DE10019547A1 - Feeding heating condensate into power generator water-steam circuit, involves feeding heating condensate directly into condensate pump on suction side or condensate line near pump - Google Patents

Abstract

The method involves feeding the heating condensate directly into the condensate pump (18) on the suction side or into the condensate line (16) near the condensate pump. Each heating condensate line (28,32) for a heating condensate leads to a common heating condensate line (34) and the common heating condensate collection line feeds all the condensate to the suction side of the pump Independent claims are also included for the following: an arrangement for implementing the method.

Description

The invention relates to a method for introducing heating condensate into the condensate sat of a water-steam cycle of a power plant, the heating condensate condensed steam from at least one associated with a low pressure preheater neten tap, and which is coming from at least one capacitor Condensate supplied by means of at least one condensate line to a condensate pump is leading. The invention also relates to an arrangement for carrying out the Process for introducing heating condensate into the water-steam cycle of a Power plant, with at least one low pressure preheater, with at least one Tap associated with low pressure preheater, with a condensate pump, with at least one heating condensate line, with a condenser, and with little least one condensate line.

Power plants with at least one steam turbine usually have a water Steam cycle, which is a heat source, for example a fossil-fueled boiler sel or a waste heat boiler, etc., and a heat sink, usually a Kon capacitor.

The water-steam cycle is usually a closed cycle, the Media in particular by means of pumps, for example a condensate pump and a feed water pump, are constantly circulated.  

To improve the efficiency of this cycle, the water is on the path between the condenser and the boiler, to a certain temperature preheated temperature so that the boiler at the highest possible water temperature its heat supply can begin. Usually several heat exchangers are used for this, the so-called preheaters, which correspond to their installation location and the one there prevailing pressure of the water, as low pressure or as high pressure preheater be designated.

The preheaters receive the thermal energy for this temperature increase of what sers by steam, which at certain points of the steam turbine or steam plant tion between the boiler and the steam turbine, the so-called taps men and is fed to the preheaters via so-called tap lines. In the pre-heater condenses the bleed steam to form heating condensate Steam cycle is supplied in turn.

The heating condensate from the low pressure preheaters becomes the water vapor Circuit fed back, for example, directly into the capacitor is conducted and there due to the pressures prevailing in the condenser as well Temperatures evaporate. This steam is released together with the steam from the Steam turbine cooled by the condenser. The resulting condensate collects at a low point in the condenser, the condensate collector.

The residual heat of the heating that can still be used for the water-steam cycle Condensate is in this way from the cooling medium, such as cooling water cools the condenser, dissipated without technical use.

In order to use this heat and thus avoid loss of efficiency, additional heat exchangers, so-called subcoolers, are often installed extract the residual heat from the heating condensate and this from the condensate on the Feed the pressure side of the condensate pump. The undercooled heating condensate can now be fed to the condenser, whereby evaporation is now avoided that will.  

Starting from this prior art, it is an object of the invention to provide a method ren specify by means of which the residual heat of the heating condensate in a simple Way is introduced into the condensate of the water-steam cycle. It is also The object of the invention is to provide an arrangement for the method according to the invention create.

According to the invention, these tasks are achieved by the method with the in the claim 1 mentioned features and by the arrangement with the genann in claim 5 characteristics solved.

Accordingly, the heating condensate is fed directly into the condensate pump on the suction side or in the condensate line in the vicinity of the condensate pump headed.

The condenser and the condensate pump are on different geodesic Heights. In this way, the condensate pump receives an inlet pressure chend the condensate column, which is between the condenser and the condensate pump forms.

The heating condensate is now fed into the condensate pump. Advantageously the heating condensate at the point of introduction is under the pressure that the condensate sat builds up at this point and thus prevents the heating condensate from evaporating can. The residual heat carried by the heating condensate heats the condensate through the introduction accordingly. This is a technically simplified way Increased efficiency of the water-steam cycle achieved.

If the residual heat was previously intended to be used by aftercoolers, can now advantageously be omitted according to the invention, what the scarf tion of the water-steam cycle is also simplified, an effect degree improvement through the use of residual heat is nevertheless achieved.

The heating condensate can advantageously be passed directly to the condensate pump the. Alternatively, and also advantageously, the heating condensate can also into the condensate line in the area of the condensate pump. Important here  is that the discharge point is chosen so that there is a sufficiently high pressure prevails so that the heating condensate does not evaporate. As a rule, the same thing are therefore in the immediate vicinity of the condensate pump, at least on a geodetic height, which corresponds approximately to that of the condensate pump or ensures a pressure that prevents evaporation of the heating condensate.

In one embodiment of the method, the heating condensate is first made from ver different heating condensate lines to a common heating condensate line led and then directed to the condensate pump. The circuit of the water Steam circuit and piping is advantageously simplified.

There is again the possibility of the entire heating condensate in the condensate initiate the sat pump directly, or into one or the condensate line.

However, the individual heating condensate lines can also easily handle the respective one Feed the heating condensate to the condensate pump.

The arrangement according to the invention is characterized in that at least one Heating condensate line is present, on the one hand with the associated Nieder preheater and on the other hand with the suction side of the condensate pump is connected that heating condensate from the low pressure preheater in question Suction side of the condensate pump flows, and that due to the pressure conditions in the heating condensate line in question prevents evaporation of the heating condensate that is.

By introducing the heating condensate to a point on the suction side of the con condensate pump, at which evaporation is avoided, is advantageously achieved, that the residual heat of the heating condensate gets into the condensate. An effect Degree improvement of the water-steam cycle has been achieved.

To adjust the pressure upstream of the condensate pump or the pressure differences between the condenser and the condensate pump and between a preheater and the condensate pump, especially geodetic  The locations of the locations of the components mentioned are selected accordingly the.

Furthermore, it may be advantageous to start the individual heating condensate lines to form a heating condensate manifold. The pipeline guide tion is simplified in this way.

Whether the individual heating condensate lines or the heating condensate manifold di into the condensate pump, or first lead into the condensate line, plays for the inventive concept a subordinate role.

An essential feature is that the heating condensate at one point on the Suction side of the condensate pump succeeded, due to the pressure conditions is prevented from evaporating. Such a place is in the area of the condensate pump, in close proximity to this.

Using the embodiments shown in the drawings, the Er invention, advantageous embodiments and improvements of the invention, and be special advantages of the invention are explained and described in more detail.

Show it:

The only figure is a section of a diagram of a water-steam cycle on.

The only figure represents a section of a diagram of a water-steam cycle run as it is intended for a power plant with a steam turbine. In the next Example is chosen a steam turbine with a condenser. But there is also steam turbines, which have, for example, a four-flow steam section and accordingly two double-flow low-pressure turbine sections, each with a condenser exhibit. However, the idea of the invention is easily transferred to such an arrangement bar.

The hatched area, marked with the word "installation level", should symbolize that the components specified below in the specified  NEN at different heights, based on this installation level represents are. Only an approximate qualitative statement should be made. Quantitative information, such as dimensions or ratios, is on the Scheme avoided.

A first low-pressure preheater 14 is present in a condenser 10 , which has a condensate collector 12 at its lowest point. At the approximately lowest point of the condensate collector 12 , a condensate line 16 is connected which leads the condensate collecting in the condensate collector 12 to the suction side of a main condensate pump 18 . The required inlet height for the main condensate pump 18 is achieved via the choice of the installation locations of the main condensate pump 18 and the condenser 10 , thus via a condensate column in the condensate line 16 . In addition, the main condensate pump 18 is driven by a motor 20 .

On the pressure side of the main condensate pump 18 , a pressure-side condensate line 22 connects and directs the condensate to the first low-pressure preheater 14 , through this, further to a second low-pressure preheater 24 , through this and finally to further preheaters, which in the single figure are not are shown.

The first low-pressure preheater 14 receives steam via a first tap 26 , which is usually taken from the low-pressure turbine section of the steam turbine, the steam cooling and condensing in the first low-pressure preheater, and thus becoming a first heating condensate, which is located in the region of the deepest point of the first low pressure preheater 14 collects. The heat energy emitted by the steam is transferred to the condensate and in this way increases its temperature.

The first heating condensate is derived via a first heating condensate line 28 from the most low-pressure preheater 14 .

The second low-pressure preheater 24 is comparable to the first low-pressure preheater 14 and is provided with steam by means of a second tap 30 . The steam condenses to a second heating condensate, which is conducted from the second low-pressure preheater 24 by means of a second heating condensate line 32 .

The first 28 and the second heating condensate line 32 are led to a heating condensate line 34 , which in turn conducts the entire heating condensate into the condensate line 16 . The heating condensate manifold 34 is located at the same level as a main condensate pump 18 . The heating condensate is therefore fed together with the condensate from the condenser 10 to the main condensate pump 18 . This ensures that the usable amount of heat that the Heizkon condensate still contributes to preheating the condensate, thus improving the efficiency of the water-steam cycle.

For the heating condensate pressure at the various points in the heating condensate lines 28 and 32 , in addition to the known parameters, such as pressure at the tap, temperatures in the low-pressure preheater, etc., the altitude of the installation locations - in the example of the only figure - of the first 14 and the second low pressure preheater 24 determining the heating condensate pressure. In particular, the heating condensate pressure at the point of the condensate line 16 at which the condensate and the heating condensate are brought together is interesting. In order to avoid evaporation of the heating condensate in this area, the corresponding heights of the installation sites for the first 14 and the second low pressure preheater 24 should be selected accordingly.

Claims (10)

1. A method for introducing heating condensate into the condensate of a water-steam circuit of a power plant, the heating condensate being condensed steam from at least one tap ( 26 , 30 ) associated with a low-pressure preheater ( 14 , 24 ), and wherein at least one Condenser come de condensate is fed to a condensate pump by means of at least one condensate line ( 16 ), characterized in that the heating condensate is introduced directly into the condensate pump ( 18 ) on its suction side or into the condensate line ( 16 ) in the vicinity of the condensate pump. 2. The method according to claim 1, characterized in that the respective, a low pressure preheater ( 14 , 24 ) associated heating condensate line ( 28 , 32 ) leads the corresponding heating condensate to a common heating condensate line, and that the common heating condensate manifold ( 34 ) the entire heating condensate of the condensate pump ( 18 ) on the suction side. 3. The method according to any one of the preceding claims, characterized net that the common Heizkondensatleitung the heating condensate of a Kon condensate line on the suction side of the condensate pump. 4. The method according to any one of the preceding claims, characterized in that the at least one heating condensate line ( 28 , 32 ) feeds the respective Heizkon condensate of the condensate line ( 16 ) on the suction side of the condensate pump. 5. Arrangement for performing the method for introducing Heizkon condensate into the water-steam circuit of a power plant according to one of claims 1 to 4, with at least one low-pressure preheater ( 14 , 24 ) with little least one of the low-pressure preheaters ( 14 , 24 ) associated tap, ( 26 , 30 ) with at least one condensate pump, with at least one heating condensate line ( 28 , 32 ) with a condenser ( 10 ), and with at least one condensate line ( 16 ), characterized in that at least one heating condensate line ( 28 , 32 ) is present, on the one hand with the associated low pressure preheater ( 14 , 24 ) and on the other hand with the suction side of the condensate pump ( 18 ) is connected such that heating condensate flows from the low pressure preheater in question ( 14 , 24 ) to the suction side of the condensate pump ( 18 ), and that due to the pressure conditions in the relevant heating condensate line ( 28 , 32 , 34 ) avoid evaporation of the Heizkon condensate that is. 6. Arrangement according to claim 5, characterized in that the pressure in the heating condensate is adjustable by the choice of the locations of the at least one low pressure preheater ( 14 , 24 ) and the condensate pump. 7. Arrangement according to claim 5 or 6, characterized in that the pressure in the condensate is adjustable by the choice of the locations of the at least one condenser ( 10 ) and the condensate pump ( 18 ). 8. Arrangement according to one of claims 5 to 7, characterized in that a heating condensate manifold ( 34 ) is present. 9. Arrangement according to one of claims 5 to 8, characterized in that the at least one heating condensate line ( 28 , 32 ) or the heating condensate manifold ( 34 ) conducts the heating condensate into the condensate pump ( 18 ). 10. Arrangement according to one of claims 5 to 10, characterized in that the at least one heating condensate line ( 28 , 32 ) or the heating condensate manifold ( 34 ) conducts the heating condensate into the condensate line ( 16 ) in the region of the condensate pump.