RU2168131C1 - Method for liquid cooling in power plant cooling tower and power plant cooling tower for realization of the method - Google Patents

Abstract

FIELD: equipment of power plants, concerns means providing for cooling of water used as the plant working medium. SUBSTANCE: method consists in the fact that obtained is a cone of liquid drops with obtained is a cone of liquid drops with particle sizes from 0.7 mm to 0.9 mm of the equivalent diameter; the angle of deviation of the liquid drop cone from the vertical does not exceed 30 deg, and the disintegrated liquid is directed inside the shaft at a speed of motion of liquid in the lower part of the shaft within 8 to 9 m/s. EFFECT: enhanced efficiency of use of the cooling tower shaft volume at a heat exchange between the water drops and air, simplified construction of the cooling tower. 3 cl, 3 dwg

Description

 The invention relates to the equipment of power plants and relates to means for cooling water used as the working fluid of the installation.

Water is usually used to cool various units of power plants. However, the discharge of warm water into the environment adversely affects the environmental situation. An increase in water temperature in natural reservoirs by 8-10 ^o C leads to the growth of simple algae, to depletion of water by oxygen and the death of many inhabitants of this reservoir.

 Technical solutions are known that make it possible to use a pond system for cooling water without adverse environmental consequences (see [1] p. 182). Create a system of ponds connected by ducts. Warm water is released into one of them, which then flows from one pond to another, while cooling. Different temperatures in ponds are useful: for heating greenhouses and greenhouses, breeding heat-loving fish, etc.

 However, this technical solution was not widespread due to its significant drawback associated with the high cost and large area required for the placement of ponds. Pa enterprises located in cities and large settlements, this method is not feasible.

 A known method of cooling warm water in spray pools, for example, given in [2]. In this technical solution, warm water is sprayed using centrifugal nozzles evenly placed over the surface of the pool.

 However, the known method does not exhaust all the possibilities of saving space for the placement of equipment for cooling water of a power plant.

Technical solutions are also known that allow to intensify heat transfer using cooling towers of a different system for heat removal. For example, according to [3], heat exchange between gas and liquid is carried out in a device containing a vertical cylindrical body, along the axis of which are two groups of atomizing liquid nozzles. In this case, the liquid is sprayed under pressure on average 3 • 10 ⁵ Pa, which provides droplet size from 0.4 to 0.5 mm in diameter, and direct liquid droplets on a conical surface with an angle at the apex of 70 ^o . Drops of liquid reach the cylindrical surface of the housing and flow down it. The liquid from the upper group of nozzles is collected using a collector made on the body and is diverted to the suction of the pump, which supplies this liquid to the lower group of nozzles. Gas is passed from bottom to top through the thus formed conical surfaces of the liquid droplets. At the same time, a reduction in the entrainment of liquid with gas is achieved, and the efficiency of heat transfer increases with direct contact of gas and liquid.

 However, when using such a technical solution for cooling the warm waters of a power plant, its significant disadvantages are manifested, consisting in the complex design of the device and the increased cost of circulating fluid in two circuits. In addition, as a result of spraying liquid on conical surfaces with the collection of droplets on the surface of the body, the body volume is not used efficiently, the contact time of the liquid droplets with gas is short.

 Technical solutions are also known in which a fan is used to intensify heat transfer and thus reduce the dimensions of the cooling tower, for example, given in [4]. In the known technical solution can be obtained significant savings in space for installation of the tower.

 However, this technical solution has a very complex mine structure, increased manufacturing costs. The increase in the speed of movement of the cooling air flow using a fan with increased hydraulic resistance of the air path leads to high operating costs.

 Other technical solutions are also known in which heat transfer is used directly between gas and droplets of liquid sprayed by nozzles, for example, in [5] gas is passed from bottom to top through a device housing in which two or more planes equipped with spray nozzles are installed perpendicular to the direction of gas movement moreover, the direction of the sprayed liquid droplets is chosen close to horizontal, and the speed of the sprayed drops is 10-15 m / s. Thus, the treated gas is passed through a series of curtains of liquid droplets, which provides enhanced heat and mass transfer between the liquid and gas.

 However, the known technical solution when used in a cooling tower of a power plant has several disadvantages, for example, increased operating costs associated with the need to additionally pump gas through the device’s casing, a complex piping system inside the casing, the volume of the device’s casing is not fully utilized.

 Of the known technical solutions, the closest object to the claimed one on the basis of essential features is the method of cooling the liquid in the cooling tower of a power plant described in the description of the invention, and the device of such a cooling tower [6], adopted by the authors for the prototype of the claimed invention.

 The object adopted as a prototype in terms of the method is a method of cooling liquid in a cooling tower of a power plant, in which heat is removed to the ambient air, while the liquid flow is crushed in the lower part of the shaft and directed against the direction of gravity, filling the volume of the tower tower, the movement of liquid is ensured due to the pressure created by the pump and due to gravity, and for movement in the mine air flow using natural aeration. The object adopted for the prototype in the part of the device is a cooling tower of a power plant containing a shaft, in the lower part of which there is a device for crushing the fluid flow, and the outlet direction of the torch of the crushed liquid is set at an upward angle, which also contains a pool for collecting chilled water, a pump and pipelines.

 Taken as a prototype method and device provide increased air flow through the tower tower. To intensify heat transfer, the movement of air flow is ensured by ejection of air by a water torch.

 However, the method and device adopted for the prototype have significant drawbacks in that the technical solution does not provide the means that make it possible to use the volume of the cooling tower shaft most effectively; when spraying nozzles are operated, the relative speed of water and air droplets is insufficient, and the size of the water droplets is not optimal, which leads to a decrease in the efficiency of heat transfer.

 The objective of the invention is to increase the efficiency of using the volume of the shaft of the tower for the implementation of heat transfer between drops of water and air.

 As a result of solving this problem, a new technical result was achieved, consisting in the development of the design of the cooling tower and a method for cooling the liquid in it, which allow modernizing the cooling towers existing at the enterprises, reduce operating costs and provide an increase in the efficiency of cooling warm water. Using the invention in the design and manufacture of new cooling towers will significantly reduce the costs of their creation and operation, which increases their competitiveness in comparison with the known ones.

This technical result is achieved by the fact that when implementing the method of cooling the liquid in the cooling tower of a power plant, in which heat is removed to the ambient air, while the liquid flow is crushed in the lower part of the shaft and directed against the direction of gravity, filling the volume of the shaft of the tower, the movement of liquid provides due to the pressure created by the pump and due to gravity, and for movement in the mine air flow using natural aeration, while, according to the invention, the fragmentation of the fluid flow in They are filled to particles with a size of not more than 0.9 mm of equivalent diameter and direct the fragmented liquid at a speed of its movement in the lower part of the shaft of at least 8 meters per second, and provide counter motion of the stream of fragmented liquid and cooling air, and the angle of deviation of the stream of fragmented liquid from the vertical set to a value of not more than 30 ^o .

To implement the proposed method in the cooling tower of a power plant containing a shaft, in the lower part of which there is a device for crushing a liquid stream, the outlet direction of the torch of crushed liquid is set at an upward angle, also containing a pool for collecting chilled water, a pump and pipelines, according to the invention, a device for fragmentation of the fluid flow is made in the form of centrifugal jet nozzles, and the pump is installed with a pressure of at least 0.12 MPa in front of the nozzles. When this nozzle can be installed on the periphery of the mine and in this case, the nozzle is installed with the inclination of the nozzle torch to the center of the shaft, and the angle of inclination of the nozzle torch is made no more than 30 ^o .

A distinctive feature of the claimed invention is that the fragmentation of the fluid flow is carried out to particles of no more than 0.9 mm of equivalent diameter and direct the fragmented fluid at a speed of its movement in the lower part of the shaft of at least 8 meters per second, while providing oncoming movement of the flow of fragmented fluid and cooling air, and the angle of deviation of the flow of crushed liquid from the vertical is set to a value of not more than 30 ^o . In this case, a liquid in the form of droplets, under the action of inertia forces of its mass, first moves upward within the shaft, reaching zero absolute speed in the upper zone of the shaft, and then downwards under the action of gravity.

 This technical solution allows you to provide the longest path of the liquid droplet within the tower tower and, thus, to obtain the maximum time for heat removal from the droplet to the cooling air. With relatively small temperature head during the heat exchange between the liquid and the cooling air, the influence of heat transfer coefficients on the amount of heat removed is significantly reduced in comparison with other heat transfer processes. The determining factors in reducing the temperature of the cooled liquid are the heat transfer surface and the duration of the heat transfer process. The increased surface of the liquid droplets in comparison with the film formed on the surfaces of the nozzles of the tower and fan cooling towers allows to obtain in the claimed invention an increased amount of heat transferred from the liquid to the cooling air. A twofold increase in the length of the liquid flow path in contact with the cooling air stream compared to tower and fan cooling towers irrigated from above also allows increasing the amount of heat transferred from the liquid to the cooling air, which compensates for a slight decrease in the heat transfer coefficient in comparison with, for example, the fan cooling tower and get a significant gain by reducing energy costs.

 Another distinctive feature of the proposed method is that the crushing of the liquid is carried out to particles of no more than 0.9 mm equivalent diameter.

 This technical solution allows you to get the optimal ratio of the surface of the droplet to remove heat and evaporation, and the loss of water with evaporation is minimal, which ultimately increases the efficiency of heat removal.

Scientific studies and experiments performed by the authors showed that when the particle size of the liquid droplets is more than 0.9 mm of equivalent diameter, the specific contact surface area of the interacting media significantly decreases, which leads to a decrease in the cooling efficiency of warm waters. The range of sizes of liquid droplets is determined by the size of the diameter of the nozzle of the spray nozzle and its design. The experiments performed by the authors showed that when a significant amount of liquid particles with a droplet size exceeding 0.9 mm appear in the nozzle flare, the temperature of the cooled water decreases by 2. ..3 ^o C less, which is very significant for the cooling tower operation and degrades all performance indicators of the power plant.

 Another distinctive feature of the proposed method is that they provide oncoming movement of the flow of fragmented liquid and cooling air due to the speed of the liquid. This is achieved due to the following distinctive feature of the proposed method, namely the fact that the speed of the fragmented liquid when it is supplied in the lower part of the shaft is set to at least 8 meters per second. At the same time, the greatest value of the heat transfer coefficient is obtained at the highest temperature head during the heat transfer process, and thereby the costs and benefits obtained in the known technical solutions are optimized.

 Scientific studies and experiments performed by the authors showed that when the speed of the liquid droplets is less than 8 m / s, the atomization fineness in the known nozzle designs is insufficient to obtain the required size (less than 0.9 mm) of the liquid droplets. In addition, when the velocity of the liquid droplets is less than 8 m / s, the ejection effect practically disappears, the ejection of air into the nozzle torch is insufficient, which worsens the resulting cooling effect.

 The dependence of the relative velocity of the fluid flow and the flow of cooling air along the shaft height is shown in FIG. 3. The average speed of movement of cooling air is defined as its flow rate divided by the cross-sectional area of the shaft, and for the claimed cooling tower is about 3 m / s. Air consumption when using aeration, that is, air movement without using a fan, but only due to the temperature head and the ejecting effect of the injected liquid, can be taken as a constant value. When liquid is injected into the volume of the tower shaft, the fluid flow rate exceeds the air velocity, but then under the influence of gravity the velocity of the liquid droplets decreases and, upon reaching the top of the path, changes to the opposite and begins to increase to the free fall of the droplet in the air, which is shown in FIG. . 3.

 From the analysis of FIG. 3 it follows that in the inventive cooling tower, the possibility of intensifying heat transfer by increasing the heat transfer coefficient, the value of which depends on the relative speed of the cooling and cooling flows, is used most optimally in comparison with the known ones. The highest relative speed is maintained in the claimed object at the highest temperature difference. The use, for example, of an irrigated nozzle in known fan cooling towers leads to a decrease in the liquid velocity, and the gain due to an increase in the air velocity in comparison with the claimed invention disappears.

The inventive method also allows you to optimize the overall structure of the tower in cross section. A distinctive feature of the proposed method is also the fact that when applying the crushed liquid in the lower part of the mine, the deviation of the flow from the vertical is set to a value of not more than 30 ^o .

 This technical solution allows much better use of the transverse dimension of the tower, which is especially important when upgrading existing cooling towers using the claimed invention. In addition, this technical solution gives an additional positive effect, which consists in ejecting the flow of cooling air due to the formation of the relative flow rates of the liquid and cooling air to obtain an additional ejection effect in the center of the tower tower.

The experiments performed by the authors showed that when the deviation of the flow of liquid droplets from the vertical is more than 30 ^{o, the} droplets reach the walls of the mine and settle on them in the form of a film, which reduces the contact surface of the liquid and air, and reduces the efficiency of heat removal.

 When using the above distinctive features of the claimed invention, it is also possible to more effectively use natural aeration to move air flow in the mine. The highest relative velocities of water and air droplets are achieved in the lower zone of the shaft (see Fig. 3), and in the upper zone where the drip trap is installed, the relative velocity is low, which significantly reduces water entrainment, for example, in comparison with fan cooling towers.

 This allows for effective heat removal and at the same time significantly reduce the entrainment of water with the air stream. In addition, the use of natural aeration does not require any additional energy costs, which reduces operating costs.

 The cooling tower of a power plant for implementing the inventive method, in addition to elements that ensure the performance of the functions discussed above, which can basically be implemented by known means, has its own distinctive features provided by the separation of functions between the plant elements.

 The first distinguishing feature of the design is that the device for crushing the fluid flow is made in the form of centrifugal jet nozzles installed in the lower part of the shaft, and it is equipped with a pump with a pressure of at least 0.12 MPa in front of the nozzles.

 The design of centrifugal jet nozzles was developed by the authors on the basis of the theoretical provisions set forth in [7 p. 26 ... 93, 189 ... 206]. Tests of these nozzles showed that they provide the required range of sizes of liquid droplets (equivalent diameter less than 0.9 mm) with a torch height of up to 7.. . 9 meters, which corresponds to the dimensions of cooling towers mines used in most power plants, provided that the pressure of the liquid in front of the nozzles is at least 0.12 MPa. With a decrease in the liquid pressure in front of the nozzle below 0.12 MPa, an uneven spectrum of the formed liquid droplets appears, which significantly reduces the cooling efficiency. In addition, the height of the spray torch is reduced, which also does not allow sufficiently efficient use of the volume of the tower shaft.

 A feature of liquid atomization by centrifugal jet nozzles is that the liquid in the nozzle is divided into two streams: one is passed through the screw channels of the liner, and the second is formed by passing part of the liquid through the axial hole in the liner. The swirling and axial flows interact in the mixing chamber and in the nozzle channel of the nozzle. As a result of the interaction of these flows, a spray of liquid is formed, and the liquid flow breaks up into droplets already at a distance of about 100 mm from the nozzle exit [8] p. 106-109, Fig. 5.3, while achieving a sufficiently large torch height, allowing you to fill with droplets the entire volume of the shaft of the tower.

The liquid, having left the nozzle, goes through several stages on its way, which are described in detail in [4, Chapter 2]: the formation of droplets, the formation of a gas-liquid torch, movement in the free flow zone, etc. Studies have shown that the main effect of heat and mass transfer occurs precisely in the free flow zone, when the droplet stream, moving at high speed, intensively ejects gas, forming a gas-liquid torch. Studies conducted for the cooling tower of a power plant showed that the diameter of the nozzle channel of the nozzle, the angle of the opening of the torch and the pressure of the liquid in front of the nozzle have a significant effect on the amount of cooling warm water (Δ t _w is the temperature difference between the water entering the tower and chilled water).

 With an increase in the diameter of the nozzle channel, the diameter of the droplets increases and, accordingly, the specific surface area of the liquid and gas contact, the ejection coefficient, and the residence time of the droplets in the contact zone decrease.

 With an increase in the angle of opening of the torch, the efficiency of processes in the zone of free flow of the torch increases. However, the larger the opening angle, the shorter this area becomes and the less the resulting cooling effect.

The most significant increase in the efficiency of the water cooling process is observed with increasing pressure in front of the nozzle in the range from 0.12 to 0.2 MPa. A further increase in pressure gives a slight increase in Δt _w with a significant increase in energy consumption.

где d_i - диаметр капель i-ой фракции; n_i - число капель в i-ой фракции; m - количество фракций, на которые распыляются капли в факеле.At the indicated parameters, a polydisperse spray takes place, which is usually conventionally conditionally finely dispersed, characterized by an average droplet diameter. Of all types of averaging, the volume-surface diameter (Sauter diameter) of the droplet is usually used, which allows you to calculate the volume and area of the real spray:

where d _i is the diameter of the drops of the i-th fraction; n _i is the number of drops in the i-th fraction; m is the number of fractions onto which droplets are sprayed in the flare.

Thus, it is the use of centrifugal jet nozzles that allows to achieve at Δt _W up to 25 ^{o the} temperature of chilled water within the temperature of the wet thermometer plus 4 - 5 ^o .

 Another distinctive design feature is that the invention provides an option in which the nozzles are mounted on the periphery of the shaft. This option allows more efficient use of the transverse dimension of the shaft of the tower, which is very important when upgrading existing cooling towers according to the claimed invention. In this case, another distinguishing feature of the design is used - that the nozzles are installed with the nozzle torch inclined towards the center of the shaft.

 This distinctive feature allows you to use the increased velocity of the fluid flow to eject cooling air, which improves heat transfer and provides the required cooling fluid.

A distinctive design feature is that the angle of inclination of the nozzle torch is made in magnitude of not more than 30 ^o . This distinctive feature also allows for the ejection of air due to the fact that in the central zone of the mine the relative velocity of the particles of liquid and air is higher than at the periphery. At the same time, uniformity in filling the shaft volume with liquid droplets is maintained. The experiments showed that when the angle of the nozzle plume is more than 30 ^o, an increased number of drops settles on the walls of the mine, a liquid film forms, which reduces the heat transfer surface and reduces the cooling efficiency.

 Thus, the above distinctive features of the claimed invention in comparison with the known technical solutions make it possible to create a cheap and efficiently operating cooling tower for any industrial power or technological installation, which accordingly will ensure its competitiveness in the modern market.

 In FIG. 1 is a schematic diagram of a cooling tower of a power plant explaining the implementation of the proposed method.

 In FIG. 2 shows an option for installing nozzles on the periphery of the shaft with an inclination towards the center.

 In FIG. Figure 3 shows the change in the relative velocity of water droplets and cooling air along the shaft height.

 The inventive cooling tower contains a shaft 1, in which a device for crushing the fluid flow is installed, made in the form of a water distribution manifold 2 and nozzles 3, and the outlet direction of the torch of the crushed fluid is set at an upward angle. The cooling tower also contains a pool 4 for collecting chilled water, a pump 5 and pipelines connecting the heat exchange equipment 6 of the power plant with a pump 5 and a water distribution manifold 2. The device for crushing the fluid flow is made in the form of centrifugal jet nozzles 3 installed in the lower part of the shaft 1. The cooling tower is equipped with a pump 5 with a pressure that provides a pressure that is controlled by a pressure gauge 7, not less than 0.12 MPa in front of the nozzles 3. When upgrading existing plants and increased hydraulic ohm resistance of the cooled equipment can be installed an additional pump in front of the nozzles 3 to provide the specified pressure.

 The cooling tower contains an air aeration system, which includes windows 8 located in the lower part of the shaft 1, a droplet eliminator 9 and a deflector 10.

 The inventive method is as follows.

 Cooling water from the pool 4 is supplied by means of a pump 5 to cool the heat exchange equipment 6. The heated water enters the water distribution manifold 2 and is sprayed into the shaft 1 using centrifugal jet nozzles 3.

 When the water pressure in front of the nozzles 3 is not less than 0.12 MPa, a plume of water droplets with a particle size of liquid of not more than 0.9 mm of equivalent diameter is formed. The direction of the torches is set from the bottom up, and water droplets ejected from the nozzles at a speed of at least 8 m / s move up against gravity, filling the volume of the shaft 1.

In the case where the cross section of the shaft 1 is increased, the nozzles 3 are placed on the periphery of the shaft 1, as shown in FIG. 2, and the exit direction of the water droplet torches is set upward with the nozzle torch inclined toward the center of the shaft at an angle of no more than 30 ^° from the vertical. In this case, liquid droplets also fill the volume of the shaft 1 and move against gravity.

 Reaching the upper zone of the mine 1, the drops lose their speed and fall under the influence of gravity, pass a second time through the volume of the mine 1 and collect in the pool 4.

 Cooling air enters the shaft 1 volume from the atmosphere through the windows 8 and moves from bottom to top under the influence of the temperature pressure created during heat removal from the liquid, as well as under the influence of ejection forces moving with an increased velocity of liquid droplets. In the upper zone of mine 1, where the speed of movement is determined only by the air flow, since the liquid droplets lost their original speed due to gravity, separation of those liquid droplets that trap the air stream takes place on the droplet eliminator. Since the air flow rate in the inventive cooling tower is lower than, for example, in a fan cooling tower, only very small drops are captured by the air flow, which then coalesce on the surfaces of the droplet eliminator and are dragged down by gravity down into the pool 4, passing through the volume of the shaft 1. The loss of cooled water with an air stream is at the same time the minimum value.

 Thus, the above distinctive features of the claimed invention in comparison with the prototype increase the competitiveness of the claimed technical solution, as it provides increased cost-effectiveness of operation.

The calculations and experiments performed by the authors showed that, in comparison with the most effective known fan cooling towers, which provide a temperature drop of warm water by 12 ... 15 ^o C, the claimed invention provides a temperature drop of warm water to 15 ... 20 ^o C at a significant reduction in energy consumption during operation and a decrease in capital investment for the construction of a cooling tower.

Bibliographic information sources
1. Gurvich S.M., Kostrikin Yu.M. "Water Treatment Operator", Moscow: Energoizdat, 1981

 2. Copyright certificate of the USSR N 1366842, F 28 C 3/06, 1986, publ. to bull. N 2, 1988

 3. European Patent Application EP 0097097, F 28 C 3/06, publ. 12/28/83.

 4. Copyright certificate of the USSR N 1601490, F 28 C 1/00, 1988, publ. in bull. N 39, 1990

 5. International patent application WO 93/18842, B 01 D 47/06, F 28 C 1/00, publ. 09/30/93.

 6. French patent N 1590956, F 28 C 1/00, publ. 05/29/70. - prototype.

 7. Galustov B.S. "Direct-flow spraying apparatus in the power system." M .: Epergoatomizdat, 1989.

 8. Pages D.G., Galustov B.S. "Fundamentals of spraying liquids." M .: Chemistry, 1984

Claims (3)

1. A method of cooling a liquid in a cooling tower of a power plant, in which heat is removed into the ambient air, while the liquid stream is divided into several streams and each of them is crushed into drops in the lower part of the shaft using a spray device, the resulting torch of liquid drops is directed against the direction forces of gravity, filling the volume of the shaft of the tower, the movement of the liquid is provided due to the pressure created by the pump and due to gravity, and for movement in the shaft of the air flow using natural aeration, exl sistent with that obtained torch liquid droplets having particle size of on the average 0.7 - 0.9 mm in equivalent diameter, wherein the flare angle of the liquid droplets from the vertical deflection axis is set at a value of not more than 30 ^o and directed fragmented liquid inside the shaft at a rate fluid movement in the lower part of the shaft is 8 - 9 m / s.  2. A cooling tower of a power plant for implementing a method for cooling a liquid, comprising a shaft, in the lower part of which there is a device for crushing a liquid stream, the outlet direction of the torch of the crushed liquid being installed at an upward angle, a pool for collecting chilled water, a pump and pipelines, characterized in that the device for crushing the fluid flow is made in the form of centrifugal jet nozzles, and the pump is installed with a pressure of 0.12 - 0.15 MPa in front of the nozzles. 3. The cooling tower of the power plant according to claim 2, characterized in that the nozzles are installed on the periphery of the shaft with a slope of the axis of the nozzle torch to the center of the shaft of no more than 30 ^o .

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