SU1694941A1 - Power-and-heat supply plant - Google Patents

Abstract

The invention relates to power engineering and can be used in heat generation power plants equipped with heat storage systems. The purpose of the invention is to increase efficiency. During the period of low electrical loads, the heat of the fresh steam from the steam generator 1 is stored in the accumulator 5, and the cooled steam is partially consumed after section 26 for generating electricity in turbine 6, after accumulator 5 and turbine 6 for heating network water. heater 16, and partly after one of the sections of the battery 5, is used to reheat the feed water in the heat exchanger 12. The period of increased electrical loads, the heat stored in sections 27 and 26, is used for steam The formation of the working fluid, which is triggered in the turbine 6 with the production of additional electricity, and the heat stored in section 28, is used for additional heating of the supply water, in addition to the main heating in the heaters 17 and 16 1 c p f files, 1 sludge

Description

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-xJ The invention relates to energy and can be used in heat and power generation plants equipped with heat storage systems.

The aim of the invention is to improve the economy.

The drawing shows a schematic diagram of the heat and power plant.

The heat and power installation includes a steam generator 1 connected by pipe 2 of fresh steam to the inlet of the main turbine 3 and through a gate 4 to the input of the heat accumulator 5, an additional turbine 6 connected by pipe 7 with a gate 8, and pipe 2 with battery 5 , a - | also condenser 9, feedwater pipeline 10 with regenerative heaters 11 installed on it, connected to steam extraction of turbine 3 (not shown), and steam-water heat exchanger 12 connected by an inlet through the pipe 13 with a shut-off body 14 to the outlet of the battery 5. The installation also includes a pipeline 15 of network water with network heaters 16 and 17 installed on it, while the heater 16 is connected to the input through a heating medium through pipelines 18 and 19 with shut-off bodies 20 and 21 to the outlets of the battery 5 and the turbine 6, respectively, and the condensate outlet through conduit 22 with shut-off element 23 to the feedwater pipeline 10, the heater 17, connected by an inlet to the heating medium with a pipeline 24 sec. steam extraction of the turbine 3, and the output of the condensate through the pipeline 25 - with pipeline 22,

The battery 5 is made in the form of serially interconnected high, medium and low temperature sections 26, 27 and 28, respectively, and sections 27 and 28 are interconnected via a shut-off member 29, the outlet of section 26 by a conduit 30 with a shut-off member 31 is connected to the pipeline 7, the outlet of section 27 is connected via pipeline 32, on which regenerative heater 33 and shut-off bodies 34, 35 are installed, to pipeline 22, the inlet of section 28 is connected by pipeline 36 with shut-off member 37 to pipeline 15 of supply water between the heater 16 and 17, and the outlet of section 28 is connected via pipeline 38 with a shut-off element 39 to pipeline 15 to preheater 16 along the network water.

The installation works as follows.

During the period of basic electric loads, all the steam produced in the steam generator 1 enters through the pipeline 2 into the main turbine 3, is condensed in the condenser 9, after which the feed water is heated in the regenerative heaters 11 and fed to the steam generator 1. In the heater 17, the network water is heated selective steam turbine 3, coming through the pipeline 24, Condensate heating steam from the network heater 17 through pipelines 25 and 22 is fed into the pipeline

5 10 feed water. In this case, all the locking bodies are closed.

During the period of reduced electrical loads, part of the fresh steam from the pipeline 2 enters the accumulator 5, where the heat

0 steam is used to heat and melt heat storage substances.

In the high-temperature section 26 of the battery 5, the main steam cooling takes place, after which part of the steam enters

5 via conduit 30 to turbine 6, where it expands, and the remainder of the steam enters the medium temperature section 27 and then to the low temperature section 28 of the battery 5, where it is additionally

0 cooling. Part of the steam used in turbine 6, and another part of the steam cooled in accumulator 5, via pipelines 19 and 18, respectively, enter the inlet of the network heater 16, in which heating of the network water takes place, compensating for its unheat- ing in heater 17 for reducing the power of the turbine 3. The condensate of heating steam from the preheater 16 is fed through conduit 22 to conduit 10 of nutrient

0 water. To reheat the feedwater, part of the steam after the battery 5 enters through the conduit 13 into the steam heat exchanger 12. Steam removal may take place after sections 26 or 27, depending on

5 feedwater temperatures at the inlet to the Steam Generator 1. In this mode of operation, the locking bodies 4, 31, 29, 14, 20. 21, 23 are open, and the locking bodies 8.39, 37,34,35 are closed.

0 During the period of increased electrical loads, pipeline 32 supplies feed water to medium-temperature 27 and high-temperature 26 sections of the accumulator 5, where as a result of water cooling

5 heat-accumulating substances, its vaporization occurs, and the resulting steam through pipelines 2 and 7 enters the turbine 6. After expansion into the latter, steam through pipelines 19 and 18 enters the inlet of the network preheater 16. Heating condensate

steam from heater 16 through pipelines 22 and 32 is fed to regenerative heater 33 of feedwater for turbine 6, where it is heated with selected steam from one of the turbines (not shown). Part of the network water from the pipeline 15 through the pipeline 38 is passed through the low-temperature section 28 of the battery 5, where it is heated and then through the pipelines 36 and 15 is fed to the inlet of the network heater 17, which reduces the consumption of the last selected steam from the main turbine 3. the mode of operation, the locking bodies 4.31, 29, 20, 14, 23 are closed, and the locking bodies 34, 35, 8, 21, 39, 37 are open.

Claims (2)

Claim 1. Thermal power plant containing a steam generator connected to the main turbine and a heat accumulator connected to the outlet with a heater installed in the supply water pipeline, feedwater pipeline, additional turbine connected to the heat accumulator and outlet - to the heater of the network water, while the output of the latter is connected to the feedwater pipeline and through a pipeline installed on it ativnost heater - to the heat accumulator to the torus, characterized in that, in order to increase efficiency, it is provided with additional line heater installed on the pipeline network of the water heater main network in the course of heating water and connected by the heating medium inlet to the steam main selection turbines, and the output to the feedwater pipeline, the heat accumulator is made in a form of successively connected high, medium and low temperature sections, the latter two being connected between themselves through a shut-off element, with the additional turbine connected to the output of the high-temperature section, the regenerative heater to the output of the middle-temperature section, and the output The low-temperature section is additionally connected to the mains water pipeline in front of the main network heater. 2. Installation pop. 1, characterized in that it is additionally equipped with a steam-water heat exchanger installed in the feedwater pipeline before the steam generator inlet and connected inlet through the heating medium to the thermal battery