Patent Application
20070151155
The present invention relates to a method of producing synthesis gas by partial oxidation of a carbonaceous stream.
Methods for producing synthesis gas by partial oxidation are well known in practice.
Generally, a (hydro)carbonaceous stream such as coal, brown coal, peat, wood, coke, soot, or other gaseous, liquid or solid fuel or mixture thereof, is partially combusted in a gasification reactor (or otherwise partially oxidised) using an oxygen containing gas such as substantially pure oxygen or (optionally oxygen-enriched) air or the like, thereby obtaining a product stream containing a.o. synthesis gas (i.e. CO and H2) and CO2.
The product stream is usually further processed, e.g. to cool the product stream in a quench section and to remove undesired components. Also, the product stream may be subjected to shift conversion, wet gas scrubbing and the like, depending on the end use of the product stream or parts thereof.
In the known method of producing synthesis gas, the quality of the product stream obtained may vary, due to e.g. disturbances or variations in the carbonaceous stream and the oxygen containing stream being fed to the gasification reactor, the amount of ash in the carbonaceous stream, etc. If for example coal is used as the carbonaceous stream, variations in H2O content of the coal may result in altered process conditions in the gasification reactor, as a result of which the composition of the product stream will also vary. Various methods of controlling a partial oxidation process are known. For example GB-A-837074 describes a process wherein the carbon dioxide in the product gas of a partial oxidation process is measured to control the steam flow.
U.S. Pat. No. 2,941,877 describes a process for controlling the oxygen-to-carbon feed ratio in a partial oxidation reactor. The oxygen-to-carbon feed ratio is controlled by measuring the methane concentration in the product gas using infrared measurement technique. A disadvantage of using methane as the control input is that the signal is not a sharp signal, making control less accurate.
The quality variation mentioned above may be even more pertinent if the end user of (parts of) the product stream desires a constant quality with only very limited variations therein.
In one aspect, the present invention provides a method of producing synthesis gas by partial oxidation of a carbonaceous stream, wherein the partial oxidation is controlled using an oxygen to carbon ratio (O/C ratio), the method comprising at least the steps of:
In another aspect the present invention provides a system for producing synthesis gas by partial oxidation of a carbonaceous stream, the system at least comprising:
wherein the quality controller is functionally coupled with the first and second flow controllers and wherein the quality controller can adjust the flow rates in the first and second flow controllers, based on the difference value.
Such a system may be suitable for suitable for performing the method according to the first aspect of the invention, preferably according to one or more embodiments of the invention.
The invention will now be described by way of example in more detail with reference to the accompanying non-limiting drawing.
In the accompanying drawing,
For the purpose of this description, a single reference number will be assigned to a line as well as a stream carried in that line. Same reference numbers refer to similar structural elements.
It has been surprisingly found that by controlling the oxygen to carbon ratio (O/C ratio) on basis of the content of CO2 in a synthesis gas product stream, process conditions in a gasification reactor (such as the gasification temperature), and thereby the quality of the product stream, may be controlled in a very simple manner.
Applicants further found that the content of CO2 in the product stream gives a sharp signal as compared to the signal of CH4 as measured by infrared, making it more suited to control this process. Applicants further found that controlling the C/O ratio is much more efficient than controlling the steam flow in order to achieve a product stream having a constant quality with only very limited variations therein.
The carbonaceous stream may be any suitable liquid, gaseous or solid stream (including slurries) suitable to be partially oxidised thereby obtaining a synthesis gas containing product stream. The term ‘carbonaceous’ is meant to also include ‘hydrocarbonaceous’. It has been found that methods provided by the present invention may be especially suitable if as a carbonaceous stream preferably a solid, particulate, high carbon containing feedstock is used. A preferred feed is a solid carbonaceous feed. Examples of such feeds are coal, biomass, for example wood and waste, preferably coal. More preferably the solid carbonaceous feed is substantially, i.e. >90 wt. %, comprised of naturally occurring coal or synthetic (petroleum)cokes. Suitable coals include lignite, bituminous coal, sub-bituminous coal, anthracite coal, and brown coal. The solid carbonaceous feed may be fed to the process as a slurry in water, or, more preferably, as a mixture of the feed and a suitable carrier gas. A suitable carrier gas is nitrogen.
As oxygen containing stream any suitable stream may be used. Usually substantially pure oxygen (e.g. obtained using an Air Separation Unit) will be used. However, also air or oxygen-enriched air may be used.
The person skilled in the art will readily understand how to select the desired selected O/C ratio for a specific carbonaceous stream to be fed in step (a). In the present specification and claims, the O/C ratio has the following meaning, wherein ‘O’ is the weight flow of molecular oxygen, O2, as present in the oxygen containing stream and wherein ‘C’ is the weight flow of the carbonaceous feed excluding any optional carrier gas or water, in case of a slurry. The desired selected O/C ratio may e.g. be determined using known energy content data for a specific carbonaceous stream such as the heating value of the feedstock in J/kg. Usually, having determined the desired selected O/C ratio, the O2 content in the oxygen containing stream will be determined and the suitable flow rates for the carbonaceous and oxygen containing feed streams will be established to obtain the desired O/C ratio.
The content of CO2 may be determined by means of infrared, although other measurement techniques can also be used. The content of CO2 is preferably measured in the gas stream as close to the partial oxidation step as possible for obvious control reasons. Nevertheless applicants found that the process can still be effectively controlled when the CO2 content is measured downstream of a water gas scrubber. This can be advantageous because the scrubbed gas will contain fewer acids making the analysis simpler. Also the person skilled in the art will understand how the determining of the content in step (c) can be done; therefore this will not be further discussed here.
The comparing of the content of the product stream with the pre-determined content may be done by hand. However, normally e.g. a suitable computer program will be used. The pre-determined content usually corresponds to the content of the expected product composition (or an expected content of one or more components thereof) that would have been obtained on basis of the selected O/C ratio if no variations or disturbances would occur. If a difference exists (i.e. the difference value) between the actual content of the product stream and the pre-determined content, then the O/C ratio is adjusted to some extent e.g. by adjusting the flow rates of the feed streams. As a result of the adjusting of the O/C ratio, the process conditions will be changed (and the steps (c) to (e) repeated) until the actual content obtains a desired value.
The person skilled in the art will understand that, if desired, the O/C ratio will only be adjusted if the difference value is above a pre-selected value. Further, the adjustment of the O/C ratio will depend on to what extent the product stream composition deviates from the pre-determined composition.
It has been contemplated that the CO2 content in the product stream content are especially suitable for comparison purposes. Thus, preferably the difference value obtained in step (c) is obtained on the basis of a comparison between the content of CO2 in the product stream and the pre-determined content for CO2.
If a difference value occurs (optionally above a preset value), the O/C ratio may be adjusted in step (e) by adjusting the flow rate of one of the carbonaceous stream and the oxygen containing stream fed in step (a) or a combination thereof. Preferably the carbonaceous stream is adjusted in step (e), while keeping the oxygen stream constant.
Reference is made to
The carbonaceous stream 20 is at least partially oxidised in the gasification reactor 2, thereby obtaining a gaseous product stream 30, typically comprising synthesis gas (i.e. CO+H2), CO2 and CH4. To this end usually several burners (not shown) are present in the gasification reactor 2. As coal is used as the carbonaceous stream 20, also a slag is formed which is removed via line 50 for further processing.
Usually, the partial oxidation in the gasification reactor 2 may be carried out at a temperature in the range from about 1200 to about 1800° C. and at a pressure in the range from about 1 to about 200 bar, typically at about 40 bar.
As shown in the embodiment of
The person skilled in the art will readily understand that the product stream 30 leaving the quenching section 6 may be further processed. To this end, it may be fed into e.g. a dry solids removal unit (not shown), a wet gas scrubber (not shown), to a shift converter (not shown), etc.
The product stream 30 containing the synthesis gas leaving the quenching section 6, and optionally leaving a further downstream wet gas scrubber, is fed to a quality controller 9, in which the content of CO2 of the product stream 30 is determined and compared with a pre-determined content of CO2. This pre-determined content of CO2 may e.g. correspond to the expected content of CO2 of product stream 30 that would have been obtained on the basis of the selected O/C ratio if no variations or disturbances would occur.
If the composition of the product stream 30 deviates from the pre-determined content of CO2, the O/C ratio of the streams 10 and 20 is adjusted thereby also affecting the process conditions in the gasification reactor 2. The person skilled in the art will understand that, if desired, the O/C ratio may only be adjusted if the deviation (i.e. the difference value) is above a pre-set value.
In order to achieve the desired adjustment of the O/C ratio of the stream 10 and 20, the quality controller 9 operates the flow controllers 7 and 8 (as indicated by the dashed lines 22 and 23) and as a result the flow rates of the streams 10 and/or 20 are adjusted accordingly. As a consequence, the process conditions (in particular the gasification temperature) in the gasification reactor 2 are altered thereby also altering the content of CO2 of the product stream 30. These adjustments of the O/C ratio may take place as long as the content of CO2 of the product stream 30 deviates from the pre-determined content of CO2.
Hereafter a non-limiting example of the method according to the invention is discussed.
Using the line-up as generally shown in
The coal and oxygen streams were fed in order to (tentatively) obtain a selected O/C ratio of about 0.713. After partially oxidising the coal stream in the gasification reactor at a temperature of about 1500° C. and a pressure of about 40 bar, a gaseous product stream was obtained. The composition of the gaseous product stream was determined and is given in Table I below (indicated as ‘actual composition’).
In the Example the content of CO2 in the product stream was measured by infrared measurement technique and compared with a (calculated) pre-determined content of CO2 in the product stream (also indicated in Table I) as a result of which a difference value between the content of CO2 in the actual composition and the pre-determined composition (in the present Example: 0.74 mol %) was obtained. The difference value was expressed as a percentage of the absolute difference between the content of CO2 in the product stream and the pre-determined CO2 content relative to the pre-determined CO2 content.
As the difference value of CO2 was deemed too high (exceeding a pre-selected value of between 0.5% and 5%, in the present Example the pre-selected value was 1%, of the predetermined content), the O/C ratio of the coal and oxygen streams fed into the gasification reactor was adjusted by amending the flow rate of the coal stream while keeping the flow rate of the oxygen stream constant. This was repeated as long as the difference value between the actual content of CO2 and the predetermined content of CO2 in the product stream was less than the pre-selected value of 1%.
It goes without saying that a pre-selected value different from 1% (such as e.g. 0.5%) may be chosen, if desired. Suitably, the pre-selected value lies between 0.5% and 5%.
(*) This result is a difference value of ˜13%, exceeding the pre-selected value of 1%.
The person skilled in the art will readily understand that the present invention may be modified in various ways without departing from the scope as defined in the claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 05112111.9 | Dec 2005 | EP | regional |
