SU1699565A1 - Water aerating device - Google Patents

Abstract

This invention relates to the treatment of water. The aim of the invention is to intensify the process of capturing and dissolving air in water, as well as simplifying the design of the device. The device consists of a housing 1 and a nozzle 2. The nozzle 2 contains an input channel 3, an intermediate channel 4 and an output channel 5 of cylindrical shape. The input channel 3 has a diameter larger than the intermediate channel 4, and the output channel 5 of the nozzle 2 has a diameter less than the intermediate channel 4. At the end of the nozzle 2 there are 6 pyramidal flow dividers. The invention relates to water treatment, in particular to devices to saturate the water with air. The aim of the invention is to intensify the process of capturing and dissolving air in water, as well as simplifying the design of the device. FIG. 1 shows a general view of the device, a longitudinal section; in fig. 2 is a section A-A in FIG. one; in fig. 3 - nozzle outlet, in an enlarged scale. forms. The nozzle has a conical surface 8 and tooth-shaped annular protrusions 9 for firmly securing the hose to the water main. The housing 1 has an inlet channel 10, an intermediate channel 11 and an output channel 12. Hole 13 is designed to supply air. The conic surface 14 has the same angle of inclination to the horizontal axis as the conical surface 8. The installation and placement of the nozzle 2 in the housing 1 is carried out by tightly fitting them along the conical surfaces 14 and 8. When water is supplied from the water mains to the inlet 3 nozzle 2 under pressure enters the stream of water. Through the hole 13, the air enters the inlet channel 10, from which it enters the intermediate channel 11, and then into the outlet channel 12. At the entrance to the output channel 12 intensive mixing of small water droplets with air occurs. The invention allows to reduce costs in the manufacture of the device. 3 il. The device consists of a housing 1 and a nozzle 2. The nozzle 2 contains an input channel 3, an intermediate channel 4 and an output channel 5 of cylindrical shape. At the same time, the inlet channel 3 has a diameter larger than the intermediate channel 4, and the outlet channel 5 of the nozzle 2 has a diameter less than the intermediate channel 4. At the end of the nozzle 2 there are dividers 6 of the pyramidal water flow, {forming the outlet 7. The nozzle has a conical surface 8 for $ (/) G} with with SP OS OS

Description

tightly mating (placing) it in the housing 1 and tooth-shaped annular protrusions 9 for firmly securing the hose from the water main.

The housing 1, like the nozzle 2, has three channels: the inlet 10, the intermediate channel 11 and the outlet 12. The opening 13 is designed to supply air. The conical surface 14 of the inlet channel 10 of the housing 1 has the same angle of inclination to the horizontal axis as the conical surface 8 of the nozzle 2. The installation and placement of the nozzle 2 in the housing 1 is accomplished by their tight coupling along the conical surfaces 14 and eight.

The device works as follows.

When water is supplied from the water supply network through a hose (not shown), mounted on the tooth-like annular protrusions 9, an inlet of water flows into the inlet 3 of the nozzle 2, under pressure. The nature of the flow in the hose is steady, laminar. When a stream of water enters the inlet 3, the laminar flow becomes turbulent due to the fact that the diameter of the channel 3 is smaller than the diameter of the hose. Turbulence is enhanced by narrowing the flow of water and increasing its velocity at the entrance to the intermediate channel 4. Further strengthening of turbulence is also achieved by narrowing the flow and increasing its speed at the entrance to the output channel 5 of the nozzle 2. The final amplification of turbulence is carried out by the dividers 6 water flow, as a result of which small water droplets fly out from the nozzle 7 of the nozzle 2, which trap air in the intermediate channel 1 and also in the outlet channel 12 of the housing 1. At the outlet of the channel 12 enters a mixture of water and air. Through the holes 13, air enters the inlet channel 10, which has a conical shape, from which it enters the intermediate channel 11, and then into the outlet channel 12. Thus, the air flow, like the water flow, changes its flow pattern from laminar to turbulent due to narrowing of the air channels. Since the final increase in turbulence air occurs at the entrance to the channel 12, then

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It is preferable to position the end face of the nozzle (orifice 7) as close as possible to the entrance to the exit channel 12, where intensive mixing of small water droplets with air occurs.

Thus, due to the hermetic shape of the two parts (housing 1 and nozzle 2), the degree of intensification of the process of air capture and dissolution in water is increased. The degree of intensification of the simple device described is so great that it can be used to aerate small-volume water without using devices that supply air through the opening 13 under pressure and without using additional parts (rotating blades, disks, etc.) to increase the turbulence of the water flow. In particular, the simple structure of the device shown in FIG. 1 and 2, can be used for aeration of water in small-sized laboratory vessels, for example, when washing photographic materials from chemical reagents, aerating aquariums, in chemical laboratories to accelerate oxidative and washing processes, etc.

In addition, the described construction of a device for aerating water can also be used to aerate large reservoirs, provided that it is complicated: its known technical solutions: a compressor for forcing air under pressure, rotating blades, discs, lattice confusors, etc. d. The combination of the advantages of the described construction with known means to increase the intensification of aeration will reduce the requirements for additional structural elements, for example, by reducing the pressure of water or air, reject individual parts or simplify their design to increase the turbulence of water flow.

The device can be made of thermoplastic materials in a progressive way, for example, by the method of injection molding into the mold.

The invention allows to reduce costs in the manufacture of the device.

Claims (1)

Invention Formula A device for aerating water, comprising a housing with an opening for air intake and a nozzle placed inside the body, characterized in that, in order to intensify the process of capturing and dissolving air in water, as well as simplifying the design of the device, the housing and the nozzle are made up of three concentric channels of variable cross section narrowing in the direction to the exit from the device The end of the nozzle is made of pyramid-shaped flow dividers, while the outer surface of the nozzle and the inner surface of the body are made conical, with the possibility of their combination. eleven Fig 2 t $ Phie.1 Figz