SU853125A1 - Steam power plant with two-shaft turbine - Google Patents

Description

one

The invention relates to a power system and is intended for use in power units with twin-shaft turbines with steam superheating.

Steam-powered installations are known that contain an intermediate superheater and a steam transfer pipe connected in parallel between high-pressure medium pressure cylinders, an external source of steam and a feedwater path. An ejector is connected to this in the steam bypass pipe, which is connected by pipelines with control valves in an enviromental medium with an external source of steam, and in the ejected medium - with a feed water path 1.

The turbine is started up to regulate the temperature of the secondary superheated steam in front of the medium pressure cylinder (DSC) and steam is supplied to the ejector from an external source, which draws in part of the steam sent to the intermediate superheater. Thus, through the intermediate superheater, steam passes less by the amount sucked into the ejector. With the high flow rates of steam sucked into the ejector, the reliability of the intermediate superheater of the boiler is reduced, which is one of the drawbacks of this steam-powered installation. In addition, the steam supply to the ejector from an external source leads to a corresponding increase in the steam output of an external source, for example, a starting boiler house, which increases capital costs and leads to an increase in condensate in the cycle, which has to be removed from the cycle, which reduces the efficiency of the installation. Also known steam power installation with

10 twin-shaft turbines containing parts of high, medium and low pressure on one shaft (HPP, CHSD and CHID), and on the other shaft - CHSD and CHDD, while the CHS steam trains are connected by pipelines,

15 each of which has a valve with a bypass, through an intermediate superheater of the boiler with an exhaust pressure pump with regenerative steam extraction, communicated with heaters, which are included in

20 feedwater path 2.

The second turbine shaft is started while the first shaft is operating, by opening the control valve on the additional pipeline with the valves closed and their bypasses on the pipelines supplying superheated steam to the CHS of the second shaft. Thus, cold steam enters the second shaft of the turbine, which has not passed through the overheated superheater, i.e.

30 steam consumption through the latter is reduced.

and the value of the selected steam to the second shaft. As a result, the cooling of the intermediate superheater is impaired, which results in its reliability and this is a disadvantage of the installation.

To increase the number of revolutions of the turbine of the second shaft, a large amount of cold steam is added to it by opening its control valve on the additional pipeline. However, an increase in the supply of cold steam to the CHSD of the second shaft turbine leads to an increase in pressure in front of the turbine, which reduces the pressure drop across the control valve and, consequently, reduces the flow of "cold steam through the additional pipeline. As a result, to further turn the turbine, open the valve on the pipeline for supplying superheated steam to the CHSD of the second shaft, which leads to sushi, a natural increase in the temperature of the steam in front of the CHSD of the turbine of the second shaft. An increase in steam temperature is caused by two factors: the supply of high-temperature steam after an intermediate superheater and a decrease in the proportion of cold steam, due to an increase in pressure before the CHD of the turbine of the second shaft.

Increasing the temperature of the steam before the CHS of the turbine leads to an increase in the time of starting the second shaft, i.e., to reduce the maneuverability and efficiency of installation.

After the valve is fully opened in the pipeline for supplying steam to the CHSD of the second shaft turbine, the regulating valve on the additional pipeline is closed and further loading of the second turbine shaft is performed by increasing the load on the boiler as in conventional steam turbine units.

When the second shaft of the turbine is stopped for repair, the valve on the steam pipe to the CHSD of the second shaft turbine is closed and the control valve on the additional pipeline opens. However, as a result of the fact that the temperature of the steam behind the CWD of the turbine is rather high, the forced cooling down of the turbine of the second shaft is limited by this temperature. As a result, a certain time is required for the turbine to naturally cool to a temperature when it is possible to proceed with its repair.

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

This goal is achieved by the fact that at least on one of the bypasses an ejector is installed that communicates via ejection, its medium with regenerative selection of a part of high pressure, and the ejected portion with a feedwater path.

The drawing shows a diagram of the steam power plant.

The installation includes a twin-shaft turbine, the CWD 1 of which with the regenerative selection 2 of the steam is connected by a pipe 3 of the steam outlet to an intermediate superheater 4, to which the pipelines 5, 6 supply steam to the valves 7, 8 and to the bypass 9, 10 10 includes an ejector 13 connected via an ejecting medium by a pipe 14 with a regulating valve 15 to a regenerative selection 2 of the CWD 1. The ejector 13 but a narrow section of an ejected medium is connected by a pipe 16 with an adjusting valve, 17 to the feedwater path 18, for example internal stage feed pump 19.

15 The Parosilov plant works in the following way.

During the operation of the first turbine shaft, steam from the CWD 1 through line 3 passes through the superheater 4 and through line 5

0 through the rear valve 7 enters the CHSD 11. To start the second turbine shaft, the regulating valve opens on the bypass 10 and the steam passed through the superheater 4 enters the ejector 13, into a narrow section of which

5 pipeline 16 receives feed water from the intermediate stage of the pump 19. The feed water is sprayed and evaporated in the ejector, resulting in the steam temperature behind the ejector and before

0 CHS 12 lowers. The control of the steam temperature before the CHD 12 is dried by the valve 17 in accordance with the required reliability criteria of the CHSD 12.

In view of the fact that all the bunks after CWD 1

5 passes through the superheater 4, its operation is highly reliable. The change in steam consumption for turning the CHS 12 is dried by opening the control valve on the bypass 10.

0 After this valve is fully opened, the increase in steam consumption for loading the CHSD 12 is dried; it is detected by supplying steam from selection 2 through conduit 14 to ejector 13. Steam from conduit 14, which came to

5, the ejector 13, creates a vacuum in the ejector, which provides additional steam suction from the pipeline 6, which provides an extension of the loading range of the CHSD 12 with respect to the cold nar.

0 Steam consumption from selection 2 to ejector 13 is controlled by valve 15. After valve 16 is fully opened, valve 8 is opened, and further loading of CHSD 12 is carried out in the usual way.

5 When the turbine shaft is stopped, the valve 8 is closed for repair and the control valve on the bypass 10 and valve 15 on the pipeline 14 opens. Feed line 16 and through the ejector 13 supply feed water, the flow of which is controlled by valve 17 so that the steam temperature behind the ejector 13 complied with the criteria for proper cooling of the CHCD 12. The proposed installation provides forced cooling of the metal

Claims (1)

Claim A steam-powered installation with a twin-shaft turbine, containing high, medium and low pressure parts on one shaft and medium and low pressure parts on the other shaft, while the steam inlets of the medium pressure parts are connected by pipelines, each of which has a bypass valve, through an intermediate superheater a boiler with an exhaust of a high-pressure part having regenerative steam extraction connected with a heater 10 mi, which are included in the feed water path, characterized in that, in order to increase reliability and is economical STI of at least one set of ejector bypasses, reported by ezhekti15 ruyuschey medium with regenerative selection of the pressure, and ejected by - a feedwater path.