ITBO20010122A1 - WELL WITH TANK AND METHOD TO REALIZE IT - Google Patents

Description

WELL WITH TANK AND METHOD TO MAKE IT.

DESCRIPTION OF THE INVENTION

The present invention is part of the technical sector concerning wells for drawing water from the water table. In particular, the invention refers to a well with a cistern and to a method for making it particularly suitable for deep aquifers, to ensure a high flow rate and water hygiene even in tropical climates and in unhealthy areas.

Wells are known with large diameter, for example 2 meters, and low depth, of the order of a few tens of meters, or of depth of the order of hundreds of meters, but with a diameter contained in a few decimeters to provide, respectively, high flow rates or collection from even deep layers.

In known wells, the water is withdrawn by means of a pump, for example manual or motorized, or other means of lifting the water.

Generally, the walls of known wells are permeable almost along their entire vertical development, allowing water to enter from aquifers at any depth.

In known wells, the water withdrawn is possibly treated for purification and introduced directly for consumption or pumped into elevated tanks of large capacity, including pylons or towers, for accumulation and to feed, with water under pressure, a water network of distribution.

The main disadvantage of known large diameter wells consists in the fact that they can withdraw water only in the presence of shallow or shallow aquifers which, if present, are often subject to pollution or contamination. Furthermore, said wells are expensive to execute.

The main disadvantage of known wells of great depth consists in the fact that they are subject to clogging, facilitated by the small diameter, and are difficult to maintain and costly to build.

A further disadvantage consists in the fact that all known wells generally draw water at any depth. Therefore they also receive surface or shallow water which can be subject to constant or sudden and uncontrolled contamination with serious health risks for direct or indirect users of the water.

Another disadvantage of known wells consists in the fact that any water accumulation occurs in the raised tanks which are expensive to build. Furthermore, raised tanks require constant control and maintenance made difficult by their elevated location; this work requires competent and specialized personnel, sometimes lacking and always expensive.

Another disadvantage of known wells equipped with raised reservoirs consists in the fact that in tropical climates, the water in the reservoirs can reach excessively high temperatures causing substantial losses due to evaporation; moreover, the light, filtering through the walls of the tank itself, for example in fiberglass in a resinous matrix, or through openings or cracks, favors the growth of algae which can clog the pipes.

Another disadvantage of these well-known wells consists in the fact that often the tanks, due to even small openings, are colonized by mosquito larvae or other harmful and dangerous insects without the workers being able to easily verify their presence and without particular being taken. precautions against infestations. In fact, the use of toxic or repellent products in water intended for human consumption is generally not permitted, nor can the traditional methods used in some countries be used, consisting, for example, of introducing insectivorous fish or amphibians into the water because they they do not survive the high temperatures reached in overhead tanks.

A further disadvantage of these well-known wells equipped with an elevated storage tank is that the latter is completely exposed to weather events, in particular to the wind which, especially in the monsoon and tropical regions, can cause very serious damage.

The main disadvantages of the known methods for constructing wells are the high cost of the excavation and the dimensional limitations of the latter. In fact, the known methods of excavating large diameter wells involve the exhaustion of the excavation debris by lifting it through containers fixed to the lower end of the drilling rods. This involves frequent and costly interruptions of the excavation and stringent limits in the depth of the latter.

The known methods of digging deep wells provide for the evacuation of excavation debris through water circulation. This method involves the use of very expensive equipment and is therefore very expensive. Furthermore, this method does not allow to carry out excavations with a diameter greater than decimetres, limiting the flow rate and causing the risk of clogging the well.

The main purpose of the present invention is to propose a well with a cistern, and a method for making it quickly and economically, capable of ensuring a high withdrawal of water even at great depths, of the order of hundreds of meters, avoiding entry of surface waters and waters of shallow aquifers.

Another purpose is to propose a well, even very deep, which minimizes the risks of occlusion and clogging and which is equipped with a high capacity tank for optimal water conservation and which is protected from meteorological events in particular from the wind and which is scarcely sensitive to telluric phenomena.

Another purpose is to keep the water at a relatively low temperature and prevent or at least reduce the growth of algae.

Another purpose of the present invention is the ease of closing and repairing any cracks and openings in the tank to prevent the entry of insects, animals, objects or light, and which allows traditional or biological methods of fighting infestations.

The above objects are achieved in accordance with the content of the claims.

The characteristics of the present invention are highlighted below with particular reference to the attached drawing tables, in which:

Figure 1 illustrates a schematic view in longitudinal section of the preferred embodiment of the well with cistern object of the present invention;

- figure 2 illustrates a transversal section according to the plane Π - Π of figure 1;

- figure 3 shows a schematic view in longitudinal section of a variant embodiment of the well of figure 1 in which some parts have been removed to better highlight others;

- figure 4 illustrates a schematic view in longitudinal section of a further variant of the well with cistern in which some parts have been removed to better highlight others;

Figure 5 illustrates a schematic view in longitudinal section of a second embodiment of the well with cistern in which some parts have been removed to better highlight others;

- figure 6 shows a schematic view of means for making the well in which some parts have been removed to better highlight others.

With reference to Figures 1 and 2, 1 indicates a well object of the present invention comprising a withdrawal portion 26 and a tank 2 provided with a cylindrical wall.

The withdrawal portion 26 substantially consists of an almost cylindrical and vertical cavity obtained in the subsoil and equipped with a jacket 4.

The cavity extends to the depth of an aquifer from which water must be drawn. The sampling portion 26 has a diameter of between 0.5 and 3 meters and a depth of between 50 and 1500 meters.

The tank 2 is partially buried and superimposed on the withdrawal portion 26.

Tank 2 is made, for example, of concrete and has a diameter of up to over 5 meters.

A septum 3 is interposed between the withdrawal portion 26 and the tank 2 and connected with a watertight seal to the latter, creating the bottom.

The septum 3 is provided at the bottom with a cylindrical flange 13 for connection to the upper end of the jacket 4 of the withdrawal portion 26.

The jacket 4 consists of a plurality of tubular segments 27 in the shape of a straight cylinder of constant diameter made of plastic material, for example Polyethylene, interconnected by welding or gluing 56 performed manually or by automatic means. It is also envisaged that the welding 56 can take place by melting the ends of the tubular segments 27 equipped with electric heating resistors integrated in the plastic material.

The jacket 4 is equipped, in correspondence with the depth of the layer or flaps from which the water is to be drawn, with a plurality of openings 5. Outside the jacket 4, in correspondence with the openings 5, the well 1 is equipped with a drainage means 14 consisting, for example, of an approximately toroidal layer of stones or stones larger than those of the openings 5.

The tank 2 is equipped at the top with a covering means 20.

The septum 3 has a through hole 12 in a central position.

The septum 3 has an annular groove 28 which circumscribes the hole 12.

One end of a tubular means 11 is hydraulically fixed to the annular groove 28. The tubular means 11 is orthogonal to the baffle 3 and places the tank 2 in flow communication with the withdrawal portion 26 through the hole 12.

The septum 3 is also equipped with a hatch means 25 with hermetic closure.

The tank 2 is equipped at the top with a removable covering means 20.

The covering means 20 is crossed by a plurality of pipes 6, 7, 19 and carries a vent duct 23 whose end external to the tank 2 has, for example, a filter designed to prevent the passage of foreign bodies and insects or other animals.

The covering means 20 is removable to allow inspection of the tank 2. To facilitate this last operation, it is provided that the covering means 20 can be divided into two parts and that the pipes 6, 7, 19 pass through the means of cover 20 in holes made in correspondence with the division between said two parts. All the cracks and interstices, in particular those between the tank 2 and the covering means 20, between the latter and the pipes 6, 7, 19 are sealed by gasket means 24. The latter consist, for example, of bushings , rings or cords in synthetic elastic material or in vegetable fiber.

It is also envisaged that the covering means 20 can be equipped with a sealed door, known and not illustrated, above a ladder inside the tank 2 to facilitate access and inspection of the latter; to avoid the risk of falling into the tank 2 from the hatch or following the opening of the covering means 20, a protection net is provided, fixed inside the tank itself.

The well comprises a first pumping means 10 located near the lower part of the withdrawal portion 26 and connected to a first pipe 6 for feeding the tank 2.

The first tube 6 flows into water treatment means 8 through the hole 12 and the tubular means 11. The water treatment means 8 are external to the tank 2 and are connected to the latter by a second tube 7. It is also provided that the water treatment means 8 are contained within the tank 2 and flow directly into the latter.

The water treatment means 8 consist, for example, of one or more sand, carbon and ion exchange resin filters. Obviously, the type and sizing of said filters of the water treatment means 8 have characteristics that depend on the quality of the water of the sampling layer (s). In the case in which the quality of the groundwater is adequate for consumption, the first pipe 6 flows directly into the tank 2. The lower portion of the tank 2 has a second pumping means 9 connected to the outside of the tank 2 by a third pipe 19 .

The third tube 19 can, for example, be connected to a known and not illustrated piezometric tank or directly to users. It is also envisaged that the withdrawal from the tank takes place through an autoclave comprising the second pumping means 9 and the third tube 19.

Any said raised tank has the sole function of keeping the water pressure constant and therefore is of small size and capacity. The first 6, second 7 and third 19 pipes are made, for example, of polyethylene or metal.

The first 10 and second 9 pumping means consist, for example, of electric immersion pumps and are respectively fed through first 17 and second 18 level sensor means placed in series, and third level sensor means 16.

The first pumping means 10 have a maximum transverse overall dimensions smaller than the diameter of the hole 12 to allow, for example in the case of maintenance, an easy and rapid extraction from the withdrawal portion 26. In the variant of figure 3, the cylindrical wall of the tank 2 is made from a plurality of tubular elements 37 in plastic material, such as Polyethylene, cylindrical in shape, of constant diameter and mutually welded.

This variant is particularly suitable for making tanks 2 of particularly high longitudinal development, up to over 100 m.

In the variant of figure 4, the jacket 4 has decreasing diameters with increasing depth. The jacket 4 presents from top to bottom sets of tubular segments 27 in the shape of a straight cylinder of decreasing diameter. The adjacent tubular segments 27 of different diameters are connected by tubular segments 27 having a truncated cone shape.

Therefore, the withdrawal portion 26 assumes a shape tapered downwards and has an upper diameter of between 1 and 3 meters and a minimum lower diameter of between 0.5 and 1.5 meters and a total depth of between 50 and 1500 meters.

The well 1 illustrated in Figures 1 and 2 and the variants of the well 1 of Figures 3 and 4 have the same operation that provides for the actuation of the first pumping means 10 in correspondence with a condition in which the first level 17 and second sensor means 18, connected in electrical series, respectively detect a tank level lower than a predetermined maximum filling level and a groundwater level higher than a predetermined minimum value at a height higher than the draft level of the first pumping means 10.

In case of failure of the first level 17 sensor means, the water level is however limited by the tubular means 11 which acts as an "overflow".

The second level sensor means 18 prevent the harmful idle operation of the first pumping means 10.

The groundwater is pumped into the tank 2 through any treatment means 8 whose filters provide for the purification and / or descaling and / or decontamination of the groundwater.

The second pumping means 9 is operated manually or by level or pressure sensors of the piezometric tank or of the autoclave placed in electrical series with the third level sensor means 16. The latter avoids the harmful idle operation of the second pumping means 9. .

D partial burial of the tank 2 and the covering means 20 keep the water stored in the tank 2 itself at a temperature lower than the external environmental one.

The vent conduit 23 allows the balancing of the internal and external pressures of the well 1 and the filter it is equipped with in collaboration with the gasket means 24, prevents the entry of insects or foreign bodies.

The trap door means 25 allows access, for inspection or maintenance, to the withdrawal portion 26 of the well 1.

The drainage means 14 and the openings 15 allow the water from the groundwater (s) to enter the well 1 only at predetermined depths while preventing the entry of debris.

The second embodiment of the well 1 illustrated in Figure 5 provides that the tank 2 is formed laterally to the withdrawal portion 26 and that the septum 3 has no openings.

The operation of the second embodiment is substantially equivalent to that of the first. Figure 6 refers to means for implementing the method to build a well with a cistern, this method provides for:

excavating a vertical cavity 53 in the subsoil by means of auger means 50 with coupling rods 52; inserting into the cavity a tubular segment 27 of a jacket 3 with a diameter smaller than that of the cavity 53;

retaining through stop means 54 the upper mouth 55 of said tubular segment 27 at the mouth of the cavity 53;

superimpose a further tubular segment 27 on the previous one held at the mouth of the cavity;

connect the lower end of each further tubular segment 27 to the upper end of each tubular segment 27 held at the mouth of the cavity 53 until the jacket 3 reaches a predetermined flap by defining a withdrawal portion 26;

fill the gap 57 between the wall of the cavity 53 and the jacket 3 with drainage means 14, at the depth of the water table from which to draw water;

fill the gap 57 between the wall of the cavity 53 and the jacket 3 with non-draining material, at the depths at which no water withdrawal is provided;

connecting a cylindrical flange 13 for connecting a septum 3 to the upper mouth 55 of the upper tubular segment 27;

- tightly fix one end of a wall of a tank 2 to the partition 3;

making a plurality of openings 5 in the tubular segments 27 of the jacket 3 corresponding to the depths of the flap before the overlapping step;

connecting consecutive tubular segments 27 by welding or gluing 56.

Furthermore, the method provides for:

perform the overlapping and interconnection phases at interruptions in the excavation for the insertion of additional 52 rods;

excavating the cavity 53 by means of auger means 50 provided with a basket 51 sliding along the rods 52; equip the tank 2 with a covering means 20.

The method also provides for:

- equip the lower portion of the well 1 with a first pumping means 10 connected in cascade at least with a first pipe 10, with water treatment means 8 and with the tank 2;

equip the tank 2 with a second pumping means 9 connected to the outside via a third tube 19; electrically control the first pumping means 10 by means of first 17 and second 18 level sensor means placed in series and respectively located at a predetermined maximum water level in the tank 2 and at a depth lower than that of the first pumping means 10 corresponding to a predetermined minimum level of groundwater to actuate the first pumping means 10 at groundwater levels higher than said predetermined minimum groundwater level and water levels of the tank 2 lower than said predetermined maximum water level in tank 2;

- equip the tank 2 with a second pumping means 9 connected to the outside via a third tube 19; electrically control the second pumping means 9 by means of third level sensor means 16 located at a predetermined minimum level of the water in the tank 2 to prevent the second pumping means 9 from being activated at the water levels of the tank 2 lower than said predetermined minimum water level of the tank 2.

The main advantage of the present invention is to provide a well with a cistern, and a method for making it quickly and economically, capable of ensuring a high withdrawal of water even at great depths, of the order of hundreds or thousands of meters, avoiding the 'entry of surface waters and waters of shallow aquifers.

Another advantage is that of providing a well even very deep that minimizes the risk of clogging and clogging and that is equipped with a high capacity tank for optimal water conservation and that is protected from meteorological events in particular from the wind and that is scarcely sensitive to telluric phenomena by keeping the water at a relatively low temperature and preventing or at least reducing the growth of algae.

Another advantage consists in the ease of closing and repairing any cracks and openings in the tank to prevent the entry of insects, animals, objects or light, and which allows traditional or biological methods of fighting infestations.

Claims (10)

CLAIMS 1) Well with cistern characterized by the fact of including: - a withdrawal portion (26) comprising a cavity obtained in the subsoil and a jacket (4) provided with a plurality of openings (5); - a tank (2) at least partially underground and in flow communication with the withdrawal portion (26); - a septum (3) of the tank (2) connected with a watertight seal with the latter, creating the bottom; the withdrawal portion (26) being intended for withdrawing water from at least one water table; the tank (2) being intended to store the water withdrawn. 2) Shaft according to claim 1 characterized in that the jacket (4) comprises a plurality of tubular segments (27) interconnected by welding or gluing (56). 3) Well according to claim 2 characterized by the fact that the tubular segments (27) are shaped like a straight cylinder of constant diameter. 4) Well according to claim 2 characterized by the fact that the tubular segments (27) are in the shape of a straight cylinder of decreasing diameter with increasing depth and in a truncated cone shape. 5) Well according to any one of the preceding claims characterized in that the plurality of openings (5) is in correspondence with said at least one water table. 6) Well according to any one of the foreseen claims, characterized in that the well (1) is externally equipped with a drainage means (14) at least in correspondence with the plurality of openings (5). 7) Well according to any one of the preceding claims, characterized by the fact that the tank (2) is equipped at the top with a removable covering means (20). 8) Well according to claim 7, characterized by the fact that the covering means (20) carries a vent duct (23). 9) Well according to any one of the preceding claims, characterized by the fact that it also comprises a first pumping means (10) located near the lower part of the withdrawal portion (26) and connected to a first supply pipe (6) of the tank (2) ). 10) Well according to claim 9 characterized by the fact that the first pipe (6) flows into water treatment means (8) connected to the tank (2) through a second pipe (7). II) Well according to any one of the preceding claims, characterized by the fact that it also comprises a second pumping means (9) located near the lower part of the tank (2) and flowing outside the tank (2) through a third pipe (19) . 12) Well according to claims 9 and 11 characterized by the fact that the pumping means, first (10) and second (9), are of the electric type and are controlled respectively by first (17) and second (18) level sensor means placed in series, and third level sensor means (16), with the sensor means being respectively located at the maximum filling level of the tank (2), the minimum water level of the withdrawal portion (26) and the minimum level of the tank (2). 13) Well according to any one of the preceding claims, characterized by the fact that the tank (2) is arranged laterally to the withdrawal portion (26). 14) Well according to any one of claims 1 to 12, characterized by the fact that the tank (2) is superimposed on the withdrawal portion (26). 15) Well according to claim 14 characterized by the fact that the septum (3) is equipped at the bottom with a cylindrical flange (13) for connection to the upper end of the jacket (4). 16) Well according to claim 14 or claim 15 characterized by the fact that the septum (3) is equipped with a hole (12) connected to a tubular means (11) intended for flow communication between the tank (2) and the portion withdrawal (26). 17) Well according to any one of claims 14 to 16 characterized in that the partition (3) is equipped with a trap door means (25). 18) Well according to claims 9 and 16 characterized by the fact that the first tube (6) passes through the tubular means (11) and the hole (12) whose diameter is greater than the maximum transverse dimension of the first pumping means (10). 19) Well according to any one of the preceding claims, characterized by the fact that the tank (2) is equipped with a plurality of gasket means (24). 20) Well according to any one of the preceding claims characterized by the fact that the tank (2) comprises a plurality of tubular elements (37) interconnected by welding or gluing (56). 21) Well according to any one of the preceding claims, characterized by the fact that at least one of the withdrawal portions (26) and the tank (2) is made of polyethylene. 22) Well according to any one of claims 1 to 19, characterized by the fact that the tank (2) is made of concrete. 23) Well according to any one of the preceding claims characterized by the fact that the withdrawal portion (26) has a diameter between 0.5 and 3 meters and a total length between 50 and 1500 meters and the tank (2) has a dimension longitudinal up to over 100 meters and diameter up to 5 meters. 24) Method to build a well with a cistern characterized by the fact of: - digging a cavity (53) in the subsoil by means of auger means (50) with coupling rods (52); - inserting into the cavity a tubular segment (27) of a jacket (3) with a diameter smaller than that of the cavity (53); - withholding through stop means (54) the upper tucking (55) of said tubular segment (27) at the mouth of the cavity (53); - overlap a further tubular segment (27) to the previous one held at the mouth of the cavity (53); - connect the lower end of each further tubular segment (27) to the upper end of each tubular segment (27) held at the mouth of the cavity (53) until the jacket (3) reaches a predetermined flap defining a withdrawal portion (26); - fill the gap (57) between the wall of the cavity (53) and the jacket (3) with drainage means (14); - fill Γ gap (57) between the wall of the cavity (53) and the tubular segments (27) with non-draining material; - connect a cylindrical flange (13) connecting a septum (3) to the upper opening (55) of the upper tubular segment (27); - secure one end of a tank (2) to the septum (3). 25) Method according to claim 24 characterized by the fact of making a plurality of openings (5) in the jacket (3). 26) Method according to claim 24 characterized by the fact of connecting consecutive tubular segments (27) by welding or gluing (56). 27) Method according to any one of claims from 24 to 26, characterized in that the overlapping and interconnection steps are carried out in correspondence with interruptions in the excavation by repositioning additional rods (52). 28) Method according to any one of claims 24 to 27, characterized by the fact of excavating the cavity (53) by means of auger means (50) equipped with a canister (51) sliding along the rods (52). 29) Method according to any one of claims 24 to 28, characterized in that the tank (2) is equipped with a covering means (20). 30) Method according to any one of claims 24 to 29 characterized by the fact of equipping the lower portion of the well (1) with a first pumping means (10) connected in cascade at least with a first tube (10), with treatment means ( 8) of water and with the tank (2); equip the tank (2) with a second pumping means (9) connected to the outside via a third tube (19); and electrically controlling the first pumping means (10) by means of first (17) and second (18) level sensor means placed in series. 31) Method according to any of claims 24 to 29 characterized by the fact of equipping the tank (2) with a second pumping means (9) connected to the outside via a third tube (19); and electrically controlling the second pumping means (9) through third level sensor means (16)