RU2710135C1 - Tidal hpp - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: invention relates to design of autonomous tidal damless low-power power plants and can be used to convert energy of sea currents (tides) into electric energy. Purpose: provision of power to remote consumers deprived of main electric networks. Tidal hydroelectric power plant comprises a pneumatic-hydraulic chamber, the underwater part of which is located at the bottom of the reservoir, and surface is communicated with atmosphere through pressure air duct, air turbine, kinematically connected to electric generator, elastic gas holder located at bottom of water reservoir. Chamber is equipped near the bottom in the zone of tide with water inlet-outlet holes and a hole on the upper end, on which the valve box is located. Box has two holes, one of which is equipped with valve spring-loaded for closing, connected to pressure air duct, and the other opening is connected through a local air duct, a check valve and a common air duct to the inlet of the gas holder, wherein from the outlet of the latter the compressed air is supplied to the air turbine by means of an air duct. In order to increase HPP power at water reservoir bottom in zone of water inflow there can be installed several pneumohydraulic chambers, additional local air ducts of which through additional check valves are connected to common gas duct of gas holder. Also, to increase HPP capacity as an air turbine, a volumetric flow meter is used, and an additional load distributed on its surface is placed on the gas head.

EFFECT: simplified design and operation of the device in automatic mode without the need for continuous maintenance.

5 cl, 1 dwg

Description

The invention relates to structures of autonomous tidal damless power plants of small power and can be used to convert the energy of sea currents (tides) to electrical energy.

 The famous "Tidal power station" according to the author's certificate of the USSR No. 1432133, IPC E 02 B 9/08, the author A.B. Ermilova [1]. This device contains a dam, forming a reservoir separated from the free sea, and the dam is made in the form of pontoon sections with channels in which the turbines are installed, and a flexible waterproof bridge with loads, anchor anchors and flexible ties securing the dam to the bottom.

 When erecting tidal hydroelectric power stations, the main costs are the construction of dams and the creation of an artificial reservoir [2]: “Tidal power plants”, the alternative energy portal [Electronic resource], www.alter220.ru, p.7, therefore, the author proposed copyright certificate No. 1432133 Use a floating flexible waterproof jumper.

  The disadvantages of this device are the structural complexity and low reliability due to the instability of the hydroelectric station to storms and the short life of the materials used. During stormy waves in the water area, emergency immersion of sections is proposed, for which Kingstones open and water enters the ballast chambers, lowering the sections below the water level, and the sections are lifted by compressed air from pre-filled receivers. In addition, the operation of the power plant requires attendants.

 It is also known "Device for extracting energy from sea currents" according to the patent of the Russian Federation No. 2401358, IPC E 02 B 9/08, authors E.N. Bellendir, A.V. Petrashkevich and others

 This device contains several cylindrical supports-shells located on the offshore shelf, a system of inlet and outlet pipelines, hydrogenerators, and the support shells installed in a row with a gap for the passage of water along a line perpendicular to the direction of the tidal currents, the cavity of the support shell is divided vertically by partitions into several tiers to accommodate pipelines and hydrogenerators, the supply pipe runs diagonally perpendicularly, and the discharge pipe runs diagonally parallel flax line installation opor- shells, ends of the conduits are in communication with the sea, and hydro placed on the discharge pipe.

 The disadvantage of this device is also the structural complexity that is implemented only for high power plants and the presence of a significant number of staff. In addition to the complexity of manufacturing the large cylindrical support shells themselves, located on the sea shelf, and cavities in shell supports with partitions for several tiers, in which pipelines and hydrogenerators are placed, a large number of autonomous hydrogenerators (a turbine with a generator) are required, the operation of which will still need to be synchronized in a power generation system.

 The closest technical solution is the "Wave Power Station" by Yu.B. Shpolyansky, B.L. Historian and others. RF patent No. 2459974, IPC F 03 B 13/24.

 This invention relates to hydropower and can be used for significant fluctuations in the level of the water surface due to tidal or tidal or surging phenomena in electrical energy.

 The device comprises a fixed support, a pneumohydraulic chamber, the movable part of which is in communication with the reservoir, and the surface part is connected with the atmosphere through a pressure duct in which a turbine with a generator is installed. In addition, the device is equipped with a rotating drive kinematically connected to the camera, which is mounted on a support with the possibility of vertical movement, and the drive is connected to the camera through a pair of power elements from a number of nut-screw, gear-toothed rack, hydraulic cylinder-rod, drum-cable and the rotary drive is equipped with automatic control with the ability to move the camera relative to the support in accordance with fluctuations in the average level of the water surface.

 The disadvantage of this device is the structural complexity, the need for support shells that perform the function of a dam, and also the need for maintenance personnel and its high cost, characteristic of high power hydroelectric power plants, included in the general system of providing electricity to consumers. In addition, to install the camera at the required level of the water surface requires an electric drive external source of electricity.

 The objective of the present invention is to remedy these disadvantages and create an autonomous, simple in design tidal hydroelectric power station that does not use external additional power sources and does not require constant costs for its maintenance.

  The technical result of the invention is as follows:

- the design is simplified due to the absence of a dam and a storage tank fenced off by the dam from the free water area of the sea;

- functioning of the device in automatic mode without the need for constant maintenance;

- the function of energy storage - compressed air is performed by an elastic gas tank located at the bottom of the reservoir;

- a gas tank located in shallow water or on land surface is equipped with additional dispersed cargoes that create pressure on its surface;

- a volumetric flowmeter with a high accuracy class was used as an air turbine.

  The technical result is achieved due to the fact that an elastic gas tank is additionally introduced into the tidal hydroelectric power station containing a pneumatic hydraulic chamber, the underwater part of which is connected to the sea, and the surface part with the atmosphere through a pressure duct fixed to the upper end of the chamber and an air turbine kinematically connected to the generator located at the bottom of the sea, the chamber is equipped with holes near the bottom of the chamber in the zone of water outflow and a hole on the upper end, on which there is a valve box with two holes, one of the cat ryh fitted on a spring-loaded closing valve which is connected to the discharge duct and the other opening is connected via a local air duct to the inlet gas holder, wherein the output from the final compressed air through the air supplied to the air turbine.

 The technical result is also achieved due to the fact that several pneumohydraulic chambers are installed at the bottom of the sea in the low tide zone, the additional local air ducts of which are connected to the common air duct of the gas tank through additional non-return valves;

  The technical result is also achieved due to the fact that a volumetric flowmeter with a high accuracy class is used as an air turbine, and an additional load is located on the surface of the elastic gas tank.

The drawing shows the design of the proposed "Tidal HPP". The device comprises an underwater pneumohydraulic chamber 1 mounted on the bottom of the sea, having openings 2 for entering and exiting water near its bottom, and a valve box 3 at the top, equipped with a spring-loaded air valve 4, which is connected to the atmosphere via a pressure duct 5, while the valve the box has a common opening 6 with a chamber, equipped inside with a float valve 7 and an opening 8 connected through a local air duct 9, a non-return air valve 10 and a common air duct 11 to the elastic gas tank 1 2, performing the function of storage of compressed air. The gas holder is equipped with a pressure relief valve 13 and is connected through a supply duct 14 and a pressure regulator 15 to an air turbine 16 loaded on an electric generator 17.

 If it is necessary to increase the power of the hydroelectric power station, several pneumohydraulic chambers are installed on the seabed (not shown in the drawing), and with each of them, through additional local air ducts 18, through additional non-return air valves 19, compressed air is supplied to the common air duct and then to the gas tank.

 In the process of operation of the device in the pneumatic chamber creates variable volumes of the air cavity 20 and the water cavity 21.

 "Tidal hydroelectric power station" works as follows. At low tide Notl. with a minimum level of water in the sea, water from chamber 1 exits through openings 2, while water cavity 21 decreases, and air cavity 20 increases due to the vacuum formed in the chamber and its filling with air through air duct 5, valve 4 and opening 6. Simultaneously while the chamber 1 is filled with air with the valve 4 open, through the hole 8, the local air duct 9, the non-return air valve 10 and the common air duct 11, the intake air partially enters the gas tank 12.

 When the sea tide occurs, water enters through the openings 2 into the chamber 1, while the water cavity 21 increases to the level Npr., And the air cavity 20 is compressed, the spring-loaded air valve 4 is closed and the compressed air through the open hole 6 of the chamber, hole 8 of the valve box, local air duct 9, non-return air valve 10, common air duct 11 is fed to the filling of the elastic gas tank 12. Compressed air from the gas tank through the supply duct 14 enters the pressure regulator 15 and then to the air turbine 16, equipped nnuyu generator 17.

 When the next outflow of water into the sea occurs, the cycles of the Tidal HPP are repeated. The stock of compressed air in the gas tank 12 should ensure uniform operation of the hydroelectric station for the period between tidal cycles, so either the pneumohydraulic chamber 1 must have the appropriate dimensions, or through additional local air ducts 18 and additional non-return air valves 19 to the common air duct 11 of the gas tank 12 similar pneumohydraulic chambers (not shown in the drawing).

 To protect the gas tank 12 from rupture when the pressure in it exceeds the standard, a pressure relief valve13 is used.

 If the chamber 1 is located at a depth exceeding the height of the chamber, then as a result of the tide, the water cavity 21 completely fills the internal volume, while the float valve 7 blocks the opening 6 of the chamber, preventing water from entering the valve box 3. In this case, the height of the pressure duct 5 should be above the water surface of the tide.

  The gas holder is attached to the bottom at a considerable depth or is equipped in shallow water, as well as on the surface of the earth with additional goods dispersed over the surface of the gas holder (not shown in the drawing). Such a storage of compressed air can be made in the form of inflatable elastic cylinders, the pressure of which can be maintained at higher parameters due to the pressure of the upper layers of water, so it is advisable to place it at greater depths or on top, at the suggestion of the author, with additional loads [5]: Pavel Kotlyar. Canadians figured out how to store surplus energy under water [Electronic resource]: www. Gazeta. com / science / 2014/07/12. shtin 1. Various reservoir equipment can be used as data of compressed air storage facilities, including elastic gas tanks of Penzelectro CJSC [6]: Gas tanks for biogas, biogas plants. CJSC Penza Oil and Gas Equipment Plant [Electronic resource]: www. penzenergo. Ru, and also - gas holders of the Austrian company Sattler Textilwerkt (Membrane gas holders for milking biogas. - “Aquatherm”, No. 5 (21), 2004, p. 98 [7].

 As an air turbine 15, it is more expedient to use a volumetric flow meter with a high accuracy class. This is due to their ability to convert most of the kinetic energy of air into mechanical energy, and the fraction of the span mass of the stream not involved in turning it into work is very small [8]: Domogatsky VA, Levchenko IV Roller-blade machine. RF patent No. 2230194, IPC F01C1, and also - "Air motors" of the company LLC "West-metrology" [Electronic resource] www. west-metrology.ru/production/air-motor.html [9].

 The proposed autonomous “Tidal hydroelectric power station” is intended for mass use, both by individual consumers, remote from main electric networks, and not by large settlements. The hydropower plant operates in automatic mode and does not require constant maintenance. A hydropower plant is assembled from serial units and structures, therefore it has a minimum cost during its construction, which allows us to recommend it for widespread use.

Claims (5)

1. A tidal hydroelectric power station containing a pneumohydraulic chamber, the underwater part of which is connected to the sea, and the surface part is connected to the atmosphere through a pressure duct fixed to the upper end of the chamber and an air turbine kinematically connected to the generator, characterized in that an elastic gas holder is introduced located at the bottom of the sea, the chamber is equipped with holes near the bottom of the chamber in the zone of water outflow and a hole on the upper end on which there is a valve box with two holes, one of which is equipped with a spring-loaded closing apani connected to the discharge duct and the other opening is connected via a local air duct to the inlet gas holder, wherein the output from the final compressed air through the air supplied to the air turbine. 2. Tidal hydroelectric power station according to claim 1, characterized in that several pneumohydraulic chambers are installed at the bottom of the sea in the tide zone, the additional local air ducts of which are connected to the common air duct of the gas tank through additional non-return valves. 3. Tidal hydroelectric power station according to claim 1, characterized in that a volumetric flow meter is used as an air turbine. 4. The tidal hydroelectric power station according to claim 1, characterized in that the additional load distributed on its surface is placed on the gas tank. 5. Tidal hydroelectric power station according to claim 1, characterized in that the chamber inside is equipped with a float valve blocking the hole at its upper end.

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