IT202100016151A1 - DEVICE FOR GENERATION OF ELECTRICITY FROM THE ENERGY OF AN EXTENSION OF WATER - Google Patents

Description

DEVICE FOR GENERATION OF ELECTRICITY FROM THE ENERGY OF AN EXTENSION OF WATER

Technical field of the invention

The present invention relates to the technical field of electrical energy generation devices. Pi? in particular, the present invention refers to a device for generating electric energy by exploiting the currents which are generated within an expanse of water, for example the sea, a river, a lake and the like.

State of the art prior to the invention

How?? known, the currents that are generated within an expanse of water, for example sea currents, constitute a low-cost and low environmental impact energy source. Devices have therefore been developed to convey the energy generated by the currents present within an expanse of water and to transform it into electricity.

An example of such devices ? disclosed in invention patent no. IT1319072, in the name of the applicant of the present application, and comprises a rotor positioned inside an expanse of water and supported by a drive shaft, which ? operationally connected to an electric generator. The rotor? housed in a container body, which has a cylindrical portion and a flared front portion, for water inlet. In the cylindrical portion and in the flared portion there are respective deflectors, to guide the water inside the container body and facilitate its interaction with the rotor.

Devices for generating electric energy from the energy of an expanse of water of the type described above, however, have the drawback due to the fact that the flow of water leaving the container body meets other water, which, in addition to slowing down the flow , causes it to deviate in unwanted directions, with consequent loss of efficiency of the electric generator to which the device? operationally connected.

Summary of the invention

The main purpose of the present invention ? therefore that of making available a device for generating electric energy from the energy of an expanse of water, configured in such a way as to present increased efficiency so? to produce a greater quantity? of electricity.

Another object of the present invention ? to make available a device for generating electricity from the energy of an expanse of water, configured to adapt to the natural variability? direction of sea currents or water flows, even rivers or canals.

Yet another object of the present invention? that of making available a device for generating electricity from the energy of an expanse of water, configured in such a way as to be able to resist, without being damaged, sea currents, sea waves or even very strong flows of water.

A further object of the present invention ? that of making available a device for generating electricity from the energy of an expanse of water, which is simple to maintain and/or replace parts.

Not the last purpose of the present invention ? that of making available a device for generating electricity from the energy of an expanse of water, which is substantially simple and reliable.

These and other aims, which will become clearer hereinafter, are achieved by a device for generating electric energy from the energy of a body of water according to the independent claim 1. Other characteristics of the present invention are defined in the dependent claims.

The invention therefore relates to a device for generating electrical energy from the energy of an expanse of water characterized in that it comprises at least one tubular body equipped with a first end positioned inside the expanse of water, or extremity? submerged, and a second extremity? positioned outside the expanse of water, or extremity? immersed, and at least one rotor housed in the first and/or in the second extremity? and supported by a drive shaft operatively connected to an electric generator.

The aforementioned combination of characteristics, and in particular the presence of the tubular body extending from the inside to the outside of the expanse of water, makes that the flow of water entering the first end? submerged tubular body comes out from the second end? emerged, therefore outside the expanse of water, advantageously avoiding slowdowns and deviations of the water flow, caused by the impact with other water and therefore increasing the efficiency of electricity generation.

In one embodiment, the rotor comprises a plurality of rotors. of blades, each equipped with a fixed portion and a movable portion extending to the fixed portion.

In one embodiment, from the first end? of the tubular body extends a flared portion, for the inlet of water into the tubular body and/or from the second end? of the tubular body extends a flared portion for the water outlet from the tubular body.

In one embodiment, within a forward portion of the first end? and/or the second extremity? of the tubular body there are first deflectors, able to guide the water inside the first and/or second end, so as to favor its interaction with the rotor.

In one embodiment, at the flared portion of the first end? there are second deflectors, able to guide the water, so as to favor its interaction with the rotor and/or with the first deflectors.

In one embodiment, the rotor drive shaft is supported by first, second and third supports. The first supports of? crankshaft of the rotor of the first extremity? of the tubular body are connected to the ends? opposite of the flared portion, the second supports of support of the motor shaft of the rotor of the first extremity? of the tubular body are connected between the? drive shaft and an input portion of the rotor and the third supports of the drive shaft of the rotor of the first end? of the tubular body are connected between the motor shaft and an output portion of the rotor. The first supports of the motor shaft of the rotor of the second extremity? of the tubular body are connected between the? drive shaft and an input portion of the rotor and the second supports of the drive shaft of the rotor of the second end? of the tubular body are connected between the motor shaft and an output portion of the rotor.

In one embodiment, the first end? of the tubular body externally brings a plurality? of guide and/or support appendages, preferably equipped with movable portions. In one embodiment, in the first end? of the tubular body there are concentric annular elements, which prevent the entry, inside the tubular body, of large objects, while allowing the water not to deviate and to be channeled into the flared portion, in which the element ring finger internal ? more longer than the others.

In one embodiment, downstream and below the flared portion of the second end? of the tubular body, ? a group of hydraulic blades is provided, which is set in rotation by the flow of water leaving the flared portion, so as to operate at least one further electric generator.

In one embodiment, the first end? of the tubular body? connected, through a flexible organ, to a floating element and the second extremity? of the tubular body? supported by one or more floating platforms.

In one embodiment, the first end rotor drive shaft is of the tubular body? supported by a? telescopic rod, which ? fixed to the bottom of the expanse of water, between the telescopic rod and the motor shaft, a ball joint being interposed, which allows the first end? of the tubular body to rotate in all directions while remaining parallel to the flow of the current.

In one embodiment, the device comprises a plurality of of tubular bodies arranged on at least two superimposed layers, each tubular body having a first end? positioned inside the expanse of water and a second end? positioned outside the expanse of water, and at least one rotor housed in the first and/or second extremity? and supported by a drive shaft operatively connected to an electric generator.

In one embodiment, the second ends of the tubular bodies of the layer arranged pi? below are supported by respective floating platforms, while the first extremities? of the tubular bodies of the layer arranged pi? at the top they are supported by means of their respective flexible members, by further floating platforms.

In one embodiment, the at least one tubular body is made of semi-flexible material.

Brief description of the drawings

Further characteristics and advantages of the invention will become more evident from the description of preferred embodiments of a device for generating electric energy from the energy of an expanse of water, illustrated for indicative and non-limiting purposes in the attached drawings, in which:

- Figure 1 ? a side view of a device for generating electrical energy from the energy of a body of water according to a preferred embodiment of the present invention;

- Figure 2 ? a perspective view of the device of Figure 1;

- Figure 3 ? a longitudinal section view of the components present at one end? submerged of the device of Figure 1;

- Figure 4 ? a perspective view of the components of Figure 3;

- Figure 5 ? a side view of a rotor of the device of Figure 1;

- Figure 6 ? a front view of the rotor of Figure 5;

- Figure 7 ? a front view of a cross section of components present at one? end? emergence of the device of Figure 1;

- Figure 8 ? a longitudinal sectional view, taken along line VIII-VIII of Figure 7;

- Figure 9 ? a perspective view of a device for generating electrical energy from the energy of a body of water according to a second embodiment of the present invention; And

- Figure 10 ? an enlarged view of the circled detail in Figure 9.

Detailed description of preferred embodiments of the invention

With reference to Figures 1 and 2, a device for generating electrical energy from the energy of a body of water according to a first preferred embodiment of the present invention is shown.

The device, indicated in general with the reference number 100, comprises a tubular body 10, having the shape of a stretched and elongated S, which comprises a first end? or end? submerged 11, intended to be positioned inside an expanse of water D, for example the sea, a river, a stream and the like, and a second end? or end? surface 12, destined to be positioned on the surface S of the expanse of water D.

The tubular body 10 ? made of material resistant to corrosion and high pressures and is, preferably, a semi-flexible tube, the curvature of which to obtain the stretched and elongated S shape can be be controlled by hydraulic systems (not shown) connected to control systems (not shown).

The end? submerged 11 of the device 100 ? preferably supported by a buoy 20, to which ? connected, by means of a flexible member 21, for example a rope or a chain, fixed to an engagement ring 23 projecting upwards from the end? submerged 11. L? extremity? emerged 12 of the device 100 ? instead supported by one or more? floating platforms 22. The buoy 20 ? can also be used to bring to the surface the? extremity? submerged 11 of the tubular body 10 to carry out maintenance operations or the like.

As shown in detail in Figures 3 to 6, inside the? submerged 11 of the tubular body 10 ? housed a rotor 30, comprising a plurality of blades 31 (Figure 6), preferably four, five or six blades, supported by a drive shaft 32. Alternatively, ? It is possible to provide a number of rotors 30 greater than one.

As shown in greater detail in Figures 5 and 6, the rotor 30 is longitudinally elongated, with the blades 31 having a fixed portion 33 and a mobile portion 34 extending to the fixed portion 33.

The movable portion 34 ? for example pivoted to a pin 35 connected to a slider (not shown) inserted in a cavity? of the driving shaft 32, movable in contrast and due to the action of a spring 36.

In this way, when the current flow should become too intense, the movable portion 34 of the blades 31 can? rotate, decreasing the incidence with respect to the current and, therefore, the energy collected on the driving shaft 32.

In a different embodiment (not shown) the movable portion 34 of the blades 31 is controlled by hydraulic or pneumatic actuators, controlled by an electronic processor. In this case, the geometry of the blades ? pre-settable and, therefore, adaptable to even very different conditions of the current flow.

As shown in detail in Figure 3, inside a front or water inlet portion of the end? submerged 11 of the tubular body 10 ? is there a plurality? of first deflectors 40, suitable for guiding the water inside the extremity? submerged 11 of the tubular body 10, so as to favor its interaction with the rotor 30.

In another embodiment, the deflectors 40 are movable at variable incidence with respect to the current of the water body.

From? end? submerged 11 of the tubular body 10 extends a flared portion 13, for inlet of the water into the tubular body 10.

Similarly to? extremity? submerged 11, the flared portion 13 also has a plurality? of second deflectors 42, which guide the water to favor its interaction with the rotor 30 and/or with the first deflectors 40.

The crankshaft 32 ? inserted inside the? extremity? submerged 11 of the tubular body 10 and ? supported by first 44, second 47 and third supports 48. The first supports 44 comprise inclined bars, which are connected, on the one hand, to enlargements 41 of the flared portion 13, while on the other hand they are all connected to a first support 39 of the driving shaft 32. The second supports 47 are inclined bars, which are connected, on the one hand, to an input portion of the rotor 30 and, on the other, to a second support 49 of the driving shaft 32. The third Supports 48 are straight bars which are connected, on the one hand, to an output portion of the rotor 30 and, on the other, to a third support 59 of the reciprocating motor 32. Furthermore, the forward supports 44 carry a plurality of of concentric annular elements 45 (in the example only four are shown), which prevent large objects from entering inside the tubular body 10 which could damage the same tubular body 10 and/or the deflectors 40, 42 and /or the rotor 30, while allowing the water not to deviate and to be channeled into the flared portion 13. The annular element 45 more? internal ? more along the others, so as to better direct the flow of water in the tubular body 10 at the connection support 39 of the supports 44, an area where turbulence could occur in the flow of water.

In a particular embodiment, not shown, at the mouth of the flared portion 13 can? a net or grille can also be placed to prevent even fish or small objects from entering the tubular body 10.

Furthermore, the annular elements 45 can also have vanes (not shown), which rotate the water to favor and/or improve the effect of the deflectors 40 and/or 42.

The end? submerged 11 of the tubular body 10 also carries externally four guide and/or support appendages 25 which, in addition to supporting the end? submerged 11 of the tubular body 10 of the device 100, allow the orientation and direction of the entire device 100 according to the currents present in the expanse of water, for example marine currents. Pi? in particular, the appendages 25 allow to maintain the? end? submerged 11 parallel to the flow of the current and, at the same time, allow the tubular body 10 to self-support, reducing the load on the buoy 20.

In practice, the appendices 25 are shaped according to an airfoil profile, so that the current flowing past them generates a sustaining force.

In particular, the appendages 25 are connected to a rear portion of the end? submerged 11 of the tubular body 10 and can have movable portions 26, which allow the tubular body 10 to be guided within the current flow.

Referring again to FIG. 1, the drive shaft 32 is connected to an electric generator 50 external to the tubular body 10. Alternatively, the electric generator 50 can? be placed inside the? extremity? submerged 11 of the tubular body 10. Furthermore, the driving shaft 32 ? supported by a? telescopic rod 37, which ? fixed to the bottom F of the expanse of water D.

Between the crankshaft 32 and the telescopic rod 37? preferably a ball joint 38 is provided, which allows the end? submerged body 11 of the tubular body 10 to rotate in all directions while remaining parallel to the flow of the current.

The connection of the ends? submerged 11 and emerged 12 of the tubular body 10, respectively to the buoy 20 and to the floating platform 22, allow the tubular body 10 to be supported even when the current present in the expanse of water, for example the marine current, is too weak to ensure its support exclusively due to the appendices 25 and the ball joint 38.

In this way, when the tubular body 10 is immersed in a flow of marine current, it? sustained, at its first end? submerged 11, by the ball joint 38 and by the appendages 25, with the flexible element 21 in tension with the buoy 20 and, at its second end? emerged 12, from the floating platform 22.

As shown in detail in Figures 7 and 8, inside the? emerged 12 of the tubular body 10 ? another rotor 60 supported by a driving shaft 62 is housed. It is possible to provide a number of rotors 60 greater than one.

The 60 rotor? entirely similar to rotor 30, illustrated above with reference to Figures 5 and 6, and will not come then further described.

Similarly to what has been described above with reference to the extremity? submerged 11 of the tubular body 10, inside a front portion of the end? emerged 12 ? is there a plurality? of first deflectors 46, able to guide the water inside the extremity? emerged 12 of the tubular body 10, so as to favor its interaction with the rotor 60.

In another embodiment, the deflectors 46 are movable at varying incidence with respect to the current of the water body.

From? end? emerged 12 of the tubular body 10 extends a flared portion 15, for the water outlet from the tubular body 10.

The crankshaft 62 ? inserted inside the? extremity? emerged 12 of the tubular body 10 and ? supported by first 67 and second 68 supports. The first supports 67 comprise inclined bars, which are connected, on the one hand, to an input portion of the rotor 60, while on the other hand they are all connected to a first support 66 of the rotor 60. driving shaft 62. The second supports 68 comprise straight bars, which are connected, on the one hand, to an outlet portion of the rotor 60, while on the other hand to a second support 69 of the driving shaft 62.

The crankshaft 62 of the rotor 60 ? connected to an electric generator 55 (see Figures 1 and 2) external to the tubular body 10. Alternatively, the electric generator 55 can? be placed inside the? extremity? emerged 12 of the tubular body 10.

Immediately downstream and below the flared portion 15, ? a group of hydraulic blades 17 is provided, supported by arms 18 so that the hydraulic blades are impacted and rotated by the flow of water leaving the flared portion 15 to operate a pair of electric generators 70, located at the sides of the support arms 18 of the hydraulic blade group 17, thereby producing additional electrical energy. Preferably, the hydraulic blade group 17 can be raised or lowered by the action of hydraulic actuators 19.

With reference to Figures 9 to 10 , a device for generating electric energy from the energy of a body of water according to a second embodiment of the present invention is shown.

The device, indicated in general with the reference number 1100, comprises a plurality of tubular bodies 10 of the type described above with reference to Figures 1 to 8.

In the illustrated embodiment, two layers of superimposed tubular bodies 10 are provided, supported by a load-bearing structure (not visible in the figure), in which the ends? emerged 12 of the tubular bodies of the lower layer are supported by respective floating platforms 22, while the ends? submerged 11 of the tubular bodies 10 of the upper layer are supported, by means of the respective flexible members 21, by further floating platforms 24.

Preferably, on the 24 floating platforms that support the ends? submerged 11 of the tubular body 10 pu? be positioned a crane 90, which, by means of a chain or rope 91, allows you to lift each end? submerged 11 of the tubular body 10, if it is necessary to carry out maintenance on the rotor 30 or other components present inside it.

The operation of the devices 100 and 1100 for producing electrical energy from the energy of a body of water according to the invention is evident from what has been described and illustrated and, in particular, basically the following.

In working condition, the water enters each tubular body 10 through the flared portion 13 of the end? submerged 11 and is rotated by the deflectors 42 and then by the deflectors 40. Subsequently the water passes through the rotor 30 causing it to rotate. The rotor 30, in turn, rotates the drive shaft 32, which drives the electric generator 50.

The water that passes through the rotor 30 is not discharged into the expanse of water, but flows inside the tubular body 10 until it reaches the end of the rotor. emerged 12, and emerge from it from the flared portion 15.

In the event that in? extremity? emerged 12 a further rotor 60 is foreseen, the water arriving at the end? emerged 12 is rotated by the deflectors 46 and passes through the rotor 60, causing it to rotate. The rotor 60, in turn, rotates the drive shaft 62 which drives the electric generator 55. Furthermore, the water leaving the flared portion 15 of the tubular body 10 impacts on the hydraulic blade group 17 located at the outlet of the flared portion 15, making it rotate and thus activating the additional electric generators 70.

When the current changes direction, the tubular body 10 rotates around the ball joint 38, guided by the appendices 25, and always remains parallel to the flow of the current.

When the current fails to guarantee the support of the tubular body 10, the support action is ? guaranteed by the buoy 20, or by the floating platforms 24, through the flexible connection member 21.

What? the tubular body 10 is prevented from resting on the seabed with the possibility? itself and/or the appendices 25 and/or the ball joint 38 and/or other parts still get damaged.

Furthermore, in an advantageous way, the buoy 20, or the floating platforms 24, signal the position of the end? submerged 11 of the tubular body 10, not visible on the surface S of the expanse of water D.

From the description given, the characteristics of the device for generating electrical energy from the energy of an expanse of water of the present invention are evident, as well as as the relative advantages are evident. In particular, the device has increased efficiency thanks to the fact that the flow of water flowing inside it, not impacting with other water, but going out directly outside the expanse of water from the end of the device. emerged from each tubular body does not undergo slowdowns or unwanted deviations.

? Finally, it is clear that the device for generating electricity from the energy of an expanse of water so conceived ? susceptible to numerous modifications and variations; moreover, all the details can be replaced by technically equivalent elements.

Claims (14)

1. Device (100; 1100) for generating electrical energy from the energy of an expanse of water (D) characterized in that it comprises at least one tubular body (10) provided with a first end? (11) positioned inside the expanse of water (D) and a second end? (12) positioned outside the expanse of water (D) and at least one rotor (30; 60) housed in the first (11) and/or in the second end? (12) and supported by a driving shaft (32; 62) operatively connected to an electric generator (50; 55). 2. Device (100; 1100) according to claim 1, wherein said rotor (30; 60) comprises a plurality of of blades (31), each comprising a fixed portion (33) and a movable portion (34) in extension to the fixed portion (33). 3. Device (100) according to claim 1 or 2, wherein from the first end? (11) of the tubular body (10) extends a flared portion (13), for the water inlet into the tubular body (10) and/or from the second end? (12) of the tubular body (10) extends a flared portion (15) for water outlet from the tubular body (10). 4. Device (100; 1100) according to any one of the preceding claims, wherein, inside a front portion of the first end? (11) and/or of the second extremity? of the tubular body (10) there are first deflectors (40; 46), able to guide the water inside the first end? (11) and/or of the second extremity? (12) of the tubular body (10), so as to favor its interaction with the rotor (30; 60). 5. Device (100; 1100) according to any one of the preceding claims, in which, at the flared portion (13) of the first end? (11) of the tubular body there are second deflectors (42), able to guide the water, so as to favor its interaction with the rotor (30) and/or with the first deflectors (40). 6. Device (100; 1100) according to any one of claims 3 to 5, wherein the drive shaft (32; 62) of the rotor (30; 60) is? supported by first (44; 67), second (47; 68) and third supports (48), wherein the first supports (44) of the driving shaft (32) of the rotor (30) of the first end? (11) of the tubular body (10) are connected at the ends? opposite of the flared portion (13), the second supports (47) of the driving shaft (32) of the rotor (30) of the first end? (11) of the tubular body (10) are connected between the driving shaft (32) and an input portion of the rotor (30) and the third supports (48) of the driving shaft (32) of the rotor (30) of the first end? (11) of the tubular body (10) are connected between the driving shaft (32) and an output portion of the rotor (30), while the first supports (67) of the driving shaft (62) of the rotor (60) of the second end? (12) of the tubular body (10) are connected between the driving shaft (62) and an input portion of the rotor (60) and the second supports (68) of the driving shaft (62) of the rotor (60) of the second end? (12) of the tubular body (10) are connected between the driving shaft (62) and an output portion of the rotor (60). 7. Device (100; 1100) according to any one of the preceding claims, wherein the first end? (11) of the tubular body (10) externally carries a plurality? of guide and/or support appendices (25), preferably equipped with movable portions (26). 8. Device (100; 1100) according to any one of the preceding claims, wherein in the first end? (11) of the tubular body (10) there are concentric annular elements (45), which prevent the entry, inside the tubular body (10), of large objects, while allowing the water not to deviate and be channeled into the flared portion (13), in which the annular element is more? internal ? more longer than the others. 9. Device (100; 1100) according to any one of the preceding claims, in which, downstream and below the flared portion (15) of the second end? (12) of the tubular body (10), ? foreseen a group of hydraulic blades (17), which raised and lowered in the flow of water by means of hydraulic actuators (18), ? rotated by the flow of water leaving the flared portion (15), so as to operate at least one electric generator (70). 10. Device (100; 1100) according to any one of the preceding claims, wherein the first end? (11) of the tubular body (10) ? connected through a flexible member (21) to a floating element (20) and the second end? (12) of the tubular body (10) ? supported by one or more floating platforms (22). 11. Device (100; 1100) according to any one of the preceding claims, wherein the drive shaft (32) of the rotor (30) of the first end? (11) of the tubular body (10) ? supported by a? telescopic rod (37), which ? fixed to the bottom (F) of the expanse of water (D), between the telescopic rod (37) and the motor shaft (32) being interposed a ball joint (38), which allows the first end? (11) to rotate in all directions while remaining parallel to the flow of the current. 12. Device (1100) according to any one of the preceding claims, comprising a plurality of of tubular bodies (10) arranged on at least two superimposed layers, each tubular body (10) being provided with a first end? (11) positioned inside the expanse of water (D) and a second end? (12) positioned outside the expanse of water (D) and at least one rotor (30; 60) housed in the first end? (11) and/or in the second extremity? (12) and supported by a driving shaft (32) operatively connected to an electric generator (50; 55). 13. Device (1100) according to claim 12, wherein the second ends? (12) of the tubular bodies (10) of the layer arranged more? below are supported by respective floating platforms (22), while the first extremities? (11) of the tubular bodies of the layer arranged more? at the top they are supported by, by means of the respective flexible members (21), further floating platforms (24). 14. Device (100; 1100) according to any one of the preceding claims, wherein the at least one tubular body (10) is? made of semi-flexible material.