RU57150U1 - UNIVERSAL SPRAYING DEVICE - Google Patents

Abstract

The utility model relates to a power system and can be used in installations for evaporative cooling of recycled water of industrial enterprises. The universal spray device comprises a supply pipe 1 with ribs 2 adjacent to it and a streamlined reflector 3 adjacent to the ribs 3 with thresholds 5. In this spray device, the streamlined reflector is made coaxially and with a clearance of conical plates 4 in the form of truncated cones, the ends of small the bases of which, in addition to the outer conical plate, are rigidly connected to the ribs 2 installed in the inlet pipe 1, and the outer conical plate is adjacent to the inlet pipe and connected to it. At the entrance to the gaps between the conical plates 4, the water stream is divided into separate streams, which, without losing speed, each move along its tapering channel. The streams of water flowing out from the narrowing interreticular channels with high speed hit the thresholds 5 of the conical plates 4, break away from them, breaking up into droplets and forming intersecting volumetric torches. When the flares collide with each other, a thin crushing of the liquid occurs, an increase in the volume of the flare, and the development of a continuously updated interface surface. 2 ill., 3 zp formulas.

Description

The utility model relates to a power system and can be used in installations for evaporative cooling of recycled water of industrial enterprises to ensure uniform distribution of water over the irrigation area both when spraying up and when spraying down.

A spray device is known that contains a supply pipe and ribs with a convex-concave streamlined reflector adjacent to them, made with waterdrops-weirs, alternating in circumference on its concave part, with waterdrops-webs located adjacent to each other and limited by vertical thresholds (see PM Certificate No. 40). , publ. 1998).

The disadvantage of this spray device is its manufacture from a polymeric material, in connection with which the ribs are made quite massive, limiting this to non-irrigated spray torches sectors comprising 15-20 ° from the entire circumference of each rib. In addition, when the cooling tower stops in winter, the ribs made of polymer materials freeze, becoming brittle, and when the cooling tower is next turned on, the spray device is destroyed by water hammer. In addition, this spray device is suitable only for spraying cooled water upwards and is unsuitable for spraying down due to insufficient development of the spray pattern.

The closest claimed technical essence is a universal spray device containing a supply pipe with ribs adjacent to it and a streamlined reflector adjacent to the ribs, made in the form of a cone facing the top of the supply pipe, and thresholds of different sizes are made in a checkerboard pattern along concentric circles on the surface of the streamlined reflector height and with an inclination to the generatrices of the cone of the streamlined reflector at an angle ranging from 90 ° to 180 ° (see RF Patent No. 2237523, IPC ⁷ V 05 V 1/26, publ. 2004).

Common disadvantages of these spray devices are low liquid spray efficiency and design complexity.

Low spraying efficiency is due to the fact that the water flow leaving the inlet pipe quickly loses speed and, when it hits the surface of the streamlined reflector, creates a small spray torch with an underdeveloped interface surface.

The complexity of the design of the analogue consists in the implementation of a streamlined reflector and springboards-weirs of a convex-concave shape, and the prototype - in the execution on the outer side surface of the cone of a streamlined reflector a large number of thresholds of different heights and with different angles of inclination, as well as triangular protrusions.

The objective of the utility model is the development of such a universal spray device, which would improve the efficiency of spraying by creating a volumetric torch and simplify the design.

The problem is solved by the development of a universal spray device containing an inlet pipe with ribs adjacent to it and a streamlined reflector with thresholds adjacent to the ribs, in which the streamlined reflector is made coaxially and with a clearance of conical plates in the form of truncated cones, the ends of which have a small base except for the outer conical plate, are rigidly connected to the ribs installed in the inlet pipe, and the outer conical plate is adjacent to the inlet pipe and oedinena with him.

New is the fact that the angle at the apex of the cone of the previous conical plate, starting from the outer one, is smaller than the angle at the apex of the cone of the subsequent conical plate.

The new fact is that the thresholds are made at the ends of the conical plates, except for the outer one, from the side of the large base of the cone by flanging its edges.

In addition, the thresholds are bent to the horizontal so that the droplet spray torches that they create intersect with each other.

The proposed universal spray device is illustrated by the drawings shown in figures 1-2.

Figure 1 presents a General view of a universal spray device, a longitudinal section; figure 2 is a section aa in figure 1.

Universal spray device includes a supply pipe 1 with adjacent ribs 2 and a streamlined reflector 3. The ribs 2 are made in

in the form of flat plates vertically mounted in the supply pipe 1, connected to each other in a “star”.

The streamlined reflector 3 is assembled from installed in each other coaxially and with a gap of conical plates 4, made in the form of truncated cones. The end face of the small base of the plates 4, in addition to the outer one, is rigidly connected to the ribs 2, and the outer conical plate adjoins the pipe 1 and is connected to it.

At the end of each conical plate 4, except the outer one, from the large base of the cone with a flanging edge, a threshold 5 is made, which is bent to the horizontal so that the droplet spray torches creating thresholds intersect each other.

Universal spray device operates as follows.

The water stream enters from the inlet pipe 1 to the streamlined reflector 3. Since the ribs 2 are located in the pipe 1 and are installed with a narrow face along the flow, they do not affect either the formation of the spray torch or the resistance to water movement.

At the entrance to the gaps between the conical plates 4, the water stream is divided into separate streams, which, without losing speed, move each along its tapering channel. Water streams escaping from narrowing interreticular channels with high speed hit the thresholds 5 of conical plates 4, break away from them, breaking up into droplets and forming intersecting volumetric flares.

When the flares collide with each other, a thin crushing of the liquid occurs, an increase in the volume of the flare, and the development of a continuously updated interface surface.

Streamlined reflector 3, made in the form of installed in each other coaxially and with a gap of conical plates 4, provides multi-spray liquid and an increase in irrigation space.

The placement of the ribs 2 in the inlet pipe 1 and the connection of the outer conical plate 4 of the flowing reflector 3 with the inlet pipe, and the rest of the conical plates with ribs, allow you to divide the stream of water leaving the inlet pipe into separate streams moving each in a separate channel formed between two adjacent conical plates.

The execution of each previous conical plate 4, starting from the outer, with an angle at the top of the cone, less than the angle at the top of the cone of the next

conical plates, provides an increase in the flow rate of water in each channel formed between two adjacent conical plates.

The implementation of the thresholds 5 at the lower ends of the conical plates 4 by flanging their edges provides spray torches with an opening angle of 360 °, which increases the spray space.

The thresholds 5 of the conical plates 4 are inclined to the generatrices of the cones in such a way that the water jets reflected from them intersect each other, providing an increase in the spraying space and finer fragmentation of the droplets when they collide with each other.

The simplification of the design of the universal spray device is achieved by performing a streamlined reflector from conical plates, and thresholds - flanging the edges at the ends of the plates from the side of the large base of the cone.

The proposed universal spray device allows you to create a volumetric spray torch and increase the irrigation space.

Claims (4)

1. A universal spray device containing a supply pipe with ribs adjacent to it and a streamlined reflector with thresholds adjacent to the ribs, characterized in that the streamlined reflector is made of coaxially mounted cone plates in the form of truncated cones, the ends of small bases of which , in addition to the outer conical plate, are rigidly connected to the ribs installed in the inlet pipe and connected to it. 2. The device according to claim 1, characterized in that the angle at the apex of the cone of the previous conical plate, starting from the outer, is smaller than the angle at the apex of the cone of the subsequent conical plate. 3. The device according to claim 1, characterized in that the thresholds are made at the ends of the conical plates, except for the outer one, from the side of the large base of the cone by flanging its edges. 4. The device according to claims 1 and 3, characterized in that the thresholds are bent to the horizontal so that the droplet spraying torches that create them intersect.