RU2187760C2 - Sprinkling system of sprinkling chamber - Google Patents

Abstract

FIELD: air conditioning equipment, sprinkling chambers of air conditioners. SUBSTANCE: sprinkling system of sprinkling chamber includes distribution horizontal collectors, vertical double uprights carrying atomizers coming in the form of dual nozzle branch pipes with outlets of equal diameter directed in opposition mounted in horizontal planes. Distribution horizontal collectors are fitted with vertical joints to change their angle of setting from 30 to 65 deg with reference to direction of flow of air. Vertical double uprights are linked to distribution collectors with the aid of vertical axial joints. Nozzle branch pipe are placed in pairs on uprights at various horizons. Each pair of nozzle branch pipes of one horizon is displaced relative to pair of nozzle branch pipes of next horizon. Axial joints of double uprights make it possible to orient axis of nozzle branch pipes up to 20 deg with regard to axis of flow of treated air to side excluding imposition of projections of spray cones formed by pairs of nozzle branch pipes. EFFECT: raised quality of treated air due to increased quality of atomization, diminished dimensions of air conditioner. 3 dwg

Description

 The invention relates to techniques for air conditioning and can be used in the irrigation chambers of air conditioners.

 Known chamber irrigation [1], used in central air conditioners, consisting of a housing with a tray, packages of plates of air diffusers and droplet eliminators and an irrigation system.

 The irrigation system consists of four collectors located on two horizons, and two rows of vertical risers with centrifugal nozzles. Water inlets are made in the upper and middle parts of the chamber. During operation of the irrigation chamber, air passing through the irrigated space is treated with a dispersed volume of water according to a two-row scheme.

 The disadvantages of this design are the fragility of the nozzles, rubber sealing rings and rubber couplings for the nozzles, its significant metal consumption, a complex and costly operating system, and the inability to control the air treatment process.

The known irrigation chamber [2], where instead of four collectors are installed two horizontal distribution manifolds at an angle of 30-40 ^o to the direction of the flow axis of the processed air, and on the vertical twin risers are sprayers made in the form of nozzle nozzles with exit holes of equal diameter. The design of the nozzle nozzles allows you to adjust the axial clearance between the planes of their outlet openings. Translation of the work of the irrigation chamber to different spray quality: coarse dispersion, medium dispersion, fine dispersion is carried out by adjusting the axial clearance between the planes of the nozzle outlet openings, i.e. nozzle nozzles and the amount of excess pressure created by the network pump. Since the diameters of the irrigation flames created by the pairs of nozzle nozzles are comparable or close to the width of the irrigation chamber, and the number of vertical twin risers can be more than three on each horizon, this design allows you to create a multi-row scheme of air treatment with dispersed circulating water. This design of the irrigation chamber is selected by the authors as a prototype.

 The disadvantage of this irrigation chamber is that to accommodate the above-described design, the volume of the chamber of a standard air conditioner of the type “KT” or “KTTs” is required, the impossibility of creating additional adjustment of the spray density when transferring the system from one spray quality to another, for example, from fine to medium or coarse. Similar situations arise when it is necessary to adjust the operation of the irrigation system to a closely suitable characteristic of an existing pump, for example, when replacing it.

 The technical problem solved by this invention is to improve the quality of the processed air by increasing the density of the spray, reducing the linear dimensions of the irrigation chamber and, as a result, reducing the size of the air conditioner.

The invention consists in the following. The irrigation chamber irrigation system, consisting of horizontal distribution manifolds, vertical twin risers with nozzles mounted on these risers in horizontal planes, made in the form of paired nozzle nozzles with exit holes of equal diameter directed towards each other, while the nozzles have the ability to control the axial clearance between the planes of the outlet openings of the nozzle nozzles, while the horizontal distribution manifolds are provided with a vertical nymi hinges with the ability to change the angle of installation of 30 to 65 ^o with respect to the direction of air flow, vertical double risers are connected to distribution by horizontal collectors through vertical axial hinges on risers at different horizons pairwise arranged nozzle pipes, each steam nozzle pipes one horizon installed with an offset relative to the pair of nozzle nozzles of the subsequent horizon, while the axial hinges of the double risers allow you to orient the axis of the nozzle ovyh nozzles 20 ^o with respect to the process air flow in the direction of the axis, excluding the spray overlay projections formed double nozzle pipes.

 Improving the quality of air treatment with recycled water by increasing the density of the spray occurs when the row of dispersed flares is densified, since at the moment of convergence of their planes the space between the flares is densely filled with small drops and water fog. At the same time, the density of the space irrigated by the system increases and the work flow of the treated air to overcome the created irrigated space increases, while the quality of the heat and mass transfer process is enhanced, increasing the coefficient of the polytropic process and bringing it as close as possible to the ideal adiabatic one. The irrigation chamber works stably in all spray modes. This is a particularly vivid example in the medium dispersion mode, where the planes of dispersed water flares and the zones between them are clearly distinguishable, densely filled with small drops and water fog.

The irrigation system of the irrigation chamber consists of horizontal distribution manifolds and vertical risers, while horizontal distribution manifolds, depending on the spray quality and the number of twin risers on the horizon, can be installed at an angle of 30-65 ^o to the axis of movement of the processed air by vertical axial joints, vertical risers are double and on them coaxially in horizontal planes there are nozzles made in the form of paired nozzle nozzles with outlet openings p vnogo diameter directed towards each other with the possibility of adjusting the axial clearance between the planes of the outlets. The presence of planes at the ends of the nozzle nozzles ensures the construction of stable flat torches that are opened normal to the axis of the twin nozzle nozzles upon impact of water jets flowing from calibrated outlet openings of equal diameter towards each other.

Vertical twin risers are connected to the horizontal distribution manifold by axial joints, which allow you to change the angles of the axes of the nozzle nozzles in the range of 0-20 ^o relative to the axis of the flow of the treated air, while there are changes in the spatial orientation of the planes of the dispersed flares, which are extreme at 65 ^{o the} provisions of the horizontal distribution manifolds have sharp angles of vertical inclination to the axis of the flow of the processed air, equal to 70 ^o . Such a change in the spatial orientation of flat water torches does not have any negative changes in the quality of the system, while their joint overlap is excluded.

 Paired nozzle nozzles are installed with the offset of each pair relative to the next pair and with respect to the central axis of each vertical twin riser, which eliminates the imposition of dispersed torches with end zones in the vertical plane of one row formed by nozzle nozzles of each of the vertical twin risers of the whole structure, which is essential improves the quality of the system and increases the density of irrigation.

 The invention is illustrated by drawings, where Fig. 1 shows a fragment of a multi-row irrigation system in an irrigation chamber with installation sites of vertical axial joints on horizontal distribution manifolds and vertical twin risers.

 Figure 2 shows a top view of the irrigation chamber and the largest installation angles of the distribution horizontal collectors and vertical twin risers are indicated, the projection angle of the flat torch to the axis of the processed air flow is also indicated.

 Figure 3 shows a schematic drawing of a vertical twin riser, made according to the arrangement of nozzles in four planar horizons.

 Each tier of a multi-row irrigation system consists of a horizontal distribution manifold 1, vertical twin risers 2, on which sprayers 4 are installed in pairs in four (as an option) planar horizons in the form of nozzle nozzles with outlet openings of equal diameter and directed towards each other. In this case, the nozzles 4 have the ability to control (decrease or increase) the magnitude of the axial clearance between the planes of the outlet openings.

Horizontal distribution manifolds 1 at their beginning along the movement of water in the volume of the irrigation chamber and vertical twin risers 2 at the points of their connection to the distribution manifolds 1 of each tier of the irrigation system have vertical axial joints that allow changing the installation angles of these elements, for example:
-the angles of the installation of horizontal distribution manifolds 1 to the axis of the flow of the processed air are from 30 to 65 ^o
- the angles of the installation of vertical twin risers, with an angle of horizontal collectors of 65 ^o , are turned so that the axis of the nozzle nozzles 4 are oriented horizontally at angles of 20 ^o to the direction of the axis of flow of the processed air. With this installation of vertical twin risers, the dispersed water flames created by the nozzle nozzles will have projections that form angles of 70 ^° to the axis of the processed air stream.

 The irrigation system of the irrigation chamber works as follows: the water is circulated by a circulation pump to the horizontal distribution manifolds 1, then it is distributed into vertical twin risers 2, the water is divided into two streams and then flows through the outlet openings of equal diameters of the nozzle nozzles 4. The jets under pressure, colliding with each other of each pair of nozzle nozzles of each horizon, form stable flat spray torches.

 When the system is operating, the planes of dispersed water torches create a multi-row air treatment with water. In the scheme of the two-tier irrigation system presented by the authors, equipped with vertical double risers 2, six in each tier, with nozzle nozzles 4 on the four horizons of each tier, at least a 4-row air treatment with water is provided, which is two or more times higher by density of irrigation than in typical irrigation chambers.

 These factors ensure the achievement of the technical task.

 The system works stably on all types of spray and can easily be tuned to the characteristics of a wide range of network pumps, for example, with low pressure and high flow rate and vice versa. The irrigation system has a high degree of reliability and does not require large operating costs. The required power consumption of the network pump motors is less than the standard components.

Sources of information
1. Equipment for central sectional air conditioners type KT 120, passport. M., 1980.

 2. RU 2158883 "Irrigation system of the camera irrigation", authors Bobkin EI , Rosseev N.I., Shelkovsky V.K. et al., IPC F 24 F 3/14; 6/14.

Claims (1)

The irrigation chamber irrigation system, consisting of horizontal distribution manifolds, vertical twin risers with sprayers mounted on them in horizontal planes, made in the form of paired nozzle nozzles with outlet openings of equal diameter directed towards each other, while sprayers have the ability to control the amount of axial clearance between the planes of the outlet openings of the nozzle nozzles, characterized in that the horizontal distribution manifolds are provided with vert with hinges with the possibility of changing their installation angle from 30 to 65 ^o with respect to the direction of air movement, vertical twin risers are connected to horizontal distribution manifolds by means of vertical axial joints, nozzle nozzles are arranged in pairs on different horizons, each pair of nozzle nozzles of the same horizon installed with an offset relative to the pair of nozzle nozzles of the subsequent horizon, while the axial hinges of the double risers allow you to orient the axis nozzle nozzles up to 20 ^o with respect to the axis of the flow of the processed air to the side, excluding the overlap of the projections of the spray torches formed by pairs of nozzle nozzles.

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