RU2150336C1 - Finely divided liquid sprayer - Google Patents

Abstract

FIELD: equipment for liquid spraying. SUBSTANCE: liquid sprayer may be used in fire-fighting equipment, for instance, as a component of sprinkler systems, in agriculture, in devices of chemical technology and heat power industry. Conical surfaces forming groove with nozzles are asymmetrical relative to transverse plane of sprayer body in point of their intersection. Angle between generator of groove upper conical surface and body transverse plane amounts from 5 to 100 dwg. Angle between generator of groove lower conical surface and body transverse plane is from 40 to 50 deg. End row of nozzles is made in the form of pair mutually perpendicular channels for liquid supply located in body longitudinal planes. Region of intersection of channels is combined with conical surface of body end part and forms outlet of each nozzle. Number of nozzles formed by paired mutually perpendicular channels ranges from 4 to 6. Conical surfaces of groove intersect channels parallel to body axis to separate them into two equal parts. EFFECT: higher uniformity and, correspondingly, intensity of liquid spraying over entire preset area. 6 cl, 1 dwg

Description

 The invention relates to techniques for spraying liquids and can be used in fire fighting equipment, for example, as part of sprinkler systems, in agriculture, in chemical technology devices and in the power system.

State of the art
Currently, various liquid sprayers are widely used. For example, a device for multi-stage spraying of liquid is known (see application RU 95115939 A, MPK-6 B 05 B 1/14, publ. 10.09.97), which contains a hollow cylindrical body, at least two of which are made on the outside conical grooves in which channels are made for the passage of fluid from the internal cavity of the housing. The channels for the passage of fluid are made through at the tops of the conical grooves parallel to their axis of symmetry. The axis of the channels in the known device is offset relative to the vertices of the conical grooves by a distance of no more than the value of the radius of the through channels. The opening angle of the conical grooves is from 40 to 60 ^o . Three through channels are made in each tier, and their axes are offset from the tier to the subsequent tier by an angle of 60 ^o relative to each other.

 The described known device creates a fine stream of droplets with a diameter of 60 - 120 microns. However, during the operation of such a device, irregular irrigation occurs with the formation of annular zones in which the irrigation intensity varies greatly. This applies, first of all, to the central zone located under the atomizer, where the intensity is two times less than in the zone farther from the atomizer. In addition, in the areas farthest from the sprayer, irrigation intensity remains low. Thus, the zone with a given intensity necessary for the implementation of the technological process has an annular shape with a small extent. As a result of this, the flow rate of the sprayed liquid is unreasonably increased to achieve the necessary irrigation intensity over the entire area of the circle of predetermined sizes.

The closest analogue of the patented device is a sprinkler fine spray (sprinkler) described in patent RU 2111033 C1 (IPC-6 A 62 C 31/02, publ. 05.20.98). The known liquid atomizer includes a hollow cylindrical body, on the outer surface of which there are several rows of nozzles, each of which is formed by a groove with symmetrical conical surfaces and channels made in the body parallel to its axis of symmetry and communicated with the internal cavity of the body, the lateral surface of which is partially crosses the conical surface of the groove, and the pipe for supplying fluid. External conical grooves of the housing are made with an opening angle in the range from 60 to 90 ^o . In addition, the sprayer contains an additional end row of nozzles located on the housing from the side opposite to the fluid supply pipe. An additional row of nozzles is formed by the intersection of the outer conical groove of the body and the lateral surface of the channels, the axes of which are located at an acute angle to the axis of symmetry of the atomizer body.

 The use of a finely dispersed sprayer of the described design allows one to obtain a uniform volume flow of finely dispersed droplets in the range of droplet diameters from 30 to 150 microns at a water supply pressure of not more than 1 MPa. However, the sprayer of this design does not allow to achieve a given distribution of flows of fine droplets on the irrigation surface of the required area without increasing the flow rate of the liquid. This is due to the fact that the droplet flows generated by most of the nozzles are oriented in the horizontal direction and have a symmetrical distribution relative to the horizontal plane at the outlet of the nozzles.

SUMMARY OF THE INVENTION
The patented invention is aimed at creating a predetermined distribution of sprayed fine droplets over a specific irrigation area and at reducing the required fluid flow rate. The achievement of this technical result is associated with an increase in the uniformity and, accordingly, the intensity of the liquid spraying over the entire surface of a given area.

 The achievement of the specified technical result is due to the fact that in a finely dispersed liquid atomizer containing a hollow cylindrical body, on the outer surface of which at least one row of nozzles is formed, formed by a groove with conical surfaces and channels made in the body parallel to its axis of symmetry and communicated with the internal cavity cases, the lateral surface of which partially intersects the conical surfaces of the grooves, and the fluid supply pipe, according to the present invention, is conical The other surfaces forming the groove are made asymmetric with respect to the transverse plane of the housing at the point of intersection.

In a preferred embodiment of the atomizer, the angle between the generatrix of the upper conical surface of the groove and the transverse plane of the body is from 5 to 10 ^o , and the angle between the generatrix of the lower conical surface of the groove and the transverse plane of the body is from 40 to 50 ^o .

 The sprayer may contain an additional end row of nozzles located on the housing from the side opposite to the fluid supply pipe.

 The end row of nozzles, it is advisable to perform in the form located in the longitudinal planes of the housing pair of mutually perpendicular channels for supplying fluid. The channel intersection region in this case is combined with the conical surface of the end part of the housing and forms the outlet of each nozzle.

 The number of nozzles formed by paired mutually perpendicular channels, it is desirable to choose from 4 to 6.

 It is advisable that the conical surface of the grooves intersect the channels parallel to the axis of the housing, dividing them into two equal parts.

 The asymmetry of the conical surfaces forming the grooves in the indicated range of angles makes it possible to organize uniform atomization of liquid at the periphery of the circle with a smooth decrease in intensity in a narrow central region. The installation of an additional end nozzle only increases the intensity to the required amount of fluid in the central region located directly below the nozzle.

 The best uniformity of liquid spraying is achieved when using in an additional end nozzle from 4 to 6 pairs of mutually perpendicular channels intersecting on the conical surface of the housing. In this case, the deviation of the irrigation intensity does not exceed 20%. This will be enough to provide the required intensity within the irrigation circle. It does not require additional fluid flow to compensate for its flow in areas with reduced spray intensity.

The best conditions for uniform spraying of liquid are also achieved by choosing the opening angles of asymmetric conical grooves in certain ranges of angles relative to the transverse plane of the atomizer body. An increase in the angle between the generatrix of the upper conical surface of the groove and the transverse plane of the atomizer body of a more extreme value (5 ^o ) leads to an unproductive increase in the angle of the spray torch over 180 ^o , and with a decrease in the angle less than the lower limit value (10 ^o ) - to reduce the area irrigated by the liquid with a given intensity value.

For the lower side of the groove, an increase in the angle between the generatrix of the lower conical surface of the groove and the transverse plane of the body more than 50 ^o leads to uneven spraying of liquid in the peripheral region of the irrigated area, and a decrease in the angle less than 40 ^o leads to uneven spraying of the liquid in the central region.

Information confirming the possibility of carrying out the invention
Further, the patented invention is illustrated by a description of a specific embodiment and the accompanying drawing, which shows a structural diagram of a finely dispersed liquid atomizer.

 The finely dispersed sprinkler contains a hollow cylindrical body 1 with a pipe 2 for supplying liquid. On the outer surface of the housing 1 there are two rows of nozzles formed by grooves 3 with conical surfaces and channels 4 made in the housing 1 parallel to its axis of symmetry. The channels 4 are in communication with the internal cavity of the housing 1. The lateral surface of the channels 4 partially intersects the conical surfaces of the groove 3.

The conical surfaces forming each groove 3 are made asymmetric with respect to the transverse plane of the housing 1 (horizontal plane) at their intersection. The generatrix of the upper conical surface of the groove 3 forms an angle equal to 7 ^o with the transverse plane of the housing 1, and the generatrix of the lower conical surface of the groove 3 forms an angle equal to 45 ^o .

An additional end row of nozzles 5 is made on the housing 1 from the side opposite to the fluid supply pipe 2, which are formed by five pairs of mutually perpendicular channels 6 for fluid passage, which intersect on the conical lateral surface of the end part of the housing 1 and form the outlet openings of each nozzle. Paired channels 6 are located at right angles to each other in the longitudinal planes of the housing 1. The conical surface of the end part of the housing 1 is made with an angle at the apex of 90 ^o .

 The through channels 4, parallel to the axis of symmetry of the housing 1, are uniformly placed in three in each row of nozzles and are offset from the channels of the adjacent row of nozzles of the neighboring row. In this embodiment, the outlet openings of the nozzles formed by the grooves 3 are staggered on the side surface of the housing 1, creating favorable conditions for spraying the liquid.

 The conical surfaces of the groove 3 intersect the channels 4, dividing them into two equal parts. With this embodiment, the same speeds of the oncoming liquid flows inside the channels 4 and the uniform outflow of the liquid stream from the outlet of the nozzle having a complex shape formed by the intersection of the conical surfaces of the grooves 3 and the cylindrical surface of the channels 4 are ensured.

 The work of a fine liquid spray is as follows.

 The sprayer is installed in an upright position. When fluid is supplied into the housing 1 through the nozzle 2 under the action of a pressure drop of 0.4 - 0.8 MPa, in the channels 4, counter flows of liquid are formed, rushing to the outlet openings of the nozzles formed by the channels 4 in the grooves 3.

After the collision of the fluid flows in the channels 4 and the outflow through the outlet openings, a fan-shaped gas-liquid flow in the form of a shroud is formed. The angle of the flow in the horizontal plane is 60 ^o . When interacting with the surrounding atmosphere, the generated stream is crushed into small drops. Due to the asymmetry of the conical surfaces of the grooves 3 relative to the transverse plane of the housing 1 (horizontal plane), the flow of fine droplets deviates from the horizontal direction by an angle in the range from 10 to 15 ^o . This angular deviation of the flow of droplets leads to an increase in the uniformity of the spraying of liquid over the entire surface with a slight reduction in the area of the irrigated surface.

In paired mutually perpendicular channels 6 of the end row of nozzles 5, a similar mechanism for crushing liquid drops is implemented, but the generated swell-like flow deviates from the horizontal plane by a larger angle, in the range from 45 to 60 ^o , in the direction to the central region of the irrigated surface located directly under the sprayer. This distribution of the sprayed liquid makes it possible to increase the uniformity of the spraying of the liquid over the central part of the irrigated surface.

 The results of comparative tests of the finely divided liquid sprayer according to the present invention and other known sprayers-analogues are presented in the attached table.

During testing, the required irrigation intensity was set at 0.025 kg / m ² s. The test results showed the high efficiency of the fine spray made according to the present invention, when used for uniform irrigation of the surface in the form of a circle with an area of 27.3 m ² . The deviation of the intensity of surface irrigation between the central and peripheral zones of the irrigated surface was 0.005 kg / m ² s. Compared with the claimed sprayer, to create a given irrigation intensity (0.025 kg / m ² s) on the entire surface of a certain area using known sprayers-analogues, it will be necessary to increase the fluid flow rate from 1.3 to 2.5 times.

 The experimental data presented confirm the feasibility of achieving a technical result when using a finely dispersed atomizer made according to the present invention.

Industrial applicability
The patented fine atomizer relates to a liquid atomization technique. The invention can be used in fire fighting equipment, for example, as part of sprinkler fire extinguishing systems, in agriculture - for spraying various types of substances on sown areas and in industrial premises, as well as in chemical technology devices and in the power system - for spraying fuel.

 In addition, the invention can be applied in various fields of technology where the generation of atomized finely dispersed fluid flows is required in both closed and open spaces.

Claims (6)

 1. A fine liquid atomizer containing a hollow cylindrical body, on the outer surface of which at least one row of nozzles is formed, formed by a groove with conical surfaces and channels made in the body parallel to its axis of symmetry and communicated with the internal cavity of the body, the side surface of which partially intersects the conical surfaces of the groove, and the pipe for supplying liquid, characterized in that the conical surfaces forming the groove are made asymmetric with respect to peppermint body plane in a place where they intersect. 2. The sprayer according to claim 1, characterized in that the angle between the generatrix of the upper conical surface of the groove and the transverse plane of the body is from 5 to 10 ^o , and the angle between the generatrix of the lower conical surface of the groove and the transverse plane of the body is from 40 to 50 ^o .  3. The sprayer according to claim 2, characterized in that it contains an additional end row of nozzles located on the housing from the side opposite to the fluid supply pipe.  4. The sprayer according to claim 3, characterized in that the end row of nozzles is made in the form of paired mutually perpendicular channels for supplying liquid located in the longitudinal planes of the body, the intersection region of which is aligned with the conical surface of the end part of the body and forms the outlet of each nozzle.  5. The sprayer according to claim 4, characterized in that the number of nozzles formed by paired mutually perpendicular channels is from 4 to 6.  6. The sprayer according to any one of the preceding claims, characterized in that the conical surfaces of the grooves intersect the channels parallel to the axis of the housing, dividing them into two equal parts.

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