EA008112B1 - Humid air turbine cycle with carbondioxide recovery - Google Patents

Abstract

A device is proposed in which carbon dioxide (152) is removed following compressor (130) which compresses a mixture of compressed air (132) and recirculated exhaust gas (118') from a gas turbine (120). The carbon dioxide depleted gas (136) is humidified (180, 114) and fed to the combustor (110).

Description

The technical field to which the invention relates is the extraction of carbon dioxide and, in particular, the extraction of carbon dioxide from a humidified turbine cycle.

State of the art

Combustible gases, and especially exhaust gases from gas turbines, often contain significant amounts of carbon dioxide, which is a greenhouse gas. Thus, in the last decade, much attention has been paid to the separation and / or isolation of carbon dioxide from combustion processes, and there are numerous devices and methods known in the art for removing carbon dioxide from an exhaust gas.

For example, carbon dioxide can be removed from various gas streams using one or more membranes, as described in US Pat. Nos. 4,130,403, 4,639,257 or 5,233,837. Membrane methods typically show relatively high selectivity to a single gas component. In addition, membrane methods can usually be carried out without circulation of energy consumption (for example, the heating and / or cooling requirements that are often necessary to remove solvent-based carbon dioxide). However, and especially depending on the composition of the feed gas, the membrane has a shorter service life, or the feed gas requires pre-treatment before contacting the membrane. In addition, membrane systems typically operate at a relatively high pressure drop, which either makes it necessary to use a supercharger or other pressure boosting equipment to supply low pressure gas, or makes membrane systems unsuitable for such a low pressure gas supply.

Alternatively, carbon dioxide can be removed using physical or chemical solvents, and many solvent processing devices are known in the art. Methods using physical solvents are particularly preferred when the partial pressure of the acid gas in the feed gas is relatively high. Thus, all or almost all physical solvents have only limited applicability for removing carbon dioxide from the exhaust gases, which are usually at about atmospheric pressure, and especially when the exhaust gas has a relatively low carbon dioxide content.

In order to circumvent the problems associated with the use of physical solvents, chemical solvents may be used to purify the feed gas, the chemical solvent being regenerated downstream to recover carbon dioxide. Purification of gases by chemical solvents usually always allows you to remove carbon dioxide from the feed gas at a relatively low pressure. However, such methods are often energy-consuming as well as expensive, and often there are problems with corrosion and solvent degradation (see, for example, US Pat. Nos. 2,065,112, 2,399,142, 2,377,966, 4,477,419 or 3,137,654). Moreover, since the partial pressure of carbon dioxide in the feed gas is reduced (for example, the exhaust gas from a gas turbine operating with a relatively large excess of air, as well as from a turbine with the injection of compressed moist air instead of steam), the size of the regeneration equipment, as well as energy, consumed by the supercharger, increase significantly to overcome the pressure drop in the regeneration equipment.

Thus, although various carbon dioxide removal devices and methods are known in the art, all or almost all of them have one or more disadvantages, especially when the partial pressure and / or carbon dioxide concentration in the feed gas is relatively low. Therefore, there is still a need for improved devices and methods for recovering carbon dioxide from various gases and, especially, gases with a relatively low partial pressure of carbon dioxide.

SUMMARY OF THE INVENTION

The present invention relates to methods and devices for removing carbon dioxide from exhaust gases, in which at least a portion of the exhaust gas is compressed to a higher pressure, thereby improving the efficiency of removal of carbon dioxide.

According to one aspect of the present invention, the device includes a combustion chamber that burns fuel in the presence of heated humidified air to produce an exhaust gas that expands in the expander. A compressor (operably connected to the expander) compresses the air and at least a portion of the gas leaving the expander to form a compressed mixed gas, from which carbon dioxide is removed in the acid gas removal unit, and a humidifier moisturizes the compressed carbon dioxide depleted mixed gas thus formed for receiving heated humidified air.

In addition, it is particularly preferable in such devices that heated humidified air is heated using the exhaust gas as a heat source, and the humidifier uses water that is heated by the compressed mixed gas and / or exhaust gas. Although various acid gas removal methods are contemplated, preferred acid gas removal devices include a membrane unit or the use of a solvent (e.g., an amine-containing solvent). In alternative devices, it is contemplated that part of the compressed mixed gas may also supply

- 1 008112 into the combustion chamber, and the cooling device provides cooling of the expanded exhaust gas with condensation as a result of water from the expanded exhaust gas.

When the acid gas removal unit includes an automatic cooling unit, it is assumed that it removes carbon dioxide from the first part of the compressed mixed gas, and that the humidifier moisturizes the second part of the compressed mixed gas to produce heated humidified air.

Thus, it is generally contemplated that the device may include a turbine combustion chamber, and in particular a combustion chamber of a humidified air turbine that receives fuel and humidified carbon dioxide depleted air, at least a portion of the moistened carbon dioxide depleted air, is formed from the exhaust gas of a humidified air turbine combustion chamber after a portion of the carbon dioxide has been removed for recovery. The carbon dioxide in such devices is advantageously recovered from air containing carbon dioxide (a mixture of fresh air and recirculated exhaust gas that contains carbon dioxide) using a membrane unit or solvent. Alternatively contemplated devices in which carbon dioxide is removed from an exhaust gas of a turbine combustion chamber may therefore include a compressor that compresses air and at least a portion of the exhaust gas (recycle gas) to form a compressed mixed gas, wherein carbon dioxide removed from the compressed mixed gas in the acid gas removal unit.

Various objects, features, aspects and advantages of the present invention will become more apparent from the following detailed description of preferred embodiments of the invention with reference to the accompanying drawings, in which like components are used with identical reference numerals.

Brief Description of the Drawings

FIG. 1 is a schematic view of an example apparatus for extracting carbon dioxide from an exhaust gas using a membrane or solvent in an acid gas removal unit.

FIG. 2 is a schematic view of an example apparatus for extracting carbon dioxide from an exhaust gas using an automatic cooling device in an acid gas removal unit.

FIG. 3 is a schematic view of an example apparatus for extracting carbon dioxide from an exhaust gas using partial wetting.

DETAILED DESCRIPTION OF THE INVENTION

The inventors have found that carbon dioxide contained in the exhaust gas of a gas turbine can be extracted under pressure by recycling at least a portion of the exhaust gas back to the compressor to increase the partial pressure of carbon dioxide in the compressed gas and to facilitate the removal of dioxide carbon using suitable acid gas removal technology (e.g. using a physical or chemical solvent, a special carbon dioxide membrane, or an automatic oh cooling).

In one particularly preferred device, as shown in FIG. 1, an example of a device 100 includes a humidified air turbine cycle for generating energy in which at least a portion of the expanded exhaust gas is recycled back to the compressor to recover carbon dioxide at elevated pressure. In particular, the combustion chamber 110 receives fuel 112 and heated humidified air 114 'and produces an exhaust gas 116, which is then expanded in the expander 120. The heat of the expanded exhaust gas 118 is then partially recovered in a heat exchanger 170, which heats the moistened air 114 from the humidifier 180, provides heat for the steam generator and additionally heats the water for humidifier 180 through an economizer 170 '.

One part of the expanded and cooled exhaust gas 118A is ventilated, while the other part of the expanded and cooled exhaust gas 118B is cooled in the cooling device 140 to form a cooled expanded exhaust gas stream 118 '(by condensation and separation of a significant part of the water), which combines with air 132 and is compressed in a compressor 130, which is operatively connected to an expander 120. Thus, the compressor 130 provides a compressed mixed gas 134, which is cooled in an additional device 160 hlazhdeniya by heating resulting in at least a portion of the water used in the humidifier. The thus cooled compressed mixed gas 134 is then supplied to an acid gas removal unit 150 (preferably a solvent based acid gas removal unit or a membrane based acid gas removal unit). The carbon dioxide product stream 152 exits the device (for example, as a commercial product), while the compressed carbon dioxide depleted mixed gas 136 is supplied to the humidifier 180. The humidifier 180 produces a humidified gas stream 114 from the compressed mixed gas 136 depleted in carbon dioxide, wherein humidified gas stream 114 is heated in a heat exchanger 170 to form a heated humidified gas stream 114 ', which is supplied to the combustion chamber 110 (the terms humidified gas stream and humidified air are used here zaimozamenyaemo).

Therefore, the device may include a combustion chamber that burns fuel in the presence of humidified air, the combustion chamber producing an exhaust gas that expands in an expander to form an expanded exhaust gas; a compressor operably coupled to the expander, wherein the compressor compresses the air and at least a portion of the expanded outlet

- 2 008112 th gas with the formation of compressed mixed gas; and an acid gas removal unit that removes carbon dioxide from the compressed mixed gas to form a compressed mixed gas depleted in carbon dioxide; and a humidifier that moisturizes the compressed carbon dioxide depleted mixed gas to form humidified air.

Alternatively, and especially when carbon dioxide is removed in the automatic cooling device, an example of the device is shown in FIG. 2. As indicated above, device 200 includes a humidified air turbine cycle for generating energy, wherein at least a portion of the expanded exhaust gas is recycled back to the compressor to recover carbon dioxide at elevated pressure. In such devices, the combustion chamber 210 receives fuel 212, heats the humidified air 214 'and produces an exhaust gas 216, which then expands in an expander 220. The heat of the expanded exhaust gas 218 is then at least partially recovered in a recuperator 270, which heats the moistened air 214 from the humidifier 280, provides heat for a steam generator (not shown) and additionally heats the water for the humidifier 280 through an economizer 270 '. The expanded and cooled effluent gas 218 is cooled in a cooling device 240 to form a cooled expanded effluent gas stream 218 '(when condensing and separating a significant portion of the water), which combines with air 232 and is compressed in a compressor 230 that is operatively connected to an expander 220. Thus , the compressor 230 provides a compressed mixed gas 234, which is cooled in an additional cooling device 260, thereby heating at least a portion of the water used in the humidifier.

The thus cooled compressed mixed gas 234 is then separated into a first stream 234A, which is supplied to the humidifier 280, and a second stream 234B, which is supplied to the automatic cooling unit 250. The carbon dioxide product stream 252 exits the device (for example, as a commercial product), while the carbon dioxide depleted exhaust gas 238 exits the device as an exhaust gas. Humidifier 280 produces a humidified gas stream 214 from the first stream 234A, wherein the humidified gas stream 214 is heated in a heat exchanger 270 to form a heated humidified gas stream 214 ', which is then supplied to the combustion chamber 210.

Thus, the installation may include a combustion chamber that burns fuel in the presence of humidified air, the combustion chamber producing an exhaust gas that expands in an expander to form an expanded exhaust gas; a compressor operably coupled to the expander, the compressor compressing the air and at least a portion of the expanded exhaust gas to form a compressed mixed gas; an automatic cooling unit that removes carbon dioxide from the first portion of the compressed mixed gas; and a humidifier that moisturizes a second portion of the compressed mixed gas to form humidified air.

In yet another contemplated device, as shown in FIG. 3, an example device 300 includes a gas turbine (e.g., a large-scale Seiega1 E1ec1ps 7EL + e turbine) with up to 20-30% air extraction in a humidified turbine cycle to generate energy, with at least a portion of the expanded exhaust gas being recycled to a compressor to recover carbon dioxide at elevated pressure. Here, the combustion chamber 310 receives fuel 312 and heated humidified air 314 'to produce an exhaust gas 316 that expands in an expander 320. The heat of the expanded exhaust gas 318 is at least partially recovered in the regenerated heat steam generator 370.

One part of the expanded and cooled exhaust gas 318A is ventilated, while the other part of the expanded and cooled exhaust gas 318B is cooled in the cooling device 340 to form a cooled expanded exhaust gas stream 318 '(by condensation and separation of a significant part of the water), which combines with air 332 and is compressed in a compressor 330, which is operatively connected to an expander 320. Thus, the compressor 330 provides compressed mixed gas 334. One portion of the compressed mixed gas 334A is supplied, for example, pit into the combustion chamber 310 (similar to that in conventional gas turbines), while the other part of the compressed mixed gas 334B is cooled in an additional cooling device 360, resulting in at least a portion of the water used in the humidifier. The thus cooled compressed mixed gas 334c is then fed to an acid gas removal unit 350 (preferably a solvent based acid gas removal unit or a membrane based acid gas removal unit). The carbon dioxide product stream 352 exits the device (for example, as a commercial product), while the compressed carbon dioxide depleted mixed gas 336 is supplied to the humidifier 380. The humidifier 380 produces a humidified gas stream 314 from the compressed carbon dioxide depleted gas 336, wherein the humidified gas stream 314 is heated in an additional cooling device 360 to form a heated moistened gas stream 314 ', which is supplied to the combustion chamber 310.

Thus, it must be recognized that the devices considered significantly facilitate the recovery of carbon dioxide contained in the exhaust gas with a relatively low partial pressure of carbon dioxide, which is especially desirable in the case of a gas turbine when a large amount of excess air is used. Therefore, the size of the extraction equipment

- 3 008112 carbon dioxide, as well as the amount of energy consumed by the supercharger, to overcome the pressure drop in the carbon dioxide recovery equipment (for example, in a direct-contact cooling device and adsorber) can be significantly reduced in devices in accordance with the present invention compared to numerous known devices.

While exhaust gas recycling can be used in numerous devices that include a turbine drive load (such as a generator or compressor), typically preferred device designs where the exhaust gas is at least partially recycled are devices that include turbines with an injection of compressed moist air instead of steam (TUV), and an exemplary installation that includes TUV is described in US Pat. No. 4,829,763, which is incorporated herein by reference. When the devices in question include the TUV cycle, it should be particularly noticeable that the previously existing difficulties of the known TUV cycles can be overcome in the carbon dioxide extraction devices in question. Among other things, previously known devices with a TUV cycle usually require custom-made turbine equipment, in which the gas turbine compressor must be significantly smaller than the expander. When removing carbon dioxide from the system in the case of solvent-based methods or when removing carbon dioxide and other gas components in the case of membrane-based methods or automatically cooling upstream of the expander, additional water vapor can be supplied to the combustion chamber and / or expander without significant change relative gas flow through the compressor and expander of the installation. Therefore, it is expected that the considered devices will not only improve the economic performance of carbon dioxide extraction in gas turbine-based devices, but also provide carbon dioxide extraction in existing recuperative gas turbines (for example, recuperative gas turbines manufactured by 8i1hsg TigOo or ΜΑΝ SYN VogDd).

In addition, it is contemplated that the devices and methods of the present invention can also be used in relatively small power plants with a capacity of 10 MW or less with the extraction of carbon dioxide from combustible gases. Alternatively, the devices and methods discussed may be included in all installations in which a gas turbine is used to drive a compressor or generator.

In addition, it is contemplated that carbon dioxide thus isolated can be used in a number of ways, and in particular, the putative methods include urea processing and improved oil recovery plants. Alternatively, the isolated carbon dioxide can be used for medical and food applications or in freezing processes or pumped into rock formations, the ocean or other places where carbon dioxide can be at least temporarily isolated. The water supplied to the humidifier in the above devices can be provided by various sources, including waste water (for example, from a plant), recycled water, or fresh water.

With regard to the considered acid gas removal plants, it must be recognized that all known methods for separating carbon dioxide from gas are suitable in connection with the description presented here. However, particularly preferred methods and devices include physical solvent based methods (see, for example, US Pat. Nos. 2,863,527, 2,926,751, 3,505,784, 2,649,166 or 3,773,896, incorporated herein by reference), chemical solvent based methods (see, for example, US Pat. 3563695 or 2177068, incorporated herein by reference), membrane methods (see, for example, US Pat. No. 4,705,540 or 4,741,744, incorporated herein by reference) and self-cooling (see, for example, US Pat. No. 6,301,927, incorporated herein by reference).

If carbon dioxide removal involves a membrane or solvent based process as shown in FIG. 1, it should be understood that the amount of recycled expanded exhaust gas 118B can vary significantly and depends, among other factors, on the particular carbon dioxide removal unit and / or the carbon dioxide partial pressure in the compressed mixed gas. Thus, it is generally contemplated that the amount of recycled expanded exhaust gas 118B may be in the range of 0 to 100 vol% of the total amount of expanded exhaust gas 118. However, and especially when the exhaust gas has a relatively low partial pressure of carbon dioxide, preferably the amount of recycled expanded the exhaust gas 118B is in the range of about 25 to 75 vol.% of the total expanded exhaust gas 118.

Similarly, when automatic cooling is used, as shown in FIG. 2, it should be understood that the amount of compressed mixed gas stream 234B that is supplied to the automatic cooling unit can vary significantly depending on specific operating parameters. However, in most of the operating conditions, suitable amounts of the compressed mixed gas stream 234B are in the range of 20 to 80 vol%. When the devices in question include a specific TUV device, as shown in FIG. 3, the amount of compressed mixed gas 334A, which is directly directed to the combustion chamber, can advantageously be from about 5 to 50 vol.%. However, depending on the particular device, the amount of compressed mixed gas 334A may also be higher than 50 vol.%. As for the cooled expanded exhaust gas stream 318B that is recycled back to the compressor, it is assumed that suitable amounts are

- 4 008112 are subject to change. However, it is usually preferred that the amount of chilled expanded effluent gas stream 318B is in the range of about 25 to about 75 vol%.

The mixing of the recycled cooled expanded effluent gas stream can be accomplished in numerous ways and all known mixing methods can be used here. For example, when an existing installation is modified into a device according to the invention, mixing can be carried out in a mixing tank upstream of the compressor inlet. On the other hand, when the device according to the invention is heterogeneous, mixing can take place by supplying recycled gas to the compressor inlet together with fresh air.

Therefore, the inventors mainly consider that the installation may include a combustion chamber of a humidified turbine that receives fuel and a humidified carbon dioxide depleted gas stream, wherein at least a portion of the moistened carbon dioxide depleted gas stream is generated from the effluent gas of a combustion chamber of a humidified turbine. Such devices may advantageously further comprise a humidifier in which the water is heated by a compressed mixed gas and / or exhaust gas. The term carbon dioxide depleted gas stream, as used herein, refers to any gas from which at least a portion of the carbon dioxide has previously been removed.

Another perspective view of a device in which carbon dioxide is removed from the exhaust gas of a turbine combustion chamber comprises a compressor that compresses air and at least a portion of the exhaust gas to form compressed mixed gas, the carbon dioxide being removed from the compressed mixed gas in an acid gas removal unit .

Thus, individual options and applications of humidified turbine cycles with carbon dioxide extraction are considered. However, it will be understood by those skilled in the art that much more modifications than those already described can be made without departing from the scope of the present invention. The subject invention considered, therefore, is not limited to anything other than the appended claims. In addition, in interpreting both the description and the claims, all terms should be interpreted as broadly as possible in accordance with the context. In particular, the terms contains and contains should be interpreted as referring to elements, components or stages, non-exclusive showing that the indicated elements, components or stages can be present, used, or combined with other elements, components or stages that are indicated implicitly.

Claims (20)

CLAIM 1. A gas turbine with a carbon dioxide recovery cycle, comprising a combustion chamber that burns fuel in the presence of a humidified gas stream, the combustion chamber producing an exhaust gas that expands in an expander to form an expanded exhaust gas; a compressor operably coupled to the expander, the compressor compressing the air and at least a portion of the expanded exhaust gas to form a compressed mixed gas; an acid gas removal unit that removes carbon dioxide from the compressed mixed gas to form a compressed mixed gas depleted in carbon dioxide; and a humidifier that moisturizes the compressed carbon dioxide depleted mixed gas to form a humidified gas stream that is supplied to the combustion chamber. 2. The turbine according to claim 1, in which the humidified gas stream is heated using the exhaust gas as a heat source, and in which the heated humidified gas stream is supplied to the combustion chamber. 3. The turbine according to claim 1, in which the humidifier uses water that is heated by compressed mixed gas and / or exhaust gas. 4. The turbine of claim 1, wherein the acid gas removal unit comprises a solvent that adsorbs at least a portion of the carbon dioxide. 5. The turbine according to claim 4, in which the solvent is a chemical solvent. 6. The turbine according to claim 1, in which the acid gas removal unit comprises a membrane unit. 7. The turbine according to claim 1, in which part of the compressed mixed gas is supplied to the combustion chamber. 8. The turbine of claim 1, further comprising a cooling device that cools the expanded exhaust gas, thereby condensing water from the expanded exhaust gas. 9. A gas turbine with a carbon dioxide recovery cycle, comprising a combustion chamber that burns fuel in the presence of a humidified gas stream, the combustion chamber producing an exhaust gas that expands in an expander to form an expanded exhaust gas; a compressor operably coupled to the expander, the compressor compressing the air mixture - 5 008112 and at least a portion of the expanded exhaust gas to form a compressed mixed gas; an automatic cooling unit that removes carbon dioxide from the first portion of the compressed mixed gas; and a humidifier that moisturizes the second portion of the compressed mixed gas to form a humidified gas stream that is supplied to the combustion chamber. 10. The turbine according to claim 9, in which the humidified gas stream is heated using the exhaust gas as a heat source and in which the heated humidified air is supplied to the combustion chamber. 11. The turbine of claim 9, wherein the humidifier uses water that is heated by compressed mixed gas and / or exhaust gas. 12. The turbine of claim 9, further comprising a cooling device that cools the expanded exhaust gas, thereby condensing water from the expanded exhaust gas. 13. A gas turbine with a carbon dioxide extraction cycle comprising a combustion chamber of a humidified air turbine that receives fuel and a stream of moistened gas depleted in carbon dioxide, at least a portion of the stream of moistened gas depleted in carbon dioxide is generated from the exhaust gas of the turbine combustion chamber with humidified air. 14. The turbine of claim 13, wherein the carbon dioxide is recovered from a humidified carbon dioxide depleted gas stream using a membrane assembly. 15. The turbine of claim 13, wherein the carbon dioxide is recovered from the humidified gas stream depleted of carbon dioxide using a solvent that adsorbs at least a portion of the carbon dioxide. 16. The turbine of claim 13, further comprising a humidifier, wherein the water used in the humidifier is heated by at least one of the compressed mixed gas and exhaust gas. 17. A carbon dioxide extraction device in which carbon dioxide is removed from an exhaust gas of a turbine combustion chamber, comprising a compressor that compresses a mixture of air and at least a portion of the exhaust gas to form a compressed mixed gas, the carbon dioxide being removed from the compressed mixed gas in a block removing acid gas to form a treated air stream that is supplied to the turbine combustion chamber. 18. The device according to 17, in which the acid gas removal unit comprises a membrane unit. 19. The device according to 17, in which the acid gas removal unit contains a solvent that adsorbs at least a portion of the carbon dioxide. 20. The device according to 17, further comprising a humidifier, in which the water used in the humidifier is heated by a compressed mixed gas and / or exhaust gas.