This disclosure relates to installed synthesis gas (Syngas) production units and potential modifications to those units to reduce the fuel firing requirements and proportionate reduction in CO2 emissions from those units with minimum hardware changes, and low capital expenditures providing economically attractive payout.
Reducing greenhouse gas emissions is rapidly becoming a necessity in every major industrial sector. The CO2 emissions form the major part of greenhouse gases. This disclosure is mainly related to reducing the fuel firing and CO2 emissions in the primary reformers and the direct fired reaction furnaces for producing synthesis gas (Syngas) used for the production of various chemicals including ammonia, methanol, hydrogen, ethylene, propylene, refined products and other petrochemicals. The embodiments presented in the disclosure are specific to the reforming sections in ammonia production facilities.
To produce Ammonia, the first step is to convert the feed gas mixed with steam along with a small amount of hydrogen (called Mixed Feed) into Synthesis gas (a mixture of mostly CO & H2) via an endothermic reforming reaction (CH4+H2O═CO+3H2) using catalyst. The reforming in Ammonia plants is carried out in two steps using a primary reformer followed by a secondary reformer operated at a high pressure and temperature. The primary reformer is a tubular reactor and is directly fired with fuel gas to provide the heat of the endothermic reaction and is the major energy consumer and CO2 emitter in ammonia plants. The secondary reformer is a fixed catalytic bed which performs additional reforming of the effluent from the Primary Reformer using the preheated process air. The oxygen molecule in the process air is completely combusted to provide the heat of the endothermic reaction and the nitrogen molecule in the air provides the needed nitrogen to later synthesize the mixture of hydrogen and nitrogen in the Synthesis section with an overall reaction as 0.88 CH4+1.26 Air+1.24 H2O=0.88 CO2+2NH3.
There are a number of technologies available to produce synthesis gas or syngas. Steam methane reforming is the most common. But there are a number of hydrocarbons other than methane that can be used in this process. These light hydrocarbon feedstocks and steam are converted in an endothermic reaction over a nickel catalyst. Heat to the reaction is provided in a radiant furnace.
Steam reforming of natural gas and other hydrocarbons produces synthesis gases that can be used to produce ammonia, methanol, hydrogen, OXO-syngas, and other chemicals.
The light hydrocarbon—steam reforming process can be described by two main reactions:
CH4+H2O═CO+3H2 ΔH=198 kJ/mol (1)
CO+H2O═CO2+3H2 ΔH=−41 kJ/mol (2)
The first reaction is reforming itself, while the second is the water-gas shift reaction. Since the overall reaction is endothermic, some heat input is required. This is accomplished by combustion of natural gas or other fuels in the direct-fired furnace of the primary reformer. Reaction (1) favors high temperature and low pressure, and proceeds usually in the presence of a nickel-based catalyst.
Depending on the required composition of the syngas and its end use, the reforming section may include a primary reformer, secondary or autothermal reformer, pre-reformer, or a pre-convective reformer.
There is a large global installed base of synthesis gas production based on steam reforming of light hydrocarbons. They are characterized by high investment requirements and significant emissions of CO2. Environmental concerns have led to an increased interest to upgrading these units to reduce CO2 emissions while doing it while saving capital investment.
Upgrading these production units, provided by different companies requires novel techniques of integrating equipment into different existing processes and this disclosure proposes several embodiments for doing this based on minimizing capital expenditures while reducing both firing and CO2 emissions.
To reduce the firing and the CO2 emissions from the combustion in the Primary Reformers in Ammonia plants, a combination of the following different options were studied.
The last three options for complete ammonia plants are still not economically viable. The ammonia industry has taken a small step with incremental reduction in CO2 emissions using a very expensive hydrogen sourced via electrolysis for existing Ammonia plants. A partial carbon capture from the flue gas of Primary Reformers has only been implemented in a handful of chemical plants, mostly where CO2 was used as a feedstock for the neighboring units.
The primary reformer is a direct fired tubular catalytic reactor. The firing provides the heat for the reforming reactions is typically carried at high pressure (10-700 psig) and high temperature (650-1700 F). The hot flue gases from the reaction chamber (radiant section) are routed to a convection section for heat recovery using heat transfer coils for various services including the preheating of the combustion air with a combustion air preheater.
The newly proposed embodiments of this disclosure are primarily to reduce the fuel firing and CO2 emissions from the primary reformers and direct fired furnaces. The reduction in CO2 emissions achieved is the same or higher than some of the current systems using an electrolysis process, or using an equivalent amount of carbon capture from the flue gases without accounting the cost of the sequestration (CCS), but at a much lower CAPEX and OPEX. For the purpose of the comparison, the size of the electrolysis system is based on the required amount of hydrogen addition to an existing ammonia plant to reduce the CO2 emissions to the same level. The CCS size basis also used the degree of reduction in the CO2 emissions.”
What is needed are approaches that can be applied to various existing syngas units which lower the firing rate on the reformers and reduce the CO2 emissions from the overall process at acceptable capital expenditures.
This need is met by the disclosure of nine novel modifications or additions as described in this disclosure to existing or new production processes using a combination of measures to reduce the process duty of reforming to both reduce fuel firing and CO2 emissions.
The novel modifications of this disclosure are shown and described in nine different embodiments (in
In the following detailed description, some temperatures and pressures are presented to provide insight. These values can vary depending on the particular installed version of synthesis gas production and the relative size and design capability of the equipment. These temperatures and pressures should not be construed as limitations in this application.
Referring first to
Depending on the required composition of the syngas and its end use, the reforming section may have a suitable combination to include a primary reformer, secondary or autothermal reformer, pre-reformer, and a pre-convective reformer. This prior art example features a primary reformer, and a secondary reformer only.
The primary reformer is a direct fired tubular catalytic reactor and is the major source of CO2 emissions in syngas production facilities. A multitude of alloyed radiant tubes 30 filled with catalyst are used for the reforming reaction. These tubes are usually placed vertically within a refractory lined radiant section 15 as shown in
The endothermic heat for the reforming reaction is provided by the direct firing of a fuel (not shown) through a set of burners 35 in the Radiant section of the Primary reformer. The fuel is a mix of mostly natural gas along with the purge gases available from the synthesis loop as well as small quantities of other purge streams from other unit operations within an ammonia plant. The burners 35 are supplied with fuel (not shown) and the combustion air either at the ambient or preheated conditions.
The major source of heat transfer in the radiant section is via radiant heat from the burner flames within the radiant section 15 to the preheated mixed feed 40 (a mixture of the feed gas, hydrogen and steam) flowing down through the catalyst tubes. The combustion air to the burners is normally preheated by an air preheater 45 installed in the convection section of the Primary Reformer. The location and the firing arrangement of the burners varies in different reformer designs and can be down-fired, side-fired, terrace-wall fired or bottom-up fired.
The flue gases leaving the radiant section is at a very high temperature (ranging between 1700 deg F. to 2200 deg F.) and are routed to the adjoining convection section 50 for heat recovery by preheating different process streams including the mixed feed in 55, process air for the secondary reformer in 60, steam superheating, feed preheating, boiler feedwater, steam generation, combustion air preheating etc. These are heated by passing them through a number of convection coils located in the convection section 50. There are various different arrangements of the convection section being horizontal or vertically upward and vertically downward along with an integrated auxiliary firing. The number and sequence of the different convection coils will differ in different primary reformer designs. However, mixed feed preheating 55, process air preheating 60, and the combustion air preheating 45 coils are common in most of the primary reformers used in ammonia plants. The Mixed Feed coil in some of the convection sections of the Reformer can be segmented as two or more sets of the coils and are usually referred as ‘Cold Leg’ and ‘Hot Leg’ of the Mixed feed coil. Similarly, the Process Air coil in some of the convection sections of the Reformer can be segmented as two or more sets of the coils and are usually referred as ‘Cold Leg’ an ‘Hot Leg’ of the Process Air coil. Additional possible coils are indicated as 65
The mixture of the clean feed gas and steam (referred as ‘mixed feed’ 40) is preheated in the convection coil 55 before routing to the catalyst tubes 30 in the radiant section of the primary reformer. The process air compressor (PAC) 25 supplies the compressed process air which is first preheated in convection coils 60 before routing to the secondary reformer.
A partially reformed gas mixture 70 leaves the primary reformer tubes at a high temperature and is routed to the secondary reformer for additional reforming and balancing of the H2/N2 ratio using the preheated process air coming from the convection coils 60 of the primary reformer. The outlet system arrangement from the primary reformer tubes to the secondary reformer varies depending on the design of the primary and secondary reformers and can use internal hot risers within the primary reformer and connected via an external transfer line to the bottom or top of the secondary reformer or cold or hot outlet manifolds connected via an external bottom transfer line to the bottom of the secondary reformer. The secondary reformer often uses a nickel-based catalyst bed 20 to accomplish the secondary reforming. The resulting Syngas from the secondary reformer leaves at a high temperature for further heat recovery and processing. The final flue gas exits the primary reformer through an Induced Draft (ID) fan exhausting the flue gas up the stack 75.
This disclosure describes nine embodiments that are aimed at reducing the incremental firing and CO2 emissions from the reforming furnaces. They are illustrated in
Referring now to
An increase in the preheat of the combustion air provides the following benefits as listed below.
An estimated reduction in the CO2 emissions with embodiment 1 (
For a similar reduction in CO2 emissions, embodiment 1 of
It is important to note that this approach of using an electrical heater to the preheating of combustion air also can lead to important improvements in a number of other important industrial processes such as steam cracking of saturated hydrocarbons, charge heaters of propane dehydrogenation (PDH) units, Primary Reformers in Methanol and Hydrogen plants, and the refinery heaters.
Referring next to
With a reduced process heat demand in the radiant tubes, the fuel firing in the radiant section of the primary reformer is also reduced with reduced CO2 emissions. This combination will also reduce the process side pressure drop of the mixed feed preheat coil depending on the reconfiguration of the two coils. The mixed feed may be preheated with or without splitting its flow between the mixed feed coil and the process air coil along with a suitable flow bypass across the process air coil depending on the operating conditions, convection coils configurations and any other constraints in primary reformer.
Since the process air preheat coil in the convection section is now used for additional preheating of the mixed feed, the process air preheating is carried out externally with an electric heater 80. The electric heater permits further raising the temperature of the process air temperature (up to 1200 deg F.) and with a much-reduced pressure drop on the process air side. Note that a part of the combustion air may be bypassed around the air preheater 45 installed in the convection section of the Primary Reformer depending on pressure drop and operating conditions.
The combination of increased preheat of both the mixed feed stream and the process air stream along with reduced pressure drop provides the following benefits as listed below.
An estimated reduction in the CO2 emissions is up to 6% of the base operating level along with the above listed advantages.
For a similar reduction in CO2 emissions, the embodiment of
Referring now to
An estimated reduction in the CO2 emissions will be up to 12% of the base operating level.
For a similar reduction in CO2 emissions, embodiment 3 needs less than 45% of the investment and the operating cost of the Electrolysis Hydrogen option with a much shorter project time frame to implement it. Also, the investment of the embodiment of
And as discussed in embodiment 2 the approach of embodiment 3 would have important contributions in a number of other important industrial processes such as steam cracking of saturated hydrocarbons, charge heaters of propane dehydrogenation (PDH) units, Primary Reformers in Methanol and Hydrogen plants, and refinery heaters.
Referring now to
Typically, with a pre-reformer in the scheme, the process steam is usually split before and after the pre-reformer as shown in
The feed gas into the pre-reforming section can be a mixture of various hydrocarbons and is always pretreated to remove potential catalyst poisons such a sulfur compounds or any other impurities. Hence often referred to as desulfurized feed gas. Then as shown some process steam is suitably added and the mixed feed is fed through a heat exchanger 135 and then heated electrically 145 (up to 1050 deg F.) and fed into the pre-reformer and through the catalyst bed 125. The partially reformed gas then is added with the balance of the process steam and passes through the convection coils 55 in the convection section before being fed through the radiant catalyst tubes 30 of the primary reformer. Note that a part of the combustion air may be bypassed around the air preheater 45 installed in the convection section of the Primary Reformer depending on pressure drop and operating conditions.
The combination of the pre-reformer along with increased preheat of both the mixed feed stream to primary reformer and the process air stream to the secondary reformer along with the reduced pressure drop provides the following benefits as listed below.
An estimated reduction in the CO2 emissions is up to 12% of the base operating level along with the above listed advantages
For a similar reduction in CO2 emissions, embodiment 4 of
As mentioned before, pre-reforming is well known and has already been commercially applied in the reforming applications. However, what is new and novel here is a combination of the pre-reforming reactor with electric heating of the feed of the pre-reformer and reuse of the process air coil for preheating the mixed feed for a maximum reduction in the firing and the associated CO2 emissions from the primary reformer with minimum changes in the convection section to reduce the important plant turnaround time for its installation.
There are four additional embodiments to follow that all include the use of a pre-reformer in the mix and an additional embodiment with the use of external add-on heaters. These multiple embodiments in all of this disclosure are presented because the suitability of each of these embodiments will depend on the operating and the design conditions of the primary reformer, therefore different solutions or embodiments may be called for.
These additional pre-reformer embodiments using different applications of use of a pre-reformer described briefly in the Brief Description of the Drawings for
An estimated reduction in the CO2 emissions is up to 12% of the base operating level along with the above listed advantages
For a similar reduction in CO2 emissions, the supplementary invention disclosure of
The investment and the operating cost of these supplementary embodiments (in
Referring now to
In addition this embodiment includes the features of embodiment 2 (
Again, as in
Referring now to
Referring now to
Referring now to
Referring now to
An optional addition of electric heater 85 in the preheated combustion air stream coming out of the Air Preheater as also shown in embodiment 1 (
The electric heaters can be added in both the mixed feed stream and the process air stream or only one of them depending on the configuration and operating conditions of the Primary Reformer. The suitability of adding an electric heater for additional preheating of the combustion air is optional and may be added based on the site-specific design and operating conditions of the Primary Reformer. The electric heaters can be separate devices for each of the streams to be preheated or they may be combined in a common single enclosure.
The electric heaters can be separate devices for each of the streams to be preheated or they may be combined in a common single enclosure for space and cost savings.
The various embodiments presented in this disclosure represent a significant step forward in the novelty of methods and apparatus that contribute to reducing the firing and carbon dioxide emissions in installed or new synthesis gas production units. Some of the contributions include:
The present invention has been described with reference to specific details of particular embodiments. It is not intended that such details be regarded as limitations upon the scope of the invention except insofar as and to the extent that they are included in the eventual presented claims.
This application claims the benefit of U.S. Provisional application 63/165,172 filed Mar. 24, 2021. The aforementioned patent application is hereby incorporated by reference in its entirety into the present application to the extent consistent with the present application.
Number | Date | Country | |
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63165172 | Mar 2021 | US |