RU69932U1 - FLOATING WAVE GENERATOR - Google Patents

Abstract

The utility model relates to electric energy generators using the energy of open water waves, namely, electric energy generators that use the movement of an element driven by wave energy relative to another element, both elements being movable relative to the bottom of the reservoir. The float wave generator comprises a housing (1) with a rectilinear vertical channel (2), made floating; stator winding (3), made on the inner wall of the vertical channel (2); a core (4) with permanent magnets (5) located inside the vertical channel (2) with the possibility of vertical reciprocating motion relative to the stator winding (3). New is that the upper part of the body (1) protrudes above the surface of the reservoir, the lower end of the vertical channel (2) communicates with the water of the reservoir, the upper end of the vertical channel (2) communicates with the atmosphere, the core (4) is floating, and the inertia of the core ( 4) differs from the inertia of the housing (1) so that in the presence of waves on the surface of the reservoir, the core (4) and the housing (1) acquire different accelerations along the vertical axis. This allows us to simplify the design of the float wave generator and increase the reliability of its operation. 9 C.p.F., 8 ill.

Description

The utility model relates to electric energy generators using the energy of open water waves, namely, electric energy generators that use the movement of an element driven by wave energy relative to another element, both elements being movable relative to the bottom of the reservoir.

Known float wave generator containing a rigid body, inside of which at least two or more winding coils are fixedly mounted, located at an angle of 45 °, in each of which a magnetic bar-core is movably mounted on the float with the possibility of reciprocating movement along the guide under exposure to kinetic wave energy [patent DE 3723002, publ. 01/19/1989].

Also, a buoy wave generator is known that contains a magnetic core attached to the bottom surface of the buoy with the possibility of vertical reciprocating movement on the wave. A winding coil is slidably movably mounted on the magnetic core, the movement of which along the magnetic core is limited, and the coil itself holds a fixed position under water by means of flat horizontal panels mounted around it that increase the resistance of the water during reciprocating movement of the core [US Pat. No. 2004061338, publ. 04/01/2004].

As a prototype adopted float wave power plant containing a vertically located sealed floating cylindrical body, the energy converter located in it, made in the form of a linear electric generator, the windings of which are mounted on the inner wall of the body, and the core is made in the form of an inertial mass with permanent magnets combined into ring sections and installed inside the windings with the possibility of vertical reciprocating movement by means of elastic elements [pa UNT RU 2037642, publ. 06/19/1995].

The main disadvantage of the known power generators is their complexity, which, in turn, also determines their low reliability.

The technical problem to be solved is the simplification of the design and increasing the reliability of the float wave generator.

The specified technical problem is solved by the proposed float wave generator, comprising a housing with a straight vertical channel,

made floating; stator winding made on the inner wall of the vertical channel; a core with a permanent magnet located inside the vertical channel with the possibility of vertical reciprocating motion relative to the stator winding. New is that when the upper part of the body protrudes above the surface of the reservoir, the lower end of the vertical channel communicates with the water of the reservoir, and the upper end of the vertical channel communicates with the atmosphere, while the core is floating, and the inertia of the core differs from the inertia of the body so that the presence of waves on the surface of the reservoir, the core and body acquire various accelerations along the vertical axis. The position of the center of gravity of the body can be chosen so that the vertical channel does not shift from the vertical in the presence of waves on the surface of the reservoir, and the position of the center of gravity of the core can be selected so that the vertical axis of the core does not move in the presence of waves on the surface of the reservoir. In order to avoid distortion and jamming during wave oscillations, it is better if the height of the core is chosen greater than its transverse size. The vertical channel and the core may have a circular cross section in the horizontal plane. To create elastic oscillatory movements, it is better if the core is spring-loaded in the vertical direction. The core can be placed inside the vertical channel using vertical guides, excluding the rotation of the core around the vertical axis, and it is better if the core is placed inside the vertical channel with a gap. A limiter may be installed at the upper end and / or lower end of the vertical channel, configured to prevent the core from exiting the vertical channel from the end at which the limiter is installed. It is better if the limiter is made in the form of a lattice that covers the end of the vertical channel, but transmits the water pressure of the wave. Two or more vertical channels can be made in the housing, each of which can contain a core placed in it and a stator winding.

The proposed utility model is illustrated by graphic materials.

Figure 1 shows a longitudinal section of a float wave generator with one vertical channel and a core with permanent magnets, figure 2 shows a longitudinal section of a float wave generator with one vertical channel, a core with ballast and a spring suspension, figure 3 shows a top view of the float Fig. 4 shows a top view of a float wave generator with one channel with guides, Fig. 4 shows a longitudinal section of a float wave generator with two channels, Figure 6 shows a top view of the float of the wave generator with two channels, shown in Figure 7

a top view of a float wave generator with four channels, Fig. 8 is a diagram illustrating installation and mounting options of a float wave generator.

The proposed utility model is illustrated by three examples of specific performance of the float wave generator equipped with one, two and four cases of energy converters, respectively.

In the first example, the float wave generator contains a foam float 1, protected by a layer of epoxy resin on a nylon mesh with a cell of 10 × 10 mm In the float 1 is fixed the top of the plastic casing of the cylindrical channel 2, which is in a vertical position. The lower and upper parts of the cylindrical channel 2 are made open, while the lower part of the channel 2 is located under the surface of the water and open to the reservoir, and the upper part is located at the top of the float 1 floating on the water surface and is open to the atmosphere. On the inner side of the channel 2 housing, a winding 3 is fixed, made of ⌀3 mm copper wire and protected by a layer of epoxy resin. Inside the winding 3 is located with the possibility of vertical reciprocating movement of the floating core 4, made of sheet steel δ = 4 mm in the form of a sealed prism with a base in the form of a circle. Permanent magnets 5 are attached to the side surface of the core 4, which are 0.12 m × 0.08 m in size. The magnets 5 are mounted around the perimeter of the core 4 with a step of 0.1 m, and in height with a step of 0.06 m, which allows you to create required total magnetic field. When the height of the casing of the cylindrical channel 2 is 1.3 m, the height of the core 4 is 0.7, while the diameter of the core 4 is 0.6 m, which eliminates its distortion and jamming in the winding 3 during wave vertical translational movement. If there is ballast 6 in the inner lower part of the core 4 and the spring suspension 7 on the outer upper part, the mass of the core 4 will be greater than the mass of the generator, therefore, the oscillator body will oscillate on the wave. In the absence of ballast 6 and spring suspension 7, the mass of the core 4 will be less than the mass of the generator housing, and the core 4 will oscillate under the pressure of the waves. The core 4 is installed in the winding 3 on two brass guides 8 that are attached to the body of the cylindrical channel 2 over the winding 3. The guides 8 make it possible to ensure between the core 4 and the winding 3 the minimum clearance necessary for the sliding vertical-translational movement of the core 4 in the winding 3 under the pressure of the wave. Above and below the core 4, rubber shock absorbers 9 are installed, and above and below the housing of the cylindrical channel 2, limiters 10 for moving the core 4, made in the form of steel gratings, are rigidly installed

attached to the edges of the body of the cylindrical channel 2 and freely passing through the wave stream. The float 1 in the plan is made in the form of a square with rounded corners, which allows you to soften the force of the impact of the wave on the generator body. Its dimensions are 1.4 m × 1.4 m, and the height determined experimentally is 0.3 m, which makes it mobile and at the same time stable on the wave. On the upper and lower restrictive gratings 10, eyelets 11 are made for flexible installation and fastening of the float wave generator using a cable 12 to the bottom or for hinging installation and fastening of the generator using rigid traverses 13 to the side of the vessel or pier. The winding 3 with the core 4 is located symmetrically relative to the axes of the float 1, which allows you to pick up different phases of wave oscillations from all sides. The center of gravity of the generator is located under water, somewhere in the lower part of the cylindrical channel 2, which ensures the stability of the generator on the wave.

In the second case, an example of a specific implementation is similar to the first, except that the wave generator contains a float 1, on which there are two cases of vertical channels with windings 3 and cores 4. The float 1 in the plan is made in the form of a rectangle with rounded corners, which softens the force of impact the waves. The length of the float 1 is 2.8 m and the width is 1.4 m, which makes it both stable and mobile on the wave.

In the third case, an example of a specific implementation is similar to the first and second, except that the wave generator contains a float 1, on which there are four cases of vertical channels with windings 3 and cores 4. The float 1 in plan is made in the form of a square with rounded corners, which softens force of impact of a wave. The dimensions of the float 1 are 2.8 m × 2.8 m, which makes it both stable and mobile on the wave.

The work of the float wave generator is as follows. Under the pressure of the waves, the float 1 begins to perform vertical-translational and lateral vibrations, which in turn leads to oscillatory reciprocating motion of the cores 4 located in the vertical channels with the permanent magnets 5 mounted on them. During oscillatory movements, the cores 4 with the permanent magnets mounted on them magnets 5 induce induction currents in the windings 3, as a result of which there is an electromotive force, which induces an electric voltage in the windings 3.

Claims (11)

1. Float wave generator, comprising a housing with a rectilinear vertical channel, made floating; stator winding made on the inner wall of the vertical channel; a core with a permanent magnet located inside the vertical channel with the possibility of vertical reciprocating motion relative to the stator winding, characterized in that the upper part of the body protrudes above the surface of the reservoir, the lower end of the vertical channel communicates with the water of the reservoir, the upper end of the vertical channel communicates with the atmosphere, core made floating, and the inertia of the core differs from the inertia of the body so that in the presence of waves on the surface of the reservoir, the core and the body acquire p various accelerations along the vertical axis. 2. The generator according to claim 1, characterized in that the position of the center of gravity of the body is selected so that the vertical channel does not move from the vertical in the presence of waves on the surface of the reservoir. 3. The generator according to claim 1, characterized in that the position of the center of gravity of the core is selected so that the vertical axis of the core does not move from the vertical in the presence of waves on the surface of the reservoir. 3. The generator according to claim 1, characterized in that the height of the core is selected greater than its transverse size. 4. The generator according to claim 1, characterized in that the vertical channel and the core have a circular cross section in the horizontal plane. 5. The generator according to claim 1, characterized in that the core is spring-loaded in the vertical direction. 6. The generator according to claim 1, characterized in that the core is placed inside a vertical channel using vertical guides, eliminating the rotation of the core around a vertical axis. 7. The generator according to claim 1, characterized in that the core is placed inside the vertical channel with a gap. 8. The generator according to claim 1, characterized in that a limiter is installed at the upper end and / or lower end of the vertical channel, configured to prevent the core from exiting the vertical channel from the end at which the limiter is installed. 9. The generator of claim 8, wherein the limiter is made in the form of a lattice that covers the end of the vertical channel. 10. A generator according to any one of claims 1 to 9, characterized in that the housing has two or more vertical channels, each of which contains a core placed in it and a stator winding.