SU1454990A1 - Steam turbine unit - Google Patents

Abstract

The invention relates to a power system and improves the efficiency and reliability of a steam turbine plant. Fresh steam lines 1 are connected to a high pressure cylinder (C) 4, part of the steps of which is located in the inner casing 5. C 4 is equipped with devices 6 for heating flange connections that are connected to the condenser via lines 13, 14, 15 ) 16. C 4 through intermediate steam heater 18 is connected to C 22 of medium pressure, equipped with a flange heating device 25, which lines 28 are in communication with the atmosphere, and lines 14, 15 are connected to K 16. In addition, the ejector 41 of the forced air chilling This consists of two stages 4.6 and 47. The exhaust pipe 51 of stage 46 is connected to the second stage 47 of the ejector 41 and K 16. The use of such systems in steam turbine installations allows to intensify the process of turbine cooling by atmospheric air and reduce the total cooling time. 1 з, п.ф-л, 1 Il. a (L

Description

The invention relates to a power system and can be used in the operation of steam turbine units and steam turbine power units of power plants in shutdown modes with damping.

The aim of the invention: is to increase efficiency and reliability.

The drawing shows a steam turbine · ^ · naya installation.

The steam turbine installation contains steam pipelines 1 of fresh steam connected through the main steam valves 2 and steam distribution elements 3 to the high pressure cylinder 4, part of the stages of which are located in the inner housing 5. The outer housing of the CVP 4 is equipped with devices 6 for heating (cooling) flange connections . (UOF), which are connected by lines 7 with valves 8 and 9 to the internal cavity 10 of the high-pressure cylinder 4. UOF 6 are connected by lines 11 with valves 12 to the atmosphere, and lines 13, 14, 15 of the medium discharge with a capacitor 16, and on line 15 installed valve 17. TS VD 4 through an intermediate superheater 18, pipelines 19, valves 20, bypass pipes 21 is connected to the medium pressure cylinder 22 (DPS), and the latter is connected to the condenser 16 through the receiver pipe 23 and the low pressure cylinder 24 (DPS) 24. The DPS 22 is equipped with a device 25 heating (cooling) flange connections (UOF), which is communicated with the DAC 22 lines 26 s. valves 27 connected to the bypass pipes 21 of the DPS 22. The UOF 25 of the DPS 22 is communicated through lines 28 with valves 29 with the atmosphere, and the discharge lines 30 of the UOF 25 of the DPS 22 are connected to lines 14 and 15 and through them to the condenser 16. Steam lines 1 fresh steam is connected to the condenser 16 by line 31 with a quick-release quick-acting device (PSBU) 32 located on it. CVP 4 is connected to the superheater 18 by pipelines 33 with a device 34 installed on them, communicating CVP 4 with the atmosphere, and a 35 s line is connected to pipelines 19 valve 36 connecting superheater spruce 18 with condenser 16. The main ejectors 39 and 40 are connected to the condenser 16 by pipelines 37 and 38. In addition, an ejection forced air cooling (EPR) 41 is connected to the circuit, which is connected by a line 42 with a valve 43 to the suction pipe 37 from the condenser 16, and a line 44 with a valve 45 to the discharge pipelines 13, 14, 30 of the UOF 6 CVP 4 and the UOF 25 of the TsSD 22. EPVR 41 includes two stages and 47. The first stage 46 of the EPVR 41 includes a nozzle 48 in communication with the source of the worker body, the suction chamber 49, the diffuser 50 and the exhaust pipe 51, and the second stu stump

EPVR 41 - nozzle 52, suction chamber 53, diffuser 54 and exhaust pipe 55. Line 44 connecting the ejector 41 to lines 13, 14, 30 of devices 6 and 25 is connected to the suction chamber 49 of the first stage 46, and line 42 connecting the ejector 41 with a pipe 37, connected to the suction chamber 53 of the second stage 51 of the EPRS 41. V. exhaust pipe 51. of the first stage 46 of the ejector 41 is connected to the suction chamber 53 of the second stage 47 of the ejector 41 by a pipeline with a valve 57, and a line 58 with a valve 59 to condenser 16, Forced air cooling is carried out as follows in a way.

After the turbine is stopped and the pipelines are stripped off, the main ejectors 39 and 40 are turned on, and then the EPVR 41, for which, with closed valves 43, 4, 59, open the valve 57 and supply steam to the nozzles 48 and 52 of the EPVR 41, and then open the valve 43 and turn off the ejectors 39 and 40. Organize the movement of air through the UOF 6 CVP 4, for which, when the valve is closed 17 open valves 8, valves 12; 45, due to which the cooling air, having passed through the UVF 6 CVP 4, enters the suction chamber'49 of the first stage 46 EPVR 41, and from there through the pipe 56 with a valve into the suction chamber 53 of the second stage 47 EPVR 41 and further into the atmosphere. / If necessary, the same in the manner they organize forced air dampening of the DAC 22.

To simplify the regulation of the flow of money.

curing and improving working conditions of the second stage 47 of the ejector 41 use a condenser 16 as an intermediate cooler between the first and second 51 steps of the ejector 41.

To do this, open the valve 59 on line 58 and close the valve 57 on the pipeline 56. The cooled air is sucked out of the condenser 16 using the second stage 51 of the EPVR 41 together with the air coming from the cylinders 4 and 22, respectively, of the high and medium pressure of the installation.

Claims (2)

The claims of the invention 1. A steam-turbine installation, including a multi-cylinder steam turbine, the high-temperature cylinder bodies of which are equipped with heating and cooling devices for flange connections communicated at the inlet by the air intake lines with the atmosphere, a condenser with suction chambers connected to it for the main ejectors and forced air cooldown ejector and waste lines of heating and cooling devices for flange connections, while the exhausts of all ejectors are connected to the atmosphere, characterized in that, in order to to increase efficiency and reliability, the suction chamber of the forced-air cooldown ejector is additionally connected by a pipeline to shut-off valves with waste lines from flange connection heating devices, and the exhaust - from condensator 15 2? Installation according to claim ^, characterized in that the ejector of forced air cooling is made in two stages, while the second stage thereof is connected to the condenser in the ejected medium.