RU2137354C1 - Apparatus for irrigating in greenhouses, hotbeds and on garden lands - Google Patents

Abstract

FIELD: agriculture, in particular, automatic irrigation of limited areas. SUBSTANCE: apparatus has main accumulating vessel with opening in its bottom, vessel bottom closing valve, and float valve disposed in auxiliary vessel. Water level in auxiliary vessel is lower than that in main vessel. Auxiliary vessel is connected via flexible hoses with hermetically sealed containers provided with porous bottoms and positioned in ground, and with discharge pipeline. Upon absorption of water by soil through porous bottoms of containers water level in auxiliary vessel is decreased and float valve is opened to allow delivery of water via float valve into main accumulating vessel. When water level in main accumulating vessel reaches predetermined value, water is discharged into low-pressure irrigation system and via pipeline into auxiliary vessel. Water level in auxiliary vessel is increased and float valve is closed. For high-pressure mode of operation of irrigation system, operation time is controlled by time required for supplying small amount of water into main accumulating vessel by slide valve. EFFECT: increased efficiency, wider operational capabilities and provision for regulating irrigation frequency. 3 cl, 2 dwg

Description

 The invention relates to irrigation systems and can be used to implement automatic irrigation in limited areas - greenhouses - greenhouses and garden plots.

 A device [1] is known, which contains a storage tank into which water is supplied through a pipeline with a control valve. At the bottom of the tank there is an outlet closed by a valve operated by a system of floats, flexible rods and levers. The valve on the pipeline is pre-regulated so that the storage tank is filled for a certain time, and after filling it, the valve automatically closes and water is supplied through the outlet to the irrigation system. Then the process is repeated.

 The disadvantage of the described device is that the water supply in it depends only on the regulation of the valve of the pressure pipe, and not on soil moisture, which in turn can change during the growing season of plants depending on weather and other factors. It also does not allow you to adjust the irrigation rate and always issues a certain amount of water equal to the volume of the storage tank to the irrigation system with a given frequency. The device, for example, does not provide water supply at low irrigation rates, which is necessary in some cases at some stages of the growing season. The device can be used only for low-pressure irrigation systems: for furrows, inlet (flooding), etc., but cannot be used for sprinkling, drip-pulse irrigation, etc., requiring high water pressure.

 A closer prototype is a device [2] containing a water tank, a beam, rigidly fixed to the axis of the stopcock with sliding loads placed on its shoulders, the movements of which are limited by magnetic stops. At one end of the beam there is a counterbalance vessel, at the other - an evaporation vessel with soil and plants placed in it. The walls and bottom of the evaporator vessel are perforated. The height of the vessel is taken to be not less than the depth of germination of the root system of the grown plants, and its area is not less than the area sufficient to grow one such plant. The evaporator is located in the irrigation zone. Drainage capacity between adjacent sections of soil in a natural (monolithic) state is imitated by the selection of the number of perforations in the evaporation vessel.

The disadvantage of the described device is inaccurate accounting for changes in soil moisture due to its being not in its natural (monolithic) state, but in the form of a piece isolated from the entire array placed in an evaporation vessel. In this case, the true value of soil moisture is distorted due to the following reasons:
the absence of influence on the soil moisture in the evaporation vessel of the molecular and mainly capillary forces of the underlying layers (up to the level of groundwater), which, as shown by studies of soil and soil hydrology, have a great effect on soil moisture;
more intensive evaporation (not only from the surface, as in soil in a natural state, but also from the sides and from below through perforations), which leads to faster drying of the soil in the evaporation vessel compared to soil in its natural state. During intensive evaporation, the balance of the rocker arm is disturbed and the process of water supply begins, i.e. the periods between the “Open” and “Closed” positions are reduced, which leads to a violation of the irrigation regime. In addition, it is known that soil water absorption, i.e. its ability to absorb and filter moisture and change its moisture in this regard depends on the presence of cracks, voids, cracks, worms and roots in it. Therefore, the absorption of soil in the "vessel-evaporator-main array" system and the soil of just the main array will be different, since there are gaps between the walls of the evaporator vessel and the niche in the main array, which contains the evaporation vessel when the beam is tilted, the parameters vary depending on the angle of the rocker arm. In this case, it is necessary to take into account the variability of water absorption in the space of the main soil massif.

 The known device does not provide water to high-pressure irrigation systems. It does not provide for the regulation of irrigation rates when water is supplied to low-pressure systems.

 The purpose of the invention is improving work efficiency, expanding operational capabilities and the ability to control the frequency of irrigation.

 This goal is achieved by the fact that a device containing a storage tank for water, a pipeline for supplying water to this tank through a float valve connected to it, an outlet pipe connected to an outlet device of the specified tank with a valve installed on the pipeline, is equipped with an auxiliary tank, the location of which height can be adjusted. In addition, the device is equipped with flexible pipelines connected at one of their ends to the auxiliary tank, and others - to sealed vessels with porous bottoms installed in the soil at a given depth in the area of the intended irrigation. The device has a flexible pipe connected at one end to the auxiliary tank, and the other to the exhaust pipe between the valve mounted on the exhaust pipe and the outlet of the storage tank. The float valve, through which water is supplied to the storage tank, is installed so that its float is located in the auxiliary tank. In addition, a flexible pipe is connected to the outlet of the float valve, the other end of which is located in the storage tank. This pipeline has a tap with a valve installed on it, while between the storage tank and the tap on a flexible pipe there is a device for fine regulation of water, for example, a valve. The same valves are installed on flexible pipelines connecting the auxiliary tank with sealed vessels with porous bottoms. Additional containers are connected to the auxiliary tank by means of pipelines with valves installed on them, the location of which can be adjusted in height.

 In FIG. 1 shows a diagram of a device; in FIG. 2 - pipelines with valves and auxiliary tanks.

 the device consists of a storage tank 1 mounted on the base 2. At the bottom of the tank there is an outlet with a seat in which the exhaust valve 3 is located. A metal rod 4 is connected to the valve, passing through a guide sleeve 6 mounted on the bracket 5. Toward the end of the rod 4 a flexible rod 7 is attached. The other end of the rod 7 is attached to the float 8 so that the length of the rod 7 can be adjusted. A retaining flexible rod 9 is attached to the upper part of the float 8, the upper end of which is fixed to a fixed support 10, made in a known manner and rigidly connected to the storage tank 1. The length of this rod is such that the float 8 cannot fall below the dotted line, i.e. e. will not reach the upper end of the rod 4. An exhaust pipe 11 is attached to the outlet, on which the control valve 12 is installed. Next to the storage tank 1 is an auxiliary tank 13, installed at a height H above ground level. This height can be adjusted in a known manner.

 Water is supplied to the device through a pipe 14 on which a valve 15 is installed. A float (ball) valve 16 is connected to this pipeline, a float 17 of which is located in the auxiliary tank 13. A flexible pipe 18 is connected to the outlet pipe of the float valve 16, the other end of which is omitted in the storage tank 1. An outlet 19 with a shut-off valve 20 is connected to the pipe 18. A device for precisely controlling the flow of water, for example, a valve 21, is also installed on the pipe 18.

 A flexible conduit 22 is connected to the auxiliary tank 13, the other end of which is connected to the outlet pipe 11 between the valve 12 and the outlet in the bottom of the storage tank 1. Co-flexible pipes 23 are also connected to the auxiliary tank 13, which are connected to porous sealed vessels 24 with their other ends bottoms. Such vessels are used in practice as humidity sensors (tensiometers). These vessels are tightly installed in the soil in the irrigation zone to a predetermined depth corresponding to the full or partial depth of the plant root system. Figure 1 conventionally shows two vessels 24, although their number can be any. At the same time, the auxiliary tank 13 should have an appropriate number of nozzles for connecting the pipelines 23. Screw clamps 25 are installed on the pipelines 23 to regulate the cross section of these pipelines. If necessary, additional auxiliary tanks 28 can be connected to the auxiliary tank 13 through pipelines 26 with valves 27, the location of which can be adjusted in height (see Fig. 2). To prevent atmospheric moisture from entering the auxiliary container 13 and additional containers 28, a removable visor 29 is installed above them.

 The device operates as follows. When irrigation by furrows, inlet, subsoil irrigation and other low-pressure method, the pipeline 11 is first connected to the irrigation system, and the valve 12 is opened. Then, by adjusting the length of the flexible rod 7, a volume of water is set in the storage tank 1, which will be supplied to the irrigation system. This volume must comply with the irrigation rate. After this, in a known manner, water is poured into the auxiliary tank 13 and tank 28, flexible pipelines 23 and vessels 24, pre-installed in the soil. Screw clamps 25 mounted on pipelines 23 must be open. The air inside these nodes must exit. In this case, the position of the containers 13 and 28 in height is adjusted. They are installed so that when they are filled, the water level is at the connection height of the flexible pipe 22 and at the same time are lower than the specified water level and the storage tank 1 corresponding to the irrigation rate. The float 17 of the float valve 16 should be free to lie at this level in the auxiliary tank 13. In this case, the float valve 16 will be in the "Closed" position. First, the pipelines 23 must be horizontal so that the water under the influence of its own weight from the auxiliary tank 13 through the pipelines 23 filled the vessels 24.

 Next, open the valve 15 of the pressure pipe 14 and close the valve 20. Fully open the valve 21. First, in the absence of water in the storage tank 1, the exhaust valve 3, under the influence of its own weight, will lower into the seat and close the outlet. If the soil moisture is low, then due to capillary and molecular forces, water is sucked in from the upper layers of the soil deeper (the effect of the “sucking soil force”), including from the vessels 24. This effect increases with decreasing soil moisture. The water is sucked out through the porous bottoms of the vessels 24. The porosity of each bottom is such that only water is seeped through them, but air breaks inside the vessels are excluded 24. It is known that the vacuum created during the suction of the water in the vessels 24 (tensiometers) is quite accurate for practical purposes soil moisture in the range from full field moisture capacity to moisture slightly lower than the lowest moisture capacity. In this range, as you know, the growth and development of plants occurs.

 When suction decreases the water level in the auxiliary tank 13 (a new level is shown by the dotted line in Fig. 1). The float 17 of the float valve 16 is lowered and the latter gradually switches to the "Open" position. Water from the pipeline 14 through the valve 16, the pipeline 18 enters the storage tank 1 and fills it to a predetermined level. The float 8 rises and opens the exhaust valve 3. Water through the pipe 11 enters the irrigation. Since there is resistance in the irrigation system, part of the water after opening the valve 3 simultaneously enters through the pipe 22 into the auxiliary tank 13 and the tank 28. The water level in them rises to the initial one and the float valve 16 switches to the closed position, t, e The water supply to the storage tank 1 is stopped. If the resistance in the irrigation system is not enough to raise water through the pipe 22 in the tank 13, 28, then by adjusting the valve 12, the desired resistance in the pipe 11 is achieved, providing a rise in the water in the tank 13, 28.

The next cycle will begin after due to the "suction power of the soil", as well as the dead weight of water, depending on the position of the pipelines 23, the level in the tanks 13, 28 will again decrease. The time between filling the storage tank 1, that is, the frequency of watering can be regulate in the following ways, based on the application of the law of fluid flow through porous media (Darcy's law):
1. the number of vessels 24, because the amount of sucked water from containers 13, 28 is directly proportional to the total area of the bottoms of these vessels;
2. a change in the resistance of the pipelines 23, because the flow rate of the water passing through them will be inversely proportional to the pressure drop, depending on the resistance (this can be done either by raising or lowering any sections of the pipelines 23 relative to the water level in the auxiliary tank 13 and the tanks 28 indicated in it, or by adjusting the screw clamps 25 installed on pipelines 23);
3. by changing the cross-sectional area of the auxiliary vessel 13 and containers 28 by connecting or disconnecting containers 28 using valves 27, since this changes the volume and, consequently, the time of suction of water using vessels 24, provided that the number of these vessels does not change .

 In addition, it is possible to change the indicated filling time of the storage tank 1. by changing the length of the pipelines 23 (if a set of replaceable pipelines is provided), since the amount of sucked water is inversely proportional to the length of the leakage path.

 If water is supplied to a high-pressure irrigation system (sprinkling, drip-pulse irrigation, etc.), then the work is performed as follows. The pipeline 19 is connected to the irrigation system, the valves 12, 20 and 15 open. Then adjust the time of water supply to the irrigation system. This is done by adjusting the filling time of a certain small volume in the storage tank 1. This volume is set by adjusting the length of the rod 7, and the water supply (flow) through the pipe 18 is controlled by the valve 21. Since the water flow through the valve 21 will be small, the filling time it can be adjusted from several hours to several days. Then, as in the previous case of irrigation through low-pressure systems, water is poured into the vessels 24, flexible pipes 23 and containers 13, 28, allowing air to escape from these nodes. The position of the containers 13, 28 is regulated in the same way as in the previous case, positioning them so that the water level in them is set at the height of the flexible pipe 22 and at the same time would be lower than the set level in the storage tank 1. At the same time, the float valve 16 be in the closed position. When water is sucked off by soil from tanks 13, 28, this valve gradually switches to the "Open" position, and water is supplied through the pipeline 19. Simultaneously through the pipe 18, a predetermined volume of the storage tank 1 will be filled for a predetermined time. After filling the specified volume, the float 8 will raise the valve 3 and water will flow through the pipelines 11, 22 into the containers 13, 28. Excess water from these containers will pour over the edge. The float valve 16 will switch to the "Closed" position and watering will stop. After that, the cycle will resume after the suction of water from the containers 13, 28. The time between cycles is regulated in the same way as in the first case when using the device for low-pressure irrigation systems.

 If the device supplies water for irrigation on open ground, then it is possible to take into account the effect of precipitation on the soil. For this purpose, it is necessary to remove the protective visor 29. Then the water level in the tanks 13, 28 will be higher due to atmospheric precipitation. As a result, the float 17 rises, i.e. the water supply from the pipeline will decrease 14. If the device works on closed ground, the influence of precipitation must be eliminated by installing a visor 29. In hot weather, in all cases, the water in tanks 13, 28 will evaporate, which also leads to a decrease in the water level in these tanks and reduction of time between cycles. Thus, the proposed device is universal, as it is applicable to all irrigation systems of high pressure and low pressure, on open and protected soils and takes into account all weather factors.

 The device can be simplified if it is used only to supply water to a low-pressure irrigation system. The float valve 16 can be installed directly above the storage tank 1 so that water from its outlet pipe would fall directly into the specified tank. This allows you to abandon the use of pipelines 18, 19, valves 20 and 21.

 In the absence of a water supply network and when using the device for a low-pressure irrigation system, it can be powered from some capacity raised to a certain height (tank, etc.), pre-filled with a pump or in some other way.

 The device is structurally simple, it has no electronics and does not require any connection to the mains. This ensures safe operation and does not require qualified maintenance. It can work autonomously without the presence of a person, which is important when it is possible only occasionally (for example, once a week) to monitor its work. The device is therefore designed for the mass consumer. It allows, if it is made from chemically resistant materials, the introduction of liquid fertilizers into the soil. The device mainly consists of commercially available parts and assemblies: valves 3, 16 used in plumbing, flexible piping, etc. As a float 8, a piece of foam can be used. The device controls the actual soil moisture in its natural state in the root zone. It is self-regulating, as it automatically changes the irrigation mode depending on soil moisture. The device allows you to adjust the irrigation rate and change the time between waterings.

Sources of information:
1. Patent of the USSR N 1790349 class. A 01 G 27/00.

 2. RF patent N 2053649 class. A 01 G 27/00, 25/16.

Claims (3)

 1. A device for irrigation of greenhouses, greenhouses and garden plots, containing a storage tank for water, a pipeline for supplying water to this tank through a float valve mounted on it, an outlet pipe connected to an outlet device of the specified tank, with a valve installed on this pipeline, characterized the fact that it is equipped with an auxiliary tank, the location of which can be adjusted in height, with flexible pipelines connected at one of their ends to the auxiliary tank, and them - to sealed vessels with porous bottoms installed in the zone of the intended irrigation in the soil at a given depth, a flexible pipe connected at one end to the auxiliary tank, and the other to the outlet pipe between the valve mounted on the outlet pipe and the outlet device of the storage tank, wherein the float valve is installed so that its float is located in the auxiliary tank.  2. The device according to claim 1, characterized in that a flexible pipe is attached to the outlet pipe of the float valve, the other end of which is located in the storage tank, the pipe being provided with a tap with a valve installed on this tap, and between the storage tank and the tap on a flexible a device is installed in the pipeline for precisely controlling the flow of water, for example, a valve.  3. The device according to claim 1, characterized in that on the flexible pipelines connecting the auxiliary tank with sealed vessels with porous bottoms, screw clamps are installed to regulate the change in the flow cross sections of these pipelines, and connected to the auxiliary tank using pipelines with the valves indicated on them additional containers, the location of which can be adjusted in height.

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