HU195389B - Tubing structure for draining water being on or in the soil and getting-in water and other liquid into soil - Google Patents

Abstract

Field of the Invention The present invention relates to a pipeline structure for draining water in the soil or soil, and for discharging water and other liquids into the soil having a liquid-permeable opening and a fluid-flow internal channel portion. The pipe structure according to the present invention is essentially in the form of a plurality of rows in the upper part of the longitudinal center plane of the tubular inner space (8), in the upper part of the longitudinal central plane of the tubular interior (8), on the outer surface of the upper wall portion. 50-90% of a fluid transfer opening (2) occupying a fluid-permeable, porous filter layer (8) that forms a liquid inside the fluid transfer orifices (2) adjacent to the inner surface of the barrier wall (1). (7). co - ΰ -1-

Description

FIELD OF THE INVENTION The present invention relates to a pipeline structure for drainage of water in or on soil, and for the delivery of water and other liquids to a soil having a fluid-through opening and a fluid-carrying internal channel portion.

Soil tunnels have long been used to drain and irrigate stagnant water bodies on the soil surface and in the soil. Basement drainage is mainly used in agriculture but has also been used for flood protection purposes. Crop crops grown in agriculture cannot withstand damage if their foliage is covered with water for an extended period of time and excessively high groundwater renders their root system unable to perform their function. If the water in the dams around the rivers gathers and leaks, the dam will lose its strength and break.

Known basins are generally made of rigid, fragile, practically evenly distributed in the villages, with relatively small water permeability openings, and are installed at depths of 50 to 160 cm, so that there is a thick layer of soil above the basement. The mistake of this deep laying is that it takes 3 to 10 hours for the water collected on the surface of the soil to get into the tunnels, so that the foliage of the crops is under water for so long that it damages them. The water leakage time into the drainage pipes, in addition to the laying depth, depends on the structure of the soil, pore volume, particle size, water permeability, etc. dependent.

During drainage, the dusty portions of the soil washed away from the soil migrate towards the tunnel, adhere to the small permeable openings on both sides, and reduce the cross-section of the openings, even if the shale layers and after they become inoperable. Thus, the main cause of rapid blockage is that the water-through openings have a small cross-section and that the soil layer above the basin is thick, from which many small particles of soil may migrate to the water-through openings.

Known methods of plumbing can also be damaged by the fact that water bodies that stagnate due to the usual formation of tunnels and deep laying can accumulate in the part of the soil where the crop roots are located and cannot function due to the stagnant water mass.

Known basins are not suitable for irrigation. The usual trickling, flooding, dripping, spraying etc. In irrigation methods, water is applied to the soil surface and leaks into the soil. 60-75% of the water used is evaporated from the surface of the soil and remains unused, so it would be beneficial to transfer the water directly to the soil. This problem has already been tried by tunneling, but not with great success, because the known design of the tunnels causes the irrigation water to flow suddenly and quickly into the surrounding soil and leak out in all directions, so that only part of the introduced water reaches the root of the plants. only part of it is utilized. It is also a mistake that the basin pipes are usually at a great depth away from the main root mass, so that the irrigation water only reaches the root system after a long time and in a small percentage.

Known underground pipes on the hillside cannot be used for irrigation with rainwater at all. Rainwater falling on the 2 hillsides flows quickly to the soil surface, causing soil erosion and washing the plants out of the soil. There is no time for the water to seep through the soil into the known basins, here or at a collection point that can be used for irrigation later.

It is also disadvantageous to install known basement pipes at relatively large depths because it takes a lot of work and energy to create the deep trench required for installation. Relatively high depth installation in known basement pipes is unavoidable, because in case of possible installation near the ground surface, heavy machinery running on the ground would crush the fragile, relatively brittle materials (concrete, steel, plastic, ceramic, etc.).

SUMMARY OF THE INVENTION It is an object of the present invention to provide a pipeline structure for drainage of water in or on soil, and for transferring water and other liquids to soil, which can be laid in close proximity to the soil surface and in direct contact with the ground airspace. they can pass through without damaging the pipeline structure, and thus begin to drain water that accumulates on or near the soil surface within 10 to 15 minutes of being formed, storing all or part of the water that can be used for irrigation, clean water or nutrient medium introduced into the interior for irrigation directly to the main root mass of the crop plants, utilizing the water and nutrient medium as a whole, allowing air, introduction of the gene into the soil and through it to the main root mass, rapid drying of the soil surface layer prior to harvest, thereby reducing the moisture content of the cereal crop, thereby facilitating harvesting, heating and cooling of the soil layer close to the and its rapid proliferation, and whose fluid-permeable openings cannot be blocked by the fine particles of any structural soil.

SUMMARY OF THE INVENTION The present invention solves the object of the present invention by providing a piping structure having a fluid-through opening and a fluid-flowing internal channel portion, characterized in that it extends over one or both sides of the longitudinal median plane of the tubular interior space In addition, there is a fluid-permeable porous filter layer formed in several rows, having fluid passageways of 50-90% of the outer surface of the upper wall portion, and an inner surface of the shape-retaining wall covering the passageways within, conducting a fluid-enclosed tubular space.

Further, at least the upper part of the wall is slit over the shape-retaining wall along the longitudinal vertical central plane, and the two halves of the upper part of the wall on each side of the longitudinal vertical central plane are longitudinally spaced by snap-like fasteners. is reinforced.

It is also typical that the shape-bearing wall has a bulbous shape set on a large diameter end perpendicular to its longitudinal cross-section, with its upper split neck and its rim protruding from the ground.

195,389

In a preferred embodiment, the two halves of the upper part of the shape-retaining wall on either side of the longitudinal vertical central plane protrude from the ground to the same height.

In another embodiment, the two halves of the upper part of the shape-retaining wall on either side of the longitudinal vertical central plane protrude from the soil at different heights and have a concave surface with fluid-carrying openings on the side of the lesser protruding half of the shape. , which extends along the length of the form-retaining wall.

In one preferred embodiment, there is a barrier, which is perpendicular to the longitudinal direction and extends longitudinally spaced from one another to the inner surface of the underside of the underside of the shape-retaining wall.

Advantageously, the ends of the several-meter-long sections of the shape-retaining wall are connected to one another or successively by snap-like fasteners, and from each of the sections of the shape-retaining wall extends their inner space to the ventilation ducts.

In the case of high groundwater it is advantageous to have an embodiment in which the bulb has an upwardly open, substantially semicircular cross-sectional channel underneath a cross-sectional shape-retaining wall, and on both sides an upwardly opening, substantially triangular cross-sectional channel, and a central, semi-circular cross-sectional channel is provided with a barrel-shaped, porous filter-like porous filter layer forming a closed tubular space that conducts fluid inside, the upper portion of which is located on the underside of the bulb's cross-sectional wall.

Preferably, the duct structure for use in the barrier has a quarter wall shaped cross-sectional wall, the solid sides coinciding with the radii of the quarter wall sections form an L-shaped wall portion, the circumferential curved portion of the quarter section , the curved wall portion is secured to a load-bearing lattice support and to the L-shaped wall portion, and wherein at least the vertical portion of the L-shaped wall portion and the porous layer of the wall portion and the L-shaped wall portion is located adjacent to the inside of a curved wall portion having openings.

Another feature of the present invention is that it has a substantially egg-shaped, cross-sectional, two-part shape-shaped retaining wall, the lower wall portion having solid openings and the upper wall portion having fluid passage openings, and the lower and upper wall portion having grooves along the horizontal dividing plane. and are laid on top of each other with their matching ribs and in some known manner joined together.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The pipeline structure of the present invention is described in detail by way of example in the drawings. Embodiments of the Invention.

Figure 1 illustrates, by way of example, a pipe structure according to the invention. In its embodiment, a schematic perspective view, partly in section, of a section thereof.

Figure 2 is a schematic perspective view, partly in section, of an embodiment of a pipeline structure for use on a hillside.

Figures 3 and 4 are schematic perspective views, partly in section, of a section of an embodiment of a piping structure, which may be advantageously used for draining water that flows into protective ditches and where the latter is filtered.

The shape-retaining wall 1 of the pipeline structure shown in Fig. 1 is shaped and has an onion-shaped cross-section at its thicker end. The material of the shape-retaining wall 1 is preferably plastic and at least the upper part of the shape-retaining wall 1 is resilient and flexible. The shape-retaining wall 1 is completely identical on both sides of its longitudinal vertical symmetry plane. The lower part of the shape-retaining wall 1 extending approximately one-third of its height is solid, i.e. there are no openings. The upper, about two-thirds, have fluid passageways 2 in successive rows having a total surface area of 50-90% of the total surface area of the same length of the upper part of the shape-retaining wall 1, i.e., fluid passageways 2 are . The fluid passage openings 2 may have the shape of a triangle, an obtuse angle, a rhombus, or other forms as appropriate.

The upper, small-width neck part 3 of the shape-retaining wall i is in close proximity to the surface of the ground and the edges 4 and the adjacent edges 4 protrude from the ground. In the embodiment of Figure 1, the flanges 4 are equally high. The two halves of the neck portion 3 on either side of the longitudinal vertical symmetry plane can be flexibly bent to one another or bent from one another, i.e. not directly attached to each other. The two halves of the neck portion 3 have internally hollow longitudinal ribs 5 which are secured to each other by means of snap-on fasteners 6 spaced apart at longitudinal intervals.

The porous material filter layer 7 is attached in some known manner to substantially the entire inner surface of the form-retaining wall 1. The filtering layer 7 covers the liquid-through openings 2 from the inside. Preferably, the filter layer 7 consists of layers of different plastics and allows water or other liquid to pass through and permeate relatively quickly. Inside the filter layer 7, there is a fluid-conducting closed tubular space, the upper, closed-tubular space 8 conducting water or other fluid in the same way as known pipelines.

Inside the shape-retaining wall 1 and the filter layer 7, there are longitudinally spaced dams 9 attached to the shape-retaining wall 1 which are made of a solid rigid material such as plastic. The upper horizontal edge of the dams 9 is at or slightly below the height of the lowest row of the fluid passage openings 2. Ventilation ducts 10 project from a suitable portion or portions of the duct structure to form an air flow connection between the upper enclosed tubular space 8 and the outside air space.

The form-retaining wall 1 is of course laid in the ground so that there is an appropriate slope for the flow of water or liquid in the upper enclosed tubular space 8. One end of the pipeline structure of the present invention is connected to a standard pipeline that conveys water or liquid flowing through the upper, closed tubular space 8 to the desired collection / discharge site,

195 389 lead. This connection can also be blocked in some known manner.

The pipeline structure of the present invention may also be connected to other standard pipelines and associated pipe fittings and tanks to provide irrigation water or other liquid, such as liquid manure, into the pipeline structure.

When the pipeline structure is in the ground, a portion of the neck portion 3, or at least the flanges 4, protrude from the ground. Machines can pass over the pipeline structure without damaging the pipeline structure because the neck portion 3 and the flanges 4 are flexible and resilient. When a body of water is formed on the surface of the soil, water leaks rapidly between the two halves of the neck and through the thin soil layer covering the fluid inlets 2 and the fluid inlets 2 into the filter layer 7 and then into the upper enclosed tubular space 8 -flow into collection space. After drainage of the surface water body, some of the water remains between the 9 dams, which provides an opportunity to create optimal living conditions for microorganisms and bacteria useful for agriculture. By opening the ventilation ducts 10, air, oxygen, can be circulated to the upper closed tubular space 8, from where it enters the main root mass in the vicinity of the fluid inlets through the filter layer 7 and the fluid inlet 2. By introducing air, the soil layer containing plants can be cooled, heated and dried.

When used for irrigation, the connection between the pipeline structure and the drain pipe connected thereto is broken, the drain pipe is closed and a suitable water or nutrient solution is passed through a suitable pipe into the upper closed tubular space 8 through which the filter passages 7 and to the soil layer next to the fluid inlets and the main root mass. Thus, nothing is evaporated from the irrigation water, the irrigation water and the nutrient are utilized at 100%, the plant always gets the right, optimal amount of them and the nutrient does not pollute the environment.

Occasionally, there is a build-up of stagnant water, not on the surface of the soil, but inside the soil, which is harmful to the plant. For example, if the groundwater is so high that the roots of the plants are in the water, the root system can no longer perform its function and will rot. The fluid passage openings 2 in the form-retaining wall 1 are substantially at the height and depth of the main root mass, so that the high groundwater cannot enter the upper, closed space 8 quickly and without damage. To counteract this phenomenon in agricultural areas where the groundwater is high, a virtually semi-circular cross-sectional channel open below the onion cross-sectional shape-retaining wall 1 and a substantially triangular cross-sectional channel open upwardly on either side thereof. There are 11 troughs. In the central, semi-circular cross-sectional channel of the trough 11, a barrel-like, porous, filter-like, filter-like, porous filtering layer 13 is formed along with its all-trough channel for conducting liquid within it. The upper part of the filter layer 13 is located at the bottom of the wall 1 holding the shape. The outer side surfaces of the filter layer 13 may come into direct contact with the ground, but the side surfaces may also be enclosed with walls similar to the form-retaining wall 1, which also have fluid-permeable openings. Thus, high groundwater is rapidly discharged through the filter layer 13 and its enclosed tubular space 12 before rising to the root level of the plants. The trough 11 and the filter layer 13 do not perform irrigation and nutrient application to soil.

The pipeline structure of the present invention consists of sections of several meters in length, which may be joined to one another in known manner, overlapping or without overlapping.

The embodiment shown in Figure 2 is advantageously used to collect rainwater falling on the hillside and to irrigate and inject nutrient medium into the soil. 1 differs from the embodiment of Fig. 1 in that the edge 4 towards the top is lower than the other edge 4 and that the two halves of the shape support wall 1 on both sides of the longitudinal vertical symmetry plane are not identical. The upper part of the wall portion facing the hilltop is recessed, deepened towards the upper closed tubular space 8. Such a design of the flanges 4 and the two halves of the form-retaining wall 1 serves to capture a larger amount of rainwater falling on the hillside and to discharge it into the storage space.

Figure 3 is a schematic diagram of a section of a pipeline structure of the present invention which is preferably used to indicate the waterlogging of the dykes and to drain water through the dykes. Here, the shape-retaining wall 1 comprises a quarter circular cross-section and two portions consisting of a solid "L" -shaped wall portion, i.e. without fluid passageways 2, and a quarter circular arcuate wall portion 15 having fluid passageways 2. The edges of the curved wall portion 15 rest against the inner surfaces of the "L" shaped portion 14. In order to increase the load-bearing capacity of the curved wall portion 15, it may be attached to a truss 16 attached to the "L" shaped wall portion 14 and to the "L" shaped wall portion 14. The upper enclosed tubular space 8 for conducting water or liquid is again surrounded by a porous layer of fluid permeable to the liquid, not shown in the drawing, located at least on the vertical inside of the L-shaped wall portion 14 and the inside of the curved wall portion 15.

In the dams, the pipeline structure of Figure 3 is positioned with the curved wall portion 15 on the water side. The barrier may comprise a plurality of tubular structures at superimposed spaced intervals, in which case there may be plastic or similar panels mounted between the tubular structures on the outer surface of the vertical leg of the "L" shaped wall portion.

In the embodiment of Figure 3, the infiltrating water is collected and drained by plastic outlet pipes connected to the "L" shaped wall portion 14, which extend at defined distances from the side of the barrier.

The embodiment of the pipeline structure according to the invention shown in Figure 4 is mainly used for collecting and purifying wastewater. Here, the shape-retaining wall 1 is divided into two parts which can be separated from one another and fastened to one another along a horizontal plane similar to an egg. The upper wall portion 17 has fluid passage openings 2, the lower wall portion 18 being solid. The upper and lower wall portions 17 are reciprocal

They are formed with longitudinal grooves and their respective support ribs 194 on their edges 195 and can be fastened to each other in a known manner.

Such piping structures may be located at the bottom of a sewage collection vessel embedded in particulate or fibrous material such as peat or sapwood.

The most important advantageous features of the pipeline structure according to the invention are as follows:

Water bodies that accumulate on the surface of the soil and stagnant water in the soil, as well as excessively high groundwater, can be quickly drained, so that the foliage of the crop does not deteriorate, its fungus does not need to be treated you can see it will not rot. With irrigation, nothing evaporates from the irrigation water, the amount of precipitation that is drained and collected unlocks or alleviates the current water requirement, and significantly less irrigation water is used to achieve the desired effect, since the irrigation water reaches the root system directly. Nutrients can also be delivered directly to the root system, less are needed, and they do not pollute the environment. Significantly greater amounts of rainwater can be collected than before, rainwater can also be collected on the hillside, and erosion of the hillside is absent. The root system can also be supplied with air and oxygen, which is beneficial for the vegetation of the plant. The soil layer containing the plant can be heated and cooled and dried quickly for harvest. The water, liquid and filter layer remaining in the pipeline structure can provide favorable climate conditions for the development of microorganisms and bacteria that are beneficial to plants. It is significantly cheaper, less work and less energy-consuming than known hollow-tube structures, and has a long lifetime and is prone to failure.

Claims (10)

A duct structure for draining water on or in the soil, and for delivering water and other liquids to the soil having a fluid inlet and a fluid channeling inner portion, characterized by a form-supporting wall (.1) surrounding an upper closed tubular space (8). in its upper part, in one or both sides of the longitudinal median plane of the upper closed tubular space (8), in successive rows, a fluid passage (2) occupying between 50% and 90% of the outer surface of the upper wall part; beside its inner surface, there is a porous filter layer (7) covering the liquid passageways (2) and forming an upper, closed tubular space (8), which conducts the liquid inside, leading to the liquid. Piping structure according to Claim 1, characterized in that the shape-retaining wall (1) is slit above the longitudinal vertical central plane, at least the upper part of the shape-retaining wall (1) being elastic, and that the shape-retaining wall (1) 1) The two halves of its upper part on each side of the longitudinal vertical central plane are secured to one another by means of longitudinally spaced, patent-like fasteners (6). Piping structure according to Claim 1 or 2, characterized in that the shape of the bulb is onion-shaped and has its upper split neck (3) and its periphery (4), which is perpendicular to the longitudinal cross-section of the wall (I). protrudes from the ground. 4. Piping structure according to one of claims 1 to 3, characterized in that the two half portions of the upper part of the shape-retaining wall (1) on both sides of the longitudinal vertical central plane protrude from the ground at the same height, 5. Piping structure according to any one of claims 1 to 3, characterized in that the two halves of the upper part of the shape-retaining wall (1) on both sides of the longitudinal vertical median plane project from the ground to different heights and a side surface extending to a lesser extent from the ground is provided with a concave surface portion having fluid-carrying openings (2) extending along the shape-retaining wall (1). 6. Figures 1-5. Piping structure according to any one of claims 1 to 3, characterized in that the upper surface of the lower part of the shape-retaining wall (1), which is connected to the inner surface of the lower part without liquid passages (2), is perpendicular to the longitudinal direction. and having barriers (9) at defined distances. 7. Piping structure according to any one of claims 1 to 4, characterized in that the ends of the several meter long sections of the shape support wall (1) are connected to one another or successively by snap-like fasteners, and that the ventilation ducts (10) connecting to the open air space. 8. Piping structure according to any one of claims 1 to 3, characterized in that the bulb has a substantially semi-circular cross-sectional channel open upwardly in the middle of the bulb and is formed by a triangular cross-sectional channel. a trough (11) and a rod-porous filter-like porous filter layer (13) forming a closed tubular space (12) conducting a liquid therein into a central semicircular passageway, the upper portion of which has a cross-sectional shape on the bulb 1) lies on the lower surface. Piping structure according to Claim 1, characterized in that it has a shape-retaining wall (1) having substantially a quarter sectional shape, the solid "L" -shaped wall portions (14) coinciding with the radii of the quarter-sectional shape forming an "L" -shaped wall portion. the circumferential curved portion of the fourth circumferential portion being formed as a curved wall portion (15) having fluid-carrying openings (2), the edges of the curved wall portion (15) resting on the L-shaped wall portion (14), the curved wall portion (15) ) and attached to the L-shaped wall portion (14), and wherein the porous layer permeable to the liquid passageways (2), the liquid conducting inside thereof, forming an upper, closed tubular space (8), is a porous layer of at least the L-shaped wall portion. Adjacent to the vertical inner side (14) and the inner side of the curved wall portion (15) containing the fluid inlet openings (2) . Piping structure according to claim 1, characterized in that it is practically an egg cross-section 195 has a shape-retaining wall (1) divided into two horizontal and upper wall portions (17, 18) having a 389 shape, the lower wall portion (18) having solid openings, and the upper wall portion (17) having fluid transfer openings (2); the upper and lower wall portions (17, 18) being superimposed on each other and joined in some known manner along the horizontal partition plane, with edges and grooves (19) thereon.