RU2527261C1 - Thermal power plant by kochetov - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: thermal power plant comprises a steam turbine condenser, a decarbonifier with an air duct, a system of return water supply, which includes a cooling tower, a water receiving well, a self-flow water conduit, a circulating pump, a discharge pipeline to the steam turbine condenser and a drainage discharge pipeline to the cooling tower, at the same time the stack of the cooling tower is equipped with a water-distribution tray with spray nozzles, which in their turn are made in the form of a nozzle with a spray disc, comprising a cylindrical body with a nozzle, rigidly connected with the body and coaxially arranged in the upper part of the body and having a cylindrical hole for supply of liquid connected to the diffuser, axisymmetric to the body and the nozzle, and to the body, in its lower part, by means of at least three spikes, a sprayer is connected, arranged perpendicularly to the axis of the body and made in the form of a solid disc.

EFFECT: invention makes it possible to increase cost-efficiency of a thermal power plant.

2 cl, 3 dwg

Description

The invention relates to energy and can be used at thermal power plants.

The closest technical solution to the claimed object is a thermal power station according to the patent of Russian Federation No. 2484265, containing a steam turbine condenser, a decarbonizer with an air duct, which includes an air heater and a fan, a reverse water supply system including a cooling tower, water well, gravity water conduit, circulation pump, pressure head a pipeline to a steam turbine condenser and a discharge pressure pipe to a cooling tower consisting of an exhaust tower and a drainage basin connected by gravity m bypass channel with a water well, while the exhaust tower of the tower is equipped with a water distribution tray with spray nozzles, an irrigation device and a water trap.

The disadvantage when using the known thermal power plant is that the thermal power plant has reduced efficiency, since the heat of the thermal power station does not use the condensation heat of the steam exhausted in the turbine, but is vented to the environment with atmospheric air, heated and saturated with water vapor in the process - and mass transfer in direct contact with circulating water in a tower-type cooling tower.

The technical result is an increase in the efficiency of a thermal power plant.

This is achieved by the fact that a thermal power station containing a steam turbine condenser, a decarbonizer with an air duct, which includes an air heater and a fan, a reverse water supply system including a cooling tower, a water intake well, a gravity water conduit, a circulation pump, a pressure pipe to the steam turbine condenser and a discharge pressure head the pipeline to the cooling tower, consisting of an exhaust tower and a drainage basin, connected by gravity bypass channel with a water well, while the exhaust The cooling tower’s tower is equipped with a water distribution tray with spray nozzles, an irrigation device and a water trap, the thermal power station is additionally equipped with a cooling water recycling system connected to each other by hydraulic circuits for preparing and consuming water, while the cooling towers have separate hydraulic circuits for preparing and consuming water, containing a casing, at the bottom of which are located at least two tanks for collecting water, which are interconnected an ion tube providing hydraulic independence of the circuits for the preparation of working water and its consumption, while one tank is connected to a pump that delivers the water cooled in the cooling tower to the consumer, which again passes through the valve through the pipeline to the second tank, from which heated water is pumped through the filter and valve it is supplied through a pipeline to a manifold with nozzles located in the upper part of the tower body, and a system for monitoring the hydraulic resistance of the filter is installed between the filter and the valve, with the exhaust tower of the cooling tower consisting of a pressure gauge and a valve, and spray nozzles are made in the form of a nozzle with a spray disk containing a cylindrical body with a fitting rigidly connected to the body and coaxially located in the upper part of the body and having a cylindrical hole for supplying fluid connected to the diffuser, axisymmetric the housing and the fitting, and to the housing, in its lower part, by means of at least three spokes a sprayer is connected, located perpendicular to the axis of the housing and made in the form of a continuous drive.

Figure 1 presents a diagram of a thermal power plant, figure 2 is a diagram of a circulating water supply system for a cooling tower, figure 3 is a diagram of a spray nozzle exhaust tower of a cooling tower.

The thermal power station (Fig. 1) contains a circulating water supply system for cooling tower 1, a decarbonizer 2 with an air duct 3, which includes an air heater 4 and fan 5, a circulating water supply system including a cooling tower, a water intake well 6, a gravity water conduit 7, a circulation pump 8, a pressure pump a pipeline 9 to a steam turbine condenser 1 and a discharge pressure pipe 10 to a cooling tower consisting of an exhaust tower 11 and a drainage basin 12 connected by a gravity bypass channel 13 to a water intake well 6, a pipe the wire 14 connecting the exhaust tower 11 of the tower with the suction duct of the fan 5 for supplying heated and saturated with water vapor air to the nozzle of the decarbonizer 2, while the exhaust tower 11 of the cooling tower is equipped with a water distribution tray 15 with spray nozzles 16 made in the form of nozzles with a sprayer (Fig. 3), as well as an irrigation device 17 and a water trap 18.

The nozzle with a spray (Fig. 3) contains a cylindrical body 30 with a fitting 31 rigidly connected to the body and coaxially located in the upper part of the body and having a cylindrical hole 32 for supplying fluid connected to the diffuser 33, an axisymmetric body and the fitting. To the housing 30, in its lower part, by means of at least three spokes 35 is connected a spray gun 34 located perpendicular to the axis of the housing and made in the form of a solid disk. The atomizer disk 34 is formed by two surfaces, one of which, facing the diffuser 33, is a curved surface, and the curve of the nth order, for example, elliptical, parabolic, etc., and the second as a plane, is the line forming this surface.

The spokes 35, by means of which the atomizer disk is attached to the body, are arranged radially with respect to the axis of the body, and can be made straight (not shown) and curved in shape, moreover, they are attached to the body by screws (not shown), and either using a detachable connection, for example threaded, or one-piece, for example by resistance welding.

The atomizer disk can be formed by two congruent and equidistant surfaces of the n-th order, while the nozzle atomizer can be made of solid materials, such as tungsten carbide.

The water recycling system using cooling towers contains cooling towers interconnected by hydraulic circuits for the preparation and consumption of water. For one consumer (Fig. 2), the system includes a cooling tower housing 19, in the lower part of which there is a tank 20 for collecting water with a recharge system 21 of water used for evaporation. The tank 20 is connected to a pump 24, which supplies the water cooled in the cooling tower to the consumer 26 through the filter 25. In the area between the filter 25 and the consumer 26, a filter hydraulic resistance control system is installed, consisting of a pressure gauge 27 and a valve 28. After heating the water in the consumer, it comes again through a valve 29 through a pipe 22 to a manifold 23 with nozzles located in the upper part of the tower tower. The water is cooled by a counter flow of air coming in counterflow from below, and the cycle of the heat and mass transfer process is repeated.

The operation of the thermal power plant is as follows.

Cooled water in the tower by the circulation pump 8 through the pressure pipe 9 is supplied to the condenser 1 of the steam turbine. In the condenser 1, the circulation water is heated due to the heat of condensation (vaporization) of the steam exhausted in the turbine and is fed through a drain pressure pipe 10 to the water distribution tray 15 of the exhaust tower 11.

From the water distribution tray 15, the water enters the spray nozzles 16, made in the form of nozzles with a spray (Fig. 3), with which the water stream is sprayed and in the form of jets and drops falls on the irrigation device 17, and then flows in the form of rain into the drainage basin 12. The liquid is supplied through a cylindrical hole 32 to the diffuser 33, and from it flows under pressure into the atomizer 34, while additionally crushing liquid droplets due to turbulence of the outlet stream, and the finely dispersed stream leaves the nozzles with a wide flame spraying liquid (solution). In the exhaust tower 11 of the tower towards the flow of water, atmospheric air moves. In the process of direct contact of heat carriers, heat and mass transfer between water and air is carried out, while the water is cooled, and the air is heated and saturated with water vapor. Then the air passes the water trap 18, where drip moisture is separated from it, and is discharged through the exhaust tower 11 of the tower into the atmosphere.

The cooling effect in the tower is achieved by evaporating 1% of the water circulating through the tower, which is sprayed by nozzles and flows into the tank in the form of a film through a complex system of irrigation channels to meet the flow of cooling air pumped by fans (not shown). An effective droplet separator reduces water loss due to drip entrainment. The amount of condensed moisture carried by the air flow depends on the water concentration and the maximum value of 25 m ³ / (h · m ²⁾ does not exceed 0.1% of the volume flow of chilled water through the cooling tower.

Part of the total flow of heated and saturated with water vapor in the exhaust tower of the tower of atmospheric air through the pipe 14 is sent to the suction box of the fan 5 and is fed under the nozzle of the decarbonizer 2. The source of chemically purified water is supplied to the decarbonizer 2, where it is decarbonized by the oncoming flow of air supplied under the decarbonizer of the exhaust tower 11 of the cooling tower through the pipe 14 with the fan 5. Decarbonized water is sent to the deaerator, from where it is supplied, for example, to feed the heating system zheniya. In the case when the temperature of the air supplied from the exhaust tower 11 of the cooling tower is insufficient to carry out the process of decarbonization of water, it is sent to the air heater 4, in which it is heated and fed with a fan 5 under the nozzle of the decarbonizer 2.

From the catchment basin 12, chilled water is supplied via a gravity bypass channel 13 to a water intake well 6 and to a gravity water conduit 7, from where it is again fed into the pressure pipe 9 by a circulation pump 8.

Providing a thermal power plant with a cooling water recycling system reduces the amount of water evaporated into the air during heat and mass transfer in the decarbonizer nozzle and discharged into the atmosphere with air, which further increases the efficiency of the thermal power plant by reducing the loss of chemically treated water with decarbonizer vapor.

Claims (2)

1. A thermal power plant comprising a steam turbine condenser, a decarbonizer with an air duct, which includes an air heater and a fan, a water recycling system including a cooling tower, a water intake well, a gravity water conduit, a circulation pump, a pressure pipe to a steam turbine condenser and a discharge pressure pipe to the cooling tower , consisting of an exhaust tower and a drainage basin, connected by gravity bypass channel with a water intake well, while the exhaust tower of the cooling tower is equipped with a water distribution tray with spray nozzles, an irrigation device and a water trap, the thermal power station is additionally equipped with a circulating water supply system for cooling towers interconnected by hydraulic circuits for preparing and consuming water, while the cooling towers have separate hydraulic circuits for preparing and consuming water, containing a casing in the lower part of which at least two water collection tanks are located, which are interconnected by a compensation pipe, ensuring hydraulic independence of the circuits for the preparation of working water and its consumption, while one tank is connected to a pump that delivers the water cooled in the cooling tower to the consumer, which again flows through the valve through the pipeline into the second tank, from which the heated water is pumped through the filter and the valve through the pipeline in the collector with nozzles located in the upper part of the tower body, and in the area between the filter and the valve, a system for monitoring the hydraulic resistance of the filter, consisting of a manometer and valve, characterized in that the spray nozzles of the exhaust tower of the tower are made in the form of nozzles with a spray disk containing a cylindrical body with a fitting rigidly connected to the body and coaxially located in the upper part of the body and having a cylindrical hole for supplying fluid connected to the diffuser, an axisymmetric body and a fitting, and to the housing, in its lower part, by means of at least three spokes a sprayer is connected, located perpendicular to the axis of the housing and made in the form of a solid ka. 2. Thermal power station according to claim 1, characterized in that the nozzle disk of the nozzle in the exhaust tower of the tower is formed by two surfaces, one of which, facing the diffuser, is a curved surface, and the curve n -th order, and the second is the plane, or the spray disk is formed by two congruent and equidistant surfaces of the n-th order, and the spokes through which the spray disk is attached to the body are located radially with respect to the axis of the body, and in shape can be made straight and curved, while the nozzle atomizer is made of solid materials, such as tungsten carbide.

Images