FR2758147A1 - Semi=submerged caisson=type breakwater - Google Patents

Abstract

A semi-submerged breakwater is mounted on piles above the sea bed so that water can pass beneath it in both directions while its upper section damps the force of the waves. The rear surface of the breakwater, facing away from the wave surge, has a section (5) which slopes downwards at an angle towards the water surface to attenuate the force of the water when the wave is retreating. The angle of the sloping surface lies between 25 and 60 degrees, and is preferably about 35 degrees, and is designed so that the water passing under the breakwater as the wave is retreating from the front surface is held by the sloping rear surface and moves back towards the front surface during the next wave surge. The height of the sloping rear surface above the waterline is no greater than the height of the transmitted wave.

Description

 The invention relates to improvements to partially submerged dykes between an upstream body of water and a downstream body of water, in order to mitigate in the downstream body of water the effects of swell which occurs in the body of water. upstream water.

 The invention applies in particular to dams mounted on piles, the word "pile" here designating any structure capable of carrying the dam while allowing water to circulate under the dam, the most frequent case actually being that of the piles. foundation.

 These dikes are designed to constitute a hydrodynamic obstacle with damping of the mass of water in motion under the dike.

 The upstream body of water is generally a sea, while the downstream body of water is generally a port.

 The invention also applies to floating breakwalls suitably stabilized in flotation.

 A dike has a front facing the body of water which is located downstream of the dyke and which will be called the downstream front and an opposite front therefore facing the body of water located upstream, and which l 'we will call upstream front.

 A first aspect of the invention relates to the downstream front.

 An object of the invention is to provide a configuration of the downstream front which produces an increase in the vortex effects near this front to better dissipate the energy of the swell.

 Another object of the invention is to provide a downstream front configuration which deflects the return current under the dike upstream, thereby artificially widening the bottom of the dike.

 Still, an object of the invention is to provide a downstream front configuration capable of creating a liquid zone where the vertical speeds recombine in the opposite direction of the propagation of the swell, thereby reducing the phenomenon of resonance on the downstream side.

 These objects are achieved according to the invention, with a dike whose part of the downstream front which is likely to be affected by the movement of water under the effect of the swell is essentially in a downward slope towards the downstream at an angle at most equal to 60 relative to the horizontal.

 In a preferred embodiment, this part of the downstream front is formed by an inclined plane whose inclination is preferably between 25 and 40 and even more preferably between 30 and 40 relative to the horizontal.

 The invention therefore adds to the known basic principle of partial-immersion box dams causing the damping of the body of water. in motion under the dam, another oscillating mass on the downstream side in phase opposition, in order to amplify the damping phenomenon and to limit the risks of resonance linked to the basic principle.

 A second aspect of the invention concerns the upstream front of the dike.

 It has already been proposed to provide the upstream front with a dike of a submerged horizontal part to limit the effect of the vertical speeds responsible for the excitation of the system, this configuration which concentrates the energy of the wave on the front part of the structure increases the efficiency but increases the horizontal forces, and moreover when the wave arrives at the level of the flat advance, its camber becomes extreme and a surge may even occur.

 An object of the invention is to improve such a configuration of the upstream front of the dam to limit the slap effects and further increase the flushing effect and the swirling effects.

 This is achieved according to the invention, by designing the upstream front with a horizontal projection followed by a curved portion which curves gradually from the horizontal advance to the vertical.

 In an improved embodiment, this arched part of the upstream front is given a parabolic shape.

 It is advantageous to combine the various aspects of the invention in the same dyke, thus producing a structure which promotes the dissipation of the energy of the swell by swirling effects, which limits the forces in the structure, and which attenuates the phenomenon of resonance that can be created on the protected body of water for certain periods of incident swells.

 A dam structure in accordance with the present invention is particularly advantageous for protecting a site where there is a problem of great depth of water.

 It is also particularly interesting in the case where the swell periods are less than twelve seconds.

 It is always advantageous compared to a partial parallelepiped dike as regards the reduction in the quantity of construction materials and the size of the dike, for at least equal performances.

 The invention will be further explained below, with reference to the figures of the accompanying drawing, the description and the figures being used to reveal various features of the invention and of the embodiments which are described and shown.

In the figures - FIG. 1 is a cross-sectional view in principle of a dam having a downstream front configuration in accordance with the present invention, - Figures 2 and 3 are diagrams of operation of this downstream front, respectively for two phases of movement back and forth from the sea under the dike, - Figures 4 and 5 are diagrams of the velocity field obtained by laser velocimetry respectively with a dike with vertical fronts and a dike with an inclined downstream front in accordance with this invention - FIGS. 6 and 7 are diagrams of the field of instantaneous speeds respectively in the case of a dike with vertical fronts and of a dike having an inclined downstream front in accordance with the present invention, during the ascent of the wave on the upstream front of the dike - Figures 8 and 9 are diagrams respectively analogous to those of Figures 6 and 7 during the withdrawal of the wave on the upstream front of the dike - fig ure 10 is a comparative graph of the resonance phenomenon observed in the case of a dam with vertical fronts and in the case of a dam having an inclined downstream edge in accordance with the present invention - FIG. 11 is a graph of comparison of the resonance modes in the case of a dam with vertical fronts and of a dam having an inclined downstream front in accordance with the present invention, respectively in the case where the downstream body of water is infinite and in that where the plane of downstream water is a reflecting body of water - Figure 12 is a comparative graph showing the improvement in the transmission coefficient provided by a dam having an inclined downstream front in accordance with the present invention compared to a conventional dam with vertical fronts, in the case where the downstream body of water is infinite - Figure 13 is a graph similar to that of Figure 12 in the case where the downstream body of water is not very reflective - Figure 14 is a graph m showing the efficiency of the inclination of the downstream front of the dike for different swell periods - FIG. 15 is a diagram of a dike presenting an upstream front in accordance with the present invention - FIG. 16 is a diagram of an embodiment a dam having a downstream front and an upstream front in accordance with the present invention
- Figure 17 is a diagram of the velocity field during the ascent of a wave in the case of a dike according to Figure 16
FIG. 18 is a diagram of the velocity field during the withdrawal of the wave in the case of a dike in accordance with FIG. 16, and
- Figures 19 to 21 show different embodiments of a dam according to the present invention.

 The dike shown in Figure 1 is a box 1 partially submerged in a body of water between an upstream area 3 where the swell occurs, for example the sea and a downstream area 4, for example a port, which must be protected swell effects.

 The box is rigidly held at an immersion dimension defined either by a metal or concrete structure, or by vertical or inclined piles 2. Protection against scouring of the base of the retaining elements may be necessary if the bottom is granular.

 This type of structure can be built on the ground in the form of small modules and set up by lifting devices. It can also be built in larger dimensions and be floated. It can also be built on site like bridges.

 In accordance with the present invention, the box has a downstream front 5, the part AB of which concerned by the movement of water is constituted by a wall inclined descending downstream at an angle a of approximately 35 relative to the horizontal. .

 This inclined wall 5 constitutes a potential energy store.

During the withdrawal of the wave on the sea side, the water level rises on the inclined wall, depending on the angle of this wall and the horizontal speeds generated under the dike. This flow is then returned to the body of water on the downstream side (Figures 2 and 3).

 We compared (Figures 4 to 9), the velocity fields obtained in the case of a parallelepiped dike with vertical downstream front 5 '(Figures 4, 6, 8) and in the case of a dike with inclined downstream front 5 (Figures 5, 7, 9). It can be seen that the instantaneous and average speeds around the downstream part of the dam are much greater and that the average flows under the structure are much more active in the case of a dam in accordance with the present invention.

 During the ascent of the wave on the upstream side (Figures 6 and 7), the speeds downstream of the dam take the orientation of the inclined wall.

This makes it possible to have a much greater recirculation in depth and to have horizontal speeds under the casing of the dam over a larger volume. In this way we can thus obtain effects at least comparable to those provided by a parallelepiped dike which would be much wider.

 During the withdrawal of the wave on the upstream side, the speeds on the downstream side feed the downstream wave in the case of a vertical downstream front 5 '(Figure 8). But in the case of an inclined front (Figure 9), this effect is shared between the supply of this same wave and a storage in the form of potential energy of the body of water on the inclined wall.

 The inclined wall therefore partially decouples the body of water on the downstream side from the body of water located under the dike, which is the exciter of the wave generation process on the downstream side.

 We quantified in Figure 10, the resonance phenomenon in the case of an inclined downstream wall according to the invention (curve represented by diamonds) and that of a conventional vertical front 5 '(curve represented by squares) , the period T of the swell being represented on the abscissa. Kpm representing the transmission coefficient, i.e. the ratio between the peak-to-valley distance of the transmitted swell (downstream side) and the peak-to-valley distance of the incident swell (upstream side), in the case where there is resonance, and Kt the value of the same ratio in which there is no resonance.

 Figure 1 1 is a graph similar to that of Figure 10 in which we compared the effect of a vertical downstream front in the case of an infinite body of water (curve represented by diamonds) and in that of '' a reflecting downstream body of water (curve represented by squares) and the effect of an inclined downstream front in the case of an infinite downstream body of water (curve represented by h) and in that of a reflecting body of water (curve represented by x).

 Figure 12 shows the evolution of the Kt value (range on the ordinate) in the case of a vertical front protecting an infinite downstream body of water (curve represented by squares) and in that of an inclined front (curve represented with diamonds).

 FIG. 13 of a similar comparison, in the case of a low-reflecting downstream body of water, between a dike having a vertical downstream front and a dike half as wide as having a downstream inclined front with the same conventions of representation as in figure 12.

 FIG. 14 is a graph showing the evolution of the value Kt plotted on the ordinate, as a function of the angle a of inclination of the downstream wall, for swells of periods T1, 2 and 2 seconds (reduced scale), ie 10 to 18 seconds scale 1.

 We see in this figure that we start to have a significant improvement when the angle a is less than 60.

 FIG. 15 is a diagram of an exemplary embodiment of a dam constituted by a box 6 mounted on piles 7 so as to be partially submerged between an upstream zone 8 and a downstream zone 9, this box having in accordance with the present invention an upstream front consisting of a flat part 10a followed by a parabolic part 10b.

 When the incident wave strikes the upstream front, the camber of the wave increases sharply on the horizontal wall 10a due to the shallow depth of immersion and the wave splits into two undulations thus greatly reducing the fluctuation height of the water level at the end of the structure.

 The wave is then channeled on the parabolic wall 10b, stored in the form of potential energy, then restored in the form of a strong horizontal current directed upstream and which opposes the new incident wave (as shown on the left part of figure 18). This opposition generates an energy loss due to the vortices thus created. For a wide range of periods, a reverse upstream surge can occur. The phenomenon of water draw generated by the vertical speeds is thus very far from the dike upstream, limiting the nourishing effect downstream.

 The phenomena due to the shape of the downstream front and that of the upstream front combine synergistically in the case of a dam comprising both a downstream front inclined in accordance with the invention and an upstream front 10 comprising a flat part and a part curve according to the invention, as shown in Figure 16.

 Figures 17 and 18 are diagrams of the velocity fields obtained with such a structure during the ascent (Figure 17) and withdrawal (Figure 18) of the wave.

 The upstream and downstream parts of the dike can constitute the two opposite faces of the same box 12 (FIGS. 16 to 20) or the two opposite faces of a group of two separate boxes located opposite and carried by respective piles. (figure 21).

The dam can be arranged, in a manner known per se, to constitute an upper carriageway, a quay, etc.
The results obtained in the channel with a structure of the type of FIG. 21 are indicated below.

Water depth: h - 0.6m or 42m in real
Width of the dike: W = 0.67m or 47m in real
Dike immersion: i - 0.1 lm or 7.7m in real
Incident wave height ailments. : Hi - 0.154m or 10.78m in real
Average incident wave height: HI = 0.9m or 6.3m in real
Minimum period used: T- 1,132s or 9.5s in real
Maximum period used: T = 1.82s or 15.2s in real 1st Viewing period: Tri = 1.3s or 10.87s in real 2nd Viewing period: T2 = 1.82s or 13.55s in real.

 It can be seen that the agitation on the downstream side, even in the worst case, remains less than 0.75 times the height of the incident swell.

 The general application and dimensioning rules according to the invention of the dike are those of known partial dikes with wider possible applications thanks to the very improved attenuation coefficient. With an equivalent transmission coefficient, we can therefore reduce the width of this type of dam.

For partial parallelepiped dikes, the following values are generally accepted
- Bottom immersion depth relative to zero hydro
Minimum: 1 / 5th of the water depth or half the height of the maximum incident swell (centennial swell), the greater of these two values being retained.

 It is not interesting to go beyond 1/3 of the water height unless the maximum swell requires it.

- Dike width
The minimum width is linked to the wavelength of the offshore swell, and we generally accept as a minimum value 1/3 of this wavelength (associated with the minimum period) or half the height d 'water; the higher of these two values being used as the minimum value.

 It should be noted that for a given immersion depth and for a given swell, the attenuation coefficient is always improved by the width of the dike, but it is not economically or technically justified to seek lower attenuation coefficients 0.2 for maximum swells.

In preferred embodiments of a dike comprising a downstream front and an upstream front according to the invention
We use as general pre-dimensioning values
- flat on the upstream front: 10% of L
- upstream front: 40% of L
- downstream profile: 40% of L
where L is the maximum width of the dike.

 The invention is not limited to the embodiments which have been described and which can be modified by adding or deleting or replacing the means described by means of different but functionally equivalent structures.

Claims (11)

 1. Dike (1) partially submerged between an upstream body of water (3) and a downstream body of water (4), to mitigate in the body of water located downstream the effects of the swell which occurs in the extent of water located upstream, This dam having a front (5) facing downstream, characterized in that the part (AB) of the downstream front which is likely to be affected by the movement of water under the effect of the swell, is essentially in a downward slope downstream at an angle (a) at most equal to 60 relative to the horizontal.  2. Dike (I) according to claim 1, wherein said angle (a) is between 250 and 40.  3. Dike (I) according to claim 2, wherein said angle (a) is between 30 and 40.  4. Dike (1) according to claim 3, in which said angle (a) is close to 35.  5. Dike (1) according to one of claims I to 4, wherein said part (AB) of the downstream front consists of an inclined plane.  6. Dike (1) according to one of claims I to 5 ct whose upstream front (10) has a horizontal projection (I () a) followed by a curved part (lOb) bending gradually from the advance horizolltalc up to the vertical.  7. [) iguc according to claim 6. wherein said arched portion (1 Oh) is dc parabolic shape.  8. Dike according to one of the revcndications 1 to 7 ct in which the two fronts of the dam are constituted by the two opposite faces of the same box (12).  9. Dike according to one of claims 1 to 7 and in which the two fronts dc the dike are constituted by the two opposite faces of a group dc two boxes (1, 6) which are separated. located opposite and carried by respective piles.  10. Dike according to one of claims 1 to 9 and which is carried by piles.  11. Dike according to one of claims 1 to X ct which constitutes a floating breakwater.