UA79895C2 - Sprayer for liquid atomization - Google Patents

Abstract

A sprayer for liquid atomization contains a cone-shaped chamber with branch pipe for supply of liquid, a spherical cap with openings, where the ratio of the total area of the crosscuts of openings of spherical cap to the area of its surface makes 0.8-16%, and the ratio of the radius of curvature of cap to the height of cone-shaped chamber is 0.1-1.0. In the lower part of cone-shaped chamber a corrugated ring with branch pipe of bleeding is mounted, which forms a heating chamber. The ratio of the height of branch pipe of bleeding to the height of the heating chamber makes 0.5-0.95, and the ratio of the area of the crosscut of branch pipe to the total area of the crosscuts of openings of spherical cap makes 0.25-2.9. Furthermore, in the heating chamber the heat-transfer agent is located, the ratio of volume of which to the volume of heating chamber makes 0.001-0.28, height from the corrugated ring to the axis of the branch pipe of liquid inlet makes 0.12-0.78 of the height of heating chamber. The heating chamber is equipped with a sleeve, and the ratio of the radius of curvature of the spherical surface of sleeve to the diameter of sleeve makes 0.85-1.95. A divider is located between the contact and the terminal.

Description

Description of the invention

The invention belongs to the field of hot liquid spraying. The invention can be used in devices for wet 2 cleaning of gas from dust. It increases the efficiency of dust capture due to the vapor-condensation effect.

The invention can also be used in chemical, metallurgical and other branches of industry, where hot liquid spraying is required.

According to the main (author's certificate of the USSR Mob54295| known nozzle for spraying liquid holding a cone-shaped chamber with a nozzle for supplying liquid, a spherical nozzle with holes, where the ratio 70 of the total cross-sectional area of the holes of the spherical nozzle to its surface area is 0.8-1695, and the ratio of the radius the curvature of the nozzle to the height of the conical chamber - 0.1-1.0.

The disadvantage of this nozzle is that it is impossible to obtain hot drops of liquid for irrigation of wet gas cleaning devices.

The purpose of the invention is to obtain hot drops of sprayed liquid. 12 The goal is achieved by installing a corrugated ring with a liquid drain nozzle in the lower part of the conical chamber, creating a heating chamber, the ratio of the height of the liquid drain nozzle to the height of the heating chamber is 0.5-0.95, the ratio of the cross-sectional area of the liquid drain nozzle to the total the cross-sectional area of the holes of the spherical nozzle is 0.25-2.Р9. There is a coolant in the heating chamber, the ratio of the volume of the coolant to the volume of the heating chamber is 0.001-0.28, the height from the corrugated ring to the axis of the liquid inlet nozzle is 0.12-0.78 of the height of the heating chamber. The heating chamber is supplied with cuffs, the radius of curvature of the spherical surface of the cuff is 0.85-1.95 of the diameter of the cuff. There is a disconnector between the contact and the terminal.

Figure 1 shows a longitudinal section of a nozzle for spraying liquid.

Fig. 2 cuff, with the radius of curvature of the spherical surface of the cuff, longitudinal section. with

The nozzle contains a cone-shaped chamber 1, in the lower part of the chamber 1 is installed a corrugated ring 3 with a (3) developed surface to increase the heat transfer of the liquid, with a nozzle 2, the drain of the liquid forms a heating chamber 6, a spherical nozzle 4 with holes 5. a nozzle 7 with an axis 15 for supply of liquid to the heating chamber 6, in which the coolant 8 is located. The inlet opening of the nozzle 2 of the liquid drain is covered by the rod 9, which is attached to the spherical surface 11 of the rubber cuff 10, the rod 9 is supplied with a spring 12 and a plate 16 with contacts 14, a splitter 17, a terminal 13 is connected to the coolant. The ratio of the height of the nozzle 2 of the liquid discharge to the total area Ф) of the intersections of the holes 5 of the spherical nozzle 4 is 0.25-2.9. The heat carrier 8 is located in the heating chamber 6, the ratio of the volume of the heat carrier 8 to the volume of the heating chamber 6 is 0.001-0.28, the height from the corrugated co ring C to the axis 15 of the nozzle 7 of the liquid introduction is 0.12-0.78 of the height of the heating chamber 6. The heating chamber 6 is supplied to the cuff 10, the radius of curvature of the spherical surface 11 of the cuff 10 is 0.85-1.95 3o of the diameter of the cuff 11. The nozzle works in the following way. Between contact 14 and terminal 13, the splitter 17 is removed by turning. Known types of energy, such as electric current, are supplied to contacts 14. Terminal 13 with contacts 14 are disconnected, because the spring 12 and the spherical surface 11 of the cuff 10 work for stretching, the rod 9 covers the entrance to the nozzle 2 of the liquid drain. Liquid is supplied under pressure through nozzle 7. It "fills the heating chamber 6 and presses on the spherical surface 11 of the cuff 10, which bends, compresses the spring C 40. 12 and captures the rod 9, the contacts 14 come into contact with the terminals 13, the circuit is closed and the heat carrier 8 s receives energy that will turn into in it, in the heat, which heats the liquid. Raised rod 8 opens the entrance

From" the liquid drains into the nozzle 2 and the heated liquid flows through the nozzle 2 into the spherical nozzle 4 and through the holes 5 the heated liquid is sprayed in drops. If the supply of liquid to the heating chamber stops, the pressure of the liquid in the heating chamber drops to zero, the spherical surface 11 of the cuff 10 and the spring 12 due to elasticity take their original position, the contacts 14 and the terminals 13 are disconnected. The chain breaks, the energy does not flow to the heat carrier 8. The concavity of the spherical surface 11 of the cuff 10 must correspond to the separation distance of the contact (se) 14 and the terminal 13. If the ratio of the radius of curvature of the spherical surface 11 of the cuff 10 to the diameter of the cuff 10 is greater than 1.95, the spherical surface 11 cuff 10 will work for compression. At minimum liquid pressure in the heating chamber 6 will be insufficient to overcome the compressive forces of the rubber spherical surface 11 and the spring 12, (Te) 20 nozzle will not be heated by the liquid.

The ratio of the height of the nozzle 2 of the liquid drain to the height of the heating chamber b less than 0.5 will reduce the volume of liquid in the heating chamber b, the less time the liquid will be in the heating chamber 6, the lower the temperature of the liquid will be. The ratio of the height from the corrugated ring C to the axis 15 of the nozzle 7 of the introduction of liquid to the height of the heating chamber 6 of the liquid greater than 0.78 will lead to the fact that the cold liquid will be supplied to the upper layers of the liquid 29 of the heating chamber 6. The liquid with a low temperature will drain through the nozzle 2 Volume ratio

GF) heat carrier 8 to the volume of the heating chamber would be less than 0.001 will lead to a decrease in the surface of the heat carrier 8 and, accordingly, the heat transfer of the liquid in the heating chamber 6 will decrease. until the formation of a vapor-liquid mixture in the heating chamber 6, the nozzle will 60 work in pulsating mode. The nozzle is manufactured and tested to heat and spray hot droplets in the inclined gas duct at the entrance to the wet apparatus. The efficiency of dust collection increased by 5-7965.

Claims (2)

The formula of the invention b5 1. A nozzle for spraying liquid containing a conical chamber with a nozzle for supplying liquid, a spherical nozzle with holes, where the ratio of the total cross-sectional area of the holes of the spherical nozzle to its surface area is 0.8-1695, and the ratio of the radius of curvature of the nozzle to the height of the conical chamber - 0.1-1.0, which is distinguished by the fact that in the lower part of the cone-shaped chamber there is a corrugated ring with a liquid drain nozzle, which forms a heating chamber, while the ratio of the height of the liquid drain nozzle to the height of the heating chamber is 0.5-0, 95, and the ratio of the cross-sectional area of the nozzle to the total cross-sectional area of the holes of the spherical nozzle is 0.25-2.9, in addition, there is a coolant in the heating chamber, the ratio of its volume to the volume of the heating chamber is 0.001-0.28, height from corrugated ring to /p. the axis of the liquid inlet nozzle is 0.12-0.78 of the height of the heating chamber. 2. The nozzle according to claim 1, which differs in that the heating chamber is equipped with a cuff, while the ratio of the radius of curvature of the spherical surface of the cuff to the diameter of the cuff is 0.85-1.95. C. The nozzle according to claim 2, which differs in that a disconnector is located between the contact and the terminal of the heating chamber. 6) IF) (o) (ee) (o) m. - with . and? -I se) (ee) se) sl ime) 60 b5