RU202417U1 - Cooling Tower Sprinkler Block - Google Patents

Abstract

The utility model relates to the field of circulating water supply, namely to the structural elements of cooling towers and other apparatus for heat exchange between liquid and gaseous media. The cooling tower sprinkler block contains cylindrical pipes with a mesh wall made of thermoplastic plastic and installed at an angle to the horizontal plane with the formation of parallel rows of pipes rigidly fastened at their contact points; threads with a thickness of 1.0 - 2.0 mm with the formation of diamond-shaped holes, while the longer diagonal of the rhombuses is parallel to the generatrix of the cylindrical surface of the pipe, the maximum length of the holes along the longer diagonal of the rhombus is 1.3 - 1.5 of the maximum width of this hole along shorter diagonal of the hole, and the acute angle between the sides of the holes is 30-40 °. As a result, an increase in the intensity of heat transfer is achieved by reducing hydraulic losses during the cross flow of the liquid and gaseous phases. 4 ill.

Description

The utility model relates to the field of circulating water supply, namely to the structural elements of cooling towers and other apparatus for heat exchange between liquid and gaseous media.

In evaporative cooling towers, block sprinklers of drip and film type are widely used, made of wooden slats, as well as of flat or wavy asbestos-cement sheet shields up to 7 mm thick (see, for example, the book Farforovskiy BC, Farforovskiy V.B. Circulating water coolers of thermal power plants L .: Energy, 1972).

Sprinklers of this type are distinguished by high material consumption, high hydraulic resistance to the flow of cooling air, low specific surface of contact between phases and low operational reliability due to the limited water resistance of wooden sprinklers and delamination of asbestos-cement sprinklers during defrosting. In addition, the use of asbestos is impractical from the point of view of its harmful effect on the environment.

Known cooling tower sprinkler in the form of a module of layers of polymeric cellular cylindrical pipes placed in layers parallel to each other and welded at the ends of the module with each other at the points of contact (see patent RU No. 2141617, class F28F 25/08, publ. 20.1119.99).

However, the horizontal arrangement of the cellular pipes in layers leads to a relatively high hydraulic resistance, which reduces the efficiency of heat transfer between the cooled water and the cooling air.

The closest to the utility model in technical essence and the achieved result is a cooling tower sprinkler block containing cylindrical pipes with a mesh wall made of thermoplastic plastic and installed at an angle to the horizontal plane with the formation of parallel rows of pipes rigidly fastened at their contact points (see utility model patent RU No. 12234, class F28F 25/08, publ. 16.12.1999).

This design of the cooling tower sprinkler block allows achieving the required degree of cooling of the circulating water due to the intensification of the heat exchange process between water and air, ensuring a more uniform distribution of water flows over the sprinkler block cross section in the passages for the cooled liquid and cooling gaseous media formed by pipes with a mesh wall.

However, in addition to the presence of a net structure, the shape of the cells forming the net structure and their size are essential. The lack of such information leads either to an increase in hydraulic resistance, or to a decrease in the intensity of heat exchange between the cooled liquid and the cooling gaseous media. As a result, it is not possible to fully exploit the possibilities of pipes with a mesh-like structure of walls.

The technical problem solved in the utility model is the elimination of the above disadvantages by optimizing the cross flow of liquid and gaseous media in the cooling tower sprinkler.

The technical result achieved from the use of the utility model is to increase the intensity of heat exchange by reducing hydraulic losses in the cross flow of liquid and gaseous media.

The specified technical problem is solved, and the technical result is achieved due to the fact that the block of the cooling tower sprinkler contains cylindrical pipes with a mesh wall, made of thermoplastic plastic and installed at an angle to the horizontal plane with the formation of parallel rows of pipes, rigidly fastened at the points of their contact with each other, in this case, the mesh wall of the cylindrical pipes is formed by crossing thermoplastic threads with a thickness of 1.0 - 2.0 mm, fastened at the intersection with each other, with the formation of diamond-shaped holes, the longer diagonal of the rhombuses of which is parallel to the generatrix of the cylindrical surface of the pipe, while the maximum length of holes along the longer the diagonal of the rhombus is 1.3 - 1.5 of the maximum width of this hole along the shorter diagonal of the hole, and the acute angle between the sides of the holes is 30 - 40 °.

Cylindrical pipes can be installed perpendicularly, i.e. at an angle of 90 ° to the horizontal surface or can be installed with an inclination (i.e. at an angle other than 90 °) to the horizontal plane to form an obtuse angle by the axis of cylindrical pipes with a horizontal plane.

Cylindrical pipes are preferably made with a length of 300-800 mm and a diameter of 70 mm with a circular or oval cross-section or with a cross-section formed by two parallel flat mesh walls interconnected by means of outwardly convex curved mesh walls.

During the study of the operation of sprinklers assembled from pipes, it was revealed that it is possible to create a relatively simple design of sprinkler blocks by making sprinkler blocks from cylindrical pipes with a mesh wall made of thermoplastic plastic, installed with the formation of vertical or installed with an inclination to the horizontal plane parallel rows, and the cylindrical pipes are rigidly fastened at the points of contact, for example, at the ends. Implementation of the sprinkler block in the above manner in combination with the fact that the mesh wall of the cylindrical pipes is formed by crossing thermoplastic filaments with a thickness of 1.0 - 2.0 mm, fastened at the intersection with each other, with the formation of diamond-shaped holes, the longer diagonal of the rhombuses of which is parallel to the generatrix of the cylindrical surface of the pipe with a maximum length of holes along the longer diagonal of the rhombus, which is 1.3 - 1.5 of the maximum width of this hole along the shorter diagonal of the hole and an acute angle between the sides of the holes, amounting to 30 - 40 °, allows you to create passages between cylindrical pipes with a mesh wall and through the cylindrical tubes with a mesh wall to distribute the cooling air more evenly between the cylindrical tubes.

The execution of a cylindrical pipe from threads less than 1 mm thick does not provide the required rigidity, and more than 2 mm unnecessarily makes the weight of the cylindrical pipe heavier. Making the long diagonal of the hole in the form of a rhombus on the reamer less than 1.3 in relation to the width of the hole in combination with the above angle of less than 30 ° leads to a significant increase in hydraulic resistance to the transverse flow of cooling air, and exceeding the above ratios of the length of the long diagonal and the value of the acute angle leads to a decrease in the rigidity of the structure of a cylindrical pipe and an excessive decrease in the surface of the pipe wall, which reduces the intensity of heat exchange between gaseous and liquid media.

Thus, the above-described mesh structure of the walls of the cylindrical pipes with the above-mentioned dimensions of the diamond-shaped holes provides practically free access of the cooling air to the water droplets that have entered the channels formed by the cylindrical pipes, which, in combination with the installation of the cylindrical pipes vertically or at the above inclination at an obtuse angle to the horizontal surface made it possible to achieve an optimal ratio between the hydraulic resistance to the flows of the cooled liquid and cooling gaseous media, which ultimately made it possible to ensure high efficiency of heat exchange with a relatively low hydraulic resistance while achieving the required structural strength of the sprinkler unit.

Cylindrical pipes can be made with a circular or oval cross-section, or cylindrical pipes can be made with a cross-section formed by two parallel flat mesh walls, coupled to each other by means of curved mesh walls convex outward, which makes it possible to adjust the size of horizontal air passages through the rows of cylindrical pipes and thus to select the sprinkler blocks depending on the design features of a particular cooling tower and thereby achieve an optimal heat exchange mode between liquid and gaseous media and at the same time allows to regulate the rigidity of the cooling tower sprinkler block structure within wide limits.

FIG. 1 shows a photo of the assembled cooling tower sprinkler unit with cylindrical pipes installed perpendicular to the horizontal plane.

FIG. 2 schematically shows a block of a cooling tower sprinkler with cylindrical pipes installed with an inclination at an obtuse angle to the horizontal plane.

FIG. 3 shows one of the cylindrical pipes with a mesh wall, from which the block of the cooling tower sprinkler is assembled.

FIG. 4 shows a fragment of the unfolded wall of a cylindrical pipe with a diamond-shaped hole

The cooling tower sprinkler block contains cylindrical pipes 1 with a mesh wall made of thermoplastic plastic and installed at an angle to the horizontal plane to form parallel rows of pipes 1 rigidly fastened at their contact points.

The mesh wall of the cylindrical pipes 1 is formed by crossing thermoplastic threads 2 with a thickness of 1.0 - 2.0 mm, fastened at the intersection with each other, with the formation of 3 diamond-shaped holes 3 on the cylindrical surface of the wall of each pipe.

The longer diagonal of the rhombuses (when representing the mesh wall of the cylindrical pipe 1 in the form of a sweep), in the form of which the holes 3 are made, are parallel to the generatrix of the cylindrical surface of the pipe 1, while the maximum length of the holes 3 along the longer diagonal of the rhombus is 1.3 - 1.5 from the maximum width of this hole 3 along the shorter diagonal of the hole 3, and the acute angle between the sides of the holes 3 is 30 - 40 °.

Cylindrical pipes 1 can be installed perpendicularly, i.e. at an angle of 90 ° to the horizontal surface or can be installed with an inclination (i.e. at an angle other than 90 °) to the horizontal plane with the formation of an obtuse angle by the axis of cylindrical pipes 1 with a horizontal plane.

Cylindrical pipes 1, preferably, are made with a length of 300-800 mm and a diameter of 70 mm with a circular or oval cross-section or with a cross-section formed by two parallel flat mesh walls, interconnected by means of outwardly convex curved mesh walls.

During operation of the cooling tower, cooling air enters the inside of the cooling tower through openings in the side walls of the cooling tower due to natural draft in tower cooling towers and forced movement in fan cooling towers, and then the cooling air enters the sprinkler unit through the mesh walls of cylindrical pipes 1 and through channels formed by cylindrical pipes 1.

The cooled water from the top of the sprinkler is evenly sprayed over the area formed by the blocks of sprinklers of the cooling tower from cylindrical pipes 1.

In the sprinkler, heat exchange between water droplets moving in a cross direction and the air flow occurs in the channels formed by cylindrical pipes 1 and holes 3 in the mesh walls of cylindrical pipes 1. In this case, the flow of cooling air in the process of heat exchange with water droplets throws them onto the mesh surface of cylindrical pipes 1 , and water droplets thrown onto the developed surface of the mesh walls of the cylindrical pipes 1 form on the mesh surface of the cylindrical pipes 1, flowing down and simultaneously intensely cooling water films.

This useful model makes it possible to solve the problem of creating a cooling tower sprinkler block with efficient heat exchange with low hydraulic resistance, which allows it to be used in devices for cooling water in water circulation systems of industrial enterprises with direct contact of the cooled water and its cooling air.

Claims (6)

1. A cooling tower sprinkler block containing cylindrical pipes with a mesh wall, made of thermoplastic plastic and installed at an angle to the horizontal plane with the formation of parallel rows of pipes, rigidly fastened at their points of contact with each other, characterized in that the mesh wall of the cylindrical pipes is formed by crossing, bonded at the intersection of thermoplastic threads with a thickness of 1.0 - 2.0 mm with the formation of diamond-shaped holes, while the longer diagonal of the rhombuses is parallel to the generatrix of the cylindrical surface of the pipe, and the maximum length of the holes along the longer diagonal of the rhombus is 1.3 - 1 , 5 of the maximum width of this hole along the shorter diagonal of the hole, and the acute angle between the sides of the holes is 30 - 40 °. 2. The sprinkler unit according to claim 1, characterized in that the cylindrical pipes are installed perpendicular to the horizontal plane. 3. The sprinkler unit according to claim 1, characterized in that the cylindrical pipes are installed with an inclination to the horizontal plane with the formation of an obtuse angle by the axis of the cylindrical pipes with the horizontal plane. 4. The sprinkler block according to claim 1, characterized in that the cylindrical pipes are made with a length of 300-800 mm and a diameter of 70 mm. 5. The sprinkler unit according to claim 1, characterized in that the cylindrical pipes are made with a round or oval cross-section. 6. The sprinkler unit according to claim. 1, characterized in that the cylindrical pipes are made with a cross section formed by two parallel flat mesh walls, coupled to each other by means of outward convex curved mesh walls.

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