RU1815343C - Method of generation of additional power at power-and-heat supply plant with network heaters - Google Patents

Abstract

Usage: in the heat power industry, in heating plants with network heaters under conditions of insufficient cooling water and no heat release. SUMMARY OF THE INVENTION: when the heat consumer is turned off, the steam consumption is increased in the head of the turbine 1 and steam is supplied from the heat recovery units 4 and 5 to the network heaters b and 7. The latter are supplied with part of the circulation water after the condenser 9, which is then passed through the low-potential heat consumer 19 and mixed before cooler 12 with the remainder of the water. At the same time, the flow rate of the circulating water and the heat load of the cooler 12 are kept constant, which ensures that the vacuum in the condenser is below the maximum permissible heat loss in the cooler. 1 ill.

Description

The invention relates to a power system and can be used to obtain additional power of electric power.

The purpose of the invention is to increase the reliability and cost-effectiveness of obtaining additional power in the absence of heat and circulating water.

Reducing the flow rate of steam into the low pressure cylinder makes it possible to keep the vacuum in the condenser below the maximum permissible value at a constant flow rate of circulating water, which increases the reliability of the last stages of the turbine. Steam cooling in a network installation with circulation water after the condenser makes it possible to increase the steam consumption in turbine extraction and to generate additional power. At the same time, maintaining the temperature of the return circulation water at the inlet to the cooler is not higher than the temperature corresponding to the maximum allowable vacuum in the condenser, limits the heat loss in the cooler and ensures reliable operation of the latter.

Condensation of steam in the high-pressure network heat exchanger by drainage of steam in the low-pressure heat exchanger allows increasing the drainage temperature of the latter to the saturation temperature of the steam of the high-pressure heat exchanger and thereby increasing the steam flow rate to the turbine head, partially displacing low-pressure regeneration and obtain a large amount of additional power .

The method is implemented by the circuit shown in the drawing.

The heating turbine 1 is equipped with a steam supply pipe 2 with a regulating body 3, steam extraction pipes 4, 5 to the network installation with heat exchangers 6 and 7 and a network pump 8, a condenser 9 connected to the supply pipes 10 and outlet 11 of the circulation water to the cooler 12. Piping outlet 11 is connected by a line 13 with a regulating body 14 with a return network water pipe 15 to a network pump 8. The heat exchangers of a network installation 6 and 7 are connected by lines 16, 17, 18 to an additional consumer of low-grade heat 19 and from pipes retraction wire 11, the circulation water cooler 12 connected to the conduit 20. At the last temperature sensor 21 is installed the circulating water, coupled to the actuator 14. Regulator to the same regulatory

the power sensor 22 of the generator 23 is connected to the body. On the forward and reverse pipelines of the network water, shut-off bodies 24, 25 are installed.

The low pressure network heat exchanger 7 (lower) is connected by a drain pipe 26 via line 27 with the regulating body 28 to the high pressure network heat exchanger 6 (upper)

on the cooling medium. A locking body 29 is installed between lines 17 and 27 on the pipeline 15. A line 31 with a locking body 32 is connected to the drainage pipe 26 after the locking body 30. The regulating body 6 is connected to temperature sensors 21 and power 22.

The method is as follows

During the period of receiving additional

electrical power when the turbine is in condensation mode with water and steam off heat exchangers 6 and 7 of the network installation increase the steam supply through pipeline 2 to the head of turbine 1 and

turn on the heat exchangers 6 and 7 in a couple. At the same time, open the regulator 14 on line 13 with the valves 24 and 25 closed and pump part 8 of the circulation water after the condenser 9 to the heat exchangers 6 and 7, after which it is discharged through lines 16, 17 18 through a heat consumer 19 to mix with the main circulating water return flow through conduit 11, and then through conduit 20 to a cooler 12. The total flow of circulating water is kept constant. At a given value of additional power, the pressure in the condenser 9 is kept below the maximum

permissible by regulating the flow of steam to the turbine head and to the network installation. At the same time, the flow rate of the circulation water through line 13 to the network installation is controlled by the signal of the temperature sensor 21 of the circulation water at the inlet to the cooler 12, maintaining a constant heat load of the cooler.

In the event that the required additional power is less than the maximum possible in this installation, the regulating body 14 is additionally affected by the signal of the generator power sensor 22.

5 In the absence of additional heat consumer 19 or a small amount of additional power, the method can be implemented when only one low-pressure network heat exchanger 7 is operating and the heat exchanger 6 is turned off.

If there is a margin in turbine capacity before being taken to a high-pressure network heat exchanger b, the method can be carried out as follows.

Increasing the steam supply through the pipeline 2 to the head of the turbine 1 and turning on the heat exchangers b and 7. In parallel, open the regulating body 14. on line 13 with the valves 24, 25, 29 closed and the valve on line 16 and pump 8 part of the circulation water after the condenser 9 to the heat exchanger 7. after which it is discharged along lines 17, 18 to mix with the main flow of circulating water into line 20. At the same time, the valves 28, 32 are opened and, when the valve is closed 30, the drain of the heat exchanger 7 along lines 26 and 27 serves for condensation of steam in the heat exchanger 6, after which about through line 31 it is diverted to the thermal circuit of the turbine. Moreover, due to the possibility of heating this drainage in the limit to the saturation temperature of the steam in the bleed to the heat exchanger 6, the steam flow to this heat exchanger and, therefore, to the turbine head is increased to a large extent.

Claims (1)

The claims A method of obtaining additional power in a cogeneration plant with network heaters by increasing the flow rate of steam to the turbine head, regulating the flow rate of steam to the condenser, supplying circulating water from the cooler to the last one, diverting part of the circulation water after the condenser to the low-potential heat consumer, and the other part to cooler, and regulating the flow of circulating water to the cooler, characterized in that, in order to increase efficiency and reliability in the absence of heat and lack of heat circulating water is supplied to the network heaters of steam from the heating selections and part of the circulating water after the condenser, and the water after the consumer of low potential heat is mixed with the remaining part of the circulating water, while maintaining a constant flow of circulating water to the condenser and thermal cooler load.