RU2278742C1 - Liquid sprayer - Google Patents

Abstract

FIELD: fire putting out.

SUBSTANCE: liquid sprayer comprises housing whose face is provided with outlet opening and controller of fluid flow rate. The liquid flow rate controller is mounted in the space of the housing and comprises chamber with movable piston, axisymmetric deflector set in the outlet opening in the housing, and rod. One end of the rod is connected with the deflector, and the other end, with the piston. The chamber of the liquid flow rate controller is divided into two spaces by the piston. The first space is in communication with the housing space through which the liquid is supplied to the outlet opening. The second control space is isolated from the space of the housing, pressure-tight, and filled with gas. The deflector has at least one profiled section that is conical or conoid in shape and projects out of the exit of the outlet opening in the housing. The cross-section of the profiled section of the deflector increases in the downstream direction. According to the other version, the control space of the liquid flow rate controller receives the spring. The chamber of the liquid flow rate controller is cylindrical and mounted coaxially to the outlet opening in the housing. The maximum diameter of the deflector is smaller than that of the outlet opening in the housing. The sprayer is provided with the axisymmetric expansion chamber arranged coaxially to the deflector at the exit of the outlet opening in the housing. The grid or perforates baffle is set at the outlet section of the expansion chamber. The chamber can move along the axis of symmetry of the deflector with respect to the housing of the sprayer.

EFFECT: expanded functional capabilities.

9 cl, 2 dwg

Description

The invention relates to equipment for spraying liquid and can be used in fire-fighting equipment, in agricultural technology as a means of decontamination and in other areas of technology.

From the USSR author's certificate No. 1839094 A1 (a description published on 12/30/1993, IPC A 62 C 31/03), a liquid atomizer is known comprising a housing having an outlet in its end portion and a fluid flow regulator installed in the housing cavity. The fluid flow regulator includes a chamber with a movable piston, which is connected to an axisymmetric radome through a rod. The chamber of the fluid flow controller is divided by a piston into two cavities: a rod and a piston. The cavities are in communication with each other and with the cavity of the body through which the fluid is supplied to the outlet, through channels of small cross section formed in the rod.

The known device includes a stock in which a cavity is made, communicated through channels with the piston cavity of the regulator. In the internal channel of the butt stock is installed, connected to the control bypass valve. The control valve plate is conical in shape and placed in the flow channel with the possibility of axial movement and overlapping channels connecting the piston cavity to the nozzle cavity of the device. The opposite part of the rod is connected with a spring-loaded stop.

When using the known device, the operator can adjust the amount of fluid flow by changing the force on the stop. By regulating the flow rate of the liquid, a uniform flow of fluid through the outlet of the atomizer is ensured when the fluid pressure in the supply lines changes. However, this device does not automatically maintain the fluid flow at a constant level without operator intervention.

In USSR author's certificate No. 1584960 A1 (description published on 09/19/1988, IPC A 62 C 31/02) a fire barrel with a liquid spray is described. The device comprises a housing, in the end part of which an outlet is made, supply lines, a handle, a nozzle for spraying liquid, and a fluid flow regulator installed in the cavity of the housing.

The fluid flow regulator includes a chamber formed by a flow channel, in which a piston coaxially mounted, moved under the influence of the lever lever of the trigger mechanism.

The bore of the adjustable valve is fixed depending on the pressure of the supplied fluid and the spring force acting on the valve. The set value of the flow rate through the nozzle of the atomizer is set by adjusting the valve spring. Automatic maintenance of a stable flow rate of water through the nozzle of the atomizer is ensured by the use of feedback on the fluid pressure. When the fluid pressure in the supply line changes, the stop of the valve spring moves, thereby changing the resulting force that acts on the valve being moved.

When using the known device, a stable flow rate is maintained when the pressure of the supplied fluid is changed. However, the used flow regulator does not have stable characteristics in the entire control range, since a spring with a nonlinear dependence of the elastic force on its compression ratio is used as a regulating element.

In addition, the pipeline connecting the control cavity of the glass, which serves as a stop for the spring, with the supply line, has a significant length. As a result, the device does not have the required speed control flow.

The closest analogue of the claimed invention is a liquid atomizer according to the patent US 759320 (published on 05/10/1904). The liquid spray contains a housing, in the end part of which an outlet is made, and a fluid flow regulator installed in the cavity of the housing. The fluid flow regulator includes a chamber with a movable piston, an axisymmetric fairing and a rod connected to the fairing on one side and the piston on the other.

The chamber of the fluid flow regulator is divided into two cavities by the piston. The first cavity is in communication with the cavity of the housing through which fluid is supplied to the outlet. The second chamber cavity, which functions as a control cavity, is isolated from the internal volume of the housing filled with liquid and is in communication with the atmosphere. A spring is installed in the cavity of the control chamber between the piston and the end wall of the chamber, with the help of which the position of the piston and the fairing connected to it are adjusted depending on the pressure of the liquid supplied to the flow channel of the atomizer (US 759320, Fig. 3).

The fairing is installed in the inlet section of the outlet channel of the atomizer body and is made with conical sections expanding and tapering in the direction of fluid flow in series. The channel of the outlet of the atomizer body is made tapering in the direction of fluid flow and has a conoidal shape.

In order to stabilize the sprayed gas-droplet flow, a preliminary swirl of the fluid flow is carried out. For this, screw channels formed on the surface of the stem are used.

The fluid supplied to the cavity of the atomizer body enters the open chamber of the flow regulator chamber and acts on the surface of the piston, causing it to move together with the stem and cowl in the opposite direction to the fluid flow. The piston moves until the pressure of the liquid on the piston is balanced and the spring force of the spring installed in the insulated cavity of the regulator is balanced. The fairing occupies a position in which a predetermined passage area is provided for the flow channel formed between the fairing and the channel wall of the outlet. As a result of the regulation of the passage section of the channel, a gas-droplet stream is generated having a predetermined value of speed and flow rate.

With increasing pressure of the fluid supply, causing an increase in the velocity of the gas-droplet flow, the force of the action of the fluid on the piston increases. The piston and associated fairing are displaced in a direction opposite to the direction of fluid flow. As a result, the area of the passage section of the channel of the outlet of the atomizer body increases. As a result of automatic control, the gas-droplet flow rate decreases to the required level with a negligible increase in fluid flow.

The known device allows you to generate stable gas-droplet flows with a constant speed when changing the pressure of the supplied fluid. In this case, automatic maintenance of a given speed is carried out by adjusting the bore of the annular tapering channel formed by two axisymmetric surfaces of a conical and conoidal shape.

However, despite these advantages, the design of the known device does not ensure the maintenance of fluid flow at a constant level when the fluid pressure varies over a wide range. Unstable flow control using a known device due to the fact that the final adjustable characteristic is the speed of the generated stream, and not its flow. In addition, as a regulatory body in the device, a spring is used that does not have the required linear characteristic of the change in the elastic force depending on the degree of compression depending on the pressure.

An object of the present invention is to provide a liquid atomizer, which automatically maintains the flow rate of the generated liquid stream at a constant level, provided that the pressure of the supplied liquid is varied over a wide range. Such a device should have a fairly simple design and have high reliability. Achievable technical result associated with the solution of the technical problems posed is to increase the efficiency of regulation of fluid flow and expand the regulation range.

The solution of the assigned technical problems is necessary for a number of practical applications of the atomizer. In particular, this is necessary when extinguishing fires of various classes (by type of burning substances and materials), when it is required to maintain a constant flow rate of the extinguishing fluid during the fire fighting process.

The achievement of the technical result is achieved by using a liquid atomizer containing a body, in the end part of which an outlet is made, and a fluid flow regulator installed in the body cavity and including a chamber with a movable piston, an axisymmetric cowl mounted in the body outlet, and a rod connected on one side with a fairing, and on the other hand with a piston. The chamber of the fluid flow regulator is divided into two cavities by the piston. The first cavity is in communication with the cavity of the housing through which fluid is supplied to the outlet. The second control cavity is filled with gas and isolated from the body cavity.

According to the present invention, the control cavity of the chamber of the fluid flow regulator is sealed, and the cowling has at least one profiled section of a conical or conoidal shape protruding beyond the exit section of the housing, the cross section of the profiled section of the cowling increasing in the direction of fluid flow.

The combination of the above essential features of the invention determines the ability to automatically maintain a given level of fluid flow through the outlet of the device by changing the area of the outlet when changing the pressure of the supplied fluid in a wide range. The invention is based on the following theoretical premises.

In the General case, the condition of constant flow rate of the fluid flow through the flow channel with changing fluid pressure and the cross-sectional area of the channel can be expressed by the following dependence:

where Q is the mass flow rate of the liquid, kg / s;

F _i - the current value of the cross-sectional area of the outlet of the atomizer, m ² ;

P _i - the current value of the pressure of the fluid supply, MPa;

ρ is the density of the liquid, kg / m ³ .

For the case under consideration, when the cross section of the flow channel of the sprayer has the shape of a ring formed between the fairing and the wall of the flow channel, the above condition will have the following form:

where D is the diameter of the outlet of the housing, m;

d _i - the diameter of the cross section of the fairing located in the plane of the outlet, m

It should be noted that the cross section of the annular channel formed by the tapering outer conoidal and inner conical surface having the smallest area is taken as the cross section of the flow channel in the considered case.

During sprayer operation, fluid flow control is carried out in accordance with the above parametric dependence. When a liquid is supplied to the atomizer under the influence of a pressure of the liquid, the regulator piston, together with the stem and fairing, moves from the initial equilibrium position to a new equilibrium position, in which the pressure in the control sealed cavity and the pressure in the body cavity filled with liquid are equalized.

Obviously, with this equilibrium position, the piston will shift in the opposite direction to the fluid flow. When displaced, a corresponding movement of the flow regulator associated with the piston of the fairing will occur. Due to the fact that the fairing has one or more shaped sections of conical or conoidal shape, expanding in the direction of fluid flow, the cross section of the annular flow channel of the atomizer is reduced. In this case, the decrease in the cross-sectional area of the channel will occur depending on the pattern of change in the cross-sectional area of the fairing in the direction of fluid flow.

In addition, when moving the fairing, the shape of the channel of the outlet of the atomizer changes, thereby affecting the opening angle of the generated gas-droplet stream. Thus, choosing the shape and dimensions of the profiled section of the fairing, it is possible to achieve not only the maintenance of fluid flow at a given level, but also a programmable change in the opening angle of the gas-droplet flow.

In addition, using a fairing with several profiled sections, each of which has different patterns of change in the shape of the fairing along its length, it is possible to create conditions for a programmed change in fluid flow depending on the pressure in the flow cavity.

The calculated change in the cross-sectional area F _{i of the} nozzle outlet to a value satisfying the condition of constant flow rate Q of fluid through the nozzle flow channel occurs according to the known parametric dependences Q = f (F _i , P _i ) = const.

The value L _{i of} movement of the piston relative to its initial position, which corresponds to atmospheric pressure in the liquid cavity of the atomizer body, depending on the current value of the liquid pressure P _i can be determined according to the Boyle-Mariotte equation based on the following relationship:

where L ₀ is the length of the control cavity of the chamber of the flow controller in the inoperative position of the sprayer;

P ₀ is the gas pressure in the control cavity of the chamber of the fluid flow controller, which is in the initial idle position.

Thus, knowing the dependence of the change in the movement of the fairing relative to the outlet of the housing on pressure, it is possible to calculate the profile of the fairing, which determines the cross-sectional area of the channel of the outlet at the current time. The cross-sectional area of the outlet cross section, in turn, determines the value of fluid flow through the atomizer.

In a preferred embodiment of the invention, the fluid flow control chamber may be cylindrical and mounted coaxially with the outlet of the housing. Moreover, the first cavity of the camera communicates with the cavity of the housing through at least one hole made in the side wall of the camera.

For the considered embodiment of the invention, it is advisable that the outlet of the housing be formed in the wall of the chamber of the fluid flow regulator, which serves as the end part of the housing.

In order to reduce the volume of the control cavity of the chamber of the flow controller by increasing the reaction force (with increasing fluid pressure), an elastic element can be installed in the control cavity. Such an elastic element in the simplest case can be made in the form of a compression spring.

The use of an elastic element installed in a sealed control cavity of the regulator chamber can significantly reduce the axial size of the regulator. During the operation of the sprayer, made according to this design variant, when the fluid is supplied to the sprayer under the influence of the pressure of the liquid, the regulator piston, together with the rod and fairing, moves from its initial equilibrium position, compressing the gas filling the control cavity and the spring. In this case, the force acting on the piston from the side of the control cavity of the flow regulator is the sum of the pressure on the piston of the compressed gas and the elastic force of the compressed spring.

A new equilibrium position of the piston and fairing in the case under consideration is achieved with less displacement of the piston compared with the case when there is no elastic element in the control cavity of the flow regulator chamber filled with compressed gas.

The value L _{i of the} displacement of the piston relative to its initial position in this case will be determined by a more complex parametric dependence:

L _i = f (P _i ; P _g ; P _control ),

where R _g is the pressure of the compressed gas in the control cavity of the chamber of the flow controller;

P _control - the elastic force of a compressed spring installed in the control cavity of the chamber of the flow regulator.

Taking into account the indicated dependence, it is possible in each case to calculate the profile of the fairing having one or more profiled sections of conical or conoidal shape. It should be noted that the selected profile of the fairing determines the cross-sectional area of the channel of the outlet of the device at the current time depending on the current value of the fluid supply pressure in the flow chamber of the spray chamber.

To regulate fluid flow over a wide range of fluid pressure changes, the maximum fairing diameter d _max is selected from the condition: d _max <D.

The fulfillment of this condition eliminates the possibility of a complete overlap of the outlet opening of the channel of the atomizer body with non-calculated fluid pressure surges.

In order to generate a wide-aperture gas-droplet flow, the atomizer can include an axisymmetric expansion chamber located coaxially with the cowling at the exit section of the housing. For effective crushing of liquid droplets, a mesh or perforated partition can be installed in the outlet section of the expansion chamber.

The expansion chamber can be made moving along the axis of symmetry of the fairing relative to the housing. This embodiment of the expansion chamber allows you to adjust the angle of the taper of the spray torch of gas-droplet flow.

At least one opening for air ejection can be made in the wall of the expansion chamber. The flow of air into the sprayed liquid stream contributes to the efficiency of crushing the fluid stream flowing through the outlet of the atomizer body.

Further, the patented invention is illustrated by examples of specific performance of the spray liquid and the accompanying drawings, which depict the following:

figure 1 is a longitudinal section of a liquid atomizer, made according to the first embodiment of the invention, on an enlarged scale (2: 1);

figure 2 is a longitudinal section of a liquid atomizer, made according to the second example embodiment of the invention, on an enlarged scale (2: 1).

In Fig. 1, the piston and fairing of the flow regulator are shown in two positions: in the initial state (solid line), when the pressure in the cavity of the atomizer body through which the fluid is supplied is equal to atmospheric pressure, and in the working position when the fluid pressure is P ₂ (dashed line). In figure 2, the piston and fairing are shown in the initial state. The arrows in the drawings show the directions of movement of the expansion chamber.

A liquid sprayer, made according to the first embodiment of the invention (see FIG. 1), comprises a housing 1 and a fluid flow regulator 2 installed in the cavity of the housing 1. The fluid flow regulator 2 includes a cylindrical chamber 3 mounted coaxially to the housing 1 and with a piston 4 The joint between the inner surface of the wall of the chamber 3 and the lateral surface of the piston 4 is sealed with O-rings 5. In the end wall 6 of the chamber 3 of the fluid flow regulator 2, an axial outlet 7 of the housing 1 is formed. In this example The device end wall 6 serves as the end part of the housing 1. The diameter D of the outlet 7 is 5 mm.

The fluid flow regulator 2 includes an axisymmetric radome 8 installed in the outlet 7 of the housing 1, and a stem 9 connected on one side to the cowl 8, and on the other to the piston 4. The cowl 8 is formed by a profiled conical section with a minimum diameter d _min = 2 mm and a maximum diameter of d _max = 4 mm (d _max <D). The cross section of the fairing 8 increases in the direction of fluid flow.

The chamber 3 of the fluid flow regulator 2 is divided by a piston 4 into two cavities. The first cavity 10 is in communication with the cavity of the housing 1 through two openings 11 made in the side wall of the chamber 3. The second cavity, the control cavity 12, is hermetically isolated from the cavity of the housing 1 by a piston 4 with O-rings 5. In the initial state of the flow regulator, the control cavity 12 is filled with air at normal atmospheric pressure P ₀ = 0.1 MPa.

In the initial state, when the air pressure in the control cavity 12 is equal to the pressure in the cavity of the housing 1, the minimum section of the fairing 8 (d _min ) is located in the plane of the inlet section of the channel of the outlet 7. The length L _{0 of the} control cavity 12 with this position of the piston 4 is 15 mm .

The initial pressure (normal atmospheric pressure) in the control cavity 12 is set during the assembly of the device using a process hole made in the end wall of the chamber of the flow regulator (not shown). When installing the piston 4 in the initial position, the pressure in the control cavity 12 is equalized with the pressure in the cavity of the housing 1 by bleeding gas through a process hole, which is then sealed with a plug.

At the outlet channel cut 7 on the side wall of the chamber 3 of the fluid flow regulator 2 coaxially to the fairing 8, an expansion cylindrical chamber 13 is installed using a threaded connection. The expansion chamber 13 from the side of the housing 1 has an end wall 14 in which four openings 15 are made for air ejection. The holes 15 are located evenly around the circumference around the end of the chamber 3.

The movement of the expansion chamber 13 along the axis of symmetry of the fairing 8 relative to the housing 1 is carried out using a running thread formed on the mating surfaces of the expansion chamber 13 and the chamber 3 of the fluid flow regulator. The drawing shows the position of the expansion chamber 13 at a maximum distance from the housing 1.

In the output section of the expansion chamber 13, a mesh 16 is installed, fixed to the end part of the expansion chamber 13 with the help of a fixing sleeve 17.

In this example implementation of the invention, the liquid atomizer is part of the injection type fire extinguisher (not shown in the drawing). The atomizer housing 1 is in communication with a container filled with a fire extinguishing liquid, which is under pressure from the displacing gas.

In the second embodiment (see FIG. 2), the liquid atomizer comprises a housing 18 and a fluid flow regulator 19 installed in the cavity of the housing 18. The fluid flow regulator 19 includes a cylindrical chamber 20 mounted coaxially to the housing 18 with a piston 21. The joint between the inner surface of the wall of the chamber 20 and the lateral surface of the piston 21 is sealed with sealing rings 22. In the end wall 23 of the chamber 20 of the fluid flow regulator 19 there is formed an axial outlet 24 of the housing 18. In this embodiment, troystva end wall 23 serves as the end portion of body 18. Diameter D of the output orifice 24 is 5 mm.

The fluid flow regulator 19 includes an axisymmetric radome 25 installed in the outlet 24 of the housing 18, and a stem 26 connected on one side to the cowl 25 and on the other to the piston 21. The cowl 25 is formed by a profiled conoidal section with a minimum diameter d _min = 4 mm and a maximum diameter of d _max = 4 mm (d _max <D). The cross section of the fairing 25 increases in the direction of fluid flow.

The chamber 20 of the fluid flow regulator 19 is divided by the piston 21 into two cavities. The first cavity 27 communicates with the cavity of the housing 18 through two holes 28 made in the side wall of the chamber 20. The second cavity — the control cavity 29 — is hermetically isolated from the cavity of the housing 18 by a piston 21 with O-rings 22. In the control cavity 29 between the piston 21 and the end wall chamber 20, a compression spring 30 is installed. In the initial state of the flow regulator 19, the control cavity 29 is filled with air at normal atmospheric pressure P ₀ = 0.1 MPa.

In the position where the air pressure in the control cavity 29 is equal to the pressure in the cavity of the housing 18, the spring 30 is in an undeformed state. In this case, the minimum section of the fairing 25 (d _min ) is located in the plane of the inlet section of the channel of the outlet 24. The length L _{0 of the} control cavity 29 at this position of the piston 21 is 10.5 mm (see FIG. 2).

At a section of the outlet channel 24, an expansion cylindrical chamber 31 is installed coaxially with the threaded joint 25 on the side wall of the chamber 20 of the fluid flow regulator 19. The expansion chamber 31 has an end wall 32 on the side of the housing 18, in which there are four openings 33 for air ejection. The holes 33 are arranged uniformly around the circumference around the end of the chamber 20.

The movement of the expansion chamber 31 along the axis of symmetry of the cowl 25 relative to the housing 18 is carried out using a running thread formed on the mating surfaces of the expansion chamber 31 and the chamber 20 of the fluid flow regulator. Figure 2 shows the position of the expansion chamber 31 at a maximum distance from the housing 18.

In the output section of the expansion chamber 31, a mesh 34 is mounted fixed to the end part of the expansion chamber 31 by means of a fixing sleeve 35.

The operation of the liquid atomizer made according to the first embodiment of the present invention is as follows.

After opening the passage channel of the locking and starting device of the fire extinguisher, a fire extinguishing liquid displaced from the tank by compressed gas is supplied to the cavity of the housing 1 of the liquid sprayer at a pressure of P ₁ = 2 MPa. The fluid enters the cavity 10 of the chamber 3 of the regulator 2 of the fluid flow through two holes 11 made in the side wall of the chamber 3. Under the influence of fluid pressure, the piston 4 moves against the direction of fluid flow. In the process of equalizing the forces acting on the piston 4 from two sides, the volume of the control cavity 12 decreases and, accordingly, the gas pressure in it increases. At the moment of reaching equilibrium between the forces acting on the piston 4 from the side of the liquid cavity 10 and from the side of the gas control cavity 12, the fairing 8 connected through the rod 9 to the piston 4 occupies a position corresponding to the calculated cross-sectional area of the channel of the outlet 7.

The value of L _{i the} movement of the piston 4 is determined in accordance with the Boyle-Mariotte law for the selected values of L ₀ , P ₀ and Pi. The maximum displacement of the piston L ₁ is 13.8 mm. The cross-sectional area of the hole 7 is determined by the diameter of the profiled section of the fairing 8 in the end plane of the wall 6. As a result, the mass flow of liquid through the channel of the outlet 7 is maintained at a predetermined level of 0.35 kg / s.

In the process of spending fire extinguishing fluid, the pressure of the supplied fluid decreases. As a result, the fluid pressure on the piston 4 decreases. When the fluid pressure drops to the level P ₂ <P _{1, the} piston 4 with the rod 9 and the cowling 8 moves under the action of the pressure of the compressed gas in the control cavity 12 in the direction of the fluid flow. The volume of the control cavity 12 increases until the piston 4 stops in a new equilibrium position (see figure 1).

At the moment of reaching equilibrium between the forces acting from the side of the control cavity 12 and from the side of the cavity 10 through which the liquid is supplied to the outlet 7, when the liquid pressure level P ₂ , the cross-sectional area of the annular channel of the outlet 7 increases in accordance with the calculated dependence Q _const = f (F _i , P _i ). As a result, the cross-sectional area is automatically adjusted to a value at which the condition of constant fluid flow through the spray when the pressure changes from P ₁ to P ₂ is satisfied, which satisfies the condition of constant fluid flow when the supply pressure is P ₂ . In this case, the displacement value L _{i of the} piston 4 relative to the initial position of the piston 4 is reduced to the value L ₂ = 11 mm <L ₁ .

Thus, in the process of operation of the patented liquid spray when the pressure of the liquid supply drops, the piston 4 associated with the fairing 8 gradually moves in the direction of the liquid supply and a corresponding increase in the cross-sectional area of the outlet 7. As a result, the flow rate of the extinguishing liquid through the atomizer remains constant during the duration of the production of extinguishing agent.

The fluid flow from the outlet 7 enters the cavity of the expansion chamber 13, where it is mixed with the air ejected from the atmosphere through the openings 15. The flow of air into the stream immediately after it leaves the nozzle outlet 7 contributes to turbulence of the fluid flow in the direction perpendicular to the axis of symmetry expansion chamber 13. As a result, the liquid is mixed with the air stream, which contributes to the effective crushing of the liquid stream into small droplets. At the outlet of the expansion chamber 13, a gas-droplet liquid flow passes through the cells of the grid 16, in which additional crushing of liquid droplets and the formation of a finely dispersed gas-droplet flow with a torch taper angle of ~ 20 ° occur.

If it is necessary to increase the cone angle of the spray torch of the gas-droplet stream, the expansion chamber 13 is moved towards the housing 1 by an appropriate distance by its rotation relative to the axis of symmetry of the fairing 8.

The operation of the liquid atomizer made according to the second embodiment of the invention (see FIG. 2) is generally carried out similarly to the first example. The differences are only in the functioning of the fluid flow regulator.

The fluid enters the cavity 27 of the chamber 20 of the regulator 19 of the fluid flow under pressure P ₁ = 2 MPa through two holes 28 made in the side wall of the chamber 20. Under the influence of fluid pressure, the piston 21 moves against the direction of fluid flow. This causes gas compression in the control cavity 29 and compression of the spring 30, which is accompanied by a corresponding increase in gas pressure in the control cavity and an increase in the elastic force of the compressed spring 30. As a result, the resulting force acts on the piston 21 from the control cavity 29 of the chamber 20 of the regulator 19, which consists of the elastic force of the compressed spring 30 and the pressure force of the compressed gas on the piston 21.

At the moment of reaching equilibrium between the resulting indicated forces and the forces acting on the piston 21 from the side of the liquid cavity 27, the fairing 25 connected through the rod 26 to the piston 21 occupies a position corresponding to the calculated cross-sectional area of the channel of the outlet 24.

The value L _{1 of the} movement of the piston 21 relative to its initial position in the considered example of the invention is determined depending on the initial volume of the control cavity, the initial pressure and type of gas, the elastic force of the compressed spring 30, depending on its deformation, and on the pressure in the cavity of the atomizer housing filled liquid.

The cross-sectional area of the channel of the outlet 24 depends on the current diameter of the profiled section of the fairing 25 in the end plane of the wall 23. As a result, the mass flow of liquid through the channel of the outlet 24 is maintained at a predetermined level of 0.35 kg / s.

When the fluid pressure drops to the level P ₂ <P _{1, the} piston 21 with the rod 26 and the cowling 25 moves under the action of the resulting spring force 30 and the pressure of the compressed gas in the control cavity 29 in the direction of the fluid flow. The compression ratio of the spring 30 decreases, and the volume of the control cavity 29 increases until the piston 21 stops in a new equilibrium position (not shown in the drawing). In this case, the amount of displacement L _{i of the} piston 21 relative to the initial position of the piston 21 also decreases to the value L ₂ <L ₁ .

Automatic adjustment of the cross-sectional area in accordance with the calculated dependence Q _const = f (F _i , P _i ) in this case occurs similarly to that described for the first embodiment of the invention.

In the course of experimental studies, it was found that when the pressure in the fluid supply system is varied in the range from 2 to 0.3 MPa using a fluid atomizer made according to the invention, stable generation of a gas-droplet flow with a constant fluid mass flow rate of 0.35 kg / s is ensured when the range of the flow of extinguishing agent ~ 8 m

Liquid sprays made in accordance with the present invention can be used in various fields of technology, primarily in fire-fighting equipment. In addition, the invention can find wide application in the composition of agricultural equipment, as a means of decontamination and in other areas of technology where the generation of fine gas-droplet flows with a constant flow rate and feed range is required.

Claims (10)

1. A liquid atomizer comprising a body, in the end part of which an outlet is made, and a fluid flow regulator installed in the body cavity and including a chamber with a movable piston, an axisymmetric cowl mounted in the body outlet, and a rod connected to one sides with a fairing, and on the other hand with a piston, while the chamber of the fluid flow regulator is divided by the piston into two cavities, the first chamber cavity is in communication with the body cavity through which the liquid is supplied to the outlet, and the second chamber cavity, which serves as the control cavity, is filled with gas and isolated from the body cavity, characterized in that the control cavity of the fluid flow control chamber is sealed and the cowling has at least one profiled section of a conical or conoidal shape protruding beyond the cut of the outlet opening of the housing, the cross section of the profiled section of the fairing increasing in the direction of fluid flow. 2. The sprayer according to claim 1, characterized in that the chamber of the fluid flow regulator is cylindrical and mounted coaxially with the outlet of the housing, the first cavity of the chamber communicating with the cavity of the housing through at least one hole made in the side wall of the chamber. 3. The sprayer according to claim 2, characterized in that the outlet of the housing is formed in the wall of the chamber of the fluid flow regulator serving as the end part of the housing. 4. The sprayer according to claim 1, characterized in that an elastic element is installed in the control cavity of the fluid flow regulator. 5. The atomizer according to claim 4, characterized in that the elastic element is made in the form of a spring. 6. The sprayer according to claim 1, characterized in that the maximum diameter of the fairing dmax is selected from the condition dmax <D, where D is the diameter of the outlet of the housing. 7. The sprayer according to claim 1, characterized in that it contains an expansion chamber of an axisymmetric shape located coaxially with the cowling at the exit section of the housing. 8. The sprayer according to claim 7, characterized in that a mesh or perforated partition is installed in the outlet section of the expansion chamber. 9. The sprayer according to claim 7, characterized in that the expansion chamber is made moving along the axis of symmetry of the fairing relative to the housing. 10. The atomizer according to claim 7, characterized in that at least one hole for air ejection is made in the wall of the expansion chamber.

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