RU2576194C1 - Dropper - Google Patents

Abstract

FIELD: medical equipment.

SUBSTANCE: invention relates to devices for drip irrigation. Dropper includes an outlet hole, a housing with a control cavity and tubular porous soft element. In dropper housing part of tubular branch pipe is arranged in control chamber and is equipped with two diametrically opposite longitudinal holes covered inside tubular porous element with flow channel. Inlet part of tubular branch pipe is plugged and is made in form of conical head and supports attached to inner side wall of branch pipe cross-section is made in form of conical unclosed short pipes with flexible plates in form of blades along perimeter and fixed clamps below ends of tubular porous element with flow channel.

EFFECT: technical result is improved reliability.

3 cl, 1 dwg

Description

The invention relates to agricultural reclamation, and in particular to devices for drip irrigation, and can be used for irrigation of crops.

Known dropper mounted across the irrigation pipe and containing a movable nozzle and coaxially connected with it a tubular porous soft element, the second end of which is fixed inside the irrigation pipe, in which, in order to increase the efficiency of the work, the movable nozzle is equipped with a perforated tube coaxially installed in it, one end fixed in it the hole of the pipeline, while the porous elastic element is mounted on a perforated tube with the possibility of changing its cross section by means of manure pipe; equipped with a position lock for the movable pipe (Copyright Certificate SU No. 1516061, class A01G 25/02 of 10.23.1989).

The disadvantages of the described dropper as applied to the problem being solved include clogging of the porous element and the perforated pipe with algae and microorganisms due to the presence of water in the irrigation pipe after the pump unit has been supplied, a high degree of irregularity of the irrigation norms at water pressure drops, and a high degree of water purification by filters.

The closest analogue to the claimed object includes a dropper containing an outlet, a housing with a perforated tube coaxially mounted therein and a tubular porous soft element, the latter is made of gas-filled plastic, the tubular porous element is multilayer, each of the layers of which is separated by a perforated tube, the permeability of each layer the porous element is reduced in the peripheral direction, while in the cavity of the tubular porous element of the smallest diameter is placed the float, and the outlet has a shutoff valve (patent RU No. 2280355, class A01G 25/02 of 07.27.2006).

The disadvantages of the dropper are the high complexity of the design due to the presence of a large number of filters and perforated tubes built into the housing and providing cleaning of the device. The presence of these elements leads to low operation and high cost. Another disadvantage is the presence of a stagnant zone inside the tubular porous element, which causes clogging and siltation of micropores with small particles of other residues in the water, which dramatically reduces the flow through them. In addition, due to the roughness of the inner walls of the tubular porous element, the movement of the float (ball) is difficult up and down; washing the dropper is difficult in general.

As a result of the search, technical means of drip irrigation were found, copyright certificates: SU No. 1416083, class. A01G 25/02 of 08/15/1988, SU No. 1468474, class. A01G 25/02 of 03.30.1989, SU No. 1501981, class. A01G 25/02 of 08.23.1989, as well as patents: RU No. 2283582, cl. A01G 25/02 of 04/13/2005, RU No. 2314678, class. A01G 25/02 of 01.20.2008, RU No. 2238109, cl. A01G 25/02 of 07/10/2008, RU No. 2337527, cl. A01G 25/02 of 11/10/2008.

However, a disadvantage of the known technical solutions is that they have low operational reliability due to the insecurity of the filtering porous elements from clogging and siltation of micropores with floating impurities, and the need for accurate mutual alignment with the walls of the irrigation pipeline, as well as the complexity of installation.

EFFECT: increased reliability by reducing the possibility of clogging and lowering the cost of a dropper.

The technical result is achieved by the fact that a dropper containing an outlet, a housing, a tubular porous soft element, in a dropper housing with a control cavity, a part of the tubular pipe is placed in the control chamber and is provided with two diametrically located longitudinal holes overlapped inside by a tubular porous element with a flow channel, this inlet of the tubular pipe is muffled and made in the form of a conical head and stops with bevels attached to the inner side wall of the pipe, the cross section of which is made in the form of conical open short pipes, overlapped by flexible plates in the form of petals around the perimeter and secured with clamps below the ends of the tubular porous element with a flow channel.

In addition, the length of the longitudinal holes is larger than the diameter of the outlet of the nozzle, and the total area bounded by the longitudinal holes is greater than the area of the part remaining between the longitudinal holes of the side surface of the nozzle.

In addition, the outer surface of the pipe is made in the form of an annular, covering it with a strainer, the edges of which are fixed on the outer side surfaces of the ends of the pipe.

This dropper design is characterized in that:

- the dropper is made with a control cavity and the tubular pipe is placed in the control chamber, which eliminates the clogging of the tubular porous element with a flow channel;

- the inlet end of the tubular nozzle is plugged and made in the form of a conical head towards the inlet of the irrigation pipe;

- the pipe is made with two longitudinal holes overlapped on the inner side by the walls of the tubular porous element;

- the conical head on the side of the mounting of the tubular porous element, like the wall of the outlet of the tube, have stops with bevels attached from the outer wall of the short pipes and made in the form of conical open pipes, overlapped by flexible plates (or elastic material) in the form of petals around the perimeter, fixed with clamps with the ends of the porous element.

The ratios of the dropper length and its transverse size (height) make it possible to carry out the dropper with an appropriate narrow cross-sectional area and flow rate entering through the flow channel in the porous element, the flow rate of which is constant for a given dropper, which, subject to other conditions (equal), depends on the elastic properties all proposed elements that respond to a change in flow rate in the dropper body, i.e. from changes in pressure H in the irrigation pipe.

To expand the range of changes in water flow, dropper sections can be changed by installing a set of such devices in the body cavity with different sizes of the nozzle itself.

For a better fit (compression) of the walls of the tubular porous element to each other to the flow channel and water outlet to the ends of the pipe, stops with bevels with flexible plates in the form of petals around the perimeter, fixed by clamps, are additionally attached to the ends inside the pipe.

It should be noted that the flow channel in the tubular porous element is a variable and, as a result, when the pressure H in the irrigation pipe changes, the gap of the flow channel changes, despite the throughput of the porous element, which also changes when it is compressed to the center of the flow channel, those. there is a process of throttling the flow. The pressure from above depends on the ratio of the length of the longitudinal holes and the diameter of the nozzle coming into contact with the walls of the flow channel in the porous cylindrical element.

The invention is illustrated in the drawing, which schematically shows a section along the axis of the pipeline with a dropper.

The dropper contains a housing 1 with a control cavity 2 connected through an inlet 3 with an irrigation pipe 4. A cavity 2 is connected with a nozzle 5, and through an outlet 6 with an exhaust pipe 7. The nozzle 5 in the middle part, located in the control cavity 2, has two diametrically located holes 8 and 9, and the flow channel 10 in the porous elastic element 11 is placed inside the pipe 5. The front of the pipe 5 is muffled and made in the form of a conical head 12. The stops 13 and 14 with bevels 15 and 16 are attached to the side of the pipe’s inner wall and 5, the cross section of the short nozzles 17 and 18 is made in the form of cones overlapped by flexible plates 19 in the form of petals around the perimeter, i.e. made in the form of wrapping a porous flexible element 10 on the outer side surfaces of the ends with short nozzles 17 and 18 with the help of clamps 20. The dotted lines show the holes 8 and 9 in the nozzle 5. The housing 1 with the nozzle 5 and the tube 7 is threaded with a removable cover 21 and fixed with an adjusting nut 22. The length of the longitudinal holes 8 and 9 is greater than the diameter of the nozzle 5, and the total area bounded by the holes 8 and 9 is greater than the area of the part remaining between the longitudinal holes of the side surface of the nozzle 5. Cross section along the lengths e pipe 5 from the outer side is made annular, covering it with a strainer 23, the edges of which are fixed with clamps 24 in the housing 1.

The execution of the housing 1, the threaded cover 21, the nozzle 5 with longitudinal holes 7 and 8, the tubular porous element 11 with a flow channel 10, a mesh cylinder filter 23 and other elements, provide for installation and operation the suitability of a dropper from commercially available parts, for example, based on the widespread use of polymeric materials that do not contain corrosive during operation.

A dropper works as follows.

From the irrigation pipe 4 of the drip irrigation system, water under pressure through the opening 3 enters the control cavity 2. Water enters through the cylindrical strainer 23, then through the longitudinal openings 8 and 9 into the nozzle 5. Under the influence of water pressure, air is first displaced through the micropores, filling all the volume of the tubular porous elastic element 11 with a flow channel 10. Suspensions and litter due to the presence of a cylindrical mesh filter 23 settle on top of it, which prevents clogging of the dropper, reliability is achieved l her work. Thus purified water enters the flow channel 10 of the tubular porous elastic element 11. When the static water pressure increases in the control cavity 2, the working area of the cylindrical porous element 11 changes when it is compressed from all sides inside the pipe 5 (working chamber). Thus, a narrowing of the cylindrical porous element 11 occurs, and the potential energy (static pressure) of the flow acts on the effective cylindrical area enclosed inside the pipe 5 with the porous element 11, and compresses it, setting the required flow rate of water entering the opening 6 of the exhaust pipe 7. The rate of flow of water (liquid) through the micropores of the porous element 11 depends on the ratio of the sizes of the longitudinal holes in the nozzle and the compression position of the porous element 11 with the flow channel 10 and is selected in such a way azom as to provide rapid reduction in water pressure along the pipeline, keeping the seepage of water through the micropores in the form of droplets. This process occurs simultaneously on all droppers of the drip irrigation system, as a result of which pressure is stabilized along the length of the pipeline. Therefore, the set water flow rate for plants in all droppers is automatically maintained.

With increasing or decreasing water pressure in the control cavity 2 of the housing 1, the porous element 11, respectively, to a greater or lesser extent automatically overlaps the cross section of the flow channel 10, while maintaining data on the flow characteristics of the dropper. In addition, the water flow passing through the inlet 3 is quenched by means of a plug made in the form of a conical head 12, fixed to the pipe 5 from the side of the irrigation pipe 4. In this case, the bevels 15 and 16 with the stops 13 and 14, the short pipes 17 and 18 provide such a compression position of the tubular porous element 11 such that upon contact of its ends a smooth deformation of the porous element 11 occurs along its entire length inside the pipe 5, i.e. together it is pressed and fixed with the help of clamps 20. Such fastening eliminates accidental separation from the walls of the short nozzles 17 and 18 during compression of the porous element 11, i.e. smoothly bends around short pipes in cross section. Due to the presence of flexible plates 19 made in the form of petals around the perimeter below the ends of the porous element 11 also fastened with clamps 20, a stable initial position of the porous element 11 is ensured with the reduction or shutdown of water in the irrigation pipe 4, as a result of which the flow channel 10 in the porous element 11 the cross section is increased to discharge water through the opening 6 of the inlet tube 7. Thus, it depends, under other conditions (equal), of the plates 19 made in the form of petals.

To expand the limits of changes in the cross section of the pipe 5 (working chamber) and flow modules can be changed by installing other such devices in the control cavity 2 of the housing 1 with a different volume of the tubular porous element 11 with a flow channel 10. The pressure from above depends on the ratio of the lengths of the openings 8 and 9 and the diameter of the pipe 5, as well as the cross-sectional area of these holes.

When the water supply is turned off, the pressure in the control cavity 2 also gradually decreases, as a result of the flexible plates 19 in the form of petals, the tubular porous element 11 returns to its original position and the micropores also take their initial position.

The described dropper will provide increased reliability by reducing the possibility of clogging and lowering the cost in drip irrigation systems.

Claims (3)

1. A dropper containing an outlet, a body, a tubular porous soft element, characterized in that in the dropper body with a control cavity, a part of the tubular nozzle is placed in the control chamber and provided with two diametrically arranged longitudinal holes overlapped inside by a tubular porous element with a flow channel, this inlet of the tubular pipe is muffled and made in the form of a conical head and stops with bevels attached to the inner side wall of the pipe, the cross section to oryh designed as a conical nozzle unclosed short, overlapping flexible plate in the form of petals and fixed along the perimeter with clamps below the ends of the tubular porous member with the flow channel. 2. A dropper according to claim 1, characterized in that the length of the longitudinal holes is larger than the diameter of the outlet of the nozzle, and the total area bounded by the longitudinal holes is larger than the area of the part of the side surface of the pipe remaining between the longitudinal holes. 3. A dropper according to claim 1, characterized in that the outer surface of the nozzle is made in the form of an annular, covering it with a strainer, the edges of which are fixed on the outer side surfaces of the ends of the nozzle.

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