FR2997458A1 - Tidal turbine system for producing electric current in marine region, has turbine and support structure including guidance units for guiding downward and upward elements toward each other, where interlocking elements co-act with each other - Google Patents

Abstract

The system has a turbine (1) including a body (11) that carries a rotor (10), and a support structure (2) including a connection unit on the ground and supports the turbine in immersion. The support structure includes an upward element (22) forming an interlocking element. The turbine body comprises a downward element (12) forming another interlocking element in order to co-act with the former interlocking element. The turbine and the support structure include guidance units e.g. truncated male part (120) and centering unit (220), for guiding the downward and upward elements toward each other.

Description

A tidal turbine system consisting of a turbine and a support structure, with positioning elements and a means for guiding the interlocking elements. The field of the invention is that of the design and manufacture of tidal systems. More specifically, the invention relates to a technique for mounting a turbine on its supporting structure. According to the principle of tidal energy, the tidal stream exerts a force on the blades of the turbines so as to rotate the rotor thereof. Turbines rotate more or less quickly depending on the tidal current and / or underwater currents. This rotation causes an alternator capable of producing a variable electric current, conventionally rectified by an offshore converter, then relayed to a network by a main cable. According to certain tidal turbine configurations, the turbines are installed at ± 50 m depth and each rest on a supporting structure. The installation of the tidal turbine system therefore involves operating successively in: - the installation of the supporting structure on the seabed; - the installation, at ± 50 m depth, of the turbine on the supporting structure. Generally, the carrier structure has a cradle or stool form on which the turbine is made to be positioned. The descent and positioning of the turbine are in practice relatively complicated operations, even perilous, because of the constraints related to the following parameters and, a fortiori, the combination of the following parameters: 30 - depth of installation; - weight of the turbine, which usually reaches several tens of tons; marine currents that reach speeds of 3 to 5 m / s at the installation depths mentioned above. The means to be used to install the turbines are therefore complex, heavy and expensive.

Anyway, the installation time is very long. Furthermore, the turbine is intended to be connected to a collector, generally intended to rectify the current produced by the tidal turbines, in order to transport the energy produced to a delivery station, itself intended to transfer energy to the network. distribution of electricity. To do this, according to a traditional design, the body of the turbine has a manhole in its rear part, through which extends the cable connecting the generator of the turbine to the collector. As the turbine is raised a few meters above the seabed (generally about ten meters), the cable leaves the body of the turbine and hangs until it comes to rest on the seabed on which it extends until manifold. However, as already mentioned above, at such depths, it is conventional to encounter relatively strong marine currents, which can reach 3 to 5 m / s. As a result, the cable, between the outlet of the turbine and the seabed, is caused to be strongly ballot, the risk that it hits elements of the tidal system, which can lead to degradation of the cable itself and / or the turbine and / or the supporting structure. Of course, if such degradations are deplored, maintenance operations may be necessary and then prove to be delicate and expensive at the depths at which the tidal systems are installed. The object of the invention is in particular to overcome the drawbacks of the prior art. More specifically, the invention aims to provide a tidal system comprising a turbine and a supporting structure of the turbine, to facilitate the installation of the turbine on the carrier structure. In this sense, the invention also aims to reduce the installation time of the turbine on the carrier structure.

The invention also aims to provide such a tidal system which limits maintenance interventions due to system damage due to possible shocks caused by the turbine cables beaten by marine currents. These objectives, as well as others which will appear later, are achieved thanks to the invention which relates to a tidal turbine system comprising a body carrying a rotor and a bearing structure including ground connection means and intended to support the immersion turbine, characterized in that the carrier structure has at least one ascending element forming a first interlocking member and in that the body of the turbine has at least one descending element forming a second interlocking member complementary to the first interlocking member to cooperate with it, the turbine and the carrier structure including means for guiding the descending element and the ascending element towards each other. In this way, a tidal system according to the invention facilitates the installation of the turbine on the supporting structure and reduces the corresponding response time. Indeed, not only the system according to the invention is not satisfied to rest the turbine on a part of the support element as is the case with the prior art, this by the implementation of a connection by interlocking, but it contributes of itself to the positioning of the turbine relative to the supporting structure, thanks to the guide means.

As will become clearer later, these guide means are available in two types of complementary means, namely: guide means in the approach phase of the turbine relative to the support structure; final guide means at the time of engagement of the turbine with the carrier structure.

It therefore clearly appears that a tidal system thus designed contributes greatly to providing assistance in setting up the turbine on its supporting structure. According to an advantageous embodiment, the ascending element of the supporting structure takes the form of a cylindrical column.

A cylindrical column is indeed optimized as to the shape of the surfaces exposed to the sea currents. In this case, the ascending element has a frustoconical concavity delimited by centering means constituting the second interlocking member, the descending element comprising a frustoconical male part intended to cooperate with the centering means. Of course, other forms of complementary members intended to fit can be envisaged without departing from the scope of the invention. For example, it is also conceivable that the male part is carried by the ascending element while the female element is then presented by the turbine. In any case, such guiding means intervene in the final phase of guiding the ascending element with the descending element, that is to say just before the interlocking and during the interlocking. Advantageously, the frustoconical male portion of the descending element is surmounted by a cradle intended to rest against the corresponding end edge of the ascending element. Thus, the seating of the turbine on the supporting structure is optimized by means of a surface-to-surface contact zone.

According to a preferred embodiment, said ascending element is connected to the ground connection means by a frame, and the frame comprises at least two uprights between which the ascending element extends, the body of the turbine carrying guiding means intended to cooperate with at least one of said amounts for positioning said downward element vertically above said ascending element. As will be explained in more detail later, such guide means intervene in a phase of approach of the turbine relative to the supporting structure, that is to say in advance of the guiding means mentioned above . In this case, according to a particular embodiment, the guide means comprise two bars extending from the body of the turbine in converging directions. According to another characteristic, the body of the turbine carries, on each side of the body, a transverse arm each intended to abut orthogonally against one of the uprights. It will be noted that the combination of the guide means which have just been described, involved in the approach phase, tends to assist the positioning of the turbine in two directions perpendicular to the upward element of the supporting structure. According to another preferred feature of a tidal turbine system according to the invention, in which the turbine is intended to be connected to a manifold by an electric cable, the turbine has a ventral outlet forming a passage for the electric cable, and the carrier structure comprises a connector presented to be directed towards the turbine body, for connection to the electric cable of the turbine. It is clear from this feature that such a design facilitates the electrical connection of the turbine to the collector via the carrier structure. In this case, the connector is advantageously integrated with the cylindrical column.

Thus, the cylindrical column is a kind of sheath in which the electric cable can extend to the ground level, thus being protected from the effect of marine currents. In other words, with such an arrangement, the cable is no longer buoyed by the sea currents as is the case with the solutions of the prior art. Other features and advantages of the invention will appear more clearly on reading the following description of a preferred embodiment of the invention, given by way of illustrative and nonlimiting example, and the appended drawings among which - Figures 1 to 3 are schematic representations of a tidal system according to the invention, illustrating successive steps of the final guide of the turbine relative to the carrier structure; FIGS. 4 and 5 are partial views of a tidal system according to the invention, schematically illustrating the descending and ascending elements of the system; FIGS. 6 and 7 are diagrammatic representations of a tidal turbine system according to the invention, illustrating two successive guide phases in approach of the turbine with respect to the carrying structure. With reference to FIGS. 1 to 3, a tidal turbine system according to the invention comprises: on the one hand, a turbine 1, comprising a body 11 carrying a rotor 10, and; - On the other hand, a supporting structure 2, including ground connection means, and being adapted to support the turbine 1 in immersion. As clearly shown in FIGS. 6 and 7, the carrier structure 1 is of the tripod type and comprises a frame 20 whose base is of generally triangular shape, presenting at each of its peaks ground connection means 21.

These ground connection means may be metal or concrete, with or without inking means on the seabed. In addition, the carrier structure has an upward element 22, extending inside the perimeter defined by the connecting means 21, 5 and preferably positioned equidistantly from each of the connecting means 21. The turbine 1 presents as to it, under the ventral portion 110 of the body 11 of the turbine, a descending element 12. According to the principle of the invention, the rising element 22 of the carrier structure forms a first interlocking member and the descending element of the turbine forms a second interlocking member complementary to the first interlocking member in order to cooperate therewith. In addition, the turbine and the supporting structure include means 15 for guiding the descending element and the ascending element towards each other. As illustrated by FIGS. 1 to 5, the ascending element 22 of the supporting structure takes the form of a cylindrical column, having at its upper end, or in the vicinity of the latter, a first fitting member 20 . According to the present embodiment, the cylindrical column has in the vicinity of its upper end centering means 220, inside the column, delimiting a frustoconical concavity 221. The downward element 12 of the turbine comprises in turn a frustoconical male portion 120, intended to cooperate with the frustoconical cavity 221 inside the cylindrical column. Furthermore, the frustoconical male portion 120 of the turbine is surmounted by a cradle 13 extending from the body 11 of the turbine.

At the junction between the cradle and the male frustoconical portion, the cradle has an annular shoulder 130, intended to rest against the corresponding end edge 222 of the ascending element. Note that the inner and outer diameters of the annular shoulder 130 on the one hand, and the upper end edge of the column on the other hand, are substantially identical so as to form complementary surfaces to one of the other. Furthermore, the cradle 13 has two side walls 131 having a decreasing height from their middle towards their lateral ends (as it appears in FIG. 5), and delimiting between them a curved reception space (as it appears on FIG. Figure 4) for receiving the body of the turbine. The guide of the interlocking phase of the falling element of the turbine with the upward element of the carrier structure is carried out in the following manner. According to the configuration illustrated in Figure 1, the frustoconical male portion 120 of the turbine is offset axially relative to the frustoconical cavity 221 of the cylindrical column of the supporting structure. By operating the descent of the turbine at a slow speed with respect to the bearing structure, the frustoconical male portion 120 engages in the frustoconical cavity of the cylindrical column, until the frustoconical male portion comes into contact with the means of rotation. centering 220. Continuing the descent of the turbine, the frustoconical male portion slides against the surface of the centering means 220 of the column, so as to gradually bring into coincidence the axis of the frustoconical male portion with the axis of the frustoconical cavity. The descent of the turbine relative to the supporting structure takes place until the frustoconical male part of the turbine and the frustoconical cavity of the column is positioned coaxially. As shown in FIG. 3, at this point, the annular shoulder 130 of the cradle 13 is in planar support on the upper end rim 222 of the column.

It should be noted that the frustoconical male portion 120 has a conicity equal to that of the upper end portion 223 of the column, so that the outer wall of the frustoconical male part matches the inner wall of the upper end portion once the descending and ascending elements nested. In addition, the turbine and the supporting structure are designed so that when the interlocking of the descending element and the ascending element is carried out, the turbine is positioned and locked in the direction of the predetermined current, thus avoiding any rotation of the turbine body in case of change of direction of the current (which would cause wear phenomena). Furthermore, as shown in FIG. 6, the frame 20 of the supporting structure is designed to connect the upward element of the supporting structure, in this case the cylindrical column, with the ground connection means. . According to the present embodiment, the frame comprises: - peripheral bars 200, connecting in pairs the connecting means 21; a support bar 201 extending between two of the peripheral bars 200, on which the rising element 22 comes to rest; a series of intermediate bars 202, extending from the peripheral bars 200 and / or the carrier bar 201, and some of which are coupled to the rising element 22, so as to maintain the latter in an orthogonal axial direction in the plane defined by the peripheral bars 200. The frame further comprises two uprights 203. Specifically, the uprights 203 are carried by two of the peripheral bars 200, and are positioned at the ends of the support bar 201 so that the An ascending element extends between the two uprights 203. The body of the turbine carries meanwhile guiding means 14 intended to cooperate with at least one of the uprights 203 to position the descending element 120 to the It is noted that the expression "vertically" implies the possibility that the ascending element and the descending element are not necessarily coaxial, thus justifying the gating. uidage obtained by the cooperation of the frustoconical male portion and centering means as described above. According to the present embodiment, the guide means 14 comprise two bars 140 extending from the body 11 of the turbine, this in converging directions. According to the embodiment illustrated in FIGS. 6 and 7, the bars 140 are connected at their convergent end by a connection bar 141 in an arc of a circle.

In addition, the body of the turbine carries, on each side of the body, a transverse arm 142. The body 11 of the turbine has a width smaller than the spacing between the uprights 203. The transverse arms 142 extend in the alignment of one another, over a length such that the distance between their free ends 143 is greater than the space between the uprights 203. Thus, each transverse arm is intended to abut orthogonally against one of the uprights 203. It will be noted that, according to the present embodiment, the two bars 140 are connected to the body of the turbine by means of the transverse arms 142. With the guiding means which have just been described, the phase guidance of approach of the turbine relative to the supporting structure is carried out as follows: in a first step, the turbine is brought roughly in the vicinity of the carrier structure, this providing at least that the bars 140 g means uidage 14 extend between the uprights 203 of the supporting structure; - In a second step, the turbine is moved substantially in a horizontal plane, so that one of the bars 140 comes into contact with the corresponding amount 203; the displacement essentially in a horizontal plane of the turbine is continued, which simultaneously results in a sliding of the bar 140 in contact with the corresponding amount 203; displacement essentially in a horizontal plane of the turbine is continued until the body of the turbine is substantially centered between the uprights 203; - In the centered position of the turbine between the uprights 203, the transverse arms 142 abut orthogonally each against a post 203. In this configuration (turbine 130 between the uprights 203, transverse arms 142 abutting against the uprights 203), the part frustoconical male extends substantially vertically above the ascending element 22 constituted by the cylindrical column. The turbine can then be lowered at a slow speed until the guiding of the engagement of the frustoconical male part in the frustoconical cavity takes place as described above. Moreover, the turbine being intended to be connected to a manifold 25 by an electric cable, it is provided according to another advantageous characteristic of the invention to pass the electric cable 3 in the frustoconical male portion 120 of the turbine. The cable 3 extends in the frustoconical male portion to a socket 30 presented at the outlet of the frustoconical male portion. In other words, the frustoconical male portion constitutes a ventral outlet of the turbine, forming a passage for the electric cable 3 connected to the alternator of the turbine.

The supporting structure comprises a connector 4, integrated in the cylindrical column constituting the upstream element 22 and presented to be directed towards the body of the turbine. The plug 30 and the connector 4 are designed such that when the engagement of the turbine with the carrier structure takes place, the plug 30 is automatically engaged with the connector 4 of the carrier structure. It is thus understood that, once the engagement of the frustoconical male portion with the frustoconical cavity made, the electrical connection cable 40 is connected to the turbine cable via the collector 4 and the socket 30. As 1 to 3, an electrical connecting cable 40 extends from the connector 4, inside the ascending element 22 to an outlet 221 at the base of the ascending element, 15 outlet being planned in the vicinity of the seabed. The cable exits the rising element to come and rest directly on the seabed.

Claims (10)

REVENDICATIONS1. Turbine system consisting of a turbine (1) comprising a body (11) carrying a rotor (10) and a bearing structure (2) including connecting means (21) on the ground and intended to support the turbine (1) immersed , characterized in that the carrier structure (2) has at least one upward element (22) forming a first interlocking member and in that the body (11) of the turbine (1) has at least one downward element (12). forming a second interlocking member complementary to the first interlocking member in order to cooperate therewith, the turbine and the supporting structure including guide means (120), (220) of the descending element (12) and from the ascending element (22) towards each other. 2. A tidal system according to claim 1, characterized in that the ascending element (22) of the carrier structure takes the form of a cylindrical column. 3. tidal system according to claim 1, characterized in that the upward element (22) has a frustoconical concavity (221) delimited by centering means (220) constituting the first interlocking member, and in that the descending element (12) comprises a frustoconical male portion (120) intended to cooperate with the centering means (220). 4. A tidal system according to claim 3, characterized in that the frustoconical male portion (120) is surmounted by a cradle (13) intended to rest against the corresponding end edge (222) of the ascending element. 5. tidal system according to claim 1, characterized in that said upward element (22) is connected to the ground connection means (21) by a frame (20). 6. tidal system according to claim 5, characterized in that the frame (20) comprises at least two uprights (203) between which extends the upward element (22), the body (11) of the turbine carrying means guide means (14) for cooperating with at least one of said uprights (203) for positioning said downward member (12) vertically above said upright member (22). 7. tidal system according to claim 6, characterized in that the guide means (14) comprise two bars (140) extending from the body (11) of the turbine in converging directions. 8. tidal system according to claim 6, characterized in that the body (11) of the turbine carries, on each side of the body, a transverse arm (142) each intended to abut orthogonally against one of the uprights (203). 9. tidal system according to any one of claims 1 to 8, wherein the turbine (1) is intended to be connected to a manifold by an electric cable (3), characterized in that the turbine has a ventral outlet forming a passage for the electric cable, and in that the carrier structure (2) comprises a connector (4) presented to be directed towards the turbine body to be connected to the electric cable (3) of the turbine. 10. tidal system according to claims 2 and 9, characterized in that the connector (4) is integrated in the cylindrical column.