RU205664U1 - 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 mechanical wave energy into electrical energy transmitted to the power supply systems of meteorological buoys, communication buoys, lighthouses, etc. and used as a part of a group of power plants combined into one network to power the lighting systems of piers, embankments and other consumers. The technical result is to increase the efficiency of the float wave power plant by ensuring the continuity of the process of converting the energy of sea waves into electrical energy. a float, an electric generator, two blocks, two drums fixed on a common shaft with two free ends, a cable is wound on each drum, and the direction of winding the cables on the first and second drums is opposite, as well as a multiplier installed between the first free end of the common shaft of the drums and an electric generator rotor, additionally equipped with a second float, a stand with a bearing, two blocks, two rod guide bushings, vertical posts, a horizontal support, two beams, and two rod guide bushings are fixed on the first beam, and four blocks are fixed on the second beam, each float is fixed on a rod located in the rod guide sleeve, and the rod guide bushings are fixed on the first beam in such a way that the linear distance between them is equal to half the wavelength, the free end of the cable is fixed to the end of each rod, which passes through two blocks, both beams are fixed on vertical posts.

Description

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

Known "Wave power plant" (RF Patent 2440510, IPC F03B 13/18, publ. 20.01.2012, BI No. 2), containing a linear electric current generator, consisting of a stator and a generating core, capable of vertical reciprocating movement inside stator, hollow float, 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 post 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 rod through a hinge device, which 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 an aggressive sea water environment.

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 unit. The generator stator is fixed to the casing. 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 mechanical 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 level of rotation speed of the generator rotor ... In addition, when the float begins to swing, the tension of the cable 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 and the transmission of rotation to the generator rotor will stop.

Closest to the claimed utility model is "Float wave power plant (options)" (Patent No. RU 2567916, IPC F03B 13/18, publ. 10.11.2015). The float wave power plant, taken as a prototype, contains a streamlined sealed float, as well as a block attached to the float, through which a cable is thrown. A vertical pendulum is attached to the end of this cable. The device also contains an electric generator and an anchor mounted on the bottom. An additional block is fixed on the float, and between the first and additional blocks on the float there are two drums on one shaft. A cable is wound on the first drum, to the end of which a pendulum is attached, and a cable is wound on the second drum, thrown through an additional block and attached to the anchor. In this case, the direction of winding the cables on the first and second drums is opposite. A multiplier is installed between the common shaft of the drums and the rotor of the electric generator. The multiplier will allow increasing the rotor speed of the electric generator at the same wave height and angle of rotation of the drums. When the wave approaches, the float under the action of the buoyancy force floats to the wave crest and the distance of the bow of the float, on which the additional block is located, increases from the bottom. The tension of the cable attached to the anchor increases, the cable unwinds from the second drum and rotates it along with the first drum. When the first drum rotates, the cable attached to the pendulum is wound around the first drum and lifts the pendulum. When both drums rotate, the rotor of the electric generator will also rotate. An electric generator converts the mechanical energy of the rotor rotation into electrical energy. When the float descends from the wave crest, the distance of the bow of the float to the bottom decreases and the tension of the cable attached to the anchor decreases. The pendulum suspended in the water creates a constant tension on the cable attached to the pendulum, and as the bow of the float descends, the pendulum will descend and wind the cable from the first drum, rotating both drums. When the second drum rotates, the cable attached to the anchor will be wound around the second drum. Together with both drums, the rotor of the electric generator will rotate. The presence of a pendulum in a float wave power plant, taken as a prototype, is a disadvantage, the presence of which leads to a decrease in the efficiency of conversion of mechanical wave energy into electrical energy, to an increase in the mass and dimensions of the power plant and to a decrease in its reliability. In the interval of the first half-period of the wave, determined by the time of movement of the float from the trough of the wave to the crest of the wave, the buoyant force of the float is spent to overcome the moment of resistance of the generator, which is proportional to the value of the generated electrical energy in this interval of the period of the wave, to the reserve of potential energy of the pendulum and to overcome the resistance of the water medium to movement pendulum up. In the interval of the second half-period of the wave, determined by the time of movement of the float from the crest of the wave to the trough of the wave, the potential energy stored by the pendulum is spent to overcome the moment of resistance of the generator, which is proportional to the value of the generated electrical energy in this interval of the period of the wave, to overcome the resistance of the water medium to the movement of the pendulum downward and to overcome the lifting force of the float, which essentially limits the downward movement of the pendulum. Taking this into account, the amount of electrical energy generated by the power plant in the interval of the second half-period of the wave is less than in the interval of the first half-period of the wave. In addition, during fluctuations in the marine environment, the pendulum performs uncontrolled vibrations in the marine environment, which lead to the appearance of both pitching and rolling of the float, which complicates the operation of the power plant and lowers its reliability.

The task is to create a float wave power plant with improved technical and economic, energy and weight and size indicators.

The technical result is to increase the efficiency of the float wave power plant by ensuring the continuity of the process of converting the energy of sea waves into electrical energy.

The technical result is achieved by the fact that a float wave power plant containing a float, an electric generator, two blocks, two drums fixed on a common shaft with two free ends, a cable is wound on each drum, and the direction of winding the cables on the first and second drums is opposite, as well as the multiplier installed between the first free end of the common shaft of the drums and the rotor of the electric generator is additionally equipped with a second float, a stand with a bearing, two blocks, two rod guide bushings, vertical posts, a horizontal support, two beams, and two rod guide bushings are fixed on the first beam , and on the second beam four blocks are fixed, each float is fixed on a rod placed in the rod guide sleeve, and the rod guide bushings are fixed on the first beam, so that the linear distance between them is equal to half the wavelength, a free end is fixed to the end of each rod cable a, which passes through two blocks, both beams are fixed on vertical posts, one end of which is fixed in the foundation of the power plant, and the other end is fixed on a horizontal support on which an electric generator, drums, a multiplier and a stand with a bearing is installed, in which the second free the end of the common shaft of the drums.

Significant differences allowing to implement the technical result:

instead of a massive and voluminous pendulum, a second float is installed;

each float, as it rises from the trough of the wave to the crest of the wave, transfers to the common shaft of the drums the maximum amount of mechanical energy determined by the buoyancy force of the float;

since the floats are located in space with a spatial shift equal to half the wavelength, then at the time when the first float reaches the crest of the first wave, the second float will take a position in the trough of the second wave and, under the action of the buoyant force, will begin to move upward towards the crest of the second wave, transmitting to the total shaft of the drums is the maximum amount of mechanical energy determined by this buoyancy force.

Thus, the maximum amount of mechanical energy will be transmitted to the drum shaft without interruptions in time. This improves the efficiency of converting the mechanical energy of sea waves into electrical energy while reducing the weight and size of the power plant.

The essence of the utility model is illustrated by a drawing, where in FIG. 1 shows a functional diagram of a float wave power plant and introduced the following designations:

1 - the first float;

2 - the second float;

3 - rod of the first float;

4 - rod of the second float;

5 - rope of the first drum;

6 - the first drum;

7 - rope of the second drum;

8 - the second drum;

9, 10 - cable blocks of the first drum;

11, 12 - cable blocks of the second drum;

13 - shaft;

14 - multiplier;

15 - stand with bearing;

16 - synchronous generator;

17 - guide sleeve of the rod of the first float;

18 - guide rod of the second float;

19 - beam for fastening the guide bushings;

20 - beam for fastening the guide blocks;

21, 22 - vertical posts;

23 - horizontal support.

The device contains the first float 1 and the second float 2, each of which is rigidly connected to the rods 3 and 4, respectively. The rod 3 of the float 1 is connected to the cable 5 of the first drum 6, and the rod 4 of the float 2 is connected to the cable 7 of the second drum 8. The cable 5 is connected to the first drum 6 through blocks 9 and 10, and the cable 7 is connected to the second drum 8 through blocks 11 and 12. Drums 6 and 8 are fixed on a common shaft 13, one end of which is connected to the input shaft of the multiplier 14, and the second end of the common shaft 13 is mounted in a rack with a bearing 15. The output shaft of the multiplier 14 is connected to the rotor of the synchronous generator 16. The rod 3 of the first float 1 is located in the guide bushing of the first rod 17, and the rod 4 of the second float 2 is located in the guide bushing of the second rod 18. Guide bushings 17 and 18 are fixed on the beam 19 with a spatial shift equal to half the wavelength. Blocks 9, 10, 11 and 12 are fixed on the beam 20. Beams 19 and 20 are fixed on vertical posts 21 and 22, the upper ends of which are fixed on the horizontal support 23, and the lower ends are fixed in the foundation of the power plant.

The device works as follows. Placing the floats with a spatial shift equal to half the wavelength provides a time shift in the movement of floats 1 and 2 equal to half the wave period. Taking this into account, when one float moves from the wave trough to the wave crest under the action of the buoyancy force, the second float moves from the wave crest to the next wave trough, etc.

When the first float 1 moves upward, from the wave trough to the wave crest, the rod 3 moves upward, dragging the cable 5 of the first drum 6 along with it. The cable 5 of the first drum 6 unwinds and drives the drums 6 and 8, which are fixed on the common shaft 13. The drums when one float moves up, N turns will be made, with N = 2A / L, where A is the wave amplitude, and L is the circumference of the drum surface on which the cable is wound. The rotation of the drums rotates the input and output shafts of the multiplier 14, as well as the rotor of the synchronous generator 16. In this case, the speed of rotation of the output shaft of the multiplier 14 and the rotor of the synchronous generator 16 is greater than the speed of rotation of the drums by the i- _th time, where i _m is the reduction factor of the multiplier. Thus, when the rise of the float 1 from the trough to the wave crest of the wave of the synchronous generator rotor make N · i _th turns. When the float 1 rises, the float 2, together with the rod 4, goes down from the crest of the wave to the trough of the wave, the cable 7 is wound on the drum 8, because the direction of winding cables 5 and 7 on drums 6 and 8 is opposite.

The movement of the cable 5 is guided by the cable blocks of the first drum 9 and 10, and the movement of the rod 3 is guided by the guide sleeve 17. The movement of the cable 7 is guided by the cable blocks of the second drum 11 and 12, and the movement of the rod 4 is guided by the guide sleeve 18. After the end of the movement of the float 1 from the wave trough to its crest, the buoyant force of the float 1 will disappear and the process of converting the mechanical energy of the wave into electrical energy with the help of the float 1 will stop at this time interval, at the same time, the float 2 will reach the trough of the next wave and, under the action of the buoyant force acting on the float 2, begins to move upward from the trough of the second wave to its crest, unwinding the cable 7 and thereby rotating the drums 6 and 8. The process of converting the mechanical energy of the wave into electrical energy will continue, but with the help of the float 2. On the time interval of the rise of the float 2, the float 1 together with rod 3 moves downward from the crest of wave 1 to the trough of wave 2, rope 5 is wound is applied to the drum 6, consumes only a small part of the energy of the float 2 and practically does not significantly affect the efficiency of converting the energy of the sea wave into electrical energy. The power generated by the float 2 when rising from the trough of the second wave to its crest and transmitted to the shaft of the synchronous generator is equal to the power generated by the float 1 when rising from the trough of the first wave to its crest and transmitted to the shaft of the synchronous generator.

The power created by the buoyancy force of the float 1 in the interval of the first half-period of the wave, W:

R _popl. = F _popl ʋ _in = mg4A / T _in ,

where F _float = mg - buoyancy force of the float 1, N;

m is the mass of water, the volume of which is equal to the volume of the float, kg;

g - acceleration of gravity, m / s ² ;

ʋ _в - speed of movement of the wave, m / s;

ʋ _in = 2A / (0.5T _in ) = 4A / T _in .

T _in - the period of the wave, s.

A - wave amplitude, m.

The mass m, expressed in kg, is numerically equal to the volume of the float V _p , expressed in dm ³ .

Electric power generated by a synchronous generator in the interval of the first half-period of the wave, P _g , W.

P _g = P _popl η _a.e.

where η _a.e. is the efficiency of the float wave power plant as a whole.

η _a.e. = η _g η _m η _b ,

where η _g is the efficiency of a synchronous generator, η _g ≈ 0.8 ÷ 0.9;

η _m - multiplier efficiency, η _m ≈ 0.9 ÷ 0.95;

η _b - drum efficiency, η _b ≈ 0.9 ÷ 0.95.

It is easy to establish that η _a.e. ≈ 0.65 ÷ 0.81.

Using the above calculated ratios, it is possible to determine the volume of the float V _p required to generate the required value of electric power P _{g by the} synchronous generator:

V _p = P _g T _in / (4Agη _p.v.e. ).

Example: it is necessary to determine the volume of the float with the following initial data: P _g = 10000 W; T _in = 5s; A = 2.5 m; η _a.c.e. = 0.75.

V _p = P _g T _in / (4Agη p.h. _e ) = 10000 5 / (4 2.5 9.8 0.75) = 680 dm ³ .

A volume of 680 dm ³ has, for example, a float with a diameter of 12 dm and a height of 6 dm. Recall that the claimed utility model has two floats with the same dimensions.

From the above, it follows that the claimed float wave power plant converts the energy of sea waves into electrical energy with a constant level of efficiency, without interruptions in time and has better mass-dimensional characteristics in comparison with the float wave power plant, taken as a prototype, due to the absence of a pendulum.

Claims (1)

A float wave power plant containing a float, an electric generator, two blocks, two drums fixed on a common shaft with two free ends, a cable is wound on each drum, and the direction of winding the cables on the first and second drums is opposite, as well as a multiplier installed between the first free the end of the common shaft of the drums and the rotor of the electric generator, characterized in that a second float, a stand with a bearing, two blocks, two guide bushings of the rods, vertical posts, a horizontal support, two beams are additionally introduced into the device, and two guide bushings of the rods are fixed on the first beam , and four blocks are fixed on the second beam, each float is fixed on a rod placed in the rod guide sleeve, and the rod guide bushings are fixed on the first beam in such a way that the linear distance between them is equal to half the wavelength, the free end of the cable is fixed to the end of each rod that goes through two block, both beams are fixed on vertical racks, one end of which is fixed in the foundation of the power plant, and the other end is fixed on a horizontal support, on which are fixed an electric generator, drums, a multiplier and a rack with a bearing, in which the second free end of the common shaft of the drums is installed.

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