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Title:
REDUCTION OR REMOVAL OF OXYGENATED HYDROCARBONS IN SYNGAS CONDITIONING
Document Type and Number:
WIPO Patent Application WO/2015/177034
Kind Code:
A1
Abstract:
A process for the conversion of one or more oxygenic compounds to one or more hydrocarbon compounds, wherein the oxygenic compounds are contacted with a catalyst comprising Co and Mo, Ni and Mo or Mn and Mo. The process may be used for the conditioning of syngas, including the reduction of tar formation for the process of preparing syngas from the gasification of coal, waste or biomass.

Inventors:
HØJLUND NIELSEN POUL ERIK (DK)
KAARSHOLM MADS KRISTIAN (DK)
NIELSEN RASMUS MUNKSGÅRD (DK)
ANDERSSON KLAS JERKER (DK)
Application Number:
PCT/EP2015/060664
Publication Date:
November 26, 2015
Filing Date:
May 13, 2015
Export Citation:
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Assignee:
HALDOR TOPSOE AS (DK)
International Classes:
C10J3/84; B01J23/34; B01J23/882; B01J23/883; C10G2/00; C10K3/02
Domestic Patent References:
WO2012166402A22012-12-06
WO2010025241A22010-03-04
Foreign References:
US20080312480A12008-12-18
US4218388A1980-08-19
Download PDF:
Claims:
Claims :

1. A process for the conversion of one or more oxygenic compounds present in syngas, obtainable by gasifica- tion of biomass, waste or coal, to one or more hydro¬ carbon compounds, wherein the oxygenic compounds are contacted with a catalyst comprising metals selected from the group consisting of Co and Mo, Ni and Mo, and Mn and Mo.

2. A process according to claim 1, wherein the catalyst comprises a support selected from one or more of the group consisting of Mg-Al204 spinel, alumina oxide, titanium oxide and zirconium oxide.

3. A process according to claims 1 and 2, wherein the

catalyst comprises 2wt% or less Mn, 7wt% or less Mo and Mg-Al204.

4. A process according to claims 1 to 3, wherein the cat¬ alyst may be present in pellet or monolith form.

5. A process according to claims 1 to 4, wherein the oxy- genie compounds are obtainable by gasification of bio¬ mass, waste or coal.

6. A process according to claims 1 to 5, wherein the oxy¬ genic compounds are obtainable by underground coal gasification .

7. A process according to claims 1 to 5, wherein the ap¬ paratus for use in the gasification according to claims 5 and 6 is a gasifier and the gasifier is se¬ lected from the group consisting of moving bed gasifi¬ er, fluid bed gasifier, biomass gasifier or pyrolysis unit.

8. A process according to claims 1 to 7, wherein the oxy¬ genic compounds comprise compounds selected from one or more of the group consisting of aldehydes, ketones, ethers, esters, alcohols and organic acids.

9. A process according to claims 1 to 8, wherein the tem¬ perature of the gasification of biomass, waste or coal is 1000 °C or less.

10. A process according to claims 1 to 8, wherein the temperature of the gasification of biomass, waste or coal is 800 °C or less.

11. A process according to claims 1 to 10, wherein the temperature of the process for the conversion of one or more oxygenic compounds to one or more hydro¬ carbon compounds is 300 °C or greater.

12. Use of a process according to claims 1 to 11 for the reduction of tar formation for the process of preparing syngas from coal, waste or biomass.

13. A catalyst comprising 2wt% or less Mn, 7wt% or less Mo and Mg-Al204.

Description:
Title: Reduction or removal of oxygenated hydrocarbons in syngas conditioning.

Gasification of biomass, waste or coal produces syngas, a gas comprising methane, carbon monoxide, hydrogen, water and carbon dioxide. Syngas may be used as a source of fuel, hydrogen or carbon monoxide. Manipulation of reaction equilibria and reaction conditions influences the ratio of the gaseous products and therefore provides the preferred gas (i.e. methane, hydrogen or carbon monoxide) .

Gasification may be carried out above- or under-ground. Gasification of biomass, waste and coal may be carried out using moving bed, fluid bed or entrained flow apparatus for gasification carried out above ground. General gasification techniques are described in: Gasification by Christopher Higman and Maarten van der Burgt GPP, Elsevier Amsterdam 2008. Underground coal gasification is described in

http : //www . ucgassociation . org

Gasification of biomass, waste and coal may be carried out at temperatures of up to 1800°C [Higman and Maarten van der Burgt] . Biomass & Bioenergy 24 (2003) pp 125-140 discloses that the temperature of such gasification processes not on- ly affects the amount of tar formed, but also the composi ¬ tion of the tar. It has been observed that oxygen containing compounds exist in the tar, in particular as the temperature of the gasification process is reduced. E.g. an increase in oxygen-containing compounds during a sawdust gasification in a fixed bed gasifier was observed at lower gasification temperatures, e.g. 800 °C . In this example the oxygenic species that were observed to be present in sig- nificant amounts were phenol, cresol and benzofuran. Oxy ¬ gen-containing tar components (oxygenic species, oxygenic compounds) may be alcohols, aldehydes, ethers, esters, ke ¬ tones and organic acids.

Gasification of biomass, waste and coal is carried out in the presence of oxygen to form syngas products such as a gaseous composition of methane, hydrogen and carbon monox ¬ ide. This is in comparison to pyrolysis of biomass to form pyrolysis oil, which is carried out in the absence of air (PCT/US2012/038747) and produces a liquid composition of products such as carboxylic acids, phenols, cresols, alco ¬ hols and aldehydes. Due to the different processes and the products and compositions formed, the gasification product composition comprising oxygenic species is gaseous and the condensed vaporous product of pyrolysis comprising oxygenic species is a liquid.

Oxygenic species have higher boiling points compared to their corresponding aromatic and aliphatic hydrocarbons.

The higher boiling point may be the cause for condensation in downstream equipment; this influences the phase of the impurities, i.e. solid or liquid phase rather than gaseous phase impurities. Additionally, the oxygenic species are water soluble, and are removed from the product syngas through scrubbing process steps. Therefore existing syngas processes require a subsequent waste water treatment step to remove the oxygenic species present in waste water from scrubbing process steps. Examples of scrubbing steps are present in US 7,618,558 B2. In order to obtain syngas with reduced oxygenic species (impurities) where the gasification of the biomass, waste or coal is carried out at low temperatures, i.e. up to 1000 °C, there is a need for a process to reduce the amount of oxygenic species present in the syngas. Additionally, the reduction of process steps, such as waste water treatment is desirable.

It has been discovered that oxygenic species may be con- verted into aliphatic or aromatic hydrocarbons in the pres ¬ ence of a catalyst comprising Co and Mo, Ni and Mo, or Mn and Mo. The conversion of the oxygenic species into hydro ¬ carbons provides impurities with a comparatively low boil ¬ ing point and that are insoluble in water, consequently re- ducing the amount of tar and requirement for waste water treatment. The present invention provides a more efficient and consolidated process for conditioning syngas obtainable from the gasification of coal, waste or biomass. The efficiency of the process of the present invention (and therefore advantage) may be demonstrated by the absence of independent process steps for the addition of a sulphur compound required to activate the catalyst, and the addi ¬ tion of hydrogen to convert the oxygenic compounds to hy- drocarbons . Both sulphur compounds and hydrogen are present in the gasification product (syngas) and are therefore not necessary to add to the process of the present invention. Therefore, two process steps, i.e. the activation of the catalyst with the addition of a sulphur compound to the composition comprising oxygenic species and the addition of hydrogen to the reaction, are not required to be added to the process of the present invention. The invention provides a process for the conversion of one or more oxygenic species (oxygenic compounds) to one or more hydrocarbon compounds, wherein the oxygenic compounds are brought into contact with (contacted with) a catalyst comprising a combination of metals selected from the group consisting of Co and Mo, Ni and Mo or Mn and Mo. The Mo, Ni and Mn may optionally be in the form of an oxide. The cata ¬ lyst comprising Co and Mo, Ni and Mo or Mn and Mo further comprises a support selected from the group consisting of Mg-Al 2 0 4 spinel, alumina oxide, titanium oxide or zirconium oxide. Examples of such catalysts include the sulphur tol ¬ erant shift catalyst from Haldor Topsoe A/S comprising Co and Mo on a Mg-Al 2 0 4 support. The sulphur tolerant shift catalyst from Haldor Topsoe A/S is also called an SSK-10 catalyst. An alternative catalyst comprises 2 wt% or less Mn and 7 wt% or less Mo on a Mg-Al 2 0 4 support; i.e. the catalyst comprises 2 wt% or less Mn, 7 wt% or less Mo and Mg-Al 2 0 4 . Catalysts may be prepared according to: Catalyst Manufacture, Second Edition, Alvin B. Stiles, CRC Press, 1995.

The catalysts may be present in pellet or monolith form. The process of the present invention is therefore suitable for use in a dusty or dust-free environment. Preparation of pellet and monolith forms of catalysts are known to the person skilled in the art, exemplary forms and processes of preparation may be found in Catalyst Manufacture, Second Edition, Alvin B. Stiles, CRC Press, 1995.

The oxygenic compounds are obtainable by gasification of biomass, waste or coal. The gasification process may be carried out above- or under-ground. Above-ground gasifica ¬ tion of biomass, waste and coal may be carried out using an apparatus selected from the group consisting of moving bed reactor (Lurgi-type reactor) , fluid bed apparatus, or a bi- omass gasifier, including, for example, a pyrolysis unit as described in Gasification by Christopher Higman and Maarten van der Burgt GPP, Elsevier Amsterdam 2008 and x Biomass Gasification' chapter 4 in Alternative Energy in Agricula- ture' Vol. II, Ed. D. Yogi Goswami CRC Press 1986 pp 83- 102.

Underground coal gasification is carried out according to http : //www . ucgassociation . org/ . The temperature of the gasification of biomass, waste or coal is 1000 °C or less. The temperature of the gasifica ¬ tion of biomass, waste or coal may be 900 °C or less, 800 °C or less, less than 800 °C, 750 °C or less, less than 750 °C, 700 °C or less, less than 700 °C .

After gasification of coal, waste or biomass, the product gas stream (syngas) is optionally cooled to 700°C or less and brought into contact with a catalyst comprising Co and Mo, Ni and Mo or Mn and Mo; the oxygenic compounds are therefore present in the gas stream of the product of the gasification of biomass, waste or coal, i.e. the oxygenic species are present in the product gas stream (syngas) . The product gas stream has a temperature of about 300 °C or greater, between 250 °C and 700 °C, between 250 °C and 650 °C, between 250 °C and 600 °C, between 350 °C and 550 °C, between 350 °C and 450 °C, between 350 and 400 °C . The prod ¬ uct gas stream has a pressure of between 1 barg and 100 barg, between 2 barg and 100 barg, up to 100 barg, up to 25 barg, up to 20 barg. Gasification by Christopher Higman and Maarten van der Burgt GPP, Elsevier Amsterdam 2008. Barg means overpressure in bar.

The oxygenic compounds comprise compounds selected from the group consisting of aldehydes, ketones, ethers, esters, al ¬ cohols and organic acids comprising oxygen. Examples of such oxygenic species comprise iso-propanol , phenol, p- cresol, coumaran, methyl ethyl ketone.

Hydrocarbon compounds include aliphatic and aromatic com ¬ pounds. Examples of such compounds include methane, ethene, ethane, propene, propane, benzene and toluene.

The present invention comprises a catalyst comprising 2wt% or less Mn, 7wt% or less Mo and Mg-Al 2 0 4 and a process of preparing said catalyst. The present invention comprises a catalyst comprising 2wt% or less Mn, 7wt% or less Mo and Mg-Al 2 0 4 for the conversion of oxygenic compounds to hydro ¬ carbon compounds .

The present invention comprises the use of a catalyst com ¬ prising 2wt% or less Mn, 7wt% or less Mo and Mg-Al 2 0 4 for the conversion of oxygenic compounds to hydrocarbon com ¬ pounds .

The process of the present invention reduces the content of oxygenic species in the product gas stream (syngas) obtain- able by gasification of biomass, waste or coal; consequent ¬ ly, the present invention is suitable for the reduction of oxygenic species present in syngas obtainable by gasifica- tion of biomass, waste or coal. The process of reducing the oxygenic species present in syngas may also be called con ¬ ditioning . The process of the present invention reduces the content of oxygenic species present in syngas obtainable by gasifica ¬ tion of biomass, waste or coal; consequently, as such oxy ¬ genic species are a component of tar formed during the gas ¬ ification process, the present invention is suitable for the reduction of oxygenic species and therefore the reduc ¬ tion of tar formed for the process of preparing syngas ob ¬ tainable by the gasification of coal, waste or biomass.

Example 1 :

Conversion of oxygenic species to hydrocarbons using a catalyst comprising Co and Mo on a Mg-Al 2 0 4 support.

Example l.a.: Catalyst Pre-treatment :

20 g of SSK-10 (catalyst comprising Co and Mo supported on Mg-Al 2 0 4 ) is loaded in a 15 mm ID tube reactor which is heated by five electrical heaters. The catalyst is sulfided in syngas containing 0.7% ¾S first at 150°C and then at 330°C. The catalyst was validated by a shift activity test with a feed containing 28.6% CO, 22.0% H 2 , 0.5% H 2 S and 48.9% H 2 0 with a GHSV of 3500h _1 , 40 barg at 260°C resulting in an approach to equilibrium at 20°C with the reactor operating at isothermal conditions.

Example l.b.: Conversion of Oxygenic Species to Hydrocar- bons :

A feed gas was made by mixing two gas streams comprising CO/CO 2 /H 2 /CH 4 and H 2 /H 2 S. Once mixed, the feed gas was passed through a pre heater at 300°C. The feed gas was then mixed with a water feed which had been pre heated to the same temperature. An oxygenic stream comprising the oxygen ¬ ic species listed in Table 2 was injected into the feed gas stream. The final feed gas composition is given in Tables 1 and 2. The gas stream was then passed over the catalyst de ¬ scribed in Example l.a. at process conditions given in Ta ¬ bles 3 and 4. After passing the feed gas composition over the catalyst of Example l.a., the exit gas pressure is reduced to about 1 barg and cooled to about 30 °C, consequently any water is condensed and removed. The liquid and gas fractions are then split into two exit streams: a liquid and a gas stream. The gas and liquid exit streams are analysed sepa ¬ rately.

The gas stream was analysed online by FID on an Agilent GC and samples of the liquid and gas streams were measured on a GC-MS(EI) in SCAN-mode: Ion range 29-320 m/z, split in ¬ jection, split 10:1 (liquid) or 20:1 (gas) with injection temperature 275°C, injection volume 0.2ym (liquid) or lym (gas), column configuration: HP-INNOWax 60m x 250ym x 0.50 ym.

Two feed gas (syngas) compositions were tested (feed 1 and 2). The GHSV for feed 1 was 2685h _1 and 3000h _1 for feed 2. Table 1 : Composition of Syngas Feed in % (H 2 S in ppm) :

Table 2 : Composition of the total oxygenic species in the two feed gases (feed in %) :

Total iso- Phe ¬ p- Couma- Methyl

Oxygenic propa- nol cresol ran Ethyl

Feed Species nol Ketone

[A+B+C+D+

[A] [B] [C] [D] [E]

E]

1 0.518 0.131 0.126 0.012 0.003 0.790

2 0.463 0.117 0.113 0.010 0.002 0.705

Table 3: Feed 1 (dry exit gas composition excluding H 2 , CO, C0 2 , CH 4 and N 2 ) at varied process conditions:

Ex Temp . P C 2 H 4 C2H6 C3H6 C 3 H 8 BenTolu ¬ Oxy-

(°C) (bar zene ene genat g) e

conversion

(%) l 1 350 3 0.0006 0.0000 0.2307 0.1008 0.0137 0.0592 40

2 l 350 20 0.0000 0.0041 0.0000 0.4398 0.0227 0.0816 57

3 450 10 0.0020 0.0141 0.1596 0.3865 0.1056 0.1200 75

450 20 0.0000 0.0206 0.0000 0.5617 0.1244 0.1291 81

Table 4 : Feed 2 (dry exit gas composition excluding

C0 2 , CH 4 and N 2 ) at varied process conditions:

Ex Temp P C 2 H 4 C2H6 C3H6 C 3 H 8 BenTolu ¬ Oxy- (°C) (bar zene ene genat g) e

conversion

(%)

5 450 20 0 0005 0 0186 0 0403 0 4747 0 1200 0 1250 88

6 450 10 0 0037 0 0100 0 2569 0 2281 0 0904 0 1102 79

7 450 5 0 0047 0 0023 0 3483 0 0518 0 0578 0 0833 61

8 450 3 0 0030 0 0010 0 3083 0 0324 0 0353 0 0530 48

9 450 20 0 0024 0 0250 0 1275 0 4050 0 1035 0 1104 86

10 1 550 20 0 0118 0 0367 0 2094 0 3375 0 1733 0 0894 92

11 550 10 0 0081 0 0069 0 4197 0 0724 0 0847 0 0430 69

12 550 5 0 0061 0 0039 0 5792 0 0323 0 0597 0 0318 78

13 550 2.5 0 0041 0 0021 0 6093 0 0000 0 0344 0 0168 73

14 550 20 0 0094 0 0271 0 3069 0 3318 0 1274 0 1050 -100

Both Tables 3 and 4 illustrate that conversion of the oxy ¬ genic species to hydrocarbon species increases with in ¬ crease temperature and pressure.

Both Tables 3 and 4 also illustrate that reduction of the oxygenic species with hydrogen increases with increased temperature and pressure. For example, iso-propanol is con ¬ verted to propene and subsequently propane; phenol and p- cresol are converted to benzene and toluene respectively;

hydrogenation of the benzene ring is also observed to some extent at high pressure. Example 2

Conversion of oxygenic species to hydrocarbons using a catalyst comprising Mn and Mo on a Mg-Al 2 C>4 support. Example 2. a.: Catalyst Pre-treatment :

20 g of a catalyst comprising Mn and Mo on Mg-Al 2 04 spinel is loaded in a 10.7 mm ID tube reactor which is heated by five electrical heaters. The catalyst is sulfided in syngas containing 0.7% H 2 S first at 150°C and then at 330°C.

Example 2.b.: Conversion of Oxygenic Species to Hydrocarbons :

The conversion of oxygenic species to hydrocarbons was re ¬ peated as in Example l.b. with the exception that the cata- lyst of 2. a. was used. The final feed gas composition is given in Tables 5 and 6 and the process conditions of the reaction are given in Table 7. The GHSV for feed 3 was 2715h _1 . Table 5: Composition of Syngas Feed in % (H 2 S in ppm) :

Total

H 2 S Oxygenic

Feed CO co 2 H 2 0 CH 4 N 2

(ppm) Species

[A+B+C+D+E]

3 9.3 6.13 12.9 24.7 61 3.1 43.0 0.904 Table 6 : Composition of the total oxygenic species in feed gas 3 (feed in %) :

Table 7 : Feed 3 (dry exit gas composition excluding

CH 4 , CO, C0 2 , N 2 , C 2 H 4 , C 2 H 6 , C 3 H 6 , and C 3 H 8 ) :

Feed 3 illustrates that reduction of the oxygenic species takes place at the process conditions provided in 2.b. us ¬ ing the catalyst of 2. a. Phenol and p-cresol are converted to benzene and toluene, some toluene dealkylation to ben ¬ zene also appears to take place.