UA148627U - WAVE ENERGY INSTALLATION - Google Patents

Abstract

Wave power plant, which contains a float structure located on the surface of the water with the possibility of reciprocating motion on the waves, stationary resistance and a mechanism for converting reciprocating motion into rotational, located on a stationary surface, the lever of reciprocating motion from the float structure to mechanism for converting movement, according to the utility model, the float structure comprises a float element mounted on the consoles, between the consoles is a rigid connecting element, to which the inner ends of the consoles are hinged at both ends, to the Central part of the connecting element rigidly attached orientation ring, the transmission lever is made of two parts, the ends of which are hinged, the other end of one part of the lever is connected to the Central part of the rigid connecting element through a bearing connection, the other end of the second part of the lever is connected to the conversion mechanism movement, and the average tea the wall of the second part of the lever rests on a stationary support, and the float structure is equipped with a pump mechanism for inflating-inflating the float element and a device for folding the float structure.

Description

A useful model belongs to hydropower, in particular to the production of energy by converting the energy of water waves into other forms of energy.

Until now, a large number of technological schemes, methods and devices for converting wave energy into electricity have been developed and practically implemented in the world.

A known device (CC 20100118597 A, 05.11.2010) with floating and stationary floats that move relative to each other and transmit the movement of the element that converts rotational energy into electrical energy.

The known device (KO 2037642 C1, 19.06.1995) for the conversion of wave energy, consisting of a linear generator and a dynamic inertial energy accumulator, which has a load and elastic elements, while it is assumed that the frequency of natural oscillations of the generator rotor is proportional to the characteristic frequency of oscillations of the float in the water.

The known device (052004/251692 A1, 16.12.2004), consisting of a float, a rotor of a linear generator and a stator with turns of an electric winding, attached to the seabed, and two hydraulic cylinders of different diameters are located coaxially between the float and the generator.

The disadvantages of all these installations include a low efficiency due to the impossibility of using large-sized float elements. Also, the complex conversion of wave energy into electricity provided by such structures leads to significant complication and increase in the price of such power plants.

As the closest analogue, a wave energy installation was chosen (per /Lumlu. uoshiBe.sot/maisnp?u-MI1178550505), which contains a floating structure located on the surface of the water with the possibility of reciprocating movement on waves, shore support and a mechanism for converting reciprocating motion in the rotary, which are located on a stationary surface, the lever for transmitting reciprocating motion from the float structure to the motion conversion mechanism. At the same time, the motion conversion mechanism is connected to the electricity generator.

The disadvantages of such an installation include the fact that its construction requires significant capital costs, the direct location of floats near the shore causes ineffective transfer of wave energy, and with coastal water turbulence, the design involves significant costs per 1 linear meter of shoreline, resulting in a limited front

From receiving wave energy. In addition, the structure of the installation is poorly protected from excessive sea waves.

The useful model is based on the task of increasing the efficiency of the wave energy installation by creating an opportunity to change the front of the working surface of the float structure depending on the power of the wave energy.

The problem is solved by the fact that in a wave energy installation, which contains a floating structure located on the water surface with the possibility of reciprocating motion on waves, a stationary support and a mechanism for converting reciprocating motion into rotary motion, which are located on a stationary surface, a reverse transmission lever - translational movement from the float structure to the motion conversion mechanism, according to the proposed solution, the float structure contains a float element fixed on the consoles, a rigid connecting element is placed between the consoles, to which the inner ends of the consoles are hinged from both ends, to the central part of an orienting wheel is rigidly attached to the connecting element, the motion transmission lever is made of two parts, the ends of which are hinged to each other, the other end of one part of the lever is connected to the central part of the rigid connecting element through a bearing connection, the other end of the second part connecting lever one with a movement conversion mechanism, and the middle part of the second part of the lever rests on a stationary support, and the float structure is equipped with a pump mechanism for inflating and deflating the float element and a device for collapsing the float structure.

At the same time, the float element can be made in the form of a pair of floats, each of which is placed on the corresponding console.

The consoles of the float structure can be made in the form of two beams, on which the wings covering the upper part of the float element are fixed.

In addition, the float structure is equipped with water wave measurement sensors connected to the mechanism of automatic control of the device for collapsing the float structure and the pump mechanism.

According to the simplest version, the device for folding the floating structure can be made in the form of a winch located on a stationary surface, connected to the keel of the floating structure.

The mechanism for converting reciprocating motion into rotary motion can be made in the form of a rack-and-pinion transmission.

The proposed design provides for the possibility of folding the floats in cases where strong winds, storms, or other adverse weather conditions pose a threat of damage to the floats. This makes it possible to create structures with a large working surface of floats without the threat of their breakage, and thus increase the efficiency of wave power plants.

The proposed wave energy installation is explained by drawings.

In fig. 1 shows the proposed wave energy installation (top view).

In fig. 2 shows the float structure in working condition (top view).

In fig. C shows the float structure in a collapsed state (top view).

In fig. 4 shows the proposed installation (side view), where two options for the location of the float structure are shown: in working and submerged states.

The proposed wave energy installation includes a floating structure 1, a stationary support 2, a mechanism for converting reciprocating motion into a rotary one 3, a reciprocating motion transfer lever 4. The drawings show an installation where the role of a stationary surface for support 2 is performed by the coast. A barge or other vessel not permanently connected to the shore can also serve as a stationary surface for support 2.

The float structure 1 contains a float element, which can have a different design.

The drawings show a version of the float element in the form of one pair of inflatable floats 5 fixed on the consoles 6. A rigid connecting element 7 is placed between the consoles b, to which the inner ends of the consoles b are connected at both ends with the help of hinge-spring connections 8 To the central part of the connecting element 7 is rigidly attached an orienting wheel 9, the end of which is connected to a device 10 located on a stationary surface for collapsing the float structure (for example, with a winch). It should be noted that other versions of the float element are possible, for example, it can be one long float fixed on two consoles, or several pairs of float elements, and, accordingly, several pairs of consoles are provided.

The motion transfer lever 4 is made of two parts 11, 12, the ends of which are connected to each other

With a hinge-spring connection 13. The other end of the part 11 of the lever 4 is connected to the central part of the rigid connecting element 7 through the bearing connection 14, the other end of the part 12 of the lever 4 is connected to the motion conversion mechanism 3, and the middle part of the part 12 of the lever rests on the stationary support 2. As shown in fig. 1, part 12 of the lever can consist of several elements rigidly fixed to each other, which ensures the placement of parts 11, 12 in the places adjacent to the connection 13, on the same line on the water surface. The float structure 1 is equipped with a pump mechanism 15 for inflating and deflating the floats 5, which is connected to the floats 5 by a system of hoses 16.

The floating structure is equipped with a sensor for measuring water turbulence 17, connected to the mechanism 18 of automatic control of the device 10 and with the pumping mechanism 15, as well as a pressure control sensor 19 located under the lever 4. A support 20 is installed at the bottom for resting on it the floating structure during immersion .

According to one of the specific execution options, the console of the float structure can be made in the form of beams, on which the fenders are fixed, covering the upper part of the inflatable floats.

Floats are made in the form of inflatable balloons, the size and shape of which are optimal for removing energy from a characteristic wave of a particular coast, and the transverse size of the float should provide the maximum range of reciprocating movement for the wave cycle of the given region, and the length of the float is determined depending on the length and shape of the waves of the region To increase the efficiency of work, it may be envisaged to supplement the design with several standard modules with additional pairs of floats.

The device for collapsing the float structure 10 can be made in the form of a winch, and the mechanism for converting the reciprocating motion into a rotary Z can be made in the form of a rack and pinion gear. Other versions of these devices are also possible.

The proposed wave power plant works as follows. In the working state, the inflated floats 5 oscillate on the waves, occupying the optimal position in relation to the direction of the waves due to the turns of the keel 9. At the same time, the reciprocating movement of the floats 5 is transmitted through the lever 4 to the motion conversion mechanism 3, and through the transmission transmits the torque to the generator electricity. When there is an excessive wave of the sea (storm), the lever 4 acquires excessive movement and presses on the sensor 19, which turns on the control mechanism 18. First of all, with the help of the pump mechanism 15, the air is drained from the floats 5 through the hose system 16. The deflated floats 5 are placed in the fenders and do not create resistance to waves. After the main air is forcibly pumped out of the floats 5, the device 10 is turned on, for example, a winch located on the shore. At the same time, the keel 9 sinks into the water, dragging the consoles 6 with floats 5 behind it, and rests on the support 20 located at the bottom, and the part 11 of the lever 4 is turned at an angle to the part 12. The sequence of operations is ensured by the presence of hinge-spring mechanisms 8, 13 When the excessive agitation of the water surface subsides, the sensor 17 sends a signal to the automatic control mechanism 18. At the same time, the operation of the device 10 is turned off and the floats 5 are inflated through the pump mechanism. 15. The floats rise to the surface, and the power plant resumes work.

The presence of a stationary support 2, on which the lever 4 rests, located on the coast or on another stationary surface, ensures minimal loss of oscillating motion.

The distance from the floats 5 to the support 2 and the distance from the support 2 to the motion conversion mechanism Z depends on the relief of the area, the energy power of the waves and the specific conditions of use of the wave energy installation. A modular design of the lever is provided, as a result of which it is possible to manufacture levers of the required length on both sides of the support.

Thus, thanks to the use of the proposed installation, it becomes possible to use floats of sufficiently large sizes, which in turn significantly increases the efficiency of work.

Claims (6)

USEFUL MODEL FORMULA 1. A wave energy installation, which contains a floating structure located on the surface of the water with the possibility of reciprocating motion on waves, a stationary support and a mechanism for converting reciprocating motion into a rotary one, which are located on a stationary surface, a lever for transmitting reciprocating motion from the floating structure to the movement conversion mechanism, which is characterized by the fact that the float structure contains a float element fixed on the consoles, a rigid connecting element is placed between the consoles, to which the inner ends of the consoles are hinged at both ends, to the central part of the connecting element rigidly the guide wheel is attached, the motion transmission lever is made of two parts, the ends of which are hinged to each other, the other end of one part of the lever is connected to the central part of the rigid connecting element through a bearing connection, the other end of the second part of the lever is connected to the motion conversion mechanism, and silver day part of the second part of the lever rests on a stationary support, and the float structure is equipped with a pump mechanism for inflating and deflating the float element and a device for collapsing the float structure. 2. The wave energy installation according to claim 1, which is characterized by the fact that the float element is made in the form of a pair of floats, each of which is placed on a corresponding console. 3. The wave energy installation according to claim 1, which is characterized by the fact that the consoles of the float structure are made in the form of two beams, on which the wings covering the upper part of the float element are fixed. 4. The wave energy installation according to claim 1, which is characterized by the fact that the float structure is equipped with water wave measurement sensors connected to the mechanism of automatic control of the device for collapsing the float structure and the pump mechanism. 5. Wave energy installation according to claim 1, which is characterized by the fact that the device for folding the floating structure is made in the form of a winch located on a stationary surface, connected to the keel of the floating structure. 6. Wave energy installation according to claim 1, which differs in that the mechanism for converting reciprocating motion into rotary motion is made in the form of a rail transmission. : 15 KI : : : Ro: Ve : : : I - dya; : my 3 a. 2 8, p A C, y vi : x : me shchi : i 55 she M : x , x ke : i mV ! not : and V nya nia : baby 8 I : b. : them and : t : : : . ode : dry land E and B : I : : KV: Y : tire Fig. 1 1 days IZ sk I ni KB Kz and I . 11 4 13 12. 1 shi se ne shi o Banya. 8. I and X. to her -shsh-e M x Y SCHE Goyan OK ; x; in U i zh KV I x 3 A o Z i o; in ts u y ! 2 and more: BUT х у х ще Mokh Z. МН 3 ; у щ и ОН НН В ХО З i ой TM и Х гЯ и у, х ще. KAH x x i o. x i : ! o x u 1 B V Ve U i i. Shchi, 7 x " i N. v. BUT r I v se V: N U i p: B I I . and g. water; dry land and 5 pcs. K; Fig. 2 : guilty st zd I . in se V x : 1 : N van N i i I - NN B : y NN B : i NKU : : z, B : NYA : : M) Z i : h- | 2 yati b 15 413.12. / : 7 My pnnny nene vnymi dikh zma t-- is I NO U х х х м yet Where I pln NK В х х х U iz ШЭ Be : НЯ х х ; i hi i : in What N g in N still sh kh 5, sha ! is: their NNI NI x i: x x U M: y : pt PE OZ x x x 3 their th Ko I I y Be IKONA U x. H ve! еще и я и х : is not from the CENTURY; х KO N u sh ha - : no OO Ho OKKO VO HIGH po z v on ХУККУХ run kuyuyuya , she i, I NOT хх и 2 NO E Y I NK Ka: i і ; : i 1 xx V i SHO V 957 v/ 5/4) I Sh : yah i ee Shan se V : b PE V I I IK V N vana N i V : eh : Z i : I NU r i I Not V : en NN I : y and o water o land : sh- : Her SI : Ne: In srig. Z za С 4 4 - і - - ях ni va o ka B I z . т в т "BK Ho UKH U re : 4 oo j kg E KO ze knnia What sh NYA i. o and - ee CHI zho. и ях шшы ш -щ tk m шка KU и мк - или и N Iv -- MK EK KMU sche in a V SY U Ah zhi H i i V Her zzht m i pos a i Nv NN NN V : in WDE more! K i EK i u i I : M M still i : k OH, i : om U m Be i i M Kh U N N : z Y v; ; Her KI PAK oh N : her. In! y UK S. vopa N susha Y y SK i od x N y y N y p KT i nn A ZOO ZY NK po Fig. 4