RU135398U1 - IRRIGATION CAMERA IRRIGATION SYSTEM - Google Patents

Abstract

1. The irrigation system of the irrigation chamber, consisting of a distribution manifold, risers, sprayers, made in the form of devices for dispersing liquid installed on the risers by means of attachment points with the ability to control the direction of the jets, characterized in that the risers are located in opposite corners of the irrigation chamber parallel to each other other and connected to a distribution manifold, which is placed diagonally on one of the faces of the irrigation chamber, while the sprayers of one riser installed us offset in height relative to another riser nozzles and are directed toward each drugu.2. The irrigation chamber irrigation system, characterized in that the distribution manifold is located diagonally on the upper face of the irrigation chamber, and the risers are arranged vertically. 3. The irrigation system of the irrigation chamber, characterized in that the distribution manifold is located diagonally on the side face of the irrigation chamber, and the risers are horizontal. 4. The irrigation system of the irrigation chamber, characterized in that the distribution manifold is located diagonally on the lower edge of the irrigation chamber, and the risers are located vertically. 5. The irrigation system of the irrigation chamber, characterized in that the attachment points are made in the form of a coupling with an eccentric displacement.

Description

The utility model relates to air conditioning technology and can be used in the irrigation chambers of industrial air conditioners.

A well-known irrigation chamber for industrial air conditioners, for example, technological passports "Equipment for central sectional air conditioners of the type" KD "," KT "or" KTTs3 "- 40; 60; 80; 120 ", consisting of a housing with a pallet, horizontal and vertical pipelines, while vertical distribution pipelines - risers are installed on the horizontal distribution pipelines - collectors. Tangential nozzles are placed on the vertical distributing risers by means of adjusting rubber rings. With a multi-row arrangement of vertical distributing risers, the outlet openings of the nozzles can be oriented according to the movement of the air stream and (or) against the air stream.

The disadvantage of this design of the irrigation chamber is its low efficiency, the fragility of the tangential nozzles and mounting rubber rings at the points of their connection to the vertical collectors, the significant metal consumption and the complexity of the internal structure of the entire irrigation system, which requires quite expensive technical operation. At the same time, the technical operation of the irrigation chamber involves the mandatory mechanical cleaning of recycled and recharge water.

A known irrigation chamber irrigation system (Utility Model Patent RU No. 15929, U1, F23F 3/14, priority 09/08/2000), which consists of inlet distribution manifolds with risers and nozzles that are mounted on risers in one vertical plane perpendicular to the movement of the air flow. Sprayers, which use liquid dispersion devices, are connected to the risers by means of rotary attachment points, which makes it possible to spatially orient the sprayers, that is, to change the directions of the sprayed streams of liquid torches inside the irrigation chamber.

The disadvantage of this design is that with a single-plane vertical orientation of the nozzles installed in the irrigation chamber, the intersection of intersecting atomized liquid torches in the chamber inevitably occurs. The application of intersecting sprayed liquid torches leads to a process of enlargement of dispersible droplets inside the irrigation chamber. This sharply reduces the quality of the irrigation chamber, i.e. the efficiency of the irrigation system described above is reduced.

This technical solution is selected by the authors as a prototype. The technical result achieved by the utility model is to increase the efficiency of the heat and mass transfer process due to the almost complete elimination of the process of enlargement of the droplets of the dispersed jets and uniform and maximum dense filling of the entire internal space of the irrigation chamber with sprayed liquid.

The irrigation chamber irrigation system consists of a distribution manifold, risers, sprays made in the form of liquid dispersion devices mounted on risers by means of attachment points with the ability to control the direction of the jets, risers are located in opposite corners of the irrigation chamber parallel to each other and connected to the distribution manifold, which is placed diagonally on one of the faces of the irrigation chamber, while the sprayers of one riser are installed with a shift in height relative to the sprayers of the other riser and directed towards each other.

Structurally, the irrigation chamber can be performed with the spatial orientation of the entire irrigation system at 90 or 180 degrees with respect to the axis of the flow of the treated air. So, for example, when the distribution manifold is located diagonally on the upper face of the irrigation chamber, and the risers are located vertically, when the distribution manifold is located diagonally on the side face of the irrigation chamber, and the risers are horizontal, when the distribution manifold is located diagonally on the lower face of the irrigation chamber, and the risers are located vertically . The attachment points can be made in the form of a coupling with an eccentric displacement.

Due to the fact that the nebulizers are mounted on risers with a height offset relative to the other distribution riser, direct spray torches of the sprayed liquid “fit” between the direct spray torches of the spray liquid of another riser. In this case, the densest filling of the volume of the irrigation chamber with dispersed liquid occurs. Directional torches of the sprayed liquid do not mix with each other and, therefore, droplets do not coarsen. The diagonal arrangement of the distribution vertical risers increases the possible volume of the dispersible liquid plume in the limited space of the irrigation chamber by increasing its length.

The utility model is illustrated by the drawing, where Fig. 1 shows the construction of an irrigation system of an irrigation chamber with vertical execution of risers.

The irrigation system of the irrigation chamber consists of a distribution manifold 1 extending diagonally at the top of the irrigation chamber, risers 2 connected to the distribution manifold 1 and mounted vertically in opposite corners of the irrigation chamber at the side wall structures, attachment points 3, nozzles 4 mounted on the risers 2 through nodes mounting 3 made with the possibility of installing atomizers 4 and its spatial minor regulation. The attachment points are made with an eccentrically shifted axis.

The irrigation system of the irrigation chamber works as follows, as an example, the design of the irrigation chamber with the location of the distribution manifold horizontally at the top and the vertical arrangement of risers is shown. The liquid, under excess pressure, is supplied to the distribution manifold 1, from where it enters vertically arranged risers 2, on which the attachment points 3 are mounted for the installation of spray guns 4. The risers 2, attachment points 3 and sprayers 4 constructively form two mutually vertical flows of sprayed liquid during operation . Moreover, the nozzles 4 of one riser 2 are located with a height offset with respect to the nozzles of the opposite riser 2. With this spatial orientation of the nozzles, the sprayed liquid flows after the sprayers 4 of one riser 2 with expanding cones fit between the flows of the sprayed liquid after the sprayers 4 of the opposite riser 2, which practically eliminates process of enlargement of drops. Counter flows of sprayed liquid uniformly fill the entire internal volume of the chamber, providing a high density of irrigation. The processed air, passing through the sprayed liquid, acquires the required humidity.

The entire combination of the above features provides the highest possible efficiency of the heat and mass transfer process of the irrigation system during its operation. This design is simple to manufacture and does not require high costs during its construction and operation.

Claims (5)

1. The irrigation system of the irrigation chamber, consisting of a distribution manifold, risers, sprayers, made in the form of devices for dispersing liquid installed on the risers by means of attachment points with the ability to control the direction of the jets, characterized in that the risers are located in opposite corners of the irrigation chamber parallel to each other other and connected to a distribution manifold, which is placed diagonally on one of the faces of the irrigation chamber, while the sprayers of one riser installed us offset in height relative to the other nozzles and riser are directed towards each other. 2. The irrigation system of the irrigation chamber, characterized in that the distribution manifold is located diagonally on the upper face of the irrigation chamber, and the risers are located vertically. 3. The irrigation system of the irrigation chamber, characterized in that the distribution manifold is located diagonally on the side face of the irrigation chamber, and the risers are horizontal. 4. The irrigation system of the irrigation chamber, characterized in that the distribution manifold is located diagonally on the lower edge of the irrigation chamber, and the risers are located vertically. 5. Irrigation system of the irrigation chamber, characterized in that the attachment points are made in the form of a coupling with an eccentric displacement.

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