The present invention relates to a system for feeding makeup water into a water steam circuit, and preheating said makeup water, in a steam power plant. In addition, the present invention relates to a method for degasifying makeup water in a water steam circuit in a steam power plant.
When process steam/heat in steam power plants is extracted, owing to leakages and losses of process steam/condensate, the water-steam circuit has to be made up by means of the continuous feeding in of makeup water. The makeup water is as a rule prepared but not degasified. For example, the makeup water contains dissolved foreign gases which have to be expelled again in a degasser of the steam power process. In order to increase the process efficiency, the makeup water has to be preheated before entry into the degasser.
At present, the makeup water is supplied, for example, to a conventional degasification device, directly into the degasser. This is technically simple and involves less cost, but is the most unfavorable variant in terms of energy.
In addition, the makeup water can be fed directly into a turbine condenser or into a low pressure preheater. This variant can, however, only be applied for relatively small quantities of makeup water.
An object of the present invention is to degasify makeup water for a water-steam circuit of a steam power plant in a way which is efficient in terms of energy and costs.
This object is achieved with a system for feeding makeup water via an extra condensate-makeup water preheater of a water-steam circuit in a steam power plant, and with a method for degasifying makeup water in a downstream degasser of a water-steam circuit in a steam power plant according to the independent claims.
According to a first aspect of the present invention, a system for feeding makeup water for a preheater and/or evaporator of a water-steam circuit in a steam power plant is described. The system has a condenser for condensing steam to form water, a degasification device for degasifying water, a feed line for feeding in makeup water, and a heat exchanger.
The condenser for condensing steam to form water (referred to below as “condensate” for the sake of better differentiation) can be supplied with steam from a turbine system of the steam power plant. The degasification device for degasifying water is coupled to the condenser in such a way that a first portion of the condensate can be fed to the degasification device. The heat exchanger is coupled to the condenser in such a way that a second portion of the condensate can be fed to the heat exchanger, wherein the heat exchanger is coupled to a feed line in such a way that makeup water can be fed to the heat exchanger. The heat exchanger is configured in such a way that the makeup water can be heated by means of the second portion of the condensate. The heat exchanger is coupled to the degasification device in such a way that the heated makeup water can be fed to the degasification device.
According to a further aspect of the present invention, a method for degasifying makeup water for an evaporator of a water-steam circuit in a steam power plant is described.
Steam power plants are frequently used nowadays to generate electrical energy. The steam which is necessary to operate the steam turbine is generated in a steam boiler from previously purified and prepared water. Further heating of the steam in the superheater causes the temperature and the specific volume of the steam to increase. The steam flows from the steam boiler via pipelines into a steam turbine system where it outputs a portion of its previously absorbed energy as kinetic energy to the turbine system. A generator, which converts the mechanical power into electrical power, is coupled to the turbine. The expanded and cooled steam then flows into the condenser where it condenses by transmitting heat to the surroundings (for example fresh water from a river) and collects as liquid water at the lowest point of the condenser. This water is referred to as condensate. The water is buffered, for example, in a supply water vessel via the condensate pumps and preheaters or heating devices, and then fed again to the steam boiler or the evaporator via a further condensate pump.
Before the water is buffered in the supply water vessel and correspondingly fed to the evaporator, the water is fed to the degasification device in order to largely remove noxious gases such as, for example, corrosive oxygen or carbon dioxide.
The degasification device according to the present invention can operate by means of a thermal degasification method or by means of a chemical degasification method. In the thermal degasification method, thermal energy, for example from extraction steam (from the medium pressure range) of the turbine system is fed to the degasification device, with the result that the water in the degasification device “comes to the boil” and is therefore heated. As a result, the noxious gases, such as oxygen and carbon dioxide, are largely removed. For the degasification, the physical fact that the solubility of gases in liquids drops as the temperature increases is exploited.
According to the present invention, condensate from the condenser, firstly, and makeup water which was previously heated in the heat exchanger, are fed to the degasification device. The makeup water is necessary, since water and steam in the water-steam circuit escape from the water-steam circuit owing to leakages. This relates, in particular, to systems with external heat consumers, that is to say systems with extraction of process steam.
According to the present invention, a heat exchanger is made available which contains, on the one hand, the second portion of the condensate. In addition, a desired quantity of makeup water is added to the heat exchanger via a feed line. The heat exchanger is configured to heat the makeup water to a desired temperature by means of the heat of the second portion of the condensate. The heated makeup water is subsequently fed (in particular directly) to the degasification device.
The heat exchanger according the present invention is, in particular, a condensate/makeup water heat exchanger. This means that the heat-emitting fluid (here the second portion of the water or of the condensate) does not change its aggregate state and remains liquid, and also the heat-absorbing fluid (here the makeup water) remains liquid and does not change its aggregate state. This results in a very compact design of the heat exchanger compared to condensing heat exchangers.
Since the makeup water is heated in a separate heat exchanger by means of the heat of a second portion of the condensate from the condenser and is subsequently fed in the heated state directly to the degasification device, the system according to the invention is very efficient energetically.
In addition, the makeup water, which can contain noxious gases, is not mixed with the first portion of the condensate until the degasification device. It is therefore possible that the devices (for example heating devices and condensate pumps) as well as the pipelines which may be present between the condenser the degasification device do not necessarily have to be constructed from corrosion-resistant stainless steel, since these devices and pipelines do not come into contact with the corrosive makeup water. With the system according to the present invention it is therefore possible to use not only the extremely energy-efficient design but also more favorable materials for the devices and pipelines between the condenser and the degasification device.
The second portion of the condensate can be smaller than the first portion of the water by at least half. The second portion of the condensate is, in particular, not branched off from the total amount of condensate until downstream of the condenser and downstream of at least one heating device, with the result that the second portion of water has already been heated by means of a heating device before the second portion of the water is fed to the heat exchanger.
According to a further exemplary embodiment, the heat exchanger is coupled to the degasification device in such a way that the second portion of the condensate can be fed to the degasification device after passing through the heat exchanger. Therefore, for example the second portion of the water is mixed with the makeup water and therefore an average temperature between the second portion of the water and the makeup water is set. The makeup water is therefore also heated. The mixture of the second portion of the condensate and the makeup water is subsequently mixed with the first portion of the water in the degasification device.
According to a further exemplary embodiment, the heat exchanger can also be coupled to the condenser in such a way that the second portion of the condensate can be fed again to the condenser after passing through the heat exchanger. As a result, the second portion of the condensate can be mixed again with the water in the condenser and subsequently fed to the water-steam process again. In particular, in a further exemplary embodiment of the invention, the second portion of the condensate is supplied downstream of the condenser and upstream of the heating device after flowing through the heat exchanger, and is mixed with the total amount of the water from the condenser.
According to a further exemplary embodiment, the system has the heating device for heating the water. The heating device is coupled to the condenser in such a way that the condensate can be fed to the heating device. The heating device is coupled to the degasification device in such a way that the heated water, or at least the first portion of the condensate, can be fed to the degasification device.
According to a further exemplary embodiment, the heating device is configured in such a way that the heating device for heating the water can be supplied with steam from the turbine system, in particular from a low pressure range of the turbine system of the steam power plant. In other words, the extraction steam is extracted from the turbine system in order to use the thermal energy of the extraction steam to heat the water downstream of the condenser. The medium pressure range of the turbine system is, in particular, a range which is close to the last turbine stage of the turbine system by virtue of the fact that the steam still has a relatively high level of thermal energy but a relatively low pressure.
According to a further exemplary embodiment, the heating device is coupled between the condenser and the heat exchanger in such a way that the second portion of the condensate can be branched off after the heating of the makeup water in the heating device and can be fed to the heat exchanger.
According to a further exemplary embodiment, the degasification device is configured in such a way that, in order to degasify the water (that is to say the first portion o the condensate and the makeup water heated in the heat exchanger), the degasification device can be supplied with steam from the turbine system, in particular from the low pressure range and/or the medium pressure range of the turbine system, of the steam power plant.
According to a further exemplary embodiment, the system also has a condensate pump which is arranged between the condenser and the degasification device in order to increase the pressure of the water.
With the present invention, the makeup water is not mixed with the condensate until in the degasification device. In order to avoid having to accept any reductions in efficiency as a result of a lack of preheating, the makeup water is heated in the condensate/makeup water heat exchanger by means of a partial stream (the second portion) of the second portion of the condensate which has already been preheated in the low pressure preheaters (heating devices). The second portion of the condensate which is used for heating can be extracted from any desired number of upstream low pressure preheaters and then used for preheating the makeup water in one or more condensate/makeup water heat exchangers. The extraction of the second portion of the water (i.e. of the preheating condensate) between the last heating device (low pressure preheater) and the degasification device is energetically appropriate. In one exemplary embodiment, the second portion of the water (condensate) which is used for preheating is fed back to the turbine condenser after the cooling in the condensate/makeup water heat exchanger.
The second portion of the condensate mass flow which is branched off for preheating the makeup water is preheated by energetically low-value extraction steam, for example from the expansion run of the steam turbine system. With the present invention, a relatively high overall efficiency can be achieved by using energetically low-value low pressure extraction steam from the expansion run of the steam turbine system.
In addition, the construction of the low pressure preheater which is used and which comes into contact with the non-degasified makeup water from corrosion-free steel (for example stainless steel) is dispensed with.
In addition, for example the need to mix the makeup water with the water/condensate in a separate condensate tank is dispensed with. The condensate pump downstream of the condenser therefore only pumps the total amount of water (condensate), which has already been degasified and therefore is less corrosive.
By virtue of the system described above it also becomes economically appropriate to combine the preheating of the makeup water by means of exhaust gas heat exchangers in conjunction with the additional condensate/makeup water heat exchanger. This is made possible because the exhaust gas heating surfaces (installed in this case, for example, as economizers in the exhaust gas duct of refuse burning systems or combined gas and steam power plants) do not have a flow of non-degasified water through them. In addition, as a result of the downstream preheating of the makeup water by means of the partial stream of the condensate, the complicated construction of the heating surfaces of the economizers from special steels (heat-resistant and corrosion-resistant) can be dispensed with.
Compared to conventional systems, the cost of the system can be reduced and, for example, the base area of a machinery house can be made smaller because the additionally installed preheaters for heating the makeup water can be dispensed with (they are necessary in particular in the case of large quantities of makeup water). As a result, the costs for the power plant components are lowered considerably. Furthermore, a very large mass flow of makeup water can be processed. This mass flow of makeup water can exceed the quantity of condensate by more than twice.
It is to be noted that the embodiments described here constitute merely a limited number of possible embodiment variants of the invention. It is therefore possible to combine the features of individual embodiments with one another in a suitable way, with the result that for a person skilled in the art, the embodiment variants which are explicit here can be considered to clearly disclose a multiplicity of different embodiments.
In the text which follows, exemplary embodiments will be described in more detail with reference to the appended figures for the sake of further explanation and for better understanding of the present invention.
Identical or similar components are provided with identical reference symbols in the figures. The illustrations in the figures are schematic and not to scale.
In particular, the heated makeup water is supplied to the heating device 109 directly downstream of the heat exchanger 102 and is not mixed with the first portion or the first mass flow M1 of the condensate of the condenser 101 until in the heating device 109.
The heat exchanger 102 can be coupled to the degasification device 109 in such a way that the second portion (or a second mass flow m2) of the condensate can be fed to the degasification device 109 after passing through the heat exchanger 102. Alternatively, as illustrated in
At least one heating device 106 or, for example, a further multiplicity of further heating devices 108, can be coupled between the condenser 101 and the degasification device 109. The heating devices 106, 108 heat the entire mass flow of the water which flows from the condenser 101 in the direction of the degasification device 109. As is illustrated, for example, in
The heating devices 106, 108 can be configured in such a way that, in order to heat the condensate, the heating devices 106, 108 can be supplied with steam (extraction steam) from the turbine system 105, in particular from a low pressure range of the turbine system 105, of the steam power plant.
The degasification device 109 is configured in such a way that, in order to degasify the water, the degasification device 109 can be supplied with steam from the turbine system 105, in particular from a low pressure range of the turbine system 105, of the steam power plant.
In addition, a condensate pump 104 can be coupled upstream or downstream of the heating devices 106, 108 in order to increase the pressure of the overall mass flow of the water downstream of the condenser 101.
In addition it is to be noted that “comprising” does not exclude any other elements or steps, and “a” or “an” does not exclude a plurality. In addition, it is to be noted that features or steps which have been described with reference to one of the above exemplary embodiments can also be used in combination with other features or steps of other exemplary embodiments described above. Reference symbols in the claims are not to be considered as restrictive.
Number | Date | Country | Kind |
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13175367.5 | Jul 2013 | EP | regional |
This application is the US National Stage of International Application No. PCT/EP2013/071814 filed Oct. 18, 2013, and claims the benefit thereof. The International Application claims the benefit of European Application No. EP13175367 filed Jul. 5, 2013. All of the applications are incorporated by reference herein in their entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2013/071814 | 10/18/2013 | WO | 00 |