CO2-containing syngas. It also relates to the catalyst used in such process.
Methanol is widely used in different applications such as: the synthesis of formaldehyde, which is then involved in the manufacture of plastic materials, paints, and textiles, for instance; the production of dimethylether, which may be used in aerosols or as an alternative fuel for diesel engines; the transesterification of triglycerides to produce biodiesel; or as a solvent or a fuel for engines.
Methanol is commercially produced from synthesis gas (syngas), i.e., a mixture of carbon oxide (i.e., carbon monoxide (CO) and/or carbon dioxide (CO2)) and hydrogen (H2) that can be produced from a variety of carbonated sources. CO and CO2 react with H2 according to the following equations:
CO+2H2=CH3OH (1)
CO2+3H2=CH3OH+H2O (2)
CO+H2O=CO2+H2 (3)
wherein the third one corresponds to the water-gas shift (WGS) reaction.
A widely used catalyst is Cu/ZnO/Al2O3 (herein after “CuZnAl”), described for instance in GB1159035.
Usually, a syngas feed stream containing about 3 vol % CO2 is used in the methanol synthesis process. This amount of 3 vol % is an optimal value since it is has been demonstrated that increasing the content of CO2 in the syngas feed is detrimental to methanol productivity with CuZnAl catalyst due to the large amount of co-produced water, which strongly inhibits the catalyst activity and results in the loss of catalyst stability (Sahibzada, M. et al: J. Catal, 1998, 174, 111-118; Martin, O. and Perez-Ramirez, J.; Catal. Sci. Technol. 2013, 3, 3343-3352). Water is produced directly in the hydrogenation of CO2 to methanol, and also in the reverse water-gas shift (RWGS) reaction which competes with the hydrogenation reaction.
It would be desirable to use larger amounts of CO2 in the production of methanol because CO2 is a green-house gas intimately related to industrial activity and modern society and therefore such a use could help in reducing the CO2 footprint of industries.
Most of the current research in methanol synthesis from CO2 has been focusing on the optimization of the commercially-available CuZnAl catalyst to prevent its deactivation in the presence of water or to inhibit the RWGS reaction, as described for example in “Zinc-rich copper catalysts promoted by gold for methanol synthesis” by Martin, O. et al.; ACS Catal. 2015, 5, 5607-5616.
In spite of the improvements, these issues have not been overcome entirely. Thus, novel catalyst formulations have been investigated, such as: Cu—ZnO—Ga2O3/SiO2 in Toyir, J. et al.; Appl. Catal., B 2001, 29, 207-215; or Pd—ZnO/CNT in Liang, X. L. et al.; Appl. Catal., B 2009, 88, 315-322; or Cu/TaC in Dubois, J. L. et al.; Chem. Lett. 1992, 21, 5-8; or LaCr0-5Cu0.5O3 in Jia, L. et al.; Catal. Comm. 2009, 10, 2000-2003.
Of these, only Cu—ZnO—Ga2O3/SiO2 displayed both high activity and selectivity (99.5%). However, also optimized catalysts with low Cu content have been shown to suffer from H2O inhibition, limiting their exploitation only at low conversion levels (Martin et al.; ACS Catal. 2015, 5, 5607-5616). Moreover, little or no data exist to evaluate the long-term stability of such catalysts in the CO2 hydrogenation reaction to methanol.
Indium oxide (In2O3) has recently been identified as a potential good catalyst for CO2 hydrogenation into methanol based on density-functional-theory calculations in “Active Oxygen Vacancy Site for Methanol Synthesis from CO2 Hydrogenation on In2O3 (110): a DFT study” Ye, J. et al.; ACS Catal. 2013, 3, 1296-1306. This study indicates that the oxygen-defective In2O3 (110) surface can activate CO2 and hydrogenate it via HCOO and H3CO species to methanol. An experimental study over commercially available In2O3 demonstrated reasonable CO2 conversion for this catalyst but only low selectivity in “Hydrogenation of CO2 to methanol over In2O3catalyst” Sun, K. et al., J. CO2 Util. 2015, 12, 1-6.
JP-A-9-141101 discloses a catalyst for the synthesis of methanol from a source gas containing H2 and CO, the catalyst containing at least the oxides of Cu, Zn, Al and Zr, and further containing the oxides of Ga, Mn or In.
US 2015/321174 describes the photocatalytic production of methanol from CO2 over a nanostructured metal oxide such as indium oxide.
U.S. Pat. No. 2,787,628 discloses the reaction of CO with H2 using as catalysts oxides of group IVa (Ti, Zr, Hf) to which may be added activating oxides of trivalent metals; a combination of zirconium oxide with indium oxide and potassium oxide is disclosed as especially suitable.
The catalyst is preferably prepared by precipitation with alkalies from an aqueous solution. Only carbon monoxide is reacted with hydrogen. The objective stated in U.S. Pat. No. 2,787,628 is to increase the yield of isobutyl alcohol.
Rameshan et al. J. Catal. 2012, 295, 186-194 report on the methanol steam reforming on indium doped palladium by in situ X-ray photoelectron spectroscopy.
The work by Barbosa et al. J. Phys. Chem. C, 2013, 117, 6143-6150 relates to methanol steam reforming over an indium promoted Pt/Al2O3 catalyst and investigates the nature of the active sites.
There is still a need for a process of methanol synthesis and a catalyst showing high stability, high selectivity, high activity, and low inhibition by water.
Thus it is an object of the invention to provide a new process and a new catalyst for methanol synthesis from syngas. Another object of the invention is to provide a new process allowing improvements in CO2 conversion into methanol. Another object of the invention is to provide a catalyst and a process for methanol synthesis showing improvements in CO2 conversion to methanol, together with high space-time yield and/or high selectivity to methanol. Another object of the invention is to provide a catalyst and a process for methanol synthesis showing high stability of the catalyst. The present invention provides the solution to one or more of the aforementioned needs.
According to a first aspect, the invention provides a process for methanol synthesis comprising the following steps:
It has been found that a indium oxide-based catalyst may act as an efficient catalyst for CO2 hydrogenation into methanol, that has none of the problems of current state-of-the-art and commercially-available methanol (CuZnAl) catalysts. Moreover, surprisingly, a synergetic effect has been demonstrated between the catalyst main active phase and selected supports, such that supported catalysts lead to an improved space-time yield compared to the bulk (i.e., unsupported) indium oxide catalyst.
The inventive process is performed in a CO-containing syngas feed stream (i.e., containing only CO2, CO, and H2). It has surprisingly been found that presence of CO in the syngas feed stream enhanced the CO2 conversion compared to the CO2 conversion in a CO-free syngas. Thus a synergetic effect between the catalyst and the presence of CO has been found for CO2 conversion. It has also been found that presence of CO in the syngas feed stream enhanced the space time yield compared to the CO2 conversion in a CO-free syngas (i.e., a syngas feed stream containing CO2 and H2). The process of the invention allows methanol synthesis from CO-rich syngas feed streams (i.e., wherein the CO2 content is at most 30 mol % based on the total carbon oxide of the syngas feed stream) and CO2-rich syngas feed streams (i.e., wherein the CO2 content is above 30 mol % based on the total carbon oxide of the syngas feed stream). Therefore, the process of the present invention can be used to reduce the industrial carbon footprint.
The inventive catalyst has also be found to be very stable compared to prior art catalysts, so that the process can be carried out more than 1,000 hours without a significant loss in the catalyst activity, i.e., the loss in the catalyst activity is kept below 25%, preferably below 10%. It is to be noted that this stability can be achieved both in CO-rich syngas feed stream and in CO2-rich syngas feed stream.
With preference, one or more of the following features can be used to better define the inventive process:
According to a second aspect, the invention relates to the use of an indium oxide-based catalyst in a process for the synthesis of methanol from syngas as defined above.
As used herein the generic term “catalyst” refers to both a “bulk” and a “supported catalyst”. A bulk catalyst is a catalyst containing indium oxide without support. A supported catalyst consists of the catalyst (i.e., the catalyst comprising indium oxide) and a support. Indium oxide is the main active phase, i.e. the active phase, of the supported catalyst.
In methanol synthesis according to the invention, a feed gas composed of hydrogen gas and carbon oxides (CO2 alone or a mixture of CO2 and CO gases) are caused to interact on an indium oxide-based catalyst.
The invention relates to a process for methanol synthesis comprising the following steps:
The process can be carried out in gaseous phase or in liquid phase. The solvent that can be used for the reaction in liquid phase includes hydrocarbons and other solvents which are preferably insoluble or only sparingly soluble in water. Preferably, the process is carried out in gaseous phase.
The process is carried out in a reactor comprising
In accordance to the invention the syngas feed stream comprises hydrogen and a mixture of carbon dioxide and carbon monoxide.
The feed stream can be CO-rich or CO2-rich. In accordance to the invention, a CO-rich feed stream contains at most 30 mol % of CO2 based on the total molar content of the carbon oxide whereas a CO2-rich feed stream contains more than 30 mol % of CO2 based on the total molar content of the carbon oxide. In a preferred embodiment of the invention, the syngas feed stream is CO-rich, i.e., the syngas feed stream contains at most 30 mol % of CO2 based on the total molar content of the carbon oxide.
In a preferred embodiment the syngas feed stream contains hydrogen and a mixture of carbon dioxide and carbon monoxide and the syngas feed stream comprises at least 3 mol % of CO2 based on the total molar content of the syngas feed stream, preferably at least 5 mol %, more preferably at least 10 mol %, even more preferably at least 20 mol %.
In a preferred embodiment the syngas feed stream contains hydrogen and a mixture of carbon dioxide and carbon monoxide and the syngas feed stream comprises at most 40 mol % of CO2 based on the total molar content of the syngas feed stream, preferably at most 35 mol %, more preferably at most 30 mol %.
In a preferred embodiment the syngas feed stream contains hydrogen and a mixture of carbon dioxide and carbon monoxide and the syngas feed stream comprises at least 1 mol % of CO based on the total molar content of the syngas feed stream, preferably at least 2 mol %, more preferably at least 10 mol %, even more preferably at least 20 mol %, most preferably at least 30 mol % and even most preferably at least 40 mol %.
In a preferred embodiment the syngas feed stream contains hydrogen and a mixture of carbon dioxide and carbon monoxide and the syngas feed stream comprises at most 75 mol % of CO based on the total molar content of the syngas feed stream, preferably at most 65 mol %, more preferably at most 50 mol %.
In a preferred embodiment the syngas feed stream contains hydrogen and a mixture of carbon dioxide and carbon monoxide and the syngas feed stream comprises at least 10 mol % of H2 based on the total molar content of the syngas feed stream, preferably at least 20 mol %, more preferably at least 30 mol %.
In a preferred embodiment the syngas feed stream contains hydrogen and a mixture of carbon dioxide and carbon monoxide and the syngas feed stream comprises at most 90 mol % of H2 based on the total molar content of the syngas feed stream, preferably at most 80 mol %, more preferably at most 70 mol %, even more preferably at most 60 mol %.
In a preferred embodiment, the molar ratio of carbon monoxide to carbon dioxide (CO:CO2) is at least 1:10, preferably 1:1, more preferably at least 2:1, even more preferably at least 3:1, and most preferably at least 4:1.
In a preferred embodiment, the molar ratio of carbon monoxide to carbon dioxide (CO:CO2) is at most 10:1, preferably at most 9:1, preferably at most 8:1.
In a preferred embodiment, the molar ratio of hydrogen to carbon dioxide (H2:CO2) in the syngas feed stream is at least 1:1, preferably it is at least 3:1, more preferably it is at least 4:1 and even more preferably at least 8:1.
The feed stream comprises H2 and a mixture of CO2 and CO, and preferably the feed stream may also comprise a further gaseous component such as an inert gas. The inert gas is for example argon.
In a preferred embodiment, the process is carried out at a reaction temperature of at least 463 K (189.85° C.), preferably of at least 563 K (289.85° C.), more preferably of at least 663 K (389.85° C.). The person skilled in the art may increase the reaction temperature in order to increase the conversion rate of the carbon oxides. The reaction temperature may be kept below 773 K (499.85° C.) as a good compromise between economic reasons and conversion rate achieved. However, higher reaction temperature can be contemplated. Since the methanol effluents have boiling point lower than these temperatures, methanol is recovered in the gas form, mixed with other gaseous reaction products. Preferably the methanol effluents are conducted to a condenser where they are condensed and collected. Later the methanol can be separated and purified from other reaction products by distillation.
In another preferred embodiment, the pressure is at least 2 MPa, more preferably at least 3 MPa, preferably at least 4 MPa and more preferably at least 5 MPa. The person skilled in the art may increase the pressure in order to increase the conversion rate of the carbon oxides. A good compromise between industrial feasibility and conversion rate achieved is to conduct the reaction under a pressure ranging from 5 to 10 MPa. However, higher pressure can be contemplated, such as pressure above 50 MPa or above 90 MPa. In an embodiment of the invention the pressure is at most 100 MPa. In a preferred embodiment the gas hourly space velocity (GHSV) is in the range of 1,000 to 100,000 liters at standard temperature and pressure (STP) of reactant gases per liter of catalyst charged to the reactor per hour, preferably 2,000 to 50,000 h−1, more preferably 5,000 to 40,000 h−1, and even more preferably 15,000 to 30,000 h−1.
In a preferred embodiment the process can be carried out with a stable performance with respect to activity and selectivity during more than 100 hours, preferably more than 1,000 hours, more preferably more than 10,000 hours, and even more preferably more than 100,000 hours without the need of reactivation or replacement of the catalyst.
In accordance with the invention, the catalyst can be supported or unsupported (bulk). When the catalyst is unsupported, the process is preferably carried out in a fixed bed or in a fluidized bed reactor comprising at least one catalytic bed. Such reactors are well-known from the person skilled in the art and for instance described in EP2257366 or in U.S. Pat. No. 7,279,138.
The present invention contemplates the use of bulk catalyst as well as supported catalyst in methanol synthesis processes. A supported catalyst is preferably a calcined supported catalyst thus any reference to a supported catalyst include a reference to a calcined supported catalyst.
According to the invention, a supported catalyst comprises a catalyst and a support to provide mechanical support to the catalyst as well as to further enhance exposure of a feed stream to active sites of the catalyst. In such a supported configuration, an amount of the catalyst (represented as weight loading of the catalyst based on the total weight of the calcined supported catalyst) can be in the range of about 0.1 wt % to about 95 wt %.
In an embodiment, the catalyst is a calcined supported catalyst and the indium oxide content in the form of In2O3 of the supported catalyst, is at least 1 wt %, preferably at least 5 wt %, more preferably at least 8 wt % based to the total weight of the calcined supported catalyst.
In an embodiment, the catalyst is a calcined supported catalyst and the indium oxide content in the form of In2O3 of the supported catalyst, is at most 70 wt %, preferably at most 60 wt %, preferably of at most 50 wt %, more preferably of at most 40 wt %, even more preferably of at most 30 wt %, most preferably of at most 20 wt %, and even most preferably of at most 14 wt % based to the total weight of the calcined supported catalyst.
In an embodiment, the catalyst is a supported catalyst and the support comprises at least one selected from silica (SiO2), alumina (Al2O3), gallium oxide (Ga2O3), cerium oxide (CeO2), vanadium oxide (V2O5), chromium oxide (Cr2O3), zirconium dioxide (ZrO2), titanium dioxide (TiO2), magnesium oxide (MgO), zinc oxide (ZnO), tin oxide (SnO2), carbon black (C), and combinations thereof.
Preferably, the catalyst is a supported catalyst and the support comprises at least one selected from zinc oxide (ZnO), zirconium dioxide (ZrO2) and titanium dioxide (TiO2) or a combination thereof; and more preferably the support is or comprises zirconium dioxide.
In an embodiment, the catalyst is a supported catalyst and the support comprises zirconium dioxide (ZrO2) in an amount of at least 10 wt %, preferably at least 30 wt %, more preferably at least 50 wt %, even more preferably at least 80 wt %, and most preferably at least 90 wt % based on the total weight of the calcined supported catalyst.
In an embodiment, the support is zirconium dioxide or a combination of zirconium dioxide with another support in which zirconium dioxide is contained in an amount of at least 10 wt %, preferably at least 50 wt %, more preferably at least 80 wt %, and even more preferably at least 90 wt % based on the total weight of the support, the other support being selected from silica (SiO2), alumina (Al2O3), gallium oxide (Ga2O3), cerium oxide (CeO2), vanadium oxide (V2O5), chromium oxide (Cr2O3), titanium dioxide (TiO2), magnesium oxide (MgO), zinc oxide (ZnO), tin oxide (SnO2), carbon black (C) and combinations thereof; preferably the other support is selected from zinc oxide (ZnO), titanium dioxide (TiO2), and combinations thereof.
A catalyst support can be porous or non-porous. In some embodiments a catalyst support can be provided in a particulate form of particles having a surface area (i.e. BET surface area), in the range of about 20 m2 g−1 to about 400 m2 g−1, such as from 30 m2 g−1 to about 200 m2 g−1 as determined according to N2 sorption analysis, a pore volume in the range of about 0.1 cm3/g to about 10 cm3/g, such as from about 0.2 cm3 g−1 to about 5 cm3 g−1 according to N2 sorption analysis according to ASTM D3663-03.
The calcined supported catalyst has preferably a surface area, (i.e. BET surface area) in the range of about 20 m2/g to about 400 m2 g−1, such as from 30 m2 g−1 to about 200 m2 g−1 as determined according to N2 sorption analysis according to ASTM D3663-03.
The catalyst can be combined with a catalyst support or other support medium through, for example impregnation, such that the catalyst can be coated on, deposited on, impregnated on or otherwise disposed adjacent to the catalyst support. For example, a supported catalyst can be synthesized by an impregnation step followed by a calcination step. The catalyst can be provided in technical shapes such as extrudates, granules, spheres, monoliths, or pellets and might contain additives such as lubricants, peptizers, plasticizers, porogens, binders, and/or fillers.
In a preferred embodiment the calcination step is performed at a temperature above 500 K (226.85° C.), preferably above 530 K (256.85° C.), more preferably above 550 K (276.85° C.), even more preferably above 570 K (296.85° C.).
The above catalyst is useful for the synthesis of methanol from hydrogen and carbon oxides or the reverse reaction thereof.
Activity for methanol synthesis reaction is determined using a home-made fixed-bed reactor set-up which has been described in detail previously (O. Martin and al., ACS Catal. 2015, 5, 5607-5616). Briefly, it comprises mass flow controllers to feed Ar, CO, H2, and CO2 (Messer, ≥99.997%), a stainless steel reactor (0.65 cm i.d.) equipped with a thermocouple placed in the reactor wall adjacent to the catalytic bed and heated by an oven, and an online gas chromatograph (Agilent 7890A) monitoring the outlet gas composition. For experiments in which the reaction conditions (i.e., temperature, pressure, R═CO/(CO2+CO), or molar feed H2:CO2) are varied, the individual conditions are maintained for 4 h. Prior to the reaction, In2O3 and ZnO catalysts are activated in Ar at 573 K and 0.5 MPa for 1 h. CuO—ZnO—Al2O3 is pretreated in 5 vol % H2 in Ar at 503 K and 0.5 MPa for 1 h. Tests are conducted using a catalyst mass of 0.3 g (particle size: 0.050-0.075 mm), a temperature of 473-573 K, a pressure of 5.0 MPa, a total flow rate of 130 cm3 STP min−1.
If not stated differently, the syngas feed stream comprises 61.5 mol % H2, 15.4 mol % CO2, and 23.1 mol % Ar. In the case of CO co-feeding, the syngas feed stream contains 61.5 mol % H2, 15.4 mol % CO+CO2, and 23.1 mol % Ar. The CO fraction is expressed as R═CO/(CO2+CO) representing the mol % of CO based on the total molar content of the carbon oxides. R is varied is step-wise following the sequence: R=0, 20, 40, 60, 80, 100, and 0%.
In experiments, in which the molar feed CO2:H2 ratio is varied, a total flow rate of 146 cm3 STP min−1 is applied. The syngas feed stream composition is consecutively changed from 45.6 mol % H2 and 22.8 mol % CO2 (molar feed H2:CO2=2) to 54.7 mol % H2 and 13.7 mol % CO2 (molar feed H2:CO2=4), 60 8 mol % H2 and 7.6 mol % CO2 (molar feed H2:CO2=8), and 63 1 mol % H2 and 5.3 mol % CO2 (molar feed H2:CO2=12), and finally to 64.4 mol % H2 and 4 mol % CO2 (molar feed H2:CO2=16). The Ar content is kept constant at 31.6 mol %.
The mol % content of the reactants H2, CO2, and CO in the syngas feed stream and the mol % content of the reactants and the methanol product in the outlet are determined by an online gas chromatograph (Agilent 7890A) equipped with an flame ionization detector (FID) and a thermal conductivity detector (TCD).
Conversion of carbon dioxide in % is determined according to the following equation:
where Aco
Yield of methanol in % is calculated according to the following equation:
where AMeOH is the integrated area of the signal of methanol in the gas chromatogram, and fc2,MeOH:Ar is the calibration factor determined for methanol taking the Ar signal at YMeOH=100% conversion as a reference.
Selectivity to methanol in % is calculated according to the following equation:
Space-time yield refers to the grams of methanol produced per grams of catalyst and per hour and is calculated according to the following equation:
where Fco
The methanol formation rate per grams of In2O3 is determined through the following equation:
where wIn2O3 is the mass fraction of indium oxide in the catalyst determined by X-ray fluorescence spectroscopy.
Powder X-ray diffraction (XRD) analysis was performed using a PANalytical X'Pert Pro MPD instrument, utilizing Cu—Kα radiation (λ=0.1542 nm), an angular step size of 0.033° 2ζ, and a counting time of 8 s per step. The average particle size of In2O3 was estimated from the (222) reflection applying the Scherrer equation.
X-ray photoelectron spectroscopy (XPS) analysis was conducted using a Physical Electronics (PHI) Quantum 2000 X-ray photoelectron spectrometer featuring monochromatic Al—Kα radiation, generated from an electron beam operated at 15 kV and 32.3 W, and a hemispherical capacitor electron-energy analyzer, equipped with a channel plate and a position-sensitive detector. The samples were firmly pressed onto indium foil patches, which were then mounted onto a sample platen and introduced into the spectrometer. The analysis was conducted at 2×10−7 Pa, with an electron take-off angle of 45°, and operating the analyzer in the constant pass energy mode. Elemental concentrations were calculated from the photoelectron peak areas after Shirley background subtraction and applying the built-in PHI sensitivity factors.
The metal composition of the calcined samples was determined by X-ray fluorescence (XRF) spectroscopy using an Orbis Micro-EDXRF spectrometer equipped with a Rh source (15 kV, 500 μA) and a silicon drift detector.
Specific surface area and pore volume were determined from the sorption isotherm of N2 at 77 K. The Brunauer-Emmett-Teller (BET) method was applied for calculating the specific surface area according to ASTM D3663-03 and the volume of gas adsorbed at saturation pressure was used to determine the pore volume.
The advantages of the present invention are illustrated by the following examples. However, it is understood that the invention is no means limited to the specific examples.
The materials used were an indium salt, i.e., indium (III) nitrate hydrate (In(NO3)3.xH2O, Alfa Aesar, 99.99%); a mainly monoclinic (NorPro, SZ 31164) or a purely cubic (synthesized according to the preparation procedure described below) ZrO2 catalyst support, and deionized water.
The ZrO2 catalyst support (Saint-Gobain NorPro, SZ 31164, extrudates having diameter 3-4 mm and length 4-6 mm) in monoclinic structure (with ˜5 wt % cubic phase) was used, having the following specifications (prior to mortar crushing):
Synthesis of the cubic ZrO2 catalyst support: 5.21 g of zirconyl nitrate hydrate (ZrO(NO3)2xH2O, Acros Organics, 99.5%) was dissolved in 500 ml of deionized water under stirring. 31 ml of ethylene diamine (Fluka, 99.5%) was added dropwise. The slurry was stirred for further 30 min and then it was refluxed for 6 h. The obtained solution was filtered and the precipitate was washed with 2 l of deionized water. After drying at 338 K in static air, the resulting the material was calcined in static air at 873 K (599.85° C.) for 2 h with a heating rate of 2 K min−1.
Preparation of the supported catalysts (11 wt % In2O3 loading): 0.76 g of indium salt was dissolved in a mixture of 70 ml of ethanol absolute (Sigma-Aldrich, 99.8%) and 24 ml of deionized water under stirring. 2 g of either crushed as-received monoclinic or as-prepared cubic zirconium dioxide (both sieve fraction<0.075 mm) were added to the solution, which was mixed by a magnetic stirrer for 5 h. The solvent was removed in a rotary evaporator at 333 K (59.85° C.). The resulting material was dried at 338 K (64.85° C.) in static air overnight and finally calcined in static air at 573 K (299.85° C.) for 3 h applying a heating rate of 5 K min−1.
The produced catalyst was used in a methanol synthesis reaction.
The below Table 1 compares the results for STY, selectivity, and CO2 conversion obtained for the catalyst of the invention compared to other catalysts in prior art studies. Reaction conditions: T=573 K, P=5 MPa, GHSV=21,000 h−1, molar H2:CO2=4:1.
The impact of the calcination temperature on the catalyst activity has been evaluated using samples of In2O3 calcined at different temperatures. The samples were calcined at 473 K (199.85° C.), 573 K (299.85° C.), 623 K (349.85° C.) and 723 K (449.85° C.) for 3 h using a heating rate of 5 K min−1. Results are shown in
In
The activity of the following catalysts in methanol synthesis at different temperatures was tested:
In2O3 and ZnO were prepared through calcination of In(OH)3 and Zn(OH)2 obtained by precipitation. The latter comprised the dissolution of 6.1 g of In(NO3)3.xH2O (Alfa Aesar, 99.99%) or 4.7 g of Zn(NO3)2.6H2O (Acros Organics, 98%) in a mixture of deionized water (24 cm3) and ethanol (Sigma-Aldrich, 99.8%, 70 cm3), followed by the addition of a solution containing the precipitating agent, i.e., 18 cm3 of 25 wt. % NH4OH (aq, Sigma-Aldrich) in 54 cm3 of ethanol. The obtained slurry was aged for 10 min at 353 K, filtered, and washed with 2 L of deionized water. The precipitate was dried at 338 K for 12 h prior to calcination in static air at 573 (heating rate: 5 K min−1) for 3 h.
The Cu—ZnO—Al2O3 catalyst was synthesized via coprecipitation mixing under vigorous stirring 100 cm3 of a 1 M aqueous metal salt solution, containing Cu(NO3)2.3H2O (Sigma-Aldrich, 98%), Zn(NO3)2.6H2O, and Al(NO3)3.9H2O (Alfa Aesar, 98%) in a molar Cu:Zn:Al ratio of 6:3:1, and 200 cm3 of a 1 M aqueous solution of Na2CO3 (Acros Organics, 99.8%), reaching a final pH of 8. The slurry was aged at 338 K for 2 h. The slurry was filtered, washed 2 L of deionized water. The precipitate was dried at 338 K for 12 h prior to calcination in static air at 573 (heating rate: 5 K min−1) for 3 h.
The results given in
From these results, it can be seen that at 573 K (299.85° C.) In2O3 displays outstanding activity with respect to the other benchmark catalysts in methanol synthesis. It can be seen that Cu—ZnO—A2O3 suffers from H2O inhibition above 503 K (229.85° C.). Without being bound by a theory, it is believed that the higher activity of In2O3 at 573 K (299.85° C.) is due to the absence of this phenomenon.
CO2 conversion and selectivity to methanol are given in
The effect of several materials as support for the indium oxide catalyst have been tested. Results are given in
The optimal loading of In2O3 on the ZrO2-supported catalysts of the examples is shown in
The CO2 hydrogenation activity of the bulk In2O3 catalyst was tested under different molar H2:CO2 ratios in the syngas feed stream (
The effect of the syngas composition was studied at the reaction temperature of 573 K (299.85° C.). The results are given in
It can be seen that the In2O3 catalyst performs optimally when using a syngas feed stream containing 20 mol % of CO2 and 80 mol % of CO based on the total molar content of carbon oxide of the syngas feed stream. The optimization of the feed stream allows a CO2 conversion from 3.5% to 18.0%.
The catalyst is inactive in a pure CO syngas stream.
XPS can be used to determine the amount of oxygen surface defects, which are thought to be essential for the activity of In2O3-based catalysts, by calculating the atomic ratio of oxygen and indium. In a stoichiometric oxide, the oxygen-to-indium ratio is 1.5. In the case of the used bulk In2O3 catalyst this ratio is 0.78. This substoichiometric ratio points to an oxygen-defective surface. Semi-quantitative information of the oxygen defects is further gained from the core-level O1s signals as depicted in
A bulk catalyst In2O3 was activated through different methods prior to testing the catalytic activity at T=573 K, P=5 MPa, GHSV=21,000 h−1, molar H2:CO2=4:1. Upon the first method, the catalyst was activated in a flow (100 cm3 STP min−1) of a mixture containing 5 mol % H2 and 95 mol % Ar based on the total molar content of the feed stream. The obtained space-time yield was 0.169 gMeoH h−1 gcat−1. Upon a second method, the catalyst was activated in a flow (100 cm3 STP min−1) of only Ar. The resulting space-time yield according to this procedure was 0.195 gMeoH h−1 gcat−1. In both cases, the temperature was raised from 303 to 573 K by 5 K min−1. This result demonstrates that a thermal activation in inert gas atmosphere is preferred over an activation in reducing gas (such as H2).
Number | Date | Country | Kind |
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16150487.3 | Jan 2016 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2016/081996 | 12/20/2016 | WO | 00 |