RU2769514C1 - Watering device - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: device contains a storage tank (1), a feeding tube (2) with a tap (3), a siphon (4) operating in automatic mode, a receiving manifold (5), distribution (6) and irrigation (7) pipelines with water outlets (8) and mixer (9). The mixer is placed in a storage container (1) and is made in the form of a closed container (10) equipped with a measuring container (11), a breather tube (12) and an air cap (13) with a hydraulic communication channel (14). The measuring container (11) is installed above the closed container (10) by means of a hollow rod (15) at a level below the upper level (WL) of water in the storage container (1). The lower end of the breather tube (12) is installed in the upper part of the closed container (10), and the upper end is above the level of the measuring container (11). The air cap (13) is installed above the lower level (LP) of water in the storage tank (1) and communicated by a hydraulic communication channel (14) with the bottom cavity of the closed tank (10).

EFFECT: simplified design and increased efficiency by expanding the range of changes in the concentration of solutions of chemicals and their dosed supply to irrigation water at each cycle "accumulation-drain".

1 cl, 9 dwg

Description

The invention relates to the field of agricultural mechanization, in particular to the multi-purpose use of discrete irrigation systems for introducing solutions of chemicals into the soil with irrigation water.

A siphon is known, containing a suction elbow with an air cap, a plug and a suction tube with a side outlet fitting, a drain elbow with a coupling, a drain tube and a breather tube, and a mechanism for starting the siphon made from the said parts of the suction and drain elbow. The suction tube is axially divided by a baffle into two parts, completely plugged at the bottom, and at the top - in part from the side of the outlet fitting, while the lower part of the baffle is made higher than the lower edge of the suction tube, the air cap is installed in the upper part of the suction tube and is made with a collar with a cutout , and the cutout is directed towards the outlet fitting, the outlet fitting is provided with a fixing nut, and its end and the inlet channel of the drain elbow are made smooth for their connection to each other by a sliding fit. Figure 12 shows a working diagram of the installation of a siphon with a storage tank and a consumer (the consumer option is a receiving pipe and irrigation pipes with water outlets), and Fig. 13 shows the state of the siphon after starting up (the liquid is drained from the storage tank freely to the consumer). [Patent of Russia 2 694 493, class. F04F 10/00 (2006.01), F04F 10/00 (2019.05) dated 07/16/2019].

In this patent, an irrigation device is created by means of a storage tank, a siphon, a receiving pipe and irrigation pipes with water outlets.

The disadvantage of this device for irrigation is the impossibility of introducing solutions of chemicals with policy water at each accumulation-draining cycle, which leads to a decrease in its efficiency due to a decrease in crop yields.

The closest technical solution (prototype) is a device for irrigation, containing distribution and irrigation pipelines with water outlets, a storage tank, a supply pipe with a tap, a siphon communicated by the suction part with the tank, and a drain - with a distribution pipeline, and a siphon launch mechanism. The triggering mechanism is made in the form of interconnected tube-liquid level sensor, ejector and manifold with inlet and outlet nozzles, while the tube-liquid level sensor is connected on one side with the suction part of the siphon through a hole made in the side wall of the storage tank, and with on the other hand, by means of an ejector - with the drain part of the siphon located in the collector through its inlet pipe, and the lower end of the sensor tube is placed in the collector above the level of the outlet pipes, and the end of the drain part of the siphon and irrigation pipelines are below it. It is equipped with a mixer communicated with the storage tank through a siphon tube, one end of which is located at the bottom of the mixer, and the other is directed upwards and placed in the storage tank below the upper level of the liquid level sensor tube, the mixer is made with a neck in which a ballast is installed with the possibility height adjustment. [Patent of Russia 2 015 661, class. A01G 25/02 (1990.01); A01M 7/00 (1990.01); dated 15.07.1994 (prototype)].

The disadvantage of this device for irrigation is the complexity of the design, low efficiency and a narrow range of application of the concentration of solutions of chemicals, which prevents the successive rapid introduction of different types of solutions of chemicals into the soil according to the active phase of plant development. Increasing the concentration of the chemical agent solution makes it difficult for water to flow from the storage tank into the mixer, and from the mixer, the solution enters the storage tank due to the increasing difference in volumetric weights of the chemical agent solution and irrigation water. When the device for irrigation with low concentrations of solutions of chemicals is used, the concentration of the solution in the mixer continuously decreases from cycle to cycle "accumulation-draining" without changing its volume, which leads to an undesirable increase in the operating time of the device for complete removal of the solution from the mixer and supply to the irrigated plot.

The device does not provide a dosed supply of a solution of chemicals to irrigation water from cycle to cycle "accumulation-draining".

The purpose of the present invention is to simplify the design and increase efficiency by expanding the range of concentration of solutions of chemicals and their dosed supply to irrigation water at each cycle of "accumulation-draining".

This goal is achieved by the fact that in the device for irrigation, containing a storage tank, a supply tube with a tap, a siphon operating in automatic mode, distribution and irrigation pipelines with water outlets, and a mixer, the mixer is placed in a storage tank and is made in the form of a closed tank equipped with a measured container, a breather tube and an air cap with a hydraulic communication channel, while the measuring container is installed above the closed container by means of a hollow rod at a level below the upper water level in the storage tank, the lower end of the breather tube is installed in the upper part of the closed container, and the upper end - above the level of the measuring tank, the air cap is installed above the lower water level in the storage tank and is connected by a hydraulic communication channel with the bottom part of the closed tank, the measuring tank is made in the form of a cup with a clamp and a scale for supplying a solution of chemicals, and its cavity is connected to the cavity of the storage tank by means of flexible pipe bki, one end of which is connected to the zone of its bottom, and the other end is passed through a clamp with the possibility of moving along the scale for supplying a chemical agent solution.

The essence of the proposed invention is shown in the figures, where Fig.1 - General view of the device for irrigation; figure 2 - General view of the design of the mixer; Fig.3 - view of the layout of the storage tank, the supply tube with a tap, a siphon and a mixer in section; Fig.4 - view of the mixer in the storage tank after charging with a solution of chemicals; Fig.5 - the state of the levels of the chemicalization agent solution in the mixer when the water level in the storage tank rises to the lower cut of the air cap; Fig.6 - the state of the levels of the chemical agent solution in the mixer when the water level in the storage tank rises above the air cap; Fig.7 - the state of the levels of the chemicalization agent solution in the mixer at the upper level (VU) of water in the storage tank; Fig.8 - view of the device for irrigation when the water level in the storage tank is lowered and Fig.9 - the state of the levels of the solution of chemicals in the mixer when the water level in the storage tank drops to the lower level (NU).

The irrigation device consists of a storage tank 1, a supply tube 2 with a faucet 3, a siphon 4 operating in automatic mode, a receiving manifold 5, distribution 6 and irrigation 7 pipelines with water outlets 8 and a mixer 9 (Figure 1). The mixer 9 is placed in the storage tank 1 and is made in the form of a closed tank 10, equipped with a measuring tank 11, a breather tube 12 and an air cap 13 with a hydraulic communication channel 14. The measuring tank 11 is installed above the closed tank 10, by means of a hollow rod 15, at the level below the upper level (WL) of water in the storage tank 1, the lower end of the breather tube 12 is installed in the upper part of the closed container 10, and the upper end is above the level of the measuring tank 11, the lower cut 16 of the air cap 13 is installed above the lower level (LL) of the water in storage tank 1, and its cavity 17 is connected by a hydraulic communication channel 14 with the bottom cavity of the closed tank 10. The measuring tank 11 is made in the form of a glass 18 with a clamp 19 and a scale for supplying a solution of chemicals 20, and its cavity is connected to the cavity of the storage tank 1 by means of a flexible tube 21, the end 22 of which is connected to the zone of its bottom, and the end 23 is passed through the clamp 19 with the possibility of moving along the solution supply scale ra means of chemicalization 20 (Figure 2 - Figure 9).

Before starting work on the device for irrigation, it is necessary to fill the closed container 10 of the mixer 9 with the required solution of chemicals through the measuring tank 11. In this case, the level of the solution of chemicals in the hydraulic channels will be established, as shown in (Figure 4).

The irrigation device works as follows. Water from the supply pipe 2 at a flow rate q, set by the valve 3, enters the storage tank 1. The water level in the storage tank 1 begins to rise slowly and until it reaches the HP (the beginning of the "accumulation-drain" cycle) and the level of the lower cut 16 of the air cap 13 does not have any impact on the closed container 10 (Figure 5). An increase in the water level in the storage tank 1 from the lower cut 16 of the air cap 13 to the end 23 of the tube 21 creates an air lock in the cap 13 and the hydraulic communication channel 14, which reliably prevents irrigation water from entering the storage tank 1 into the closed tank 10 and reducing the concentration of the product solution chemicalization in it (Fig.6). A further increase in the water level in the storage tank 1 above the level of the end 23 and before reaching the WU leads to the filling of the glass 18 of the measuring tank 11 through the tube 21 with the end 22, the hollow rod 15 and the breather tube 12 with irrigation water and an increase in the level of the solution of chemicals in the hydraulic channel connection 14 (Fig.7).

When the water level in the storage tank 1 reaches the WT, the siphon 4 automatically starts up and drains the accumulated volume of water with a solution of chemicals at a flow rate Q to the irrigated area through the intake manifold 5, distribution 6 and irrigation 7 pipelines with water outlets 7. Slow accumulation of water in the storage tank 1 with input flow rate q and a quick drain from it with flow rate Q, sometimes exceeding the input flow rate q by two or more orders of magnitude, makes it possible to obtain a uniform distribution of irrigation water over the irrigated area through water outlets 8. Reducing the water level in storage tank 1 to the end level 23, water from the glass 18 of the measuring container 11 through the tube 21 freely drains into the storage tank 1, thereby providing a predetermined volume of supply of the chemicalization agent solution to the irrigation water for the "accumulation-draining" cycle by means of the latch 19, the scale for supplying chemicalization solutions 20 and tube 21 A further decrease in the water level in the storage tank 1 (Fig.8) , under the action of water pressure in the measuring tank 11, leads to the displacement of the chemical agent solution from the closed tank 10 into the storage tank 1 through the hydraulic communication channel 14 and the air cap 13. The decrease in the water level in the storage tank 1 to HL (the end of the "accumulation-draining" cycle ”) communicates the air cavity 17 of the cap 13 with the atmosphere, ensures the flow of the volume of water from the measuring tank 11 to the upper part of the tank 10 and the displacement of the same volume of the solution of chemicals from it into the storage tank 1. Due to the slow flow of water from the measuring tank 11 into the upper layer tank 10 and its lower volumetric weight than the volumetric weight of the solution in the tank 10, two layers of liquid are formed in it, a solution of chemicals located at the bottom and irrigation water from the top, there is an inactive dissolution of the solution of chemicals with irrigation water and a decrease in the concentration of the solution at bottom of the tank 10 (Fig.9). Further, at each “accumulation-draining” cycle, a certain volume of irrigation water enters from the measuring tank 11 into the upper part of the tank 10 and displaces a dosed volume of a concentrated solution of chemicals from its bottom cavity into the storage tank 1.

By changing the level of the end 23 on the scale for supplying doses of the solution 20 through the tube 21 and the latch 19, a change in the volume of supply of the chemical agent solution from the tank 10 to the irrigation water of the storage tank 1 is achieved.

Establishing a measuring tank 11 above the level of the air cap 13 allows you to expand the range of changes in the concentration of chemical solutions used, which contributes to the sequential and rapid introduction of different types of chemicals solutions into the soil according to the active phase of plant development and increase the efficiency of the irrigation device.

The breather tube 12 allows the mixer 9 to be charged with a solution of chemicals through a measuring container 11.

Thus, by placing the mixer 9 in the storage tank 1, performing in the form of a closed tank 10 and supplying a breather tube 12 and an air cap 13 with a hydraulic communication channel 14, setting the measuring tank 11 above the closed tank 10 by means of a hollow rod 15 at a level below the top level (VU) of water in the storage tank 1, the lower end of the breather tube 12 in the upper part of the closed tank 10, and the upper end is above the level of the measuring tank 11, the lower cut 16 of the air cap 13 is above the lower level (NU) of water in the storage tank 1 and communicating the cavity 17 with a hydraulic communication channel 14 with the bottom cavity of the closed container 10, making a measuring container in the form of a glass 18 with a clamp 19 and a scale for supplying a solution of chemicals 20 and communicating its cavity with the cavity of the storage container 1 through a flexible tube 21, the end 22 of which is connected to zone of its bottom, and the end 22 is passed through the clamp 19 with the possibility of moving along the scale for supplying a solution of chemicals zation 20, a simplification of the design and an increase in efficiency were achieved by expanding the range of changes in the concentration of solutions of chemicals and their dosed supply to irrigation water at each accumulation-drain cycle.

In the conditions of the workshops of the FGBNU VNII "Rainbow" in 2021, an experimental sample of a device for irrigating a site with an area of up to 36 m ² was made with the following design parameters

Storage tank 1 volume 18 l, height 35 cm.

Siphon 4, connection size 1/2" with storage container 1.

The upper level (VU) from the bottom of the storage tank is 1 27 cm.

The lower level (NU) from the bottom of the storage tank is 1 15 cm.

Receiving manifold 5 PND32.

Distribution 6 and irrigation 7 pipelines PVC6.

Number of outlets 8 36 pcs.

Mixer 9

Measuring container 11, volume 0.09 l, upper cut level 26 cm.

Air cap 13 Ф32 mm, height 25 mm.

Cutting level 16 from the bottom of the storage tank 1 16 cm.

Closed container 10 volume 0.75 l, height 14 cm.

Hydraulic channel 13 and flexible tube 20 PVC6 tube.

Bench tests of an experimental sample were carried out in laboratory conditions in order to determine the reliability of its operation and the stability of the supply of a concentrated solution of chemicalization agents to irrigation water during each cycle of "accumulation-draining" of irrigation water. The test results are positive. During the test, not a single failure was observed, both for the irrigation device as a whole and for mixer 9 separately. In each phase of the "accumulation" cycle, the air plug formed in the air cap 13 and the hydraulic communication channel 14 reliably prevented the flow of water from the storage tank 1 into the closed tank 10 and a decrease in the concentration of chemicals solutions in it, and in each phase of the "drain" cycle under the action of water pressure in the measuring tank 11, a concentrated solution of chemicals was displaced from a closed tank 10 into a storage tank 1 in a constant volume determined by the solution supply scale 20. The coefficient of uniform distribution of irrigation water with a solution of chemicals over the irrigated area through water outlets 8 was 0.82 , which corresponds to the technical requirement of devices for discrete irrigation.

The use of the proposed invention in discrete irrigation systems for introducing chemical solutions into the soil with irrigation water will significantly increase the reliability and efficiency of these systems.

Claims (2)

1. An irrigation device containing a storage tank, a supply tube with a tap, a siphon operating in automatic mode, a receiving manifold, distribution and irrigation pipelines with outlets and a mixer, characterized in that the mixer is placed in a storage tank and is made in the form of a closed tank, equipped with a measuring container, a breather tube and an air cap with a hydraulic communication channel, while the measuring container is installed above the closed container by means of a hollow rod at a level below the expected upper water level in the storage tank, the lower end of the breather tube is installed in the upper part of the closed container, and the upper one is above the level of the measuring tank, the air cap is installed above the estimated lower water level in the storage tank and is connected by a hydraulic communication channel with the bottom part of the closed tank. 2. Irrigation device according to claim 1, characterized in that the measuring container is made in the form of a cup with a clamp and a scale for supplying a solution of chemicals, and its cavity is connected to the cavity of the storage tank by means of a flexible tube, one end of which is connected to the zone of its bottom, and the other is passed through a clamp with the possibility of moving along the scale for supplying a solution of chemicals.

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