RU2187018C1 - Windmill-electric generating plant - Google Patents

Abstract

FIELD: wind- power engineering. SUBSTANCE: plant has annular pontoon-rotor, wind-responsive operating elements, and flexible links between rotor and energy converter hubs; novelty is that wind-responsive elements are disposed on annular deck coaxial with and parallel to annular pontoon which is mounted above the latter and attached to annular pontoon by means of pins, preferably truss ones. EFFECT: enhanced power capacity, operating efficiency, and stability of plant. 8 cl, 1 dwg

Description

 The invention relates to the field of low energy and can be used to create high-power installations.

 Known is a wind power installation containing wind-sensing working bodies mounted on a frame of load-bearing elements placed on an annular pontoon located in a liquid-filled annular channel, and an energy converter kinematically connected with the pontoon, made hollow, partially filled with liquid and equipped with retractable blades mounted on the internal and external surfaces of the pontoon (see ed. St. USSR 1719713, BI 10, 1992).

 A disadvantage of the known solution is the need to build an annular channel, which significantly complicates and increases the cost of installation. The disadvantage is also expressed in the complication of the transfer of mechanical energy to electric generators.

 Also known is a wind power installation containing an annular pontoon rotor equipped with wind-sensing working bodies and flexible coupling elements of the rotor with the hubs of the energy converter (see RF patent 2119092, BI 26, 1998).

 The disadvantages of the prototype are low bending rigidity of the installation with large diameters; wind-sensing working bodies located on the ring pontoon are at a sufficiently low level, which leads to a decrease in the efficiency of the installation; the location of the pontoon and wind-picking working bodies on the same diameter increases the resistance to movement of the annular pontoon on the water. In addition, the integral design of the rotor and the lack of lifting mechanisms complicate the maintenance and repair of the wind power installation.

 The problem to which the invention is directed is expressed in increasing the efficiency of a wind power installation and its stability.

 The technical result that is achieved when solving the problem is expressed in the reduction of the resistance forces to the movement of the annular pontoon on the water while increasing the power on the shaft of the wind power installation; in ensuring the placement of wind-picking working bodies in the area most favorable for work at their maximum distance from water; provides a significant increase in the rigidity of the entire structure, which becomes a spatial truss.

 The problem is solved in that the wind power installation containing an annular pontoon rotor, equipped with wind-sensing working bodies and flexible coupling elements of the rotor with the hubs of the energy converter, is characterized in that the wind-sensing bodies are placed on the annular deck, coaxial and parallel with the annular pontoon placed above it and bonded to the annular pontoon by means of rod, preferably truss elements.

In addition, the distance between the parallel annular pontoon and the deck is determined from the relation
h = 0.05 ..... 0.2D,
where h is the distance between the annular pontoon and the deck,
D is the largest diameter of the rings.

 The distance between the annular pontoon and the deck exceeds the maximum height of the wave crests at the installation location.

 At the same time, the upper annular deck is made of a larger outer diameter than the lower annular pontoon, and the lower annular pontoon is assembled from separate pontoons rigidly interconnected, for example, by bolts. In addition, the lower annular pontoon is made with gaps between the pontoons.

In this case, the main flexible elements are installed between the annular deck and the hub of the energy converter, in addition, it is equipped with additional flexible elements, some ends of which are fastened with an annular pontoon, while others are connected with mechanisms for changing the length of the links, for example, winches placed on the hub of the energy converter, and the hub of the energy Converter is located above the level of the annular pontoon so that additional flexible elements make an angle to the water surface of at least 5 ^o .

 A comparative analysis of the essential features of the proposed solution with the essential features of analogues and prototype indicates its compliance with the criterion of "novelty."

 Moreover, the features of the characterizing part of the claims solve the following functional tasks.

 The sign "... Wind-receiving organs are placed on the annular deck, coaxial and parallel with the annular pontoon placed above it ..." allows you to place wind-sensing working bodies in the area most favorable for work.

 The sign "... a ring deck, .. fastened to an annular pontoon by means of rod, preferably truss elements ..." allows to increase the bending rigidity of the rotor with virtually no restrictions by increasing the distance between the rings.

 The features of the second claim are selected from the conditions for ensuring the strength and stability of the wind power installation.

 The sign "... the distance between the annular pontoon and the deck exceeds the maximum height of the wave crests at the installation location ..." ensures the free passage of waves under the annular deck. This reduces the wave effect.

 The sign "... the upper annular deck is made of a larger outer diameter than the lower annular pontoon ..." is aimed at reducing the resistance forces to the movement of the pontoon on water.

 The signs "... the lower ring pontoon is assembled from separate pontoons rigidly interconnected, for example, with bolts ..." and "... the lower ring pontoon is made with gaps between the pontoons ..." are included for technological needs. The implementation of the annular pontoon from separate rigidly connected pontoons will facilitate the manufacture and repair of the rotor, and the gaps between the individual pontoons will provide the opportunity for small vessels to pass, which will facilitate maintenance of the wind power installation.

 The sign "... the main flexible elements are installed between the annular deck and the hub of the energy converter. .." provides the radial stiffness of the rotor of the wind power installation without restricting the vertical movement of the rotor, for example, when water level fluctuates.

Signs "... it is equipped with additional flexible elements, some ends of which are fastened with an annular pontoon, while others are connected with mechanisms for changing the length of additional flexible elements, for example, winches placed on the hub of the energy converter ..," and "... the hub of the converter energy is located above the level of the annular pontoon so that additional flexible elements make an angle to the water surface of at least 5 ^o ... "provide the ability to lift the entire rotor using tension mechanisms above the water for maintenance and repair and allow you to raise the rotor above the water in the cold season and ensure the operation of the wind power installation with the support of the rotor on the ice surface.

 The invention is illustrated in the drawing, which shows a wind power installation in section.

 The drawing shows an annular pontoon 1, an annular deck 2, trusses 3, wind-picking working bodies 4, rotation mechanisms 5 of the working bodies 4, the energy converter 6, the hub 7 of the energy converter 6, the main flexible elements 8, additional flexible elements 9 and length changing mechanisms connections 10.

 The rotor of a wind power installation consists of two load-bearing systems connected by shaped structures 3 so that the section planes of these systems are parallel to the surface of the water. The lower supporting system is made in the form of an annular pontoon 1 (one side of which is made of the necessary shape to support the water surface), assembled from separate pontoons with gaps of more than three meters between the pontoons, rigidly connected, for example, by bolts or welding. You can make a pontoon with minimal wave resistance, for example, in the form of two pipes of circular cross section, which provide sufficient stability.

 On the upper supporting system, representing the annular deck 2 (made, for example, in the form of a flat disk), wind-sensing working bodies 4 are installed, made in the form of rotary blades with a mechanism for their rotation 5. The rotation mechanisms of 5 blades 4 can be made in any well-known version, for example, a gear drive from a driven motor driven by a weather vane. The distance between the annular pontoon and the annular deck is determined from the ratio h = 0.05-0.2D from the condition of ensuring the strength and stability of the installation. Here h is the distance between the annular pontoon and the annular deck, and D is the largest diameter of these rings. The bending rigidity of a wind power installation can be increased without limitation by increasing the distance between the annular pontoon and the annular deck and increasing their width. The rotor rotates around a stationary base on which an energy converter 6 is mounted, a hub 7 is made at its upper ends. Moreover, the hub 7 of the energy converter 6 is positioned above the level of the annular pontoon 1. The annular deck 2 is connected to the hub 7 of the energy converter 6 by the main flexible elements 8 (for example , cable system), which provide radial rigidity of the installation rotor. The annular pontoon 1 with additional flexible elements 9 is connected with mechanisms 10 for changing the length of ties, for example, winches, which are located on the hub 7 of the energy converter 6.

 Wind power installation works as follows.

 In the initial state, additional flexible elements 9 are weakened so that the rotor of the installation is fully supported on the surface of the water. When the wind is amplified, the rotation mechanisms 5 of the wind-receiving working bodies 4 are set in working condition, in which the rotor begins to rotate. At the same time, due to the friction forces of the rotor against the water, a water ring is unwound. When the set speed is reached, the energy converter 6 is turned on. From the action of the wind on the wind-picking working bodies 4, the rotor experiences a torque, which is transmitted through the flexible elements 8 to the hub 7 and the energy converter 6, and the radial load, which is held by the flexible elements 8 on the leeward side and stiffness of the rotor from the windward side. Large waves during normal operation of the installation are partially smoothed out by the water ring and can pass through trusses between the annular pontoon 1 of the annular deck 2. When it becomes possible to freeze the water surface, the rotor is lifted by pulling additional flexible elements 9 by mechanisms 10 for changing their length. When a stable ice situation is reached, the rotor can be lowered to the ice surface.

Claims (8)

 1. Wind power installation containing an annular pontoon rotor, equipped with wind-sensing working bodies and flexible coupling elements of the rotor with the hubs of the energy converter, characterized in that the wind-sensing bodies are placed on the annular deck, coaxial and parallel with the annular pontoon, placed above it and fastened to the annular pontoon by means of rod, preferably truss elements. 2. Wind power installation according to claim 1, characterized in that the distance between the parallel annular pontoon and the deck is determined from the ratio
h = 0.05 - 0.2D,
where h is the distance between the annular pontoon and the deck;
D is the largest diameter of the rings.  3. Wind power installation according to paragraphs. 1 and 2, characterized in that the distance between the annular pontoon and the deck exceeds the maximum height of the wave crests at the installation location.  4. Wind power installation according to claim 1, characterized in that the upper annular deck is made of a larger outer diameter than the lower annular pontoon.  5. Wind power installation according to claim 1, characterized in that the lower annular pontoon is assembled from individual pontoons rigidly connected to each other, for example, by bolts.  6. Wind power installation according to paragraphs. 1 and 5, characterized in that the lower annular pontoon is made with gaps between the pontoons.  7. The wind power installation according to claim 1, characterized in that the main flexible elements are installed between the annular deck and the hub of the energy converter, in addition, it is equipped with additional flexible elements, some ends of which are fastened with an annular pontoon, and others are connected with mechanisms for changing the length of additional flexible elements, for example, winches placed on the hub of the energy converter. 8. Wind power installation according to claims 1 and 7, characterized in that the hub of the energy converter is located above the level of the annular pontoon so that additional flexible elements make an angle to the water surface of at least 5 ^o .