RU159390U1 - DEVICE FOR DOMESTIC IRRIGATION - Google Patents

Abstract

1. An intra-soil irrigation device, including a supply pipe hydraulically connected to a perforated humidifier, made long enough to reach the upper boundary of the soil layer, characterized in that the perforated humidifier is made in the form of a cylindrical cup with a lid perforated in the central part and equipped with a dirt trap, located under the lid and made in the form of an inverted cone perforated around the periphery, the inlet pipe is equipped with a vortex hydroaerator, p a hollow cylinder with a float rigidly connected to the plug, the parameters of which correspond to the parameters of the inner hole of the tangential nozzle of the vortex hydroerator, coaxially located under the dirt trap, and under the vortex hydroaerator, the lower part of the cylinder communicates with the valve module, which includes a valve channel and a valve connected to a float located outside the valve channel. 2. The device according to claim 1, characterized in that the perforation is made on half of the side surface of the cylindrical glass. The device according to claim 1, characterized in that the perforation is made along the entire lateral surface of the cylindrical glass.

Description

The utility model relates to irrigation and irrigation systems in agriculture, in particular to irrigation and drainage, and can be used for irrigation of perennial plantations on steppe and slope lands.

There are known drip irrigation systems (RMS) used in foothill areas on large slopes (δ≈0.3), in areas with inadequate water supply, in areas with rugged terrain, light soils, soils subject to water erosion, and also where there are sparse sources of clean water (Reclamation systems and facilities (allowance for SNIP 2.06.03-85) Drip irrigation: Moscow. 1986, VO O Soyuzvodproekt). These drip irrigation systems include water intake facilities, pressure-generating units (pump station), irrigation automation units, filters, water metering equipment, fertilizer mixing and dosing devices, distribution and irrigation piping networks, droppers, etc.

The disadvantage of these systems is the high investment for construction and large human resources, high demands on the quality of irrigation water, which is associated with the costs of its treatment, on the one hand, and the loss of fertile silt sediment of mountain rivers, on the other.

A known system of subsurface focal irrigation, which includes a main canal or water conduit, distribution and irrigation irrigation with a plug at the end of pipelines, focal humidifiers from perforated tubes in the root zone, water-measuring equipment, a device for mixing and dosing fertilizers, while the distribution pipeline is equipped with graduated taps water flow, the irrigation pipe is formed by pieces of flexible tubes connecting the humidifiers in series, and has a bias towards the end of Yes, plantings, humidifiers are made of open polyethylene pipes with a length of at least 600 mm with two outlets at a level of 200 mm from the upper end with the flexible pipes connected to the latter to receive irrigation water from the water intake, freely installed above the planting horizontal and connected to taps and having perforation at the lower end with a hole diameter of 2-3 mm. In addition, the water intake is a quencher of water pressure from the distribution pipeline, provides a direction to both sides of it along a number of landings and creates the necessary pressure in the irrigation pipeline, and the humidifiers are deepened into the soil with a rod equipped with a conical tip, a handle and a stop and inserted inside them open tubes with the possibility of its removal (Pat. 2337528 RF, IPC A01G 25/06, 10.11.2008).

The disadvantage of this system is the complexity of the design and assembly, the lack of aeration mode and direct focus on the irrigation object. Application of the system is focused mainly on mountainous and hilly terrain.

A device for local subsoil irrigation of plants containing a humidifier and an independent source of water supply, characterized in that the humidifier is made in the form of a glass with a perforated portion covered by hydrophilic material in its lower part, and an autonomous source of water supply is made in the form of a vessel with a narrow throat and plug equipped with a slot, the dimensions of which satisfy the following ratios (Pat. 2214088 RF, IPC A01G 25/06, 01/01/2002).

The disadvantage of this device is the lack of automation of irrigation and the complexity of the replenishment of the liquid used autonomous devices, the absence of aeration regime of irrigation.

Closest to the claimed utility model is a subsoil irrigation system including a unit for preparing vaporous moisture in the volume of compressed air, supply pipelines hydraulically connected to a network of subsoil perforated humidifiers, while the subsoil perforated humidifiers are made long enough to reach the upper boundary of the soil layer with established moisture , and the area of the holes of the perforation of the humidifier increases from top to bottom, providing moistening of the vertical cone different volume of soil around the humidifier to lower its expansion (US Pat. 2,259,709 of the Russian Federation, the IPC A01G 25/06, 15.12.2003).

The disadvantage of this system is its complexity, due to the presence of additional equipment for supplying compressed air and aeration of the irrigation fluid.

The task is to expand the technical means of irrigation and irrigation using aerated systems.

The technical result of the application of the utility model is to improve the quality and effectiveness of subsoil irrigation of perennial crops.

The technical result is achieved by the fact that the subsoil irrigation device, including the supply pipe, is hydraulically connected to a perforated humidifier, made long enough to reach the upper boundary of the soil layer, while the perforated humidifier is made in the form of a cylindrical glass with a cover perforated in the central part, and equipped with a dirt trap located under the cover and made in the form of an inverted cone perforated around the periphery, the wire is equipped with a vortex hydraulic aerator located under the dirt trap, and a hollow cylinder coaxially mounted under the vortex hydraulic aerator with a float rigidly connected to the plug, the parameters of which correspond to the parameters of the internal opening of the tangential nozzle of the vortex hydraulic aerator, while the lower part of the cylinder communicates with the valve module, which includes a valve channel and a valve connected to a float located outside the valve channel.

The subsoil irrigation device is characterized in that the perforation is made on half of the lateral surface of the cylindrical glass.

The subsoil irrigation device is characterized in that the perforation is made over the entire lateral surface of the cylindrical cup.

The implementation of the device of subsoil irrigation in the form of a cylindrical glass provides the optimal rigidity of the structure, which is under static pressure of radial direction from the moistened soil. The presence on the side surface of the cylindrical glass of perforation allows you to create effective penetration of water into the irrigated area, while preventing the penetration of large-sized particles of soil into the cavity of the cylindrical glass. The use of cell perforation, for example, in the form of a hexagonal shape, allows you to increase the total perforation area, reduce the size of the drainage holes, thereby preventing soil particles from entering the cavity of the cylindrical glass, while maintaining optimal structural rigidity. If it is necessary to create a directed effect of intra-soil focal irrigation, only half of the lateral surface of a cylindrical glass can be perforated. The presence of a perforated cover in the central part provides the possibility of air flow penetration and free access to structural elements, and the presence of a dirt trap made in the form of an inverted cone perforated around the periphery helps to prevent foreign bodies from entering the cavity of the cylindrical glass during air flow. The use of a vortex hydroaerator (HAV) located in the upper part of the cylindrical glass creates a forced air flow through the perforations of the cover and the dirt trap, which aerates the irrigation fluid and ensures the entry of atmospheric air with a low content of carbon dioxide (CO ₂ ) and high oxygen content (O ₂ ), as well as the displacement of soil air enriched in carbonic acid and depleted in oxygen. The aeration process is one of the most important components of the existence, development and fertility of plantations, contributes to their normal growth, their intensive absorption of nutrients, as well as the rapid oxidation and decomposition of organic compounds in the soil.

The location in the cavity of a cylindrical cup mounted coaxially with the hydraulic aerator, a hollow cylinder, with a float rigidly connected to the plug, the parameters of which correspond to the parameters of the inner hole of the tangential nozzle of the vortex hydraulic aerator, together with the valve module connected to it at the bottom, allows metering (due to its intermittent blocking) liquid entering the cylindrical glass to the level necessary for irrigation, increasing the effectiveness of subsoil irrigation. Automatic blocking of fluid flow in a particular humidifier allows the redistribution of fluid flow to other humidifiers, thereby expanding the technical capabilities of subsoil irrigation.

The height and diameter of the hollow cylinder, the distance between the float and the plug rigidly connected to it should ensure that the liquid flow in the filled humidifier is completely blocked and that the tangential nozzle of the vortex hydro-aerator of the liquid sprayed from the internal opening is allowed to enter the humidifier cavity.

Valve module elements — a valve channel, a valve, and a float connected to it located outside the valve channel are designed to limit the maximum rise of the float (in a liquid-filled perforated humidifier) not higher than the height of the hollow cylinder, for example, to a height not higher than 1 / 3 parts of the height of the hollow cylinder (depending on the required irrigation parameters).

Thus, the combination of all the above characteristics provides an increase in the efficiency and quality of intra-soil irrigation of perennial plantations and allows to expand the technical capabilities of irrigation and irrigation systems.

The essence of the utility model is illustrated by drawings, where in FIG. 1 shows the design of an intra-soil irrigation device; in FIG. 2 - appearance of a perforated humidifier.

The subsoil irrigation device includes a supply pipe 1, hydraulically connected to a perforated humidifier 2, made long enough to reach the upper boundary of the soil layer 3. The perforated humidifier 2 is made in the form of a cylindrical cup 4 with a cover 5 perforated in the central part, and equipped with a dirt trap 6 located under the cover 5. The dirt trap 6 is removable, in the form of an inverted cone perforated around the periphery. The inlet pipe 1 is equipped with a vortex hydroaerator 7 located under the dirt trap 6. A hollow cylinder 8 is installed under the vortex hydroaerator with a float 9 rigidly connected to the plug 10, the parameters of which correspond to the parameters of the inner hole 11 of the tangential nozzle 12 of the vortex hydroerator 7. The lower part of the cylinder 8 is connected with a valve module 13, which includes a valve channel 14 and a valve 15 connected to a float 16 located outside the valve channel 14.

The device of subsoil irrigation works as follows. Irrigation liquid (water with dissolved mineral fertilizers) is piped 1 and fed under high pressure to the vortex hydroerator (VGA) 7. In the spiral channel of variable cross section of the tangential nozzle 12 of the vortex hydroerator 7, the water flow swirls with an increase in its linear velocity. At the same time, injection and mixing of the water stream with the air flowing through the perforations of the cover 5 and the dirt trap 6 takes place. The liquid is aerated. The aerated liquid gets sprayed onto the inner surface of the cylindrical cup 4 of the humidifier 2, partially filling its cavity and partially absorbing into the soil through perforations.

If the rate of entry of the aerated liquid into the humidifier 2 exceeds the rate of its penetration into the soil, then the liquid begins to rise, filling the cavity of the perforated humidifier 2 and the hollow cylinder 8. At the same time, the floats 9 and 16 rise. When the float 16 reaches the maximum possible height, valve 15 blocks the access of liquid to the channel 14 and, accordingly, to the hollow cylinder 8. The liquid continues to fill the cavity of the perforated humidifier 2. At the same time, the area of its penetration into the soil increases.

Having risen to the open edge of the hollow cylinder 8, the liquid begins to flow into it, as a result of which the float 9 rises and the plug 10 closes the inner hole 11 of the tangential nozzle 12 of the CAA 7. At the same time, the flow of irrigation fluid into the cavity of the perforated humidifier 2 stops.

As the liquid is absorbed into the soil, its level in the cavity of the humidifier 2 decreases, and inside the hollow cylinder 8, the water level remains at the same level, which ensures that the water flow through the CAA 7 is blocked until the liquid level drops so much that with it lower the float 16, opening the valve 14 and allowing the liquid to drain from the cylinder 8. At the same time, the plug 10 moves down and the fluid supply through the CAA 7 is resumed.

Thus, it is possible to control the flow of fluid along the height of the wetted layer. When performing perforation along the entire lateral surface of the cylindrical cup 4, circular irrigation of the soil is carried out. If directed irrigation is necessary, perforation is performed on half of the lateral surface of the cylindrical cup 4, and the humidifier is installed in the soil so that the perforations are facing the irrigated plant.

Thus, improving the quality and effectiveness of intra-soil irrigation of perennial plantings, as well as expanding the technical capabilities of irrigation and irrigation systems, is achieved.

Claims (3)

1. An intra-soil irrigation device, including a supply pipe hydraulically connected to a perforated humidifier, made long enough to reach the upper boundary of the soil layer, characterized in that the perforated humidifier is made in the form of a cylindrical cup with a lid perforated in the central part and equipped with a dirt trap, located under the lid and made in the form of an inverted cone perforated around the periphery, the inlet pipe is equipped with a vortex hydroaerator, p a hollow cylinder with a float rigidly connected to the plug, the parameters of which correspond to the parameters of the inner hole of the tangential nozzle of the vortex hydroerator, coaxially located under the dirt trap, and under the vortex hydroaerator, the lower part of the cylinder communicates with the valve module, which includes a valve channel and a valve connected to a float located outside the valve channel. 2. The device according to claim 1, characterized in that the perforation is made on half of the side surface of the cylindrical glass. 3. The device according to claim 1, characterized in that the perforation is made along the entire lateral surface of the cylindrical glass.

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