WO2014111919A2 - A catalyst and a process for catalytic conversion of carbon dioxide-containing gas and hydrogen streams to hydrocarbons - Google Patents
A catalyst and a process for catalytic conversion of carbon dioxide-containing gas and hydrogen streams to hydrocarbons Download PDFInfo
- Publication number
- WO2014111919A2 WO2014111919A2 PCT/IL2014/000006 IL2014000006W WO2014111919A2 WO 2014111919 A2 WO2014111919 A2 WO 2014111919A2 IL 2014000006 W IL2014000006 W IL 2014000006W WO 2014111919 A2 WO2014111919 A2 WO 2014111919A2
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- WO
- WIPO (PCT)
- Prior art keywords
- catalyst
- carbon dioxide
- reactors
- phase
- spinel
- Prior art date
Links
- 239000003054 catalyst Substances 0.000 title claims abstract description 185
- 229910002092 carbon dioxide Inorganic materials 0.000 title claims abstract description 132
- CURLTUGMZLYLDI-UHFFFAOYSA-N Carbon dioxide Chemical compound O=C=O CURLTUGMZLYLDI-UHFFFAOYSA-N 0.000 title claims abstract description 117
- 239000001569 carbon dioxide Substances 0.000 title claims abstract description 55
- 238000000034 method Methods 0.000 title claims abstract description 54
- 230000008569 process Effects 0.000 title claims abstract description 38
- 238000006243 chemical reaction Methods 0.000 title claims description 62
- 239000007789 gas Substances 0.000 title claims description 36
- 229930195733 hydrocarbon Natural products 0.000 title claims description 31
- 150000002430 hydrocarbons Chemical class 0.000 title claims description 31
- UFHFLCQGNIYNRP-UHFFFAOYSA-N Hydrogen Chemical compound [H][H] UFHFLCQGNIYNRP-UHFFFAOYSA-N 0.000 title claims description 29
- 239000001257 hydrogen Substances 0.000 title claims description 29
- 229910052739 hydrogen Inorganic materials 0.000 title claims description 29
- 230000003197 catalytic effect Effects 0.000 title description 7
- 229910052596 spinel Inorganic materials 0.000 claims abstract description 77
- 239000011029 spinel Substances 0.000 claims abstract description 77
- 238000005984 hydrogenation reaction Methods 0.000 claims abstract description 45
- 239000012071 phase Substances 0.000 claims description 91
- XEEYBQQBJWHFJM-UHFFFAOYSA-N iron Substances [Fe] XEEYBQQBJWHFJM-UHFFFAOYSA-N 0.000 claims description 90
- 239000007788 liquid Substances 0.000 claims description 41
- 239000000203 mixture Substances 0.000 claims description 41
- 239000000243 solution Substances 0.000 claims description 38
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims description 34
- 229910052595 hematite Inorganic materials 0.000 claims description 24
- 239000011019 hematite Substances 0.000 claims description 24
- LIKBJVNGSGBSGK-UHFFFAOYSA-N iron(3+);oxygen(2-) Chemical compound [O-2].[O-2].[O-2].[Fe+3].[Fe+3] LIKBJVNGSGBSGK-UHFFFAOYSA-N 0.000 claims description 24
- VHUUQVKOLVNVRT-UHFFFAOYSA-N Ammonium hydroxide Chemical compound [NH4+].[OH-] VHUUQVKOLVNVRT-UHFFFAOYSA-N 0.000 claims description 19
- 239000007864 aqueous solution Substances 0.000 claims description 19
- 229910052742 iron Inorganic materials 0.000 claims description 19
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- 239000002184 metal Substances 0.000 claims description 18
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- SZVJSHCCFOBDDC-UHFFFAOYSA-N iron(II,III) oxide Inorganic materials O=[Fe]O[Fe]O[Fe]=O SZVJSHCCFOBDDC-UHFFFAOYSA-N 0.000 description 14
- VNWKTOKETHGBQD-UHFFFAOYSA-N methane Chemical compound C VNWKTOKETHGBQD-UHFFFAOYSA-N 0.000 description 14
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- 238000012360 testing method Methods 0.000 description 11
- 150000002500 ions Chemical class 0.000 description 10
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- RYGMFSIKBFXOCR-UHFFFAOYSA-N Copper Chemical compound [Cu] RYGMFSIKBFXOCR-UHFFFAOYSA-N 0.000 description 9
- 229910002091 carbon monoxide Inorganic materials 0.000 description 9
- 239000002105 nanoparticle Substances 0.000 description 9
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- 150000002823 nitrates Chemical class 0.000 description 6
- BWHMMNNQKKPAPP-UHFFFAOYSA-L potassium carbonate Chemical compound [K+].[K+].[O-]C([O-])=O BWHMMNNQKKPAPP-UHFFFAOYSA-L 0.000 description 6
- 239000002244 precipitate Substances 0.000 description 6
- 238000009826 distribution Methods 0.000 description 5
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- 241000252073 Anguilliformes Species 0.000 description 4
- AEMRFAOFKBGASW-UHFFFAOYSA-N Glycolic acid Chemical compound OCC(O)=O AEMRFAOFKBGASW-UHFFFAOYSA-N 0.000 description 4
- VYPSYNLAJGMNEJ-UHFFFAOYSA-N Silicium dioxide Chemical compound O=[Si]=O VYPSYNLAJGMNEJ-UHFFFAOYSA-N 0.000 description 4
- 150000001336 alkenes Chemical class 0.000 description 4
- QVGXLLKOCUKJST-UHFFFAOYSA-N atomic oxygen Chemical compound [O] QVGXLLKOCUKJST-UHFFFAOYSA-N 0.000 description 4
- XTVVROIMIGLXTD-UHFFFAOYSA-N copper(II) nitrate Inorganic materials [Cu+2].[O-][N+]([O-])=O.[O-][N+]([O-])=O XTVVROIMIGLXTD-UHFFFAOYSA-N 0.000 description 4
- 238000004821 distillation Methods 0.000 description 4
- 239000012153 distilled water Substances 0.000 description 4
- 229910052734 helium Inorganic materials 0.000 description 4
- 229910001960 metal nitrate Inorganic materials 0.000 description 4
- 239000011259 mixed solution Substances 0.000 description 4
- 239000003345 natural gas Substances 0.000 description 4
- 229910052760 oxygen Inorganic materials 0.000 description 4
- 239000001301 oxygen Substances 0.000 description 4
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- 238000006467 substitution reaction Methods 0.000 description 4
- 239000002028 Biomass Substances 0.000 description 3
- JLDSOYXADOWAKB-UHFFFAOYSA-N aluminium nitrate Chemical compound [Al+3].[O-][N+]([O-])=O.[O-][N+]([O-])=O.[O-][N+]([O-])=O JLDSOYXADOWAKB-UHFFFAOYSA-N 0.000 description 3
- 125000004432 carbon atom Chemical group C* 0.000 description 3
- 238000006555 catalytic reaction Methods 0.000 description 3
- 230000003247 decreasing effect Effects 0.000 description 3
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- SWQJXJOGLNCZEY-UHFFFAOYSA-N helium atom Chemical compound [He] SWQJXJOGLNCZEY-UHFFFAOYSA-N 0.000 description 3
- 238000002173 high-resolution transmission electron microscopy Methods 0.000 description 3
- VCJMYUPGQJHHFU-UHFFFAOYSA-N iron(III) nitrate Inorganic materials [Fe+3].[O-][N+]([O-])=O.[O-][N+]([O-])=O.[O-][N+]([O-])=O VCJMYUPGQJHHFU-UHFFFAOYSA-N 0.000 description 3
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- IJGRMHOSHXDMSA-UHFFFAOYSA-N Atomic nitrogen Chemical compound N#N IJGRMHOSHXDMSA-UHFFFAOYSA-N 0.000 description 2
- 229910017488 Cu K Inorganic materials 0.000 description 2
- 229910017541 Cu-K Inorganic materials 0.000 description 2
- LFQSCWFLJHTTHZ-UHFFFAOYSA-N Ethanol Chemical compound CCO LFQSCWFLJHTTHZ-UHFFFAOYSA-N 0.000 description 2
- NHNBFGGVMKEFGY-UHFFFAOYSA-N Nitrate Chemical compound [O-][N+]([O-])=O NHNBFGGVMKEFGY-UHFFFAOYSA-N 0.000 description 2
- AZDRQVAHHNSJOQ-UHFFFAOYSA-N alumane Chemical class [AlH3] AZDRQVAHHNSJOQ-UHFFFAOYSA-N 0.000 description 2
- 238000004458 analytical method Methods 0.000 description 2
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- QTBSBXVTEAMEQO-UHFFFAOYSA-M Acetate Chemical compound CC([O-])=O QTBSBXVTEAMEQO-UHFFFAOYSA-M 0.000 description 1
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- XAGFODPZIPBFFR-UHFFFAOYSA-N aluminium Chemical compound [Al] XAGFODPZIPBFFR-UHFFFAOYSA-N 0.000 description 1
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- 229910021529 ammonia Inorganic materials 0.000 description 1
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- 239000006227 byproduct Substances 0.000 description 1
- 238000009903 catalytic hydrogenation reaction Methods 0.000 description 1
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- FAHBNUUHRFUEAI-UHFFFAOYSA-M hydroxidooxidoaluminium Chemical compound O[Al]=O FAHBNUUHRFUEAI-UHFFFAOYSA-M 0.000 description 1
- 238000005470 impregnation Methods 0.000 description 1
- 230000006872 improvement Effects 0.000 description 1
- 238000003780 insertion Methods 0.000 description 1
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- 150000002632 lipids Chemical class 0.000 description 1
- 238000011068 loading method Methods 0.000 description 1
- 230000007774 longterm Effects 0.000 description 1
- 238000005259 measurement Methods 0.000 description 1
- 229910000000 metal hydroxide Inorganic materials 0.000 description 1
- 150000004692 metal hydroxides Chemical class 0.000 description 1
- 239000004570 mortar (masonry) Substances 0.000 description 1
- 229910052757 nitrogen Inorganic materials 0.000 description 1
- 238000000696 nitrogen adsorption--desorption isotherm Methods 0.000 description 1
- 229910000069 nitrogen hydride Inorganic materials 0.000 description 1
- 238000005457 optimization Methods 0.000 description 1
- 150000002894 organic compounds Chemical class 0.000 description 1
- 230000003647 oxidation Effects 0.000 description 1
- 238000007254 oxidation reaction Methods 0.000 description 1
- 238000010979 pH adjustment Methods 0.000 description 1
- 239000012188 paraffin wax Substances 0.000 description 1
- 239000003208 petroleum Substances 0.000 description 1
- 230000001699 photocatalysis Effects 0.000 description 1
- SCVFZCLFOSHCOH-UHFFFAOYSA-M potassium acetate Substances [K+].CC([O-])=O SCVFZCLFOSHCOH-UHFFFAOYSA-M 0.000 description 1
- 235000011056 potassium acetate Nutrition 0.000 description 1
- XAEFZNCEHLXOMS-UHFFFAOYSA-M potassium benzoate Chemical compound [K+].[O-]C(=O)C1=CC=CC=C1 XAEFZNCEHLXOMS-UHFFFAOYSA-M 0.000 description 1
- 235000015320 potassium carbonate Nutrition 0.000 description 1
- TYJJADVDDVDEDZ-UHFFFAOYSA-M potassium hydrogencarbonate Chemical compound [K+].OC([O-])=O TYJJADVDDVDEDZ-UHFFFAOYSA-M 0.000 description 1
- 239000004323 potassium nitrate Substances 0.000 description 1
- 235000010333 potassium nitrate Nutrition 0.000 description 1
- FGIUAXJPYTZDNR-UHFFFAOYSA-N potassium nitrate Inorganic materials [K+].[O-][N+]([O-])=O FGIUAXJPYTZDNR-UHFFFAOYSA-N 0.000 description 1
- 230000001376 precipitating effect Effects 0.000 description 1
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Classifications
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- B01J23/00—Catalysts comprising metals or metal oxides or hydroxides, not provided for in group B01J21/00
- B01J23/70—Catalysts comprising metals or metal oxides or hydroxides, not provided for in group B01J21/00 of the iron group metals or copper
- B01J23/74—Iron group metals
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- B01J23/70—Catalysts comprising metals or metal oxides or hydroxides, not provided for in group B01J21/00 of the iron group metals or copper
- B01J23/76—Catalysts comprising metals or metal oxides or hydroxides, not provided for in group B01J21/00 of the iron group metals or copper combined with metals, oxides or hydroxides provided for in groups B01J23/02 - B01J23/36
- B01J23/78—Catalysts comprising metals or metal oxides or hydroxides, not provided for in group B01J21/00 of the iron group metals or copper combined with metals, oxides or hydroxides provided for in groups B01J23/02 - B01J23/36 with alkali- or alkaline earth metals
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- B01J27/00—Catalysts comprising the elements or compounds of halogens, sulfur, selenium, tellurium, phosphorus or nitrogen; Catalysts comprising carbon compounds
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- C07C1/02—Preparation of hydrocarbons from one or more compounds, none of them being a hydrocarbon from oxides of a carbon
- C07C1/12—Preparation of hydrocarbons from one or more compounds, none of them being a hydrocarbon from oxides of a carbon from carbon dioxide with hydrogen
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- B01J—CHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
- B01J35/00—Catalysts, in general, characterised by their form or physical properties
- B01J35/60—Catalysts, in general, characterised by their form or physical properties characterised by their surface properties or porosity
- B01J35/64—Pore diameter
- B01J35/647—2-50 nm
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01J—CHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
- B01J37/00—Processes, in general, for preparing catalysts; Processes, in general, for activation of catalysts
- B01J37/0009—Use of binding agents; Moulding; Pressing; Powdering; Granulating; Addition of materials ameliorating the mechanical properties of the product catalyst
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01J—CHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
- B01J37/00—Processes, in general, for preparing catalysts; Processes, in general, for activation of catalysts
- B01J37/08—Heat treatment
- B01J37/082—Decomposition and pyrolysis
- B01J37/088—Decomposition of a metal salt
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01J—CHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
- B01J37/00—Processes, in general, for preparing catalysts; Processes, in general, for activation of catalysts
- B01J37/16—Reducing
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P20/00—Technologies relating to chemical industry
- Y02P20/50—Improvements relating to the production of bulk chemicals
- Y02P20/52—Improvements relating to the production of bulk chemicals using catalysts, e.g. selective catalysts
Definitions
- a catalyst and a process for catalytic conversion of carbon dioxide-containing gas and hydrogen streams to
- Oxygen can be combined with natural gas and steam to produce syngas that contains carbon monoxide, carbon dioxide and hydrogen by a process called autothermal reforming (L. Basini and L. Piovesan, "Reduction on Synthesis Gas Costs by Decrease of Steam/Carbon and Oxygen/Carbon Ratios in the Feedstock” , Ind. Eng. Chem. Res. 1998, 37, 258-266; Kim Aasberg-Petersen , Thomas S. Christensen, Charlotte Stub Nielsen, lb Dybkjasr, "Recent developments in autothermal reforming and pre- reforming for synthesis gas production in GTL applications", Fuel Processing Technology 83 (2003) 253- 261).
- the syngas produced by all those methods is mixed with hydrogen produced by electrolysis and carbon dioxide from an external source to form a mixture of carbon dioxide, carbon monoxide and hydrogen that is reacted on tubular reactor packed with solid catalyst to generate an organic liquid and a gas that contain hydrocarbons and water containing oxygenates as a by-product.
- US 5,140,049 discloses a method for producing olefins from H 2 and C0 2 using potassium promoted catalysts of the Fe 3 0 4 /2%K and Fe 2 . 85 CO 0 .i 5 O 4 /2% .
- catalysts based on iron and potassium supported on alumina which optionally contain also copper, i.e., catalysts of the formulas Fe- /Al 2 0 3 and Fe-K-Cu/Al 2 0 3 were reported in US 4,555,526, WO 97/05088 and WO 01/34538.
- Non-stoichimetric , copper-containing spinel based on Fe-Al-0 system was reported by Tanaka et. al . as being useful for exhaust gas treatment (JP 2011045840).
- the preferred catalyst operative in the present invention comprises iron-containing spinel phase (before activation).
- spinel phase indicates a mixed oxide having the formula A 2+ B 3+ 0 4 .
- the divalent ion A 2+ is Fe 2+ and is essentially free of Cu 2+
- the trivalent ion B 3+ is Fe 3+ in combination with Al 3+ .
- the spinel component of the catalyst may be represented by either one of the two formulas :
- y is in the range from 0.05 to 0.95;
- x is in the range from 0.0 to 0.05, i.
- a catalyst which consists of hematite and spinel phases together is represented by the formulas: a [ Fe 2 0 3 ] ⁇ [ Fe 2+ ( Fe 3+ y Al 3 V y ) 2 0 4 ] Formula I
- the catalyst according to the invention does not contain hematite phase and is copper-free.
- the preferred catalyst consists of a spinel of Formula 1 :
- the catalyst consists of potassium promoted spinel of Formula 1 : K/Fe 2+ ( Fe 3+ y Al 3+ i_ y ) 2 0 4 , wherein y is in the range from 0.05 to 0.95, more preferably from 0.25 to 0.75, even more preferably from 0.3 to 0.7, and specifically from 0.4 to 0.6, with the weight ratio Fe :Al : preferably varying from 100:20:3 to 100:30:10.
- the formula K/Fe 2+ (Fe 3+ yAl 3+ 1- . y ) 2 04 indicates that the potassium is applied onto the surface of the spinel of Formula 1.
- the catalyst of the invention is prepared by a process comprising dissolving in an aqueous solution at least one ferric compound and at least one aluminum compound, and optionally cupric compound, adjusting, preferably gradually, the pH of the metal-containing solution, e.g., to about 6.0 - 8.5, by means of an addition of an alkaline agent, whereby co-precipitation of the metals in the form of their hydroxides occurs, separating the solid formed from the liquid phase, and subjecting same to drying and calcination (for dehydration and formation of the spinel phase and optionally hematite phase).
- Suitable starting materials for use in the preparation of the catalyst are water-soluble ferric and aluminum salts, such as the nitrate salts.
- the metal nitrates exist in hydrated forms: Fe(N0 3 ) 3 '9H 2 0 and Al (N0 3 ) 3 ' 9H 2 0, which are especially preferred.
- the preferred concentrations of the ferric and aluminum salts in the aqueous solution are from 1900 to 2100 and 900 to 1100 gram/L, respectively, with the relative amounts of the salts being adjusted to form the desired composition of the catalyst.
- the water-soluble metal salts e.g., the nitrates
- the weight ratio Al:Fe in the solution is not less than 20:100, e.g., from 20:100 to 30:100.
- the adjustment of the pH of the aqueous solution to the range from 6.0-8.5, e.g., 7.0-8.5, especially from 7.5 to 8.0, in order to affect the co-precipitation of the metal hydroxides, is preferably accomplished by means of gradual addition of an aqueous solution of a base, such as ammonium hydroxide, which solution is preferably applied in a dilute form, with concentration of not more than 5% by weight.
- the gradual addition preferably lasts not less 10 minutes, e.g., not less than 20, 30 or 60 minutes, and may be accomplished by portionwise addition or feeding a stream of ammonium hydroxide solution at a suitably slow flow rate.
- the solution of the metals and the slowly added NH 4 OH solution are preferably held at a temperature below 30°C, e.g., at room temperature.
- the experimental results reported below indicate that a sharp increase of the pH of the aqueous metal solution ⁇ e.g., due to a rapid addition of a concentrated alkaline solution) may unfavorably alter the composition of the catalyst, ultimately causing the formation of the hematite phase following the calcination stage.
- the precipitate formed is separated from the mother liquor, e.g., by filtration or any other solid/liquid separation technique, and is preferably washed with water and dried at temperature in the range of 100-140°C for period of at least 24 h.
- the dried material is preferably treated with an aqueous solution of a potassium salt, e.g., the solid is impregnated with a solution of potassium carbonate, nitrate or acetate until incipient wetness is observed, followed by drying.
- the impregnation- drying cycle may be repeated several times, in order to load the potassium solution onto the surface of the solid.
- the weight ratio Fe: is in the range from 100:3 to 100: 10.
- the solid is then subjected to drying in air at a temperature in the range of 100-140°C for period of at least 24 hours followed by calcination in air at a temperature in the range from 400 to 500°C for period of at least 6 h.
- the catalyst obtained exhibits surface area of not less than 80 m 2 /gram, e . g . , between 80 and 180 m 2 /gram; pore volume of not less than 0.1 cmVgram, e.g. between 0.1 and 0.5 cmVgram, and average pore diameter between 3.0 and 7.0 nm.
- Elemental analysis by means of energy dispersive X-ray spectroscopy of the preferred catalyst of Formula 1 indicates that the weight ratio Fe:Al is in the range from 100:20 to 100:30.
- X-Ray Diffraction (XRD) indicates that the preferred catalyst of Formula 1 has average crystal size of 1.5 to 3 nm.
- the hematite phase alone which transforms at the activation step to carbides Fe 5 C 2 and Fe 7 C 3 , is capable of producing the desired high olefins/paraffins , but is not sufficiently active to permit acceptable C0 2 conversion.
- a catalyst which consists of pure K-promoted spinel phase i.e., the catalyst of Formula 1, particularly when subjected to specific activation conditions and employed in a continuous process running through a set of successively arranged reactors, namely, a cascade of reactors, demonstrates an excellent activity.
- the high activity is amounting to depressing of the formation of carbon deposits and stabilization of active carbide phases in a modified spinel matrix.
- This modified spinel matrix has less Fe content reduced at activation and in situ self-organization of the parent spinel phase due to partial removal of Fe-ions forming carbide phases Fe 5 C 2 and Fe 7 C3.
- copper i.e., in the spinel of Formula 2: (Cu 2+ x Fe 2 V x ) (Fe 3+ y Al 3 V y ) 2 0 4 ] facilitates reduction of iron ions during activation and at C0 2 hydrogenation conditions .
- copper is redundant when the activation is accomplished by means of carburization .
- the catalyst of the invention can be processed to form pellets.
- the powdery material collected following the precipitation and separation of the spinel of Formula 1 Fe 2+ (Fe 3+ y Al 3+ 1 _ y ) 2 0 4 from its mother liquor is combined with a binder such as aluminum hydroxide (bohemite) powder and water to form a workable slurry.
- a binder such as aluminum hydroxide (bohemite) powder and water
- the weight ratio Fe 2+ ( Fe 3+ y Al 3+ i_ y ) 2 0 : alumina :water is from 1:0.14-0.71:0.43-0.86 .
- the mixture is extruded and the so-formed extrudates are loaded with potassium, e.g., by means of the aforementioned impregnation with potassium carbonate solution, followed by drying and calcination.
- Another way to form pellets from the spinel of Formula 1 Fe 2+ ⁇ Fe 3+ y Al 3+ i_ y ) 2 ⁇ is by means of pressurizing the calcined powder after insertion of potassium using special form that yield cylindrical or empty cylindrical pellets.
- the catalyst of the invention is loaded into a suitable reactor, e.g., a continuous fixed bed reactor, or into a plurality of consecutively arranged reactors, as described in more detail below.
- the catalyst may be applied either in a powder or granular form.
- the particle size of the catalyst used may be in the range from 100 ⁇ to 3 mm.
- the powdery catalyst collected following the calcination step may be granulated, milled and then passed through a suitable sieve in order to collect the desired population of particles.
- the catalyst may also be applied in the form of pellets.
- the thickness of the catalyst layer packed in the reactor may vary within the range of 7 mm to 3 m provided the particle size is selected so as to avoid excessive pressure drop.
- the catalyst In order to be operative in the carbon dioxide hydrogenation process, the catalyst needs first to undergo activation.
- the activation of the catalyst is carried out in-situ, by either reduction (hydrogenation) or carburization .
- Reduction involves the flow of hydrogen stream through the reactor in which the catalyst is placed at a temperature of not less than 400°C.
- the flow rate of the hydrogen stream is not less than 100 cmVmin per gram of catalyst.
- the reduction is continued at atmospheric pressure for not less than 3 hours.
- the temperature is adjusted in hydrogen flow according to the process conditions and a C0 2 /H 2 mixture is fed to the reactor.
- Carburization involves the exposure of the catalyst to a carbon-containing atmosphere. To this end, streams of carbon monoxide, hydrogen and an inert gas carrier are caused to flow through the reactor in which the catalyst is placed at a temperature of not less than 300°C.
- the flow rates of the three gaseous components are at least 30:30: 150 cirrVmin per one gram of the catalyst, respectively.
- the carburization is continued at atmospheric pressure for not less than 3 hours.
- the fresh catalyst consists of spinel phase of Formula 1 of high dispersion with crystal size of 1.5 to 3 nm, e.g., around 2 nm.
- the spinel phase After activation by carburization and stabilization in C0 2 /H 2 hydrogenation at 300°C for 100-150 h, e.g., 120 h, the spinel phase is converted to Fe-carbide phases with crystal size of 25 and 45 nm while the crystal size of the spinel phase increases to 8.5 nm with decreasing the y value in its formula Fe ( Fe y Ali_ y ) 2 ⁇ 4 from 0.47 to 0.25. It means that part of the iron in the spinel phase during activation-stabilization is converted to carbides.
- the activity of the catalysts of the invention resides in the combination of the catalytic action of two phases - spinel catalyzing presumably the reverse water gas shift reaction producing CO, and iron carbides catalyzing both reverse water gas shift and Fischer-Tropsch reaction that converts C0/H 2 to hydrocarbons.
- Another aspect of the invention is a process for the preparation of hydrocarbons comprising the hydrogenation of carbon dioxide-containing gas in the presence of iron- containing catalyst devoid of hematite phase, said catalyst being copper-free, wherein the catalyst is activated in-situ by means of carburization, said carburization comprises treating said catalyst with a mixture of H 2 and CO at elevated temperature.
- the content of the carbide phases in the catalyst is less than 15 wt%, preferably from 5 to 10 wt% , relative to the total weight of the catalyst.
- the carbon dioxide hydrogenation reaction is allowed to start.
- Carbon dioxide-containing gaseous stream and hydrogen stream are continuously fed to the reactor at H 2 /C0 2 of not less than 2 and weight hourly space velocity (HSV) not less than 0.1 h "1 , preferably not less than 0.5 and more preferably not less than 1.
- HSV weight hourly space velocity
- the reaction is carried out at a temperature in the range from 250 to 360°C at pressure of not less than 5 atmospheres, e.g., from 10 to 30.
- the carbon dioxide-containing gas stream used in the present invention may be neat carbon dioxide and also any gas mixture which contains carbon dioxide, for example, a mixture of carbon dioxide and carbon monoxide, with the molar fraction of carbon dioxide being not less than 0.25, more specifically not less than 0.5.
- one aspect of the invention relates to a cascade process for hydrogenation of carbon dioxide-containing gaseous stream employing a plurality of serially arranged reactors, comprising:
- FIG. 4 A suitable apparatus for carrying out the process of the invention is schematically illustrated in Figure 4, in which the cascade configuration consists of three serially arranged reactors .
- Each reactor is provided with a suitable amount of a catalyst loaded therein.
- the amount of catalyst in each reactor is adjusted to improve conversion and productivity.
- the total amount of the catalyst used in the process may be equally divided between the set of reactors .
- Each reactor is provided with a discharge line (4), with a cooler (5), a gas-liquid separator (6) and a liquid-liquid separator (7) positioned successively along said discharge line.
- Each liquid-liquid separator (7) is connected to two tanks, (8) and (9), for collecting organic and aqueous phases, respectively.
- the gas-liquid separator is connected by means of a feed line (10) into the consecutive reactor.
- Carbon dioxide, hydrogen and optionally carbon monoxide required for the process are supplied through feed lines
- Hydrogen may be produced by the electrolysis of water in an electrolysis unit (not shown) and carbon dioxide may be recovered from industrial processes such as the combustion of fossil fuels in power generating plants, cement or steel plants.
- Another useful source of the reactans required for the process is carbon dioxide-rich syngas, i.e., a gas mixture comprising C0 2 , H 2 and CO where the concentration of C0 2 is greater than the normal concentration in conventional syngas, i.e., the molar fraction of carbon dioxide in the syngas is not less than 0.25 and preferably not less than 0.5.
- carbon dioxide (11) and hydrogen (12), and optionally carbon monoxide (13) streams are fed to the first of said serially arranged reactors, with their relative amounts being adjusted by means of flow controllers (14).
- hydrogen may be directly fed also to each of the successive reactors by means of feed lines (15, 16) equipped with flow controllers (14), so as to maintain an optimal ratio between the gaseous reactants .
- C0 2 , H 2 and CO may be fed at molar ratios 1:5:1.
- the temperature and pressure maintained within each of the serially-placed reactors are as set forth above, and the preferred WHSV, when using the copper-free catalyst of the invention, i.e., of Formula 1, is not less than 0.5.
- the gaseous mixture produced at each reactor is discharged (4), and subjected to cooling and condensation (5) whereby a liquid-gas mixture is obtained.
- This mixture is separated into its liquid and gaseous components in a gas-liquid separator ⁇ 6 ) .
- the gaseous, non-condensable component which consists of non-reacted C0 2 , H 2 and CO with light organic compounds is removed from the liquid component and fed directly to the next reactor via line (10).
- the liquid component is fed to a liquid-liquid separator (7), where it is separated into organic and aqueous phases, which are collected in two distinct tanks.
- the organic product (8) (containing mainly alkanes and alkenes with 6-20 carbon atoms in their molecules) is further processed to produce high-quality liquid fuels by methods known in the art. As shown in Figure 4, a further separation may be conducted after the third stage, to separate liquids from non-condensable products.
- the cascade configuration illustrated in Figure 4 removes the limitations on C0 2 conversion rendered by high water partial pressure in the downstream parts of the catalysts layer in one fixed-bed reactor and allows reaching C0 2 conversions of > 75% and up to > 90%.
- Implementation of the reactors cascade arrangement according to the present invention allows to get higher C0 2 conversions and oil productivities in comparison to operting with the same catalyst but in a single reactor. This improvement is obtained irrespective of the type of catalyst used (either pure Fe-oxide or spinel or mixed catalysts) and composition.
- Implementation of cascade reactors configuration according to the present invention removes the limitation of - 60% C0 2 conversion that appears to be the upper limit when using Fe-based catalysts in a single reactor. This allows reaching >90% C0 2 conversion at WHSV > 1 h "1 .
- the present invention permits obtaining the liquid hydrocarbon oil as an excellent feedstock for production of transportation fuels: gasoline, jet fuel and diesel fuel according to well established technologies [A.de Klerk, Energy Environ. Sci., 2011, 4, 1177],
- the oil productivity at similar total WHSV obtained in three reactors in series increases by about factor of 3 and reaches 170-520 gram of oil per kilogram of catalyst per hour. This corresponds to the productivity of about 0.5 million ton oil /year of the unit with 100 ton catalysts loading.
- the catalysts according to the present invention tested in a cascade reactors arrangement demonstrated excellent stability in 500 hour on stream runs.
- a typical chromatogram of the liquid oil produced by the hydrogenation process of the invention indicates that the oil consists of hydrocarbons with 6 to 27 carbon atoms where distribution maximum is centered at 10-12 carbon atoms.
- the hydrocarbon compositions of the liquid products formed in each of the three consecutive reactors are comparable ⁇ in each set of adjacent bars, the left, middle and right bars correspond to the first, second and third reactors placed in series)
- the oil contains about 60 wt% of n-olefins and n-paraffins at weight ratio of 5:1, about 1 wt% aromatics, 0.1-0.2 wt% oxygenates and the rest - iso- olefins and iso-paraffins at weight ratio of 4:1.
- the water fraction separated from oil contains 2-5 wt% of total organic carbon in form of light oxygenates .
- Distillation patterns demonstrate that the organic liquid obtained in C0 2 hydrogenation according to the present invention can be separated by distillation to gasoline, jet and/or diesel fuels fractions according to technical needs. These fractions may be further upgraded to fit the fuels specification requirements by means of methods known in the art, e.g., as it is done for hydrocarbon products obtained in a regular CO/H 2 Fischer-Tropsch process [A.de Klerk, supra].
- Figure 1 shows the multicomponent elements distribution maps of K/Fe-Al-O-spinel catalyst obtained by HRTEM/EELS: (1) - after hydrogen reduction and stabilization in C0 2 hydrogenation at 300°C for 120 h; (2) - after carburization and stabilization in C0 2 hydrogenation at 300°C for 120 h.
- Figure 2 shows XRD patterns of K/Fe-Al-O-spinel catalyst: (1) - fresh; (2) - after activation by carburization; (3) after stabilization in C0 2 hydrogenation at 300°C for 120 h.
- Figure 4 illustrates a scheme of an apparatus based on a cascade reactors system useful for C0 2 hydrogenation.
- Figure 5 is a bar diagram illustrating the contents of paraffins, olefins, aromatics and oxygenates in the hydrocarbon oil obtained after one, two and three reactors in series . Examples
- X-Ray Diffraction The X-ray diffraction (XRD) patterns were obtained with a Phillips 1050/70 powder diffractometer fitted with a graphite monochromator , at 40 kv and 28 mA. Software developed by Crystal Logic was used. The data were collected in a range of 2 ⁇ values between 5° and 80° with a step size of 0.05°. Phase identification was performed by using BEDE ZDS computer search/match program coupled with the ICDD (International Center for Diffraction Data) Powder Diffraction File database (2006).
- ICDD International Center for Diffraction Data
- the average crystal size was obtained by averaging of the data calculated for reflections (110), (200); (220), (311); (220), (311), (440); (020), (112); (102), (211) and (110), (200) of the XRD patterns corresponding to the Hematite Fe 2 0 3 phase (ICDD Card 86-550), Magnetite Fe 3 0 4 (ICDD Card 19-629), Cu-Al-Fe-0 spinels (ICDD Cards 34-192, 77-10), Hagg carbide Fe 5 C 2 (ICDD Card 36-1248), carbide Fe 7 C 3 (ICDD Card 17-333) and metallic a- Fe (ICDD Card 6-696) phases, respectively.
- composition of spinel phases nanoparticles in prepared catalytic materials was derived from XRD data - by fitting the measured parameters of the unit cell of cubic Fe 2 0 3 -phase to the contents of Cu 2+ and Al 3+ ions at tetrahedral and octahedral positions, respectively, in the cubic framework of spinel phase with space group Fd3m.
- EDAX Energy dispersive X-ray spectroscopy
- the total elemental composition of catalysts was measured by EDAX method using Quanta-200, SEM-EDAX, FEI Co. instrument.
- the contents of Cu 2+ and Al 3+ ions in spinel nanoparticles were confirmed by the data of local EDAX method recorded with the electronic spot diameter of 5 nm with the field emission analytical transmission electron microscope ( JEOL JEM-2100F) operated at accelerating voltage of 200 kV.
- the nanoparticles of spinel phases were identified by recording the m lticomponent distribution maps for nanoparticles observed at HRTEM images.
- High resolution TEM / electron energy loss spectroscopy (H TEM/EELS )
- the transmission electron microscope (JEOL JEM-2100F) used for materials analysis was equipped with a Gatan imaging filter (GIF Quantum) / EELS system. Regular and energy- filtered images were taken from the same samples point for Fe, 0 and C elements at L-edge 708 eV; -edge 532 eV and K- edge 284 eV, respectively. The obtained elemental distributions maps were further combined in one RGB image marking Fe by red, C by green and 0 by blue colors. This yielded multicomponent elements distribution maps for nanoparticles observed in regular HRTEM images.
- Gatan Digital Micrograph software was used for EFTEM imaging, recording and processing of EELS data.
- the samples for HRTEM were prepared by depositing a drop of ethanol suspension of the solid catalyst on a silica-coated copper grid that formed a contrast oxide background for carbon-rich particles.
- the catalyst was prepared by co-precipitation from the aqueous solution of Fe, Cu and Al nitrates by addition of aqueous ammonium hydroxide solution.
- 21.0 gram of Al(NO 3 ) 3 "9H 2 0, 72.3 gram of Fe (N0 3 ) 3 '9H 2 0 and 6.8 gram of Cu(N0 3 ) 2 '3H 2 0 salts were dissolved in 20 , 20 and 4 cm 3 of distilled water, respectively. All three solutions were then mixed together, and 500 cm 3 of 3% NH 4 OH solution were gradually added to this mixed salts solution at room temperature under stirring during a period of 10 min. The pH of solution after the addition of NH 4 0H was 6.8. A solid precipitated from the solution.
- the solid was separated by filtration and washed on the filter with 500 cm 3 of distilled water. Then the solid was dried in air at 110°C for period of 24 h.
- the obtained material was impregnated by incipient wetness with aqueous solution containing 1.04 gram 2 C0 3 .
- the impregnated material was dried in air at 110°C for period of 48 h and calcined in air at 450°C for period of 6 h (temperature increasing rate 5°C/min) .
- the material has the following weight ratio of metal components (EDAX) :
- Fe:Al: :Cu 100:15:6:5, surface area 100 m 2 /g, pore volume 0.17 cm 3 /g and average pore diameter 4.3 nm.
- the material contained two phases (XRD) : 30 wt% of hematite Fe 2 0 3 and 70 wt% of phase with spinel structure which composition reflects partial isomorphous substitution of Fe 2+ ions with Cu 2+ , and Fe 3+ ions with Al 3+ ions, such that the spinel phase of the catalyst has the formula:
- the catalyst was prepared according to procedure described in Example 1. However, in the present example the adjustment of pH value to 6.8 was achieved by adding 200 cm 3 of aqueous NH 4 OH solution with concentration of ammonium hydroxide of 10%.
- no Fe 2 0 3 hematite phase was formed after calcination at 450°C.
- the catalyst was prepared according to the procedure described in Example 1 but without any addition of Cu(N0 3 ) 2 salt to the mixed solution of metal nitrates.
- the material contained two phases ( XRD ) : 41 wt% of hematite Fe 2 0 3 and 59 wt% of phase with spinel structure which composition reflects partial isomorphous substitution of Fe 3+ ions with Al 3+ ions, such that the spinel phase of the catalyst is represented by the following formula:
- the catalyst was prepared according to the procedure described in Example 1, but without any addition of Cu ⁇ N0 3 )2'3H 2 0 salt to the mixed solution of metal nitrates.
- 94 gram of Fe (N0 3 ) 3 ' 9H 2 0 salt was used for preparation of iron salt solution in 50 cm 3 water and for adjustment of the pH value to 6.8, 535 cm 3 of 3% NHOH aqueous solution were added to the metal salt solution.
- the material contained two phases ⁇ RD ) : 45 wt% of hematite Fe 2 0 3 and 55 wt% of phase with spinel structure whose composition reflects partial isomorphous substitution of Fe 3+ ions with Al 3+ ions, such that the spinel phase of the catalyst is represented by the formula:
- the catalyst was prepared according to the procedure described in Example 1 but without the addition of Cu(N0 3 ) 2 ' 3 H 2 0 salt to the mixed solution of metal nitrates.
- 115.7 gram of Fe (N0 3 ) 3 ' 9H 2 0 salt was used for preparation of iron salt solution in 62 cm 3 of water and for the adjustment of the pH value to 6.8 was added 570 cm 3 of 3% NH 4 OH aqueous solution.
- Iron Oxide catalyst was obtained by combustion synthesis using glycolic acid as organic complexant. 12.6 gram of Glycolic acid were dissolved in 10% aqueous ammonia up to pH 6.5 and slowly added to a solution containing 67 gram of Fe(N0 3 ) 3 ' 9 H 2 0 dissolved in 50 cm 3 of water. Then the water, ammonia and part of N0 3 ⁇ ions converted to N0/N0 2 were removed from the mixed solution in rotavapor increasing the temperature from 40 to 80°C up to complete drying of the material. The dried precipitate was calcined in air at 350°C for 1 h (heating rate 5°C min ⁇ 1 ).
- the formed iron oxide was impregnated by incipient wetness method with aqueous K 2 C0 3 solution, followed by drying in air at 110°C overnight.
- the material consisted on 35 wt3 ⁇ 4 Hematite Fe 2 0 3 and 65 wt% Magnetite Fe 3 0 4 . It had surface area of 110 m 2 /gram, pore volume 0.31 cm 3 /gram and average pore diameter 4.3 nm.
- Example 7 (of the invention)
- the catalyst was prepared by co-precipitation from the aqueous solution of Fe and Al nitrates by gradual addition of aqueous ammonium hydroxide solution.
- 27.0 gram of Al(N0 3 ) 3 * 9H 2 0 and 57.9 gram of Fe(N0 3 ) 3 -9H 2 0 were dissolved in 60 cm 3 of distilled water each.
- the solutions were then mixed together and the pH value was adjusted to 8.0 by gradually adding 250 cm 3 of aqueous NH 4 OH solution with concentration of ammonium hydroxide of 5 wt .
- the addition time was 15 minutes.
- the precipitate was recovered and impregnated with K2CO3 solution as described in Example 1.
- the atomic ratio of Fe:Al in the precipitating solution was 2:1.
- no Fe 2 0 3 hematite phase was formed after calcination at 450°C.
- the catalyst was prepared by co-precipitation from the aqueous solution of Fe and Al nitrates by addition of aqueous ammonium hydroxide solution as described in Example 7. After mixing the aqueous solutions of Fe- and Al-salts the pH value was adjusted to 8.5 by gradually adding 265 cm 3 of an aqueous NH 4 OH solution (with concentration of 5 wt%). The addition time was 15 minutes. The precipitate was recovered and impregnated with 2 C0 3 solution as described in Example 1. The material consisted of only one - Al-substituted Fe 3 0 4 spinel phase of formula Fe ( Fe 3+ o. 31 Al 3+ o.
- the catalyst was prepared by co-precipitation from the aqueous solution of Fe and Al nitrates by addition of aqueous ammonium hydroxide solution as described in Example 7. After mixing the aqueous solutions of Fe- and Al-salts the pH value was adjusted to 7.2 by gradually adding 100 cm 3 of aqueous NH 4 OH solution with concentration of ammonium hydroxide of 5 wt% . The addition time was 15 minutes and the precipitate was recovered and impregnated with K 2 C0 3 solution as described in Example 1.
- the compositions of the catalysts of Examples 1 to 10 are tabulated in Table A.
- Example 11-22 the catalysts of Examples 1-10 were tested for their activity and selectivity in C0 2 hydrogenation reaction to form fuel compositions.
- Catalysts testing included catalyst activation, reaction and products analysis.
- Catalysts activation was done by means of two methods: reduction in hydrogen at 100 cm 3 /min*gram cat , temperature 450°C, atmospheric pressure for 24 h; and carburization in a mixture of carbon monoxide and hydrogen in helium at flows 30:30:140 cm 3 /min*gram cat respectively, at temperature 300 °C, atmospheric pressure for 3 h.
- C0 2 hydrogenation reaction was conducted by passing a mixture of H 2 and C0 2 flows at ratio 4:1 through the 3 gram of catalyst mixed with 1.8 gram of inert silica packed in a tubular reactor ⁇ 11 mm ID and 210 mm long, 45 mm catalytic phase) and heated up to 300°C or 320°C at the total pressure of 10 atm.
- the reaction products were cooled down to +4°C and separated in cooled (+4°C) container.
- Gas products were analyzed in online Agilent 789 OA Series Gas Chromatograph equipped with 7 columns and 5 automatic valves using helium as a carrier gas. Liquid products were separated into aqueous and organic phases.
- Aqueous phase was analyzed for Total Organic Carbon in Shimadzu T0C-V C PN Analyzer.
- the distillation patterns of hydrocarbon oil were estimated by simulated distillation method based on the maximal boiling points of components in 10 vol% oil fractions.
- Con Con for conversion
- Example 1 The Catalyst of Example 1 was packed in a fixed bed reactor and activated by H 2 reduction as described above. The effect of HSV on the reaction products was determined. The results are shown in Table 1. Increasing of the space time by decreasing of WHSV of CO 2 did not increase the CO 2 conversion beyond 60%.
- Example 1 The catalyst of Example 1 was packed in a fixed bed reactor and activated by carburxzation as described above. The effect of WHSV upon the reaction products was determined. The results are shown in Table 2. Comparison of the results presented in Tables 1 and 2 indicates a significantly higher activity of the catalyst after carburization compared with its activation by hydrogen reduction. Higher C0 2 conversions and oil productivities were measured at different WHSV with carburized catalyst.
- the selectivities to C 6+ hydrocarbons and oil productivity obtained with this catalyst of the present invention are significantly higher compared to that measured with carburized K/FeO x or biphasic K/Cu-Fe-Al-0-Fe 2 0 3 , K/Fe-Al-O- Fe 2 0 3 catalysts.
- the catalyst prepared according to Example 6 was packed in the tubular reactor and activated by carburization as described above. The testing results are shown in Table 8.
- the catalyst prepared according to Example 9 was packed in the tubular reactor and activated by hydrogen reduction as described above. The testing results are shown in Table 9.
- the catalyst prepared according to Example 8 was packed in the tubular reactor and activated by carburization as described above. The testing results are shown in Table 10.
- the catalyst prepared according to Example 9 was packed in the tubular reactor and activated by carburization as described above. The testing results are shown in Table 11.
- the catalyst prepared according to Example 10 was packed in the tubular reactor and activated by hydrogen reduction as described above. The testing results are shown in Table 12.
- Example 6 gram of the catalyst prepared as described in Example 1 was packed in three fixed bed reactors in series. 2 gram of catalyst was packed in each reactor and activated by carburization as described above.
- the testing system consisted of 3 consecutive SS fixed bed reactors with pressure, temperature and flow controls (shown in Figure 4). After each reactor the heavy organic products (oil) and water were condensed in a cooling system and collected in the tank. After separation of liquid products, the gases containing non-reacted C0 2 , H 2 and light Hydrocarbons, C1-C5 proceeded to flow to the next reactor. After each reactor the gas and liquid products were analyzed as described above. All the three reactors were kept at the same temperature and total pressure of 10 atm.
- Example 23 6 gram of catalyst prepared as described in Example 3 was packed in three fixed bed reactors in series as set out in Example 23.
- the aqueous and liquid hydrocarbons phases were separated from light gases between first and second and between second and third reactors as shown in Figure 4.
- the catalyst in all three reactors was activated by carburization as described above and tested as in Example 23.
- the effects of temperature and total pressure upon the reaction products were determined. The results are shown in Table 14.
- the oil hydrocarbon composition was similar to that obtained for oil collected in Example 23.
- Example 23 6 gram of catalyst prepared as described in Example 6 was packed in three fixed bed reactors in series as set out in Example 23. The catalyst was activated by carburization as described above and tested as in Example 23. The effect of WHSV upon the reaction products was determined. The results are shown in Table 15. The oil hydrocarbon composition was similar to that obtained for oil collected in Example 23.
- Example 16 6 gram of catalyst prepared as described in Example 7 was packed in three fixed bed reactors in series as set out in Example 23.
- the aqueous and liquid hydrocarbons phases were separated from light gases between first and second and between second and third reactors as shown in the scheme of Figure 4.
- the catalyst in all three reactors was activated by carburization as described above and tested as in Example 23.
- the effects of WHSV C o2 upon the reaction products were determined. The results are shown in Table 16.
- the cascade reactors configuration with this catalyst of the present invention gives maximal Ce+ hydrocarbons selectivity and oil productivity about 0.5 kg/kg cat h. Table 16
- Example 7 6 gram of catalyst prepared as described in Example 7 was packed in three fixed bed reactors in series with pressure, temperature and flow controls as set out in Example 23. 2 gram of the catalyst was packed in each reactor and activated by carburization as described above. The catalyst was tested in hydrogenation reaction of the mixture of CO2 and CO by feeding a mixture of H 2 , C0 2 and CO flows at molar ratio 5:1:1, respectively. After each reactor the heavy organic products (oil) and water were condensed in a cooling system and collected in the tank. After separation of liquid products, the gases containing non-reacted C0 2/ CO and H 2 and light hydrocarbons flowed to the next reactor. The gas products were analyzed as described above after the third reactor.
- Fe(Fe + y Al 3+ i_y) 2 0 from Example 7 was formed as extrudates with cylindrical shape using Al 2 0 3 as a binder. 11.73 gram of Fe (Fe 3+ y Al 3+ i_y ) 2 0 4 prepared in Example 7 was mixed with 4.89 gram of A100H powder (Disperal P2 , Sasol Ltd., Germany) and water was added to get a slurry. The slurry was kneeded in a mortar and extruded using a matrix with 1.2 mm cylindrical shape opening. The extrudates were dried at room temperature for 24 h, then at 110 °C overnight and calcined at 450 °C for period of 2 h (temperature increasing rate 5°C/min).
- the so- formed material was impregnated by incipient wetness with aqueous solution containing 2.15 gram K 2 C0 3 .
- the impregnated material was dried in air at 110°C for period of 24 h and calcined in air at 450°C for period of 2 h ⁇ temperature increasing rate 5°C/min) .
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Abstract
The invention relates to a catalyst suitable for use in the hydrogenation of carbon dioxide-containing gas, said catalyst comprising spinel phase of the formula [ Fe2+(Fe3+yAl3+1-y)2O4 ]. Processes for preparing the catalyst and processes for the hydrogenation of carbon dioxide-containing gas in the presence of the catalyst are also disclosed.
Description
A catalyst and a process for catalytic conversion of carbon dioxide-containing gas and hydrogen streams to
hydrocarbons
Land, air and marine transportation relies almost entirely on the availability of petroleum-derived liquid fuels. Given the limited availability of crude oil and the locations of the oil-producing countries, this dependence poses major security, economic, and environmental problems for the Western world.
Alternative routes for the production of synthetic liquid fuel from sources other than crude oil may be divided into three groups :
(i) conversion of coal and natural gas by a two-stage process, i.e., gasification to syngas (a mixture of CO and H2), followed by Fischer-Tropsch (FT) synthesis;
(ii) conversion of biomass {cellulose, starch and lipids) by a wide variety of processes; and
(iii) conversion of carbon dioxide and water.
Among the three groups of conversion processes described above, the group using the most basic raw materials - carbon dioxide and water - is definitely the most attractive long- term alternative, with two main routes currently being explored with the aim of establishing the most viable process: artificial photosynthesis through photocatalytic and photoelectrochemical processes and water splitting combined with carbon dioxide hydrogenation. The development of the latter route is at a more advanced level, since both stages of the process have been successfully demonstrated at the bench scale.
Of the other two processes, those based on syngas are the most highly developed. Synthetic fuels have been produced for the past ninety years from coal and natural gas through a highly endothermic gasification process to syngas, followed by a highly exothermic FT process to produce paraffin mixtures, which are then further processed to a variety of final products.
Splitting of water generates hydrogen and oxygen. Oxygen can be combined with natural gas and steam to produce syngas that contains carbon monoxide, carbon dioxide and hydrogen by a process called autothermal reforming (L. Basini and L. Piovesan, "Reduction on Synthesis Gas Costs by Decrease of Steam/Carbon and Oxygen/Carbon Ratios in the Feedstock" , Ind. Eng. Chem. Res. 1998, 37, 258-266; Kim Aasberg-Petersen , Thomas S. Christensen, Charlotte Stub Nielsen, lb Dybkjasr, "Recent developments in autothermal reforming and pre- reforming for synthesis gas production in GTL applications", Fuel Processing Technology 83 (2003) 253- 261). A similar process could be conducted with bio-gas instead of natural gas (McKenzie P. Kohn, Marco J. Castaldi, Robert J. Farrauto, "Auto-thermal and dry reforming of landfill gas over a Rh/γ- A1203 monolith catalyst", Applied Catalysis B: Environmental 94 (2010) 125-133). Gasification is another option for converting biomass with oxygen to syngas (Richard C. Baliban, Josephine A. Elia and Christodoulos A. Floudas, "Biomass to liquid transportation fuels (BTL) systems: process synthesis and global optimization framework", Energy Environ. Sci., 2013, 6, 267-287). The syngas produced by all those methods is mixed with hydrogen produced by electrolysis and carbon dioxide from an external source to form a mixture of carbon dioxide, carbon monoxide and hydrogen that is reacted on tubular reactor packed with solid catalyst to generate an
organic liquid and a gas that contain hydrocarbons and water containing oxygenates as a by-product.
While dealing extensively with the conversion to hydrocarbons of syngas (a mixture of CO and hydrogen that may contain some C02) via the Fischer-Tropsch synthesis, considerably lesser amount of work is reported in the art in respect of C02 hydrogenation. The feasibility of a process of carbon dioxide hydrogenation to form liquid fuels depends on the performance of the catalyst used to advance the reaction and on other process variables.
US 2,692,274 describes the catalytic reduction of carbon dioxide with hydrogen in the presence of iron oxide which contains 0.5% of copper and 0.8% K.
US 5,140,049 discloses a method for producing olefins from H2 and C02 using potassium promoted catalysts of the Fe304/2%K and Fe2.85CO0.i5O4/2% .
A series of catalysts based on iron and potassium supported on alumina, which optionally contain also copper, i.e., catalysts of the formulas Fe- /Al203 and Fe-K-Cu/Al203 were reported in US 4,555,526, WO 97/05088 and WO 01/34538.
J. S. Hong et.al. [Applied Catalysis A, 218, 53-59, 2001] reported the synthesis of Fe-Al-Cu-K catalyst, its in-situ activation by means of hydrogen reduction at 450°C, followed by cooling down to 300°C, at which temperature the reaction was allowed to start in a continuous fixed bed reactor, into which C02:H2 (1:3) streams were fed. After activation and stabilization at reaction conditions the catalyst contained
two phases - iron oxide Fe304 and carbide Fe5C2. The best C02 conversion reported by these authors was around 40%.
Riedel et al. [Topics in Catalysis, Vol. 26, p. 41-54 (2003)] report the synthesis of Fe-Al-Cu-K catalyst by the quick addition of an aqueous NH3 solution to a hot nitrate solution of iron, aluminum and copper. The precipitate was separated, washed and dried, and then impregnated with aqueous solution of potassium carbonate.
Non-stoichimetric , copper-containing spinel based on Fe-Al-0 system was reported by Tanaka et. al . as being useful for exhaust gas treatment (JP 2011045840).
It has now been found that liquid fuels can be prepared with high productivity by a reaction of carbon dioxide with hydrogen on solid porous catalyst based on iron. The preferred catalyst operative in the present invention comprises iron-containing spinel phase (before activation). In its most general form, spinel phase indicates a mixed oxide having the formula A2+B3+04. According to the present invention, the divalent ion A2+ is Fe2+ and is essentially free of Cu2+, whereas the trivalent ion B3+ is Fe3+ in combination with Al3+. Thus, the spinel component of the catalyst may be represented by either one of the two formulas :
Fe2+(Fe3+ yAl3+i_y)204 (spinel of Formula 1)
wherein y is in the range from 0.05 to 0.95; or
(Cu xFe i-x) <Fe yAlJ i_y)204 (spinel of Formula 2)
wherein x is in the range from 0.0 to 0.05, i.
and y is in the range from 0.05 to 0.95.
According to the notation used herein, a catalyst which consists of hematite and spinel phases together is represented by the formulas: a [ Fe203 ] β [ Fe2+ ( Fe3+ yAl3Vy)204 ] Formula I
a[Fe203 ] p [ (Cu2+ xFe2+i-x) ( Fe3+ yAl3Vy) 204 ] Formula II wherein a is <5wt% and β >95wt%, correspondingly, and x and y are as previously defined.
More preferably, however, the catalyst according to the invention does not contain hematite phase and is copper-free. Thus, the preferred catalyst consists of a spinel of Formula 1 :
Fe2+(Fe3+ yAl3+i_y)204? 0.05<y<0.95, preferably 0.25<y<0.75, e.g., 0.30<y<0.70.
In its most preferred form, the catalyst consists of potassium promoted spinel of Formula 1 : K/Fe2+( Fe3+ yAl3+i_y) 204 , wherein y is in the range from 0.05 to 0.95, more preferably from 0.25 to 0.75, even more preferably from 0.3 to 0.7, and specifically from 0.4 to 0.6, with the weight ratio Fe :Al : preferably varying from 100:20:3 to 100:30:10. The formula K/Fe2+(Fe3+yAl3+ 1-.y)204 indicates that the potassium is applied onto the surface of the spinel of Formula 1.
The catalyst of the invention is prepared by a process comprising dissolving in an aqueous solution at least one ferric compound and at least one aluminum compound, and optionally cupric compound, adjusting, preferably gradually, the pH of the metal-containing solution, e.g., to about 6.0 - 8.5, by means of an addition of an alkaline agent, whereby co-precipitation of the metals in the form of their
hydroxides occurs, separating the solid formed from the liquid phase, and subjecting same to drying and calcination ( for dehydration and formation of the spinel phase and optionally hematite phase).
Suitable starting materials for use in the preparation of the catalyst are water-soluble ferric and aluminum salts, such as the nitrate salts. The metal nitrates exist in hydrated forms: Fe(N03)3'9H20 and Al (N03 ) 3' 9H20, which are especially preferred. The preferred concentrations of the ferric and aluminum salts in the aqueous solution are from 1900 to 2100 and 900 to 1100 gram/L, respectively, with the relative amounts of the salts being adjusted to form the desired composition of the catalyst. The water-soluble metal salts, e.g., the nitrates, can be added to the aqueous solution in a solid form in any desired order, or can be pre-dissolved in separate solutions, which are subsequently combined together. Preferably, the weight ratio Al:Fe in the solution is not less than 20:100, e.g., from 20:100 to 30:100.
The experimental results reported below indicate that the best catalysts of the invention are the copper-free pure spinel of Formula 1. However, the presence of small amounts of copper, i.e., the catalysts { Cu2+ xFe2+i_x ) (Fe3+ yAl3+i_y)204 (spinel of Formula 2) can still be used, provided that x is less than 0.05. In the event that the catalysts of Formula 2 are contemplated, cupric salt, e.g., Cu(N03)2'3H20 is added to the solution described above.
The adjustment of the pH of the aqueous solution to the range from 6.0-8.5, e.g., 7.0-8.5, especially from 7.5 to 8.0, in order to affect the co-precipitation of the metal hydroxides, is preferably accomplished by means of gradual addition of an aqueous solution of a base, such as ammonium hydroxide, which
solution is preferably applied in a dilute form, with concentration of not more than 5% by weight. The gradual addition preferably lasts not less 10 minutes, e.g., not less than 20, 30 or 60 minutes, and may be accomplished by portionwise addition or feeding a stream of ammonium hydroxide solution at a suitably slow flow rate. During pH adjustment, the solution of the metals and the slowly added NH4OH solution are preferably held at a temperature below 30°C, e.g., at room temperature. The experimental results reported below indicate that a sharp increase of the pH of the aqueous metal solution {e.g., due to a rapid addition of a concentrated alkaline solution) may unfavorably alter the composition of the catalyst, ultimately causing the formation of the hematite phase following the calcination stage. Working with Al:Fe weight ratio as set out above and carefully basifying the solution afford, following the calcination, the hematite-free spinel of Formula 1.
The precipitate formed is separated from the mother liquor, e.g., by filtration or any other solid/liquid separation technique, and is preferably washed with water and dried at temperature in the range of 100-140°C for period of at least 24 h. Before the calcination step, the dried material is preferably treated with an aqueous solution of a potassium salt, e.g., the solid is impregnated with a solution of potassium carbonate, nitrate or acetate until incipient wetness is observed, followed by drying. The impregnation- drying cycle may be repeated several times, in order to load the potassium solution onto the surface of the solid. The presence of potassium renders the surface of the catalyst slightly alkaline, and hence increases the affinity of the catalyst towards carbon dioxide, which is an acidic gas. In general, the weight ratio Fe: is in the range from 100:3 to 100: 10.
The solid is then subjected to drying in air at a temperature in the range of 100-140°C for period of at least 24 hours followed by calcination in air at a temperature in the range from 400 to 500°C for period of at least 6 h.
The catalyst obtained exhibits surface area of not less than 80 m2/gram, e . g . , between 80 and 180 m2/gram; pore volume of not less than 0.1 cmVgram, e.g. between 0.1 and 0.5 cmVgram, and average pore diameter between 3.0 and 7.0 nm. Elemental analysis by means of energy dispersive X-ray spectroscopy of the preferred catalyst of Formula 1 indicates that the weight ratio Fe:Al is in the range from 100:20 to 100:30. X-Ray Diffraction (XRD) indicates that the preferred catalyst of Formula 1 has average crystal size of 1.5 to 3 nm.
The experimental results reported below indicate that the use of a pure copper-free Al-substituted spinel phase, i.e., the compound of Formula 1, in a nano-sized form, results in an increase in the C02 conversion and also in a better reaction selectivity towards the heavier, liquid hydrocarbons (designated C6+). The spinel component, after activation and self-organization at C02 hydrogenation conditions, is highly active and capable of supporting the conversion of carbon dioxide at an appreciable extent to higher hydrocarbons C5+. When the hydrogenation of C02 is carried out in the presence of a spinel catalyst containing a hematite component, its activity is lower due to the formation of a large amount of carbon deposits blocking the active phases. This is a result of oxidation of Fe-carbide phases formed during hematite carburization at the activation step by reactions with C02 and water formed in the process:
3 Fe5C2 + 3C02 = C + 2C0 +5 Fe304
3Fe5C2 + 20H2O = 5Fe304 + 20H2 + 6C
Conversely, the hematite phase alone, which transforms at the activation step to carbides Fe5C2 and Fe7C3, is capable of producing the desired high olefins/paraffins , but is not sufficiently active to permit acceptable C02 conversion. However, a catalyst which consists of pure K-promoted spinel phase, i.e., the catalyst of Formula 1, particularly when subjected to specific activation conditions and employed in a continuous process running through a set of successively arranged reactors, namely, a cascade of reactors, demonstrates an excellent activity. The high activity is amounting to depressing of the formation of carbon deposits and stabilization of active carbide phases in a modified spinel matrix. This modified spinel matrix has less Fe content reduced at activation and in situ self-organization of the parent spinel phase due to partial removal of Fe-ions forming carbide phases Fe5C2 and Fe7C3. It appears that the presence of copper [i.e., in the spinel of Formula 2: (Cu2+ xFe2Vx) (Fe3+ yAl3Vy)204] facilitates reduction of iron ions during activation and at C02 hydrogenation conditions . We have found that copper is redundant when the activation is accomplished by means of carburization .
It should be noted that the catalyst of the invention can be processed to form pellets. To this end, the powdery material collected following the precipitation and separation of the spinel of Formula 1 Fe2+(Fe3+ yAl3+ 1_y )204 from its mother liquor is combined with a binder such as aluminum hydroxide (bohemite) powder and water to form a workable slurry. For example, the weight ratio Fe2+ ( Fe3+ yAl3+i_y) 20 : alumina :water is from 1:0.14-0.71:0.43-0.86 . The mixture is extruded and the so-formed extrudates are loaded with potassium, e.g., by means of the aforementioned impregnation with potassium carbonate solution, followed by drying and calcination.
Another way to form pellets from the spinel of Formula 1 Fe2+ { Fe3+ yAl3+i_y ) 2Ο is by means of pressurizing the calcined powder after insertion of potassium using special form that yield cylindrical or empty cylindrical pellets.
In use, the catalyst of the invention is loaded into a suitable reactor, e.g., a continuous fixed bed reactor, or into a plurality of consecutively arranged reactors, as described in more detail below. The catalyst may be applied either in a powder or granular form. For example, the particle size of the catalyst used may be in the range from 100 μιη to 3 mm. Thus, the powdery catalyst collected following the calcination step may be granulated, milled and then passed through a suitable sieve in order to collect the desired population of particles. The catalyst may also be applied in the form of pellets. The thickness of the catalyst layer packed in the reactor may vary within the range of 7 mm to 3 m provided the particle size is selected so as to avoid excessive pressure drop.
In order to be operative in the carbon dioxide hydrogenation process, the catalyst needs first to undergo activation. The activation of the catalyst is carried out in-situ, by either reduction (hydrogenation) or carburization .
Reduction involves the flow of hydrogen stream through the reactor in which the catalyst is placed at a temperature of not less than 400°C. The flow rate of the hydrogen stream is not less than 100 cmVmin per gram of catalyst. The reduction is continued at atmospheric pressure for not less than 3 hours. After that the temperature is adjusted in hydrogen flow according to the process conditions and a C02/H2 mixture is fed to the reactor.
Carburization involves the exposure of the catalyst to a carbon-containing atmosphere. To this end, streams of carbon monoxide, hydrogen and an inert gas carrier are caused to flow through the reactor in which the catalyst is placed at a temperature of not less than 300°C. The flow rates of the three gaseous components (CO, H2 and inert gas (N2, He, Ar)) are at least 30:30: 150 cirrVmin per one gram of the catalyst, respectively. The carburization is continued at atmospheric pressure for not less than 3 hours.
The experimental results reported below indicate that the mode of catalyst activation is of significance. The reduction leads to the transformation of the iron ions in spinel phase into the metallic iron that is subsequently converted to a mixture of Fe304 inactive in Fischer-Tropsh reaction and catalytically active FeCx carbide phases. Activation by means of carburization is preferred since it converts iron ions existing in the spinel phase in the starting catalyst directly to iron carbide phases of higher dispersion (particles of 20-35 nm) leaving the Fe-impoverished spinel phase as aggregates of nanoparticles of higher dispersion (8- 10 nm) randomly mixed with iron carbide nanoparticles (Figure lb) . After hydrogen reduction and stabilization at reaction conditions the nanoparticles of carbide and spinel phases are larger {50 - 100 nm) and separated from each other by carbon that decreased the contact interface between carbide and spinel phases (Figure la).
Typical X-ray diffraction patterns of the fresh, activated (carburization) and stabilized at C02/H2 hydrogenation conditions catalyst of the present invention are presented in Figure 2. The fresh catalyst consists of spinel phase of Formula 1 of high dispersion with crystal size of 1.5 to 3 nm, e.g., around 2 nm. After activation by carburization and
stabilization in C02/H2 hydrogenation at 300°C for 100-150 h, e.g., 120 h, the spinel phase is converted to Fe-carbide phases with crystal size of 25 and 45 nm while the crystal size of the spinel phase increases to 8.5 nm with decreasing the y value in its formula Fe ( FeyAli_y ) 2Ο4 from 0.47 to 0.25. It means that part of the iron in the spinel phase during activation-stabilization is converted to carbides. It is believed that the activity of the catalysts of the invention resides in the combination of the catalytic action of two phases - spinel catalyzing presumably the reverse water gas shift reaction producing CO, and iron carbides catalyzing both reverse water gas shift and Fischer-Tropsch reaction that converts C0/H2 to hydrocarbons.
The effect of hematite phase content that may exist in the catalyst together with the substituted spinel phase at different amounts depending on the synthesis conditions is clearly illustrated in Figure 3, which compares the C02 conversions and liquid hydrocarbon oil productivities measured in testing examples of the present invention and comparative examples at standard conditions. As shown in Figure 3, the content of hematite phase in copper-free catalysts was in the range from 0 {pure spinel) to 100% {pure Fe-oxides). The catalyst containing pure spinel without Fe- oxide phase demonstrated the most efficient combination of catalytic activity and selectivity to C6+ hydrocarbons reflected by highest productivity of C6+ hydrocarbons. The pure Fe-oxide phase without A1-, mixed Fe-Al-O-spinel - Fe203 materials or Cu-Al containing spinel promoted with potassium after activation display much lower activity in C02 hydrogenation to hydrocarbons than the catalyst consisting of pure Fe-Al-0 spinel phase.
Accordingly, another aspect of the invention is a process for the preparation of hydrocarbons comprising the hydrogenation of carbon dioxide-containing gas in the presence of iron- containing catalyst devoid of hematite phase, said catalyst being copper-free, wherein the catalyst is activated in-situ by means of carburization, said carburization comprises treating said catalyst with a mixture of H2 and CO at elevated temperature. Following carburization, the content of the carbide phases in the catalyst is less than 15 wt%, preferably from 5 to 10 wt% , relative to the total weight of the catalyst.
Following the in-situ activation of the catalyst, the carbon dioxide hydrogenation reaction is allowed to start. Carbon dioxide-containing gaseous stream and hydrogen stream are continuously fed to the reactor at H2/C02 of not less than 2 and weight hourly space velocity ( HSV) not less than 0.1 h"1, preferably not less than 0.5 and more preferably not less than 1. The reaction is carried out at a temperature in the range from 250 to 360°C at pressure of not less than 5 atmospheres, e.g., from 10 to 30.
It should be noted that the carbon dioxide-containing gas stream used in the present invention may be neat carbon dioxide and also any gas mixture which contains carbon dioxide, for example, a mixture of carbon dioxide and carbon monoxide, with the molar fraction of carbon dioxide being not less than 0.25, more specifically not less than 0.5.
As already noted above, it has been found that it is advantageous to conduct the catalytic hydrogenation of carbon dioxide-containing gaseous stream via a cascade process, namely, by using a plurality of fixed bed reactors arranged is series. The chief advantage offered by the cascade
process of the invention resides in that it allows the introduction of intermediary step of water removal between each pair of serially-connected reactors. It has been found that water, which is a co-product of the reaction, has a double negative effect on the catalysts performance. First, the partial pressure of the water, which increases along the catalyst bed from inlet to outlet, inhibits the reverse water-gas shift reaction: C02 + H2 → C0+H20, thus it limits the C02 conversion. Second, at high partial pressure of water the active carbide Fe5C2 phase is oxidized to iron oxide that deactivates the catalyst. As a result, C02 conversion in one reactor reaches a limited value, well below 100%. (the experimental results reported below indicate that conversion measured at 300°C, WHSV <1 h"1 and total pressure of 10 atm asymptotically approaches - 60%).
Accordingly, one aspect of the invention relates to a cascade process for hydrogenation of carbon dioxide-containing gaseous stream employing a plurality of serially arranged reactors, comprising:
(i) feeding carbon dioxide-containing gas stream and hydrogen stream into at least the first of said serially arranged reactors which are loaded with iron-containing catalyst, said catalyst being copper-free, wherein said catalyst was brought to an active form by means of carburization;
(ii) discharging a gaseous reaction stream from at least one of said serially arranged reactors and cooling same, to form a liquid-gas mixture, wherein the liquid component of said mixture comprises condensable reaction products consisting of water and organic liquids, and the gas component of said mixture comprises reactants and non-condensable reaction products;
(iii) removing said gaseous component from said liquid component;
(iv) separating said liquid component into an organic and aqueous phases, and collecting at least said organic phase; (iv) directing the removed gaseous component into the successive reactor in said serially arranged reactors.
A suitable apparatus for carrying out the process of the invention is schematically illustrated in Figure 4, in which the cascade configuration consists of three serially arranged reactors .
The serially-positioned reactors are designated by numerals
(I) , (2) and (3). Each reactor is provided with a suitable amount of a catalyst loaded therein. The amount of catalyst in each reactor is adjusted to improve conversion and productivity. Alternatively, the total amount of the catalyst used in the process may be equally divided between the set of reactors .
Each reactor is provided with a discharge line (4), with a cooler (5), a gas-liquid separator (6) and a liquid-liquid separator (7) positioned successively along said discharge line. Each liquid-liquid separator (7) is connected to two tanks, (8) and (9), for collecting organic and aqueous phases, respectively. The gas-liquid separator is connected by means of a feed line (10) into the consecutive reactor.
Carbon dioxide, hydrogen and optionally carbon monoxide required for the process are supplied through feed lines
(II) , (12) and (13), respectively. Hydrogen may be produced by the electrolysis of water in an electrolysis unit (not shown) and carbon dioxide may be recovered from industrial processes such as the combustion of fossil fuels in power generating plants, cement or steel plants. Another useful source of the reactans required for the process is carbon
dioxide-rich syngas, i.e., a gas mixture comprising C02, H2 and CO where the concentration of C02 is greater than the normal concentration in conventional syngas, i.e., the molar fraction of carbon dioxide in the syngas is not less than 0.25 and preferably not less than 0.5.
In the specific embodiments shown in Figure 4, separate C02, H2 and CO feeds are shown, equipped with flow controllers (14), and the gases are combined in a feed line (15) and introduced into the first reactor. While the description that follows relates to the embodiment illustrated in Figure 4, it should be noted that a combined gaseous stream, e.g., carbon dioxide-rich syngas, may be utilized.
In operation, carbon dioxide (11) and hydrogen (12), and optionally carbon monoxide (13) streams are fed to the first of said serially arranged reactors, with their relative amounts being adjusted by means of flow controllers (14). As shown in Figure 4, hydrogen may be directly fed also to each of the successive reactors by means of feed lines (15, 16) equipped with flow controllers (14), so as to maintain an optimal ratio between the gaseous reactants . For example, C02, H2 and CO may be fed at molar ratios 1:5:1.
The temperature and pressure maintained within each of the serially-placed reactors are as set forth above, and the preferred WHSV, when using the copper-free catalyst of the invention, i.e., of Formula 1, is not less than 0.5.
The gaseous mixture produced at each reactor is discharged (4), and subjected to cooling and condensation (5) whereby a liquid-gas mixture is obtained. This mixture is separated into its liquid and gaseous components in a gas-liquid separator { 6 ) .
The gaseous, non-condensable component, which consists of non-reacted C02, H2 and CO with light organic compounds is removed from the liquid component and fed directly to the next reactor via line (10). The liquid component is fed to a liquid-liquid separator (7), where it is separated into organic and aqueous phases, which are collected in two distinct tanks. The organic product (8) (containing mainly alkanes and alkenes with 6-20 carbon atoms in their molecules) is further processed to produce high-quality liquid fuels by methods known in the art. As shown in Figure 4, a further separation may be conducted after the third stage, to separate liquids from non-condensable products.
Notably, the cascade configuration illustrated in Figure 4 removes the limitations on C02 conversion rendered by high water partial pressure in the downstream parts of the catalysts layer in one fixed-bed reactor and allows reaching C02 conversions of > 75% and up to > 90%.
Implementation of the reactors cascade arrangement according to the present invention, with water removal between each pair of succssive reactors, allows to get higher C02 conversions and oil productivities in comparison to operting with the same catalyst but in a single reactor. This improvement is obtained irrespective of the type of catalyst used (either pure Fe-oxide or spinel or mixed catalysts) and composition. Implementation of cascade reactors configuration according to the present invention removes the limitation of - 60% C02 conversion that appears to be the upper limit when using Fe-based catalysts in a single reactor. This allows reaching >90% C02 conversion at WHSV > 1 h"1.
The present invention permits obtaining the liquid hydrocarbon oil as an excellent feedstock for production of
transportation fuels: gasoline, jet fuel and diesel fuel according to well established technologies [A.de Klerk, Energy Environ. Sci., 2011, 4, 1177], The oil productivity at similar total WHSV obtained in three reactors in series increases by about factor of 3 and reaches 170-520 gram of oil per kilogram of catalyst per hour. This corresponds to the productivity of about 0.5 million ton oil /year of the unit with 100 ton catalysts loading. The catalysts according to the present invention tested in a cascade reactors arrangement demonstrated excellent stability in 500 hour on stream runs.
A typical chromatogram of the liquid oil produced by the hydrogenation process of the invention indicates that the oil consists of hydrocarbons with 6 to 27 carbon atoms where distribution maximum is centered at 10-12 carbon atoms. As shown in the bar diagram of Figure 5 , the hydrocarbon compositions of the liquid products formed in each of the three consecutive reactors are comparable {in each set of adjacent bars, the left, middle and right bars correspond to the first, second and third reactors placed in series) The oil contains about 60 wt% of n-olefins and n-paraffins at weight ratio of 5:1, about 1 wt% aromatics, 0.1-0.2 wt% oxygenates and the rest - iso- olefins and iso-paraffins at weight ratio of 4:1. The water fraction separated from oil contains 2-5 wt% of total organic carbon in form of light oxygenates .
Distillation patterns demonstrate that the organic liquid obtained in C02 hydrogenation according to the present invention can be separated by distillation to gasoline, jet and/or diesel fuels fractions according to technical needs. These fractions may be further upgraded to fit the fuels specification requirements by means of methods known in the
art, e.g., as it is done for hydrocarbon products obtained in a regular CO/H2 Fischer-Tropsch process [A.de Klerk, supra].
In the drawings ;
Figure 1 shows the multicomponent elements distribution maps of K/Fe-Al-O-spinel catalyst obtained by HRTEM/EELS: (1) - after hydrogen reduction and stabilization in C02 hydrogenation at 300°C for 120 h; (2) - after carburization and stabilization in C02 hydrogenation at 300°C for 120 h.
Figure 2 shows XRD patterns of K/Fe-Al-O-spinel catalyst: (1) - fresh; (2) - after activation by carburization; (3) after stabilization in C02 hydrogenation at 300°C for 120 h.
Figure 3 demonstrates the effect of the content of Fe203 (Hematite) phase in the mixed Fe203-Fe-Al-0-spinel catalyst on the catalysts performance in C02 hydrogenation. Testing conditions: T = 300°C, Ptotai = 10 atm, H2/C02 = 4.
Figure 4 illustrates a scheme of an apparatus based on a cascade reactors system useful for C02 hydrogenation. (1), (2) and (3) serially-positioned reactors; (4) discharge line; (5) cooler; (6) gas-liquid separator; (7) liquid-liquid separator; (8) organic collector; (9) aqueous phases collector; (10) feed line into the consecutive reactor; (11), (12) and (13) carbon dioxide, hydrogen and carbon monoxide feed lines, respectively; (14) flow controllers; (15), (16) gas feed lines.
Figure 5 is a bar diagram illustrating the contents of paraffins, olefins, aromatics and oxygenates in the hydrocarbon oil obtained after one, two and three reactors in series .
Examples
Methods
X-Ray Diffraction (XRD) The X-ray diffraction (XRD) patterns were obtained with a Phillips 1050/70 powder diffractometer fitted with a graphite monochromator , at 40 kv and 28 mA. Software developed by Crystal Logic was used. The data were collected in a range of 2Θ values between 5° and 80° with a step size of 0.05°. Phase identification was performed by using BEDE ZDS computer search/match program coupled with the ICDD (International Center for Diffraction Data) Powder Diffraction File database (2006). The average crystal size of Fe304, Fe2+(Fe3+yAl3+i_y)204 spinel, Fe203, Fe5C2 and Fe7C3 phases was determined from the Scherrer equation h = Κλ/ [ (B2 - β2)0-5 cos{20/2)], where K = 1.000 is the shape factor, λ = 0.154 nm, β is the instrumental broadening correction, and B is the reflection broadening at corresponding 2Θ. The average crystal size was obtained by averaging of the data calculated for reflections (110), (200); (220), (311); (220), (311), (440); (020), (112); (102), (211) and (110), (200) of the XRD patterns corresponding to the Hematite Fe203 phase (ICDD Card 86-550), Magnetite Fe304 (ICDD Card 19-629), Cu-Al-Fe-0 spinels (ICDD Cards 34-192, 77-10), Hagg carbide Fe5C2 (ICDD Card 36-1248), carbide Fe7C3(ICDD Card 17-333) and metallic a- Fe (ICDD Card 6-696) phases, respectively. The relative content of Fe-oxides, carbide phases and amorphous carbon phase represented in X-ray diffractograms by a wide reflection centered at 2Θ = 22° was obtained by Rietveld refinement of the XRD profile by using the DBWS-9807 program.
The composition of spinel phases nanoparticles in prepared catalytic materials was derived from XRD data - by fitting the measured parameters of the unit cell of cubic Fe203-phase to the contents of Cu2+ and Al3+ ions at tetrahedral and octahedral positions, respectively, in the cubic framework of
spinel phase with space group Fd3m. The parameters of unit cells of spinel phases were calculated based on the positions of reflections detected in X-ray diffractograms around 2Θ =30° (220), 35.5° (311) and 63° (440).
Surface area and pore volume measurements
Surface area and pore volume were derived from N2 adsorption- desorption isotherms using conventional BET and BJH methods { Barrett-Joyner-Halenda method, Journal of American Chemical Society, 73, 373, 1951). The samples were degassed under vacuum at 250-70 °C, depending on their thermal stability. Isotherms were measured at liquid nitrogen temperature with a NOVA-2000 Quantac rome, Version 7.02 instrument.
Energy dispersive X-ray spectroscopy (EDAX)
The total elemental composition of catalysts was measured by EDAX method using Quanta-200, SEM-EDAX, FEI Co. instrument. The contents of Cu2+ and Al3+ ions in spinel nanoparticles were confirmed by the data of local EDAX method recorded with the electronic spot diameter of 5 nm with the field emission analytical transmission electron microscope ( JEOL JEM-2100F) operated at accelerating voltage of 200 kV. The nanoparticles of spinel phases were identified by recording the m lticomponent distribution maps for nanoparticles observed at HRTEM images.
High resolution TEM / electron energy loss spectroscopy (H TEM/EELS )
The transmission electron microscope (JEOL JEM-2100F) used for materials analysis was equipped with a Gatan imaging filter (GIF Quantum) / EELS system. Regular and energy- filtered images were taken from the same samples point for Fe, 0 and C elements at L-edge 708 eV; -edge 532 eV and K- edge 284 eV, respectively. The obtained elemental distributions maps were further combined in one RGB image marking Fe by red, C by green and 0 by blue colors. This yielded multicomponent elements distribution maps for
nanoparticles observed in regular HRTEM images. Gatan Digital Micrograph software was used for EFTEM imaging, recording and processing of EELS data. The samples for HRTEM were prepared by depositing a drop of ethanol suspension of the solid catalyst on a silica-coated copper grid that formed a contrast oxide background for carbon-rich particles.
Example 1 (comparative)
Preparation of a catalyst consisting of hematite phase [Fe203] and spinel phase of the formula
[ (Cu2+ xFe2Vx) (Fe3+ yAl3+i-y)zQ4; (x=0.54, y=0.65)]
The catalyst was prepared by co-precipitation from the aqueous solution of Fe, Cu and Al nitrates by addition of aqueous ammonium hydroxide solution. 21.0 gram of Al(NO3)3"9H20, 72.3 gram of Fe (N03 ) 3'9H20 and 6.8 gram of Cu(N03 )2'3H20 salts were dissolved in 20 , 20 and 4 cm3 of distilled water, respectively. All three solutions were then mixed together, and 500 cm3 of 3% NH4OH solution were gradually added to this mixed salts solution at room temperature under stirring during a period of 10 min. The pH of solution after the addition of NH40H was 6.8. A solid precipitated from the solution. The solid was separated by filtration and washed on the filter with 500 cm3 of distilled water. Then the solid was dried in air at 110°C for period of 24 h. The obtained material was impregnated by incipient wetness with aqueous solution containing 1.04 gram 2C03. The impregnated material was dried in air at 110°C for period of 48 h and calcined in air at 450°C for period of 6 h (temperature increasing rate 5°C/min) . The material has the following weight ratio of metal components (EDAX) :
Fe:Al: :Cu = 100:15:6:5, surface area 100 m2/g, pore volume 0.17 cm3/g and average pore diameter 4.3 nm. The material contained two phases (XRD) : 30 wt% of hematite Fe203 and 70
wt% of phase with spinel structure which composition reflects partial isomorphous substitution of Fe2+ ions with Cu2+, and Fe3+ ions with Al3+ ions, such that the spinel phase of the catalyst has the formula:
[ (Cu2+ xFe2+!_x) (Fe3+ yAl3Vy)204] where x = 0.54 and y = 0.65.
Example 2 (comparative)
Preparation of a catalyst consisting of spinel phase only
[(Cu2+ 3tFe2+ 1_x)(Fe3+ yAl3+ 1_y)204; (x=0.72, y=0.71)]
The catalyst was prepared according to procedure described in Example 1. However, in the present example the adjustment of pH value to 6.8 was achieved by adding 200 cm3 of aqueous NH4OH solution with concentration of ammonium hydroxide of 10%. The fast basification caused the inclusion of more Cu and Fe ions in {Cu2+ xFe2+i_x) (Fe3+ yAl3+i_y ) 204 spinel phase with x = 0.72 and y = 0.71. Correspondingly, no Fe203 hematite phase was formed after calcination at 450°C. The material had the following weight ratio of metal components (EDAX): Fe:Al:K:Cu = 100:15:5:6, surface area 138 mVgram, pore volume 0.20 cm3/gram and average pore diameter 4.3 nm.
Example 3 (comparative)
Preparation of a catalyst consisting of hematite phase [Fe203] and spinel phase of the formula
[ Fe+( Fe3+ yAl3Vy)2Ο4] ; (y=0. 0 ) ]
The catalyst was prepared according to the procedure described in Example 1 but without any addition of Cu(N03)2 salt to the mixed solution of metal nitrates. The material has following weight ratio of metal components (EDAX) : Fe:Al:K = 100:15:6, surface area 107 m2/gram, pore volume 0.20 cm3/gram and average pore diameter 3.4 nm. The material contained two phases ( XRD ) : 41 wt% of hematite Fe203 and 59 wt% of phase with spinel structure which composition reflects
partial isomorphous substitution of Fe3+ ions with Al3+ ions, such that the spinel phase of the catalyst is represented by the following formula:
[Fe2+(Fe3+yAl3+i_y)204] where y= 0.40.
Example 4
Preparation of a catalyst consisting of hematite phase
[Fe203] and spinel phase of the formula
[ Fe2+ (Fe3+ YAl3+i-y) 204 ] (y=0.6 )]
The catalyst was prepared according to the procedure described in Example 1, but without any addition of Cu{N03)2'3H20 salt to the mixed solution of metal nitrates. In this example 94 gram of Fe (N03 ) 3' 9H20 salt was used for preparation of iron salt solution in 50 cm3 water and for adjustment of the pH value to 6.8, 535 cm3 of 3% NHOH aqueous solution were added to the metal salt solution. The resultant material has the following weight ratio of metal components (EDAX): Fe:Al:K = 100:12:5, surface area 113 mVgram, pore volume 0.21 cm3/gram and average pore diameter 4.9 nm. The material contained two phases { RD ) : 45 wt% of hematite Fe203 and 55 wt% of phase with spinel structure whose composition reflects partial isomorphous substitution of Fe3+ ions with Al3+ ions, such that the spinel phase of the catalyst is represented by the formula:
[Fe2+(Fe3+ yAl3Vy)204] where y = 0.64.
Example 5 (comparative)
Preparation of a catalyst consisting of hematite phase [Fe203] and spinel phase of the formula
[Fe2+{Fe3+ yAl3VY)204] (y=0.70) ]
The catalyst was prepared according to the procedure described in Example 1 but without the addition of Cu(N03)2'3H20 salt to the mixed solution of metal nitrates. In this example 115.7 gram of Fe (N03 ) 3' 9H20 salt was used for
preparation of iron salt solution in 62 cm3 of water and for the adjustment of the pH value to 6.8 was added 570 cm3 of 3% NH4OH aqueous solution. The material obtained has the following weight ratio of metal components (EDAX) : Fe:Al:K = 100:9:4, surface area 93 mVgram, pore volume 0.21 cm3/gram and average pore diameter 6.5 nm. The material contained two phases (XRD) : 86 wt% of hematite Fe203 and 14 wt% of phase with spinel structure whose composition reflects isomorphous substitution of Fe3+ ions with Al3+ ions, such that the spinel phase of the catalyst is represented by the formula [Fe2+(Fe3+ yAl3+ 1_y)204] where y = 0.70.
Example 6 (comparative)
Preparation of a catalyst consisting of iron oxide
phases [Fe203; Fe304]
The procedure is according to US 5,140,049.
Iron Oxide catalyst was obtained by combustion synthesis using glycolic acid as organic complexant. 12.6 gram of Glycolic acid were dissolved in 10% aqueous ammonia up to pH 6.5 and slowly added to a solution containing 67 gram of Fe(N03)3 ' 9 H20 dissolved in 50 cm3 of water. Then the water, ammonia and part of N03 ~ ions converted to N0/N02 were removed from the mixed solution in rotavapor increasing the temperature from 40 to 80°C up to complete drying of the material. The dried precipitate was calcined in air at 350°C for 1 h (heating rate 5°C min^1). The formed iron oxide was impregnated by incipient wetness method with aqueous K2C03 solution, followed by drying in air at 110°C overnight. The material consisted on 35 wt¾ Hematite Fe203 and 65 wt% Magnetite Fe304. It had surface area of 110 m2/gram, pore volume 0.31 cm3/gram and average pore diameter 4.3 nm.
Example 7 (of the invention)
Preparation of a catalyst consisting of copper-free spinel phase only [Fe(Fe3+ yAl3Vy)204; (y=0.47)]
The catalyst was prepared by co-precipitation from the aqueous solution of Fe and Al nitrates by gradual addition of aqueous ammonium hydroxide solution. 27.0 gram of Al(N03)3 *9H20 and 57.9 gram of Fe(N03)3-9H20 were dissolved in 60 cm3 of distilled water each. The solutions were then mixed together and the pH value was adjusted to 8.0 by gradually adding 250 cm3 of aqueous NH4OH solution with concentration of ammonium hydroxide of 5 wt . The addition time was 15 minutes. The precipitate was recovered and impregnated with K2CO3 solution as described in Example 1. In the present example the atomic ratio of Fe:Al in the precipitating solution was 2:1. Correspondingly, no Fe203 hematite phase was formed after calcination at 450°C. The material had the following weight ratio of metal components (EDAX) : Fe:Al:K = 100:24:6, surface area 128 nrVgram, pore volume 0.53 cmVgram and average pore diameter 3.5 nm.
Example 8 (of the invention)
Preparation of a catalyst consisting of copper-free spinel phase only [Fe (Fe3+ yAl3+i_y) 2Ο4 (y=0.31)]
The catalyst was prepared by co-precipitation from the aqueous solution of Fe and Al nitrates by addition of aqueous ammonium hydroxide solution as described in Example 7. After mixing the aqueous solutions of Fe- and Al-salts the pH value was adjusted to 8.5 by gradually adding 265 cm3 of an aqueous NH4OH solution (with concentration of 5 wt%). The addition time was 15 minutes. The precipitate was recovered and impregnated with 2C03 solution as described in Example 1. The material consisted of only one - Al-substituted Fe304 spinel phase of formula Fe ( Fe3+o.31Al3+o.69 ) 204 and had following weight ratio of metal components (EDAX): Fe :Al : = 100:42:6, surface
area 118 m2/gram, pore volume 0.43 cm3/gram and average pore diameter 3.0 nm.
Example 9 (of the invention)
Preparation of a catalyst consisting of copper-free spinel phase only [Fe(Fe3+ yAl3+i_y)20 ; (y=0.71)]
The catalyst was prepared by co-precipitation from the aqueous solution of Fe and Al nitrates by addition of aqueous ammonium hydroxide solution as described in Example 7. After mixing the aqueous solutions of Fe- and Al-salts the pH value was adjusted to 7.2 by gradually adding 100 cm3 of aqueous NH4OH solution with concentration of ammonium hydroxide of 5 wt% . The addition time was 15 minutes and the precipitate was recovered and impregnated with K2C03 solution as described in Example 1. The material consisted of only one - Al- substituted Fe304 spinel phase of formula Fe ( Fe3+ 0.7iAl3+ 0.29 ) 2Ο4 and had following weight ratio of metal components (EDAX): Fe : Al : K = 100:12:6, surface area 103 m2/gram, pore volume 0.38 cm3/gram and average pore diameter 3.7 nm.
Example 10 (comparative)
Preparation of a catalyst consisting on iron, copper and potassium deposited on Al203 support
(According to WO 97/05088, WO 01/34538 Al , US 4,555,526).
To 36 gram of Fe(N03)3'9H20, 1.25 gram of Cu(N03)2 .3H20 and 3 gram of K2C03 dissolved in 100 cm3 of distilled water was added 20 gram of a powder of γ-Αΐ203 with surface area of 180 irfVgram. The mixture was vigorously stirred and heated at 80°C to evaporate water. After evaporation of water, the solid reaction mixture was dried at 120°C in air for 24 hours and calcined at 450°C for 6 hours. The obtained catalyst had following weight ratio of metal components (EDAX): Fe:Cu:Al:K = 100:6:21:0.34, surface area 76 m2/gram, pore volume 0.16 cm3/gram and average pore diameter 8.2 nm.
The compositions of the catalysts of Examples 1 to 10 are tabulated in Table A.
Table A
In the next set of examples (Examples 11-22), the catalysts of Examples 1-10 were tested for their activity and selectivity in C02 hydrogenation reaction to form fuel compositions. Catalysts testing included catalyst activation, reaction and products analysis.
Catalysts activation was done by means of two methods: reduction in hydrogen at 100 cm3/min*gramcat, temperature 450°C, atmospheric pressure for 24 h; and carburization in a mixture of carbon monoxide and hydrogen in helium at flows 30:30:140 cm3/min*gramcat respectively, at temperature 300 °C, atmospheric pressure for 3 h.
C02 hydrogenation reaction was conducted by passing a mixture of H2 and C02 flows at ratio 4:1 through the 3 gram of catalyst mixed with 1.8 gram of inert silica packed in a tubular reactor {11 mm ID and 210 mm long, 45 mm catalytic phase) and heated up to 300°C or 320°C at the total pressure
of 10 atm. The reaction products were cooled down to +4°C and separated in cooled (+4°C) container. Gas products were analyzed in online Agilent 789 OA Series Gas Chromatograph equipped with 7 columns and 5 automatic valves using helium as a carrier gas. Liquid products were separated into aqueous and organic phases. Aqueous phase was analyzed for Total Organic Carbon in Shimadzu T0C-VCPN Analyzer. The liquid organic phase composition was analyzed by Agilent 190915-433 Gas Chromatograph combined with Mass Spectrometer in the range M/Z= 33-500, equipped with 5973 mass selective detector, HP-5MS column {30 m, 250 μκι, i.d. 0.25 μι ) and helium as a carrier gas. The distillation patterns of hydrocarbon oil were estimated by simulated distillation method based on the maximal boiling points of components in 10 vol% oil fractions. The oil productivity was calculated based on the weighted amounts of organic liquid ( oil) collected over a specific period of time on stream: OP = Woil Wcat RT gram/gram catalyst/h, where Wcat is weight of catalyst (gram) loaded to reactor, RT -time period on stream (hours). The selectivity to CO, CH4, C2-C5 and C6+ hydrocarbons was calculated on the carbon basis as Si = [C± I (Cc02*Xco2) ] * 100%, where Ci amount of carbon (gram) contained in product (i) produced at period of time, CCo2 _ amount of carbon (gram) contained in C02 passed the reactor at the same period of time, XC02 - C02 conversion. In the tables below, the following abbreviations are used: Con for conversion, Sel for selectivity and Pro for productivity.
Example 11
Carbon dioxide hydrogenation in one fixed bed reactor
The Catalyst of Example 1 was packed in a fixed bed reactor and activated by H2 reduction as described above. The effect of HSV on the reaction products was determined. The results
are shown in Table 1. Increasing of the space time by decreasing of WHSV of CO2 did not increase the CO2 conversion beyond 60%.
Table 1
Example 12
Carbon dioxide hydrogenation in one fixed bed reactor
The catalyst of Example 1 was packed in a fixed bed reactor and activated by carburxzation as described above. The effect of WHSV upon the reaction products was determined. The results are shown in Table 2. Comparison of the results presented in Tables 1 and 2 indicates a significantly higher activity of the catalyst after carburization compared with its activation by hydrogen reduction. Higher C02 conversions and oil productivities were measured at different WHSV with carburized catalyst.
Table 2
C2-C5 C6+ oil co2 co2 Methane CO
WHSV Con. , Sel . Sel.
IT1 % % %
Sel. Pro. Sel. Pro .
% (g/gcat.h).102 % (g/gcafh).io2
6 40 10 12 38 32.2 29 24.6
3 46 11 7 41 20.1 26 12.5
1 53 8 5 15 10.9 19 3.5
Reaction conditions: Temperature 300°C, Total pressure 10 atm, H2/C02 = 4 raol/mol.
Example 13
Carbon dioxide hydrogenation in one fixed bed reactor
Catalyst prepared as described in Example 3 was packed in a fixed bed reactor and activated by carburization as described above. The effects of WHSV on the reaction products were determined. The results are shown in Table 3.
Table 3
Reaction conditions: Temperature 300°C/ Total pressure 10 atm, H2/C02=4.
Example 14
Carbon dioxide hydrogenation in one fixed bed reactor
Catalyst prepared as described in Example 4 was packed in a fixed bed reactor and activated by carburization as described above. Effects of WHSV upon the reaction products were determined. The results are shown in Table 4.
Example 15
Carbon dioxide hydrogenation in one fixed bed reactor
Catalyst prepared as described in Example 5 was packed in a fixed bed reactor and activated by carburization as described above. The effects of WHSV on the reaction products were determined. The results are shown in Table 5.
Table 5
Reaction conditions: T=300°C, P=10 atm, H2/C02=4.
Example 16
Carbon dioxide hydrogenation in one fixed bed reactor in the presence of a catalyst consisting of spinel phase only
(Cu-free)
Catalyst prepared as described in Example 7 was packed in a fixed bed reactor and activated by carburization as described above. The effect of WHSV upon the reaction products was determined. The results are shown in Table 6.
Table 6
C2-C5 C6+ oil
co2 C02 Methane CO
WHSV Con. , Sel. Sel.
IT1 ¾ 9-
Sel. Pro. Sel. Pro.
% ( g/gcat«h).io2 % ( g/gCafh).io2
1 52 12 6 39 7.9 29 5.8
6 45 12 13 27 26 40 38.5
Reaction conditions: T = 300°C, Total pressure 10 atm, H2/C02=4.
The selectivities to C6+ hydrocarbons and oil productivity obtained with this catalyst of the present invention are significantly higher compared to that measured with carburized K/FeOx or biphasic K/Cu-Fe-Al-0-Fe203, K/Fe-Al-O- Fe203 catalysts.
Example 17
Carbon dioxide hydrogenation in one fixed bed reactor in the presence of a catalyst consisting of spinel phase only
(containing Cu)
Catalyst prepared as described in Example 2 was packed in a fixed bed reactor and activated by H2. The effect of WHSV upon the reaction products was determined. The results are shown in Table 7.
Table 7
Reaction conditions: T = 300°C, Total pressure 10 atin, H2/C02=4.
Example 18
Testing in one fixed bed reactor of a catalyst consisting of iron oxide phases [Fe203; Fe304] and not containing spinel phase
The catalyst prepared according to Example 6 was packed in the tubular reactor and activated by carburization as described above. The testing results are shown in Table 8.
Table 8
Reaction conditions: 300°C, 10 atm, H2/C02=4, WHSV=1.0 h"1
Example 19
Carbon dioxide hydrogenation in one fixed bed reactor
The catalyst prepared according to Example 9 was packed in the tubular reactor and activated by hydrogen reduction as described above. The testing results are shown in Table 9.
Table 9
Reaction conditions: Temperature 300°C, total pressure 10 atm, H2/C02=4, HSV= 1 h"1.
Example 20
Carbon dioxide hydrogenation in one fixed bed reactor
The catalyst prepared according to Example 8 was packed in the tubular reactor and activated by carburization as described above. The testing results are shown in Table 10.
Table 10
Reaction conditions: Temperature 300 °C, total pressure 10 atm, H2/C02=4, WHSV= 1 h"1.
Example 21
Carbon dioxide hydrogenation in one fixed bed reactor
The catalyst prepared according to Example 9 was packed in the tubular reactor and activated by carburization as described above. The testing results are shown in Table 11.
Table 11
Reaction conditions: Temperature 300 °C, total pressure 10 atm, H2/C02=4, WHSV= 1 h"1.
Example 22
Carbon dioxide hydrogenation in one fixed bed reactor
The catalyst prepared according to Example 10 was packed in the tubular reactor and activated by hydrogen reduction as described above. The testing results are shown in Table 12.
Table 12
Reaction conditions: Temperature 300 °C, total pressure 10 atm, H2/C02=4, WHSV= 1 h-1.
C02 conversion levels achieved by the catalysts of Examples 1-10, when operating under the following set of experimental conditions: Temperature 300 °C, total pressure 10 atm, H2/C02=4, WHSVco2= 1 h"1, as reported in Examples 11-22, are tabulated in Table B,
Table B
In the next set of examples {Examples 23-27), some of the catalysts demonstrating C02 conversion of slightly more than 50% according to the data tabulated in Table B (i.e., the catalysts of Examples 1, 3, 4 and 7) were tested in an experimental set-up consisting of three reactors positioned in series, with water removal taking place between each pair
of consecutive reactors, i.e., between the first and second reactors, and between the second and third reactors.
Example 23
Carbon dioxide hydrogenatxon in three reactors in series
6 gram of the catalyst prepared as described in Example 1 was packed in three fixed bed reactors in series. 2 gram of catalyst was packed in each reactor and activated by carburization as described above. The testing system consisted of 3 consecutive SS fixed bed reactors with pressure, temperature and flow controls (shown in Figure 4). After each reactor the heavy organic products (oil) and water were condensed in a cooling system and collected in the tank. After separation of liquid products, the gases containing non-reacted C02, H2 and light Hydrocarbons, C1-C5 proceeded to flow to the next reactor. After each reactor the gas and liquid products were analyzed as described above. All the three reactors were kept at the same temperature and total pressure of 10 atm.
The catalyst performance as a function of temperature, H2:C02 molar ratio and the number of reactors (N) in the testing system is listed in Table 13.
Table 13
Carbon dioxide hydrogenation in three reactors in series
6 gram of catalyst prepared as described in Example 3 was packed in three fixed bed reactors in series as set out in Example 23. The aqueous and liquid hydrocarbons phases were separated from light gases between first and second and between second and third reactors as shown in Figure 4. The catalyst in all three reactors was activated by carburization as described above and tested as in Example 23. The effects of temperature and total pressure upon the reaction products were determined. The results are shown in Table 14. The oil hydrocarbon composition was similar to that obtained for oil collected in Example 23.
Table 14
Reaction conditions: H2/C02=4.
Example 25
Carbon dioxide hydrogenation in three reactors in series
6 gram of catalyst prepared as described in Example 6 was packed in three fixed bed reactors in series as set out in Example 23. The catalyst was activated by carburization as described above and tested as in Example 23. The effect of WHSV upon the reaction products was determined. The results
are shown in Table 15. The oil hydrocarbon composition was similar to that obtained for oil collected in Example 23.
Table 15
Reaction conditions: T= 300°Cf H2/C02=:4, total pressure 10 atm.
Example 26
Carbon dioxide hydrogenation in three reactors in series in the presence of a catalyst consisting of spinel phase only
(Cu-free catalyst)
6 gram of catalyst prepared as described in Example 7 was packed in three fixed bed reactors in series as set out in Example 23. The aqueous and liquid hydrocarbons phases were separated from light gases between first and second and between second and third reactors as shown in the scheme of Figure 4. The catalyst in all three reactors was activated by carburization as described above and tested as in Example 23. The effects of WHSVCo2 upon the reaction products were determined. The results are shown in Table 16. The cascade reactors configuration with this catalyst of the present invention gives maximal Ce+ hydrocarbons selectivity and oil productivity about 0.5 kg/kgcat h.
Table 16
Reactio conditions: T = 320°C, Total pressure 10 atm, H2/C02=4.
Example 27
Carbon dioxide/Carbon monoxide hydrogenation in three
reactors in series
6 gram of catalyst prepared as described in Example 7 was packed in three fixed bed reactors in series with pressure, temperature and flow controls as set out in Example 23. 2 gram of the catalyst was packed in each reactor and activated by carburization as described above. The catalyst was tested in hydrogenation reaction of the mixture of CO2 and CO by feeding a mixture of H2, C02 and CO flows at molar ratio 5:1:1, respectively. After each reactor the heavy organic products (oil) and water were condensed in a cooling system and collected in the tank. After separation of liquid products, the gases containing non-reacted C02/ CO and H2 and light hydrocarbons flowed to the next reactor. The gas products were analyzed as described above after the third reactor. The liquids were collected from three reactors were mixed and analyzed as described above. All the three reactors were kept at the same temperature and total pressure. The oil productivity was calculated based on the weighted amounts of organic liquid (Woil) collected per hour: OP = Woii/Wcat/h, where cat is total weight of loaded catalyst. The selectivity
to CH4, C2-C5 and C6+ hydrocarbons was calculated on the carbon basis as Si = [Ci / {CCo2+co*XTotai) ] * 100%, where Ci amount of carbon (gram) contained in product (i) produced at period of time, Cc02+co ~ amount of carbon (gram) contained in both C02 and CO that flowed through the reactor at the same period of time, XTotai ~ total conversion of C calculated as Creacted Cin (weight fraction) . The effect of pressure upon the reaction products was determined. The results are shown in Table 17.
Table 17
Reaction conditions: T= 320°C, H2/C02/CO=5 : 1 : 1.
Example 28
Carbon dioxide hydrogenation in three reactors in series with different catalysts at C02 conversion of 75% adjusted by varying of WHSVCo2
In the set of experiments described in this Example, the performance (activity and selectivity) of the catalysts tabulated in Table B was measured under identical conditions (the same feed composition, temperature, pressure and CO2 conversion). The latter variable is controlled by varying the space velocity. Using the three packed-bed-reactors-in-series system illustrated in Figure 4, high C02 conversion (75%) was reached to reflect the selectivity to hydrocarbons.
Thus, 6 gram of catalysts prepared as described in Examples 1, 3, 4, 6, 7, 8 and 9 were packed in separate experiments in
three fixed bed reactors in series as set out in Example 23. The catalysts were activated by carburization as described above. The results set out in Table 18 were measured for every catalyst after 200 h of run at 300°C, P = 10 atm, H2/C02 = 4 and properly adjusted WHSVCo2 to produce total C02 conversion of 75%.
Table 18
The results shown in Table 18 demonstrate that the catalysts consisting of pure phase of Al-substituted Fe304 with spinel structure, i.e., the catalysts represented by Formula 1 Fe2+(Fe3+ yAl3+i_y)204; (y=0.05 - 0.95, preferably y=0.25 - 0.75 and more preferably y=0.30 - 0.70), i.e., catalysts of Examples 7, 8 and 9, display higher catalytic activity in conversion of C02 to hydrocarbons compared with the catalysts of Examples 1, 3, 4 and 6.
Example 29
Preparation of extruded catalyst consisting of spinel phase only [Fe(Fe3÷yAl3+i_y)204; (x=0.00, y=0.47)]
Fe(Fe+ yAl3+i_y)20 from Example 7 was formed as extrudates with cylindrical shape using Al203 as a binder. 11.73 gram of Fe (Fe3+ yAl3+i_y ) 204 prepared in Example 7 was mixed with 4.89 gram of A100H powder (Disperal P2 , Sasol Ltd., Germany) and water was added to get a slurry. The slurry was kneeded in a mortar and extruded using a matrix with 1.2 mm cylindrical
shape opening. The extrudates were dried at room temperature for 24 h, then at 110 °C overnight and calcined at 450 °C for period of 2 h (temperature increasing rate 5°C/min). The so- formed material was impregnated by incipient wetness with aqueous solution containing 2.15 gram K2C03. The impregnated material was dried in air at 110°C for period of 24 h and calcined in air at 450°C for period of 2 h {temperature increasing rate 5°C/min) .
Claims
Claims
1 ) A catalyst suitable for use in the hydrogenation of carbon dioxide-containing gas, said catalyst comprising spinel phase of the following formula:
[Fe2+{Fe3+ yAl3+i_y)204] Formula 1 wherein y is from 0.05 to 0.95.
2) A catalyst according to claim 1, wherein y is from 0.25 to 0.75.
3) A catalyst according to claim 2, wherein y is from 0.3 to 0.7.
4) A catalyst according to any one of claims 1 to 3 , having average crystal size in the range from 1.5 to 3 nm, as measured by X-Ray diffraction (XRD) .
5) A catalyst according to any one of claims 1 to , which further comprises potassium on its surface.
6) A process for preparing compounds of Formulas 1 or 2 : Fe2+(Fe3+yAl3 y)204 Formula 1
wherein y is in the range from 0.05 to 0.95; or (Cu2+ xFe2Vx) (Fe3+ yAl3+i_y)204 Formula 2
wherein 0.0<x≤0.05, and y is in the range from 0.05 to 0.95; comprising dissolving in an aqueous solution at least one ferric compound and at least one aluminum compound, and optionally cupric compound, gradually adjusting the pH of the metal-containing solution by means of addition of an alkaline
agent, whereby co-precipitation of the metals in the form of their hydroxides occurs, separating the solid formed from the liquid phase, and subjecting same to drying and calcination.
7) A process according to claim 6, wherein the pH is adjusted within the range from 6 to 8.5, wherein the addition time of the alkaline agent is not less than 10 minutes.
8) A process according to claim 6 or 7 , wherein a dilute aqueous solution of ammonium hydroxide is added, with concentration of not more than 5% by weight.
9) A process according to claim 7 or 8, wherein the metal- containing solution and the ammonium hydroxide solution are held at room temperature during the addition.
10) A process according to any one of claims 6 to 9, wherein the weight ratio Al:Fe in the metals-containing solution is not less than 20:100, thereby obtaining a hematite-free catalyst following the calcination.
11) A process for the preparation of hydrocarbons comprising the hydrogenation of carbon dioxide-containing gas in the presence of iron-containing catalyst, said catalyst being devoid of hematite phase and copper-free, wherein the catalyst is activated in~situ by means of carburization, said carburization comprises treating said catalyst with a mixture of ¾ and CO at elevated temperatures.
12) A process according to claim 11, wherein the iron- containing catalyst is as defined in any one of claims 1 to 5.
13) A cascade process for the hydrogenation of carbon-dioxide containing gas, employing a plurality of serially arranged reactors, comprising:
(i) feeding carbon dioxide-containing gas and hydrogen streams into at least the first of said serially arranged reactors which are loaded with iron-containing catalyst, said catalyst being copper-free, wherein said catalyst was brought to an active form by means of carburization;
(ii) discharging a gaseous reaction stream from at least one of said serially arranged reactors and cooling same, to form a gas-liquid mixture, wherein the liquid component of said mixture comprises condensable reaction products consisting of water and organic liquids, and the gas component of said mixture comprises reactants and non-condensable reaction products ;
(iii) separating said gaseous component from said liquid component ;
(iv) separating said liquid component into an organic and aqueous phases, and collecting at least said organic phase; and
(v) feeding the gaseous component into the successive reactor in said serially arranged reactors.
14) A process according to claim 13, wherein the catalyst loaded in said reactors is as defined in any one of claims 1 to 5.
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AU2015203898A AU2015203898B2 (en) | 2013-01-17 | 2015-07-13 | A catalyst and a process for catalytic conversion of carbon dioxide-containing gas and hydrogen streams to hydrocarbons |
US14/801,292 US9522386B2 (en) | 2013-01-17 | 2015-07-16 | Catalyst and a process for catalytic conversion of carbon dioxide-containing gas and hydrogen streams to hydrocarbons |
US15/350,133 US20170056861A1 (en) | 2013-01-17 | 2016-11-14 | Catalyst and a process for catalytic conversion of carbon dioxide-containing gas and hydrogen streams to hydrocarbons |
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