DE102015219398A1 - Method for operating a gas-and-steam combined cycle power plant and gas and steam combined cycle power plant - Google Patents

Abstract

The invention relates to a method for operating a gas-and-steam combined cycle power plant (10) in which hot steam is generated by means of exhaust gas of a gas turbine (12) by means of which at least one generator (30) is provided via at least one turbine device (22) is powered by electric current, wherein at least a portion of heat contained in the steam is used to effect an endothermic chemical reaction.

Description

The invention relates to a method for operating a gas-and-steam combined cycle power plant according to the preamble of patent claim 1 and to a gas-and-steam combined cycle power station according to the preamble of patent claim 8.

Such a method for operating a gas-and-steam combined cycle power plant and such a gas and steam combined cycle power plant (CCGT) are already well known from the general state of the art. The gas-and-steam power plant is also referred to as a combined cycle power plant and comprises at least one turbine device, at least one generator that can be driven by the turbine device for providing electric power and at least one gas turbine. If the generator is driven by the turbine device, then the generator can convert mechanical energy into electrical energy or electrical current and provide this electrical energy or the electric current. The electrical current can then be fed, for example, into a power grid.

The gas turbine thereby provides exhaust gas, by means of which hot steam is generated. For example, the gas turbine, a fuel, in particular a gaseous fuel such as natural gas supplied, wherein the fuel is burned by means of the gas turbine. In particular, the gas turbine is supplied in addition to the fuel oxygen or air, so that from the air and the fuel, a fuel-air mixture is formed. This fuel-air mixture is burned, resulting in exhaust gas of the gas turbine results. By means of the exhaust gas, for example, a liquid, in particular water, is heated and thereby evaporated, resulting in hot steam. This means that the hot steam is generated by means of the exhaust gas of the gas turbine such that by means of the hot exhaust gas of the gas turbine, a liquid such as water is evaporated.

The steam is supplied to the turbine device, so that the turbine device is driven by means of the steam. As already described, the generator is driven via the turbine device or by means of the turbine device. The gas and steam combined cycle power plant, also referred to as gas and steam combined cycle power plant, is a power plant in which the principles of a gas turbine power plant and a steam power plant are combined. The gas turbine or its exhaust gas serves as a heat source for a downstream steam generator, by means of which the steam for the turbine device or for driving the turbine device is generated. The turbine device is thus designed as a steam turbine.

It has been found that such a combined cycle power plant (CCGT), in particular depending on the power requirements, must be switched off, so that the generator does not provide electrical power and, for example, is not driven and so by means of the combined cycle power plant no Electricity is fed into the grid. As a result of the shutdown, the gas-and-steam combined cycle power plant can cool down, whereupon a restart of the gas and steam combined cycle power plant requires a particularly long time and a particularly high energy consumption. Therefore, it is usually intended to keep the gas and steam combined cycle power plant warm during a time during which the gas and steam combined cycle power plant is off. The gas-and-steam combined cycle power plant is kept warm by means of steam. This steam for keeping warm is usually produced by means of a boiler, in particular a gas boiler. By means of the boiler, a liquid such as water is evaporated, for which purpose a fuel is used. The steam generated by the boiler is passed through at least part of the gas and steam combined cycle power plant to keep it warm. Then, the gas-and-steam combined cycle power plant can be started after a shutdown of the same as part of a warm start, since the gas-and-steam combined cycle power plant then has an already sufficiently high temperature at which it can be started.

However, with increasing time that the gas and steam combined cycle power plant is shut down, an increasing amount of steam is required for keeping the gas and steam combined cycle power plant warm as it progressively cools down. Generating steam to keep warm or warm the shutdown gas and steam combined cycle power plant is usually very energy consuming.

It is therefore an object of the present invention to further develop a method and a gas-and-steam combined cycle power plant of the type mentioned at the beginning in such a way that the gas-and-steam combined cycle power plant can be heated or kept warm in a particularly efficient manner.

This object is achieved by a method having the features of patent claim 1 and by a gas-and-steam combined cycle power plant having the features of patent claim 8. Advantageous embodiments with expedient developments of the invention are specified in the other claims.

In order to further develop a method of the kind specified in the preamble of patent claim 1 in such a way that the gas-and-steam combined cycle power plant can be kept warm or heated particularly efficiently, it is provided according to the invention that at least part of the part produced by means of the gas turbine Steam contained heat is used to effect an endothermic chemical reaction, that is, a heat-absorbing chemical reaction. For the sake of simplicity and readability, the gas and steam combined cycle power plant will hereinafter be referred to as a combined cycle power plant or simply a power plant.

By utilizing the heat contained in the vapor to effect the endothermic chemical reaction, it is possible to store in products of the endothermic chemical reaction at least a portion of the heat used to effect the endothermic chemical reaction, such stored heat, for example can be used at a later date to heat or keep at least a part or partial area of the power plant. Thus, by utilizing an endothermic chemical reaction, heat can be effectively and efficiently stored with or without heat conversion, such that the power plant can be kept warm, especially while it is turned off. In particular, different components or components can also be heated or kept warm with increasing time during which the power plant is switched off, in order thereby to realize a warm start of the power plant subsequent to a shutdown of the power plant. As a result, the power plant can be activated or turned on particularly quickly and with low energy.

It has been found that by utilizing an endothermic chemical reaction, the power plant can be maintained or heated much more efficiently than if steam were used to maintain the power plant warm by means of a boiler, particularly a gas boiler. Such a gas boiler is a gas burner, by means of which, with the use of fuel, in particular gaseous fuel, steam for keeping warm or heating of the power plant is generated.

The invention is now based on the idea during the operation of the power plant, i. during a time during which the power plant is turned on, to divert at least a portion of the energy contained in the steam produced anyway by the exhaust gas of the gas turbine and to use for effecting the endothermic reaction to store energy or heat in the products of the endothermic reaction, which later, while the power plant is shut down, can be used to keep the power plant warm.

Thus, a thermochemical heat storage is used, in which, for example, the endothermic reaction takes place. In the heat storage, the heat stored in the products of the endothermic reaction can be stored and used effectively and efficiently for later purposes.

In an advantageous embodiment, it is provided that by means of products of the endothermic chemical reaction, an exothermic chemical reaction is carried out, is released in which heat, by means of which at least a portion of the gas-and-steam combined cycle power plant is heated or kept warm. The endothermic reaction is carried out, for example, in an endothermic reactor. The exothermic reaction is carried out, for example, in an exothermic reactor, by means of which the heat released in the exothermic reaction is at least indirectly used to keep the power plant warm while it is switched off.

In an advantageous embodiment, it is provided that by means of the heat released in the exothermic chemical reaction steam is generated, by means of which at least the part of the gas-and-steam combined cycle power plant is heated or kept warm.

In an advantageous embodiment, it is provided that at least one heat exchanger is provided, via which at least part of the heat released during the exothermic reaction to the part of the gas-and-steam combined cycle power plant or to a medium, in particular a liquid or a gas, or a component of the gas and steam combined cycle power plant is transmitted.

The medium is used, for example, to keep the power station warm. The medium is, for example, water, which can be vaporized by means of the heat released. The medium can, for example, contact educts and / or products of the exothermic reaction directly, in particular flowing or flowing around in order to heat the medium and thereby vaporize it, for example. The component may be a heat exchanger, via which the released heat is transferred, for example, to the medium in order to heat the medium, in particular to evaporate it. Through the use of the heat exchanger, a spatial separation of the medium from the educts and / or products of the exothermic reaction is possible, so that the medium does not directly touch the products and / or educts of the exothermic reaction.

In an advantageous embodiment, it is provided that at least the part of the in the means of the exhaust gas of the gas turbine generated steam during normal operation of the gas and steam combined cycle power plant is used to effect the endothermic chemical reaction, wherein during normal operation, the generator is driven and provided by the generator electrical current.

In an advantageous embodiment, it is provided that after normal operation, a holding operation is performed, in which the gas-and-steam combined cycle power plant is heated or kept warm by means of the energy released, while a caused by the generator providing electrical power, in particular a through the turbine means causes driving of the generator, is omitted. During the keep warm operation, the power plant is switched off.

In an advantageous embodiment, it is provided that at least one heat exchanger is provided, by means of which at least the part of the heat contained in the steam generated by means of the exhaust gas of the gas turbine is transferred to educts of the endothermic chemical reaction.

The branched off steam can, for example, directly touch or flow around the educts of the endothermic reaction, in order to realize heat transfer from the steam to the educts of the endothermic reaction. By using a heat exchanger, a spatial separation of the generated steam from the educts of the endothermic reaction can be realized, so that the generated steam does not directly touch the educts of the endothermic reaction.

In order to further develop a gas-and-steam combined cycle power plant of the type specified in the preamble of claim 8 such that the gas-and-steam combined cycle power plant is particularly efficient, i. can be kept warm or heated energiegünstig, at least one reactor is provided according to the invention, which at least a portion of contained in the heat generated by the gas turbine steam can be supplied to cause an endothermic chemical reaction in the reactor by means of the supplied heat from the steam. Advantageous embodiments of the method according to the invention are to be regarded as advantageous embodiments of the gas-and-steam combined cycle power plant according to the invention and vice versa.

Further advantages, features and details of the invention will become apparent from the following description of a preferred embodiment and from the drawing. The features and feature combinations mentioned above in the description as well as the features and feature combinations mentioned below in the description of the figures and / or shown alone in the several figures can be used not only in the respectively indicated combination but also in other combinations or alone, without the frame to leave the invention.

The drawing shows in the single FIGURE is a schematic representation of a gas and steam combined cycle power plant, which can be kept particularly energiegünstig by utilizing an endothermic chemical reaction.

The single figure shows a schematic representation of a whole 10 designated gas-and-steam combined cycle power plant, which is also referred to as a combined cycle power plant or - for better readability - as a power plant. The power plant comprises at least one gas turbine 12 which is supplied for example in the context of a method for operating the power plant fuel. This supply of fuel to the gas turbine 12 is in the figure by a directional arrow 14 illustrated. In particular, the fuel is a gaseous fuel such as natural gas. Furthermore, the gas turbine 12 Air supplied, which in the figure by a directional arrow 16 is illustrated. By means of the gas turbine 12 the fuel is burned, resulting in exhaust gas of the gas turbine 12 results. Thus, the gas turbine 12 the exhaust ready, which in the figure by a directional arrow 18 is illustrated. In the gas turbine 12 For example, a mixture of the fuel and the air is formed, and this mixture is burned. This results in the exhaust gas of the gas turbine 12 ,

Based on the directional arrow 18 it can be seen that the exhaust gas is a steam generator 20 the power plant is supplied. The steam generator 20 is also referred to as a boiler or evaporator. Further, the steam generator 20 a liquid, in particular in the form of water supplied. In this case, there is a heat transfer from the exhaust gas of the gas turbine 12 to the water, which heats and vaporizes the water. This will generate steam from the water. This means that by means of the exhaust gas of the gas turbine 12 and by means of the steam generator 20 Steam from the steam generator 20 supplied water (liquid) is generated. As a result of this heat transfer from the exhaust gas to the water, the exhaust gas is cooled, so that it, for example, with a first temperature T1 from the steam generator 20 is dissipated. For example, the first temperature T1 is at least substantially 90 ° C (degrees Celsius).

The power plant also includes a whole 22 designated turbine device, which in this case a first turbine 24 and a second turbine 26 includes. The turbine 24 is designed for example as a high pressure turbine, the turbine 26 is designed as a medium-pressure and low-pressure turbine. The means of the exhaust gas of the gas turbine 12 and with the help of the steam generator 20 generated steam is the turbine device 22 supplied, so that the turbine device 22 , especially the turbines 24 and 26 be powered by the generated hot steam. By means of the turbine device 22 For example, energy contained in the hot vapor is converted into mechanical energy, the mechanical energy being transmitted through a wave 28 provided. The turbine device 22 For example, in the figure, not shown in detail turbine wheels, where the steam is supplied. As a result, the turbine wheels are driven by the steam. The turbine wheels are, for example, non-rotatable with the shaft 28 connected, so the shaft 28 is driven by the turbine wheels when the turbine wheels are driven by the steam.

The power plant further comprises at least one generator 30 , which over the shaft 28 from the turbine device 22 is driven or driven. The generator 30 is thus the over the shaft 28 supplied mechanical energy supplied, by means of the generator 30 at least a part of the supplied mechanical energy is converted into electrical energy or electric current. The generator 30 can provide this electrical power, which can be fed, for example in a power grid.

The steam is from the turbine device 22 discharged and a heat exchanger 32 fed, which acts as a capacitor or is formed. By means of the heat exchanger 32 the steam is cooled, whereby the steam condenses. As a result, the steam is returned to the aforementioned water, which is the steam generator 20 can be fed again.

To the steam by means of the heat exchanger 32 To cool, the heat exchanger 32 For example, a cooling medium, in particular a cooling liquid supplied. In this case, a heat transfer from the steam to the cooling liquid take place, whereby the steam is cooled and condenses in the sequence.

The power plant has a plurality of lines not shown in detail in the figure, through which respective flows of the means of the exhaust gas of the gas turbine 12 generated steam flow. These flows can have different temperatures. In the figure, different temperatures T2, T3 and T4 of the by means of the exhaust gas of the gas turbine 12 shown, wherein the temperature T2, for example, 595 ° C, the temperature T3 360 ° C and the temperature T4 is 240 ° C. The water leaves the condenser, for example, at a temperature T5, which is for example 40 ° C.

Depending on the power requirement, i. depending on the amount of electrical power that must be provided by the power grid, the power plant is activated, i. turned on, and deactivated, i. off. For example, the power plant is switched off with only a small power requirement. If the power requirement increases, the power plant is switched on again after switching off. This switching, which is connected in time to a shutdown of the power plant, preferably takes place as a warm start to turn on the power plant quickly and energy-efficient. To realize this warm start, in particular to realize a particularly energiegünstigen warm start, the power plant after switching off and during a time during which the power plant is switched off, kept warm or heated to avoid excessive cooling or cooling of the power plant.

In order to heat up or heat the power station particularly energiegünstig, at least a part of in by means of the gas turbine 12 used steam generated heat used to effect an endothermic chemical reaction. For this purpose, the power plant comprises at least one reactor 34 in which the endothermic chemical reaction can take place.

For example, by means of the exhaust gas of the gas turbine 12 generated steam or one of the aforementioned flows or at least a part of one of the aforementioned flows of means of the exhaust gas of the gas turbine 12 generated steam branched off from at least one of the aforementioned lines. This branched off, by means of the exhaust gas of the gas turbine 12 steam generated, for example, a line 36 flow through the power plant and is by means of the line 36 to the reactor 34 guided. At least part of the line 36 Throughgoing steam contained heat is used to control the endothermic chemical reaction in the reactor 34 to effect.

For this, the heat of the line 36 flowing through educts fed to the endothermic chemical reaction. The endothermic chemical reaction is a reaction that absorbs energy or heat. This heat thus comes from the line 36 flowing steam. In particular, flows through the reactor 34 supplied steam, for example, a heat exchanger 38 , by means of which at least a part of which in the heat exchanger 38 passing through heat transmitted to the reactants of the endothermic chemical reaction. The endothermic chemical reaction produces products from the educts endothermic chemical reaction. These products store at least a portion of the heat used to effect the endothermic chemical reaction.

The endothermic chemical reaction is, for example, a forward reaction of a chemical equilibrium reaction. This chemical equilibrium reaction includes, for example, a reverse reaction, which is an exothermic chemical reaction. In the context of the reverse reaction, the products of the endothermic chemical reaction (forward reaction) are starting materials of the reverse reaction, the starting reaction starting materials being products of the reverse reaction.

In the context of the reverse reaction (exothermic chemical reaction) heat is released. This released heat can be used at least in part to keep the power plant warm, especially while the power plant is off. This means that by means of the products of the endothermic chemical reaction an exothermic chemical reaction (reverse reaction) is carried out in which heat is released. By means of the released heat at least a part of the power plant is heated or kept warm. Thus, a thermochemical heat storage is provided in which heat is stored during operation of the power plant. This stored heat is used while the power plant is shut down to heat or keep the power plant warm. This means that the thermochemical heat accumulator is charged or charged during operation of the power plant and discharged while the power plant is shut down.

In particular, it can be provided that steam is generated by means of the heat released during the exothermic chemical reaction. For example, one of the steam generator 20 different, additionally provided steam generator 40 provided, which is supplied to at least part of the heat released in the reverse reaction. By means of the steam generator 40 supplied heat is a liquid, especially water, heated and thereby evaporated, whereby by means of the steam generator 40 Steam is generated. The liquid, in particular the water, thus becomes the steam generator 40 fed. The by means of the steam generator 40 Steam generated by the heat released is taken from the steam generator 40 dissipated, which in the figure by a directional arrow 42 is illustrated. The steam generator 40 For example, discharged steam is supplied to at least a portion of the power plant to heat or heat at least that portion of the power plant by means of the steam generated by the heat released during the reverse reaction.

The power plant includes, for example, another heat exchanger 44 via which at least part of the heat released during the exothermic chemical reaction is transferred to the part of the power plant to be kept warm or to a medium for keeping the power station warm or else to a component of the power plant. The medium is, for example, the water that is the steam generator 40 is supplied.

In this case, this is the steam generator 40 so that the steam generator 40 over the heat exchanger 44 the heat released in the exothermic chemical reaction is supplied. This is in the figure by a directional arrow 46 illustrated. In the consequence can by means of the steam generator 40 with the aid of the heat released in the context of the exothermic chemical reaction steam can be generated in the manner described, by means of which finally at least a part of the power plant can be kept warm. The heat exchanger 44 is for example in the steam generator 40 arranged so that the heat released in the reverse reaction to the steam generator 40 supplied water can be supplied, causing the steam generator 40 supplied water is evaporated.

In particular, it is conceivable components or components of the gas-and-steam combined cycle power plant 10 to keep warm or warm while the power plant is shut down. As a result, the power plant at a desired power on a sufficiently high and advantageous temperature to enable the power plant by means of a warm start again or turn on.

The power plant is based in particular on the idea during the operation of the power plant heat sources, in particular already available heat sources, such as by means of the exhaust gas of the gas turbine 12 use generated steam to recover heat, which can be stored using the endothermic chemical reaction.

It is provided that at least the part of the in the means of the gas turbine 12 generated steam during normal operation of the power plant is used to effect the endothermic chemical reaction, wherein during normal operation of the generator 30 is driven so that during normal operation by means of the generator 30 electric power is provided.

By switching off the power plant normal operation is stopped. In order to avoid excessive cooling of the power plant, a warming operation is performed after normal operation and due to the shutdown of the power plant, in which the power plant is heated or kept warm by means of the energy released, while a through the generator 30 causing provision of electrical current, in particular during a through the turbine device 22 causes driving of the generator 30 , stays undone.

The branched off, by means of the exhaust gas of the gas turbine 12 produced steam, whose heat is used to effect the forward reaction and, in particular, stored in the products of the forward reaction, for example, has a mass flow of 14.4 kg / s and a temperature of 152 ° C. By a heat transfer from the steam through the heat exchanger 38 For example, the steam is cooled from 152 ° C. to 105 ° C. to the educts of the forward reaction. Furthermore, the steam may for example have a pressure of 5 bar.

Alternatively, it is conceivable that the means of the exhaust gas of the gas turbine 12 generated steam used to effect the forward reaction has a pressure of 38 bar and a mass flow of less than 21.4 kg / s. As a result of the heat transfer from the line 36 or the heat exchanger 38 flowing steam through the heat exchanger 38 to the educts of the forward reaction, the steam is cooled, for example, from 334 ° C to about 247 ° C. This means that the forward reaction takes place, for example, at 152 ° C. or at 334 ° C. For example, the back reaction takes place at 250 ° C so that, for example, the steam generated by the heat released in the back reaction has a temperature of 250 ° C.

Alternatively or additionally to the generation of steam by means of the released heat, it is conceivable to provide steam and to heat this supplied steam by means of the heat released in the exothermic chemical reaction, in particular to overheat it. Thus, the steam for holding the power plant 250 ° C and thereby, for example, in the manner described from a temperature to 250 ° C or 250 ° C to an even higher temperature to be warmed up. The steam for keeping the power plant warm, for example, has a mass flow of 1.4 kg / s to 5 kg / s and a pressure of 5 bar. As part of keeping the power plant warm, heat transfer from the steam generated by the heat released in the reverse reaction to the power plant or components of the power plant, so that the steam, for example, from 250 ° C to a contrast lower temperature, in particular 150 ° C cools. In particular, it is conceivable that the steam, by means of which at least a part of the power plant is kept warm or heated, 250 ° C. The heat to be kept part of the power plant, the steam is supplied to keep warm the power plant, so that a heat transfer from the steam to keep the power plant warm to the power plant or to be kept warm part of the power plant. As a result, the steam is cooled to keep the part of the power plant warm so that the temperature of the steam, for example, drops from 250 ° C to 150 ° C. The steam then has a very high temperature, so that heat contained in the steam after keeping warm at least the part of the power plant can optionally be used for other purposes.

By using the heat exchanger 38 a spatial separation of the reactants of the forward reaction of the branched off steam can be realized, so that the branched off steam does not directly touch the reactants of the forward reaction. Alternatively, it is conceivable that the branched off steam directly touches the educts of the forward reaction and thereby flows against or flows around it. Then, for example, eliminates the heat exchanger 38 , This is also transferable to the reverse reaction: through the use of the heat exchanger 44 For example, a spatial separation of the educts and / or products of the reverse reaction from the medium, which is heated by means of the released heat and used to keep the power plant warm, can be realized, so that the medium does not directly touch the reactants and / or products of the reverse reaction. Alternatively, it is conceivable that the medium directly touches the educts and / or products of the reverse reaction and flows against or flows around. Then, for example, eliminates the heat exchanger 44 ,

Overall, it can be seen from the figure that by utilizing the endothermic reaction, any heat available anyway can be efficiently and effectively stored. The stored heat can in particular be used effectively and efficiently at a later time in order to heat or keep warm at least part of the power plant.

Claims (8)

Method for operating a gas-and-steam combined cycle power plant ( 10 ), in which by means of exhaust gas of a gas turbine ( 12 ) hot steam is generated by means of which at least one turbine device ( 22 ) at least one generator ( 30 ) is powered to provide electric power, characterized in that at least a portion of heat contained in the steam is utilized to effect an endothermic chemical reaction. A method according to claim 1, characterized in that by means of products of the endothermic chemical reaction, an exothermic chemical reaction is carried out, in which heat is released, by means of which at least a part of the gas and steam combined cycle power plant ( 10 ) is heated or kept warm. Process according to Claim 2, characterized in that steam is generated by means of the heat released during the exothermic chemical reaction, by means of which at least the part of the gas-and-steam combined cycle power plant ( 10 ) is heated or kept warm. Method according to claim 2 or 3, characterized in that at least one heat exchanger ( 44 ) is provided, via which at least a part of the heat released to the part of the gas-and-steam combined cycle power plant ( 10 ) or to a medium, in particular a liquid or a gas, or a component ( 40 ) of the gas and steam combined cycle power plant ( 10 ) is transmitted. Method according to one of the preceding claims, characterized in that at least the part of the heat contained in the steam during a normal operation of the gas-and-steam combined cycle power plant ( 10 ) is used to effect the endothermic chemical reaction whereby, during normal operation, the generator ( 30 ) and by means of the generator ( 30 ) Electricity is provided. Method according to Claim 5, in which reference is made to one of Claims 2 to 4, characterized in that, after normal operation, a holding operation is carried out, in which the gas-and-steam combined cycle power plant ( 10 ) is heated or kept warm by means of the released energy, while a through the generator ( 30 ) provides electrical power, in particular a through the turbine device ( 22 ) causes the generator to be driven ( 30 ), is omitted. Method according to one of the preceding claims, characterized in that at least one heat exchanger ( 38 ) is provided, by means of which at least the part of the heat contained in the vapor is transferred to reactants of the endothermic chemical reaction. Gas and steam combined cycle power plant ( 10 ), with at least one turbine device ( 22 ), with at least one of the turbine device ( 22 ) drivable generator ( 30 ) for providing electrical power, and with at least one gas turbine ( 12 ), by means of which exhaust gas can be provided for generating hot steam, by means of which the turbine device ( 22 ) and over this the generator ( 30 ), characterized in that at least one reactor ( 34 ) to which at least part of the heat contained in the steam can be supplied in order to 34 ) by means of the supplied heat from the steam to effect an endothermic chemical reaction.

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