RU2611719C1 - Sprinkling machine for studying free-flow water conductivity of soils - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: sprinkling machine is made in the form of plow beams of tubes with holes. Holes are drilled at an angle to each other and placed upwards so that the jets of water in the air collide and partly break into droplets. Eventually, the stream energy is extinguished in the deflector. The deflector is made in the form of an inverted upside-down dripping pan with borders. The deflector is installed coaxially above the sprinkling machine. The distance between the sprinkling machine and deflector is adjusted by the threaded bolts and lock nuts. Sprinkling machine and a deflector are mounted on the water-conducting pipeline. The pipeline has a view of a two-arm lever with equal moments of force and fixed to the support of the coaxial tubes. The support is provided with a base and anchors.

EFFECT: providing accurate accounting of artificial rain precipitation over a wide range of regulatory structures, rain intensity, droplets size and their kinetic energy.

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Description

The invention relates to agriculture, land reclamation and can be used for laboratory and field experiments to study pressure-free water permeability of soils with different structure, rain intensity, grain size and energy of falling drops.

Several sprinkler designs are known for determining the pressure-free permeability of soils in the field.

In non-irrigated farms S.V. Astapov proposes to conduct experiments on the study of the rate of absorption of rain into the soil using a tank of water specially mounted at a height of 1.0 m, equipped with a wide drain pipe with a sprinkler nozzle at the end in the form of a watering can (Dolgov S.I. Agrophysical methods for studying soils. - M .: Nauka, 1966. - S. 78).

Yerkhov I.S. offers a sprinkler to determine the pressure-free water permeability of soils and the permissible rain intensity, which consists of a riser on a tripod, two or three sprinkling short-jet deflector nozzles of simultaneous action with diaphragms with a diameter of 4-5 mm (Erkhov I.S. soil during irrigation irrigation. - M.: Science, Soil Science, 1975, No. 9. - S. 94-100).

Ivonin V.M. To conduct experiments on studying the water permeability of soils and runoff during heavy rains, it is recommended to use a mobile drip and jet spray sprinkler installation consisting of a water tank mounted on a metal support, a hose with a valve supplying water to the sprinkler in the form of a frame with a water outlet, supports for him, metal shields enclosing the experimental site, tray and runoff water intake. (Ivonin V.M., Terteryan V.A., Vodyanoy S.M. Soil erosion on clearings of mountain slopes / Ed. By V.M. Ivonin. - Rostov-on-Don: Publishing House SKNTs VSh, 2001. - S. 38, 139-143).

For studies of pressure-free filtration of soils and runoff Kulik V.Ya. offers a special installation with variable rain intensity and refers to 18 titles of scientific literature, where sprinkler devices are described and research is carried out. (Kulik V.Ya. Water infiltration into the soil: A quick reference. - M .: Kolos, 1978. - P. 12-13).

Mini-sprinklers of various designs and methods of their use in agriculture are described in “Inventions Abroad” No. 3, MKI A01G 25/00, No. 2142262, No. 17, MKI A01G 25/00, No. 2166730. France 1973. All of the above sprinklers have a very narrow range of applications, they cannot accurately reproduce the rain structure inherent in various sprinklers and simulate the size and energy of falling drops.

The closest technical solution is a portable installation for determining the water permeability of soils in the field (irrigation method on small areas by Prof. Tanner), which consists of a water pump, a pipeline with a sprinkler, a manometer and a spray, a fence such as a screen, a metal square enclosing the soil registration area , a spillway from the registration square, a closed water intake of a runoff, a registrar of the volume of flowing water (Kachinsky AN Soil Physics. Part 2. Water-physical properties of soils. - M .: Higher School, 1970, - P. 43-45.) .

The disadvantages of this portable installation for determining water-free permeability of soils by sprinkling small areas is the inability to control the intensity of rain, droplet size and their energy, typical for sprinkling machines currently in use, as well as the difficulty of accounting for precipitation that goes not only to the registration site, but also to the adjacent site and runoff.

The technical result achieved by the invention is the creation of a sprinkler design for studying pressure-free water permeability of soils with a wide range of regulation of the structure of rain intensity, droplet size and their kinetic energy, providing coverage of the entire spectrum of irrigation irrigation technology elements, all existing irrigation machines, plants, apparatuses and accurate metering precipitation of artificial rain, which went on non-pressure absorption of water into the soil.

This technical result is achieved by the fact that the sprinkler is made in the form of a barrage of tubes with holes drilled at an angle to each other and oriented upwards so that in flight the water jets collide and partially collapse into droplets, but finally the energy of the jets is extinguished in the form of an inverted upside down pan with sides mounted coaxially above the sprinkler, the distance between the sprinkler and the reflector is regulated by threaded guides, nuts and locknuts, and the sprinkler and reflector are mounted anes in the water-conduit in the form of a two-arm lever with equal moments of forces, fastened on a support of kooksialno spaced tubes, with a base and anchors, which provide the possibility of changing the distance between the sprinkler and the soil structure and stability in space.

In FIG. 1 shows a sprinkler for studying pressure-free water permeability of soils, a general view; in FIG. 2 - a row of tubes with holes and a reflector, detailing the layout, in FIG. 3 - construction of a row of tubules with holes.

The sprinkler for studying pressure-free water permeability of soils consists of a hollow stand 1, welded to the base 2 with anchors 3, a movable stand 4, a retainer 5, a water pipe 6, a fastener 7, a coupling 8, a sprinkler 9 in the form of a grill from tubes, a distribution tube 10, reflector 11 in the form of a baking sheet turned upside down with rails 12, threaded guides 12, nuts 13, lock nuts 14, holes 15 and 16 made at an angle to each other, with trickles of water flying out, artificial rain torch 17, water source 18, pump 19 walked nga 20, valve 21, water meter 22 and plates with holes 23.

Sprinkler for studying pressure-free water permeability of soils works as follows.

Before the start of the experiment on the study of free water permeability of soils, the sprinkler is calibrated in the same field where the studies are planned. The site for calibration and study of pressure-free water permeability of soils is chosen on a site typical for this field according to the topography, granulometric composition, water-physical properties of soils and the presence of a water source. To carry out calibration, a sprinkler is installed on a selected site closer to the source of water 18. Moreover, the source of water 18 can be a water supply system, a closed irrigation network, an open irrigation canal, a lake, a pond, a river or a tank mobile in transport. Installation of the sprinkler begins with the installation of a hollow post 1, welded to the base 2 with anchors 3, which are pressed into the soil of the platform with their feet. After making sure that the hollow column 1 is securely fixed and the vertical position is inserted, a movable column 4 is inserted into it, which is fixed with a latch 5. A water pipe 6 is fixed to the movable part of the column 4 using a fastening 7. The height of the water pipe 6 depends on the design parameters of the sprinkler machines designed or acting on the field, and is regulated by the movement of the movable stand 4 relative to the hollow stand and its fixation at the desired height using the latch 5. In addition, the water pipe 6 can move along the movable stand 4 with holes and fixed with a fastener 7. A sprinkler 9 in the form of a row of water from tubes with holes 15 and 16 and a distribution pipe 10 is connected to one of the shoulders of the water supply pipe 6 by a coupling 8. Above the sprinkler 9, in the form of a row of water from pipes, the reflector 12 is fixed, in the form of a baking sheet with the sides turned upside down, which is attached to the sprinkler with threaded guides 12 passing through the plates with holes 23, nuts 13 and locknuts 14. To the second arm of the water supply about the pipeline 6, the water sensor 22, the valve 21, the hose 20, the pump 19, which is immersed in the water source 18, are sequentially mounted. For the spatial stability of the whole structure, the water pipe 6, loosening the fastener 7, are moved left or right, achieving equal left-hand moments M1 = Q1 * L, and the right M2 = Q2 * L of the shoulders, after which the water supply pipe is finally fixed 6. After the sprinkler structure is mounted and installed at the required height from the soil surface, its calibration begins, as a result of which ivayutsya corresponding parameters of rain intensity, droplet size and energy. Pump 19 begins to supply water from a water source 18 through a hose 20, through an open valve 21, a water meter 22, a water supply pipe 6, a distribution pipe 10, and into the bed 9 of the pipes. With the corresponding pressure in the entire system, water begins to fly out of the holes 15 and 16 in the form of streams directed upward at an angle to each other. In case of collisions with each other, the trickles partially disintegrate into droplets, but the energy of the trickles is finally extinguished when they collide with the reflector 11, in the form of a baking sheet with the sides turned upside down, after which precipitation falls with an artificial rain torch 17. Average intensity ρ, mm / min of precipitation of the artificial rain torch 17 is controlled by valve 5, changing the pressure and water supply, and is determined as the quotient of dividing the volume of water supplied V, l by the irrigation area S, m ² during t, min:

ρ _cp = V / S * t, mm / min.

For various sprinkling machines, plants and apparatuses, the average rain intensity is in the range from ρ _avg = 0.1 mm / min to ρ _avg = 0.5 mm / min. The sprinkler design for studying pressure-free water permeability of soils allows reproducing, due to regulation, any rain intensity in the range from 0.1 mm / min to 0.5 mm / min. The duration of non-pressure filtration is influenced not only by the intensity of the rain, but also by the size of the raindrops, their diameter, d, mm. The size of rain drops in various sprinklers and plants can vary from 0.2-0.5 mm to 1.5-2.0 mm, which affects the duration of pressureless absorption of water into the soil during sprinkling. With an increase in the diameter of rain drops, the time of pressureless water permeability of soils and the value of the irrigation norm before the formation of puddles decreases. That is, there is an inversely proportional relationship between the duration of pressureless water permeability of soils, the intensity of rain, and the size of the droplets. The same relationship is observed between the value of the irrigation rate before the formation of puddles and the intensity of rain and the size of the drops. The sprinkler for studying the pressure-free water permeability of soils during sprinkling allows you to adjust the size of the droplets in the range from 0.2 to 2.0 mm by changing the distance between the bed 9 of the tubes and the reflector 11 using guides with thread 12, nuts 13 and locknuts 14. The energy of the falling raindrops is regulated by changing the height of the bed 9 from the tubes and the reflector 11 relative to the soil surface, which is changed by pulling the movable stand 4 from the hollow stand 1 and fixing it with a latch 5.

In addition, the height of the ridge 9 from the tubes can be changed by moving the water supply pipe 6 relative to the movable stand 4 and fixing it with a fastening 7. The size of the raindrops is determined by the well-known method from their fingerprints on desalinated paper filters with a diameter of 9 cm, previously rubbed with ink powder using a cotton swab. The energy E _k (ERG, j, kgm) of the falling raindrop, conditionally taking its shape as a ball, is calculated by the formula:

,

,

where r is the average radius of the droplet in the form of a ball, measured with filter paper; ρ is the density of water equal to 1; m is the mass of the drop; g - acceleration of gravity 9.8 m / s ² . In the technical system of units, the unit of energy is 1 kgm = 1 kg * 1 m = 9.81 j.

Having finished all work on the calibration of the sprinkler, we proceed to conduct experiments (determining the water permeability of the soil during irrigation with a specific sprinkler machine or installation).

To this end, the calibrated sprinkler, having previously switched off the pump, is transferred to the experimental site and installed by the method described above, without violating the calibration parameters. An experimental site should be prepared for the experiment. It must be plowed or have a sown, vegetative crop. Before the start of the experiment, soil samples are taken at a moisture content of 10 cm to a depth of one meter, a few meters (2-3 m) from the experimental site. After installing the sprinkler and sampling to determine the soil moisture, an experiment is started by turning on the pump 19 lowered into the water source 18. The time of the beginning of the first drops of the artificial rain 17 torch falling onto the soil surface is recorded in the log. During the experiment, the time of the beginning of the formation of puddles on the experimental sprinkling site and the time of formation of the surface water flow (the formation of streams on the experimental site, i.e. the connection of individual puddles with streams) are noted. The time interval t from the start of deposition _sn first droplet t _n artificial rain torch 17 prior to the formation of puddles on the experimental site _L t is the period when the average of rain intensity ρ _cp corresponds pressureless soil permeability K _sn at a sprinkling, _sn t = t _l -t _n , min and ρ _sr = K _vp , mm / min.

Therefore, taking into account the above, the average pressure-free water permeability of soils during sprinkling from the beginning of the experiment to the formation of puddles will be equal to:

K _VP = V / S * t _VP , mm / min.

The time interval t _g from t _n — the beginning of the first drops of the artificial rain torch 17 before the formation of runoff at the test site t _article , the formation of streams between puddles — corresponds to the time of issuing the permissible irrigation rate m _add , mm or m ³ / ha with the corresponding average rain intensity ρ _avg The value of the permissible irrigation rate will be equal to:

m _add = V / S, mm.

To exclude accidental errors, experiments on studying water-free permeability of soils during irrigation irrigation must be carried out with the appropriate rain structure, at least three times in a specific field and at the chosen experimental site. The experiments are usually carried out on a plowed and already sown field or during the growing season of plants. It is during the growing season that crops need irrigation with various sprinklers, which helps to increase their productivity.

Claims (1)

A sprinkler for studying pressure-free water permeability of soils, including a water source with a pump, a pipeline with a sprinkler, a manometer and a water sprayer, characterized in that the sprinkler is made in the form of ridges of tubes with holes drilled at an angle to each other and oriented upwards so that in flight trickles of water collide and partially collapse into droplets, but finally the trickle energy is extinguished in the reflector in the form of a baking sheet with the sides turned upside down, mounted coaxially above the sprinkler, the distance The sprinkler and the reflector are regulated by threaded guides, nuts and locknuts, and the sprinkler and reflector are mounted on the drain pipe in the form of a two-arm lever with equal moments of force, mounted on a support from pipes coaxially located in each other with the base and anchors, which provide the possibility of changing the distance between the sprinkler and the soil and the stability of the structure in space.

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