ES2262405B1 - LOW REFLECTION STRUCTURE. - Google Patents

Abstract

The structure of low reflection, object of the present patent application, is applied fundamentally, but not exclusively, to a floating drawer of vertical wall with preferably parallelepipedic shape and constructed in mass concrete, reinforced or prestressed, and that is lightened by cells. These cells provide buoyancy for transfer and commissioning, and once in its final position, they are filled with granular material, concrete or other materials thus providing the weight drawer for its function as a gravity structure. The drawer is equipped with low reflection conditions, by means of the arrangement of grooves in its outer face, which communicate the free waters with chambers and sets of dissipation chambers, whose shapes and dimensions are established to allow the combination of several dissipation mechanisms of energy, ensuring the efficiency of the device for a wide range of conditions of the incident agitation.

Description

Low reflection structure.

Object of the invention

The low reflection structure, object of the This patent application consists of a vertical structure, preferably parallelepipedically and preferably built in mass concrete, reinforced or prestressed, being lightened said structure by cells, being able to be part of said cells adapted to form dissipation chambers of Energy.

Said structure may consist of independent modular elements; by prefabricated drawers that are transferred until they are put into work, and once in their final position, they are filled with granular material, concrete or other materials, thus providing the weight drawer for its function as a gravity structure; or by blocks that are built in situ , that is, in their place of use.

The invention is applicable in structures maritime or river, and in particular in shelter works (dikes) and docking (springs), due to its excellent technical conditions (residing mainly in reducing the reflection of the energy) and economic.

Technical background

When the waves affect a structure maritime or river, a part of its energy is transmitted through of or on said structure, another part dissipates and the energy remaining is reflected towards the free waters, either the sea or the River. The power transmission may be due to the overflow of the swell over the structure or to the porous flow through the structure in case this is permeable. The dissipation, by On the other hand, it can be produced by turbulence or friction viscose. In these structures, when their function is that of shelter, it is it is desirable that the transmitted energy is not high. In others situations are intended to reduce the amount of energy reflected, without increasing the transmitted. For this it is necessary to create mechanisms to dissipate energy in the process of interaction of swell with the structure.

The reflection process depends on the characteristics of the structure, geometry and porosity, as well as of the incident waves on said structure. The proportion of energy that a reflex structure can be quantified by the reflection coefficient, defined by the quotient between the significant height of the waves that affect the structure and the significant wave height of the waves reflected by it.

There are different structures for construction of piers and dikes, mainly the structures of Slope and vertical structures. In the slope structures, or of inclined wall, the dissipation of energy occurs mainly due to the turbulence generated in the process of breakage of the waves on the slope, reflecting a small fraction of incident energy compared to structures vertical

The slope structures, although usually widely used, they are being partly displaced by vertical structures mainly due to various issues, such as environmental restrictions, cannot be directly usable as docking dock and reasons economic.

On the other hand, vertical structures and mainly those formed by floating drawers usually have of a vertical smooth facing. When it is intended to reduce the reflection, holes or slits are usually arranged in its face and part of the outer row cells are used, or all of them,  as chambers for partial dissipation of wave energy. These solutions are based on:

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the reduction of direct reflection by reducing the percentage of wall solid vertical,

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the dissipation of wave energy by friction in the openings, and

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in the turbulence generated in the chambers constituted in the outer row  of cells.

They are usually drawer employees that they have a solid vertical wall, which reflects in their practice all the incident waves, sometimes reaching a reflection coefficient close to unity, usually between 0.95 and 1. There are drawers without dissipation chamber, which are arranged on a breakwater and on the bottom of the sea. This type of drawers reflects the waves when hitting the vertical wall facing with the swell, keeping the water on the back side of the drawer, quiet and without alterations.

These high reflection conditions generate basically two types of problems in:

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The spring walls located in docks, since these walls reflect the energy of the waves that penetrate these docks or the one generated by the passage of ships, being created agitation conditions that hinder the operations of ships, as well as the transhipment of goods and passengers between docks and boats, or in the case of marinas, since greater wave agitation, less comfort for users of the port.

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The areas close to the outer wall of the shelter docks, since  the overlap of the incident wave with the reflected one generates a increased agitation zone that makes maneuvering difficult approach to port, being able to generate danger in certain cases and at least making navigation very uncomfortable, especially for light boats.

Also another type of floating drawer, known as a Jarlan type drawer, it presents a dissipation chamber between a perforated wall and a rear wall, placed on a breakwater arranged on the bottom of the sea. Said drawer presents on its side faced with the sea and on which the waves hit a wall with a plurality of perforated holes. The main problem of This type of drawers lies in the distribution of weight over the base of the drawer, since the resulting one moves towards the part rear of it, moving away from the front facing of the drawer. As a result of this the resistant conditions of the drawer before the waves are reduced due to the decrease of the weight of the same and to the displacement of its center of gravity.

Another type of multicellular drawer, has a plurality of curved passages inside, ranging from its frontal facing (oriented towards the waves) to the part top of said drawer. As in the previous case, the resistant conditions of the drawer against the waves get worse due to to the hollow parts, in addition to being prevented, due to the exit of the water from the top, using the top of the drawer for transport or disembarkation of people, equipment or goods.

Vertical structures are usually designed as concrete solutions for specific environments, not being applicable such structures to other environments for which they have not been designed

In view of the above and for certain cases, it is desirable to obtain a vertical structure with a Low reflection configuration of application to different environments. Significant progress has been made in that regard, since at allow a reduction of energy reflection in structures maritime verticals in front of high vertical structures reflection you get the following advantages:

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Reduction of agitation inside of port docks, facilitating the maneuvers of ships, as well as loading and unloading operations. This feature It is of particular importance in those port terminals specialized with high performance requirements in which they operate large ships, and on the premises sports.

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Height wave and cant wave less than in vertical structures reflective, and may affect the maneuverability of ships in access channels and other navigation areas,

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Hydrodynamic forces smaller than in vertical reflective structures,

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Minor wave lift on the exposed structure wall highly reflective vertical,

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Reduction of erosion problems in the vertical structure of the structure and reduction of undercutting foot of it, and

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Reduction of energy transmitted by overflow in docks and dikes, thus reducing the risk for people, equipment or merchandise.

The vertical structures and in particular the drawers known in the state of the art have been designed and constructed, as already indicated, usually as specific solutions to reduce reflection in situations concrete, that is, have been designed with the aim of being employees in a specific place defined by certain conditions of use that will be required by said place of location of the drawer, being scarce solutions, such as those of Jarlan type, with claims of a certain generality.

The drawer solutions above described are mainly characterized by a behavior with a relatively low coefficient of reflection for your conditions of design, presenting a significant worsening of energy absorption conditions as we separate from the optimal conditions for which they were designed.

Exhibition of the invention

The objective of the present invention is to provide a vertical structure, and in particular a floating drawer, whose efficiency in reducing reflection is maximal, and it keep reasonably uniform throughout the period range of waves that most frequently affects the shelter works and docking, under the conditions in which the agitation reduction, also providing tools techniques that allow its preliminary design for the generality of the cases.

Also another objective of the present invention is that the specific energy dissipation elements that are have the least possible negative impact on the stability conditions of the drawer against waves and others horizontal actions.

To achieve these objectives it has been developed the specific case of a floating drawer described then in which various mechanisms overlap energy dissipation so that it is possible to standardize the response of the drawer from the point of view of reflection, to vary the conditions of the incident waves (especially the period), depending on the reflection reduction mechanism that prepondere. The effectiveness of such dissipation mechanisms is variable depending on the period of the incident wave.

The low reflection floating drawer for construction of maritime structures such as docks and dikes it is parallelepipedically, so that its juxtaposition forms the linear works of docks and docks. One of its vertical faces It forms the vertical facing facing the waves. Said drawer it is divided inside by rows of cells separated from each other by partitions

The cells may have different configurations such as square, rectangular, circular or polygonal, with longitudinal and transverse dimensions defined by the lengths well of the sides in cases of square or rectangular cells well of the diameter of the circle circumscribed to the polygon in the case of polygonal and Circular

The floating drawer, preferably concrete armed, it has a set of rows of cells, at least two, each of which usually has, except for special provisions, The same number of cells.

In the outer vertical wall they are arranged slots, in a number between the unit and the total number of outer row cells, allowing waves to enter the dissipation chamber formed by the cell or set of cells that communicate directly with the free waters through the slot or slots, and by the cells or groups of cells that are They communicate with them inside the drawer. The basis of bliss slot is placed in height between the support surface of the drawer and a point, which is below or at sea level and extends in height until the coronation, or upper part, of the drawer. The outer groove can affect several adjacent cells, or to a single cell, and can therefore be the width of said slot between 20% and 300% of the longitudinal width of a cell, and the total sum of the lengths of the slots totals between the 15% and 75% of the length of the drawer.

The cell or cells with the outer groove and in contact with the free waters, of the sea or river, is communicated with, at least, the adjacent cell of the second row of cells, located immediately following the first row, and forming of this way another dissipation chamber in the second row of cells. These cameras (the one in the outer row and the one in the immediate one inside) are communicated by openings whose dimension minimum is 25% of the longitudinal width of the cell. Likewise, all the cells of the first and second rows will be, in general, communicated with its adjacent cells. The openings of communication with adjacent cells have a minimum dimension 25% of the cell dimension measured perpendicular to the facing.

For use in infrastructure port, the floating drawer is located on the breakwater and a once there fill their cells with filling material to provide the stability drawer against waves and other horizontal actions, such as the loading of land. In the filling of the cells you have to keep in mind that the cells that are communicated with the outside must have their solera or fund determined by the sealing cap of said filler material, below or flush with sea level. Also, the cameras of dissipation that are not in direct contact with the wall exterior, that is, those of the second row or those of the first that do not communicate directly with the free waters, they must have of its solera or bottom located at a level equal to or greater than that of situation of the bottom of the cameras communicated with the outside, said solera or bottom always being below or flush with the level from sea.

The described configuration of the floating drawer provides it with a set of energy dissipation mechanisms What are they:

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Reduction of reflection in the exterior vertical facing of the drawer facing the sea waves, due to the outer grooves located therein,

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Slot energy dissipation outside, both during the entry of water (wave crest) and to his departure (sine wave),

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Energy dissipation due to turbulence in the inner chambers arranged in the cells,

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Energy dissipation, both in the outside as inside the drawer by the process of overlapping incident swell trains and reflected with different phase angle, direction of propagation and direction in its case.

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Energy dissipation by falling water outlet jet from inside the drawer, in the sine phase of wave, on the outside water, and by the same phenomenon between Different interior dissipation chambers.

Description of the figures

To facilitate the understanding of the invention 4 figures are included in the present patent application whose purpose is the best understanding of the fundamentals on which it is based the invention at hand and a better understanding of the description of a preferred embodiment having in note that the character of the figures is illustrative and not limitative.

Figure 1 shows an elevation view of the drawer object of the present invention from the sea side.

Figure 2 shows section A.A 'of the figure 3.

Figure 3 shows a plan view of the Floating drawer object of the present application.

Figure 4 shows a section of the drawer in its definitive installation in the case of a dock.

Description of a preferred embodiment

The floating drawer 1 example of the object of the The present invention is composed of a parallelepipedic body with a vertical facing 2 to face the swell once arranged the drawer 1 in its working position. Also, the drawer 1, as a particular case, is divided into four rows 4, 5 that are each divided into eleven cells 9 of square configuration.

Each of cells 9 of the first row 4 It has a slot 3 in the vertical wall 3 that communicates these cells with the sea, allowing the waves to enter the dissipation chamber formed by said cells. The basis of said Slots 3 is located in height between the support surface 15 of the drawer 1 and a point 7, which is below or flush with the sea level 6 and extends in height to coronation 16, or upper part of drawer 1.

Cells 9 with the outer groove and in contact with the outside or sea, they are communicated with the cells adjacent to the second row 5 of cells, located immediately following the first row 4, thus forming another dissipation chamber in said cell of the second row 5. Also, all cells in the first 4 and second 5 rows can be communicated with its adjacent cells, creating cameras of dissipation in said cells.

For the use of drawer 1 in one docking port facility, a general landfill is available 10 in the back part of the structure, separated from the drawer by a pedraplén 12 and a quarry base or all one of quarry 13 on which is located in drawer 1.

Once the drawer 1 is placed, fill in cells 9 thereof, so that the rear rows of drawer 1 are fill completely with said filling material 11. The cells or dissipation chambers of the first row 4 are filled with said filling material 11 until its bottom or bottom 17 is placed by below or flush with sea level 6. Also, the chambers of dissipation of the second row 5 must be filled with the material of padding 11 until its bottom or bottom 8 is located at a height equal to or greater than the situation of the bottom 17 of the cameras communicated with the outside of the first row 4, always being said solera or bottom 8 below or at sea level 6. In the rows that form energy dissipation chambers will be arranged a concrete plug, mass or reinforced, on the material of filling, which prevents its removal due to turbulence generated in the cameras, the base of the camera being defined dissipation by the upper level of said concrete plug.

The operation of drawer 1 is easy deduction from its constructive structure. The waves affect on vertical wall 2, reflecting part of the wave and allowing the passage to the dissipation chamber of the first row 4 of the rest of it. Energy is dissipated therefore during water inlet and outlet of the outer grooves 3. Once the wave has entered the dissipation chamber, turbulence is created that contribute to energy dissipation due to confrontation of incoming and outgoing waves of both cameras of dissipation of the first row 4, how of the second row 5.

Also, due to the overlapping process of incident waves and reflected with different phase angle, direction of propagation and direction, energy dissipation is seen favored and accentuated.

Once the first incident wave has reached to the dissipation chambers of the second row 5, this one it is reflected towards the water inlet in drawer 1, generating a water outlet jet from inside the drawer, in the sine phase of wave, on the outside water, as well as between the chambers of interior dissipation, thus dissipating energy.

Claims (16)

1. Low reflection structure for the construction of shelter structures, berthing or protection of sea or river banks, such as docks and dikes, of the type constituted by parallelepipedic elements separated from free sea or river waters by means of an exterior vertical facing facing said free waters and said structure being lightened in its interior by rows constituted by cells separated from each other by partitions, having at least two rows of cells, each of said rows counting with a certain number of cells, and the endowment being provided vertical wall of at least one groove in at least one of said cells of the first row, located immediately behind the vertical wall, said groove communicating at least said cell with the free waters, and at least one cell being in contact with the groove exterior communicated with at least one of the adjacent cells, either of the same row or of a second row located immediately behind the first row, said at least two cells communicating with each other forming a single dissipation chamber, characterized in that it has two rows with lightened cells, the bottoms of the dissipation chambers of the first and second rows being located at different levels. 2. Structure according to claim 1, characterized in that the dissipation chambers formed by the cells that are connected to the outside have their bottom or bottom, once the filling material is introduced into the cells, below or flush with the sea level. 3. Structure according to claim 1, characterized in that the dissipation chambers that are not in direct contact with the free waters have their bottom or bottom, once the filling material is introduced into the cells and the corresponding concrete plug is executed, located at a level equal to the location of the bottom of the cameras connected to the outside and always below or at sea level. 4. Structure according to claim 1, characterized in that the dissipation chambers that are not in direct contact with the free waters have their bottom or bottom, once the filling material is introduced into the cells and the corresponding concrete plug is executed, located at a higher level than the location of the cameras connected to the outside and always below or at sea level. 5. Structure according to claim 1, characterized in that the dissipation chambers are communicated with adjacent cells of the same row, creating dissipation chambers in said cells. 6. Structure according to claim 5, characterized in that said dissipation chambers are communicated with the adjacent chambers through at least 25% of their transverse width. 7. Structure according to claim 5, characterized in that said dissipation chambers are communicated with the adjacent chambers throughout their transverse width. 8. Structure according to claim 1, characterized in that the outer groove can affect several adjacent cells. 9. Structure according to claim 1, characterized in that the dissipation chambers of the second row communicate with the dissipation chambers of the first row by means of openings in the cells whose minimum dimension is 25% of the longitudinal width of the cell. 10. Structure according to claim 1, characterized in that the horizontal dimension, or width, of the outer groove is between 20% and 300% of the longitudinal width of a cell. 11. Structure according to claim 1, characterized in that the sum of the horizontal dimensions or widths of the grooves made in its outer face totals between 15% and 75% of the total length of the drawer. 12. Structure according to claim 1, characterized in that the base of the groove is located in height between the support surface of the drawer and a point located below or flush with the sea level, extending in height to the coronation, or part top of the drawer. 13. Structure according to claim 1, characterized in that the cells are square, their longitudinal width and transverse width being determined by the dimensions of the square side. 14. Structure according to claim 1, characterized in that the cells are rectangular, their longitudinal width being determined by the dimensions of the longitudinal side and its transverse width by the dimensions of the transverse side. 15. Structure according to claim 1, characterized in that the cells are polygonal, their longitudinal width and transverse width being determined by the diameter of the circle circumscribed to the polygon. 16. Structure according to claim 1, characterized in that it is a floating drawer.