MD1007Z - Tidal plant (embodiments) - Google Patents

Abstract

The invention relates to systems for the conversion of energy from renewable sources, namely to tides energy conversion plants.The tidal plant, according to a first embodiment, comprises a rotor with blades (4) with hydrodynamic profile, which shaft is rigidly connected to the rotor of an electric generator with permanent magnets. The blades (4) are installed on the hub (5) of the rotor by means of axes (6) and rods (7), installed in grooves (8), made on the hub (5) in the form of an arc of a circle.According to a second embodiment, the tidal plant comprises two rotors with blades with hydrodynamic profile, installed on the opposite sides of the electric generator. The shaft of one rotor with blades is rigidly connected to the rotor of the electric generator and the shaft of the second is connected through an overrunning clutch to the stator of the electric generator. The blades of the rotors are installed on the hubs directed relative to each other at an angle of 180°.

Description

The invention relates to energy conversion systems from renewable sources, namely to installations for converting energy flows and refluxes.

A tidal installation is known, which is used in tidal dams and consists of an upstream rotor and a downstream rotor, which rotate in opposite directions. The rotor blades have the same hydrodynamic profile. The angle of attack of the blades can be variable and can be controlled in order to reduce turbulence or to adjust the speed of rotation of the rotor. The rotor hubs can be fixed to a cylindrical housing using special supports [1].

The disadvantage of the installation is that it has a complicated construction.

Also known is a tidal installation, which contains two rotors, mounted coaxially, which rotate in opposite directions. One rotor can be coupled to the rotor of an electric generator, and the other rotor can be coupled to its stator. The number of blades on a rotor and the hydrodynamic profile of the blades can be different, so that the rotors do not eclipse each other [2].

The disadvantages of the solution are that it has relatively low conversion efficiency and complicated construction.

The problem that the invention solves is increasing conversion efficiency and simplifying construction.

The tidal installation, according to the first variant of the invention, eliminates the above-mentioned disadvantages by including a rotor with hydrodynamic profile blades, the shaft of which is rigidly connected to the rotor of an electric generator with permanent magnets. The hydrodynamic profile blades are installed on the rotor hub by means of axles, fixed in the convex part of the hydrodynamic profile of the blades with the possibility of rotation around the axle axes at an angle, limited by rods, fixed in the trailing sector of the hydrodynamic profile of the blades and installed in grooves, made on the rotor hub, in the form of a circular arc, the center of curvature of which coincides with the axis of the said axles.

The tidal installation, according to the second variant of the invention, eliminates the disadvantages mentioned above by including two rotors with blades with a hydrodynamic profile, the shaft of one being rigidly connected to the rotor of an electric generator with permanent magnets, the shaft of the second being connected through a one-way coupling to the stator of the said generator, with the possibility of rotating the rotors with blades in opposite directions. The rotors with blades are rigidly connected to the rotor and stator of the said generator from opposite sides thereof, at the same time the blades of both rotors are installed on their hubs oriented to each other at an angle of 180º and fixed by means of axles in the convex part of the hydrodynamic profile of the blades with the possibility of rotation around the axle axes at an angle, limited by rods, fixed in the trailing sector of the hydrodynamic profile of the blades and installed in grooves, made on the rotor hubs, in the shape of a circular arc, the center of curvature of which coincides with the axis of the said axles.

The result of the invention consists in increasing the efficiency of tidal energy conversion by converting the energy of the ebb and flow through the same hydrodynamic blades, made self-adjusting, also by using two rotors with blades, installed on both sides of the electric generator.

The invention is explained by the drawings in Fig. 1-7, which represent:

- Fig. 1, general view of the tidal installation with a rotor (according to the first variant);

- Fig. 2, view I of Fig. 1;

- Fig. 3, diagram of the blade positions in the case of flow and reflux (according to the first variant);

- Fig. 4, general view of the tidal installation with two rotors (according to the second variant);

- Fig. 5, view II of Fig. 4;

- Fig. 6, diagram of the positions of the blades of two rotors in the case of flow and reflux (according to the second variant);

- Fig. 7, diagram of connecting the shafts of two rotors with the rotor and stator of the permanent magnet electric generator (according to the second variant).

The tidal installation (Fig. 1) includes a tower 1, on which a nacelle 2 with a rotor 3 with blades 4 with a hydrodynamic profile is mounted. The blades 4 are installed in the hub 5 (Fig. 2) by means of axles 6, installed close to the leading edge of the hydrodynamic profile of the blades 4 with the possibility of their rotation around the axes of the axles 6. In the trailing edge of the blades 4, rods 7 are fixed, which are installed in grooves 8, made on the hub 5 in the form of a circular arc, the center of curvature of which coincides with the axis of the axles 6.

The tidal installation (Fig. 4) additionally includes the rotor 9 with blades 10 with a hydrodynamic profile. The blades 10 are oriented at an angle of 180º to the blades 4 and installed in the hub 11 (Fig. 5 and 7) by means of axles 12, fixed close to the leading edge of the blades 10 with the possibility of rotation around the axes of the axles 12. Close to the trailing edge of the blade profile 10 are fixed rods 13, which are installed in the grooves 14, made on the hub 11, in the form of an arc of a circle, the center of curvature of which coincides with the axis of the axles 12.

The rotor shaft 3 is rigidly connected to the rotor 15 of the electric generator 16 with permanent magnets, and the rotor shaft 9 is connected by means of the one-way coupling 17 to the stator 18 of the generator 16 (fig. 7).

The tidal installation (fig. 1) operates in the following way.

During the flow, the water currents act on the hydrodynamic blade 4, which will rotate around the axis of the axle 6 to the limit position A, optimal in terms of conversion efficiency, provided by the rod 7, supported with its cylindrical part in the end wall of the groove 8. The rotational movement, obtained from the rotation of the blades 4 under the action of the hydrodynamic effect, is transmitted to the rotor 15 of the generator 16. During the reflux, the water currents act on the blade 4, which will rotate around the axis of the axle 6 in the opposite direction to the limit position B, optimal in terms of conversion efficiency, provided by the rod 7, supported with its cylindrical part in the wall of the other end of the groove 8.

The tidal installation (fig. 4) operates in the following way.

The operation of the rotor 3 of the installation in Fig. 4 during flow and reflux is similar to the operation of the rotor of the installation in Fig. 1. The obtained rotational movement is transmitted to the rotor shaft 15 of the generator 16. The blades 10 of the rotor 9 during the flow will rotate around the axis 12 to the optimal limit position D in terms of conversion efficiency, provided by the rod 13, supported with the cylindrical part in the end wall of the groove 14. The rotational movement of the rotor 9, obtained from the rotation of the blades 10 under the action of the hydrodynamic effect, which has a reverse direction compared to the rotor 3, will be transmitted through the one-way coupling 17 of the stator 18 of the generator 16. During the reflux, the water currents act on the blade 10, which will rotate around the axis of the shaft 12 in the reverse direction to the limit position C, optimal in terms of conversion efficiency, provided by the rod 13, supported with the cylindrical part in the wall of the other end of the groove 14. Thus, in the case of flow and reflux, the rotation in opposite directions of rotors 2 and 9, and therefore of rotor 15 and stator 18, will be ensured, which will allow increasing the efficiency of generator 16.

Thus, as a result of the implementation of the invention, the conversion efficiency will be increased and the construction simplified.

1. GB 2477532 A 2011.08.10

2. WO 2007017629 A1 2007.02.15

Claims (2)

1. Tidal installation, which includes a rotor with blades with a hydrodynamic profile, the shaft of which is rigidly connected to the rotor of an electric generator with permanent magnets, characterized in that the blades with a hydrodynamic profile are installed on the rotor hub by means of axles, fixed in the convex part of the hydrodynamic profile of the blades with the possibility of rotation around the axes of the axles at an angle, limited by rods, fixed in the trailing sector of the hydrodynamic profile of the blades and installed in grooves, made on the rotor hub, in the shape of a circular arc, the center of curvature of which coincides with the axis of the said axles. 2. Tidal installation, which includes two rotors with blades with hydrodynamic profile, the shaft of one being rigidly connected to the rotor of an electric generator with permanent magnets, the shaft of the second being connected by a one-way coupling to the stator of said generator, with the possibility of rotating the rotors with blades in opposite directions, characterized in that the rotors with blades are rigidly connected to the rotor and stator of said generator from opposite sides thereof, at the same time the blades of both rotors are installed on their hubs oriented to each other at an angle of 180º and fixed by means of axles in the convex part of the hydrodynamic profile of the blades with the possibility of rotating around the axes of the axles at an angle, limited by rods, fixed in the trailing sector of the hydrodynamic profile of the blades and installed in grooves, made on the rotor hubs, in the shape of a circular arc, the center of curvature of which coincides with the axis of the said axles.