RU2610630C1 - Fan cooling tower - Google Patents

Abstract

FIELD: power industry.

SUBSTANCE: fan cooling tower includes a housing, a spraying device, a liquid collection tank and a fan, the casing consists of two parts - the upper part, including a sprinkler and a water-drop eliminator between which the manifold of the spraying device with solid-cone spray nozzles is located, and a lower part in which a water collection tank for collecting cooled water with a fan mounted on it is located. The housing is made from sheet stainless steel and the water collection tank has a diffuser which is a part of the housing and is connected with a fan, arranged with a plastic impeller and a multi-speed motor, allowing to change performance of the cooling tower during operation, depending on the weather conditions, by changes in air flow, and the sprinkler includes stacked in layers parallel tubular elements made of thermoplastic material with a lattice wall. The edges of the tubular elements are welded together, the tubular elements are made with a triangular cross-section, and between each layer of tubular elements across the tubular elements along each their end there is strip is laid from thermoplastic material, welded to tubular elements in areas of their contact with the strip. In process of welding end sections of tubular elements are fused, as well as end sections of strips laid between them, and solid end walls of the block are formed in process of fusing. Cavities of each tubular element and tube-to-tube space is filled with hollow polymer balls. Ball diameter÷ is 510% more than the maximum size of the cell of the lattice wall of the tubular elements and the spray nozzle comprises a hollow housing with a nozzle and the central core, the housing is designed with a duct for liquid supply and comprises a coaxial bushing rigidly connected with the housing with the nozzle fixed in the lower part of the bushing, the nozzle is designed as a cylindrical two-section bushing, which top cylindrical section is coupled by a threaded connection with a central cylindrical core having a through inner central hole and mounted with an annular space relative to the inner surface of the cylindrical bushing and the annular space is connected to at least three radial ducts made in the two-secttion busshing, they connect the duct with an annulus, formed by the inner surface of the bushing and the outer surface of the top cylindrical section. The annulus is connected with the duct of the housing for liquid supply, and at the bottom of the central cylindrical core a hollow conical swirler is fixed which conical shell is fixed by means of at least three spokes fixed with one end to the conical shell of the swirler at its upper part and with the other end - in an annular groove formed on the inner cylindrical surface of the central cylindrical core. On the outer surface of the hollow conical swirler a spiral slicing is made.

EFFECT: improved performance of the cooling tower.

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Description

The invention relates to contact coolers, in particular to cooling towers.

The closest technical solution to the claimed object is a cooling tower according to the patent of the Russian Federation No. 2418250, F 28 C 1/02, containing a housing, a spray device, a tank for collecting liquid and a fan (prototype).

The disadvantage of the cooling tower is the relatively low efficiency due to the low degree of spraying liquid with nozzles and uneconomical due to water overruns due to the absence of a plate sprinkler and a droplet eliminator.

The technical result is an increase in the performance of the tower.

This is achieved by the fact that in a fan cooling tower containing a housing, a spray device, a liquid collection tank and a fan, the housing consists of two parts - the upper part, including an irrigator and a droplet separator, between which there is a collector of the spray device with solid nozzles, and the lower part, in which there is a catchment tank for collecting cooled water with a fan installed on it, the casing is made of stainless steel sheet, and there is a diffuser in the catchment tank, which представляет represents a part of the casing and is connected to a fan made with a plastic impeller and a multi-speed electric motor, which allows, depending on weather conditions, to change the cooling tower performance due to changes in air flow, and the sprinkler contains tubular elements made of layers parallel to each other from thermoplastic material with a lattice wall, and at the ends of the tubular elements are welded together, the tubular elements are made with a triangular cross section and between a strip of thermoplastic material is welded to each layer of tubular elements across the tubular elements along each end thereof, welded to the tubular elements at the points of contact with the strip, and during the welding process the butt ends of the tubular elements and the stripes laid between them are melted and form monolithic end faces during the fusion process the walls of the block, and the cavities of each of the tubular elements and the annulus are filled with hollow polymer balls, and the diameter of the balls is 5 ÷ 10% more than the maximum the cell size of the lattice wall of tubular elements, and the nozzle contains a hollow body with a nozzle and a central core, the body is made with a channel for supplying fluid and contains a sleeve coaxially rigidly connected to the body with a nozzle fixed in its lower part, made in the form of a cylindrical two-stage sleeve, the upper cylindrical the step of which is connected by means of a threaded connection to a central cylindrical core having a through inner central hole and installed with an annular gap o relative to the inner surface of the cylindrical sleeve, and the annular gap is connected to at least three radial channels made in a two-stage sleeve, connecting it to the annular cavity formed by the inner surface of the sleeve and the outer surface of the upper cylindrical stage, and the annular cavity is connected with the channel of the housing for supplying fluid and in the lower part of the central cylindrical core a hollow conical swirl is fixed, the conical shell of which is fixed by at least three knitting needles, fixed at one end on the conical side of the swirl, in its upper part, and the other end in the annular groove made on the inner surface of the central cylindrical core, while on the outer surface of the hollow conical swirl made screw thread.

In FIG. 1 shows a diagram of a film fan cooling tower; FIG. 2 is a side view of a fan tower, FIG. 3 - sprinkler unit, in FIG. 4 is a nozzle diagram.

The film-type fan cooling tower (Figs. 1 and 2) is an open type evaporative cooling tower and, with very moderate energy consumption, provides the preparation of water used for cooling with a temperature of 5 ° C below the outdoor temperature using a dry thermometer. The cooling tower consists of two parts: the upper part, consisting of a casing 2, in the lower part of which there is an irrigator 6, in the upper part, a droplet separator 7, and between them there are collectors 8 of the spray device with nozzles. In the lower part of the tower, on the base 1, there is a catchment tank 4 for collecting cooled water with a fan 3 installed on it.

The casing is made of stainless steel sheet, which ensures reliable long-term operation of the cooling tower, low weight and, as a result, the possibility of installing the cooling tower on the roofs of industrial buildings. The design of the tank 4 provides a diffuser, which is a part of the housing and is connected to the fan, as well as a drain pipe 5.

The collector 8 of the spray device is located in the upper part of the housing 2 and is a system of pipes connected in parallel with holes on which nozzles are staggered.

Sprinkler 6 and droplet separator 7 are made of PVC plastic (polyvinyl chloride) with an additive that provides high-strength chemically resistant plastic that does not support combustion and maintains its operational properties at an outdoor temperature of -60 ° C to + 55 ° C.

Sprinkler 6 (Fig. 3) used in the cooling tower is composed of tubular elements 9 of thermoplastic material with a lattice wall folded in layers parallel to each other. At the ends 10, the tubular elements 9 are welded together, made with a triangular cross-section, and between each layer of the tubular elements 9 across the tubular elements 9, a strip 11 of thermoplastic material is laid along each of their ends 10, welded with the tubular elements 9 in places of their contact with the strip 11 moreover, during the welding process, the end sections of the tubular elements 9 and the strips 11 laid between them are melted and monolithic end walls of the block are formed during the reflow process. The cavities of each of the tubular elements 9 and the annular space are filled with hollow polymer balls 12, and the diameter of the balls is 5 ÷ 10% larger than the maximum cell size of the lattice wall of the tubular elements 9.

In addition, in the nozzle block in cross section, all tubular elements 9 can have the same cross section and can be made in the form of an equilateral or isosceles triangle. The tubular elements 9 in the layers can be stacked so that in the cross section the tubular elements 9 are located one below the other or the tubular elements 9 in the layers can be stacked so that in the cross section in the adjacent layers the tubular elements 9 of the same layer are located between the tubular elements 9 adjacent layer.

When using the nozzle block as a sprinkler, the water to be cooled in the tower is sprayed onto the sprinkler, and then it flows down the surface of the tubular elements 9 and is cooled by an oncoming air flow, while during operation, the rigid structure of the blocks allows you to maintain the original configuration of the assembled block, which allows to increase the efficiency of heat and mass transfer in the cooling tower.

When using the nozzle block as a water trap, drops of water that are carried away with the air stream, when passing, several layers of tubular elements 9 settle on the surface of the latter, collect in large drops and flow back to the cooling tower pool. This prevents the loss of water with a drip.

The nozzle (Fig. 4) has a cylindrical hollow body 13 with a channel 15 for supplying fluid and contains a sleeve 14 coaxially and rigidly connected to the body with a nozzle fixed in its lower part, made in the form of a cylindrical two-stage sleeve 16, the upper cylindrical step 18 of which is connected by a threaded connection with a central cylindrical core 19 having a through inner central hole 22, and installed with an annular gap 21 relative to the inner surface of the cylindrical sleeve 16. The annular gap OP 21 is connected with at least three radial channels 17, made in a two-stage sleeve 16, connecting it with an annular cavity 20 formed by the inner surface of the sleeve 14 and the outer surface of the upper cylindrical stage 18, and the annular cavity 20 is connected with the channel 15 of the housing 13 for supply liquids.

In the lower part of the central cylindrical core 19, a hollow conical swirler 23 is fixed, the conical shell of which is fixed by at least three knitting needles 24, fixed at one end to the swirl conical shell, in its upper part, and to the other end in an annular groove (not shown in the drawing ) made on the inner surface of the central cylindrical core 19. On the outer surface of the hollow conical swirler 23 a screw thread is made.

The nozzle is as follows.

Liquid under pressure is supplied to the cavity 15 of the nozzle body 13 and then flows in two directions: the first - into the annular cavity 20 through radial channels 17 into the annular gap 21 between the nozzle and the central core 19.

The second direction in which the liquid enters is through the channel 15 for supplying liquid to the cavity of the central hole 22 of the central core 19, and then to the lower part of the central cylindrical core 19, and through the conical swirler 23, comes out and meets the flow of the first direction, forming fine fluid flow.

The use of a finely dispersed sprayer of the described design allows one to obtain a uniform volume flow of finely dispersed droplets in the range of droplet diameters from 30 to 150 microns with a water supply pressure of not more than 1 MPa.

The cooling tower operates as follows.

The cooling effect in the tower is achieved by evaporation - 1% of the water circulating through the tower, which is sprayed by nozzles and flows into the tank 4 in the form of a film through a complex system of irrigation channels 6 towards the flow of cooling air pumped by fan 3.

Effective droplet separator 7 can reduce water loss as a result of drip entrainment. The amount of droplet moisture carried away by the air flow depends on the density of irrigation and at a maximum value of 25 m ³ / (hour × m ² ) does not exceed 0.1% of the volumetric flow rate of the cooled water through the cooling tower.

Claims (1)

A fan tower comprising a housing, a spray device, a fluid collection tank and a fan, the housing consists of two parts - an upper part including an irrigator and a droplet separator, between which a manifold of the spray device with nozzles is located, and a lower part in which a water collector tank is located for collection of cooled water with a fan installed on it, and the casing is made of stainless steel sheet, and in the water tank there is a diffuser, which is a part of the casing and with a fan made with a plastic impeller and a multi-speed electric motor, which allows, depending on weather conditions, to change the performance of the tower due to changes in air flow, and the sprinkler contains tubular elements made of layers parallel to each other made of thermoplastic material with a lattice wall, moreover, the ends of the tubular elements are welded together, the tubular elements are made with a triangular cross section and between each layer of tubular elements across a strip of thermoplastic material is welded with tubular elements along each of their ends, welded with tubular elements in places of their contact with the strip, moreover, during welding, the end sections of the tubular elements and the strips laid between them are melted and monolithic end walls of the block are formed during the fusion process, and the cavities of each of tubular elements and the annulus is filled with hollow polymer balls, and the diameter of the balls is 5 ÷ 10% larger than the maximum cell size of the lattice wall of the tubular elements, characterized in that the nozzle contains a hollow body with a nozzle and a central core, the body is made with a channel for supplying liquid and contains a sleeve coaxially rigidly connected to the body of the sleeve with a nozzle fixed in its lower part, made in the form of a cylindrical two-stage sleeve, the upper cylindrical step of which connected by means of a threaded connection to a central cylindrical core having a through inner central hole and mounted with an annular gap relative to the inner the surface of the cylindrical sleeve, and the annular gap is connected to at least three radial channels made in a two-stage sleeve, connecting it to the annular cavity formed by the inner surface of the sleeve and the outer surface of the upper cylindrical stage, and the annular cavity is connected with the channel of the housing for supplying fluid, and a hollow conical swirl is fixed in the lower part of the central cylindrical core, the conical shell of which is fixed by means of at least three spokes, fastening one end to a conical shell swirler at its upper part, and the other end - in an annular groove formed on the inner cylindrical surface of the central core, wherein the outer surface of the hollow conical swirler formed helical cutting.

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