Flash tank design

Abstract

A water-steam circuit of a power plant includes at least one low-pressure steam system and a reservoir for waste water from the water-steam circuit, wherein the reservoir has, in addition to at least one waste water feed line, a further heat supply from the water-steam circuit and a steam outlet which is connected via a waste steam pipe to the low-pressure steam system of the water-steam circuit. A method for cleaning waste water from a power plant having a water-steam circuit, wherein the waste water is conducted into a reservoir and, in addition to a steam fraction generated by automatic evaporation of waste water in the reservoir, a water fraction that is also produced is evaporated using energy from the water-steam circuit, and the entire steam mass flow is introduced into a low-pressure steam system of the power plant.

Claims

1. A water-steam circuit of a power plant comprising: at least one low-pressure steam system, and a vessel for waste water from the water-steam circuit, comprising at least one waste water inflow line configured to deliver waste water from a respective steam drum of the water-steam circuit to the vessel, wherein the waste water from the water-steam circuit functions as a first supply of heat from the water-steam circuit to the vessel, wherein the vessel is further configured to receive a discrete, second supply of heat from the water-steam circuit, effective to evaporate an accumulating water fraction in the vessel using energy from the second supply of heat from the water-steam circuit, the vessel further comprising a steam outlet that is connected, via a waste steam pipe, to the at least one low-pressure steam system of the water-steam circuit and adapted for introducing an entire steam mass flow from the vessel into the at least one low-pressure steam system of the power plant.

2. The water-steam circuit as claimed in claim 1, further comprising: an intermediate-pressure steam system, wherein, for the second supply of heat, an intermediate-pressure steam line branches off from the intermediate-pressure steam system and discharges into a steam inlet of the vessel.

3. The water-steam circuit as claimed in claim 2, wherein the intermediate-pressure steam line branches off from a cold reheater line.

4. The water-steam circuit as claimed in claim 2, wherein the intermediate-pressure steam line branches off from a hot reheater line.

5. The water-steam circuit as claimed in claim 1, wherein, for the second supply of heat, there is arranged in the vessel a heat exchanger which, during operation, is charged on the primary side with hot water whose temperature is above a temperature corresponding to an evaporation pressure in the vessel.

6. The water-steam circuit as claimed in claim 5, wherein, for a purpose of charging the heat exchanger with the hot water, the heat exchanger is connected to an intermediate-pressure feed water preheater.

7. The water-steam circuit as claimed in claim 1, wherein a jet pump, that is connected on a working medium side to a high-pressure or intermediate-pressure steam system, is connected into the waste steam pipe such that it is connected, on an intake medium side, to the steam outlet of the vessel and, on an outlet side, to the at least one low-pressure steam system.

8. The water-steam circuit as claimed in claim 7, wherein, for the second supply of heat a heat exchanger is disposed in the vessel, and wherein for a purpose of charging the heat exchanger with hot water, the heat exchanger is connected to a condensate preheater.

9. The water-steam circuit as claimed in claim 7, wherein the waste steam pipe discharges into a low-pressure steam line leading to a steam turbine.

10. The water-steam circuit as claimed in claim 1, further comprising: at least one evaporator and at least one superheater connected downstream of the at least one evaporator, and, arranged between the at least one superheater and the at least one evaporator, a condensate collection and return line for intercepting condensate present in the at least one superheater and for returning the condensate into the at least one evaporator without passing through the vessel.

11. A method for purifying waste water of a power plant having a water-steam circuit, comprising: guiding the waste water from a steam drum of the water-steam circuit into a vessel via a waste water inflow line, wherein the waste water from the water-steam circuit functions as a first supply of heat from the water-steam circuit to the vessel, and in addition to producing a steam fraction by automatic evaporation of waste water in the vessel, evaporating a water fraction that continues to accumulate using energy from the water-steam circuit, wherein the energy is received in the vessel via a discrete, second supply of heat from the water-steam circuit, and guiding a total steam mass flow from the vessel into a low-pressure steam system of the power plant.

12. The method as claimed in claim 11, Wherein, as the second supply of heat from the water-steam circuit, intermediate-pressure steam or high-pressure steam is introduced into the vessel.

13. The method as claimed in claim 11, Wherein, as the second supply of heat from the water-steam circuit, a heat exchanger is arranged in a water region of the vessel is charged on the primary side with water at a temperature that is above a temperature corresponding to an evaporation pressure in the vessel.

14. The method as claimed in claim 13, wherein the heat exchanger is charged with water from an intermediate-pressure feed water preheater.

15. The method as claimed in claim 11, wherein to pump the total steam mass flow a jet pump is operated with high-pressure or intermediate-pressure steam, and the jet pump causes a pressure reduction in the vessel and steam issuing from the jet pump is supplied to the low-pressure steam system.

16. The method as claimed in claim 15, wherein, as the second supply of heat from the water-steam circuit, a heat exchanger is arranged in a water region of the vessel, and wherein the heat exchanger is charged with water from a condensate preheater.

17. The method as claimed in claim 11, wherein relatively clean boiler waste water is intercepted by condensate collection and return lines assigned to individual pressure stages and is fed directly back to respective evaporators without passing through the vessel.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention will be explained in more detail, and by way of example, with reference to the drawings. In the drawings, which are schematic and not to scale:

(2) FIG. 1 shows a first exemplary embodiment of the inventive water-steam circuit of a power plant,

(3) FIG. 2 shows a second exemplary embodiment of the inventive water-steam circuit of a power plant, and

(4) FIG. 3 shows a third exemplary embodiment of the inventive water-steam circuit of a power plant.

DETAILED DESCRIPTION OF INVENTION

(5) FIG. 1 shows, in a schematic and highly simplified manner, a first exemplary embodiment of the inventive water-steam circuit 1 of a power plant 2, using the example of a combined-cycle turbine plant. A gas turbine (not shown) is connected to the waste heat steam generator 28 which is provided for generating the operating steam of the steam turbine 22 using waste heat from the gas turbine.

(6) The exhaust gases from the gas turbinewhich are still at approximately 550 to 650 C.are supplied to the waste heat steam generator 28, flow through it from the exhaust gas inlet 29 to the exhaust gas outlet 30 and leave the waste heat steam generator 28 toward a chimney (not shown in greater detail).

(7) The waste heat steam generator 28 in the example of FIG. 1 is embodied as a multi-pressure boiler with natural circulation and comprises a low-pressure steam system 3, an intermediate-pressure steam system 8 and a high-pressure steam system 17. However, this invention can also be used in the case of waste heat steam generators that are embodied in individual or all evaporator pressure stages as forced-circulation or as forced once-through evaporators.

(8) On their path through the waste heat steam generator 28, the hot exhaust gases of the gas turbine carry their heat to a high-pressure superheater 35, then to a reheater 36, onward to a high-pressure evaporator 34, a high-pressure preheater 37, then to an intermediate-pressure superheater 33, an intermediate-pressure evaporator 32, an intermediate-pressure preheater (or also intermediate-pressure feed water preheater) 14, then to a low-pressure superheater 25, an intermediate-pressure evaporator 24 and finally to a condensate preheater 21.

(9) Steam that has been superheated in the high-pressure superheater 35 is fed through a steam discharge line 38 to a high-pressure stage of the steam turbine 22, where it is expanded, performing work. The hot steam that has been partially expanded in the high-pressure stage is then fed, together with steam from the intermediate-pressure superheater 33, to the reheater 36 where it is re- or further superheated and fed via a discharge line 39 to an intermediate-pressure stage of the steam turbine 22, where it is expanded, performing mechanical work. The steam that has been partially expanded there is fed, together with the low-pressure steam from the low-pressure steam system 3 of the waste heat steam generator 28, to a low-pressure stage of the steam turbine 22, where it is further expanded, releasing mechanical energy.

(10) The expanded steam is condensed in the condenser 40, and the condensate thus produced is fed, by means of a condensate pump 41 and after heating in the condensate preheater 21, directly to the low-pressure steam system 3 or, by means of a feed water pump 42and appropriately pressurized therebyto the intermediate-pressure steam system 8 or to the high-pressure steam system 17, where the condensate is evaporated. After steam generation and superheating, the steam is fed back to the steam turbine 22 to be expanded and to provide mechanical work.

(11) During operation of the power plant 2, operating waste water accumulates discontinuously in the water-steam circuit 1. In particular in the case of natural-circulation and forced-circulation boilers (drum boilers), there is therefore a need to remove the impurities from the circuit via the drains on the boiler drum.

(12) To that end, there is provided in the water-steam circuit 1 of FIG. 1 a vessel 4 which has waste water inlet lines 31 from the low-pressure 3, intermediate-pressure 8 and high-pressure 17 steam systems, via which, along with the waste water, heat is also fed to the vessel 4. In that context, part of the waste water which enters will evaporate immediately, the other part accumulates as boiling water. The pressure in the vessel 4 is fixed such that the internal pressure of the vessel matches the low-pressure evaporator pressure. This is achieved by the steam outlet 6 on the vessel 4, which connects, via a waste steam pipe 7, to the low-pressure steam system 3, in the example of FIG. 1 to the low-pressure drum 15. This waste steam pipe 7 conveys the steam resulting from evaporation into the connecting system.

(13) The residual waste water remaining after evaporation is further evaporated by means of a further supply of heat 5 from the water-steam circuit 1, and the resulting steam is again fed to the low-pressure steam system 3 via the waste steam pipe 7. To that end, intermediate-pressure steam from the cold reheater line 11 is conveyed, via an intermediate-pressure steam line 9, into the vessel 4. A corresponding steam inlet 10 on the vessel 4 is arranged, in the exemplary embodiment, below the waterline 12. A different arrangement is conceivable, however.

(14) The small quantity of residual waste water still remaining after this can then either be discharged into the public waste water system or be fed to further processing steps 43.

(15) FIG. 2 shows another embodiment of the water-steam circuit 1 according to the invention, in which a heat exchanger 13 arranged in the water region 27 of the vessel 4 is heated using hot water from the intermediate-pressure feed water preheater 14. In this exemplary embodiment too, the waste steam pipe 7 discharges into the low-pressure drum 15.

(16) The embodiment of FIG. 3 adds, to the example of FIG. 2, a jet pump 18 which is operated using steam from the high-pressure 17 or intermediate-pressure 8 steam system of the waste heat steam generator 28, and which reduces the pressure in the vessel 4 and compresses the steam produced in the vessel 4 to the point that it can be fed to the low-pressure steam line 23. It is thus possible to use, for heating the heat exchanger 13, hot water at a lower temperature than in the example of FIG. 2.

(17) In that context, the jet pump 18, that is connected on the working medium side 16 to the intermediate-pressure steam system 8, is connected into the waste steam pipe 7 such that it is connected, on the intake medium side 19, to the steam outlet 6 of the vessel 4 and, on the outlet side 20, to the low-pressure steam line 23.

(18) By virtue of the lower temperature (in comparison to the embodiment of FIG. 2) required for heating the heat exchanger 13, the latter is connected, in the exemplary embodiment of FIG. 3, to the condensate preheater 21.

(19) In all exemplary embodiments, the water-steam circuit 1 has, arranged between the superheaters 25, 33, 35 and the respective associated evaporators 24, 32, 34, condensate collection and return lines 26 for intercepting condensate present in the superheaters 25, 33, 35 and for returning the condensate into the evaporators 24, 32, 34.

(20) This measure is not essential, but relieves the water processing in the vessel 4 since the clean boiler waste water are fed directly back to the respective evaporators and need not pass through the vessel 4 beforehand.