RU2523816C1 - Pneumatic sprayer (versions) - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: pneumatic atomiser annular slotted gas nozzle is arranged at diffuser edge and features conical shape with taper angle of 60-150 degrees. Atomiser inner annular gas chamber incorporates extra two opposed nozzles. Axes of nozzles cross so that the angle between the axis of every nozzle and mirror axis of pneumatic atomiser varies from 30 to 90 degrees. Total area of the nozzles outlet cross-sections makes 0.3-1.0 of that of atomiser annular slotted gas nozzle. In compliance with second version, said atomiser annular slotted gas nozzle is arranged at diffuser edge and features conical shape with taper angle of 60-150 degrees and outlet cross-section of variable area over annulus perimeter.

EFFECT: dispersed spray of fluids and suspensions, longer life, controlled shape and sizes of gas-drop spray.

4 cl, 5 dwg

Description

The invention relates to energy and is intended for spraying liquids and suspensions, for example, water-coal fuel (VUT).

Known pneumatic nozzle in which a stream of liquid is introduced into the coaxial gas stream [Spraying liquids / Borodin V.A. and others - M., 1976]. The principle of operation of such nozzles is associated with the occurrence of waves on the interfaces between the liquid and gas, as a result of the interaction of which with the gas stream, the liquid stream (film) breaks up into droplets.

A disadvantage of the known nozzle design is the fact that with an increase in the size of the liquid nozzle and the flow rate of the liquid, the quality of atomization sharply worsens.

Known pneumatic nozzle containing a housing with an axially arranged rod, a liquid channel and two gas channels located on opposite sides of the liquid channel, the liquid and gas channels passing first into the liquid and gas slotted nozzles, respectively, and then into a common mixing chamber, formed by the inner surface of the housing and the outer surface of the output, made spherical, the end face of the rod [RF patent No. 2106914, 1996, B05B 7/02].

In this nozzle, a liquid stream is supplied to a high-speed associated gas stream along the convex generatrix of the outlet end of the rod. Due to the Coanda effect, the liquid jet adheres to the walls of the stem. The free boundary of such a jet is unstable (Taylor instability). On the surface of the jet, longitudinal ribs are formed. With increasing distance from the nozzle, the height of the ribs increases, and the jet disintegrates into lamellar radial streams. Associated high-speed gas flow blows through each lamellar stream of liquid from two sides. Due to Helmholtz instability, trickles break up into small drops. Directly at the stem wall, the droplet size may not be small enough. The gas stream introduced into the mixing chamber through the internal gas nozzle produces additional grinding of the droplets.

In such a nozzle, the width of the annular gas and liquid nozzles should be sufficiently small, and the flow velocities large. When using a nozzle for spraying highly viscous liquids due to the presence of narrow gaps in the nozzle design, high pressure is required to pump the liquids. In addition, such nozzles wear out quickly if they are used to spray suspensions containing solid abrasive particles.

Thus, a disadvantage of the known nozzle is its low efficiency when spraying viscous liquids and suspensions and its rapid wear.

Also known is a pneumatic nozzle [RF patent No. 2015347, 1991, E21F 5/04], comprising a housing with a nozzle for supplying compressed air, mounted along the axis of the housing with axial movement of the fluid supply pipe, at the end of which is located a spray nozzle made in the form of a truncated cone, mounted on one end of a spring installed inside the pipe for supplying fluid, the other end of which is fixed inside the pipe, and an air nozzle formed by the protrusion of the housing and the pipe for supplying fluid, while the elastic A ring for adjusting the shape of the air nozzle is mounted on the outer surface of the fluid supply pipe, and a sleeve is installed in the end part of the fluid supply pipe with axial movement. The nozzle for supplying compressed air is located tangentially to the inner surface of the housing and at an angle to its longitudinal axis.

In this nozzle, a liquid jet flowing out of a slotted conical nozzle collides with a gas flow running at an angle and is sprayed onto droplets. Effective atomization of a liquid stream occurs only at high speeds of both gas and liquid flows. Therefore, a disadvantage of the known nozzle is the lack of efficiency when spraying viscous liquids and suspensions. In addition, the design of the spray device, in cases where the liquid contains abrasive particles, does not preclude rapid wear of the walls of the slotted liquid nozzle.

Of the known solutions, the closest in technical essence to the proposed invention is a pneumatic nozzle [RF patent No. 2346756, 2009, B05B 7/08], comprising a housing with a pipe for supplying gas, a pipe for supplying liquid along the axis of the housing, passing into the diffuser , at the end of which there is an annular nozzle in the form of an axisymmetric head converging to the axis of the housing, and an annular slotted gas nozzle at the outlet of the annular chamber, formed by the housing and the outer boundary of the annular nozzle, the length of the generatrix cages from the gas outlet nozzle to the edge of the diffuser has a diameter of the order of the length of the diffuser edge.

In this nozzle, a gas jet flowing out of the slot nozzle, without tearing off due to the Coanda effect, moves along the converging outer wall of the nozzle and forms a converging jet gas stream outside the nozzle. As a result of the collision of elementary streams at a point on the axis of the nozzle, a critical point forms and a jet stream forms along the axis of the nozzle and a return jet of the cumulative type. The supply of the working fluid through the pipe along the axis of the nozzle leads to the formation of a liquid jet, which, colliding with the return gas stream, spreads with a thin jet film along the walls of the diffuser. At the exit of the diffuser, the liquid film collides with a conical gas stream. In this zone, as well as in the zone of collision of gas-liquid jets in the region of the critical point, intense interaction of flows and dispersion of liquid droplets occur.

The experiments showed that outside the rather narrow range of the ratio of the momentum ratios of the gas and liquid flows in the region of the outlet edge of the diffuser, the gas stream breaks off from the walls of the head and an annular vortex forms, and if the suspension is used as the working fluid, the head is abrasively destroyed. In addition, due to the axial symmetry of the nozzle, the angle of expansion of the gas-droplet torch is not always sufficient.

Thus, the disadvantage of the prototype is the fact that the nozzle design does not provide low wear at all operating modes, and also does not allow controlling the size and shape of the gas-droplet jet created by it in wide enough ranges.

The objective of the invention is to provide a pneumatic nozzle with such a form of gas and liquid paths, the design of which would ensure dispersion of the spraying of liquids and suspensions without rapid wear of equipment and with the ability to control the size and shape of the gas-droplet torch.

The problem is solved using the option of a pneumatic nozzle containing a housing with an internal annular gas chamber and a nozzle for supplying compressed gas to it, a fluid supply pipe installed along the axis of the housing, passing into the diffuser, and an annular slotted gas nozzle formed by an annular nozzle and nozzle body on exit from the inner annular chamber.

An annular slit gas nozzle is mounted on a slice of the diffuser and has a conical shape with a taper angle of 60 to 150 degrees, the inner annular gas chamber of the nozzle is additionally equipped with two nozzles mounted opposite each other, and the axis of the nozzles intersect or intersect so that the angle between the axis of each nozzle and the axis of symmetry of the pneumatic nozzle is from 30 to 90 degrees, while the total area of the transverse output sections of the nozzles is 0.3-1 square cross-sectional output section of the slotted annular g gas nozzle.

Preferably, the axis of the nozzles intersect or cross in the area below the diffuser at a distance of the order of the diameter of the outlet edge of the diffuser.

The problem is solved with the help of another variant of a pneumatic nozzle, comprising a housing with an internal annular gas chamber and a nozzle for supplying compressed gas to it, a fluid supply pipe installed along the axis of the housing, passing into the diffuser, and an annular slotted gas nozzle formed by an annular nozzle and nozzle body at the exit of the inner annular chamber.

An annular slotted gas nozzle is mounted on a slice of the diffuser and has a conical shape with a taper angle of 60 to 150 degrees, and an output cross section with a variable area around the perimeter of the ring.

Preferably, flats are made at the end of the nozzle body to obtain an output cross section of an annular slotted gas nozzle with a variable area around the perimeter of the ring.

Figure 1 shows the nozzle according to the first embodiment of the invention and shows a longitudinal section of the proposed pneumatic nozzle.

In another embodiment, the essence of the invention is illustrated in Fig.2-5.

Figure 1 presents the housing 1 of a pneumatic nozzle; pipe 2 gas supply; annular gas chamber 3; fluid supply pipe 4; diffuser 5; ring nozzle 6; annular slotted gas nozzle 7; additional nozzles 8.

The nozzle comprises a housing 1 with a nozzle 2 for supplying gas, an annular gas chamber 3, a pipe 4 for supplying liquid, passing into the diffuser 5, with an annular nozzle 6, forming together with the nozzle housing 1 an annular slotted gas nozzle 7, nozzles 8.

An annular slotted gas nozzle 7 is mounted on a slice of the diffuser 5 and has a conical shape with a taper angle of 60 to 150 degrees.

At the end of the inner annular gas chamber 3 of the nozzle, two nozzles 8 are installed opposite each other with intersecting or intersecting axes of the nozzles, the angle between the axis of each nozzle and the axis of symmetry of the pneumatic nozzle being from 30 to 90 degrees, while the total area of the transverse exit sections of the nozzles is 0 , 3-1 the cross-sectional output sectional area of the slotted annular gas nozzle (Figure 1).

The axis of the nozzles 8 intersect or cross in the area below the diffuser 5 at a distance of the order of the diameter of the outlet edge of the diffuser 5 (Figure 1).

Figure 2-5 shows the nozzle of the second embodiment.

The nozzle has two mutually perpendicular planes of symmetry: horizontal and vertical.

Figure 2 shows the cross section of the nozzle with a horizontal plane, Figure 3 with a vertical plane, and Figure 4 shows a profile view of the nozzle.

Figure 5 shows the shape of an annular slotted gas nozzle with a variable area around the perimeter of the ring.

A variable area around the perimeter of the ring can be obtained by any means known from the prior art.

Figure 2-5 shows the nozzle in which the output cross section of the annular slotted gas nozzle is made with a variable area around the perimeter of the ring due to the execution of two symmetrically arranged sections at the end of the nozzle body - flats 10.

At the end of the nozzle body two symmetrically arranged flats 10 are made to obtain an annular slotted gas nozzle 7 having an output cross section with a variable perimeter area (Figure 5).

Due to the presence of flats 10, the outer edge of the annular gas nozzle takes a three-dimensional (non-axisymmetric) shape, and the output section of the gas nozzle 7 acquires a variable cross-sectional area around the perimeter of the ring. The angle between the planes 10 and the axis of the nozzle exceeds the taper half-angle of the gas slot nozzle 7.

The implementation of the nozzle in accordance with the first embodiment and the second embodiment of the invention leads to the achievement of the task.

The proposed options for pneumatic nozzles work as follows.

A gas stream flowing from the annular slotted gas nozzle 7 forms a converging conical jet gas stream outside the nozzle, which bifurcates into a direct stream and a return stream near the nozzle symmetry axis. The pipe 4 to the diffuser 5 serves the working fluid. In the region of transition of the pipe 4 to the diffuser 5, the return gas stream collides with the liquid stream, as a result of which the liquid stream spreads along the walls of the diffuser 5, forming a jet film stream. At the cross section of the diffuser 5, a film jet of liquid interacts with a gas stream, creating a conical gas-droplet torch. Further downstream, at the critical point, an intense collision of gas-droplet jets occurs, further dispersion of liquid droplets and the formation of an expanding gas-droplet plume.

In the first version of a pneumatic nozzle with nozzles 8, gas jets flowing from nozzles 8 interact with a gas-droplet torch, which leads to additional grinding of liquid droplets, and, in addition, they deform the gas-droplet torch and increase its cross-sectional area.

When the axes of the nozzles 8 are intersecting lines, the cross section of the gas-droplet flow takes the form of an ellipse with a large axis perpendicular to the plane in which the axes of the nozzles 8 lie.

When the axes of the nozzles 8 are intersecting lines, the cross section of the gas-droplet torch also takes an ellipsoidal shape, however, the large axis of the ellipse lies in the plane passing through the axis of the nozzle and the centers of the outlet edges of the nozzles 8.

In the second embodiment of the pneumatic nozzle, the pulse of the gas stream flowing from the annular slotted gas nozzle 7 takes a variable value along the perimeter of its cross section, which leads to deformation of the cross section of the gas-droplet torch.

The proposed pneumatic nozzle options make it possible to control the size and shape of the gas-droplet torch.

The technical result of the proposed invention is the creation of a pneumatic nozzle with such a shape of gas and liquid paths, the design of which ensures dispersion of spraying liquids and suspensions without rapid wear of equipment and the ability to control the size and shape of a gas-droplet torch.

Technical documentation has been developed for the proposed pneumatic nozzle, prototypes have been manufactured and tested. Tests on water and coal-water fuel showed a good quality of spraying at LLC “Plant of wall blocks” (Novosibirsk).

Claims (4)

1. A pneumatic nozzle comprising a housing with an internal annular gas chamber and a nozzle for supplying compressed gas to it, a fluid supply pipe mounted along the axis of the housing, passing into the diffuser, and an annular slotted gas nozzle formed by an annular nozzle and nozzle housing at the outlet of the inner annular chamber, characterized in that the annular slotted gas nozzle is mounted on a slice of the diffuser and has a conical shape with a taper angle of 60 to 150 degrees, the inner annular gas chamber of the nozzle additional o equipped with two nozzles mounted opposite each other, and the axis of the nozzles intersect or intersect so that the angle between the axis of each nozzle and the axis of symmetry of the pneumatic nozzle is from 30 to 90 degrees, while the total area of the transverse exit sections of the nozzles is 0.3-1 cross-sectional area of the slit annular gas nozzle. 2. The pneumatic nozzle according to claim 1, characterized in that the nozzle axes intersect or cross in the area below the diffuser at a distance of the order of the diameter of the outlet edge of the diffuser. 3. A pneumatic nozzle comprising a housing with an internal annular gas chamber and a nozzle for supplying compressed gas to it, a fluid supply pipe mounted along the axis of the housing, passing into the diffuser, and an annular slotted gas nozzle formed by an annular nozzle and nozzle housing at the outlet of the inner annular chamber, characterized in that the annular slotted gas nozzle is mounted on a slice of the diffuser and has a conical shape with a taper angle of 60 to 150 degrees, and an output cross section with a variable cross-sectional area meter ring. 4. The pneumatic nozzle according to claim 3, characterized in that flats are made at the end of the nozzle body to obtain an output cross section of an annular slotted gas nozzle with a variable area around the perimeter of the ring.

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