LT6790B - Automatic soil water level control method and system - Google Patents

Abstract

The invention provides an automatic soil water level control system, which comprises drainage pipes, a water level control well and a float valve. The well has the following components: a housing of the well, a bottom, a cover, a side profile and a separator. The float valve has the following components: a housing of the float valve, a rear cover, a front plate, a mounting plate, a rear lever, a front lever, a float, a valve, a hinge, fasteners, a valve gasket, a valve opening to remove the air, a plate. When there is no water in the well, the float valve is opened and water flows through the drainage pipes and the float valve into the well. The separators in the well control the water level in the soil since the water level in the soil and the well is the same. The water raises the float upward; the rising float closes the valve. The water rises in the area in front of the float valve. When a lot of water accumulates, the water opens the valve due to the pressure, some water flows towards the well. There is a balance. This is how the system controls the soil water level when the relief is rough. Each float valve raises the water level in the soil area in front of the float valve.

Description

TECHNICAL FIELD

The invention belongs to the field of regulating the soil water level by means of drainage pipes, and more particularly to a system with devices which regulate the soil water level by means of a float valve and a drainage well with tabs.

BACKGROUND OF THE INVENTION

The invention provides a method of regulating the soil water level and a system implementing that method, where the soil water level can be regulated both automatically and manually using existing or newly constructed drainage pipes or tubes.

Document CN103953007 (published on 30/07/2014) provides a technical solution when the soil water level is regulated mechanically. The document describes a drainage system consisting of drainage pipes and a device with a valve that can close or open the water flow. The valve opens due to the pressure created by the accumulated water. A higher amount of water creates a higher pressure, so the valve opens more widely and more water flows through. The soil water level is regulated automatically. The disadvantage of the present invention is that it is not possible to manually drain the soil water quickly, so that the regulation of the soil water level is partial. When the vertical drainage wells are high, the soil is unstable, the frost affects the well, there is a problem of well stability.

Patents CA2466976C (published September 11, 2007) and US8342775 (published January 1, 2013) describe drainage systems that are automatically regulated by a controller. The flow of water is regulated according to a predetermined date, taking into account the recurring climatic conditions each year. The problem is that the system is inflexible when the amount of water flowing through the soil is controlled according to a predetermined date: climatic conditions in different years and thus humidity. can vary greatly. Automatically operated drainage systems have the following disadvantages: after prolonged use, they also become leaking due to changes in soil deposits or pipe geometry.

Patent CN208110359 (published 16/11/2018) provides a technical solution where the drainage system controller can receive signals from the environment: measured temperature, water level or other parameters. Based on the data received, the controller electronically controls the drainage system by closing or opening the water flow valve. However, this method of management is complicated and expensive to install.

Document US2010276015 (published 04/11/2010) describes a drainage system consisting of horizontal drainage pipes and vertical wells. The water level in the wells is regulated by means of plates in the wells, the amount of which can be varied. The flow of water in the horizontal drainage pipes is regulated by means of a float valve, automatically according to the pressure in the valves of the drainage pipes.

Documents RU2581195C1 (published 20/04/2016), RU2609441C1 (published 2017-02-01), describe drainage systems where the water level is regulated by means of float valves in horizontal drainage pipes. The amount of soil water creates pressure that acts on the floating mechanisms, which open or close the water flow gate. Both documents provide improvements to float valves. The disadvantage of these inventions is that only float valves are improved. The water collection well has unresolved shortcomings: its shape is not resistant to environmental influences, the problem of well stability and tightness is unresolved. Often, after prolonged use, such drainage systems become leaky, the rubber of the tabs loses its tightness when exposed to water pressure, and the water pressure can be torn off the tabs.

The listed state of the art analogues found have drawbacks compared to the solution presented in this description. The technical solution presented in this description does not have the above-mentioned problems, the improvements increase the efficiency and durability of the soil water regulation system.

SUMMARY OF THE INVENTION

The invention provides an automatic soil water level regulation system comprising drainage pipes, a water level control well and a float valve. The well has the following components: well body, bottom, lid, side profile and tab. The float valve has the following components: float valve body, rear cover, front plate, mounting plate, rear lever, front lever, float, valve, hinge, fasteners, valve gasket, valve vent, vent. When there is no water in the well, the float valve is open, the water enters the well through the drainage pipes and the float valve. The tabs in the well regulate the water level in the soil because the water level in the soil and the well are the same. The water raises the float to the top, the float rising to close the valve. Water rises in the area in front of the float valve. When a lot of water accumulates, the water opens the valve due to the pressure, some of the water drains into the well. There is a balance. This way the system regulates the soil water level when the terrain is uneven. Each float valve raises the water level in the soil area in front of the float valve.

BRIEF DESCRIPTION OF THE DRAWINGS fig. Construction scheme of water level control well. Here 1- water level control well, 1.1- well housing, 1.1.1- well connection pipe: inlet, 1.1.2- well connection pipe: outlet, 1.2- bottom, 1.3- cover, 1.4-tab, 1.5- side profile.

fig. Layout diagram. Here 1.4- tab, 1.4.1- tab gasket, 1.4.2- tab hook, 1.4.3 - Screw-in plate to ensure the tightness of the tab gasket.

fig. Cross-sectional view of the side profile. Here is the 1.5- side profile.

fig. Flow diagram of the float valve. Here 2- float valve, 2.1 float valve body, 2.2- rear cover, 2.3- front plate, 2.4- mounting plate, 2.5- rear lever, 2.6- front lever, 2.7- float, 2.8- valve, 2.9- hinge, 2.10- fasteners, 2.11 - valve gasket, 2.12 - valve opening for air extraction.

fig. Float valve faceplate. Here 2.3- front plate, 2.13 screw plate ensuring the tightness of the valve gasket.

fig. Flow valve construction diagram, alternative. Here 2.3- front plate, 2.4- mounting plate, 2.5- rear lever, 2.6- front lever, 2.7- float, 2.8- valve, 2.9- hinge, 2.10- fasteners, 2.11 - valve gasket, ensuring tightness due to sediment.

The illustrations provided are more illustrative, scale, proportions and other aspects do not necessarily correspond to a real technical solution.

BEST MODES FOR IMPLEMENTATION

Automatic soil water level regulation systems have disadvantages:

the drainage well is not resistant to environmental influences, when the vertical drainage wells are high, the soil is unstable, the frost affects the well, a problem of well stability occurs. After a while, the tabs lose their tightness, and the float valve does not close tightly due to plaque, its rubbers are not mechanically fastened with plates or screws, which can cause them to tear or peel off. In addition, many systems cannot be adjusted manually. The description provides a system for the automatic regulation of soil water levels that addresses these shortcomings.

When the soil relief is uneven, keeping the soil water level at the same height throughout the area, the water level for some plants will be adequate; part of the plant water will last because the plant roots will not reach the soil water; and for the rest of the plants there will be too much water as the roots of the plants will flash. The absolute level of soil water should be different in different soil areas, i. the water level would be at a similar distance from the soil surface everywhere. In this case, the soil water level control system has drainage pipes, a water level control well and a float valve. The drainage pipes are connected to the well and the float valve is inserted between the drainage pipes in the area of the soil where the relief rises, i. where the soil water level needs to be raised. The float valves installed in the drainage pipe system automatically regulate the flow of water through the drainage pipes. Improvements increase the efficiency and longevity of the soil water regulation system. There is a more stable and resistant to environmental impact water level control well. The description also provides an improvement to the float valve in that the float valve components prevent plaque formation, thus addressing the problem of valve tightness. In addition, the improvement of the tabs solves the problem of tightness in the water level control well.

The automatic soil water level regulation system described in the present invention has the following interconnected parts:

- drainage pipes;

- water level control well (1);

- float valve (2).

Drainage pipes are pipes commonly used in a drainage system to remove excess water from the soil. Drainage pipes are hollow elements that can be made of a variety of materials, usually ceramic or plastic. Drainage pipes are buried in the soil where they lie horizontally or sloping. Drainage pipes are connected into a single drainage system in such a way that they form a slope, so that excess soil water flows through them to the drainage ditch at the lowest point or another place where the water is removed. The ceramic drainage pipes in the drainage system are leaking close to each other, thus soil water enters the drainage pipes through the cracks between the pipes. Plastic drainage pipes are corrugated and have holes through which water enters the pipe and flows into the drainage ditch. The described system of automatic regulation of soil water level can be adapted to existing drainage pipes or new drainage pipes can be laid.

The water level control well (1) (hereinafter referred to as the 'well') has the following components (Figure 1):

- well body (1.1);

- the bottom (1.2);

- the lid (1.3);

- tab (1.4);

- side profile (1.5).

The well body (1.1) is a cylindrical tube with a circular cross-section, a pipe placed vertically in the soil. The well housing (1.1) can be made of various materials (plastic, metal, wood, fiberglass and other natural or synthetic materials), usually the well housing is made of PVC plastic. The well housing (1.1) must be airtight and strong. An important feature of the well housing is that the well housing (1.1) is cylindrical and therefore resistant to environmental influences: it is not distorted or lost due to moisture, cold, mechanical or other effects. At the bottom of the well housing (1.1) there is a water inlet or well connection pipe: inlet (1.1.1) and a drainage hole or well connection pipe: outlet (1.1.2). A drainage pipe is inserted into the water inlet or connection pipe (1.1.1) through which the soil water from the drainage system enters the well. The drainage hole or the drain connection pipe (1.1.2) through which the soil water is removed from the well (1) may be open, or a drainage pipe or drainage mouth may be connected to the drainage hole (1.1.2). In the well housing (1.1), between the water inlet hole (1.1.1) and the water outlet hole (1.1.2), tabs (1.4) are inserted, which divide the well body (1.1) into two parts. The tabs (1.4) are placed vertically in such a way that the well (1) has two tanks, and the soil water entering the well (1) through the water inlet (1.1.1) is not removed but accumulates. The well body (1.1) has a bottom (1.2) at the bottom and a lid (1.3) at the top. There may be a lock at the top of the well housing (1.1) to allow the well (1) to be locked.

The bottom of the well (1.2) is the part of the bottom of the well body (1.1) integrated into the well body (1.1), which seals the well body (1.1) from below. The upper part of the bottom (1.2) is inserted into the well body (1.1), therefore the diameter and shape of this part must be adapted to the diameter and shape of the well body (1.1). The diameter of the lower part of the bottom (1.2) is larger than the diameter of the well body (1.1), so such a bottom provides stability to the well. The bottom (1.2) can be made of various materials (plastic, metal, wood, fiberglass and other natural or synthetic materials), usually the bottom (1.2) is made of PVC plastic. The bottom of the well (1.1) is attached to the well body (1.1) by means of metal angles, the angles can be attached to both the outer and inner part of the well body (1.1).

The manhole cover (1.3) is the part at the top of the manhole body (1.1) that covers the manhole body (1.1). The diameter and shape of the cover (1.3) must be adapted to the well body (1.1). The lid (1.3) can be made of various materials (plastic, metal, wood, fiberglass and other natural or synthetic materials), usually the lid (1.3) is made of PVC plastic. The cover (1.3) is not integrated in the well housing (1.1): the cover (1.3) can be raised and lowered. The lid (1.3) has a hook and a lock, the other part of the lock is on the well body (1.1), so the well (1) can be locked. In individual cases, the cover (1.3) may not have a hook (1.4.2) and / or a lock.

The manhole tab (1.4) is the part of the plate-shaped manhole (1) enclosed between the side profiles (1.5) and capable of moving up / down (Fig. 2). The tab (1.4) can be made of various materials (plastic, metal, wood, fiberglass and other natural or synthetic materials), usually the tab (1.4) is made of PVC plastic. The dimensions of the tab (1.4) must match the dimensions of the well body (1.1) and the side profile (1.5). The tab (1.4) must be strong to withstand the force generated by the water pressure and the effects of the environment, and watertight. Insert the tab (1.4) tightly into the side profiles (1.5) facing each other. The ends of the tab, which are inserted into the side profile (1.5), are thinner than the rest of the tab (1.4). In an individual case, the ends of the tab (1.6) may be the same thickness as the tab itself (1.4). The tab (1.4) can be attached to the side profile (1.5) and in other ways that ensure tightness. The tab (1.4) has one or more hooks (1.4.2) that allow the tab to be inserted and removed from the well (1). The water level control well (1) has a lower tab (1.4) and at least one other tab (1.4) which is sealed or otherwise attached to the side profiles (1.5). The number of tabs (1.4) is selected according to the soil relief - the larger the height difference in the system, the more tabs (1.4) will be needed.

The lower tab (1.4) is fixed, i. it is fixed and tightly attached to the side profiles (1.5) and the bottom (1.2). The lower tab (1.4) is inserted vertically into the well housing (1.1) in such a way that the well housing (1.1) is divided into two tanks in which the water does not mix. In individual cases, the lower tab (1.4) can be removed. The other tabs (1.4) are placed tightly on top of each other by inserting them into the side profiles (1.5). The tabs (1.4) divide the well housing (1.1) into two parts in such a way that two water tanks in which the water does not mix appear in the well housing (1.1). On one side of the tab (1.4) there is a gasket glued or otherwise attached to the profile ( 1.4.3) ensuring tightness when the tabs (1.4) are placed on top of each other and inserted into the side profile (Fig. 3). The gasket can be made of various materials, most commonly using porous EPDM rubber (1.4.1). The gasket (1.4.1) is glued to the entire perimeter of the tab (1.4) and secured with a plate (1.4.3). A solid gasket (1.4.1) is usually used, but individual strips of gasket can also be glued on the sides of the tab (1.4). In an individual case, the gasket (1.4.1) may cover the entire surface of the tab (1.4). The gasket (1.6.1) is usually slightly protruding slightly beyond the dimensions of the tab (1.4), but in the individual case the gasket (1.4.1) may coincide with the dimensions of the tab (1.4). The gasket (1.4.1) is mechanically tightened by plates (1.4.3) which press the gasket (1.4.1) against the tab. The plate can be made of various materials, but PVC plastic or steel is most commonly used. The tab (1.4) and the plates have overlapping holes, so the tab (1.4) and the plate are tightened with the help of bolts, nuts, washers. In the individual case, the gasket (1.4.1) can be on both sides of the tab (1.4).

The side profile of the well (1.5) is an elongated part attached to the walls of the well body (1.1), which is shaped in such a way that one side can fit snugly against the well body (1.1) and the other side has a cavity in which the tab can be tightly inserted. (1.4) (Fig. 3). The side profile (1.5) can be made of various materials (plastic, metal, wood, fiberglass and other natural or synthetic materials), but the most commonly used aluminum side profile (1.5). The side profile (1.5) is tightly, firmly and rigidly attached to the inner wall of the well body (1.1) in a vertical position. The side profile (1.5) has an opening facing the inside of the well (1) and is oriented so that the tab (1.4) can be tightly inserted into the opening. In individual cases, the tab (1.4) can be attached to the side profile (1.5) in other ways without inserting the tab (1.4) into the opening of the side profile (1.5). The well housing (1.1) has two side profiles (1.5) facing each other. The side profile at the bottom, in individual cases to ensure tightness against water accumulation inside the profile, can be sealed with a plate, the shape of the inner part of the profile, which can be made of various materials (plastic, metal, wood, fiberglass and other natural or synthetic materials) , but PVC is the most commonly used material. Holes may be made in the side housing, in the lower part, in the outlet part in individual cases, in case water is removed from the profile, otherwise if the water accumulates inside the profile, the profiles may break with ice during freezing.

The float valve has the following components (Fig. 4):

- float valve body (2.1);

- rear cover (2.2);

- front plate (2.3);

- mounting plate (2.4);

- rear lever (2.5);

- front linkage (2.6);

- float (2.7);

- the valve (2.8);

- hinge (2.9);

- fasteners (2.10);

- valve gasket (2.11);

- valve opening for air extraction (2.12);

- a screw plate to ensure the tightness of the valve gasket (2.13).

The float valve body (2.1) is the part of the float valve that holds the other parts of the float valve. The float valve body (2.1) can be made of various materials (plastic, metal, wood, fiberglass and other natural or synthetic materials), usually made of PVC plastic. At the top of the float valve body (2.1) there is a hole or holes (2.12) through which air is removed from the float valve body (2.1). The holes shall be covered with a geotextile or other cloth that prevents soil from entering the float valve body (2.1). Both ends of the float valve body (2.1) are covered by a rear cover (2.2).

The rear cover (2.2) is the part of the float valve (2) that covers the ends of the float valve body (2.1). The diameter and shape of the tailgate (2.2) must match the diameter and shape of the float valve body (2.1). The rear cover (2.2) has a hole through which it is connected to drainage pipes or PVC pipe. The back cover (1.4) can be made of various materials, usually PVC plastic. The end cap (1.4) connects the float valve on both sides to the drainage pipes or PVC pipe and prevents soil from entering the float valve body (2.1).

The front plate (2.3) is the part of the float valve (2) which is sealed in the float valve body (2.1) (Fig. 5). The shape and diameter of the front plate (2.3) must match the shape and diameter of the float valve body (2.1). The front panel (2.3) can be made of various materials, usually made of PVC plastic. The front plate (2.3) has a hole that can be closed or opened by a valve. Around the hole is a gasket (2.11), which is needed for the valve (2.8) to seal the hole, the gasket is glued and fastened with plates (2.13). The gasket can be made of various materials, usually a rubber gasket is used. The front panel (2.3) has a threshold - the hole is raised above the edge of the front panel (2.3). The part of the front plate (2.3) between the edge of the front plate (2.3) and the hole may have a slope. The sill and slope are necessary to prevent the formation of scale at the bottom of the faceplate (2.3) and the valve (2.8) to seal the hole. One embodiment of the front plate (2.3) around the hole is a rubber or other resilient material (2.11) located around the hole in the front plate (2.3) and raised above the front plate (2.3) (Fig. 6). This rubber shape also prevents the formation of deposits at the bottom of the front plate (2.3) and the valve (2.8) tightly covering the hole.

The mounting plate (2.4) is the part of the float valve (2) that is mounted on the top of the inside of the float valve body (2.1). Attach to the mounting plate (2.4) the parts of the float valve (2) that control the movement of the float (2.7) and the valve (2.8). The mounting plate (2.4) can be made of various materials, the mounting plate (2.4) made of PVC plastic is usually used.

The end lever (2.5) is the part of the float valve (2) that is attached to the mounting plate (2.4). One end of the rear lever (2.5) is connected to the mounting plate (2.4) and the other to the front lever (2.6). Both joints are flexible so that the rear lever (2.5) can move up and down. The rear lever (2.5) can be made of various materials, usually a PVC plastic rear lever (2.5) is used.

The front lever (2.6) is the part of the float valve (2) with one end attached to the rear lever (2.5) and the other end to the valve (2.8). The front lever (2.6) is flexibly connected to the rear lever (2.5) so that the front lever (2.6) can move up and down, thus moving the front lever (2.6) to move the valve (2.8), which opens or closes the hole in the front panel ( 2.3). The front lever (2.6) can be made of various materials, usually made of PVC plastic.

The float (2.7) is the lighter part of the float valve (2) attached to the rear lever (2.5) and the front lever (2.6). The float (2.7) can be made of various materials lighter than water, usually a float (2.7) made of non-absorbent foam is used. The soil water raises or lowers the float (2.7). Rising up or down, the float (2.7) moves the front lever (2.6) connected to the valve (2.8), which opens or closes the hole in the front plate (2.3). As the float (2.7) rises, the valve (2.8) closes the hole in the front plate (2.3); allowing the float (2.7) to go down, the valve (2.8) opens the hole in the front plate (2.3).

The valve (2.8) is the part of the float valve (2) attached to the front lever (2.6) and the hinge (2.9). The valve (2.8) can be made of various materials, usually a valve (2.8) made of PVC plastic is used. The valve (2.8) regulates the flow of soil water through the float valve (2) and the drainage pipes, closing or opening the hole in the front panel (2.3). When the valve (2.8) is lowered, it presses against the gasket (2.11), seals the hole tightly and does not leak soil water. When the hole is exposed, soil water flows through it.

Fasteners (2.10) are elements that connect or fasten parts of a float valve (2) to each other. Fasteners (2.10) are common elements used in plumbing to connect or fasten items: bolt, nut, washer, screw, nozzle, and so on.

The soil water level is regulated automatically and manually. When the soil is level, the automatic soil water level adjustment system consists of drainage pipes and a well (1). Drainage pipes are connected into a unified system and lie in the soil at a slight slope. A well (1) is installed at the lowest point of the relief, to which a drainage pipe system is connected. The well (1) has a drainage hole or a connection pipe (1.1.2) through which the soil water from the well (1) escapes to the drainage ditch or elsewhere. When there is only a lower tab (1.5) in the well (1), the maximum removal of soil water from the soil. As much water enters the well (1) through the water inlet or the connection pipe (1.1.1), the water is immediately removed through the water inlet or the connection pipe (1.1.2). The tabs (1.4) can be inserted manually into the well (1). The tabs (1.4) are tightly stacked on top of each other so that no water passes through them. When tabs (1.4) are added to the well (1), the soil water flowing through the drainage pipes accumulates in the well (1). In the well (1), the water level rises on the side of the housing (1.1) where there is a water inlet or connection pipe (1.1.1). When the soil water reaches the top of the upper tab (1.4), the water flows over the top of the upper tab (1.4), enters the side of the housing (1.1) where the drainage hole (1.1.2) is located, and is removed. Water below the top of the upper tab (1.4) is not removed from the well (1). Since the water in the well (1) and in the soil is like in contact vessels, water is not removed from the soil either. In this case, the soil water is maintained at the same height as the top of the upper tab (1.4). By changing the number of tabs (1.4) in the well (1), the water level in the soil can be adjusted. When heavy machinery has to enter the fields, e.g. In the case of spring tillage, some of the tabs (1.4) can be removed manually to lower the soil water level briefly. Once the soil is cultivated, the plants need water to grow, so the tabs (1.4) are added manually and the soil water level is raised. Soil water levels can be adjusted in other cases as well. For example, after removing part of the tabs (1.4) after a heavy rain, the excess water can be drained quickly. After inserting the tabs (1.4), raise the soil water level again.

When the soil relief is uneven, keeping the soil water level at the same height throughout the area, the water level for some plants will be adequate; part of the plant water will last because the plant roots will not reach the soil water; and for the rest of the plants there will be too much water as the roots of the plants will flash. The absolute level of soil water should be different in different soil areas, i. the water level would be at a similar distance from the soil surface everywhere. In this case, in addition to the drainage pipes and the well, a float valve (2) is also used. The drainage pipes are connected to the well (1) as in the case described above. In the soil area where the terrain rises, the soil water level also needs to be raised. Therefore, a float valve (2) is usually placed on the drain collector at that point between the drainage pipes. When there is no water in the well (1), the float valve (2) is open, all the water flows through the float valve (2). When water appears in the soil, it flows through the drainage pipes and the float valve (2), the soil water enters the well (1). In the well (1), the soil water accumulates, rises and maintains the soil water level at the height at which the upper edge of the top tab of the well (1.4) is. Soil water also accumulates in the drainage pipes and thus in the float valve (2) until it reaches the float (2.7). The float (2.7) rises and the valve (2.8) closes. When the float (2.7) is fully raised, the valve (2.8) is also fully closed. In this case, the float valve (2) closes the soil water flow through the drainage pipes, so that the soil water level is different in front of and behind the float valve (2). Between the float valve (2) and the well (1) is the soil water level as the water level in the well (1). In front of the float valve (2), the soil water level is higher because the water is not removed by the drainage pipes. In this way, the float valve (2) raises the soil water level in the drainage system. When the soil water level is raised to the set height, water builds up before the float valve (2) accumulates, thus opening the valve (2.8) and part of the water drains into the well (1) where it is removed. When the soil water level in front of the float valve (2) drops, close the valve (2.8). The float valve (2) is designed in such a way that there is a balance between the water pressure in the soil in front of the float valve (2) and the lifting capacity of the float (2.7). Increasing the lifting capacity of the float (2.7) will increase the water level in the soil in front of the float valve (2) accordingly. Thus, the valve (2.8) is opened or closed by two forces acting in opposite directions, and when they equalize, a correspondingly raised soil water level is maintained in front of the float valve (2). The higher soil water level in front of the float valve (2) does not adhere exactly to the float valve (2), some of the water flows above the float valve (2). Therefore, in order to raise the soil water level in the drainage system a lot, several float valves (2) need to be installed, depending on the difference in terrain heights.

The automatic method of regulating the soil water level has the following steps:

- soil water enters the drainage pipes and the float valve body (2.1);

- the valve (2.8) is open, so that the soil water enters the tank of the well (1) containing the water inlet (1.1.1) via the float valve (2);

- in the tank of the well (1) with the water inlet hole (1.1.1), the soil water accumulates and rises upwards until it reaches the upper tab (1.4);

- the soil water flows through the upper edge (1.4) of the upper tab into the tank on the side of the well (1) containing the drainage hole (1.1.2) from which it is removed;

- the equilibrium of the soil water level in the soil and in the well (1);

- if water accumulates in front of the float valve (2), the soil water raised in the float valve (2) raises the float (2.7);

- the float (2.7) closes the valve (2.8);

- the soil water rises in the soil area in front of the float valve (2);

- the raised soil water, due to the pressure created in the valve (2.8), overcomes the resistance of the float (2.7), opens the valve (2.8);

- the soil water flows through the float valve (2) into the tank of the well (1), which has a water inlet hole (1.1.1);

- the float (2.7) closes the valve (2.8) because the water pressure in the valve (2.8) decreases and the water in the float valve (2) raises the float (2.7);

- equilibrium: in the soil area between the float valve (2) and the well (1), the soil water level is at the height of the top of the upper tab (1.4); and the water level in the soil area in front of the float valve (2) is raised.

Thus, when the soil relief is level, the automatic soil water level regulation system has drainage pipes and a water level control well (1). When the terrain is uneven, the automatic soil water level adjustment system has drainage pipes, a water level control well (1) and a float valve (2). The number of float valves (2) depends on the soil relief: the greater the height differences, the more float valves (2) the system will need to maintain the soil water level in the plant root zone. Thus, thanks to drainage pipes, a well (1) and float valves (2), water in the soil is in the root zone of the plant during the dry season, and after rain or in other cases, excess water can be drained quickly. The soil water level is adjusted both automatically and manually by removing or adding tabs (1.4).

A specific example showing the number of float valves (2) is not limited to the following. If, in the case described, the terrain of the soil in which the drainage system is installed is uneven, the automatic soil water level control system consists of drainage pipes, a well (1) and float valves (2). The number of float valves (2) depends on the soil relief. If there is a 90 cm height difference in the drainage system, 3 float valves (2) must be installed, one at a height of 30 cm.

These examples provide a system for the automatic regulation of soil water levels. In order to illustrate and describe the present invention, a description of the most preferred embodiments is provided above. The dimensions, materials, method of connection, number of parts themselves and other parameters in the description may vary - the description should be considered as an illustration and not as a limitation. It is not an exhaustive or restrictive description intended to determine the exact form or embodiment. The above description should be considered as an illustration rather than as a limitation. Obviously, many modifications and variations can be apparent to those skilled in the art. an embodiment is selected and described in order for those skilled in the art to best explain the principles of the present invention and their best practice for different embodiments with different modifications suitable for a particular use or application. It is intended that the scope of the invention be defined by the definition appended thereto and its equivalents, in which all the above terms have the broadest meaning, unless otherwise indicated.

Modifications may be made to the embodiments described by those skilled in the art without departing from the scope of the present invention, as defined below.

Claims (10)

DEFINITION OF THE INVENTION 1. An automatic soil water level control system comprising drainage pipes, a float valve (2) and a water level control well (1), characterized in that the water level control well (1) has the following components: - well body (1.1); - the bottom (1.2); - the lid (1.3); - tab (1.4), - side profile (1.5); and the float valve (2) has the following components: - float valve body (2.1); - rear cover (2.2); - front plate (2.3); - mounting plate (2.4); - rear lever (2.5); - front linkage (2.6); - float (2.7); - the valve (2.8); - hinge (2.9); - fasteners (2.10); - valve gasket (2.11); - valve opening for air extraction (2.12); - a screw plate to ensure the tightness of the valve gasket (2.13). 2. An automatic soil water level control system according to claim 1, characterized in that the body of the water level control well (1.1) is cylindrical with a circular cross-sectional shape. 3. An automatic soil water level control system according to the preceding claims, characterized in that the water level control well (1.1) has a bottom (1.2) which is wider than the housing (1.1), so that the well (1) is stable. 4. An automatic soil water level control system according to the preceding claims, characterized in that the water level control well (1) has a lower tab (1.4) fixedly and tightly attached to the side profiles (1.5) and the bottom (1.2); and at least one more tab (1.4) which is sealed or otherwise attached to the side profiles (1.5); the tabs (1.4) are stacked on top of each other and can be removed. 5. An automatic soil water level control system according to the preceding claims, characterized in that a spacer (1.4.1) or other sealing material is fastened to the entire perimeter of the tab (1.4) by means of plates, which is mechanically tightened by plates (1.4.3), therefore the tabs (1.4) can be placed tightly on top of each other. 6. An automatic soil water level control system according to the preceding claims, characterized in that the side profile (1.5) of the water level control well has a cavity facing the inside of the well (1) and is fixed to the inner wall of the well body (1.1) in a vertical position that the tab (1.4) can be tightly inserted in the cavity. 7. An automatic soil water level adjustment system according to the preceding claims, characterized in that the front plate (2.3) has a threshold - the edges of the hole are raised above the front plate (2.3) - and / or have a slope at the bottom of the hole, so that no deposits form on the front plate. (2.3) at the bottom. 8. An automatic soil water level control system according to the preceding claims, characterized in that there is a valve gasket (2.11) around the hole in the front plate (2.3), which rises above the front plate (2.3) and is sealed by the plates (2.13), so that no plaque around the hole. 9. An automatic method for regulating the soil water level using an automatic regulation system according to the preceding claims, characterized in that the automatic method for regulating the soil water level has the following steps: - soil water enters the drainage pipes and the float valve body (2.1); - the valve (2.8) is open, so that the soil water enters the tank of the well (1) containing the water inlet (1.1.1) via the float valve (2); - in the tank of the well (1) with the water inlet hole (1.1.1), the soil water accumulates and rises upwards until it reaches the upper tab (1.4); - the soil water flows through the upper edge (1.4) of the upper tab into the tank on the side of the well (1) containing the drainage hole (1.1.2) from which it is removed; - the equilibrium of the soil water level in the soil and in the well (1); - if water accumulates in front of the float valve (2), the soil water raised in the float valve (2) raises the float (2.7); - the float (2.7) closes the valve (2.8); - the soil water rises in the soil area in front of the float valve (2); - the raised soil water, due to the pressure created in the valve (2.8), overcomes the resistance of the float (2.7), opens the valve (2.8); - the soil water flows through the float valve (2) into the tank of the well (1), which has a water inlet hole (1.1.1); - the float (2.7) closes the valve (2.8) because the water pressure in the valve (2.8) decreases and the water in the float valve (2) raises the float (2.7); - equilibrium: in the soil area between the float valve (2) and the well (1), the soil water level is at the height of the top of the upper tab (1.4); and the water level in the soil area in front of the float valve (2) is raised. 10. An automatic method for adjusting the soil water level according to claim 9, characterized in that the soil water level in the well (1) can be adjusted manually by changing the number of tabs (1.4) in the well (1).