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CATALYST PRECURSOR, METHOD OF PREPARATION AND USE THEREOF

20180119021 ยท 2018-05-03

    Inventors

    Cpc classification

    International classification

    Abstract

    A catalyst precursor suitable for the Fischer Tropsch reaction is described comprising cobalt oxide supported on a porous support wherein the porous support is a ceramic foam comprising a closed cell structure.

    Claims

    1. A Fischer Tropsch reaction catalyst precursor, comprising cobalt oxide supported on a porous support that is a ceramic foam comprising a closed cell structure.

    2. A catalyst precursor according to claim 1, wherein the cobalt content of the catalyst precursor, expressed as Co, is in the range of 5-50% by weight.

    3. A catalyst precursor according to claim 1, wherein up to 20% by volume of the cell volume is interconnected.

    4. A catalyst precursor according to claim 1, wherein the average cell diameter is in the range of 10-150 m.

    5. A catalyst precursor according to claim 1, wherein the cell fraction of the foam is in the range of 50-95% by volume.

    6. A catalyst precursor according to claim 1, wherein the cell wall thicknesses is up to 500 m with an average cell wall thickness in the range of 10-100 m.

    7. A catalyst precursor according to claim 1, wherein the ceramic foam comprises titania.

    8. A method for preparing a catalyst precursor according to claim 1, comprising the steps of: (i) forming a ceramic foam comprising a closed cell structure, (ii) applying a cobalt compound to the ceramic foam and (iii) heating the cobalt-containing foamed metal oxide to form the catalyst precursor.

    9. A method according to claim 8 wherein the ceramic foam is formed by steps comprising: (a) forming a suspension of a ceramic powder in a liquid, (b) adding a gas to the liquid to create a wet foam, and (c) heating the wet foam to form the ceramic foam.

    10. A method according to claim 9, wherein the ceramic powder particle size in the suspension is in the range of 1 nm to 20 m.

    11. A method according to claim 9, wherein the suspension contains one or more amphiphiles that act with the ceramic powder to stabilise the wet foam.

    12. A method according to claim 11, wherein the amphiphiles comprise one or more C2-C6 carboxylic acids or esters thereof, C2-C6 gallate esters, or alpha amino acids.

    13. A method according to claim 11, wherein the amphiphile comprises one or more of valine, isoleucine, leucine, phenylalanine or tryptophan.

    14. A method according to claim 9, wherein the wet foam is shaped before heating.

    15. A method according to claim 14, wherein the shaped foam is subjected to a heating step at a temperature in the range of 500-1600 C.

    16. A method according to claim 8, wherein the cobalt compound is an organic cobalt compound, a cobalt complex or a cobalt salt.

    17. A catalyst prepared using a catalyst precursor according to claim 1, comprising cobalt in elemental form supported on a porous support, wherein the porous support is a ceramic foam comprising a closed cell structure.

    18. A catalyst according to claim 17 encapsulated in a hydrocarbon wax.

    19. A method for preparing a catalyst according to claim 17, comprising applying a reducing gas stream to a Fisher Tropsch reaction catalyst precursor comprising cobalt oxide supported on a porous support that is titania comprising a closed cell structure; wherein at least a portion of the cobalt oxide is converted to elemental form.

    20. A Fisher-Tropsch reaction process for producing hydrocarbons, comprising contacting a synthesis gas comprising carbon monoxide and hydrogen with a catalyst according to claim 17.

    Description

    EXAMPLE 1 TITANIA FOAM PREPARATION

    [0066] a) A ceramic foam was prepared using a titania suspension containing 30% wt solids.

    [0067] 128 g titania powder (P25 available from Evonik) were added slowly to 300 ml demineralised water in a stirred vessel. Then, without pH adjustment, 0.36 mmol DL-phenylalanine were added per gram of titania (7.6 g DL-phenylalanine). The pH of the suspension was 4.59. Air was then introduced into the suspension to form bubbles using a gas inducing impeller for 30 minutes. The foam was cast into a tray and dried at room temperature and at atmospheric pressure. It was then calcined with a nitrogen purge by heating at 2 C./min to 600 C. After 45 minutes at 600 C. the nitrogen flow was replaced by air. The total dwell at 600 C. was 4 hours. The resulting ceramic foam support was crushed and sieved to 0.5 mm.

    [0068] A porosity measurement was made by immersing the ceramic foam in demineralised water at room temperature for 4 days and measuring the water up-take by the increase in weight. The porosity measured in this way includes the volume of the cells and accessible pores and indicates the volume of cobalt solution that may be used to prepare the catalyst. The porosity of the foamed titania was 0.8 cm.sup.3/g after 4 days. [0069] b) The method was repeated for different titania contents in the suspension as follows;

    TABLE-US-00001 Titania DL-phenylalanine Porosity weight % mmol/g titania pH cm.sup.3g.sup.1 17.5 0.82 4.65 2.2 20.0 0.36 4.50 1.6 20.0 0.54 4.52 1.5 20.0 0.72 4.56 1.4 25.0 0.39 4.56 0.9 25.0 0.54 4.58 1.0 [0070] c) The method was repeated, replacing the phenyl alanine with n-butyric acid. pH adjustment was required before air entrainment using potassium hydroxide.

    TABLE-US-00002 Titania Butyric Acid pH after pH after weight mmol/g butyric acid KOH Porosity % titania addition Foaming addition cm.sup.3g.sup.1 20 0.36 3.86 Not 4.65 2.3 Observed 20 0.54 3.71 4.65 2.2 20 0.72 3.66 4.40 1.8 25 0.36 3.71 4.50 1.8 25 0.54 3.68 4.50 1.5 25 0.72 3.56 4.00 1.4 30 0.36 3.66 4.30 1.2 30 0.54 3.60 4.30 1.4 30 0.72 2.46 3.20* 1.1 *pH was not increased further since an increase in viscosity was observed [0071] d) The method was repeated, replacing the phenylalanine with other alpha-amino acids. Unless otherwise indicated, no pH adjustment was performed prior to air entrainment.

    TABLE-US-00003 Titania DL-amino acid Porosity Example weight % mmol/g titania pH cm.sup.3g.sup.1 1(d)(i) 30 0.21 DL-leucine 3.66 0.62 1(d)(ii) 30 0.54 DL-valine 4.02 0.47 1(d)(iii) 30 0.43 DL-phenyl alanine 1.60* 0.45 1(d)(iv) 25 0.36 DL-Leucine 0.93* 0.52 1(d)(v) 20 0.22 DL-tryptophan 3.25 0.50 1(d)(vi) 20 0.74 DL-leucine 3.96 2.84 1(d)(vii) 25 0.72 DL-isoleucine 1.28* 0.63 1(d)(viii) 25 0.72 DL-methionine 1.21* 0.44 *pH adjusted by addition of nitric acid

    EXAMPLE 2: CATALYST PRECURSOR PREPARATION

    [0072] a) Cobalt Nitrate Impregnation of Titania Foam of Example 1(a).

    [0073] 7 g of cobalt nitrate hexahydrate (Co(NO.sub.3).sub.2.6H.sub.2O) and 2.2 ml demineralised water were heated until the melting and dissolution of the salt were complete. This was added in aliquots to 15 g of the ceramic foam product of Example 1(a) in a plastic bag. After each addition the material was kneaded into the support. The impregnated foam was dried for 2 hours at 105 C. and calcined for 2 hours at 300 C. The process was then repeated. 5.5 g Co(NO.sub.3).sub.2.6H.sub.2O and 2.74 ml demineralised water were heated until the melting and dissolution of the salt were complete. This was added in aliquots to 16.5 g of the impregnated ceramic foam product from the first impregnation in a plastic bag. After each addition the material was kneaded into the support. The resulting material was dried for 2 hours at 105 C. and calcined for 2 hours at 300 C. The cobalt content of the catalyst precursor by ICPAES was 10.8% wt. The cobalt surface area as determined by hydrogen chemisorption was 1.0 m.sup.2/g catalyst.

    [0074] b) Cobalt Amine-Carbonate Impregnation of Titania Foam of Example 1(a).

    [0075] A cobalt amine carbonate solution was prepared as follows; 198 ml of a 28% ammonia solution was added to 20.4 g ammonium carbonate in a round bottomed flask and diluted with 193.4 ml demineralised water. The resulting solution was stirred for 20 minutes then 23.7 g of cobalt basic carbonate was added over 15 minutes and the solution stirred at 150 rpm for a further 2.5 hr to give a purple solution. 30% hydrogen peroxide solution was added drop wise while the solution was stirred at 234 rpm until the Oxido-reduction potential (Metler Toledo transmitter M 700) was near to 100 mV. Stirring was continued for a further 10 minutes and then the solution was filtered.

    [0076] 385 ml of the Co amine carbonate solution (2.6% w/w Co) was added to a 2 L four-necked round bottom flask. A stirrer, temperature probe, lute and condenser were fitted to the flask. 52 g of the ceramic foam product of Example 1(a) was added. This mixture was then diluted with 385 mL water and 165 mL ammonia before being heated and agitated for 80 minutes to cause evolution of the ammonia and deposition of cobalt oxide in the cells and pores of the ceramic foam. The mixture was filtered and washed with 80 ml demineralised water. The catalyst precursor was dried at 105 C. for 8 hours. It was not calcined. The cobalt content of the catalyst precursor by ICPAES was 11.2% wt. The cobalt surface area as determined by hydrogen chemisorption was 1.1 m.sup.2/g catalyst.

    [0077] c) Cobalt Amine-Carbonate Impregnation of Titania Foams of Examples 1(d) (i)-(iv).

    [0078] The method of Example 2(b) was repeated using instead the titania foams obtained in Examples 1(d) (i)-(iv). The target cobalt content in each case was 13% by weight. The cobalt surface areas for the catalyst precursors, as determined by hydrogen chemisorption, are set out below.

    TABLE-US-00004 Foam Cobalt Surface Area (m.sup.2/g catalyst) 1(d)(i) 3.9 1(d)(ii) 1.6 30 1(d)(iii) 1.5 1(d)(iv) 1.5

    EXAMPLE 3 CATALYST TESTING

    [0079] 0.5 g of the catalyst from Example 2(a) was tested for catalytic performance in Fischer-Tropsch synthesis. The reaction conditions were syngas (H.sub.2:CO of 2:1) flow rate 30 ml.sub.N/min, 20 bar and 210 C. with GHSV 3590 ml.sub.N sygas.Math.g catalyst.sup.1.Math.h.sup.1 and a target conversion of 50%. The selectivity to C5+ was 92%.

    [0080] 0.25 g of the catalyst from Example 2(b) was tested for catalytic performance in Fischer-Tropsch synthesis. The reaction conditions were syngas (H.sub.2:CO 2:1) flow rate 44 ml.sub.N/min, 20 bar and 210 C. with GHSV 10338 ml.sub.N sygas.Math.g catalyst.sup.1.Math.h.sup.1 and a target conversion of 50%. The selectivity to C5+ was 91%.

    [0081] 0.25 g of each of the catalysts from Example 2(c) was tested for catalytic performance in Fischer-Tropsch synthesis. The reaction conditions were syngas (H.sub.2:CO of 2:1), 20 bar and 210 C. and a target conversion of 50%. The remaining reaction conditions and selectivity to C5+ for the catalysts based on the different foam materials were as follows;

    TABLE-US-00005 Temp- GHSV (ml.sub.N Flow Rate Pressure erature syngas .Math. g Selectivity Foam (ml.sub.N/min) (bar) ( C.) catalyst.sup.1 .Math. h.sup.1) to C5+ 1(d)(i) 49.48 20 210 12082 89.51 1(d)(ii) 33.98 20 210 7816 89.90 1(d)(iii) 15.20 20 210 3461 86.71 1(d)(iv) 15.13 20 210 3642 90.02