ITUA20164991A1 - Water protection system to avoid future floods - Google Patents

Description

WATER COURSES PROTECTION SYSTEM TO AVOID FUTURE AT LUVIONI.

Description of the invention

The invention which will be explained below describes a system for positioning baffles in the riverbeds of watercourses. This system can be applied to any type of watercourse whether it is a course with large flows or a torrential type with flows of different sizes, depending on the season, or to artificial or natural watercourses of different conformation. . Utility of the invention: to prevent the formation of floods and the consequent floods forever.

Information on existing systems.

The spillways currently in use only remove parts of the water. With their designers they do not consider that if the quantity of water decreases by one part, the pressure of the remaining part remains the same because the water not removed, having a freer riverbed after the spillway, causes its speed to increase exponentially. and therefore, without the embankments being able to brake a little with friction, for a principle of physics, a smaller quantity of water with high pressure, behaves as if the spillway was not there.

Furthermore, considering the flood events that contain in the riverbed, millions of me. of water, since the overflow can only remove not many me. on the second, the remaining millions will remain on the riverbed, filling the riverbed almost to its full height and at every obstacle it finds, it overflows. If you do not find an obstacle, it is sufficient that an embankment, due to the conformation of the land, is a little lower, at that point there will still be a flood. In order to have positive effects from the spillways, it is necessary, first of all, to think about how the first spillway was designed by its inventor, and to stick to that project as much as possible. The various existing rolling barriers are huge, expensive, almost all very high, they slow down the flow of water and retain a large part of it, but they are almost always positioned in one place.

Another system, nice and simple, is composed of mini barriers in a great slope, it almost has the same system as the present one, but being very low to allow them to be easily bypassed even by a non-alluvial flow, so they do not retain large quantities of water. water and neither do they cancel the pressure, because each waterfall from one mini barrier to the next takes on more pressure than in normal conditions.

In particular, the works, especially bridges with very thick and low supporting vaults by their nature, will always stop the natural flow. In urban areas, sometimes there is, under a cover of the riverbed, a smooth concrete casting equal to its size, this in cases of normality or intense precipitations, will increase the speed of the water exponentially, which at the first obstacle of any kind, it will cause the well-known harmful consequences.

Nature considerations about the appointment.

Considering that every watercourse flows, starting from a very inclined front, then passing to a less inclined front, and then passing to an even less inclined front and then settling on a horizontal front until its final flow . Given that currently all watercourses are left free to flow without considering that the works carried out by mankind can pose obstacles to the natural flow. In these cases, serious situations emerge, especially in times of intense and long rainfall with an alluvial character, such as the rise in the level of the watercourse, with the subsequent flooding. In watercourses, the present system provides for the positioning of partitions having varying heights and distances between them determined by the conformation of the watercourse itself. This system is applicable to all watercourses, large and small, natural or artificial. This system finds its simplest and most effective application in torrential watercourses which undergo strong swells due to long and intense rains. This always simple and effective intervention can also be easily applied to streams, streams and similar small watercourses. This system, ecological, simple and above all low cost of work, if applied to larger watercourses, with the interventions carried out in suitable places, no matter how intense and long the rainfall is, will no longer have forever devastating effects and will not be harmful both for the flora present and for the habitually sedentary fauna in the watercourse. In environments similar to the Mediterranean one, the current system can be applied in the terms set out. In monsoon or other environments, subject to events such as hurricanes etc., the present system needs to be partially revised, but it achieves the same purposes.

Before the first barrier, at a distance of about mt. 1.50 a low and fixed asymmetrical butterfly wing bench will be placed which will have the function of creating tubulence and circulation of water, obtaining that the silt remains in suspension without settling and then proceeds to the next.

Summary of the invention

The object of the present invention provides a non-complex, low cost and eco-friendly system for the safety of any watercourse. This system provides for a plurality of laminar-type septa (hereinafter: barriers or septa). The first 3 will have respectively heights of mt. 0.30 the first, mt. 0.40 the second mt. 0.50 the third, with proportionate feet, the fourth will be cm high. 80, its upper base will be 40 cm, the lower base cm. 80 well welded to its foot high cm. 25 and cm long. 125. From the fifth to the end, excluding the possible reef in the sea, they will have h = 100/120 cm. depending on the positioning with feet deep of cm. 20/25 and about cm long. 145 to offer greater stability, and will be placed before any transverse elements, such as bridges, walkways and the like, to protect them. All except the first and the last eventual will be provided with a passage hole protected by a filter for not fine debris and, cm. 250/300 before the septum, the fixed asymmetrical butterfly vane will be implanted, which will allow the silt to pass through the hole. All the barriers after the first four after the spring, will all be, depending on the position and the environmental impact, of a height of about mt. 100, 1.20 or better mt.

1.40 and in the shape of a rectangle trapezoid with the lower base of cm. 80/120 welded to the foot long cm. 140/160 deep about cm. 20/25 cm., The upper base will be about mt. 0.40 / 0.50. The material with which it will be built will be concrete of the plastic type, suitable for the presence in humid environments, with internal reinforcement formed by rods of ferrous material of mm.20, possibly well protected. bed of the watercourse considered. They will have the various heights indicated which are meant above ground. After the first one, all other barriers that follow will have a filter element that will prevent debris and stones from blocking the water passage hole. This filtering element, provided with a quantity of holes, will be of any material, preferably plastic, of about mt.

0.60 per mt. 0.50, welded to the front of the barrier at the water outlet hole. In this way the passage of water without impediments will be favored. In the sloping riverbed they will be placed at about m. 4.50 one from the other the first from the second and m. 3,4 or 6 between the second and the third, these will be very robust barriers always in the shape of a rectangle trapezoid and about m high.

0.30 / 40/50 at m. 6 or 10 first from the following, with the function of retaining both the transported material and the quantity of water, the silt will not settle with the previous insertion of cm. 250/300 of an asymmetrical butterfly-shaped fixed vane which, by creating a state of turbulence, will have the silt in suspension and therefore be able to pass through the filter and the hole. The first will be placed after the source where the current begins to pick up speed and will have a v in the upper part in the center to allow the water to exit, before it, at about cm. 0.80 / 100 an asymmetrical banderula with a cassymmetric butterfly will be placed which, with the turbulence, will favor the flow of even a large part of the silt. The barrier following the first low ones, about 1 meter high, very robust, will allow a better seal of the barrier. In all barriers, in the absence of adequate embankments, an inverted T shape will be placed on both sides to guarantee the possibility of anchoring the barrier. They will be slightly higher than the barrier and slightly wider than the upper barrier width.

U Their support foot will have a total length of about mt. 1.80, so that the foot has great stability.

Another aspect of the system foresees at the end of the watercourse, only in the case of an estuary outlet to the sea, a barrier will be placed with the shape of a rectangle trapezoid very similar to the previous ones only with a greater height, equal to mt. .1.50. It will have the task of giving water to the sea, even when the waves of a rough sea can prevent access. From this height the water will behave as in a waterfall, and therefore will give the sea without any hitch. In the case of an outlet to the sea, this must be the first job carried out, as all the following work, starting from the point closest to the source, will move material that will fill the difference in height between the riverbed and the last barrier. . Then the first three barriers will be placed upstream from all the others, and then to descend, one after the other until the last one, just before the confluence of various types.

Brief description of the drawings

Figure 1 shows how the barriers (8-7-6-5-4-12) must be placed in the various floors 1,2,3

Drawing 2 shows (8) with the inverted V, (7-6), with the hole (10) the filter

Claims (6)

Claims 1. Watercourse protection system consisting of partitions of various confor mation placed along the watercourse in the very steep plane 1), in the less steep plane 2), and in the almost horizontal plane 3). 2. System according to claim 1 wherein the septum (8) has an upper central V-shaped opening (16); the septa (7-6) have a lower central hole (10) and a filter (13). The partitions (8) (7) (6) are all placed along the floor 1) and welded to both natural and artificial embankments (14). 3. System as per claim 1 where the septum (4), along the plane 2, is larger than the septa (8-7-6). 4. System as per claim 1 where the septa (5) larger than (4) and smaller than any septum (12), placed before the estuary along the plane (3). 5. System as per claim 1 where in the floors 1) 2) and 3) in correspondence of each partition, there is the presence of natural or artificial embankments (14) and the conformation of the walls (5) with the foot (16) , the hole (10) and the filter (13). 6. System according to claim 1 where it can be seen that along the plane 1) before the partition (8) a fixed and low vane in the shape of asymmetrical butterfly wings (15).