RU2472086C1 - Thermal power plant - Google Patents

Abstract

FIELD: power industry.

SUBSTANCE: thermal power plant includes steam turbine condenser, decarboniser with air duct, to which air heater and fan are connected, and recirculating water supply system. Recirculating water supply system includes cooling tower, water-receiving well, gravity water conduit, circulation pump, pressure pipeline to condenser of steam turbine and drain pressure pipeline to cooling tower. Cooling tower consists of stack and water-collecting basin connected via gravity bypass channel to water-receiving well. Stack of cooling tower is equipped with water-distributing tray with spray nozzles, spraying device and water catcher. Spraying device of cooling tower is made in the form of a module consisting of layers of polymer cellular tubes. Tubes are cylindrical and arranged in all layers parallel to each other and welded on edges of module between themselves in connection places. Cavities of each of the tubes and intertube space is filled with hollow polymer balls. Diameter of balls is larger by 5-10% than maximum size of tube cell.

EFFECT: increasing economy of thermal power plant.

2 dwg

Description

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

Known thermal power plant according to the patent of the Russian Federation No. 2350760, 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 drain pressure line 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 The tower of the cooling 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 a reduced efficiency, since the heat of the power plant does not use the heat of condensation of the steam exhausted in the turbine, but is discharged into the environment with atmospheric air.

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 nozzles and 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 pipe to the cooling tower, consisting of an exhaust tower and a catchment basin, connected by gravity bypass channel with a water well, at the exhaust tower of the cooling tower is equipped with a water distribution tray with spray nozzles, an irrigation device and a water trap, and the cooling tower irrigation device is made in the form of a module from layers of polymer cellular pipes, the pipes are cylindrical, placed in all layers parallel to each other and welded along the ends of the module in places contact, while the cavities of each of the pipes and the annulus are filled with hollow polymer balls, and the diameter of the balls is 5 ÷ 10% larger than the maximum cell size t K.

Figure 1 presents a diagram of a thermal power plant, figure 2 - irrigation device cooling tower in a perspective view.

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

The irrigation device of the cooling tower (Fig. 2) is made in the form of a module from layers 19 of polymeric cellular pipes 20. The pipes are oriented in all layers 19 parallel to each other and are welded along the ends 21 of the module between them in places 22 of contact. The cavities of each of the pipes and the annular space are filled with hollow polymer balls 23, and the diameter of the balls is 5 ÷ 10% greater than the maximum cell size of the pipes 20.

The implementation of the tower in this way allows you to give the ends of the module the properties of stiffness diaphragms. This makes it possible to avoid subsidence of the irrigating layers, i.e. to ensure during installation and to maintain during operation the optimal geometry of the curved cellular surfaces of the pipes to create a thin water film throughout the sprinkler without dripping. Thus, uniform heat and mass transfer is achieved and, therefore, the cooling ability of the irrigator increases and its material consumption decreases. Additional rigidity of the design gives the filling of the pipes and the annular space with hollow polymer balls 23.

Moreover, to increase the rigidity of the pipe structure in adjacent layers can be staggered relative to each other.

Cellular polymer pipes 20 are obtained by extrusion, cut into sections, the length of which corresponds to the length of the side of the module, and laid in the conductor, observing the necessary laying direction, i.e. placing the pipes 20 parallel to each other. After accumulation in the conductor of the required number of pipes 20, heating elements are brought to their ends and welded to each other in places of contact 22. Due to this, stiffness diaphragms are formed at the ends 21 of the sprinkler module, allowing it to maintain the initial optimal geometry of its elements during operation. An additional rigidity of the structure is given by a denser stacking of pipes in a checkerboard pattern in adjacent layers.

The water recycling system using cooling towers contains cooling towers interconnected by hydraulic circuits for the preparation and consumption of water. For one consumer (not shown), the system includes a cooling tower housing, in the lower part of which there is a tank for collecting water with a system for replenishing water used for evaporation. The tank is connected to a pump, which supplies the water cooled in the cooling tower to the consumer through a filter.

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, water enters the spray nozzles 16. With the help of nozzles 16, 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 catchment basin 12. In the exhaust tower 11 of the cooling tower, the water flows towards atmospheric air. 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 towards the flow of cooling air pumped by fans (not shown). An effective droplet separator reduces water loss due to drip entrainment. The amount of droplet moisture carried away by the air flow depends on the irrigation density and at a maximum value of 25 m ³ / (h · m ² ) does not exceed 0.1% of the volumetric flow rate of the cooled 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 duct of the fan 5 and is fed under the nozzle nozzles decarbonizer 2.

The irrigation device of the tower is as follows.

Water sprayed by nozzles enters the sprinkler and flows off with a thin film without droplet formation along its elements. In this case, uniform heat and mass transfer occurs over the entire volume of the sprinkler, and therefore, the cooling ability of the sprinkler increases and the material consumption decreases.

The source chemically purified water is supplied to the decarbonizer 2, where it is decarbonized by a counter flow of air supplied to the decarbonizer nozzle from the exhaust tower 11 of the cooling tower through the pipe 14 with fan 5. Decarbonized water is sent to the deaerator, from where it is fed, for example, to recharge the heat supply system. 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 (1)

A thermal power station comprising 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 a steam turbine condenser and a discharge pressure pipe to a cooling tower consisting of from an exhaust tower and a drainage basin connected by a gravity bypass channel to a water intake well, while the exhaust tower of the cooling tower is provided one distribution tray with spray nozzles, an irrigation device and a water trap, characterized in that the cooling tower irrigation device is made in the form of a module from layers of polymer honeycomb pipes, the pipes are cylindrical, placed in all layers parallel to each other and welded along the ends of the module between them in contact, in this case, the cavities of each of the pipes and the annular space are filled with hollow polymer balls, and the diameter of the balls is 5-10% larger than the maximum cell size of the pipes.

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