RU199555U1 - Float wave power plant - Google Patents

Abstract

The utility model relates to the field of electrical engineering and can be used in the production of electrical energy by converting wave energy into electrical energy transmitted to power supply systems, for example, meteorological buoys, communication buoys, lighthouses, and can be used as a part of a group of power plants united into one network to power lighting systems piers, embankments and other consumers. A floating wave power plant made of N generators, the bodies of which have a cylindrical shape and are fixed on a support, and each generator has two springs placed at the top and bottom of the inductor, and a rod on which the float and the inductor are fixed with the ability to reciprocate with a period equal to the period of oscillation of the T wave, the electric windings of the generators are in the form of coils and are placed between the annular cores of the stator magnetic circuit of each generator, the inductors of the generators are made in the form of a set of annular magnets with annular ferromagnetic inserts between them, additionally equipped with n floats fixed on the rod of each generator, and the cases of N generators are fixed along the longitudinal axis of the support, oriented in the direction of movement of the sea wave, and are displaced relative to each other by a distance equal to 1 / (2N) the length of the sea wave λ.

Description

The utility model relates to the field of electrical engineering and can be used in the production of electrical energy by converting wave energy into electrical energy transmitted to the power supply systems of meteorological buoys, communication buoys, lighthouses, and can be used as a component of a group of power plants united in one network to power the pier lighting systems. embankments and other consumers.

Known "Wave power plant" (RF Patent 2440510, IPC: F03B 13/18, publ. 01/20/2012, BI No. 2), containing a linear electric current generator, consisting of a stator and a generating core, capable of vertical reciprocating motion inside the stator, a hollow float, a rod kinematically connecting the core with the float, vertical guide beams with supporting rollers moving along them, dampers. The installation is equipped with a vertical rack and a body fixed on it, made in the form of a hollow body made of non-metallic material with central holes on the roof and on the bottom, inside which the stator and the generating core are located, while the vertical guide beams are rigidly fixed on the roof and on the bottom of the body, supporting the rollers are attached to the lateral surface of the generating core, and the float, which has a bottom, a nose, a roof and a valve, is connected to the stem through a hinge device that is rigidly attached to the float roof.

The disadvantages of the device are low efficiency and unevenness of the process of converting mechanical energy of waves into electrical energy, low reliability and insufficient durability of the structure. The operation of a complex multicomponent system is ensured by guide rollers, bearings, oil seals, hinges, which complicates the product and affects reliability, especially in the aggressive environment of sea water.

Known "Float wave power plant" (RF Patent No. 2513070, IPC: F03B 13/18, publ. 20.04.2014, BI No. 11), which contains a streamlined sealed float and a cylindrical body vertically located inside the float with a pendulum placed in it. The pendulum is suspended from the end of a cable that is thrown over a block mounted on a rotating axle. The other end of the cable is attached to an anchor mounted on the bottom. The rotor of an electric generator with permanent magnets is connected to the rotating axis of the block. The generator stator is fixed to the housing. The stator winding of the generator is connected to the input of the charger, and the output of the device is connected to the battery, which, together with the device, is located in the instrument compartment in the upper part of the float.

The disadvantages of the device are the low efficiency of converting wave energy into electrical energy, caused by the small amplitude and frequency of the EMF induced in the generator winding, since the transformation of the linear displacement of the float into the rotational movement of the rotor of the electric generator is carried out without the reduction necessary to achieve the required value of the rotational speed of the generator rotor. When the direction of rotation changes, the generator stops generating electrical energy and transferring it to the load. In addition, when the float starts rolling, the cable tension will weaken and, as a result, the coefficient of adhesion of the cable to the block will decrease down to zero, as a result, the cable will slip, the rotation of the generator rotor and the transfer of energy to the load stops.

The closest to the claimed utility model is the "Float wave power plant" (RF Patent No. 194378, IPC: F03B 13/16, publ. 09.12. 2019, BI No. 34). The float wave power plant, taken as a prototype, contains three single-phase generators, the bodies of which are made of ferromagnetic material, rigidly connected to each other, fixed on a support, have a cylindrical shape, a stator with an electric winding and an inductor with a multi-pole magnetic system are placed inside the body of each generator. the pole division of which is equal to τ, two springs located above and below the inductor, a float and a rod connected to an inductor and a float common to three generators, with the ability to reciprocate with a period equal to the period of oscillation of the wave T _in , electric windings having the shape of the coils and placed between the ring cores of the stator magnetic circuit of each generator, are located in space strictly parallel to each other, the total height of each coil and the ring core is equal to the pole division τ, the inductors of three single-phase generators are made in the form of a set of ring magnets with ring ferrous magnetic inserts between them, forming three multi-pole magnetic systems with a spatial shift between them equal to 2τ / 3, and the linear dimensions of all three generators are chosen in such a way that the generation of electrical energy is possible only in the wave sections with the highest travel speed.

The disadvantages of a utility model taken as a prototype are:

- the amplitude of the voltage generated by the float wave power plant is not constant, but modulated with a frequency of two times the frequency of the sea wave, the modulation depth is equal to the amplitude of the sea wave;

- effective conversion of sea wave energy into electrical energy is possible only in two sections of the sea wave period, where the sea wave travel speed is greatest:

- on the falling part of the wave period from 3T _in / 8 to 5T _in / 8;

- on the ascending part of the wave period from 7T _in / 8 to 9T _in / 8.

The total duration of these sections is (1/2) T _in . In the remaining two sections of the wave period, the total duration of which is also equal to (1/2) T _in , the amplitude of the generated voltage decreases down to zero, and a pause appears in the process of generating electrical energy. The presence of this pause leads to a decrease in the efficiency of converting sea wave energy into electrical energy.

The task is to create a float wave power plant with continuous generation of electrical energy during the entire period of the sea wave, without pauses.

The technical result is to increase the efficiency of converting sea wave energy into electrical energy.

The technical result is achieved by the fact that a float wave power plant containing N generators, whose bodies are made of ferromagnetic material, have a cylindrical shape and are fixed on a support, a stator with an electric winding is located inside the body of each generator, an inductor with a multi-pole magnetic system, the pole division of which is equal to τ , two springs, a float and a rod, on which the float and the inductor are fixed, with the ability to reciprocate with a period equal to the oscillation period of the wave T _in , the electric windings of the generators have the shape of coils and are placed between the ring cores of the stator magnetic circuit of each generator, the total height of each coil and ring core is equal to the pole division τ, the inductors of the generators are made in the form of a set of ring magnets with ring ferromagnetic inserts between them, springs are placed above and below the inductors, while the linear dimensions of the generators are selected in such a way that the gene electric energy can be controlled only in the sections of the wave with the highest speed of movement, it is additionally equipped with n floats fixed on the rod of each generator, and the cases of N generators are fixed along the longitudinal axis of the support, oriented in the direction of movement of the sea wave, and are displaced relative to each other by a distance 1 / (2N) sea wavelength λ.

Significant differences allowing to implement the technical result:

- N generators with floats are placed along the longitudinal axis of the support, oriented in the direction of movement of the sea wave, with a spatial shift relative to each other Δ equal to 1 / (2N) sea wavelength λ, i.e. Δ = [1 / (2N)] λ. Due to this, the modulation frequency of the voltage of the float wave power plant increases by a factor of N compared to a single-phase generator, and the modulation amplitude decreases by [(2N) ² -1] / 3 times. For example, at N = 2, the modulation amplitude will decrease by [16-1] / 3 = 5 times;

- the float wave power plant generates electrical energy during the entire period of the sea wave continuously, without pauses, while each generator generates electrical energy only in the sections of the wave with the highest speed of movement at the point in space where the generator is installed, which ensures high efficiency of sea wave energy conversion into electrical energy.

The essence of the utility model is illustrated by drawings, where:

- in Fig. 1 shows a structural diagram of a float wave power plant with N generators (for example, N is taken equal to 2) and a spatial shift of the installation of generators equal to Δ = 1 / 2N) λ (for example, N = 2 Δ = (1/4) λ), and introduced the following designations:

1 - the first float generator;

2 - the second float generator;

3 - generator case;

4 -spring;

5 - float;

6 - stock;

7 - inductor;

8 - stator magnetic core with winding,

- in Fig. 2 shows time diagrams explaining the principle of operation of a float wave power plant, and the following designations are introduced:

9 is a graph of the change in the wave amplitude at the point of the generator installation;

10 is a graph of the change in the wave speed at the point of the generator installation;

- in Fig. 3 shows the timing diagram of the voltage waveform of one generator over the interval of one sea wave period:

11 - generator voltage 1;

12 - modulating voltage curve of generator 1;

- in Fig. 4 shows a timing diagram of the voltage waveform of two generators placed on a support with a spatial shift equal to Δ = [1 / (2N)] λ = [1/4] λ:

13 - modulating voltage curve of generator 1;

14 - modulating voltage curve of generator 2.

The device contains N generators (for example, two generators, 1 and 2), the bodies 3 of which, made of a ferromagnetic material, have a cylindrical shape and are fixed on a support, two springs 4, a float 5 and a rod 6 are introduced into each generator the float 5 and the inductor 7, with the possibility of reciprocating motion with a period equal to the oscillation period of the wave T _in , the electric windings of the generators are in the form of coils and are placed between the ring cores of the stator 8 of each generator, the inductors 7 of the generators are made in the form of a set of ring magnets with springs 4 are placed between the annular ferromagnetic inserts, springs 4 are placed above and below the inductors 7, the device is additionally equipped with n floats 5 fixed on the rod 6 of each generator, and the N generator cases are placed along the longitudinal axis of the support, oriented in the direction of movement of the sea wave, and are displaced relative to each other each other at a distance equal to 1 / (2N) sea wavelength nine.

The device works as follows.

When the sea wave 9 moves, the float 5, the rod 6 and the inductor 7 of each generator (for example, 1 or 2) reciprocate. In this case, the magnetic lines of force of the inductor 7 intersect the conductors of the stator winding 8 and induce a voltage 11 in them. The speed of movement of the inductor 7 is equal to the speed of movement of the float 5, therefore, the voltage amplitude of the generator 11 in the interval of one period of the sea wave is modulated by the envelope curve 12, the shape of which repeats the shape of the curve the speed of the sea wave 10. Springs 4 absorb the force of impact when the inductor moves inside the housing 3.

When placing N (for example, two) generators along the longitudinal axis of the support, oriented in the direction of movement of the sea wave, and displacing them relative to each other at a distance equal to 1 / (2N) the length of the sea wave 9, the modulating voltage curves of these generators 13 and 14 are shifted in phase for an interval equal to [1 / (2N) T _in . With N = 2, the displacement of the modulating curves 13 and 14 will be (1/4) T _in , the modulation frequency increases by 2 times, and the modulation amplitude decreases by [(2 * 2) ² -1] / 3 = 5 times in comparison with the same parameters of one generator.

When placing three generators along the longitudinal axis of the support, oriented in the direction of movement of the sea wave, and their displacement relative to each other at a distance equal to 1 / (6) the length of the sea wave 9, the modulating voltage curves of these generators are shifted in phase by an interval equal to [1 / (6)] T _in , the modulation frequency increases by 3 times, and the modulation amplitude decreases by [(2 * 3) ² -1] / 3 = 11.66 times compared to the same parameters of one generator.

Due to this, the generation of electrical energy in the claimed device is realized throughout the entire period of the sea wave continuously, without pauses.

The given calculation results show that the declared float wave power plant converts the energy of the sea wave into electrical energy without interruptions, pauses in the interval of the sea wave period, which significantly increases the efficiency of converting sea wave energy into electrical energy.

Claims (1)

A float wave power plant containing N generators, the bodies of which are made of ferromagnetic material, have a cylindrical shape and are fixed on a support, inside the body of each generator there is a stator with an electric winding and an inductor with a multi-pole magnetic system, the pole division of which is τ, two springs and a rod, on which a float and an inductor are fixed with the ability to reciprocate with a period equal to the oscillation period of the wave T _in , the electric windings of the generators are in the form of coils and are placed between the ring cores of the stator magnetic circuit of each generator, the total height of each coil and the ring core is equal to the pole division τ , the inductors of the generators are made in the form of a set of ring magnets with ring ferromagnetic inserts between them, and springs are placed above and below the inductors, while the linear dimensions of the generators are selected in such a way that the generation of electrical energy is possible only on sections of the wave with the highest speed of movement, characterized in that the device is additionally equipped with n floats fixed on the rod of each generator, and the cases of N generators are fixed along the longitudinal axis of the support, oriented in the direction of movement of the sea wave, and are displaced relative to each other by a distance equal to 1 / (2N) sea wavelength λ.

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