RU129568U1 - COASTAL WAVE ENERGY CONVERTER - Google Patents

Abstract

An energy converter of coastal waves containing a hollow reinforced concrete massif that forms a reservoir filled with water through the front (facing the sea) wall by sweeping waves through it and having a water pipe with a low-pressure hydraulic turbine in the underwater part of the rear wall, characterized in that the front wall is hinged to the foundation of the structure and can swing in waves, transferring energy to an additional linear hydraulic converter.

Description

The claimed solution relates to the field of energy, in particular to means for extracting the energy of sea waves in the coastal zone.

The Oscillating wave surge converter (OWSC) solutions are known from the technical level, in particular, the Oyster system - patent WO 20PCT GB 2006000906 - 03/15/2006, as well as Overtopping Wave Energy Converter (OWEC, TAPCHAN) (article Marine Renewable ( Wave and Tidal) Opportunity Review, December 2005, Scottish Enterprise publication, http://www.oceanrenewable.com/wp-content/uploads/2007/03/oregreport.pdf).

The main part of the OWEC type converter is a tank, in which the wall facing the sea has a slope and an upper edge rising above the sea level so that the waves poured through it into the tank. Outlets with low-speed turbines are located in the underwater part of the opposite wall, rotating due to the difference in water levels in the tank and in the sea and transmitting rotation to electric current generators. To increase the efficiency of the system, various forms of the wall facing the sea are used, for example with a slope and channels narrowing when approaching the tank, as in the TAPCHAN system.

However, with a small wave, only a small part of the wave crest overflows over the edge of the front wall. Most of the energy is reflected from the front wall back into the sea.

Thus, this solution has the following disadvantages:

- high loss of wave energy on the front wall;

- low flow rate in the channels of hydraulic turbines;

- low efficiency when exposed to small short waves;

- icing at low air temperatures.

The OWSC type transducer consists of a sash hinged in the lower part to the foundation at the bottom of the coastal zone. Under the influence of waves, the sash swings relative to the vertical plane. The shutter in the Oyster system consists of several horizontally oriented floats connected to each other, which, due to buoyancy forces, ensure that the shutter returns to the vertical position after the action of the wave. The shutter is also connected to the base by a linear hydraulic converter (pump) that feeds water through pipes to the turbines, which are driven by an electric current generator.

This solution has the following disadvantages:

- effective use only on large waves, when there is intense swaying of the "wings";

- the possibility of shear and destruction of structures by storm waves.

The task is to create a combined design of the coastal wave transducer based on the OWSC and OWEC systems, which allows eliminating their shortcomings and combining their advantages.

The technical result is to increase the efficiency of the energy converter of coastal waves due to the use of wave energy in a wide range of heights and frequencies, reducing the loss of wave energy on the front wall; increasing the flow rate in the channels of hydraulic turbines.

The indicated technical result is achieved in a coastal wave energy converter containing a hollow reinforced concrete massif forming a reservoir filled with water through the front (facing the sea) wall by sweeping waves through it and having a water supply pipe with a low-pressure turbine in the underwater part of the rear wall, according to the utility model, the front the wall has a hinge on the foundation of the structure and can swing in waves, transmitting energy to an additional linear hydraulic converter.

The design of the device is shown in the drawing. The reinforced concrete massif giant (1), forming a reservoir (2), is fixed at the bottom. Its front, from the sea side, wall (3) is connected to the base plate (4) by means of hinges. The movable front wall and the foundation plate are connected by a linear hydraulic converter (5). In the underwater part of the rear fixed wall (6) are openings with hydraulic turbines (7).

The device operates as follows. When the wave rises, a part of the energy is taken over by the front wall, transmitting it to a linear hydraulic converter (5). The top of the wave overlaps through the front wall (3) and enters the reservoir (2), forming a difference in water levels in the sea and in the reservoir (pressure). Due to the pressure, a flow is formed through the hole in the rear wall, which drives the hydraulic turbine (7). Kinetic energy from the operation of a linear hydraulic converter and a hydraulic turbine is converted into electrical energy.

It can be used in the energy industry as a power plant.

Claims (1)

An energy converter of coastal waves containing a hollow reinforced concrete massif that forms a reservoir filled with water through the front (facing the sea) wall by sweeping waves through it and having a water pipe with a low-pressure hydraulic turbine in the underwater part of the rear wall, characterized in that the front wall is hinged to the foundation of the structure and can swing in waves, transferring energy to an additional linear hydraulic converter.

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