PT105135B - EQUIPMENT FOR PRODUCING ELECTRICAL ENERGY WITH MARITIME AND SEA CURRENTS - Google Patents

Abstract

The present invention relates to the machine which generates electrical energy, the operation of which is based on the movement of the pendulum, with an end in the magnet, inside an air-filled sphere (1), with two halves joined in a vertical axis (10), RUGGED EXTERIOR SURFACE, WHICH MOVES WITH WATER PASSAGE IN THE SEA AND IS SUPPORTED BY TWO SUPPORTS (3, 9). WHEN THE PENDULUM HAS MOVED, IT IS STILL EXCITED BY THE INTERACTION WITH TWO FIXED, LARGE-DIMENSIONAL AND EXTERIOR PLASTIC-COATED IRON ELEMENTS SUPPORTED IN TWO SUPPORTS (6). THE ELECTRIC CURRENT IS TRANSFERRED THROUGH CABLES (2). WEIGHT (7) BELOW THE SPHERE CONFIRMS YOU STABILITY. THE BASE (4) HAS A HANGER (5) FOR THE REMOVAL OF THE STRUCTURE. ALL COMPONENTS IN CONTACT WITH WATER HAVE A HYDRODYNAMIC FORM.

Description

DESCRIPTION

Equipment for producing electricity with sea currents and tides. Technical area of the invention

At present, most of the electricity is still obtained through the use of sources or that are non-renewable (such as fossil fuel-fired plants) or with a high environmental impact (dams). However, in Portugal, a significant part of electricity is already produced from renewable sources, such as wind, where there is no significant environmental impact. Nevertheless, the sea is very vast off the Portuguese coast, there are no equipment installations that allow generating electricity from sea currents, tides, or currents in estuaries of rivers. Across the world, the contexts of sea energy use are either very small or are in the study / prototype phase. However, the energy contained in marine water movements may be important to meet the energy needs of our society.

While it is true that there is a need for environmentally-friendly electrical energy, it is also true that renewable forms of production will only be a real option for economic operators if the energy they produce produces competitive production costs. This question is essential. The energy of a sea current of 19.2 km / h is equivalent to that contained in winds of 176 km / h, and thus, although the velocity of the currents is lower than the wind, there is an expectation of obtaining good results as in land with the winds.

In addition to efficiency issues, the factors of maintenance and maintenance of a machine at sea are also important. In fact, contact with sea water can have a detrimental effect on energy-generating equipment. There is thus a need to protect them properly. The impact on the marine habitat should also be taken into account in projects of this type, leading to the choice of technical options that allow it to be minimized, both visually and operationally. 1/5

State of the art

In the context of sea waves, for example USP 7453165, generators are used inside a spherical object. For marine currents, fans are used. The design of permanent magnets is considered (" Proofs of Pedagogical Aptitude ", Anabela Gonçalves, UNL, 2000, p.62).

SUMMARY OF THE INVENTION The present invention relates to a machine for producing electrical energy with sea currents and tides, the operation of which is based on the movement of a sphere (may be another hydrodynamic object) and its impactor contained therein, which will have origin in the friction provoked by the passage of marine currents and magnetic induction field of a permanent magnet at the end of the pendulum and two external iron elements.

This machine is especially suitable for seafloor sites located in the coastal strip, with depths up to at least 100 meters, as it has a robust structure and materials. It is also indicated for places where the sea currents present an average dynamism, since the machine has two elements of iron and an imán that have like objective to prolong the oscillating movement of the pendulum that allows the generation of electrical current (main distinctive element of the invention). At the extremes of motion, the gravitational force subtracted from the thrust force on the pendulum is less than the pulling force of the magnet until the thrust force extinguishes and the gravitational force becomes greater than the force of the magnet and the pendulum descends again. Achieving acceptable performance, with increased efficiency.

In the specific case of the production of electric power at sea, for which the machine of this invention is especially indicated, it may be pointed out that an equipment with these characteristics may lead to an increase in the production of electric energy, while avoiding the visual impact or in the circulation of ships, which could arise if the production of energy were carried out on or near the surface of the sea. This invention overrides these drawbacks as it is located at a reasonable depth, which is possible thanks to its constitution and shape.

Another advantage is that the equipment which generates the energy is in contact with the air, inside the sphere, and not in contact with the sea water. On the one hand, the pendulum in contact with the air will have a more fluid movement than it would have if it were in contact with the water, on the other, the fact that it does not contact with sea water means that it is not subject to deterioration due to salt and moisture. The machine according to the present invention comprises a support which stabilizes it in the seabed under which there is in parallel 2/5 a very thin structure which allows some mobility of the whole machine in order to allow its adaptation to the direction of chains. Under this structure, there are support supports for the machine and the two lateral iron elements. This sphere contains, in addition to air and pendulum with permanent magnet end, two (may be only one) parallel generators that are located laterally to the central pendulum support shaft. These generators, whose pendulum-driven movement allows the production of electric current, are supported by an inner structure of the ball at its top, which maintains them in the correct position and in line with the pendulum. The generated current is routed through cables that exit the sphere through its top and go to the structure of the machine. Under the sphere is an electronic system to detect its movement, for the purpose of monitoring the evolution of its operation. The machine can be installed in conjunction with other machines, in a cage structure, with a shape that can be pyramidal, allowing greater stability of the joint structure.

Thus, the machine object of the present invention is characterized in that it is a mechanical and electrical equipment, specially designed to produce electrical energy with the sea currents and tides. The present invention is hereinafter described in detail, without limitation and by way of example, by means of a preferred embodiment thereof, shown in the accompanying drawings, in which: Fig. 1 is a schematic (front) simplified perspective view of an embodiment of the machine according to the invention; and Fig. 2 is a schematic (side) and simplified perspective representation of an embodiment of the machine according to the invention; and Fig. 3 is a schematic section (inside of the ball and pendulum) of said machine of Figs. 1 and 2; and Fig. 4 is a schematic and simplified perspective front view of an embodiment of the sensor embedded in the weight surface located on the underside of the ball according to the invention; and Fig. 5 is a simplified schematic (top) perspective representation of an embodiment of the microscopic flaps of the sphere surface according to the invention; and Fig. 6 is a schematic (lateral) simplified perspective view of an embodiment of the weights and supports for transporting electricity to land according to the invention. 3/5

Description of the Preferred Embodiment

With reference to the figures, the preferred embodiment of the invention will now be described, wherein the machine is constituted by a set of bodies shown in said figures, assembled as follows.

All the exterior elements of the machine have a hydrodynamic shape. The support structure (4) secures and maintains the stabilized machine in the seabed and houses remote ball motion monitoring equipment (1) (constituted by a sensor (24), emitter, detector in its structure below the ball, and a reflecting crystal, by weight (7)). In the frame there are side rings (5) for removing the machine to the surface. The support structure (4) consists of a resistant material (with good indices of strength / weight and tensile strength, eg polyester and steel) at the pressure (and high point stresses) and the aquatic medium and has a volume and density that allow to compensate the vertical force originated by the ball (1) essentially full of air (it is attentive to the principle of Archimedes).

On and parallel to said structure (4), there is a non-energy-producing mobile structure (12), with small wheels, with inner collar (4) for lateral movement (about 45 degrees for each side) of the machine, that the whole machine is more in the direction of the sea currents. Above the movable structure (12), there are the side supports (3, 9) of the ball, connected so as to prevent water from entering but allowing movement thereof, and also the supports of the iron elements (8, 11) which can be coated in paint (or plastic), and are lateral and superior to the resting point of the pendulum, near the equatorial region of said sphere (1), not contacting the surface thereof. The ball (1) is constructed of titanium or alloys titanium molybdenum. Said iron elements (8, 11) on their side which is exposed to direct movement of the sea currents, have an oval shape. The position of said elements should be such that it increases the number of times that the pendulum (22,23), of permanent magnet end in Alnico (23), reaches the extreme points of its oscillating movement. This, together with the formation of two temporary and alternating magnetic circuits, wherein the ball (23) at the end of the pendulum (22, 23) is movable, and the iron elements are fixed (8, 11), are unexpected technical effects of this equipment. The materials existing inside said sphere (1), other than those of the pendulum end (Alnico), do not interfere with said elements (8, 11). The magnetic field of the magnet does not reach the generators and titanium or titanium alloy molybdenum is used in some components (shafts, supports and shafts) to avoid it.

Said side supports (3, 9) of the ball have at their end connections to bearings and rotators (not shown). Said ball (1) has a smooth inner surface 4/5 and the roughness of its outer surface is justified by the existence of thousands of millimetric flaps arranged facing the sea current and spaces between them (25). The intervals between the flaps allow flows of water and the oscillating movement, with capture and release of forces. Said ball (1) has two halves which are joined along a vertical axis (10) with rubber, a clamping clamp, bolts that tighten the flap laterally and / or further by indirect permanent connection with rivets. The transport of energy to earth is done by means of one or two cables (2), well insulated, which will be secured to a sequence of supports (26), which may be of steel, fixed in weights (27). The central shaft (16, 17) is between the two equal inductor-induced generators (15, 21), for example, which are located on each side at the ends of the horizontal shaft (16) where the two inductors of the generators, as if they were the same object. The two generators are secured by their top and laterally (14, 19, 20) by a light structure, which arises from the top of the ball, securing them with screws and recesses (not shown). The support elements are connected to the top surface of the sphere, and through them the cables are passed to the elements inside the sphere, there being no other way of contact between these elements. The weight of this structure is counterbalanced by an outer weight (7) at the lower end of the sphere. The center point of the wheel (17) is that where the " fixed " of the pendulum which ensures that the pendulum can move its loose end (22, 23) without it impacting the inner surface of the ball.

When said end (23) moves towards one of the opposing iron elements (8, 11), it is under its action and this, together with the action of the sea current, allows its movement, the actuation of the generators (15). , 21) and consequently the production of energy.

Lisbon, August 5, 2013 5/5

Claims (11)

An apparatus for producing energy, characterized in that it comprises a hydrodynamic object, supported by two supports (3, 9), in this case a sphere (1), with a smooth inner and outer rough surface, filled with multiple millimeter flaps, arranged with (25), said ball (1) having two halves, joined along a vertical central axis (10), and having inside thereof a pendulum (22, 23) with a permanent magnet, which oscillates and is connected to a shaft (16) which simultaneously drives two parallel generators (15, 21), in turn connected to electricity cables (2), which are secured to a sequence of supports (26) fixed in weights (27), said pendulum (22, 23) having a movement which is further extended by the interaction of the magnetic field of its end (23) with two iron elements (8, 11) ), which are external to the ball (1), lateral and sup above the equatorial region of said sphere (1), not contacting the surface thereof, both alternately forming with the pendulum end a temporary magnetic circuit, and the whole assembly is hydrodynamic in shape and supported by (4) which is attached to the ground, with rings, in which remote monitoring circuit and parallel mobile structure (12) is housed. Energy producing equipment according to claim 1, characterized in that it has a sphere, the outer surface of which is rough, consisting of thousands of millimeter flaps with faces oriented in the direction of the sea current, with a certain arrangement (25), and inner surface is smooth. Energy producing equipment according to claims 1 to 2, characterized in that the end of the pendulum (23) is also moved by magnetic interaction with two iron elements (8, 11), the combined action of which enables the end of the pendulum the pendulum (23) has a prolonged movement when it moves towards one of these elements (8, 11), which, together with the action of the sea currents, enables the generators (15, 21) to be energized. An apparatus for producing energy according to claims 1 to 3, characterized in that it has two generators (15, 21) and an axis which is common to the center of the sphere and made of titanium or alloy titanium molybdenum. 1/2 Energy producing equipment according to claim 1, characterized in that it has side rings (5) in the support structure (4) adjacent to the seabed. Apparatus for producing power according to one of Claims 1 to 5, characterized in that the support structure (4), consisting of pressure and water-resistant material, houses a remote monitoring apparatus comprising a sensor, emitter, detector its structure below said sphere (1), and a reflecting crystal (24) in the weight (7), which has a smooth surface. Energy producing equipment according to one of Claims 1 to 6, characterized in that it has, above the support structure (4), a second parallel movable support structure (12), which allows the whole assembly to be set in the direction of the chain the sea. An energy producing apparatus according to claim 7, characterized in that the moving structure is on wheels and further by an inner rim to said structure (4) which is in contact with the ground. Energy producing equipment according to one of Claims 1 to 8, characterized in that it has a sphere (1), which is open or closed, using two halves, which are joined along a vertical axis with rubber, and fasten with the use of screws, clamps and / or rivets (10). Energy producing equipment according to one of Claims 1 to 9, characterized in that it has a set of fixed supports (26) in weights (27), for guiding the electric cables (2) along the seabed until it reaches Earth. 11. Apparatus according to any one of the preceding claims, characterized in that it comprises hydrodynamic object (1) essentially filled with air, of titanium or alloy titanium molybdenum, of rough outer surface, constituted by thousands of multiple flaps (25), two simultaneous drive generators (15,21) and pendulum (22, 23) therein, wherein only its movable end (23) is in Alnico, two iron elements (8, 11), side and fixed, of dimension calculated according to the size of said movable end (23), covered by plastic, and a support structure (4) equipped with electronic remote control system. Lisbon, August 5, 2013 2/2