US20100205863A1

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Publication number: US20100205863A1
Application number: US12/668,577
Authority: US
Inventors: Serge Biollaz; Tilman J. Schildhauer; Martin Seeman
Original assignee: Scherrer Paul Institut
Current assignee: Scherrer Paul Institut
Priority date: 2007-07-10
Filing date: 2008-07-03
Publication date: 2010-08-19
Also published as: EP2167617A1; CN101802146A; WO2009007061A1; CA2693459A1

Abstract

A method for converting a raw gas into a methane-rich and/or hydrogen-rich gas includes the following steps: a) providing the raw gas stemming from a coal and/or biomass gasification process, thereby the raw gas comprising beside a methane and hydrogen content carbon monoxide, carbon dioxide, alkanes, alkenes, alkynes, tar, especially benzole and naphthalene, COS, hydrogen sulfide and organic sulfur compounds, especially thiophenes; thereby the ratio of hydrogen to carbon monoxide ranges from 0.3 to 4; b) bringing this raw gas into contact with a catalyst in a fluidized bed reactor at temperatures above 200° C. and at pressures equal or greater than 1 bar in order to convert the raw gas into a first product gas, thereby simultaneously converting organic sulfur components into hydrogen sulfide, reform tars, generate water/gas shift reaction and generate methane from the hydrogen/carbon monoxide content; c) bringing the first product gas into a sulfur absorption process to generate a second product gas, thereby reducing the content of hydrogen sulfur and COS from 100 to 1000 ppm down to 1000 ppb or less; d) optionally bringing the second product gas into a carbon dioxide removal process to generate a third product gas at least almost free of carbon dioxide; e) bringing the third product gas into a second methanation process to generate a fourth product gas having a methane content above 5 vol %; f) optionally bringing the fourth product gas into a carbon dioxide removal process to generate a fifth product gas at least almost free of carbon dioxide g) bringing the fifth product gas into an hydrogen separation process in order to separate a hydrogen rich gas from a remaining methane-rich gas, called substitute natural gas.

Description

The present invention relates to a method for converting coal or biomass to at least almost sulfur-free substitute natural gas. Further, the invention relates to a process to produce a methane rich gas mixture from gasification derived sulphur containing synthesis gases.
In particular, the present invention relates to a continuous production process of synthetic natural gas (SNG) from biomass, coal or naphta. More specifically, the present invention relates to the production of clean gaseous heating fuels from these less valuable sulphur containing hydrocarbonaceous materials.

DESCRIPTION OF THE PRIOR ART

The production of SNG from biomass is the conversion of a “dirty/difficult” fuel into a clean burning well known commodity. The costumer has the freedom to use the SNG for power generation, heating or mobility. A big plus is the already existing infrastructure such as pipelines and compressed natural gas (NG) cars. To insert the product gas of the methanation into the grid it has to be cleaned of CO₂and compressed to 5 to 70 bars to meet the standards of average natural gas.

The conversion of biomass to SNG is a complex process, which can be structured roughly into four main units; gasification, raw gas cleaning, fuel synthesis and gas sweetening. A solid feed is thermally converted to a raw gas and subsequently cleaned of particles, tars and sulphur. In the fuel synthesis, the raw gas is converted into raw SNG (a CH₄/CO₂mixture) that is cleaned from CO₂and optionally H₂(gas sweetening) before injection into the natural gas grid.

The presence of sulphur in the feedstocks leads to the formation of H₂S, COS or organic sulphur species, depending on the temperature of the gasification. Low temperature (LT) gasification promotes the formation of organic sulphur species such like thiophenes, mercaptanes and thio-ethers, whereas high temperature (HT) gasification leads to the formation of exclusively H₂S and COS.

The typical raw gas composition of HT and LT gasification is shown in table 1.

	TABLE 1

	Low Temperature gasification	High Temperature
	(600-1000° C.)	gasification (1000-2000° C.)

	H₂, CO, CO₂, H₂O	H₂, CO, CO₂, H₂O
	CH₄	a few ppm
	alkanes, alkenes, alkynes	nil
	(especially ethylene)
	Tars (Naphtalene, . . . )	nil
	H₂S, COS	H₂S, COS
	Org. S-species (mercaptanes, thio-	nil
	ethers, thiophenes
	HCN, NH₃	HCN, NH₃
	Org. N-species (e.g. pyridine)	nil

For the synthesis of SNG, LT-gasification is advantageous (higher overall cold-gas efficiency), as the raw gas contains already substantial amounts of CH₄. Drawbacks of this kind of raw gas are the high amount of poisonous components, such as alkenes, alkynes, H₂S, COS, organic S-species, HCN, NH₃, organic N-species.

For that reason, an efficient gas cleaning is required to protect the catalysts applied in the fuel synthesis. An example of a state of the art to produce synthesis gas for applications such as Fischer-Tropsch-Synthesis or production of Methanol, DME, and SNG is shown inFIG. 1a.

A scrubber at low temperatures is used to remove the tars and the organic S-species and N-species. H₂S, COS are absorbed on solid absorbers available for this duty (active carbon, ZnO or other metal oxides . . . ). In general, the gas cleaning is followed by a Water-Gas-Shift reactor, CO₂-seperation and multiple methanation units. To increase the calorific value of the gas to the quality limits of the gas grid, CO₂and H₂is removed. The order of units4-9 can be different.

Disadvantage of this process scheme is the high number of operation units and the different temperature levels of the units (especially cooling down to the scrubber temperature). To avoid this kind of temperature gradients in the process, the use of raw gas from a HT-gasification is common, an example of such process is shown in FIG. 1b (U.S. Pat. No. 3,928,000, EP 0,120,590). The different gas composition enables S-resistant Water-Gas-Shift (WGS) and S-resistant Methanation and lowers the amount of operation units. However, the raw gas composition is less favorable for the SNG synthesis as the SNG composition results in higher energetic losses.

First, the energetic effort in the gasification unit is higher for the production of pure H₂, CO, CO₂-mixtures; secondly the pure H₂, CO, CO₂-mixtures result in higher thermal losses in the synthesis due to the exothermic enthalpy of the methanation reaction.

DESCRIPTION OF THE INVENTION

By means of the subject process, the unfortunate temperature level sequence and the number of operation units of the process shown inFIG. 1aas well as the energetic losses of the process shown inFIG. 1bcan be avoided. A methane-rich stream can be produced from sulphur containing feedstocks containing 10 to 95 mol % of methane.

The first step following the Low-Temperature-gasification is a multifunctional process unit featuring hydrodesulphurization/denitrogenation, methanation, WGS, tar reforming and cracking and the hydrogenation/reforming of alkenes and alkynes simultaneously. The H₂S produced from the organic sulphur species by hydrolysis and the COS are removed by absorption on common absorber materials such like ZnO, CuO. CO₂can be removed before or after the 2^ndmethanation step. For the adjustment of the calorific value excess H₂is separated and may be recycled tounit2.

The hydrodesulphurization unit (HDS) is a common process step for the desulphurisation of feedstocks in the petrochemical industry or of natural gas before steam reforming. The applied catalysts for these units tend to catalyse both methanation and watergas shift reaction which is unwanted as these exothermic reactions may lead to a thermal runaway of the reactor. In the subject process, however, the methanation and WGS-reactions are desired.

To control the temperature rise due to exothermic reactions, a fluidised bed reactor equipped with means for heat removal can be applied. The catalyst fluidisation offers additionally the potential for internal regeneration of the catalyst from carbon deposits caused by compounds like ethylene or tars in the LT-gasifier producer gas. Such an internal regeneration can be found for fluidised bed methanation and can be enhanced by staged addition of recycle H₂and/or steam in the upper part of the fluidised bed.

Moreover, the raw gas stream leaving the unit can be tailored to the requirements of a 2^ndmethanation unit to minimise the total number of process units by the addition of steam, H₂from the recycle and the proper choice of temperature and pressure. alkenes and alkynes simultaneously. The H₂S produced from the organic sulphur species by hydrolysis and the COS are removed by absorption on common absorber materials such like ZnO, CuO. CO₂can be removed before or after the 2^ndmethanation step. For the adjustment of the calorific value excess H₂is separated and may be recycled tounit2.

Moreover, the raw gas stream leaving the unit can be tailored to the requirements of a 2^ndmethanation unit to minimise the total number of process units by the addition of steam, H₂from the recycle and the proper choice of temperature and pressure.