ITBO970272A1 - METHOD AND DEVICE FOR SOIL IRRIGATION. - Google Patents

Description

DESCRIPTION

of the patent for industrial invention

The present invention relates to a method for irrigating land.

Currently, in particularly arid areas or areas with reduced availability of water for irrigation, it is known to water the plants with the "drop by drop" method, which consists in positioning a respective dispenser in correspondence with each plant to be watered, which is connected via a network of pipes to a pressurized water supply unit. When water under pressure circulates inside the network of ducts, a succession of drops of water come out of each dispenser and fall near the plant, watering it.

The main drawback of the method described above is that of requiring relatively expensive and unreliable devices for its implementation. First, the method described above requires a dispenser for each plant, so the network of ducts is relatively large, and must be fed by a large power supply unit capable of delivering water at a relatively high pressure, so that to counteract the considerable pressure drop inside the ducts. Furthermore, each dispenser is usually provided with a capillary tube to bring the water to the plant, and this capillary tube is often subject to clogging due to the hardness of the water or because of the fertilizers that can usually be dissolved in the water to favor the plant growth. Finally, in the "drop by drop" method, part of the water that is dispensed does not reach the ground and the plant, but is instead dispersed into the surrounding environment by evaporation.

The aim of the present invention is therefore to provide a method free from the drawbacks described above.

According to the present invention, a method is provided for the irrigation of characterized soils

made up of comprising the phases of:

- drive at least one dispensing device into the ground in correspondence with the portion of land to be irrigated

connecting said dispensing device to a pressurized liquid feeding unit through at least one connection duct; And

by means of the said dispensing device, to make the said liquid percolate inside the ground, creating a plurality of capillary flows in the ground itself.

The present invention also relates to a device for irrigating land.

According to the present invention, a device for the irrigation of land is provided, characterized in that it comprises a tubular body having a first end portion, which is adapted to be driven into the ground, and a second end portion, opposite to the first, which is provided at the top with fluid-tight closing means; said second end portion being connected to a pressurized liquid supply unit; the said tubular body being filled at least partially with a granular filling material through which the liquid under pressure percolates into the ground.

The present invention will now be described with reference to the attached drawings, which illustrate a non-limiting example of embodiment, in which:

Figure 1 schematically illustrates an irrigation unit made according to the dictates of the present invention;

Figure 2 is a front elevation view, with parts in section and parts removed for clarity, a detail of Figure 1; And

Figure 3 is a front elevation view, with parts in section and parts removed for clarity, a variant of the detail illustrated in Figure 2.

With reference to Figure 1, the number 1 indicates as a whole a dispensing device adapted to be used in an irrigation unit 2 which comprises, in addition to a plurality of dispensing devices 1, also a supply unit 3 for pressurized liquid (preferably , but not necessarily, water), which is connected to the dispensing devices 1 by means of a pipe 4. In the illustrated example, the devices 1 are connected to each other in cascade by means of respective pipes 5, and the power supply unit 3 is connected through the pipe 4 preferably, but not necessarily, to only one of the dispensing devices 1.

With reference to Figure 2, each dispensing device 1 comprises a tubular body 6 which extends coaxially to an axis 7, and has two opposite end portions, indicated respectively with 6a and 6b, the first of which is suitable for being driven into the ground 8, the second of which protrudes from the ground 8 itself and is provided with a plug 9, which is screwed to the end of the end portion for the fluid-tight closure of the tubular body 6 itself. The tubular body 6 is filled at least partially with a granular filling material 10 consisting preferably, but not necessarily, of a mixture of sand, fine gravel, and possibly fertilizer.

The end portion 6a is provided externally with a plurality of flexible fins 11 which prevent the extraction of the end portion 6a itself from the ground 8.

The end portion 6b, on the other hand, is provided with a plurality of sleeves 12, which extend from the tubular body 1 perpendicular to the axis 7, communicate with the interior of the tubular body 1 itself, and are able to make a rapid connection with the pipes 4 and / or 5. In the illustrated example, the cap 9 is also provided with a respective sleeve 12 similar to those present on the end portion 4b. Inside each sleeve 12 there is a respective valve 13 which allows the passage of the liquid from and towards the inside of the tubular body 6 only if a pipe 5 is connected to the sleeve 12 itself.

According to a first variant illustrated in figure 3, the sleeves 12 are devoid of the respective valve 13 and are instead provided, each, with a respective tap 14 through which it is possible to prevent the passage of liquid inside the sleeve 12.

According to a further variant not shown, the tubular body 6 is made of transparent material to facilitate the control of the level of the filling material 10 inside the tubular body 6 itself. According to a third variant not shown, the end portion 6a of the body tubular 6 and without flexible fins 11, and instead has at least one rib which extends on the external surface according to a substantially helical profile.

In use, after having established the distribution of the dispensing devices 1 according to the type of irrigation to be carried out, each device 1 is driven into the ground 8 in such a way that its end portion 6a is totally below the surface 15 of the land 8 itself. Subsequently, before the dispensing devices 1 are connected to each other and to the pressurized liquid supply unit 3 via the pipes 4 and 5, each device 1 is filled at least partially with the granular filling material 10, which can possibly include fertilizer material.

Once the connection of the devices 1 to the supply unit 3 is completed, the supply unit 3 itself in succession fills the inside of each dispensing device 1 with liquid, and then brings the liquid itself to a pressure determined in such a way as to force the liquid to percolate into the ground 8 through the filling material 10. During the percolation phase, the liquid advances into the ground 8 dividing itself into a plurality of capillary streams 16 which branch off from each device 1 in all directions, always remaining below the surface 15 of the land 8 itself

The main advantage of the method described above is to significantly reduce the extension of the network of pipes 4 and 5 that connect the power supply unit 3 to the devices 1, since each device 1 is able to irrigate an upper portion of soil 8 to the irrigable one with a similar dispensing device used in the "drop by drop" method. The dispenser device 1 described above is not subject to clogging as it does not have capillary tubes, moreover it has the advantage of allowing controlled fertilization of the soil 8, since each dispensing device 1 can contain an amount of fertilizer depending on the characteristics of the surrounding soil 8 , or plants close to the device 1 itself.

Furthermore, the method described above has the further advantage of requiring the irrigation liquid to be fed with a relatively low flow rate, allowing the use of feed pumps readily available on the market at low costs.

Finally, the method described above has the advantage of drastically reducing the quantity of liquid dispersed by evaporation in the external environment, allowing to reduce the size of any storage tanks for the irrigation liquid. In fact, the irrigation liquid is introduced into the ground 8 below its surface 15, which is known to be the part with the highest temperature.

Claims (1)

R I V E N D I C A Z I O N I Device (1) for irrigation of land (8) characterized in that it comprises a tubular body (6) having a first end portion (6a), which is suitable for being driven into the ground, and a second end portion (6b), opposite to the first (6a), which is provided at the top with fluid-tight closing means (9); said second end portion (6b) being connected to a pressurized liquid supply unit (3); the said tubular body (6) being filled at least partially with a granular filling material (10) through which the liquid under pressure percolates into the ground (8). Device according to claim 3, characterized in that said first end portion (6a) is provided externally with anti-extraction means (11) to prevent the extraction of said first end portion (6a) from the ground (8). Device according to claim 3, characterized in that at least a part of said filling material (10) consists of fertilizing material. Device according to claim 3, characterized in that said second end portion (6b) is provided with at least one sleeve (12), which is able to couple with a respective connection duct (4, 5) inside the which said feeding unit (3) feeds liquid under pressure; each said sleeve (12) communicating with the interior of the tubular body (6). Device according to claim 3, characterized in that said closing means (9) comprise a lid (9) which is screwed tightly to the fluid on top of said second end portion (6b). Device according to claim 7 characterized by the fact that said cover (9) is provided with a respective sleeve (12), which is able to couple with a respective connection duct (4, 5) inside which said unit feed (3) feeds liquid under pressure; the said sleeve (12) being communicating with the inside of the tubular body (6). Device according to claim 6 or 8, characterized in that said sleeve (12) is provided with interception means (13, 14}, which are adapted to selectively prevent the passage of said liquid inside the sleeve (12) . Device according to claim 3 characterized in that said tubular body (6) is made of transparent material.