RU2361681C1 - Deflector ejector nozzle - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention is related to irrigation equipment and may be used in water sprinkler machines. Invention objective is to increase quality of artificial rain. For this purpose body flow path is arranged with abrupt narrowing. Hole that compresses jet is arranged in the form of cylindrical nozzle with sharp inlet edge and cylindrical part with length of at least four diametres of jet (d) with radial holes 0.2 d at the distance of 0.5 d from sharp edge. Deflector is arranged as flat, with diametre of (2.5-3)d with triangular grooves on deflector working surface. Grooves are located in the form of fan with wrapping angle of 180° with fan centre displaced to the side of pressing hole. Check-nut serves for fixation of nozzle in required area.

EFFECT: lower rain intensity, smaller drop size and lower energy of soil impact, higher wind resistance.

6 dwg

Description

The invention relates to irrigation equipment and can be used in sprinkler machines.

In order to obtain better parameters of artificial rain (the intensity and size of rain drops, the energy of rain impact on the soil) with low energy consumption, short-blast baffle nozzles are widely used in the world, they operate at pressures from 0.05 to 0.15 MPa (B. M. Lebedev. “Sprinkling machines.” M.: Mechanical Engineering, 1977, p. 23).

Cup-shaped short-blast baffle nozzles are known (Handbook "Irrigation Mechanization". M.: Agropromizdat, 1990, p. 124, Fig. 31a).

In the lower part of the aluminum body of the nozzle there is an internal thread for connection to the pipe of the farm, through which water flows. The top of the nozzle is a funnel with windows. In the upper part of the body is placed a replaceable nozzle made of plastic. In the upper part of the funnel, a bar is attached, on which there is a deflector made of bleached cast iron, its conical part is directed downward. The axis of the cone coincides with the axis of the nozzle. The angle of the cone at the apex is 120 °. The distance from the nozzle plane to the apex of the deflector cone is two diameters of the nozzle opening.

A jet of water leaving the nozzle opening vertically upwards flows around the cone and takes a conical shape with an angle of inclination of 30 ° to the horizon. With further movement in air, the flow on a short stretch of the path retains continuity in the form of a film, but then decays and continues to move in the form of drops. Thus, the area in the form of a circle is irrigated.

The nozzle hole in the inlet half has a conical shape, in the outlet half is cylindrical.

The disadvantages of the nozzle described above include the complexity of manufacturing, a large number of parts (5), high cost, and the rain torch is not windproof. Under operating conditions, they are often used with a downward flow, i.e. deflector down, which increases the energy of the drop on the soil and increases the intensity of the rain.

Known nozzle with a spoon-shaped baffle (reference "Mechanization of irrigation". M: IN "Agropromizdat", 1990, p. 125, Fig. 36 (c)). Its outlet is made in the form of a partition with chamfers outside and inside. A stream of water flowing out of the hole, hitting a deflector, takes the form of a bowl. Such a film is not windproof. In domestic and foreign irrigation practice, such a nozzle did not find application, although it was created in the early 60s of the last century.

The well-known short-jet deflector nozzles “Rainstar” E AS50 of the Austrian company “Bauer” with a downward flow of water are used, the deflectors of which are flat, round in shape with radial grooves. Rain torch is located in a circle. The use of radial grooves allows you to divide the film into trickles. The film, divided into trickles, has a large flight range, which allows to increase the capture area by artificial rain with one nozzle by 20-30%, and therefore, reduce the rain intensity. In this case, the jet is more windproof.

The disadvantage of such nozzles is the difficulty in manufacturing, the artificial rain torch is located only parallel to the horizon, the deflector forming surface is made perpendicular to the flowing stream, the speed of the film or stream formed is extinguished more than when it touches an inclined surface, therefore, the irrigation area with such a nozzle at equal costs and pressures it will be less, and the intensity of the irrigated area is higher.

The closest analogue is the well-known directional deflector nozzle (Reference. Irrigation mechanization. M.: Agropromizdat, 1990, p. 125, Fig. 3.1.b).

The body and nozzle deflector are made at the same time. A jet of water, leaving the nozzle, striking the deflector, is directed on one side relative to the axis of the nozzle, preserves the continuity of the jet in the form of a film, then splits into droplets.

Rain torch is flat. Depending on the angle at which the nozzle is located, the torch can be directed parallel to the horizon or at the desired angle. The nozzle is simpler, reliable in operation, and made of plastic - it is cheap.

Lack of nozzle: continuous film is not windproof.

The problem to which the claimed invention is directed is to improve the quality of artificial rain.

The technical result is a decrease in rain intensity, droplet size and impact energy on the soil, increasing wind resistance.

The technical result is achieved by the fact that in the known nozzle, including the housing and the deflector, made integral with the nozzle body and located at an angle of 30 ° relative to the axis of the jet, according to the invention, the flowing part of the nozzle body is made with a sudden narrowing, and the jet compressing hole is made in the form of a cylindrical nozzle with a sharp inlet edge and a cylindrical part with a length of at least four jet diameters (d) with radial holes of 0.2 d at a distance of 0.5 d from the sharp edge, the deflector is made flat, diameter ohm 2.5-3 d with triangular grooves on the working surface of the deflector of variable depth from 0 to 1.5-2 mm, with a step equal to the depth of the groove on the outer diameter of the deflector, and the grooves are arranged in the form of a fan with a swivel angle of 180 ° with an offset the center of the fan relative to the axis of the jet in the direction of the compression hole at a distance d, and a lock nut serves to fix the nozzle in the desired plane.

The invention is illustrated by drawings:

Figure 1 - shows the nozzle baffle ejector, General view.

Figure 2 is a view along arrow A in figure 1. Deflector.

Figure 3 is a view along arrow B in figure 2. Deflector.

In Fig.4 is a cross section GG in Fig.1, a cross section of the body in a compressed stream of the jet.

In Fig.5 is a section bB in Fig.3, the cross section of the deflector along the axis of the jet.

Figure 6 - Installation of nozzles on the sprinkler.

The nozzle consists of a housing 1, a lock nut 2, an arm 3, a deflector 4, a sharp edge 5, a compression hole 6, triangular grooves 7 with an offset fan center 8 of the deflector grooves 8, radial holes 9.

The nozzle works as follows. The flow of water passing through the flowing part of the nozzle, behind the sharp edge 5 (Fig. 1) is compressed, forming a vacuum. Through holes 9 (Fig. 5), water is saturated with air. The air-water jet, leaving the nozzle, hits the deflector 4, made with triangular grooves 7 in the form of a fan, forms a flat torch in separate trickles. With further movement in the air, water-air streams in a short section of the path remain continuous, but then disintegrate and continue to move in the form of drops. Thus, the site is irrigated.

From the theory of hydraulics it is known that with a sudden narrowing (Handbook of hydraulic calculations. / Edited by P.G. Kiselev. M .: Energia, 1972, p. 54), a nozzle with a sharp edge forms a vacuum in a compressed section which reaches a maximum value of 0.75-0.8 of the pressure in front of the nozzle.

As noted above, the deflector nozzles provide good rain quality, starting with a pressure in front of the nozzle of 0.05 MPa.

Given that the jet expires into the atmosphere, limiting the working pressure in front of the nozzle to 1.0 MPa, it can be guaranteed that the nozzle will work in its full cross section and there will be no vacuum breakdown.

In the deflector nozzle we offer, the resulting vacuum during sudden constriction is used to saturate the jet with air.

For this, the flow part of it is performed with a sudden narrowing. At a distance of 0.5 d (jet diameter) from the sharp edge of the nozzle inlet, radial holes with a diameter of 0.2 d are drilled (FIG. 5), connecting the vacuum to the atmosphere.

The deflector of the proposed nozzle is made flat (figure 4), with triangular grooves. The center of the grooves (Fig. 3) is shifted in the opposite direction of the jet movement direction by d. Fan of grooves 180 °. The maximum depth of the grooves (figure 4) of 1.5-2.0 mm The deflector plane relative to the axis of the jet is located at an angle of 30 ° (Fig. 1.)

The deflector of the nozzle we offer, in shape, angle of contact of the jet with the deflector plane, will allow you to have minimal energy consumption for crushing the jet and increase its flight range, and therefore, increase the irrigation area with one nozzle, and reduce the true rain intensity, and increase wind resistance.

The length of the cylindrical part of the nozzle is equal to four jet diameters.

In accordance with the recommendations of P.G. Kiselev "Reference book for hydraulic calculations." "Energy", M., 1972 p. 54. the length of the cylindrical part of the nozzle with a sharp inlet edge should be ≥3d, while the flow coefficients µ, velocity φ, compression of the jet at the outlet of the nozzle ε and resistance λ have the following values in the quadratic resistance region.

The amount of energy lost in the cylindrical part is 33% of the pressure.

A vacuum is formed in the nozzle, which in a compressed section reaches 0.75 ÷ 0.8 of the pressure in front of the nozzle.

With increasing length of the cylindrical part, the vacuum in the compressed section decreases.

1. The maximum length of the cylindrical part of the nozzle e _CR , at which the vacuum does not form, is determined by the dependence:

,

,

where λ is the coefficient of resistance along the length.

ε is the compression ratio in a rarefied section.

2. The amount of radial holes taken from the calculation of the total cross-sectional area of the radial holes (F _holes) which is smaller than the difference of squares of diameters of the nozzle (F _cn) and jets compressed section (F _SJ)

F _resp <F _sp -F _Comp.

On the other hand, it was possible to process the holes with a cutting tool.

3. The distance of the hole from the sharp edge, equal to 0.5 jet diameter, is taken from the condition that the radial holes hit the center of compression of the jet cross section.

4. The diameter of the deflector adopted (2.5 ÷ 3) d _Art . Based on the recommendation of B. Lebedev "Sprinkling machines". M .: "Engineering", 1977, pp. 24-27, where the diameter of the deflector for short-jet nozzles is equal to 2 nozzle diameters.

In this case, the jet flows completely around the deflector. In our case, the jet does not flow around the deflector completely, but partially. The lower part of the deflector does not take part in the work of dissecting the jet. Therefore, structurally, the diameter of the deflector is recommended to take 2.5-3 diameter of the jet.

5. The depth of the grooves on the deflector has a significant effect on the following jet parameters: flight range, droplet size and uniformity of rain distribution. Considering that the torch of the deflector nozzles does not rotate, an increase in the depth of the groove, on the one hand, has a positive effect on the range of the jet, but, on the other hand, the uniformity of rain distribution worsens and the size of the drops increases. Therefore, we have adopted grooves with a depth of 0 to 1.5-2 mm.

According to these recommendations, prototypes were manufactured, which underwent laboratory tests.

In this case, the deflectors were made of three types: flat without grooves, flat with grooves, with grooving with jet displacement and without displacement.

The experiment showed that the nozzle made according to the described recommendations, in comparison with the nozzle made with a flat deflector and without sharp input edges, has agrotechnical indicators higher.

Rain trapping area is 10% higher. The size of the artificial rain drops is 12% smaller.

When tested with a working pressure of 10 m water. column break vacuum was not observed. Air suction was carried out stably.

From the theory of jets of sprinkling machines (B. Lebedev. "Sprinkling machines". M: Mashinostroitel, 1977, p. 79) it is known that the diameter of the droplet (d _k ) is determined by the following relationship:

,

,

where α is the surface tension coefficient of the drop;

ρ _air is the density of air;

C _x - aerodynamic coefficient of air resistance;

U _max - the maximum drop rate.

Analyzing the equation, we see that the surface drop stress coefficient α can be variable, because air appeared in the drop. Therefore, ceteris paribus, the droplet size will be smaller, its specific gravity will also be less.

The pressure exerted by a drop on the ground is determined below by the following relationship:

,

,

where P is the pressure exerted by a drop on the soil;

γ is the specific gravity of the drop;

q is the acceleration of gravity.

Analyzing the last equation, it can be noted that a drop filled with air will have a lower specific gravity. Thus, this nozzle will allow under other conditions (equal pressure and flow) to get smaller drops and reduce the energy of their impact on the soil.

Claims (1)

Ejector deflector nozzle, comprising a housing, a deflector made integral with the nozzle body and located at an angle of 30 ° relative to the axis of the jet, characterized in that the flow part of the nozzle body is made with a sudden narrowing, and the jet compresses the hole in the form of a cylindrical nozzle with a sharp inlet edge and a cylindrical part with a length of at least four jet diameters (d) with radial holes of 0.2 d at a distance of 0.5 d from a sharp edge, the deflector is made of a flat diameter (2.5 ÷ 3) d with triangular grooves at work whose surface of the deflector is of variable depth from 0 to 1.5-2 mm in increments equal to the depth of the groove on the outer diameter of the deflector, the grooves being located in the form of a fan with a 180 ° girth angle with a shifted center of the fan relative to the jet axis towards the compression hole at a distance d , and to lock the nozzle in the desired plane, a lock nut is used.

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