RU2319019C1 - Thermal power station - Google Patents

Abstract

FIELD: heat power engineering.

SUBSTANCE: invention is designed for recovery of heat of blowdown water. Proposed thermal power station contains steam turbine connected by live steam pipeline with steam boiler to which blowdown and feed water pipe lines are connected, high-pressure regenerative heaters placed in feed water pipelines connected by heating medium to turbine steam extractions, and water-to-water heat exchanger connected to blowdown waster pipeline. Water-to-water heat exchanger is made two-stage. First stage of heat exchanger is connected to boiler blowdown water pipeline. Cooled blowdown water is connected to second stage of heat exchanger by heating medium after first stage of heat exchanger. First and second stages of heat exchanger are connected by heating medium to condensate lines of two regenerative high-pressure heaters in direction of feed water flow.

EFFECT: increased economy.

1 dwg

Description

The invention relates to the field of power engineering and can be used in thermal power plants.

A well-known analogue is a thermal power station containing a steam turbine connected by a sharp steam pipeline to a steam boiler, to which a purge water pipeline and a feedwater pipe are connected, regenerative high-pressure heaters included in the feedwater pipe, connected through a heating medium to the turbine steam extraction. A water-water heat exchanger connected through a heating medium to a purge water pipeline is included in the feed water pipe between the regenerative heaters and the steam boiler (see Patent No. 2227829 “Thermal Power Station”, IPC ⁷ F01K 17/02, B.I. 2004. No. 12).

The described analogue is adopted as a prototype.

A disadvantage of the analogue is reduced efficiency due to the large capital costs of installing a large-sized water-to-water heat exchanger for using a relatively small amount of purge water and heating a large amount of feed water. Due to these disadvantages, the scope of the prototype is limited.

The technical result achieved by the present invention is to increase efficiency by reducing capital costs and increasing the efficiency of using the heat of purge water, expanding the scope of the invention.

To achieve this technical result, a thermal power plant is proposed comprising a steam turbine connected by a steam line to a steam boiler, to which purge and feed water pipelines are connected, regenerative high-pressure heaters included in the feed water pipe, connected via a heating medium to turbine steam withdrawals, a water-to-water heat exchanger connected to the purge water pipeline.

A feature of the claimed station is that the water-water heat exchanger connected to the purge water pipeline is made two-stage, the first stage of the heat exchanger is connected to the boiler purge water pipe, the cooled purge water pipeline is connected to the second stage of the heat exchanger after the first heat exchanger stage, and the medium to be heated the first and second stages of the heat exchanger are included in the condensate pipelines of the last two regenerative heaters along the feed water of pressure.

A new set of station features makes it possible to achieve the desired technical result due to the maximum possible use of the high potential of the purge water heat for heating the condensate of the last regenerative high pressure heaters along the feed water by a sufficiently large amount, since the purge water and condensate flows are comparable in magnitude. Since the consumption of condensate is many times less than the consumption of feed water, the capital costs for installing a water-to-water heat exchanger are significantly reduced compared to the prototype and the scope of application of the claimed solution expands.

Information confirming the possibility of carrying out the invention with obtaining the above technical result are as follows.

The thermal power station (see drawing) contains a steam turbine 1 connected by a steam line 2 of sharp steam to a steam boiler 3, to which a purge water pipe 4 and feed water pipe 5 are connected, a two-stage heat exchanger connected to the purge water pipe 4 (6, 7). The first stage 6 of the heat exchanger is connected to the purge pipe 4 of boiler 3, the chilled purge water pipe is connected through the heating medium to the second stage 7 of the heat exchanger after the first stage 6 of the heat exchanger, and the first 6 and second 7 stages of the heat exchanger are included in the condensate pipelines of the last two along the heating medium feed water of high pressure regenerative heaters 8.

Thermal power station operates as follows. The steam boiler 3 generates steam, which is supplied through the steam pipe 2 to the steam turbine 1. Feed water to the boiler 3 is supplied through the feed water pipe 5 through high pressure regenerative heaters 8. A two-stage heat exchanger connected to the purge water pipe 4 (6, 7). The first stage 6 of the heat exchanger is connected to the purge pipe 4 of boiler 3, the chilled purge water pipe is connected through the heating medium to the second stage 7 of the heat exchanger after the first stage 6 of the heat exchanger, and the first 6 and second 7 stages of the heat exchanger are included in the condensate pipelines of the last two along the heating medium feed water of high pressure regenerative heaters 8.

New features make it possible to use the high potential of the purge water heat to heat one of the feed water streams — the condensate of the high-pressure heater — by a sufficiently large amount at the minimum capital cost.

Claims (1)

A thermal power plant comprising a steam turbine connected by a steam pipe to a steam boiler, to which purge and feed water pipes are connected, regenerative high pressure heaters connected to the feed water pipe, connected through a heating medium to the turbine steam extraction, connected to a purge water pipe - a water heat exchanger, characterized in that the water-water heat exchanger connected to the purge water pipeline is made in two stages, to the pipeline The boiler’s purge water is connected to the first stage of the heat exchanger, the chilled purge water pipe is connected to the second stage of the heat exchanger via the heating medium after the first stage of the heat exchanger, and the first and second stages of the heat exchanger are connected to the condensate pipelines of the last two regenerative high pressure heaters along the feed water.