SU1713659A2 - Spray head - Google Patents

Abstract

The invention relates to a device for spraying liquids and can be used to desorb gases dissolved in a liquid. The goal is to expand technological capabilities by increasing the efficiency of desorption of gas-saturated liquids in the spraying process and ensuring that the intensity of the desorption process can vary with constant spraying performance. For this, the spray head is provided with an external source of compressed gas and a pressure regulator connected to it. In the wall of the latter, an ejection nozzle is made in the direction of the liquid of the cylinder at its end on the side of the spray. .The holes in the remaining cylinders are made through uniformly spaced apertures communicating with the ejection nozzle by means of a pipeline with adjustable elements. The pipeline is connected to a pressure regulator. The spray head allows you to smoothly increase the desorption efficiency of a gas-saturated spray liquid with constant spray performance and improve the quality and uniformity of splitting the fluid flow into fine and monodisperse spray, and also smoothly reduce the degree of desorption of liquid spray and a constant spray performance and ensure a change in a wide range of intensity of the desorption process of the sprayed liquid with constant spray performance. 2 illustrationsl

Description

The invention relates to a device for spraying liquids, can be used to desorb gases dissolved in a liquid, and is an improvement of the spray head according to the authors. Ev, №829197.

The purpose of the invention is the expansion of technological capabilities due to an increase in the spraying process of the efficiency of desorption of gas-saturated liquids and the possibility of changing the intensity of the desorption process with constant spray performance.

FIG. 1 shows a spray head, a general sectional view; in fig. 2, section A-A in FIG. one,

The spray head contains a tapered nozzle 1 and a nozzle 2 fixed at its output end with an internal diameter of the flow channel 3 increasing in the direction of fluid flow. The nozzle 2 is made stepwise in the form of a series of consecutive cylinders 4-7. The spray head is also provided with an external source 8 of compressed gas, for example, a cylinder with compressed gas, and a pressure regulator 9 connected to it. In the wall of the latter, along the motion of the liquid cylinder 7, an ejection nozzle 10 is made at its end on the spray side, and in the walls of the remaining cylinders 4-6 are made through uniformly spaced holes 11, which are connected via pipeline 12 with regulating elements, for example, valves 13 connected to pressure regulator 9. The holes 11 are evenly spaced around the circumference of the cross-section of the nozzle 2 and interconnected by an annular manifold 14, which is part of the pipeline 12 and communicates with the latter through a corresponding valve 13. The valve 15 serves to connect the external source 8 and the pressure regulator 9 from the pipeline 12, and a valve 16 for disconnecting the conduit 12 from the ejection nozzle 10.

The spray head works as follows.

The jet of the gas-saturated liquid to be sprayed flows with a constant capacity from the cone nozzle 1 into the channel 3 of the nozzle 2. At the same time, the liquid jet first enters the cylinder 4 of the nozzle 2, where it is compressed and a ring vacuum zone is created at the walls of the cylinder 4. Moving further, the jet enters from cylinder 4 successively into cylinders 5-7 and, having flowed out of cylinder 7 of nozzle 2 to the outside, forms a spray of liquid. - Moving, for example, from cylinder 4 to cylinder, it is intensively moving from jet to pass a step transition between these cylinders and, getting into the cylinder 5, undergoes a sharp expansion in its cavity. As a result, an annular vacuum zone is formed on the side of the cylinder 5 in the step transition zone between said cylinders 4 and 5. A similar picture will take place with the further movement of the jet towards the spraying through subsequent cylinders 6 and 7. The annular vacuum zones formed in the zones of step transitions between the cylinders with their rarefaction affect the flow of flowing gas-saturated liquid, which causes instant volume boiling of carbonated liquid and discharge from the stream the latter in the rarefaction zones of a significant amount of gas contained in the liquid, and also increases the efficiency of destruction of the integrity of the sprayed sweat. Eye of the liquid on the drops. Thus, during the passage through the nozzle 2, the main amount of gases dissolved in it is removed from the sprayed liquid, which together with the spray are removed from the nozzle 2 beyond the device to the spray side. At the same time, as a result of intense outflow

the sprayed liquid and gases separated from it from the cylinder 7, said liquids and gases intensively wash the ejection nozzle 10; As a result, a certain vacuum is created in the channel of the nozzle 10, which through pipe 12, valves 13 and holes 11 are transferred into the cavity of the flow channel 3 of the nozzle 2 into the zones immediately adjacent to the stepped ledges at the junction points between the nozzle cylinders, i.e. The vacuum created in the ejection nozzle 10 superimposes and increases the vacuum created in the annular vacuum zones at the places of stepped interruptions between the cylinders of the nozzle 2. As a result, at a constant spraying performance, the degree of negative pressure of the indicated vacuum zones in the channel 3 of the nozzle 2 on the sprayed liquid flow increases ,

5 which increases the efficiency of desorption of gas-saturated liquids during the spraying process, and also intensifies the process of splitting the liquid stream into a fine spray.

0 If necessary, changes in the process of spraying (reducing or increasing) the efficiency of liquid desorption at a constant spraying performance increase or decrease the degree of vacuum supply (vacuum) from the ejection nozzle 10 to the annular vacuum zones of any specific or all cylinders 5-7 4-7 nozzles 2 For this, increase or decrease the degree of overlap.

0 valve 16 and the corresponding control valves 13 on the outlets of the pipeline 12 to the openings 11 of the corresponding nozzle cylinders 2.

If necessary, a more significant decrease in desorption of the gas-saturated spraying liquid with the same design of the nozzle 2 and constant spray performance shut off the valve 16 and open the valve 15, after

0 which the regulator 9 sets the required pressure of the compressed gas coming from the external source 8 into the pipeline 12. After that, the corresponding control valves 13 provide the necessary supply of compressed gas under a certain pressure from the pipeline 12 to the corresponding annular vacuum zones at the sites of step transitions between the cylinders 4-7 to cancel the vacuum that forms in them. As a result, the degree of dilution in these annular vacuum zones of the nozzle 2 decreases and its effect on the flow of liquid through the nozzle 2 decreases, which leads to the required and necessary reduction in the degree of gas removal from gas-saturated sprayed liquids. If necessary, by means of the regulator 9 and the valves 13, it is possible to set such pressure and flow rate of gas supplied from the outside to the vacuum zones of the nozzle 2, at which the process of desorption of the sprayed liquid may not take place at all, and the liquid saturated with gas will be sprayed. Those. The device provides a wide range of changes in the degree of desorption of the sprayed liquid during the operation of the device with constant spray performance,. Shch. 5 those 15 20 FORUMA and 3 ABOUT spraying head on the author. No. 829197, characterized in that, in order to expand technological capabilities by increasing the efficiency of desorption of gas-saturated liquids during the spraying process and to enable the intensity of the desorption process to change at a constant spraying performance, it is equipped with an external source of compressed gas and a regulator connected to it pressure, while in the wall of the latter, along the motion of the liquid of the cylinder, an ejection nozzle is made at its end on the side of the spray, and in the walls of the remaining cylinders through-enes, uniformly arranged on the circumference holes communicated with the ejection nozzle by means of control elements with the pipeline connected to a pressure regulator. H “7,;: 7 xh //

Figg

Claims (2)

Claim Spray head according to ed. St. No. 829197, characterized in that, with the aim of expanding the technological 5 capabilities by increasing the desorption efficiency of gas-saturated liquids during the spraying process and providing the possibility of changing the intensity of the desorption process at a constant spraying productivity, it is equipped with an external source of compressed gas and a pressure regulator connected to it, at the same time, an ejection nozzle is made in the wall of the last cylinder along the liquid path at its end from the spray side 15, and in the walls of the remaining cylinders through holes evenly spaced around the circumference, in communication with the ejection nozzle by means of a pipeline with 20 control elements connected to a pressure regulator. 77777777X 7777 //// 2/2/22/2 Figure 1 75 4 g 11 4 \ / 7 ' 1 ---------1] —A —— 1 U -... 1 / S