RU2554140C2 - Water sprinkling nozzle of cooling tower - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: water sprinkling nozzle of the cooling tower contains input section converging along the water flow, manhole and output section expanding along the flow direction, at that on the outside surface of the output section the water turbulising elements are made, the input section is made with cylindrical nozzle, wall thickness of the input section gradually reduces in direction from the nozzle to manhole, and water turbulising elements are made in form of flat rectangular shoulders located parallel to nozzle axis by rows along the concentric circles, at that shoulders of the second row (from nozzle axis) are installed in staggered order in relation to the shoulders of other rows, shoulders of the last row along the water flow are made double, shoulders of the next to the last row are made with V cut-out at middle, width of shoulders gradually increases, and height gradually decreases from row to row in direction from the nozzle axis , and at edge of the output section a row of shoulders is made, the shoulders are inclined at blunt angle to the tangential generatrix surface of the output section passing through the interfacing point of the shoulder and edge of the output section.

EFFECT: increased dispersion degree and uniform water spraying at output of the water spraying nozzle.

5 dwg

Description

The invention relates to a power system and other industries that use recycled water supply at their enterprises, and is intended for spraying cooled water in fan and tower cooling towers.

Known water spray nozzle containing reflectors in the form of a continuous cone with teeth along the periphery (see copyright certificate SU No. 313567, publ. 1971).

Here the teeth split the stream of water into separate streams. However, the water flow generated by the nozzle provides only annular irrigation and does not irrigate the cooling tower area near the nozzle.

The closest to the invention in technical essence and the achieved result is a water-spraying nozzle of the cooling tower, containing an inlet section, tapering in the direction of the water flow, a neck and an outlet section, expanding in the direction of the water stream, and elements on the outer surface of the outlet section (see GB patent No. 2135215, publ. 30.08.1984).

However, this nozzle does not provide the required degree of dispersion of the water flow from the nozzle.

The objective of the invention is to remedy the above disadvantages.

The technical result consists in the fact that an increase in the degree of dispersion and uniformity of water dispersion at the outlet of the water-spraying nozzle is achieved.

This problem is solved, and the technical result is achieved due to the fact that the water-spraying nozzle of the cooling tower contains an inlet section, tapering in the direction of the water flow, a neck and an outlet section, expanding in the direction of the water stream, and on the outer surface of the outlet section there are made elements that inlet water the section is made with a cylindrical nozzle, the wall thickness of the inlet section gradually decreases in the direction from the nozzle to the neck, and the elements that turbulent the water flow are made in the form of flat rim-shaped protrusions arranged parallel to the nozzle axis in rows in concentric circles, and the protrusions of the second row from the nozzle axis are staggered with respect to the protrusions of the other rows, the protrusions of the last row along the water flow are doubled, the protrusions of the penultimate row along the water flow are made with V -shaped in the middle, the width of the protrusions monotonously increases, and the height of the protrusions monotonously decreases from row to row in the direction from the axis of the nozzle, and a series of protrusions are made along the edge of the outlet section, inclined at an obtuse angle to the tangent generatrix of the surface of the output section passing through the mating point of the protrusion and the edge of the output section.

Figure 1 presents a top view of the water spray nozzle.

Figure 2 presents a section bB in figure 1.

Figure 3 presents a view A of figure 2.

Figure 4 presents a section bb in figure 2.

Figure 5 presents a section GG of figure 2.

The water-spraying nozzle of the tower contains an inlet section 1, tapering in the direction of the water flow, a neck 2 and an outlet section 3, expanding in the direction of the water stream.

Elements 4 are made on the outer surface of the outlet section 3, which turbulent the water flow. The inlet section 1 is made with a cylindrical nozzle 5, and the wall thickness of the inlet section 1 gradually decreases in the direction from the nozzle 5 to the neck 2.

On the outside of the nozzle 5, two flats 6 are made, necessary for installing the nozzle with a wrench, and the elements 4 that turbulent the water flow are made in the form of flat rectangular protrusions arranged parallel to the nozzle axis 7 in rows along concentric circles, and the protrusions of the second row from the nozzle axis 7 installed in a checkerboard pattern with respect to the protrusions of other rows. The protrusions of the last row along the water flow are doubled (see FIG. 5), and the protrusions of the penultimate row (see FIG. 4) along the water flow are made with a V-shaped cut in the middle. The width of the protrusions monotonically increases, and the height of the protrusions monotonically decreases from row to row in the direction from the axis 7 of the nozzle.

Along the edge of the output section 3, a series of protrusions 8 are made, obliquely oblique to the tangent generatrix of the surface of the output section 3 passing through the mating point of the protrusion 8 and the edge of the output section 3.

During operation, water from a pipeline (not shown) of the reverse water supply system through a nozzle 5 enters the inlet section 1, where the water flow rate increases and reaches a maximum speed in the neck 2. Part of the water flow at the periphery of the stream runs onto elements that turbulent the water flow 4 and due to this, it is intensively turbulized, successively increasing the degree of turbulence from row to row as the elements 4 flow around the turbulent water flow, moreover, because the protrusions of the latter at the water flow, the rows are doubled (see Fig. 5), and the protrusions of the penultimate row (see Fig. 4) along the water flow are made with a V-shaped cut in the middle, a sharp and uneven change in the passage sections is achieved in the height of the V-shaped cuts , which causes the formation of both horizontal and vertical vortices in the water stream, which as a result allows you to get a fine stream of water at the outlet of the nozzle, which then enters the sprinklers of the cooling tower. A further increase in turbulence is achieved due to the fact that the width of the protrusions monotonically increases, and the height of the protrusions monotonically decreases from row to row in the direction from the nozzle axis 7, which allows vertical vortices to form in the flow due to the flow around the upper edges of the protrusions, which further increases the degree of turbulence water flow.

At the same time, the central part of the water flow, flowing out of the nozzle vertically upward, is scattered as a result of interaction with the air surrounding the nozzle and forms a fine water stream in the zone surrounding the nozzle exit section 3. Due to the fact that the wall thickness of the inlet section 1 gradually decreases in the direction from the nozzle 5 to the neck 2, it is possible to use the pressure drops that occur during the flow around the protrusions of the water to form oscillations of the thinner walls of the nozzle, which in turn makes it possible to increase the turbulence of the water flow along the walls and reduce the thickness of the boundary layer of water with a corresponding increase in the dispersion of the water flow at the exit of the nozzle. Thus, it seems possible to achieve a more uniform distribution and finely dispersed water spraying on the tower sprinkler, which increases its cooling ability by up to 20%.

This invention can be used in all industries where recycled water supply is used with fan and tower cooling towers.

Claims (1)

A water-spraying nozzle of a cooling tower containing an inlet section, tapering in the direction of the water stream, a neck and an outlet section expanding in the direction of the water stream, wherein elements on the outer surface of the outlet section are turbulizing the water stream, characterized in that the inlet section is made with a cylindrical nozzle, wall thickness the inlet section gradually decreases in the direction from the nozzle to the neck, and the elements that turbulent the water flow are made in the form of flat rectangular protrusions parallel to the axis of the nozzle in rows along concentric circles, and the protrusions of the second row from the nozzle axis are staggered with respect to the protrusions of other rows, the protrusions of the last row along the water flow are doubled, the protrusions of the penultimate row along the water flow are made with a V-shaped cut in the middle, width the protrusions monotonically increases, and the height of the protrusions monotonically decreases from row to row in the direction from the axis of the nozzle, and along the edge of the outlet section, a series of protrusions are made, obliquely oblique to the tangent generatrix ited output portion passing through the coupling point of the projection portion and the output edge

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