RO127672B1 - Hydrotechnical-architectural system for protecting shores against waves - Google Patents

Abstract

The invention has to do with a hydro-technique architectural system, capable to annihilate any tsunami waves size, destined in principle to the protection of people, animals, infrastructure and the existent architecture and the coastal environment of seas and oceans. The invention is composed of a PSS system made of one or many reinforced concrete tubes (preferable having a rectangular section) (A), for discharge/intake the tsunami wave (TW). PSS system contains an intake gate (B), for the (TW), an evacuation gate (C), and two floaters (D) and (E), permitting the (TW) to enter and exit in and out to the PSS system. The entire tsunami protection system, may be built using many PSS tubes with one or several intake and evacuation gates as necessary. The PSS system can also be used for protection against tidal waves and coastal erosions.

Description

This invention relates to an architectural hydrotechnical system, for the protection of the terrestrial coasts against tsunami waves, and is intended to protect humans, animals, infrastructure, existing architecture, the environment on the coasts of the world's seas and oceans, and against coastal erosion.

The technical problem solved by the invention consists in redirecting the water flow of the waves back to the ocean, through a hydrotechnical system having a simple construction, easy to achieve and with maximum efficiency.

The architectural hydrotechnical system for the protection of the terrestrial coasts against waves, according to the invention, eliminates the above-mentioned disadvantages in that it consists of a reinforced concrete tube, provided with an entrance gate and an exit gate, both gates with structural strength characteristics. which are operated in turn, the inlet gate - by a pump float, and the outlet gate - by an inner float; the pump float is actuated by the sea or ocean water level, and the inner float is actuated by the water level accumulated inside the tube, characterized in that the inlet gate is drilled in the upper wall of the tube, in a horizontal position, and at its end towards shore, and the exit gate is made transversely, in a vertical position, at the end of the tube off the ocean, and the tube is arranged below the level of the ocean floor, with a slope lower than the slope of the ocean floor, so that the exit gate is located above the level of the ocean floor, to allow the evacuation of water accumulated inside the tube.

The advantages of the hydrotechnical system, according to the invention, are that it offers, in addition to total protection against tsunami waves with a height of 10 ... 100 m, a clear and free view of the ocean or sea, as well as people's access to surfing activities, fishing, swimming, and other water sports, in the water or on the beach, totally unobstructed access. The hydrotechnical system can generate extraordinary activities, new ideas and concepts of protection against this phenomenon, as well as new ideas to avoid other natural disasters on a global scale.

The disadvantages are limited to the construction cost, maintenance costs, as well as the investments that must be made and borne by the interested state, for the construction of such a facility, as well as the need to employ a large number of workers in several fields.

The above-mentioned disadvantages can be considered minor, given that the huge damage caused and created by this so-called tsunami disaster can be reduced to the point where they are completely eliminated.

The hydrotechnical system comes into action only when the power and height of the sea or ocean waves exceed the accepted limit, a limit known and known by the inhabitants of the respective coastal areas (the regulation limit of the system).

The following is an embodiment of the invention, in connection with FIG. 1 ... 25, which represents:

- fig. 1, overview of the installation according to the invention, with the highlighting of the component parts and of the identification areas I ... V;

- fig. 2, the representation of the four phases of the sea or ocean water level, the normal level, the withdrawn water level, the beginning of the wave formation, the formed wave;

- fig. 3 is an overview of area I of FIG. 1;

- fig. 4 is an overview of area II of FIG. 1, with the representation of the component parts;

- fig. 5 is an overview of area III of FIG. 1, with the representation of the component parts;

- fig. 6 is an overview of area IV of FIG. 1, with the highlighting of the wave in formation;

- fig. 7 is an overview of area V of FIG. 1;

- fig. 8, overview of the entrance gate, highlighting the component parts;

- fig. 9, top view of the entrance gate, highlighting the position of the gate axis;

RO 127672 Β1

- fig. 10, side view of the entrance gate; 1

- fig. 11, bearing detail and shaft input gate;

- fig. 12, the representation of the differences between the wind wave and the tsunami wave; 3

- fig. 13, analytical representation during the movement of the tsunami wave towards the shore;

- fig. 14, analytical representation during the movement of the tsunami wave towards the shore, and 5 its redirection through the interior of the system according to the invention;

- fig. 15, state of the art, representation of the principle of communicating vessels; 7

- fig. 16, artistic representation during the movement of the tsunami wave towards the shore, and its redirection through the interior of the system according to the invention;

- fig. 17 is an overview of the hydrotechnical system according to the invention;

- fig. 18, architectural overview of the hydrotechnical system according to the invention; 11

- fig. 19, detail of the locking and unlocking system of the entrance gate;

- fig. 20, pump float detail; 13

- fig. 21, exhaust gate detail;

- fig. 22, inner float overview;

- fig. 23, detail of the system for locking, unlocking and closing the exhaust gate;

- fig. 24, floating pump float view and how to guide and adjust the stroke; 17

- fig. 25, air pump view of the pump float, connected to the water drainage system.19 further, the hydrotechnical system is presented in more detail, exposing its component parts, as well as the way it works. The hydrotechnical system can be built 21 to protect people, animals, infrastructure, architecture, the environment, as well as against the erosion of coasts or oceans on smaller or larger portions, depending on the preferences of the beneficiary. The hydrotechnical system may be designed with a single tube A or several tubes A for discharge, discharge, recirculation, each tube A being provided with one or more 25 inlet gates B, as well as outlet gates C, or their repetition on the desired portion of the coast. It is also possible to use groups of tubes A forming part of the same structure, 27 which can be multiplied to cover the desired portion of the coast to be protected.

Pipes A can be made of prefabricated reinforced concrete portions, connected to each other, 29 sealed with special rubber and Teflon gaskets. These A-tubes can be extended to the ocean or sea as needed. Tube A can have double height or can be superimposed to control gigantic water flows.

The inlet gate B is actuated by a pump float D, and the outlet gate 33 is actuated by an inner float E.

Entrance gate B can be constructed according to the beneficiary's preference, smaller or larger, so that, depending on its size, the construction dimensions of the tube A can be estimated, for which it is also necessary to take into account observations made 37 on the size of the waves in those areas, as well as the inclination of the seabed or ocean.

Such observations are also needed to determine the relative size of the 39 tsunamis to be annihilated, to which can be added a percentage of overprotection. The input and discharge capacity of the hydrotechnical system must be estimated to be at least 41 equal to that of the tsunami wave, which must be recirculated back to the ocean, where the volume of ocean water far exceeds the volume of recirculated water. Note that when the water level 43 inside the tube A reaches the maximum adjustment level, the inner float E is activated, and it unlocks the outlet gate C. The outlet gate C is empty on the inside and, once 45 unlocked, makes the air bag inside it to open on its own, forced upwards by the pressure of the sea water, rotating around its horizontal axis, which is at the top 47 of tube A, which must never open in a perfectly horizontal position .

EN 127672 ts1 At the time of the first tsunami wave, it is best to have tube A already empty inside, making it possible for huge amounts of water to be removed immediately. The tsunami wave activates a pump float D, and it unlocks the entrance gate B before the tsunami wave reaches its area. After the tsunami, the water left inside tube A must be drained as soon as possible. This involves the pump float D of the inlet gate B, which is provided with an air pump which, by moving it up and down, pumps air inside the tube A. It is necessary for this tube A to be hermetically sealed, in order to not to lose the air pressure inside. It is important that the pump float D, unlocking the inlet gate B, be adjusted so that it is activated at a certain height of the tsunami wave, from where the danger of destruction begins to increase, at which point the system comes into action.

Once the inlet gate B has been unlocked by the pump float D, it opens automatically, because its rear part b is larger and heavier than the front part l ₂ , h> l ₂ · Gate B rotates and stops in the open position at an angle of about

60 ... 70 ° with the normal surface of the water, angle at which the water flows naturally, not forcing the entrance gate backwards.

Pump float D pumps air through a stainless steel tube that extends into tube A. This pumping system allows air to enter inside tube A, but does not allow it to escape until all the water inside has been discharged through another pipe.

Another important point is that the pump D float can also be activated if the ocean water recedes before the tsunami wave forms, and if the tsunami wave forms without the ocean or sea water receding before it forms. .

After the tsunami plague has passed, the gates must be closed by employees for the maintenance of the hydrotechnical system, either manually or electromechanically, with the help of electric motors or an air pressure system, obtained by the same pump float. A simple manual system will be displayed here. This operation is necessary in order to prepare the hydrotechnical system for a future incident.

Tube A must also contain a manhole which must also be sealed.

In order to better understand the way the hydrotechnical system works, its figures, numbering 25, will be explained in a sequential order of the tsunami phenomenon and its annihilation, as well as the process of operation of the hydrotechnical system.

in fig. 1 shows the component parts of the hydrotechnical system, which is divided into five parts (sections), numbered from left to right with the Roman numerals I, II, III, IV, V:

I represents a commercial or residential area and a part of the beach;

II, the beach and a portion of tube A where, at the top, is the entrance gate B, open at about 60%;

III represents the continuation of tube A to the farthest end of the coast, where tube A has the exit gate C of the collected water flow, belonging to the tsunami wave VT;

IV represents the crest of the tsunami wave CVT, at the base of which one can distinguish the level of the sea / ocean withdrawn NMR, and the crest of the tsunami wave;

V shows the continuation of the tsunami wave, followed by a decrease in water level.

in fig. 1 may also be distinguished the two floats D and E, which are used to open (unlock or unlock) the two gates B and C.

The entrance gate B is practiced in the upper wall of the tube A, in a horizontal position, and at its end towards the shore, and the exit gate C is practiced transversely, in a vertical position, at the end of the tube A located off the ocean. Tube A is arranged below the level of the ocean floor, with a slope lower than the slope of the ocean floor, so that the exit gate C is located above the level of the ocean floor, to allow the discharge of water accumulated inside tube A.

RO 127672 Β1

Gates B and C are embedded by frames, and the frame of gate B has the possibility of extension 1 above the water level. Both the metal frames and the gates B and C are provided with springs for forcing the quick opening of the gates B, C, and the tube A, inside, is provided with some networks 3 of pipes that have mounted inside them valves that allow the evacuation water remaining inside tube A, which is to be removed only when tube A is hermetically closed, after the cessation of the tsunami, and some pipes are connected from inside tube A, through its walls, to the outside, where, further, they are connected to the pipeline networks of float 7 pump D, and others are used for water drainage.

in fig. 2 shows the four phases of the ocean, before and during the formation of the 9 VT tsunami wave:

a. normal sea / ocean level during MFN flow. Here we must consider the 11 difference in the level of flow and ebb;

b. the sea / ocean water level at NMR retreat should be estimated as much as possible, 13 in order to take into account the inclination parameters of tube A;

c. the level where the VT tsunami wave is to operate the float / pump D (see fig. 18), 15 to unlock the lock of the entrance gate B can when the wave has reached the entrance gate B, it should be open and the wave should enter inside tube A; 17

d. the level where the crest of the CVT tsunami wave is and the point where the OT wave was already to be withdrawn.19

Fig. 3 represents the first part of section I of fig .1, in which are presented:

a. coastal development (residential or commercial) 21

b) beach;

c. sea level during MFN flow.23

Fig. 4 represents, in a simple form, the tube A and the inlet gate B. It can be seen that the base of the inlet a is below sea level during the MFN flow, while the inlet gate 25 rises to the level of the tsunami wave VT , preferably above the level of the CVT wave crest.

Fig. 5 represents section III of fig. 1, or the continuation of the tube A and the end where 27 the exit gate C is located.

Fig. 6 represents the formation of the OT wave after the ocean water has receded. The hydrotechnical system 29, whether the ocean or sea water recedes or not, must come into action by opening the entrance gate B. 31

Fig. 7 shows a decrease in the level of the OT wave, which suggests that it will be followed by another OT wave. 33

Fig. 8 shows the entrance gate B which must never open at 90 ° or in a vertical position. The entrance gate B, positioned horizontally when closed, is fixed 35 on a axis of rotation which allows the ends of the shaft to rotate in the bearings mounted on the sides of the tube A, which is arranged transversely in its longitudinal direction, and the shaft 37 gate B is mounted on the gate outside the center of gravity of gate B, to allow it to rotate about its axis, with the heavier part, from the shore, downwards, inside tube A, and 39 the front part, from the ocean, to rotate upwards, making it possible to open gate B at an angle of 60 ... 70 ° to the surface of the water when it is in the open position. 41

At the bottom, gate B is provided with resistance ribs positioned longitudinally and parallel to each other, forming, at the same time, channels for guiding the flow of water 43 inside the tube A during recirculation, but rotation of the gate B can only be possible. only after unlocking and opening it via the connected D-float pump system 45

RO 127672 Β1 with gate B through a system of levers. The triangular reinforcements of the gate are also used to guide the water of the VT wave. If the VT wave exceeds the gate B in height, then the remaining water flows on the back of the inlet gate B and flows into the tube A, continuing its course inside it:

a - axis of rotation of the entrance gate;

b - reinforcement farm;

c - hinge bearing.

Fig. 9 shows a front view of the bottom face of the entrance gate B and a side view, having> l ₂ , to allow it to be opened once it has been unlocked.

Fig. 10 shows the back or bottom of the entrance gate, with> l ₂ , to allow it to open itself, automatically, when unlocked.

In fact, the entrance gate B and the exit gate C are provided, in the area of closure or contact with their frames, with strong springs, to force them to open. The letter a represents the axis of rotation, b - the reinforcing farm and c - the bearing, the hinge of the entrance gate B.

Fig. 11, represents a simple hinge system for the entrance gate B. It can also be replaced with a system with encapsulated bearings.

stick. 12 a represents the normal waves of the sea or the ocean. You can also see the current of water inside the rotating wave. The rotational movement is generated by the tangential force of the wind b with the crest of the wave, as well as by the friction of the water in contact with the seabed, which causes the wave to break before reaching the shore; the figure below shows the movement of the current c of the VT wave moving in a straight line towards the shore, and causes the VT wave to increase in height and to propagate all its force over the shore. Guiding the VT wave back to sea, through tube A, where the volume of water is much larger, causes the two currents, the incoming and the outgoing, to rotate on each other, which leads to a reduction in the linear speed of the wave. VT and even to reduce its water flow.

Fig. 13 shows a technical representation of the volume of a VT wave, and its movement towards the shore, through the letters a, b, c ..., and λ represents the length between the ridges and h is the height of the wave.

Fig. 14 also indicates a technical representation of the flow of each VT wave, in order to better understand its effect through the tube A. The letters a, b, and c represent the flow of a three-phase VT wave. Number 2 represents the water flow of a VT wave captured inside the tube A, which met another VT wave, where their rotation occurs.

Fig. 15 reminds each of us about the principle of communicating vessels, an important phenomenon for the operation of the hydrotechnical system.

Fig. 16 represents something similar to FIG. 14, than that in a different manner, where h is the height of the VT wave between the maximum point of the CVT wave crest and the sea level during the MFN flow.

Fig. 17 shows a little more artistically the arrival of the VT wave, after the ocean water receded, at this time the pump float D was activated due to the withdrawal of ocean water, because the float D was lowered and unlocked the entrance gate B. The exit gate C is still blocked, and will be unlocked when the float E, inside the tube A, will be actuated by the water level inside it. Here, 1 represents the shoreline in aerial view, or the normal sea or ocean level NMF, 2 represents the level of the water withdrawn from the sea or ocean NMR, before the VT wave is formed, or its base, and 3 is the level of the VT wave approximately .

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Fig. 18, shows the entrance gate in the open position at 60 ... 70 °, already prepared to 1 block the passage of the VT wave to the shore and also to guide and allow the water flow of the VT wave to discharge inside the tube A. The exit gate C, here, has already been activated 3 (unlocked) by the float E inside the tube A (see fig. 22), which, in turn, has been activated by the water level a inside the tube A. At this point the next OT waves already have 5 ground ready for their return to where they began to form.

It is known that the hydrostatic pressure at the surface of a liquid in equilibrium is uniform. 7 normally, the force of the water current that is discharged through the tube A (whose inclination allows to increase the rate of return of the water flow that belonged to the VT wave, now a 9 controlled current) is greater than that of the current of a VT wave normal. Once the VT wave joins its mass with the water inside the tube A, it forces its flow outwards. 11

The hydrostatic pressure at the surface of a liquid is kept in balance as long as there are no level differences: 13

P = pgh where p is the pressure, p represents the density which, in this case, is the same throughout the water flow, g is the weight and h is the height of the water flow. When tube A is in full action, a hydrostatic balance is created, where the pressure is defined by the formula:

Δρ = pgAh where Δρ represents the pressure difference as a function of the height difference Ah. To this pressure can be added (possibly), in some cases, the gravitational force G exerted on the water flow inside the tube A when a new wave VT is preceded again 21 by the withdrawal of seawater from the coastline, beyond of the exit gate C, causing the hydrotechnical system to empty quickly. 2. 3

Fig. 19 shows a part of the system for unlocking the inlet gate B in the tube A.

Entrance gate B is closed but unlocked, as shown in the drawing. A latch d is withdrawn 25 from the entrance gate B and is actuated by a fork c which, in turn, is activated by a rod e.

The letter a represents the manhole of the PSS tube, then b is the plug that closes the access chamber 27 to the lock / unlock system gate B, and closes the gasket of the gate B for its sealing.

Fig. 20 depicts pump float D with its activation arms a and b. Arm a 29 unlocks gate B when the pump float D is pressed (if the ocean water recedes), and arm b unlocks gate B by pulling action in above it, 31 to the pump float D (in case the VT wave comes unexpectedly), and operates the pump float, raising it beyond the maximum limit from which it was set to open gate B. Letter 33 c represents the axis of pump float guide D; d is the pull axis of the arm b, e is the connecting fork of the arms a and b, f is the connecting sleeve of the fork e with the activating arms 35 a and b; g is the connecting rod of the arms a and b, and h is the main activating rod.

Fig. 21 provides some details about the exit gate C. 37

Exit gate C has double walls, acting as an air bag, is positioned vertically at the end of tube A off the ocean or sea, when closed, is 39 arranged on an axis fixed transversely to the top of it, allowing the shaft which is mounted on the gate C to rotate together with it, in the bearings also mounted on the side parts 41 of the tube A, at its upper part. At the bottom, the exit gate C is provided with resistance ribs similar to those of the entrance gate B, positioned 43 vertically when it is closed. These ribs pass through the lower wall of the outlet gate C, extend inwards, and are provided with holes, to allow the air pressure 45 and the temperature inside the outlet gate C to be uniform, in order to avoid

EN 127672 Β1 torsional pressure stress during opening when the exit gate C is unlocked by a lever system connected by a rod to the inner float E. The exit gate C also has a system of pulleys by which a cable is operated with a simple float to the surface, which is used to mark the position of the exit gate, as well as for its use in the process of closing the exit gate C, after the total recirculation of tsunami waves or dangerous waves ceased.

Letter a represents the hinge ear of the gate C, b is the resistance bushing and lubrication of the gate shaft c, d is the hole (in concrete) for the passage of the main rod of the gate unlocking / unlocking system C. Letter e represents the concrete iron from the tube structure A, f is the outlet / outlet gate sealing gasket C, g is the pulley wheel of the gate closure / locking system C, and h is the gate lock cable C.

Fig. 22 exposes the entire system for unlocking the outlet gate C, where the inner float E is pushed upwards by the water level in the tube A, and activates the unlocking system of the gate C, and the letter c represents the float that maintains the closing cable of the gate C on the surface, to lock the C gate after the tsunami.

Fig. 23 provides details about the pulley wheel e for limiting and closing the exhaust gate C. Here, in this drawing, it should be noted in particular the cable f which limits the opening and closing of the exhaust gate C, as well as one of the stops g inside the wall of the tube A. The other elements have been presented previously, but, for a possible addition of details in the future, it is good to be numbered as well.

Fig. 24 provides additional details about float D. Letter a represents the guide shaft of float D, which is provided with a threaded shaft b, for adjusting the pump float D to a certain height (limit); once the VT wave exceeds this limit in height, the pump float D is pushed up and unlocks the inlet gate B. Gate B can also be opened if the ocean water recedes before the VT wave forms. The pump float D, moreover, is also lowered, and activates the system for unlocking / unlocking the gate B. The letters c and d represent the up / down movement guide of the float D, which does not allow the float to rotate around its own axis. The letter b represents the height adjustment screw of float D.

Fig. 25 shows a portion of the pump float D, where the pump a, with all its parts, constitutes the system for pumping air through the pipe g, the valves f and c, inside the tube A, to force the water inside it to come out through the pipeline it is, and empty, in the sense of preparing it for the annihilation of a future tsunami.

The legend:

- A, tub;

- B, entrance gate;

- C, exit gate;

- D, pump float;

- E, inner float;

- MFN, sea level during the flow;

- NMR, sea level receded;

- CVT, the crest of the tsunami wave;

- OT, tsunami waves;

- FM, seabed;

- FO, the bottom of the ocean.

Claims (6)

Claims 1 1. Architectural hydrotechnical system for the protection of the terrestrial coasts against 3 tsunami waves, giant waves and against coastal erosion, by redirecting the water flow of the waves back to the ocean, which is composed of a reinforced concrete tube (A), 5 provided with an inlet gate (B) and an outlet gate (C), both gates with structural strength characteristics, which are actuated in turn, the inlet gate (B) by a pump float (D), and 7 gate outlet (C) by an inner float (E); the pump float (D) is driven by the sea or ocean water level, and the inner float (E) is driven by the water level accumulated in the chamber 9 of the tube (A), characterized in that the inlet gate (B) is drilled in the upper wall of the tube (A), in a horizontal position and at its extremity towards the shore, and the exit gate 11 (C) is practiced transversely, in a vertical position, at the end of the tube (A), located off the ocean, the tube (A) being arranged below the level of the ocean floor, with an inclination less than 13 the inclination of the ocean floor, so that the outlet gate (C) is located above the level of the ocean floor, to allow the discharge of water accumulated inside the tube (A). 15 The architectural hydrotechnical system according to claim 1, characterized in that the tube (A) is made of segments of reinforced concrete, sealed and assembled together with 17 rubber and Teflon gaskets, which are fixed with screws to each other, to provide superior resistance to seismic movements; it is also provided with frames that embed the gates (B and C); the first 19 frame has the possibility of extension above the water level, and both the metal frames and the gates (B, C) are provided with springs forcing the rapid opening of the gates (B, C), and the tube (A), in 21 inside, it is provided with a network of pipes that have valves mounted inside them that allow the discharge of water remaining inside the tube (A), to be removed only when the tube (A) is hermetically closed, after the cessation of the tsunami, and of these pipes, some are connected from the inside of the pipe (A), through its walls, to the outside, where they are further connected to the networks of the pump float pipes (D), and others are used for draining water; also, the tube (A), depending on the number of possibilities of protection 27 against various destructive natural phenomena, also allows, by its construction, also the lateral attachment or overlap of several tubes of this type (A), so as to offers both an increased protection factor and the possibility to modify or adapt other connecting elements between type (A) pipes, depending on the geological conditions and the size of the capacity 31 of the hydrotechnical protection system, as well as for the collection of sewerage and drainage networks. of floods, which, at the same time, create an increased resistance to seismic movements; at the same time, the tube (A) is also provided with other component elements, such as pressure, salinity and temperature sensors, in order to provide adequate protection qualities. 35 Architectural hydrotechnical system according to Claim 1, characterized in that the entrance gate (B), positioned horizontally, when closed, is fixed on a 37-axis shaft which allows the shaft ends to rotate in the bearings mounted on the sides of the tube (A) which is arranged transversely, in its longitudinal direction, and the axis of the gate (B) 39 is mounted on the gate outside the center of gravity of the gate (B), to allow it to rotate about its axis, with the side heavier, from the shore, down, inside the tube (A), and 41 the front, from the ocean, to rotate upwards, making it possible to open the gate (B) at an angle of 60 ... 70 ° to the surface of the water, when it is in the open position, and on the lower part 43, the entrance gate (B) is provided with resistance ribs positioned longitudinally and parallel to each other, forming, at the same time, channels for guiding the water flow 45 inside the tube (A), in during recirculation, but rotation of the gate (B) can only be possible after unlocking and opening it by means of the floating system pump D connected to the 47 gate (B) by a system of levers. RO 127672 Β1 Architectural hydrotechnical system according to claim 1, characterized in that the double-walled outlet gate (C), acting as an air bag, is positioned vertically at the end of the tube (A) off the ocean or sea; when closed, it is arranged on a shaft fixed transversely to the top of it, allowing the shaft which is mounted on the exit gate (C) to rotate with it, in the bearings also mounted on the sides of the tube (A), at the top of it, and the exit gate (C), at the bottom, is provided with resistance ribs similar to those of the entrance gate (B), inside it the ribs of the gate (C) are positioned vertically when it is closed and these ribs pass through the lower wall of the outlet gate (C), extend inwards, and are provided with holes, to allow the air pressure and temperature inside the outlet gate (C) to standardize, in order to avoid torsion at pressure demands on it during opening, when the outlet gate (C) is unlocked by a system of levers connected with a rod to the inner float (E); the exit gate (C) also has a pulley system through which a cable is operated with a simple float to the surface, which is used to mark the position of the exit gate, as well as to use it in the process of closing the door. exit gate (C), after the total recirculation of tsunami waves or dangerous waves has stopped. Architectural hydrotechnical system according to claim 1, characterized in that the cylindrical pump float (D), which is activated vertically at the surface of the water, above the rear wall of the tube (A), is positioned on a cylindrical shaft, mounted on a tube (A), which allows the float (D) to move from top to bottom, and its travel is regulated by a threaded guide screw, so that, by its movement, the pump float (D) to unlock the entrance gate (B) when the ocean water level is detected, both when the ocean water recedes, before the tsunami wave forms, and when the ocean water does not recede, before the tsunami wave forms, by the movement transmitted to the release system of the gate (B) by means of a lever system, as a component part of the pump float (D), which also has in its composition a pump which is also activated by its up and down movement, which pumps air inside the tube (A), then c when it is hermetically sealed, in order to force the water accumulated inside the tube (A) to the outside, by the pressure formed inside, through a system of pipes, thus preparing the architectural hydrotechnical system for the future process of coastal protection land. Architectural hydrotechnical system according to claim 1, characterized in that the parallel float (E), of parallelepiped shape, mounted internally on the rear wall of the tube (A), near the inlet gate (B), acts and unlocks the outlet gate (C) by means of the lever network, as a component of the inner float (E), so that, when the tube (A) is filled, and when, when sensing the pressure of the water level inside it, a value was recorded close to the water level pressure outside the tube (A), to signal the quick release and opening of the outlet gate (C), to start the process of recirculating the water flow brought by tsunami waves, giant waves or waves that create coastal erosion.