RU2315470C2 - Sprinkler head - Google Patents

Abstract

FIELD: farm crop irrigation equipment.

SUBSTANCE: sprinkler head had nozzle equipped with discharge opening closed with plate, three juxtaposed conical bowls positioned on said plate and having different angles of inclination of their generatrices. Pressure compensating mechanism fixed above upper conical bowl is formed as vertically mounted pin inserted into aperture provided through immovable holder equipped with bores and located on hollow tubular brackets. Lower part of vertical pin is provided with threaded portion onto which conical hollow deflector is threaded. Deflector has rigid base and conical guides made from plastic material. Corrugated hollow circular chamber positioned in axially aligned relation under holder is connected with its upper base to holder bores and with its lower base to conical hollow deflector. Wind compensating mechanism positioned on vertical pin is made in the form of two planks provided with flat petals-brattices and fixed perpendicular to pin. Vertical pin is joined to immovable holder through flat spiral spring. Sprinkler head of such construction allows constant flow rate and uniform droplet distribution to be maintained regardless of pressure value and wind speed.

EFFECT: improved irrigation quality, provision for avoiding of necessity for increasing irrigation time which might occur due to non-uniform irrigation, and reduced consumption of water.

3 dwg

Description

The invention relates to techniques for irrigation of crops.

A sprinkler nozzle is known, which consists of three perforated disks located coaxially to the nozzle, the middle of which is mounted movably and spring-loaded on the nozzle side, and which allows automatically maintaining a constant water flow rate when the pressure changes (copyright certificate No. 454875, A01G 25/00, published December 30, 74. Bulletin No. 48.).

The disadvantage is the significant unevenness of the distribution of water droplets, a low spray pattern, significant resistance to water movement, and the lack of the ability to control rain characteristics depending on wind speed.

Closest to the proposed invention (prototype) is a sprinkler nozzle, including a pressure pipe, a pressure compensating mechanism made in the form of a sealed chamber with a membrane and hollow brackets, as well as a membrane installed inside the sealed chamber (copyright certificate No. 1132860, A01G 25/00, published 01/07/85. Bulletin No. 1.).

The disadvantage is the inability to control the characteristics of the rain depending on the wind speed, as well as the inability to ensure dispersion of the spray.

An object of the invention is to increase the uniformity of the distribution of rain, as well as maintaining a constant flow rate and the independence of the quality indicators of rain with varying pressure and wind speed.

The task is achieved in a sprinkler nozzle, including a nozzle and hollow brackets, on which a pressure compensating mechanism is mounted, including a conical deflector and a chamber, where according to the invention the nozzle outlet is closed by a plate on which three conical cups are mounted on top of one another on the same axis with different diameters at the base of the bowls and made with different angles of inclination of the generatrix of the conical surface, the conical guides of the two lower bowls having smaller angles between the surfaces of the bowls and an horizontal plane than the angle between the conical surface of the upper bowl and the horizontal plane, as well as the conical deflector and the horizontal plane, the angles of which are equal to each other, while the pressure-compensating mechanism is mounted above the upper conical bowl and is made in the form of a vertical axis placed in a through step hole of the fixed the holder, made in the form of a cylinder with grooves located diametrically opposite to each other, and the cylinder is mounted on a hollow tubular bracket and the vertical axis has a thread in the lower part on which a hollow conical deflector is screwed with a rigid base and conical guides of plastic material on which through holes for drainage are made, and a chamber is arranged coaxially under the holder, which is made circular, corrugated and hollow inside and mounted under the holder so that its upper base is connected to the grooves of the holder, and the lower base is rigidly connected to the conical hollow deflector, while the outlet openings of the hollow corrugation The chambered chamber is in communication with the grooves in the rigid base of the hollow conical deflector; in addition, a wind compensation mechanism is installed on the vertical axis, made in the form of two strips with flat sail sails perpendicular to it and crosswise to each other, and the vertical axis connected to the fixed holder by means of a flat coil spring.

The novelty and originality lies in the fact that, unlike the prototype, the nozzle outlet is closed by a plate on which three conical cups are mounted one above the other on the same axis axially, while they are made with different angles of inclination of the generatrix of the conical surface, and the angle between the conical surface the upper bowl and the horizontal plane, as well as the conical deflector and the horizontal plane are equal to each other. This allows the conical deflector, descending along the vertical axis, to fit snugly against the upper conical bowl and bypass the entire water flow through the conical bowls located below, which have a smaller angle between the generators of the conical surface of the bowls and the horizontal plane, which allows to reduce the angle between the water jet and the horizontal plane and increases the range of the jet.

Above the upper conical bowl, a pressure compensating mechanism is installed, made in the form of a vertical axis, placed in a through step hole of a fixed holder, made in the form of a cylinder with grooves and mounted on hollow tubular brackets. In the lower part, the vertical axis has a thread on which a conical deflector is screwed, made hollow and which has a rigid base and conical guides of plastic material that can stretch when filled with water. An annular corrugated chamber is installed under the holder, hollow inside, communicating the grooves of the holder with the grooves of the conical hollow deflector. The conical guides of the hollow conical baffle made of plastic material have the ability to stretch when filling the cavity of the baffle with water and block the central hole in the plate, allowing you to maintain a constant flow rate.

A wind compensating mechanism is installed on the vertical axis, made in the form of two strips fixed to the top of the vertical axis perpendicular to it and crosswise to each other with flat sail petals, when the wind acts on them, the vertical axis starts to rotate, and the conical hollow deflector descends down the thread until it touches the upper conical bowl. Moreover, the vertical axis is connected to the fixed holder by means of a flat coil spring, which is twisted when the wind rises, and when it is lowered, it unwinds by rotating the axis in the opposite direction and returning the conical hollow deflector to its original position.

Figure 1 presents a General view of the nozzle with a longitudinal section; figure 2 is a section aa; figure 3 is a top view of figure 1.

The nozzle includes a cylindrical body 1 (Fig. 1), in the upper part of which a nozzle 2 is installed, having two internal longitudinal guide ribs 3, made opposite to each other and helping to reduce the vortex formation of water.

In the middle part, the cylindrical body 1 of the nozzle is made with two through grooves in which the lower ends of two hollow brackets in the form of half rings of brackets 4 located vertically and diametrically opposite to each other, as well as internal guide ribs 5, helping to reduce the vortex formation of water, are installed.

The upper outlet of the nozzle 2 is closed by a plate 6, on which three conical bowls 7, 8, 9 are mounted one above the other on the same axis axially and having a different diameter at the base of the bowls.

The plate 6, on which the bowls 7, 8, 9 are mounted, has a hole in the center in the form of a circle (Fig. 2), as well as four slots located opposite each other 10, 11, 12, 13, in the form of half rings, having thus maximum passage area of openings and located between the bases of the bowls, creating minimal water resistance and improving the distribution of speeds.

The conical bowls 7, 8, 9 are made with different angles of inclination of the generatrix of the conical surface, which makes it possible to evenly distribute water around the circumference and along the height of the spray jet, without creating significant resistance. Moreover, the conical guides of the two lower bowls 8 and 9 have smaller angles between the surfaces of the bowls and the horizontal plane than the angle between the conical surface of the upper bowl 7 and the horizontal plane, as well as the guides of the conical hollow deflector 14 and the horizontal plane, the angles of which are equal to each other.

Above the upper conical bowl 7, a pressure compensating mechanism is installed, which is a vertical axis 15 placed in a through step hole of the fixed holder 16. Moreover, the holder 16 is made in the form of a cylinder with internal grooves located diametrically opposite to each other, and installed in the upper part of the hollow tubular brackets 4 .

The vertical axis 15 has a thread in the lower part on which a conical hollow deflector 14 is screwed, having a rigid base and conical guides of plastic material, in which through holes for draining are made. Thus, the conical deflector 14 has the ability to move in the vertical direction while rotating the vertical axis 15.

An annular chamber 17, made corrugated and hollow inside, is installed coaxially under the fixed holder 16, it is installed in such a way that its upper base is connected to the grooves of the holder 16, and the lower base is rigidly connected to the conical hollow deflector 14. The outlet openings of the hollow corrugated chamber 17 are in communication with grooves in the rigid base of the hollow deflector 14, which allows water to be supplied from the sprinkler nozzle cavity through the hollow brackets 4, grooves in the holder body 16 into the hollow corrugated chamber 17, and from it into the cavity of the conical deflector 14. The conical guides of the hollow conical deflector 14 of plastic material have the ability to stretch when filling the cavity of the deflector 14 with water. The corrugated chamber 17 does not allow the conical deflector 14 to rotate together with the rotating vertical axis 15, and also has the ability to stretch when lowering the conical deflector 14.

A wind compensating mechanism is installed on the vertical axis 15, made in the form of two strips 18 (Fig. 3) fixed to the top of the vertical axis perpendicular to it and crosswise to each other with flat petals-sails 19, which receive wind pressure and transmit rotation to the axis 15. Moreover, the vertical axis 15 is connected to the fixed holder 16 by means of a flat coil spring 20, which, when the wind rises, is twisted, and when it is lowered, it is untwisted by rotating the axis 15 in the opposite direction.

Thus, the conical hollow deflector 14 when exposed to wind on the petals of the sail 19 and the rotation of the vertical axis 15 has the ability to fall on the thread and fit snugly to the upper conical bowl 7, blocking the outlet with a water stream through the hole in the center of the plate 6, on which the conical bowls are mounted 7, 8, 9, i.e. in the case of strong wind, it bypasses the entire flow of water through the conical bowls 8 and 9 below, which reduces the angle between the water jet and the horizontal axis and increases the range of the jet. In the case of increasing pressure, the water entering the cavity of the conical hollow deflector 14 stretches the conical guides made of plastic material, overlaps the central hole in the plate 6, allowing to maintain a constant flow rate.

The nozzle works as follows. Water from the pipeline enters the housing 1, then enters the nozzle 2, where, passing along the guide ribs 3 becomes ordered.

Passing further through the perforated holes of the plate 6, water is evenly distributed between the bowls 7, 8, 9 and the conical hollow deflector 14 and enters outward with a uniform torch.

When the wind speed exceeds the nominal irrigation mode, the force of the wind pressure acts on the petals-sails 19, turning the vertical axis 15, the thread of which the conical hollow deflector 14 moves downward, twisting the flat spiral spring 20. Having lowered, the conical hollow deflector 14 is adjacent to the upper conical bowl 7, covers the central hole in the plate 6, forcing all the water to pass through the annular slots 10, 11, 12, 13 and further between the surfaces of the conical bowls 7, 8, 9. Since the conical guides are two x the lower bowls 8 and 9 have smaller angles between the surfaces of the bowls and the horizontal plane than the angle between the conical surface of the upper bowls 7 and the horizontal plane, as well as the conical hollow deflector 14 and the horizontal plane, the angle between the water jet and the horizontal plane decreases, which means spraying distance increases in the wind direction. The corrugated chamber 17, stretching, does not interfere with the lowering of the conical hollow deflector 14.

After the termination of the action of the wind, the flat spiral spring 20, spinning, causes the vertical axis 15 to rotate in the opposite direction. On the threaded connection of the vertical axis 15, the conical hollow deflector 14 rises vertically up to its original position.

Thus, there is an automatic change in the angle of departure of the jet, and hence the range of water supply, depending on the wind speed.

In case of excess pressure in the pipeline, part of the water from the cylindrical body 1 of the nozzle under pressure rises along the semicircular hollow brackets 4 and flows through the grooves in the fixed holder 16 into the corrugated chamber 17, from which into the cavity of the hollow conical deflector 14, stretching conical guides made of elastic material. Since the drain holes in the conical hollow baffle 14 have a small throughput, the pressure in the cavity of the conical hollow baffle 14 increases. Thus, the conical guides of the conical hollow deflector 14 are pressed against the upper conical bowl 7 and block the hole in the plate 6, and the drain holes in the conical hollow deflector 14 are closed and do not cause significant leaks.

When the pressure drops, water ceases to be supplied through the hollow brackets 4 into the corrugated chamber 17 and further into the cavity of the conical hollow deflector 14. Conical guides made of elastic material return to their original position, opening drain holes through which residual water is removed.

Thus, a constant flow rate is ensured when the pressure in the pipeline changes.

The proposed constructive solution allows, regardless of the pressure and wind speed, to maintain a constant flow rate and uniform distribution of rain drops, which improves the quality of irrigation, eliminates the need to increase irrigation time due to irregularity of irrigation, and reduces water consumption.

Claims (1)

Sprinkler nozzle, including a nozzle and hollow brackets, on which a pressure compensating mechanism is mounted, including a conical deflector and a chamber, characterized in that the nozzle outlet is closed by a plate on which three conical cups are mounted on top of one another on the same axis, with different diameters in the base bowls and made with different angles of inclination of the generatrix of the conical surface, and the conical guides of the two lower bowls have smaller angles between the surfaces of the bowls and the horizontal plane, h m the angle between the conical surface of the upper bowl and the horizontal plane, as well as the conical deflector and the horizontal plane, the angles of which are equal to each other, while the pressure compensating mechanism is mounted above the upper conical bowl and made in the form of a vertical axis placed in the through step hole of the fixed holder, made in the form of a cylinder with grooves located diametrically opposite to each other, and the cylinder is mounted on hollow tubular brackets, and the vertical axis has t in the lower part is a thread on which a hollow conical deflector is screwed with a rigid base and conical guides of plastic material, on which through holes for drainage are made, and a chamber is arranged coaxially under the holder, which is made annular, corrugated and hollow inside and installed under the holder such so that its upper base is connected to the grooves of the holder, and the lower base is rigidly connected to a conical hollow deflector, while the outlet openings of the hollow corrugated chamber are communicated s with grooves in the rigid base of the hollow conical deflector, in addition, a wind compensation mechanism is installed on the vertical axis, made in the form of two slats with flat sail sails fixed perpendicular to it and crosswise to each other, and the vertical axis is connected to the fixed holder by means of a flat coil spring.

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