DE102010017317A1 - System for cooling gas turbine inlet air - Google Patents

Abstract

A system includes an air cooler (133). The air cooler (133) includes an air path (144), a heat exchanger (174) adapted to cool a dehumidifying liquid, and a cooler (194) adapted to receive the dehumidifying liquid and into direct contact with the dehumidifying liquid To bring air path (144). In addition, the dehumidifying liquid is configured to cool and remove moisture from the air in the air path (144).

Description

BACKGROUND TO THE INVENTION

The The invention described herein relates to a system and method for cooling of gas turbine inlet air.

A Gas turbine burns a mixture of fuel and air to one or to drive multiple turbine stages. As is known, the sucks Gas turbine generally ambient air into a compressor, the the air with a view to optimum combustion of the fuel compressed in a combustion chamber to a suitable pressure. Unfortunately, can the temperature and humidity of the ambient air depends on geographic location, season and the like vary. The moisture contained in the air can be components damage the gas turbine. For example, the humidity can cause corrosion and icing accelerate in the gas turbine compressor. In addition, the temperature can the ambient air reduce the performance of the gas turbine. An influence the temperature and humidity of the gas turbine Air can therefore increase the performance and life of the gas turbine improve significantly.

BRIEF DESCRIPTION OF THE INVENTION

in the The following are specific embodiments according to the subject the original one Invention summarized. These embodiments are not intended to limit the scope of the present invention, but rather should these embodiments only a brief description of possible expressions of Give invention. In fact, the invention can cover a variety of forms, which are similar to the embodiments set forth below, or can differ from these.

In a first embodiment contains one System a turbine air purifier comprising a dehumidifying fluid path, which is adapted to a dehumidifying liquid by a stream of air to conduct, which is directed to a turbine inlet, as well as a porous Medium disposed in the dehumidifying liquid path, being the porous one Medium is designed to direct the airflow into direct contact with the Entfeuchtungsflüssigkeit to convey.

In a second embodiment belong to a system: an air cooler, with an air path, a heat exchanger, which is adapted to cool a dehumidifying liquid, and a cooler, which is adapted to receive the dehumidifying liquid and this in immediate contact to bring with the air path, with the dehumidifying liquid is adapted to cool air in the air path and moisture from this too remove.

In a third embodiment belong to a system: a media cooler, with an air path, a dehumidifying liquid path and a porous medium, in both the air path and in the dehumidifying fluid path in the media cooler is arranged, wherein the porous medium to set up a direct contact between the air in the air path and the dehumidifying liquid in the dehumidifying liquid path to convey.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other features, aspects and advantages of the present invention after reading the following detailed description in conjunction with the attached Drawings more understandable, where matching Parts throughout with matching Reference signs are provided:

1 FIG. 12 is a block diagram of one embodiment of an integrated coal gasification combined cycle power plant (IGCC) incorporating an air cooling unit according to one embodiment; FIG.

2 illustrates the air cooling unit and the gas turbine, as in 1 are shown, in a block diagram, according to an embodiment;

3 schematically illustrates a cooler of the in 2 shown air cooling unit, according to an embodiment; and

4 FIG. 4 is a graph illustrating an operation of the in 1 illustrated air cooling unit, according to an embodiment.

DETAILED DESCRIPTION THE INVENTION

Hereinafter, one or more specific embodiments of the present invention will be described. In an effort to provide a concise description of these embodiments, not all features of an actual implementation may be included in the description. It should be clear, however, that in the development of any such realization, as in any technical or constructive project, numerous application-specific decisions have to be made to special ones To achieve goals of the developers, z. B. Conformance with systemic and economic constraints that may vary from one implementation to another. In addition, it should be understood that such a development effort could be complex and time consuming, but nonetheless would be routine to development, manufacture, and manufacture for those skilled in the art having the benefit of this description.

If Elements more diverse embodiments of the present invention are intended to be indefinite and certain article "a" or "one," the "etc. include the presence of more than one element. The Terms "include," "include," and "have" are meant as inclusively to understand and mean that may be additional Elements exist that differ from the listed elements differ.

As discussed in detail below, relate to the disclosed embodiments a system and method for cooling gas turbine inlet air by means of a dehumidifying liquid cycle. In particular, you can the disclosed embodiments use a moisture absorber / cooler that has a direct contact medium, the one dehumidifying liquid cycle uses, instead of heat exchangers, those with indirect contact work (eg with one in cooling coils isolated working fluid), an evaporative cooler, a mechanical cooler, a absorption chiller or use thermal energy storage systems. The system has at least one circuit for cooled dehumidifying liquid on to heat and To absorb moisture from a turbine inlet airflow, what the air condition of a drying temperature, that of the Environment significantly below, and a relative humidity to Result, which is significantly lower than 100%. The heat and Material transfer process takes place when the intake air uses an immediate touch cooler flows through the downstream one or more turbine inlet air filters can be installed.

Cooled dehumidifying liquid will be in immediate touch brought to air by an air path arranged in a cooler flows. This causes the dehumidifying liquid to extract water from the air and even diluted with water. About that In addition, the direct contact causes the cooled dehumidifying liquid with the air a heat transfer, which cools the air and the dehumidifying liquid heated. The dehumidifying liquid and the water from the air through a (for example, porous) medium separated, and the dehumidifying liquid and the water become in a sump of the cooler collected. After the diluted and heated Entfeuchtungsflüssigkeit has reached the drip pan, it is at least a cooling heat exchanger pumped to dissipate the absorbed heat, wherein the temperature of the dehumidifying liquid back to its original preset Level is reduced to be returned to the intake air cooler. To one desired Maintain concentration of dehumidifying liquid, is the system with at least one re-circulation cycle equipped, of a side stream of the diluted and heated dehumidifying fluid absorbs their temperature by means of at least one heater increases and then the dehumidifying liquid causes the absorbed moisture by means of an evaporator release. The recycled dehumidifying liquid gets back into the cooler drip tray fed. With a view to efficient use of energy can the heating element recovered from turbine exhaust heat or other available heat sources use, for example, a turbine housing vent passage.

1 FIG. 12 is a diagram of one embodiment of an integrated coal gasification combined power plant (IGCC) system. FIG 100 which can produce and burn a synthesis gas, ie a synthetic gas. As explained below, the system can 100 one or more air cooling units (e.g. 133 Using a direct contact medium having a dehumidifying liquid cycle, each air cooling unit may be adapted to simultaneously reduce the temperature and humidity of the air use. The following description is intended to illustrate possible applications of the disclosed air cooling units. Elements of the IGCC system 100 can a fuel source 102 For example, a solid state feed that can be used as an energy source for the IGCC system. The fuel source 102 may be based on coal, petroleum coke, biomass, wood materials, agricultural waste products, tars, coke gas and asphalt, or other carbonaceous elements.

The solid fuel of the fuel source 102 can become a feedstock processing unit 104 be directed. The feed preparation unit 104 For example, the size and shape of the material of the fuel source 102 by chopping, milling, chopping, pulverizing, compressing or palletizing the material of the fuel source 102 change to produce a feedstock. In addition, the fuel source can 102 in the feedstock processing unit 104 Water or other suitable liquids may be added to produce a slurry feedstock. In other embodiments, no liquid is added to the fuel source, resulting in a dry feedstock.

The feedstock may be from the feedstock processing unit 104 to a gasification device 106 be led. The gasification device 106 For example, the feedstock may be made into a synthetic gas, e.g. B. in a combination of carbon monoxide and hydrogen, convert. This conversion can be accomplished by subjecting the feed to a controlled amount of steam and oxygen, depending on the type of gasifier used 106 high pressures, eg. B. in the range of about 20 bar to 85 bar, and temperatures of z. B. about 700 degrees Celsius to 1600 degrees Celsius. The gasification process may involve subjecting the feedstock to a pyrolysis process in which the feedstock is heated. The temperatures inside the gasification device 106 during the pyrolysis process, depending on the fuel source 102 , which is used to produce the feed, range from about 150 degrees Celsius to 700 degrees Celsius. The heating of the feedstock during the pyrolysis process may produce a solid (eg, a coke) and residual gases (eg, carbon monoxide, hydrogen, and nitrogen). The weight of charcoal left over from the feedstock from the pyrolysis process may only be up to about 30% of the weight of the original feedstock.

Subsequently, in the gasification device 106 a combustion process take place. The combustion may include introducing oxygen to the char and residual gases. The coke and residual gases may react with the oxygen to form carbon dioxide and carbon monoxide, generating heat for the subsequent gasification reactions. The temperatures during the combustion process can range from about 700 degrees Celsius to 1600 degrees Celsius. Next, during a gasification step, steam may enter the gasifier 106 be introduced. The coke can react with the carbon dioxide and steam to produce carbon monoxide and hydrogen at temperatures ranging from about 800 degrees Celsius to 1100 degrees Celsius. Essentially, the gasifier uses steam and oxygen to allow part of the feedstock to be "burned" to produce carbon monoxide and release energy, driving a second reaction that converts further feed to hydrogen and additional carbon dioxide.

In this way, by the gasification device 106 produced a resulting gas. This resultant gas may be about 85% carbon monoxide and hydrogen in equal proportions, as well as CH _4, HCl, HF, COS, _NH3, HCN, and containing (depending on the sulfur content of the feedstock) H ₂ S. This resulting gas can be referred to as impure synthesis gas, since it contains, for example, H ₂ S. The gasification device 106 may also waste products, such. B. slag 108 , which may contain a wet ash material. This slag 108 can from the gasification facility 106 be removed and disposed of, for example, as a road surface or as other building material. For purification of the impure synthesis gas, a gas purification unit 110 be used. The gas purification unit 110 may purge the impure synthesis gas to remove the HCl, HF, COS, HCN and H ₂ S from the impure synthesis gas, which is a departure from sulfur 111 in a sulfur processing unit 112 may include, for example, a process for removing acidic gas in the sulfur processing unit 112 , In addition, the gas purification unit 110 salts 113 from the impure synthesis gas by means of a water treatment unit 114 Separate, the water purification techniques can use to the basis of the impure synthesis gas usable salts 113 to create. After that, that can be done by the gas purification unit 110 Gas emitted a clean synthetic gas (where, for example, the sulfur 111 is removed from the synthetic gas), the trace amounts of other chemical substances, eg. B. NH ₃ (ammonia) and CH ₄ (methane).

A gas processing unit 116 Can be used to make residual gas components 117 To remove, for example, ammonia and methane, as well as methanol or other chemical residues from the clean synthesis gas. However, the removal of residual gas components 117 from the clean synthesis gas optional because the clean synthetic gas can be used as a fuel even if the residual gas components 117 , z. B. Tail gas contained therein. At this point, the clean synthetic gas may contain about 3% CO _3, about 55% H _2, and about 40% CO ₂ and be substantially free of H ₂ S. This clean synthetic gas can be a combustion chamber arrangement 120 , z. B. a combustion chamber of a gas turbine 118 , are supplied as combustible fuel. Alternatively, the CO _{2 may be} removed from the clean syngas prior to delivery to the gas turbine.

The IGCC system 100 can also use an air separation plant (LZA) 122 contain. The LZA 122 can be used to decompose air, for example by distillation techniques, in proportional gases. The LZA 122 may be from the air that comes from a supplemental air compressor 123 is fed, separating oxygen, and the LZA 122 Can separate oxygen of the gasifier 106 respectively. In addition, the LZA 122 a dilute nitrogen (DGAN) compressor 124 to dispose of separate nitrogen.

The DGAN compressor 124 can from the LZA 122 Nitrogen taken up at least compress to pressure levels with those in the combustion chamber 120 in order not to impair the proper combustion of the synthesis gas. Therefore, the DGAN compressor 124 after the DGAN compressor 124 has sufficiently compressed the nitrogen to a suitable level, the compressed nitrogen of the combustion chamber 120 the gas turbine 118 respectively. The nitrogen may be used as a diluent to, for example, control emissions.

As described above, the compressed nitrogen originating from the DGAN compressor can be used 124 the combustion chamber 120 the gas turbine 118 be supplied. The gas turbine 118 can a turbine 130 , a drive shaft 131 and a compressor 132 and the combustion chamber arrangement 120 contain. The combustion chamber 120 can fuel, for. As synthetic gas, record, which can be injected from the fuel nozzles starting with pressure. This fuel can be used with compressed air as well as with the DGAN compressor 124 mixed compressed nitrogen and in the combustion chamber 120 to be burned. This combustion can produce hot pressurized exhaust gases.

The combustion chamber 120 The exhaust gases can be directed towards an exhaust outlet of the turbine 130 to steer. While from the combustion chamber 120 originating exhaust gases the turbine 130 Traverse, cause them in the turbine 130 arranged turbine blades the drive shaft 131 along an axis of the gas turbine 118 set in rotation. As you can see, the drive shaft is 131 with different components of the gas turbine 118 including the compressor 132 connected.

The drive shaft 131 can the turbine 130 with the compressor 132 connect to form an impeller. The compressor 132 can have blades that are connected to the drive shaft 131 are connected. In this way, a rotation of the turbine 130 arranged turbine blades cause the drive shaft 131 that the turbine 130 with the compressor 132 connects, in the compressor 132 arranged blades rotatably drives. This rotation of the blades in the compressor 132 causes the compressor 132 Air compresses it through an air intake opening in the compressor 132 has recorded. The over the air intake opening of the compressor 132 absorbed compressed air can be from an air cooling unit 133 (eg an air cooler). The cooled air can then pass through the compressor 132 be compressed, and the compressed air can enter the combustion chamber 120 be fed and mixed with fuel and compressed nitrogen to allow an increase in the efficiency of combustion. The drive shaft 131 can also with a load 134 be connected, which may be a stationary load, for. As an electrical generator for generating electrical power, for example in a power plant. In fact, the load can be 134 be any suitable device by the torque output of the gas turbine 118 is driven.

As discussed in more detail below, one embodiment includes the air cooling unit 133 (ie, the turbine air purification unit) comprises a direct-contact-medium-moisture absorber / cooler having a dehumidifying liquid cycle, the air-cooling unit 133 is designed to simultaneously reduce the temperature and humidity of the air. Reducing the temperature and humidity of the air can increase the performance and life of the gas turbine 118 improve. For example, the reduced temperature may be through the gas turbine 118 increase shaft output, and the reduction of humidity can reduce the risk of moisture in the air due to corrosion of components of the engine 118 Reduce. The air cooling unit 133 which utilizes a direct-contact medium-containing moisture absorber / cooler having a dehumidifying liquid circuit, satisfactorily cools both low and high humidity climates, and thus is not limited to low humidity climates such as evaporative coolers. As another example, an embodiment of the air cooling unit 133 using a direct contact medium moisture absorber / cooler with a dehumidifying liquid cycle, providing good cooling by means of a simple medium and by direct contact with a dehumidifying liquid, rather than isolating a cooling fluid in extensive heat exchanger cooling coils, which may be costly and require considerable space to have.

The IGCC system 100 may also be a steam turbine 136 and a heat recovery steam generation (HRSG) system 138 contain. The steam turbine 136 can be a second load 140 drive. The second load 140 may also be an electrical generator for generating electrical power. However, both the first and the second load can 134 . 140 also be other types of loads passing through the gas turbine 118 and through the steam turbine 136 can be driven. Although the gas turbine 118 and the steam turbine 136 As shown in the illustrated embodiment, different loads 134 and 140 can drive the gas turbine 118 and the steam turbine 136 also be used in tandem to drive a single load across a single shaft. The special constructions of the steam turbine 136 as well as the gas turbine 118 can be application specific and have any combination of sections.

The system 100 can also use the HRSG 138 contain. Heated exhaust gas from the gas turbine 118 can in the HRSG 138 ge be used and used to heat water and produce steam, which is used to the steam turbine 136 drive. For example, an ejection of a low-pressure section of the steam turbine 136 in a condenser 142 be directed. The capacitor 142 can a cooling tower 128 use to exchange heated water for chilled water. The cooling tower 128 serves to the capacitor 142 To supply cooling water to assist a condensation of the steam coming from the steam turbine 136 to the capacitor 142 is headed. Condensate from the condenser 142 can turn into the HRSG 138 be directed. Again, can also exhaust gas from the gas turbine 118 in the HRSG 138 be steered to that from the condenser 142 to heat the water and produce steam.

Combined cycle systems such as the IGCC system 100 can be hot exhaust gases from the gas turbine 118 to the HRSG 138 where they can be used to produce high pressure, high temperature steam. The one by the HRSG 138 generated steam can then pass through the steam turbine 136 passed through to generate electricity. In addition, the generated steam can be supplied to other processing processes that can use steam, for. B. the gasification device 106 , The production cycle of the gas turbine 118 is often referred to as the "high energy cycle", whereas the steam turbine production cycle 136 often referred to as the "low energy cycle". The combination of these machines can be a combined cycle using power plant 143 form. By a combination of these two cycles, as in 1 Illustrated is the IGCC system 100 increase the efficiencies of both cycles. In particular, exhaust heat derived from the high energy cycle may be captured and utilized to generate steam for use in the low energy cycle. The exhaust gas from the gas turbine may also, as explained below, in connection with the air cooling unit 133 be used.

2 shows a schematic representation of an embodiment of the gas turbine 118 and the air cooling unit 133 , While only a simple cycle gas turbine 118 in 2 illustrated and described below, it should be noted that the air cooling unit 133 in the context of a simple cycle engine in conjunction with an IGCC system 100 or independent of an IGCC system 100 can be used. Similarly, the air cooling unit 133 associated with a simple cycle power plant or combined cycle power plant 143 either in an IGCC system 100 or independent of an IGCC system 100 be used. In fact, the application of an air cooling unit 133 as set forth below, are generally used for any turbine system.

As previously discussed, the gas turbine includes 118 the combustion chamber arrangement 120 , the turbine 130 and along an axis of the gas turbine 118 arranged drive shaft 131 , weight 134 and the compressor 132 , The compressor 132 take along the path 144 cooled air from the air cooling unit 133 on. The cooling of this air can, as below in connection with the air cooling unit 133 be achieved via a cooling and dehumidifying process.

As described above, the air cooling unit 133 Serve to cool air to the compressor 132 supply. The air cooling unit 133 This cooling process can be done by passing air along a path 144 through a media cooler 146 passes. The media cooler 146 may be a heat exchanger that draws heat from a stream of air flowing along the path 144 flows to the compressor 132 to be fed. In the illustrated embodiment, the media cooler allows 146 a dehumidifying liquid, along one or more paths 148 through an intermediary 150 through and / or over the surface thereof, thereby passing along the path 144 flowing air is allowed, both with the intermediary 150 as well as to come into direct contact with the dehumidifying liquid. In addition, the media cooler can 146 in some embodiments, a portion of the dehumidifying liquid on a surface of the mediator 150 spray while part or most of it the dehumidifying liquid directly into the mediator 150 into or along its surface. However, some embodiments may omit spraying the dehumidifying liquid into the air stream, and instead directing (or injecting) the dehumidifying liquid directly into the mediator 150 in and along it to reduce the likelihood that the dehumidifying liquid will be carried away with the airflow. In both cases, the dehumidifying liquid is not isolated from the inside of pipes or the like from the environment (for example, from the airflow), but rather allows the mediator 150 the air flow, the air and the dehumidifying liquid either along an outer surface of the medium 150 or to bring it into direct contact in its porous interior.

In the disclosed embodiments, the dehumidifying liquid absorbs moisture and heat from the air in response to the direct contact between the air and the dehumidifying liquid. The dehumidifying liquid may therefore be considered as a dehumidifying solution due to the water content. For example, the dehumidifying agent solution may be a hygroscopic solution (ie, a substance that attracts water molecules from the immediate environment, either by absorption or by adsorption), for example, water and lithium chloride (H ₂ O / LiCl), water, and lithium bromide (H ₂ O / LiBr ), and water and potassium formate (H ₂ O / CHKO ₂ ). That is, while the dehumidifying liquid (or dehumidifying solution) comes into direct contact with the air flowing along the path 144 the dehumidifying liquid removes water from the air (ie it lowers the humidity) to increase the proportion of water with respect to the dehumidifying liquid. As discussed herein, the terms dehumidifying liquid and dehumidifying solution may be used interchangeably since the proportion of water relative to the dehumidifying liquid portion may vary constantly as moisture is taken up by the dehumidifying liquid and subsequently removed from the dehumidifying liquid.

The medium 150 For example, it may be a porous, corrugated or serrated plastic that comes in contact with the air / dehumidifier solution. In further embodiments, graphite and / or metallic compounds may be used to form the medium 150 to build. The medium 150 can be structured, for. B. may have a cross-flow pattern, or it may be unstructured. Regardless of the structure of the intermediary 150 represents the mediator 150 an area for immediate contact between air and the dehumidifying solution. This area may be referred to as an area of immediate interaction of air / dehumidifier solution. In this area of an immediate interaction, the moisture contained in the air on the mediator 150 Condensate and then added to the dehumidifying solution, and / or the moisture contained in the air can be absorbed directly by the dehumidifier solution. Thus, the along one or more paths 148 streaming dehumidifier solution will capture at least a portion of the moisture contained in the air while still allowing it to travel to the air (from which the trapped moisture is drawn) further along the path 144 in the compressor 132 to stream. In specific embodiments, the area of direct interaction may reduce the humidity of the air by at least about 5, 10, 15, 20, 30, 40, 50, 60, 70, 80, or 90 percent, while in the desiccant solution an increase in the amount of water is brought about , In this way, the moisture (eg, water droplets or humidity) will at least largely be out of the mediator 150 separated air separated (ie separated). In addition, as discussed below, the air may be substantially cooled by the dehumidifier solution. For example, the dehumidifying solution may be cooled to a temperature lower than that of the air, thereby allowing heat to be dissipated from the air into the dehumidifying solution.

It should be noted that the intermediary 150 can work with either polluted or filtered air. Accordingly, upstream of the mediator 150 a filter 152 used to remove impurities carried by the air before the air inside and / or on the surface of the intermediary 150 brought into direct contact with the dehumidifier solution. In a modification, the filter 152 from the air cooling unit 133 be distant. In addition, the filter can 152 with the media cooler 146 be formed integrally or separately from this.

As described above, the dehumidifying solution flows along the paths 148 while the air along the path 144 flows. After the dehumidifier solution has absorbed moisture from the air, it can (in an increased proportion of water) in a drip pan 154 or at the bottom of the media cooler 146 accumulate. The dehumidifying solution can be pumped 156 over a line 158 from the drip tray 154 be removed. The pump 156 can the dehumidifier solution via a pipe 162 to a bypass valve 160 transport. The bypass valve 160 For example, it can regulate the reprocessing of the dehumidifying fluid and the supply of the dehumidifying liquid to the media cooler 146 regulate / control. In this regard, the bypass valve 160 a small part, for example about 5, 6, 7, 8, 9 or 10%, in the pipe 162 existing dehumidifier solution, into the pipe 164 channel it to a reprocessing unit 166 supply.

The reprocessing unit 166 can one from the media cooler 146 be independent unit. The reprocessing unit 166 For example, water may be automatically removed from the dehumidifying solution to maintain the concentration of the dehumidifying liquid at an appropriate level. That is, the reprocessing unit 166 may serve to remove the water from the dehumidifier solution to provide a concentrated dehumidifying liquid for use in the media cooler 146 to create. In the reprocessing unit 166 the dehumidifier solution flows through a heat exchanger 168 , The heat exchanger 168 heats the dehumidifier solution by means of a heat flow 170 so that their water vapor pressure is that of the outside air 184 significantly exceeds. The heat flow 170 For example, from the exhaust outlet of the turbine 130 or the reprocessing unit 166 can other heat sources, eg. B. steam boiler water, an electric heating element, and so on, use. In a game Ausführungsbei the dehumidifier solution, as indicated by the directional arrow 172 indicated by a piping and / or by cooling coils of the heat exchanger 168 stream. The heat flow 170 can with the tubing in the heat exchanger 168 come in contact and can therefore heat the dehumidifier solution therein indirectly by heating the piping. In a modification, the heat flow 170 with the dehumidifying solution in the heat exchanger 168 come into direct contact to allow immediate heat exchange. Regardless of the method of heat exchange in the heat exchanger 168 heat is applied to the dehumidifying solution in the heat exchanger 168 transfer. The dehumidifier solution in the heat exchanger 168 transferred heat causes the increase of the partial vapor pressure of the water in the dehumidifier solution. In fact, the water vapor pressure difference between the heated dehumidifier solution and the outside air 184 as discussed below, the drive for the removal of moisture.

The reprocessing unit 166 directed the fluid out of the heat exchanger 168 to a second heat exchanger 174 (eg, a dehumidifier cooler) configured to cool the fluid. The illustrated heat exchanger 174 can be a distributor 176 have to apply the fluid evenly to one or more feed units 178 distributed, which are adapted to the fluid in a core 180 into it, which has a fixed bed contact area 182 may include. As mentioned above, the heat exchanger transfers 168 by means of the heat flow 170 Heat on the dehumidifying solution so that the water vapor pressure of the water in the dehumidifying solution is significantly higher than that of the outside air 184 , outside air 184 gets through the fixed bed interface 182 and water evaporates from the dehumidifier solution into the outside air 184 so that the solution is concentrated. The hot, humid air from the reprocessing unit 166 is with the outside air 184 ejected, and the now cooled and concentrated dehumidifying liquid along the directional arrows 186 through the core 180 in the drip tray 188 of the heat exchanger 174 stream. Thus, the drip tray 188 be a collection point for the regenerated dehumidifying liquid. This dehumidifying liquid can then be passed through a pipe 190 to the drip pan 154 of the media cooler 146 be transferred. In the drip tray 154 For example, the dehumidifying fluid may mix with the dehumidifying solution to reduce the total ratio of dehumidifier to water in the sump 154 to enrich. It should also be noted that the water removal capacity of the reprocessing unit 166 can be regulated / controlled to the humidity load of the inlet of the compressor 132 to fit. This can be achieved by the heat flow 170 to the heat exchanger 168 is regulated to maintain a constant concentration of the dehumidifying liquid.

As described above, the dehumidifier solution can be pumped by means of the pump 156 over a line 158 from the drip tray 154 be removed. The pump 156 can the dehumidifier solution via a pipe 162 to a bypass valve 160 transport. The bypass valve 160 For example, the supply of dehumidifying liquid to the media cooler 146 Taxes. In this regard, the bypass valve 160 the dehumidifier solution along the line 192 over the radiator 194 to the media cooler 146 conduct.

The cooler 194 may be a cooling heat exchanger that serves to reduce the heat of the dehumidifier solution. In this way, the temperature of the to the media cooler 146 supplied dehumidifying solution be less than that along the path 144 entering air. Thus, direct exposure of the air to the cooled dehumidifier solution while moisture from passing through the media cooler 146 flowing air, serve to effect a direct heat exchange to reduce the overall temperature of the air, along the path 144 through the media cooler 146 flows. The dehumidifier solution, along with the along the path 144 through the media cooler 146 flowing air can come in contact with the air through a distributor 196 be brought into contact, which can serve the dehumidifier solution evenly to one or more feed units 198 of the media cooler 146 to distribute. In addition, the distributor can 196 who is on an upper section of the intermediary 150 is arranged, the dehumidifier solution via the feed units in an indoor area 199 of the intermediary 150 conduct. That is, the feed units 198 Can the dehumidifier solution in the media cooler 146 (For example, into the interior of the media cooler) finely distribute (eg spray), so that they along with the path 144 flowing air may come into direct contact, as described above, both to cool the air immediately and to remove moisture therefrom. Air cooled and dehumidified in this way can go to the compressor 132 flow, resulting in an increase of the gas turbine 118 output shaft power and a reduction of the exposure of the components of the gas turbine 118 caused by corrosion by water vapor.

3 shows a diagram of an embodiment of the media cooler 146 , As previously described, the media cooler 146 Serve with air for use in a compressor 138 to cool and dehumidify. As you can see, hot air can flow along directional arrows 200 in the media cooler 146 stream. In the illustrated embodiment, the air flows into each of three sections 202 . 204 and 206 of the media cooler 146 , While three sections are shown, it should be noted that the entirety of the media cooler 146 based on one or more sections. Each of the section 202 . 204 and 206 contains a distributor 196 , which can serve a dehumidifying solution evenly to one or more feed units 198 of the media cooler 146 to distribute. The feed-in units 196 Can the dehumidifying solution in the media cooler 146 distribute it finely (eg spray or inject), making it along with the directional arrow 200 flowing air can come into direct contact, both to cool the air immediately and to remove moisture from it. The distributor 196 can dehumidify fluid over a pipe 208 supplied, which may be, for example, a pipe, with the radiator 194 from

2 connected is. In addition, a secondary line 210 be used to add a high proportion of dehumidifying solution in the media cooler 146 contribute.

The secondary line 210 For example, it can be a pipe with the radiator 194 from 2 connected is. However, the line ends 210 not at a distributor 196 , Instead, the line can 210 feed channels 212 have a mist of dehumidifying solution directly into the media cooler 146 can spray (or inject) to come into contact with the air along the directional arrows 200 flows through the media cooler. That is, the feed channels 212 The dehumidifying liquid can be directed towards an inlet side 213 of the intermediary 150 spray into the air stream. It should be noted that the lines 208 and 210 can be used in conjunction to provide a more uniform distribution of the dehumidifying agent-rich solution to the air in the media cooler 146 to provide. In a modification, either the line 208 or 210 for example, be used individually to the total cost of the media cooler 146 to reduce.

While the dehumidifying liquid comes into contact with the moisture in the along the directional arrows 200 flowing air, the dehumidifying liquid absorbs water from the air and carries it in the mediator 150 continued. As stated earlier, the intermediary represents 150 a contact area ready to allow an immediate contact between the air and the dehumidifying agent solution, while also providing a flow path to carry away the dehumidifying solution after it has cooled the air and removed the moisture therefrom. As is known, the dehumidifying liquid may be cooled much more strongly compared to the air, e.g. B. 10, 20, 30, 40 or 50 degrees Fahrenheit be cooler than the air. The temperature difference can thus cause the moisture contained in the air on the mediator 150 condensed, wherein the dehumidifying liquid can absorb the condensed water and carry away. However, the temperature difference may also cause the moisture in the air to condense or collect on the dehumidifying liquid, e.g. On the droplets of the dehumidifying liquid spray steel and / or on the stream of dehumidifying liquid in the intermediary 150 , In any event, the dehumidifying liquid cools the airflow while also removing moisture from the airflow via an immediate air / dehumidifying liquid contact. The dehumidifying solution, in turn, flows through the mediator (along with the absorbed moisture) 150 away from the airflow, while the airflow is increasing from the mediator 150 away. The dehumidifying solution thus removes a substantial portion of the moisture (e.g. the water content) of the air, the mediator 150 crosses. The dehumidifier solution may be in a collection area 214 accumulate to over a line 216 in the drip tray 154 of the media cooler 146 to be dissipated. From there, the dehumidifier solution having a high water content can be passed over a pipe 158 from the media cooler 146 be removed to be recycled or reprocessed, as described above.

The air, whose water content is now reduced, and cooled by direct contact with the previously cooled dehumidifier solution, flows along the directional arrows 218 from the intermediary 150 continued. At this point, the along the directional arrows 218 flowing air downstream of the mediator 150 on a mist eliminator 220 to meet. The mist eliminator 220 may serve to remove any excess vapor / mist (eg fluid) from the along the directional arrows 218 flowing air before transfer to the compressor 132 to remove. For example, the mist eliminator 220 any remains of the feed channels 212 field dehumidifying liquid spray mist. The mist eliminator 220 For example, a filter may be moisture blocking the passageway while permeable to air. Next, note that the mist eliminator 220 based on the air velocities and the ability of the dehumidifying liquid and the mediator 150 , Water from the through the media cooler 146 to remove flowing air, optionally from the media cooler 146 can be removed.

4 shows a graphical representation of the effects of using an air cooler 133 as described above. In particular, illustrated 4 graphically comparing the disclosed air cooler 133 compared to other cooling techniques, showing that on the air cooler 133 improved performance due to this.

Specifically, a graph represents 222 an evaporative cooling technique, a graph 224 represents a cooling technique, and a graph 226 represents a combined dehumidification and cooling technique according to specific embodiments of the disclosed air cooler 133 , Each of these graphs 222 . 224 and 226 starts at a common starting point 228 about 100 degrees Fahrenheit, about 20% relative humidity and about 0.008 specific humidity. As you can see, these graphs give way 222 . 224 and 226 with regard to temperature and humidity considerably from the common starting point 228 from. For example, the evaporative cooling graph shows 222 however, a drop in air temperature to about 75 degrees Fahrenheit also shows a significant increase in relative humidity to over 60% and a specific humidity to about 0.015. These increased humidity levels can cause the suction opening of the compressor 132 coated with ice, and can be attached to components of the gas turbine 118 Cause corrosion. The cooling graph 224 shows a drop in air temperature to about 50 degrees Fahrenheit with a substantial increase in relative humidity up to about 90 percent. Although the cooling graph 224 until about 60 degrees Fahrenheit indicates a substantially constant specific humidity, the specific humidity drops to a value of about 0.007 at about 50 degrees Fahrenheit.

In contrast, the air cooling unit 133 air passing through, by the direct contact with cooled dehumidifying liquid and the mediator 150 As discussed above, be used in combination as indicated by the graph 226 shown both dehumidifying and cooling experienced. The above in connection with the air cooling unit 133 The techniques described may cause the temperature of the air to be reduced to less than about 60 degrees Fahrenheit. While the air is cooled down to this temperature, the specific humidity of the air can be reduced to about 0.0025, while the relative humidity can remain at about 30 percent. Accordingly, by means of the use of cooled dehumidifying agents and the mediator 150 in a media cooler 146 Similar temperature reductions as are experienced in air coolers, but at lower levels of humidity, are achieved resulting in an increase in shaft power output for the gas turbine 118 and leads to a reduction in corrosion that occurs due to intake air moisture on the components of the gas turbine.

The present description uses examples to illustrate the invention, including to describe the best mode and, moreover, to enable every professional to use the invention in practice, for example, any Establish and use facilities and systems, and any to carry out associated procedures. The patentable scope of protection The invention is defined by the claims and is capable of others to those skilled in the art. Such others Examples are intended to be within the scope of the claims if they are structural elements that stand out from the literal Content of the claims do not differ, or if they have equivalent structural elements with insubstantial differences from the literal content of the claims.

A system contains an air cooler 133 , Of the air cooler 133 contains an air path 144 , a heat exchanger 174 , which is adapted to cool a dehumidifying liquid, and a radiator 194 which is adapted to receive the dehumidifying liquid and these in direct contact with the air path 144 bring to. In addition, the dehumidifying liquid is adapted to moisture from the air in the air path 144 to cool and remove.

100

integrated Coal Gasification Combined Power Plant (IGCC) System

102

fuel source

104

Feedstock preparation unit

106

gasifier

108

slag

110

Gas cleaning unit

111

sulfur

112

Sulfur processing unit

113

salts

114

Water treatment unit

116

Gas processing unit

117

Residue gas components

118

gas turbine

120

combustion chamber

122

Air separation plant

123

air compressor

124

Verdünnungsstickstoffgas- (DGAN) densifier

130

turbine

131

drive shaft

132

compressor

133

Air cooling unit

134

load

136

steam turbine

138

Wärmerückgewinnungsdampferzeugungs- (HRSG) system

140

load

142

capacitor

143

combined Cycles using power plant

144

path

146

media cooler

148

path

150

media

152

filter

154

drip tray

156

pump

158

management

160

bypass valve

162

management

164

management

166

Reprocessing unit

168

heat exchangers

170

heat flow

172

arrow

174

heat exchangers

176

distributor

178

feed units

180

core

182

Touchpad

184

ambient air

186

Shovel through channel

188

drip tray

190

management

192

management

194

cooler

196

distributor

198

feed units

199

interior

200

management

202

section

204

section

206

section

208

management

210

management

212

feed channels

213

inlet side

214

collecting area

216

management

218

arrow

220

Dunstbeseitiger

222

graphic presentation

224

graphic presentation

226

graphic presentation

228

starting point

Claims (10)

System comprising: an air cooler ( 133 ), with: an air path ( 144 ); a heat exchanger ( 174 ) configured to cool a dehumidifying liquid; and a cooler ( 194 ), which is adapted to receive the dehumidifying liquid and the dehumidifying liquid in direct contact with the air path ( 144 ), wherein the dehumidifying liquid is adapted to the air in the air path ( 144 ) to cool and remove moisture from it. System according to claim 1, with an intermediary ( 150 ), which is adapted to the dehumidifying liquid through the air path ( 144 ) to flow. The system of claim 2, wherein the mediator ( 150 ) comprises a porous means adapted to direct the dehumidifying liquid into direct contact with the air in the air path ( 144 ) bring to. System according to claim 2, with a spray injector ( 198 ), which is adapted to apply the dehumidifying liquid to the intermediary ( 150 ) to spray. System according to claim 2, with a mist eliminator ( 220 ) in the air path ( 144 ) downstream of the mediator ( 150 ), the mist eliminator ( 220 ) is adapted to fluid from the air in the air path ( 144 ) to remove. A system according to claim 2, including a dehumidifying liquid recycling device (10). 166 ), which is adapted to remove moisture from the dehumidifying liquid. System according to claim 1, with a spray injector ( 212 ), which is adapted to the dehumidifying liquid in the air path ( 144 ) to spray. The system of claim 1, including: a sump ( 154 ), which is adapted to collect the dehumidifying liquid, and a pump ( 156 ), which is adapted to the dehumidifying liquid from the drip pan ( 154 ) to which the dehumidifying liquid coolers ( 194 ). The system of claim 2, wherein the mediator ( 150 ) Plastic, graphite or a metallic compound. The system of claim 1, wherein the dehumidifying liquid Lithium chloride, lithium bromide or potassium formate.