UA18636U - Cooling tower - Google Patents

Abstract

A cooling tower has a chamber for supply of waste steam outside the condenser of turbine inside which evaporation sections of bundle of heat pipes are placed, those are arranged as straight circular cylinder with axis normal to the axes of heat pipes, condensation sections of those are placed in the chamber of heat exchange with environment separated from the chamber for waste steam supply with pipe plate, this is at the side of the cylinder side surface connected to atmospheric air and connected to exhaust pipe, where fan is installed, with transition air dust in which pipe grid is mounted, there the ends of the condensation sections of heat pipes are fixed. The lower section of the chamberof waste steam supply is connected to the working volume of condenser of turbine, its heat exchanger is connected to sprinkling unit of arranged separately chamber of evaporation cooling equipped with a nozzle placed under the sprinkling unit, a fan in the upper part of that chamber, this is installed in exhaust pipe connected to the chamber of evaporation cooling with transition air duct, and storage basin, at that the last one is connected by pipeline to heat exchanger of condenser of the turbine.

Description

Description of the invention

The useful model refers to the field of energy and can be used in the development of cooling towers at 2 thermal and nuclear power plants.

Known installation for cooling | see author's certificate of the USSR Mo 1326864, IPC E2881/06, publ. 1985), which contains a chamber for supplying spent steam with evaporating sections of the heat pipe package in it and condensing areas equipped with fins of the heat pipe package outside the chamber in the air flow generated by the fan. This technical solution is characterized by increased efficiency and reliability due to the use of heat pipes installed in such a way that their evaporating sections are located in the exhaust steam supply chamber, and the condensing sections are in the surrounding air. Heat pipes intensify the processes of heat exchange between the spent steam and the environment. However, the efficiency of the installation decreases due to the fact that the flow around the heat-emitting surface of the heat pipes is uneven due to the fact that the position of each of the heat pipes of the package is not the same in relation to the air flow, and therefore the total heat output 72 from the package of heat pipes will be low.

As a prototype, the condensing unit closest in terms of technical essence was chosen | see declaratory patent for a utility model Mo 5093, IPC E2881/06, publ. 2005), which contains an exhaust steam supply chamber, inside which there are evaporation sections of a package of heat pipes laid in the form of a straight circular cylinder, the axis of which is perpendicular to the axes of the heat pipes, the condensing sections of which are located in a heat exchange chamber with an environment separated from the exhaust steam supply chamber a pipe board, and which is connected to the atmospheric air from the side of the cylinder and is connected to the exhaust pipe, where the fan is installed, by a transitional air duct, in which a pipe grid is mounted, in which the ends of the condensing sections of the heat pipes are fixed. Heat pipes are equipped with fins in the heat exchange chamber with the environment. In this condensing unit, the efficiency is increased due to the fact that in the chamber of heat exchange with the environment, a high uniformity of the supply of atmospheric air to each of the heat pipes of the pu package from its periphery to the center is ensured by choosing the optimal shape of the package and, accordingly, the channel for forming the air flow. The execution of a package of heat pipes in the form of a straight circular cylinder provides approximately the same conditions for the heat exchange of each of the heat pipes with the air flow created by the fan.

The use of an exhaust fan in this installation makes it possible to increase reliability by ensuring the elimination of the danger of its freezing in winter, since it is installed in the flow of already heated atmospheric air in the heat exchange chamber with the environment.

At the same time, this installation has disadvantages characteristic of dry cooling towers, to which it belongs. at

The temperature of cooled water in such an installation in the warm period of the year is much higher (it can be 15-209С higher than the air temperature), and in winter it is lower (it can be only 5-62), than in evaporative cooling towers in . M | -

See, for example, the book Farforovsky B.S., Farforovsky V.B. Coolers of circulating water.-L.: Znergia,

Leningrad Department, 1972.-112 p.). This causes the danger of water freezing in radiators during the winter, especially in areas with severe winters. In addition, the cost of a radiator or dry cooling tower is much higher than the cost of a cooling tower with direct contact of water and air. The cost increase is due to the replacement of relatively inexpensive nozzles with heat exchangers. with

The basis of a useful model is the task of creating a cooling tower, in which the new structure of the turbine condenser and the new relationship of the exhaust steam supply chamber, the heat exchange chamber with the environment, and the evaporative cooling chamber would allow for increased efficiency and reliability and lower costs.

The problem is solved by the fact that in the condensing unit, which contains a supply chamber - 15 spent steam outside the turbine condenser, inside which there are evaporating sections of a package of heat pipes, laid in the form of a straight circular cylinder, the axis of which is perpendicular to the axes of the heat pipes, (ee) condensing sections which are placed in the heat exchange chamber with the environment, separated from the exhaust steam supply chamber by a pipe board, and which is connected to the atmospheric air from the side of the cylinder and is connected to the exhaust pipe, where the fan is installed, by a transitional air duct, in which (95) 50 a pipe grid is mounted, in which the ends of the condensing sections of the heat pipes are fixed, according to the useful

F model, the lower part of the exhaust steam supply chamber is connected to the working volume of the turbine condenser, the heat exchanger of which is connected to the spraying device of a separately made evaporative cooling chamber, equipped with a nozzle placed below the spraying device, a fan in the upper part of this chamber, installed in the exhaust a pipe connected to the evaporative cooling chamber 59 by a transition duct, and a water collection basin, and the latter is connected by a pipeline to the heat exchanger of the turbine condenser. Heat pipes can be equipped with fins in the exhaust steam supply chamber, or in the heat exchange chamber with the environment, or along their entire length.

The connection of the lower part of the spent steam supply chamber with the working volume of the turbine condenser, the heat exchanger of which is connected to the spraying device of a separately made evaporation and cooling chamber, equipped with a nozzle located below the spraying device, a fan in the upper part of this chamber, installed in the exhaust pipe, connected to the evaporative cooling chamber by a transition duct, and a water collection basin, and the latter is connected by a pipeline to the heat exchanger of the turbine condenser, and the heat pipes can be equipped with fins in the exhaust steam supply chamber, or in the heat exchange chamber with the environment, or along their entire length ., makes it possible to increase the efficiency by reducing the temperature of the cooled water by using the evaporative cooling mechanism in the evaporative cooling chamber in the proposed cooling tower, which allows to obtain a cooling limit significantly lower than the air temperature and thus implement a weight of evaporative cooling. At the same time, the "dry" part of the cooling tower in the form of a waste steam supply chamber and a heat exchange chamber with the environment with a package of heat pipes in them allows pre-cooling of water to a temperature higher than the dry bulb air temperature, as well as reducing water losses in the evaporative cooling chamber. The turbine condenser will work more efficiently, since it is a combination of a surface condenser with a heat exchanger in the form of a coil and a mixing type condenser, since in it the waste steam will also condense on the 7/0 Water jets coming from the waste steam supply chamber. And this additionally makes it possible to reduce the temperature pressure (temperature difference between steam and water at the outlet of the condenser) to 0.2-0.C. instead of 4-5 degrees. for surface capacitors. This circumstance makes it possible to reduce the size of the capacitor and its cost | see, for example, the book Farforovsky B.S., Farforovsky V.B. Circulating water coolers.-L.: Znergia, Leningrad department, 1972.-112 p., p. 78). The reliability of the cooling tower is increased due to the fact that there is no problem of the fan icing in the winter, as well as due to the high reliability of the heat pipes and the fact that if even one of the parts of the cooling tower ("dry" or evaporative) fails, which is unlikely, the other will ensure the operation of the cooling tower. Reducing the cost of the cooling tower is ensured by combining the advantages of evaporative and dry water cooling methods in it, which leads to a reduction in the dimensions of the condenser and each of its components, a reduction in irreversible water losses, and therefore, in cost.

The technical essence and principle of operation of the proposed cooling tower is explained by the drawing.

The drawing shows a cooling tower in section. The cooling tower includes chambers: supply of spent steam 1, heat exchange with the environment 2 and evaporative cooling 3. Chamber 1 and chamber 2 are separated from each other by a pipe board 4, in which heat pipes 5 are fixed and sealed. Condensing areas 6 of heat pipes 5 are introduced into chamber 2, and their evaporation sections 7 are located in chamber 1. The ends of the condensing sections 6 of the heat pipes 5 are fixed in the pipe grid 8. The turbine 9 is connected to the working volume of the condenser 11 and the working volume of the condenser 11 by the exhaust steam pipe 10. is connected by a condensate pipe 12 with a condensate pump 13 in it with the working volume of the condenser 11. A transition duct 14 connects the chamber 2 with an exhaust pipe 15, in which a fan 16 is installed. The heat exchanger 17 of the condenser 11 is connected by a pipeline 18 Ge) by a sprinkler device 19 in chamber 3, which also houses a nozzle 20 and a water collection basin 21, which is connected to the heat exchanger by a chilled water pipeline 22 with a pump 23 in it compartment 17 of the condenser 11. Chamber C is equipped with a transition duct 24 and an exhaust pipe 25, in which a fan 26 is installed. The condenser 11 is equipped with a condensate pipe 27 with a condensate pump 28 in it. co

The cooling tower works as follows. The spent steam from the turbine 9 is directed to the spent steam chamber 1 and into the working volume of the condenser 11 through the spent steam pipe 10 /-" . The spent steam in the chamber 1 heats the evaporating sections 7 of the heat pipes 5, simultaneously condensing. The heat carrier in the heat pipes 5 evaporates or boils and moves in the form of steam to their condensing sections 6 from chamber 1 to chamber 2, transferring the heat taken from the spent steam due to the latent heat of steam formation.

Favorable conditions for this are created by a large area of heat exchange of spent steam with heat pipes 5, - s formed by ribs on the evaporation sections 7 and condensation sections b of the heat pipes. In chamber 2 due to the heat exchange of the branched surface of the heat exchange formed by the ribs on the condensing sections of the heat pipes with the flow of air formed by the fan 16 coming from the side of the chamber 2, the condensing sections of the heat pipes 5 are cooled and the coolant in them condenses. The condensed heat carrier of the heat pipes 5 is returned in the form of liquid to the evaporation sections 7 - heat pipes. The condensate of the spent steam formed in the chamber 1 of the cooling tower is supplied to the working volume of the condenser 11 through the condensate line 12 with the help of the condensate pump 13. Moreover, the temperature

Me of chilled water in chamber 1, which is the "dry" part of the proposed cooling tower, can only be at a higher temperature

Ge) air on a dry bulb and this part performs the function of pre-cooling water. In the working volume of Condenser 11, heat exchange takes place between condensate of spent steam, spent steam that

Mami enters from the turbine 9 through the steam pipe of the spent steam 10, as well as with the heat exchanger 17 of the condenser 11, as a result of which the spent steam condenses, and its condensate is mixed with the condensate coming from the chamber 1 and cooled as a result of interaction with the heat exchanger 17. In its in turn, the water in the heat exchanger 17 is cooled due to evaporative cooling in the chamber 3. The heat exchange of the water sprayed by the spraying device 19 in the chamber C on the nozzle 20, which distributes it into a jet and drops, is carried out when it interacts with the air flow generated by the exhaust fan 25 Cooling of water in this case is carried out by transferring heat from water to air due to surface evaporation and heat transfer by contact. Cooled water, and the cooling limit during evaporative cooling can be much lower than the air temperature, which is a characteristic advantage of evaporative coolers, because it accumulates in the pool 21. Water from the pool 21 is sent to the heat exchanger 17 of the condenser 11 with the help of the pump 23 through the chilled water pipeline. Then the cycle repeated The cooled condensate from the working volume of the condenser 11 is pumped out by the pump 28 through the condensate pipe 27.

A model of a cooling tower was manufactured and tested, which included a steam chamber with a heating unit, several heat pipes, the evaporating sections of which are mounted in a hermetic chamber, and the condensing sections 65 are led through insulating seals into a chamber for heat exchange with the surrounding air, equipped with an exhaust fan. The steam chamber was connected by a steam pipe to the sealed chamber in its upper part.

The hermetic chamber was equipped with a condensate collector in its lower part and connected to the working volume of the turbine condenser simulator, which was also connected by a pipe to the steam chamber. The heat exchanger of the condenser simulator was attached to a pipe with holes in its upper part, which acted as a sprinkler device, and was installed in a separate chamber (evaporative cooling chamber simulator) with a wooden grid simulating a nozzle, an exhaust fan and a vessel for collecting chilled water , which in turn was connected by a pipe to the heat exchanger of the condenser simulator.

As a result of the conducted research, the following was established: - some time after turning on the heater of the steam chamber, steam began to be produced in it and 7/0 flowed into the hermetic chamber with the evaporation sections of the heat pipes, which was evidenced by the increase in the temperature of the heat pipes, which was monitored; - after warming up the heat pipes in the chamber - a chamber simulator of heat exchange with the environment as a result of heat exchange with the air flow created by the fan, condensate began to accumulate in the condensate collector; - condensation of steam in the working volume of the condenser occurred both due to heat exchange with the condensate coming from the hermetic chamber, and due to heat exchange with the heat exchanger of the condenser simulator, the water in which was cooled in the simulator of the evaporative cooling chamber; - post-cooling of the condensate took place in the simulator of the turbine condenser; - the use of heat pipes with fins in the evaporative sections increased the efficiency of the "dry" 2° part of the cooling tower due to both the high performance indicators of the closed evaporation-condensation cycle implemented in them, and due to the increased area on which heat exchange between steam and heat pipes takes place, and between atmospheric air and heat pipes; - with the help of the "dry" part of the cooling tower, the temperature of the cooled water can be obtained only higher than the air temperature according to the dry thermometer, and this part performs the function of pre-cooling the water and contributes to the reduction of water consumption. A reduction in the cost of a cooling tower is provided by a combination of the advantages of evaporative and dry water cooling methods, which leads to a reduction in the size of the condenser and the cooling tower as a whole compared to the size of a completely dry installation, and, accordingly, to a reduction in cost; - the high reliability of the cooling tower is determined by the high reliability of the heat pipes, their significant number when used in the cooling tower, and the elimination of fan icing in winter. "oh co

Claims (4)

Formula of the invention (Se) 1. A cooling tower containing a chamber for supplying spent steam outside the turbine condenser, inside which (2,0) 35 the evaporating sections of a package of heat pipes laid in the form of a straight circular cylinder, the axis of which is perpendicular to the axes of the heat pipes, the condensing sections of which are placed in the heat exchange chamber with the environment, separated from the exhaust steam supply chamber by a pipe board, which is connected to the atmospheric air on the side of the cylinder and is connected to the exhaust pipe, where the fan is installed, by a transitional air duct, in which a pipe grid is mounted, in which the ends of the condensation pipes are fixed " sections of heat pipes, which is distinguished by the fact that the lower part of the exhaust steam supply chamber with c is connected to the working volume of the turbine condenser, the heat exchanger of which is connected to the spray device of a separately made evaporative cooling chamber, equipped with a nozzle located below the spray device, fan in the upper part other parts of this chamber, installed in the exhaust pipe, connected to the evaporative cooling chamber by a transition duct, and a water collection basin, and the latter is connected by a pipeline to the heat exchanger of the turbine condenser. - 2. Cooling tower according to claim 1, which differs in that the heat pipes are equipped with fins in the exhaust steam supply chamber. co 3. Cooling tower according to claim 1, which differs in that the heat pipes are equipped with fins in the heat exchange chamber with the FD environment. 4. Cooling tower according to claim 1, which differs in that the heat pipes are equipped with ribs along their entire length. (95) 42) c 60 b5