EP2746656A1 - Drainage of a power plant assembly - Google Patents

Abstract

The power plant (1) has drainage lines (11) fluidically connected to an upstream side of a water-steam circuit (2) and fluidically connected on a downstream side of an overpressure vessel (20). A steam-conducting supply line (12) is fluidically connected to the overpressure vessel for supplying steam to the water-steam-circuit. An atmospheric pressure container (30) is connected with the overpressure vessel such that the steam is conducted from the overpressure vessel to the pressure container. The pressure container is connected with a recirculation pipe (40). An independent claim is also included for a method for operating power plant.

Description

The present invention relates to a power plant, in particular a coupled gas and steam power plant, which has a number of drainage pipes for dewatering a water-steam cycle, and a method for operating such a power plant.

Steam-powered power plants, in particular coupled gas and steam power plants, have a water-steam cycle, which can sometimes be designed as one or more circulating steam generator with steam drums and the associated heating surfaces. Such circulation steam generators are usually subdivided into a high-pressure stage, a medium-pressure stage and a low-pressure stage, depending on their working pressure regime. Within individual pressure stages of the water-steam cycle, by absorbing thermal energy, steam (hereinafter referred to simply as steam) is generated which can be supplied to one or more steam turbines for generating electric energy. Instead of a circulation steam generator of the power plant, the steam generator can also be designed as a forced flow steam generator (Benson boiler, Sulzer boiler, etc.). However, such circulation steam generators are usually provided only in the high-pressure stage of the water-steam cycle, but can in principle also be provided for the lower pressure stages.

Due to numerous chemical and physical processes fall in the water-steam cycle during operation of the power plant more or less heavily contaminated wastewater. In order not to impair the readiness of the power plant during operation by these impurities, it is necessary to drain the power plant and thus remove the impurities or wastewater from the water-steam cycle. Such drainage is typically during ongoing operation of the Power plant made. In this case, the drains are discharged from normally closed in regular operation lines in which the wastewater has accumulated. For discharging the relevant lines are opened for a short time and derived the drainages. During the drainage, the water-steam circuit is thus lost water, which must be supplied again by additional water, so-called deionized, the water-steam cycle.

In addition, condensate water collects in the pipes of the water-steam cycle, which precludes an efficient use of the water-steam cycle. Such condensation water is formed, in particular due to time-varying operating conditions in the water-steam cycle. Condensation water falls so for example when you shut down the power plants in the water-steam cycle, since at decreasing operating temperatures, the vapor contained in the water-steam cycle condenses increasingly condensed and the resulting condensed water also accumulates in parts of the system, for a longer Contact with liquid water are not provided. In this respect, when powering down a power plant it is necessary to remove more water from the water-steam cycle in order to avoid unwanted condensation of water in unscheduled parts of the plant. At the same time less water is refilled in the water-steam circuit when driving down to keep at the end of the Abfahrprozesses relevant plant components largely free of condensed water.

In order to remove such condensation water from the water-steam circuit, it also makes use of suitable drainage pipes, which are fluidly connected to the water-steam cycle. Sometimes these are identical to the drainage pipes for the discharge of contaminated waste water from the water-steam cycle.

At this point, it should be noted that in the sense of the present invention drainage of the power plant Both contaminated wastewater, as well as sludge, may be, as well as condensed water that has accumulated in unintended areas of the water-steam cycle.

According to the prior art, it is already known to collect drainages from different parts of the water-steam circuit, in particular from different pressure stages, and to guide them together. Here, the drainages, such as in the WO 2006/058845 described, be cached in a tank for further treatment.

A disadvantage of these solutions of the prior art, however, is that the caching of the drainages, the thermal energy therein can not be made usable. Rather, the thermal energy is dissipated unused in discarding the drainage into the environment from the power plant. In addition, it turns out to be disadvantageous that introduced into the water-steam cycle to replace the drains drainage additional water must be re-treated thermally to be raised to a temperature level, which is already present in the water-steam cycle water corresponds or comes sufficiently close. This, in turn, requires the expenditure of thermal energy and makes the energy balance of the power plant unfavorable. In addition, it proves to be disadvantageous that the drained from the water-steam cycle drainages must be processed in an energetically complex process, in particular to separate the slurries of reusable as deionized water. It is particularly unfavorable in terms of the balance of resources, if the treated water is no longer returned to the water-steam cycle, but is discarded as in the environment.

According to these disadvantages, which are known from the prior art, it turns out to be technically necessary to propose a solution for the dewatering of a power plant, which avoids the disadvantages known from the prior art. In particular, the technical solution to be proposed is intended to enable an energetically advantageous use of the energy extracted by the discharge of dehydrations from the water-steam cycle. In other words, it should be made with respect to the overall energy balance of the power plant operation improved drainage. Moreover, it is desirable to make available again the energy dissipated from the water-steam cycle and the drainages for the power plant and in particular for the water-steam cycle.

These objects of the present invention are achieved by a power plant according to claim 1 and by a method for operating such a power plant according to claim 14.

In particular, these objects of the invention are achieved by a power plant, in particular a coupled gas and steam power plant, comprising a number of first drainage pipes, which are fluidly connected upstream with a water-steam cycle, and which are fluidly connected downstream with a pressure vessel , Wherein further at least one steam leading supply line is fluidly connected to the pressure vessel over which steam can be re-supplied to the water-steam cycle.

• Entwässern von Wasser und /oder Dampf aus einem Wasser-Dampf-Kreislauf durch Zuführen an einen Überdruckbehälter;
• Zurückführen von Dampf aus dem Überdruckbehälter an den Wasser-Dampf-Kreislauf.

Furthermore, the objects underlying the invention are achieved by a method for operating a power plant, in particular a coupled gas and steam power plant, preferably a power plant as described above and below, comprising the following steps:

• Dewatering water and / or steam from a water-steam cycle by supplying to a pressure vessel;
• Returning steam from the pressure vessel to the water-steam cycle.

The idea of the invention teaches the dehydration of the water-steam cycle by means of a number of first drainage lines, which are fluidly connected upstream of the water-steam cycle upstream. When draining the drains through these drainage pipes, the first drains are introduced into a pressure vessel in which a relaxation can be set to a relatively lower pressure level compared to the pressure level of the water-steam cycle. However, the pressure vessel further has a pressure level which is above the ambient pressure level. In this respect, there is an overpressure level in it. During the relaxation, on the one hand, there is a reduction in the temperature level of the introduced dehydration and, preferably, at least a partial evaporation of the liquid dehydration. The steam present in the overpressure container, which furthermore has usable thermal energy, is again supplied to the water-steam cycle for further use via the supply line which is fluidly connected to the overpressure container. This is particularly unproblematic, since this steam contains no impurities and thus the water-steam cycle can be fed back in "purified" form. When relaxing in the pressure vessel, the impurities remain largely or even substantially completely in the liquid phase, ie in the liquid water.

It is advantageous that the thermal energy contained in the recirculated steam can again be available for power generation in the water-steam cycle of the power plant. Furthermore, this back the water-steam cycle recycled steam saves the use of additional make-up water, which in turn would be reprocessed before it could be fed to the water-steam cycle.

Furthermore, it is advantageous that the accumulation of dehydration and of steam, which must be supplied to the environment, can be drastically reduced in terms of quantity. As a result, the sometimes relatively strict regulatory requirements and environmental regulations can be met more easily.

In addition, as already indicated, the addition of additional water (deionized) to replace the drains drained significantly reduced, whereby the necessary desalination for the deionized cost and energy technology can be advantageously reduced.

Compared to the normal operation known from the prior art, a power plant with the present invention can thus be operated both economically and environmentally friendly and thus with higher efficiency.

At this point it should be pointed out again that the concept of steam in the sense of vaporous water should be understood, as it occurs, for example, in the water-steam cycle. The quality of the water, for example, due to an alternating content of various impurities, should have no influence on the conceptual meaning. Similarly, the term of the water should include wastewater as well as in the water-steam cycle remaining useful water or condensation water. The same applies to the steam discharged from the water-steam cycle as well as to the useful steam remaining in the water-steam cycle. In this respect, according to the case, the concept of water or steam can also be equated with the concept of drainage.

According to the embodiment, it is also possible that the number of first drainage pipes is "one", ie according to the invention the power plant only comprises one drainage pipe. According to the execution of the pressure vessel is due to its pressure level compared to the pressure level of the water-steam cycle as well as compared to the pressure level of the environment as a pressure relief tank.

According to a first preferred embodiment of the power plant according to the invention, it is provided that the number of first drainage lines upstream with the water-steam cycle in the high-pressure and / or medium-pressure stage, in particular in the steam drum of the high-pressure and / or steam drum of the medium-pressure stage are interconnected. A fluidic interconnection "in the area" means in local proximity, wherein a fluidic interaction is brought about. In particular, according to the embodiment, the interconnection with the high-pressure and / or medium-pressure stage, or the steam drum of the high-pressure and / or steam drum of the medium-pressure stage. Likewise, the interconnection can also take place with a forced-circulation steam generator of the high-pressure and / or a forced-circulation steam generator of the medium-pressure stage.

Alternatively or additionally, the number of first drainage lines upstream can also be connected to the water-steam circuit in the region of the low-pressure stage, in particular in the region of the steam drum of the low-pressure stage. Similarly, the interconnection can also be done with a forced flow steam generator of the low pressure stage.

Due to the pressure levels prevailing in the high-pressure and / or medium-pressure stage, there is an advantageous introduction, in particular an energetically advantageous introduction of the water or steam removed from the water-steam cycle into the overpressure container. According to the embodiment, there is a change in the pressure level, in particular a relaxation of the steam, wherein the dehydration discharged into the pressure vessel again advantageously returns to the water-steam cycle when it is in the vapor phase can be. Due to the relatively higher pressure level of the derived from the high-pressure and / or medium-pressure steam is in particular in the pressure vessel before a relatively higher pressure level, which favors the return to the water-steam cycle energetically.

According to a further advantageous embodiment, it is provided that the feed line leading at least one steam can supply steam to the water-steam circuit in the region of the low-pressure stage, in particular in the region of the steam drum of the low-pressure stage. The term "in the field" means in the local area, as stated above. According to the embodiment, the connection is made, in particular, with the low-pressure stage, in particular the steam drum of the low-pressure stage. Due to the prevailing in the low pressure stage relatively lower pressure levels, a transfer of steam from the pressure vessel in the water-steam cycle is energetically particularly favorable. In particular, it is conceivable that the pressure level of the vapor in the pressure vessel is not substantially below the pressure level of the low pressure stage or even at the same pressure level or above. In this respect, the low-pressure stage is suitable for printing, and thus energy technology for returning the discharged from the pressure vessel vapor particularly.

According to a further advantageous embodiment of the invention, it is provided that the power plant also has an atmospheric pressure vessel, which allows a vapor release to substantially atmospheric pressure, and which is line connected to the pressure vessel so that steam from the pressure vessel can be passed into the atmospheric pressure vessel. The atmospheric pressure vessel and the pressure vessel are thus ready for the accumulation of drainages. The drains are passed in vapor phase from the pressure vessel into the atmospheric pressure vessel, wherein the pressure vessel transferred to a correspondingly lower pressure level can be. Thus, the atmospheric pressure vessel serves on the one hand to accumulate dehydration and at the same time also to regulate the pressure of the pressure in the pressure vessel. Furthermore, the atmospheric pressure container allows a suitable discharge of the drainages, without the pressure vessel, such as during operation, must be subjected to printing changes. For example, it is possible to discharge condensed drainages from the atmospheric pressure container into the environment, this happening at a point in time when the atmospheric pressure container and the overpressure container are not interconnected in any fluid connection. According to the invention, relaxation to substantially atmospheric pressure level should include a pressure level corresponding to the atmospheric pressure level with a pressure tolerance of up to 20%.

Furthermore, it is also possible that adjusting means are included in the power plant, which are adapted to adjust the amount of steam which can be passed from the pressure vessel into the atmospheric pressure vessel. In particular, the adjusting means between the pressure vessel and atmospheric pressure vessel is connected by line technology. Accordingly, the actuating means can dissipate the fluid connection between the pressure vessel and the dewatering tank when discharging the condensate drainages located in the atmospheric pressure vessel, so that removal from the atmospheric pressure vessel can be carried out without further influence with respect to the change of the pressure level in the pressure vessel.

According to a further advantageous embodiment of the invention, it is provided that a number of second drainage lines is connected, which are connected upstream with the water-steam cycle, and which are connected downstream of the atmospheric pressure tank, and via which water and steam from the water Steam cycle can be fed to the atmospheric pressure vessel. According to the embodiment, therefore, water and steam from the water-steam cycle, which is in particular at a relatively low pressure level, are transferred to the atmospheric pressure vessel. It may also prove advantageous, according to the embodiment, to transfer dehydrations from the water-steam cycle into the atmospheric pressure vessel if the dewatering collected therein is to be subjected to a different treatment form than the dehydration collected in the overpressure vessel.

According to the embodiment, it is further possible for the number of second drainage lines to be "one", i. According to the invention, the power plant comprises only a second drainage line.

According to a particularly advantageous continuation of this idea, it is provided that the number of second drainage lines is connected upstream to the water-steam cycle in the region of the low-pressure stage. As stated above, the terminology "within range" in a local area. In particular, according to the embodiment, the interconnection with the low-pressure stage. The pressure level in the low-pressure stage is sometimes sufficiently low to transfer steam into the atmospheric pressure vessel, which can not be energetically used to return to the water-steam cycle. In this respect, it seems advantageous to supply the drains discharged from the high-pressure and / or medium-pressure stage to the overpressure container, whereas the liquid drains discharged from the low-pressure stage are preferably provided for rejection into the environment. Vapor drains discharged from the low-pressure stage can preferably also be supplied to the overpressure container, as already explained above.

According to a further advantageous aspect of the invention it is provided that the atmospheric pressure container is connected to a recirculation line, which allows water from the atmospheric pressure container of a first Supplying cold source, and returned the so thermally treated water again in the atmospheric pressure vessel. The recirculation of water from the atmospheric pressure vessel allows the prevention of steam formation in the atmospheric pressure vessel.

According to a further embodiment of the power plant according to the invention, the overpressure container and / or the atmospheric pressure container is line-connected with a second cold source, which makes it possible to thermally treat water discharged from the overpressure container and / or the atmospheric pressure container. In this respect, for example, the drains discharged from the pressure vessel or the atmospheric pressure vessel can be cooled before further processing or separation and cleaning. This cooling is required for most purification processes known from the prior art. This cooling can in turn be done by means of water from the main capacitor of the power plant or water from an intermediate cooling to provide the second source of cold. The water thus treated can, according to the embodiment, again be provided for recycling into the water-steam cycle as a deionate.

According to a further embodiment of the invention, it is provided that the overpressure container and / or the atmospheric pressure container is line-connected with a collecting container, in which water located in the overpressure container and / or in the atmospheric pressure container can be transferred for storage. The collecting container is capable in particular of the collection of condensed drainages and allows the merging of these before, for example, a further cleaning and treatment of these drains can take place. The merger is particularly useful and advantageous in terms of process technology and energy.

According to a further development of this embodiment according to the invention, provision is made for the collecting container to be connected to a processing unit by line technology, wherein the processing unit can at least partially clean the water from impurities. After cleaning the present as drainage water by means of the treatment unit, the recycled water can be supplied to the water-steam circuit again as additional water (deionized).

According to a continuation of this idea, it is also possible that the collecting container and / or the treatment unit is connected in terms of line technology with the main capacitor of the power plant such that water can be supplied from this to the main capacitor. As in the entire application, the main capacitor corresponds to the capacitor in which the steam is condensed, which is fed to the steam turbine or steam turbines for power generation.

The invention will be explained in more detail below with reference to individual figures. In this case, the features with the same technical effect preferably have the same reference numerals.

It should also be pointed out that the figures are merely a schematic representation of the idea of the invention, which represents no restriction as to the feasibility of the invention.

Furthermore, the individual features shown in the following figures are claimed in isolation as well as in any combination with other features as far as they fall under the present invention idea.

Figur 1

eine schematische Darstellung einer Ausführungsform der erfindungsgemäßen Kraftwerksanlage;

Figur 2

eine flussdiagrammatische Darstellung einer Ausführungsform des erfindungsgemäßen Verfahrens zum Betreiben einer Kraftwerksanlage;

Hereby shows:

FIG. 1

a schematic representation of an embodiment of the power plant according to the invention;

FIG. 2

a flowchart representation of an embodiment of the inventive method for operating a power plant;

FIG. 1 shows a possible embodiment of the present inventive power plant 1, which has a water-steam cycle 2. According to the embodiment, the water-steam circuit 2 is comprised by the steam part of a gas and steam power plant 1. Here, the water-steam cycle 2 a total of three different pressure levels 3, 5, 7, which serve for steam preparation. The steam processed in these pressure stages 3, 5, 7 is supplied to the power generation of a steam turbine 90 (or several steam turbines 90), which is fluidly connected to a main condenser 100 as a cold source. Likewise, it is possible for the steam prepared in the pressure stages 3, 5, 7 to be led to the main condenser 100 via condensation diverter stations not provided with reference numerals.

In order to supply the resulting in a start-up or shutdown or normal operation or in standstill operation of the power plant 1 drainages in the respective pressure levels 3, 5, 7, a cleaning or recycling according to the invention in the water-steam cycle 2, sees the power plant 1 before a number of first drainage pipes 11, which allow the extracted from the pressure stages 3, 5, 7 dewatering a pressurized container 20 zuzuleiten. In this case, the first drainage lines 11 are fluidically connected upstream with corresponding line sections of the respective pressure stage 3, 5, 7. In particular, the first dewatering lines 11 upstream fluidly connected to a flange of a forced continuous steam generator of the high-pressure stage 3 not shown further upstream or the steam drum 6 of the medium-pressure stage. with no further shown flange of a forced flow steam generator of medium pressure stage 5 be interconnected. Likewise, there is a possible interconnection with steam drum 8 of the low-pressure stage 7, to which, however, according to the embodiment can be dispensed with. According to another advantageous embodiment, this latter first drainage line 11 is not provided for the discharge of drains from the low pressure stage 7 in the pressure vessel 20.

After initiation of the dehydration in the pressure vessel 20 is a separation into vapor and liquid fractions of the dehydration, wherein the vaporous components can be advantageously recycled back into the water-steam cycle 2. Since the steam is not present in contaminated form, can thus easily be provided without further purification of the water-steam cycle treated water / steam. For this purpose, a supply line 12 is fluidly connected to the pressure vessel 20, which is connected downstream of the steam drum 8 of the low-pressure stage 7. It is thus possible to supply the steam present in the overpressure container 20, the low-pressure stage 7 operated at a lower pressure level compared to the high-pressure stage 3 or intermediate-pressure stage 5, whereby the steam thus recirculated is again available for electrical power generation by means of the turbine 90 (steam turbine) can stand. In this case, the turbine 90 can likewise be designed as a number of individual turbines which are suitably connected to the respective pressure stages 3, 5, 7.

Furthermore, the power plant 1 comprises an atmospheric pressure tank 30, which is also fluidly connected to the pressure vessel 20. In the line provided between the overpressure container 20 and the atmospheric pressure container 30 for connection, an adjusting means 25 is also provided, which allows to interrupt the fluid connection or to adjust the fluid flow suitable. Thus, it is possible to transfer the steam present in the overpressure container 20 to the atmospheric pressure container 30 during operation. This can on the one hand the pressure level in the pressure vessel 20 can be suitably set, and on the other hand, the dehydration resulting in the atmospheric pressure vessel 30 can be appropriately discharged without simultaneously having to change the pressure level in the pressure vessel 20. Thus, according to the embodiment, a discharge line 35 is provided, via which, in particular, vaporous water can be supplied from the atmospheric pressure container 30 to the environment / environment U.

For dewatering the working at a relatively lower pressure level low pressure stage 7 second drainage lines 13 are also provided, which allow a transfer of incurred in the low pressure stage 7 drainages in the atmospheric pressure vessel 30.

In order to recycle the dehydrations incurred in the overpressure container 20 and the atmospheric pressure container 30, in particular in liquid form, for further use in the water-steam circuit 2, they can be diverted into a collecting container 70. For thermal conditioning, in particular for cooling these drainages before introduction into the collecting container 70, according to the invention a first cold source 50 as well as a second cold source 60 are provided.

In addition, the power plant 1 provides a recirculation line 40, which drainages can be taken from the atmospheric pressure tank 30 to supply them to the first cooling source 50. Thereafter, the so thermally conditioned dehydrations are completely or partially recycled to the atmospheric pressure vessel 30, but at a lower temperature level. This temperature treatment allows the reduction of undesirable steam formation in the atmospheric pressure tank 30, because the steam is condensed.

• Entwässern von Wasser und/oder Dampf aus einem Wasser-Dampf-Kreislauf (2) durch Zuführen an einen Überdruckbehälter (20)(erster Verfahrensschritt 200);
• Zurückführen von Dampf aus dem Überdruckbehälter (20) an den Wasser-Dampf-Kreislauf (2) (zweiter Verfahrensschritt 210) .

FIG. 2 shows a flowchart diagram of an embodiment of the method according to the invention for operating a power plant. The following steps are included:

• Dewatering water and / or steam from a water-steam cycle (2) by supplying to an overpressure container (20) (first method step 200);
• Returning steam from the pressurized container (20) to the water-steam circuit (2) (second method step 210).

Further embodiments emerge from the subclaims.

Claims (14)

Power plant (1), in particular a coupled gas and steam power plant (1), comprising a number of first drainage pipes (11), which are fluidly connected upstream with a water-steam circuit (2), and which downstream with a pressure vessel (20 ) are fluidically interconnected, wherein further at least one steam supply line (12) with the pressure vessel (20) is fluidly connected, via which steam the water-steam cycle (2) can be fed again. Power plant according to claim 1,
characterized in that the number of first drainage pipes (11) upstream of the water-steam cycle (2) in the high-pressure (3) and / or medium-pressure stage (5) are connected. Power plant according to one of claims 1 or 2,
characterized in that the number of first drainage lines (11) upstream of the water-steam cycle (2) are connected in the Nierdruckstufe. Power plant according to one of the preceding claims,
characterized in that the at least one steam leading supply line (12) the water-steam circuit (2) in the region of the low pressure stage (7), in particular in the region of the steam drum (8) of the low pressure stage (7) can supply steam. Power plant according to one of the preceding claims,
characterized in that the power plant (1) further comprises an atmospheric pressure tank (30), which is a vapor release to substantially atmospheric pressure allows, and which with the pressure vessel (20) line technology is connected so that steam from the pressure vessel (20) in the atmospheric pressure vessel (30) can be passed. Power plant according to one of the preceding claims,
characterized in that further comprises an adjusting means (25) of the power plant (1), which is adapted to adjust the amount of steam which can be passed from the pressure vessel (20) in the atmospheric pressure vessel (30). Power plant according to one of the preceding claims 5 or 6,
characterized in that it comprises a number of second drainage conduits (12) connected upstream of the water-steam circuit (2) and connected downstream of the atmospheric pressure tank (30), and via which water and / or steam from the water-steam circuit (2) the atmospheric pressure vessel (30) can be fed. Power plant according to claim 7,
characterized in that the number of second drainage lines (13) upstream of the water-steam circuit (2) in the region of the low-pressure stage (7) is connected. Power plant according to one of the preceding claims 5 to 8,
characterized in that the atmospheric pressure tank (30) is connected to a recirculation line (40) which allows water from the atmospheric pressure tank (30) to be supplied to a first cold source (50) and the water thus thermally treated is returned to the atmospheric pressure tank (30) leads. Power plant according to one of the preceding claims,
characterized in that the overpressure container (20) and / or the atmospheric pressure container (30) with a second cooling source (60) is connected by line technology, which allows to treat thermally from the pressure vessel (20) and / or the atmospheric pressure vessel (30) discharged water , Power plant according to one of the preceding claims,
characterized in that the overpressure container (20) and / or the atmospheric pressure container (30) is line-connected with a collecting container (70) in which corresponding in the pressure vessel (20) and / or the atmospheric pressure vessel (30) located water transferred to storage can be. Power plant according to claim 11,
characterized in that the collecting container (70) is connected in terms of line technology with a treatment unit, wherein the treatment unit can at least partially clean the water from impurities. Power plant according to claim 11 or 12,
characterized in that the collecting container (70) and / or the treatment unit is connected in terms of line technology with the main capacitor (100) of the power plant (1) such that water from these can be fed to the main capacitor (100). Method for operating a power plant (1), in particular a coupled gas and steam power plant (1), preferably one according to the preceding claims, comprising the following steps: - Dewatering of water and / or steam from a water-steam cycle (2) by supplying to a pressure vessel (20); - Returning steam from the pressure vessel (20) to the water-steam circuit (2).

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