RU2201510C2 - Steam turbine plant - Google Patents

Abstract

FIELD: heat power engineering. SUBSTANCE: invention relates to steam turbine plants using heat of geothermal source with high salt content in gas-steam-water mixture. According to invention, washing system is introduced into plant to provide periodical washing out of blading part and end seals of turbine from salt deposits. EFFECT: improved reliability and increased service life of steam power plant using for its operation heat of geothermal source. 6 cl, 1 dwg

Description

 The invention relates to a power system, in particular to steam power plants using the heat of geothermal sources with high salinity of a gas-steam mixture.

 Known steam turbine installation proposed in the patent of the Russian Federation 2044923 class. F 03 G 7/00 publ. 1995, and containing the water outlet of the separating stages of the turbine, a washing water pump, a regenerative heat exchanger, a second stage separator with a steam washing device.

 A disadvantage of the known installation is the lack of reliability and resource due to the inability to completely eliminate the presence of salts in the steam sent to the turbine using the means used.

 The purpose of the invention is to increase reliability and increase the resource of a steam power plant using the heat of a geothermal source.

 The technical result that can be obtained by using the invention is the prevention of salt deposits in the flow part and the end seals of the turbine.

 The goal is achieved in that in a steam turbine installation that uses the heat of geothermal sources, containing a second stage separator with a steam washing device, the output of which is coupled to the turbo drive inlet, a mixing condenser, and a pump for pumping water from the condenser.

 The installation additionally contains a flushing system for the flow part and end seals of the turbo drive, including a water outlet of the separating stages of the turbo drive, a regenerative heat exchanger, a flush water tank, a flush water pump, flush water injection valves and nozzles, and allowing a flushing to be performed on the running unit from scaling of the flow part end seals of a turbo drive.

 The wash water tank is structurally located in the steam space of the condenser, so that during operation of the installation it is constantly replenished with condensate coming from the water outlet of the separating stages of the turbo drive under the action of a pressure differential between the separating stages and the steam space of the condenser, in case of overflow, the condensate is discharged into the condensate collector of the condenser.

 The regenerative heat exchanger is connected by an inlet through a heating medium to a water outlet of the separating stages of the turbo drive, and by an outlet to a flushing water tank, by an inlet through a heated medium, to a pump for rinsing water, and an outlet to valves for supplying flushing water to the nozzles. On the line between the outlet through the heating water of the regenerative heat exchanger and the inlet to the washing water tank, a water lock is provided, which excludes the possibility of steam passing from the turbine to the condenser.

 The condensate coming from the regenerative heat exchanger exit through the heating medium into the washing water tank and having overheating with respect to the saturation temperature in the condenser, passes through the expander when it enters the tank, ensuring uniformity and low noise of the process of transition of the condensate to the equilibrium state. The washing water is supplied to the steam line of the turbo-drive's hot steam through two lines, which differ in the number of injection nozzles (respectively, by the flow rate) of the washing water, which allows changing the flow rate combination of the lines (first, or second or both) to regulate the flow rate of water for washing the turbine drive flow-through.

 The scheme of the proposed steam turbine installation is shown in the drawing.

 The installation comprises a moisture separator of the second stage with a steam flushing device at the inlet 1, flushing water supply valves 2, 3, 4, nozzles 6, 7, 8, a turbine drive of the electric generator 9, a water outlet of the separating stages 10 of the turbine drive 9, a mixing condenser 11, supply pipelines 12 and a condenser cooling water drain 13, a cooling water pump 14, a wash water collecting tank 15, a condensate expander 16, a wash water pump 17, a regenerative heat exchanger 18.

 Water outlet 10, tank 15, condensate expander 16, flush water pump 17, regenerative heat exchanger 18, valves 3, 4, 5 and nozzles 6, 7, 8 form a turbine flushing system.

 Steam turbine works as follows.

 The steam-water mixture from the first-stage moisture separator located on the geothermal field enters the second-stage moisture separator 1, which has a steam washing device at the inlet, into which washing water is supplied through valve 2 to reduce the salt concentration in the steam. After the moisture is separated in the separator 1, the steam enters the turbo drive 9, from which, after completing the work, it is sent to the mixing condenser 11, where it condenses on the jets of cooling water coming in through the pipe 12 and pumped out of the condenser by the pump 14.

 The pure condensate formed during expansion of the steam in the turbine 9 is separated by the separating stages of the turbine and through the water outlet 10 is sent to the wash water tank 15, passing along the path through the regenerative heat exchanger 18 as a heating medium and an expander 16.

 In the regenerative heat exchanger 18, in order to increase the efficiency of the cycle, part of the heat from the condensate from the water outlet 10 is transferred to the washing water, which is pumped to the valves 2, 3, 4, 5. The condensate goes into equilibrium. corresponding to the pressure in the capacitor occurs in the expander 16.

 When the turbine is operating under load, valve 2 is constantly open and the flushing water is constantly supplied to flush the steam.

 Valves 3, 4, 5 open and close with a predetermined frequency and supply flushing water to the nozzles 6, 7, 8, through which it is injected into the steam lines and moistens the next steam to a given degree of humidity.

 The number of nozzles behind valves 4 and 5 is different, so by combining their opening (only 4, only 5, or 4 + 5), the amount of water supplied can be controlled.

 Wet steam entering the flow part and the end seals of the turbine flushes out the starting scaling, which increases the reliability and service life of the steam turbine unit.

Claims (6)

 1. A steam turbine installation using the heat of geothermal sources, containing a second stage moisture separator with a steam flushing device, the output of which is coupled to the turbo drive inlet, a mixing condenser, a pump for pumping water from the condenser, characterized in that it additionally contains a flushing system for the flow part and the end turbine drive seals, including the water outlet of the separating stages of the turbine drive, a regenerative heat exchanger, a wash water tank, a wash water pump, feed valves and flushing water injection nozzles, and allowing for a running installation to perform flushing from scaling of the flow part and the end seals of the turbo drive.  2. Installation according to claim 1, characterized in that the washing water tank is structurally located in the steam space of the condenser, so that during operation of the installation it is constantly replenished with condensate coming from the water outlet of the separating stages of the turbo drive under the action of a pressure differential between the separating stages and the steam space of the condenser , and in case of overflow, the condensate is discharged into the condensate collector of the condenser.  3. Installation according to claim 1, characterized in that the regenerative heat exchanger is connected to the washing water tank through the water outlet of the separating stages of the turbo drive, and the outlet to the washing water tank, by the input to the pump for washing the washing water, and the outlet to the valves rinse water supply to nozzles.  4. Installation according to claim 1, characterized in that on the line between the outlet of the regenerative heat exchanger through the heating water and the inlet to the wash water tank, a water lock is provided, which excludes the possibility of steam passing from the turbine to the condenser.  5. Installation according to claim 1, characterized in that the condensate coming from the regenerative heat exchanger exiting through the heating medium into the washing water tank and having overheating with respect to the saturation temperature in the condenser, passes through the expander when entering the tank, ensuring uniformity and low noise of the process the transition of condensate to an equilibrium state.  6. Installation according to claim 1, characterized in that the supply of washing water to the steam line of the steam of the turbo drive is carried out in two lines, which differ in the number of injection nozzles (respectively, flow rate) of the washing water, which allows changing the combination of switching the lines (first, or second, or both) to regulate the flow rate of water for flushing the flow part of the turbo drive.