REFORMING PROCESS INTEGRATED WITH GAS TURBINE GENERATOR

Abstract

A reforming process comprising for production of a hydrogen-containing synthesis gas with a thermally integrated gas turbine engine wherein the hot exhaust gas of the gas turbine engine is the heat source for preheating one or more process streams of the reforming process.

Claims

1-21. (canceled)

22. A process, comprising: reforming a hydrocarbon-containing gas to obtain a hydrogen-containing synthesis gas; producing mechanical power with a gas turbine engine; preheating at least one process stream of the reforming process, wherein: a heat source of the preheating includes exhaust gas of the gas turbine engine; the preheating includes a heat transfer from the exhaust gas to the process stream and the heat transfer is performed in an indirect heat exchanger wherein the exhaust gas and the process stream do not mix; wherein the step of preheating at least one process stream of the reforming process includes at least one of: a) preheating a hydrocarbon-containing gas prior to reforming of the hydrocarbon-containing gas in a reformer; b) preheating a hydrocarbon-containing gas prior to pre-reforming of the hydrocarbon-containing gas in a pre-reformer; or c) preheating a hydrocarbon-containing gas directed to a reforming process prior to removal of sulphur from the hydrocarbon-containing gas.

23. The process of claim 22, wherein the gas turbine engine operates with a simple cycle where no heat from the exhaust gas of the gas turbine engine is used in a heat recovery steam generator to produce steam for a steam turbine.

24. The process of claim 22, wherein the heat exhaust gas traverses a first side of the indirect heat exchanger and the process fluid traverses a second side of the heat exchanger, and heat is transferred from the exhaust gas to the process fluid while they traverse the first side and second side of the heat exchangers.

25. The process of claim 22 wherein exhaust gas from the gas turbine engine transfers heat to preheating processes according to two or more of the options a) to c); or in a sequence according to the order a) to c), so that the exhaust gas effluent of one preheating process of the sequence is used as heat source for the subsequent process of the sequence, in accordance with the order.

26. The process of claim 25, further comprising: a first preheating process according to option a) wherein exhaust gas from the gas turbine engine transfers heat to a hydrocarbon gas prior to reforming; a second preheating process according to option b) wherein exhaust gas cooled after the first preheating process transfers heat to a hydrocarbon gas prior to a pre-reforming; a third preheating process according to step c) wherein exhaust gas further cooled after the second preheating process transfers heat to a hydrocarbon gas prior to a desulphurization process.

27. The process of claim 26 wherein the full amount of heat transferred to the hydrocarbon gas in each of the preheating processes according to a), b) and c) is provided by the exhaust gas of the steam turbine.

28. The process of claim 26, further comprising a process of pre-heating of a boiler feed water which is in parallel to the third preheating process of option c) and wherein the exhaust gas from the second pre-heating process of option b) is split between the third pre-heating process and the parallel pre-heating of boiler feed water.

29. The process of claim 22, further comprising steam superheating with exhaust gas as heat source, the steam superheating being performed first in the sequence.

30. The process of claim 22, further comprising a post-firing of the exhaust gas prior to one or more pre-heating process, the post-firing being performed by mixing the exhaust gas with a CO.sub.2-depleted hydrogen-containing gas generated in the process.

31. The process of claim 22, further comprising firing the gas turbine engine with a fuel gas including a CO.sub.2-depleted hydrogen-containing gas generated in the process, optionally mixed with natural gas.

32. The process of claim 22, further comprising using the hydrogen-containing gas as a makeup gas for the synthesis of ammonia optionally after addition of nitrogen.

33. The process of claim 22, further comprising a post-firing of exhaust gas of the gas turbine engine wherein the fuel of the gas turbine engine and the fuel used to post-fire the exhaust gas is a hydrogen-containing gas produced internally in the process and contain no more than 10% of carbon and preferably no more than 5% of carbon.

34. The process of claim 22 wherein: reforming is performed by pure autothermal reforming with low steam to carbon ratio, possibly with pre-reforming in an adiabatic reactor, but without a previous primary reforming in a furnace with a radiant section including tubes filled with catalyst; superheated steam is generated by cooling the hot effluent of the autothermal reforming, prior to removal of carbon dioxide; after removal of carbon dioxide the reformed gas is further purified by cryogenic condensation and removal of methane followed by liquid nitrogen wash to remove inerts.

35. The process of claim 34 wherein the step of autothermal reforming is performed at a steam to carbon ratio of no more than 2.0.

36. The process of claim 22 wherein at least some of the carbon dioxide removed from the reformed gas is compressed at a high pressure above 100 bar and in a range 150 to 200 bar, and the so obtained high-pressure carbon dioxide is stored under pressure for carbon capture or used for enhanced oil recovery or for the synthesis of urea.

37. The process of claim 36 wherein high-pressure carbon dioxide is used for enhanced oil recovery, wherein the carbon dioxide is liquified, rectified and recompressed for use in the enhanced oil recovery, wherein heat from the exhaust of the gas turbine is used to provide energy input of the rectification of the CO.sub.2.

38. The process of claim 22, further comprising producing electrical energy with a generator coupled to the gas turbine engine.

39. The process of claim 22 wherein the reformer includes an autothermal reformer (ATR).

40. A plant for producing a hydrogen-containing gas, the plant comprising: a reforming section arranged to reform a hydrocarbon source to obtain a hydrogen-containing gas; a gas turbine engine which is integrated in the process; at least one pre-heater configured as an indirect heat exchanger having a first side and a second side, arranged to preheat at least one process fluid of the reforming process using exhaust gas of the gas turbine engine as a heat source, wherein: the first side is traversed by exhaust gas of the gas turbine, optionally after a post-firing; the second side is traversed by a process fluid of the reforming process which is any of: a) a hydrocarbon-containing gas prior to admission in reformer for a step of reforming; b) a hydrocarbon-containing gas prior to admission in a pre-reformer for a pre-reforming step; c) a hydrocarbon-containing gas prior to admission in a desulphurizator for removal of sulphur from a feed of the reforming section.

41. The plant of claim 40, further comprising a heat recovery steam generator or a heat storage block for recovering heat from the exhaust gas of the gas turbine engine use during startup of the plant, and a bypass line arranged to provide that the exhaust gas of the gas turbine engine can bypass the heat recovery steam generator or a heat storage block after startup is completed and during normal operation.

42. The plant of claim 40, further comprising no auxiliary boiler for providing heat for any of the preheating processes according to options a), b) or c).

43. The plant of claim 40, wherein the gas turbine engine is arranged in a simple cycle and is not coupled with a heat recovery steam generator and steam turbine for production of electricity.

44. The plant of claim 40, wherein the plant is a front-end of an ammonia synthesis plant for production of ammonia make-up gas.

45. The plant of claim 40, wherein the reformer includes autothermal reformer.

Description

DESCRIPTION OF FIGURES

[0057] FIG. 1 is a block diagram showing a gas turbine engine thermally integrated with a process for generation of hydrogen-containing synthesis gas, according to an embodiment.

[0058] FIG. 2 is a block diagram of a variant of the embodiment of FIG. 1.

[0059] FIG. 3 is a block diagram of another variant of the embodiment of FIG. 1.

DETAILED DESCRIPTION

[0060] FIG. 1 illustrates the following items: [0061] 100 Gas turbine generator [0062] 101 Compressor [0063] 102 Combustor [0064] 103 Turbine [0065] 104 Generator [0066] 105 Air feed [0067] 106 Natural gas [0068] 107 CO.sub.2-depleted synthesis gas [0069] 108 Firing portion of the CO.sub.2-depleted synthesis gas [0070] 109 Post-firing portion of the CO.sub.2-depleted synthesis gas [0071] 110 Exhaust gas [0072] 111 Exhaust gas after post-firing [0073] 112 Exhaust gas effluent from steam superheater [0074] 113 Exhaust gas effluent from ATR pre-heater [0075] 114 Exhaust gas effluent from prereformer preheater [0076] 115 Exhaust gas for HDS preheater [0077] 116 Exhaust gas for BFW preheater [0078] 117 Exhaust gas effluent after HDS and BFW preheaters [0079] 118 Chimney [0080] 200 Hydrocarbon gas [0081] 201 HDS preheater [0082] 202 HDS unit [0083] 203 Pre-reformer preheater [0084] 204 Pre-reformer [0085] 205 ATR preheater [0086] 206 ATR [0087] 207 Purification stage [0088] 208 Steam superheater [0089] 209 Boiler feed water (BFW) preheater [0090] 210 Hydrogen-containing gas [0091] 211 CO.sub.2 stream [0092] 220 Preheated hydrocarbon gas [0093] 221 Desulphurized gas [0094] 222 Feed to the pre-reformer 204 [0095] 223 Pre-reformed gas [0096] 224 Feed to the ATR 206 [0097] 225 Reformed gas effluent from the ATR 206

[0098] The block diagram of FIG. 1 illustrates a process where basically the hydrocarbon-containing gas 200 is converted into the reformed gas 210. The input gas 200 after preheating is treated in the HDS unit 202 to remove suphur. The so obtained desulphurized gas is subject to pre-reforming in the pre-reformer 204 and the so obtained pre-reformed gas is subject to autothermal reforming in the ATR 206. The pre-reforming and the autothermal reforming are preceded by a pre-heating in the heaters 203 and 205.

[0099] The output reformed gas 225 of the ATR 206 is further processed in a purification stage 207 to obtain the hydrogen-containing gas 210. The processing in the purification stage 207 includes removal of CO.sub.2 and may include e.g. shift and methanation. The processing may also include the addition of nitrogen to obtain ammonia makeup synthesis gas. The removal of CO.sub.2 generates a stream 211 of CO.sub.2 separated from the input gas.

[0100] The gas turbine generator 100 includes a gas turbine engine and a generator 104. The gas turbine engine includes a compressor 101, a combustor 102 and a turbine 103.

[0101] The gas turbine generator 100 is thermally integrated with the above described process of reforming and synthesis gas generation. Particularly, the gas turbine generator 100 is thermally integrated with a heat recovery section denoted by 120 for process pre-heating.

[0102] A CO.sub.2-depleted synthesis gas 108 obtained in the reforming process, more precisely in the purification stage, fuels the gas turbine generator 100 together with natural gas 106.

[0103] Said CO.sub.2-depleted synthesis gas 108 is a portion of a gas stream 107 withdrawn from the purification stage 207 after removal of CO.sub.2. Another portion 109 of said gas is used for post-firing as illustrated.

[0104] The fuel gas including the CO.sub.2-depleted synthesis gas 108 and the natural gas 106 meets compressed air delivered by the compressor 101 in the combustor 102; the combustion fumes expands in the gas turbine 103 which drives the generator 104; hot exhaust gas 110 are discharged by the turbine 103.

[0105] The electric energy produced by the generator 104 can be internally used by the reforming process, to power various items and auxiliaries including pumps and compressors for example. Among others, the energy produced by the generator 104 may be used for compression of the CO.sub.2 stream 211.

[0106] In a variant, the gas turbine generator 100 may be fueled entirely by the CO.sub.2-depleted gas 108, i.e. without the addition of natural gas 106 or other fuels.

[0107] As illustrated the hot exhaust gas 110 leaving the turbine 103 is subject to optional post-firing by mixing with the gas 109. Post-firing can be performed because the gas 110 contains a certain amount of oxygen and increases the temperature of the gas.

[0108] The so obtained hot exhaust gas 111 after post-firing (or the gas 110 in case of no post-firing), is the heat source of the steam superheater 208, the ATR preheater 205, the pre-reformer preheater 203, the HDS preheater 201 and the BFW preheater 209. The hot gas 111 is progressively cooled until it becomes the cooled exhaust gas 117 which is discharged via the chimney 118. The hot gas 114 effluent from the pre-reformer preheater 203 is split into a portion 115 which provides the heat source of the HDS pre-heater 201 and another portion 116 which provides the heat source of the BFW pre-heater 209. The effluents from said heaters join to form the stream 117.

[0109] It should be noted that the hot exhaust gas transfers heat to the superheater 208, the ATR preheater 205, the pre-reformer preheater 203 and the parallel of the HDS preheater 201 and the BFW preheater 209 in this order, according to the temperature required by the concerned pre-heating processes.

[0110] The above mentioned preheaters are indirect heat exchangers of a known type, for example tube heat exchangers.

[0111] With regard to the process side, the line 220 denotes the pre-heated gas fed to the HDS unit 202. The desulphurized gas 221 from said unit 202 is heated in the preheater 203 and the so obtained gas 222 is fed to the pre-reformer 204. The so obtained pre-reformed gas 223 is heated in the preheater 205 to form the feed 224 of the ATR.

[0112] FIG. 2 illustrates an embodiment where a heat recovery steam generator 130 is provided at the output of the turbine 103. The exhaust gas of the turbine can bypass said generator 130 via a bypass conduit 131. The steam generator 120 is used unit during the start-up to produce steam for the process. When the HRSG is in use during startup, the cooled gas 132 leaving the HRSG may be sent to the chimney 118. During normal operation (after the startup procedure is completed), the exhaust gas of the turbine bypasses the HRSG via the line 131 and forms the exhaust gas directed to the preheaters.

[0113] FIG. 3 illustrates another embodiment where a heat storage block 140 is provided at the output of the turbine 103. The exhaust gas of the turbine can bypass said heat storage block 140 via a bypass conduit 141. Similarly to the above described generator 120, the storage block 130 is used unit during the start-up to produce steam for the process. During normal operation, the storage block is bypassed via the line 141.

Example

[0114] The following Table 1 compares two exemplary ammonia processes of the prior art with ammonia processes according to two embodiments of the invention.

[0115] Cases [1] and [2] refer to an ammonia process integrated with a combined-cycle gas turbine generator for the production of electricity, where process heat of the reforming process is provided by one or more fired heaters. Particularly, case [1] refers to a prior-art configuration with a 100% natural gas-fired gas turbine; Case [2] refers to a prior-art configuration with a 100% CO.sub.2-depleted synthesis gas-fired gas turbine, i.e. wherein the gas turbine is fired with a portion of the CO.sub.2-depleted synthesis gas produced in the reforming process.

[0116] Cases [3] and [4] refer to embodiments of the invention with a thermally integrated simple-cycle gas turbine according to FIG. 1. Case [3] relates to a co-fired gas turbine (fired with natural gas and CO.sub.2-depleted synthesis gas) and case [4] refers to an embodiment with a natural gas-fired gas turbine.

[0117] The following advantages can be noted in Table 1:

[0118] the overall natural gas consumption of the invention, including captured CO.sub.2 compression and electric power generation, is 0.15 to 0.40 Gcal/tNH3 lower than the prior art, depending on the percentage of CO.sub.2-depleted synthesis gas used for electric power generation;

[0119] the invention reaches CO.sub.2 emissions lower than 0.2 tons of CO.sub.2 per ton of produced ammonia, as in the co-fired embodiment.

TABLE-US-00001 TABLE 1 [1] Prior [2] Prior [3] Inven- [4] Invention art NG- art H2- tion ATR ATR front- fired fired front-end + end GTG Combined Combined Integration, Integration, Cycle Cycle co-fired NG-fired Overall natural 7.38 7.49 7.25 7.08 gas consumption Gcal/t NH.sub.3 Natural gas 6.75 7.14 6.94 6.19 feed (process) Gcal/t NH.sub.3 Natural gas fuel — 0.35 — 0.29 (heat) Gcal/t NH.sub.3 Natural gas fuel 0.63 — 0.31 0.60 (power) Gcal/t NH.sub.3 Overall CO.sub.2 0.22 0.18 0.17 0.28 emissions to the atmosphere t CO.sub.2/t NH.sub.3