RU57840U1 - WAVE POWER INSTALLATION - Google Patents

Abstract

The utility model relates to the field of renewable energy, namely, devices for converting the energy of waves of water bodies into electricity. The utility model is designed to increase the reliability of power plants using wave energy to generate electricity. The wave power plant declared in the utility model includes a vertical, bottom-mounted support, swinging bar mounted on the support with the possibility of rotation around the axis of the support, a float mounted on one end of the swinging bar. The float has an inlet at the bottom and an outlet at the top, equipped with remotely controlled valves, and an electric generator. The vertical support fixed at the bottom has a length such that its upper end is under water for any possible force of excitement. The wave force sensor is connected to remotely controlled valves, the float is connected to a pneumatic line connected to a pressure source, the swinging rod is connected to a pump, which is connected by a pipeline to the hydropotential energy accumulator on the shore, the electric generator is located on the coast and connected to a hydraulic turbine connected to the hydropotential energy accumulator goes into safe mode by filling the float with water when the wave strength is exceeded, which is determined by the corresponding sensor. 1 n P. f-ly, 8 s. P. f-ly, 3 ill.

Description

The inventive utility model relates to the field of renewable energy, namely, devices for converting the energy of waves of water bodies into electricity.

Known wave power plant according to the patent application of the Russian Federation No. 94025338 IPC 8 F 03 13/12. The wave power plant comprises a vertical support, a pipe mounted on the support with the possibility of rotation around its axis, two horizontal supports connected by guides along which a cylinder-shaped float moves, on the axis of which are mounted wheels moving along the guides, and by means of flexible coupling, leading the winding of the generator. The installation also contains two electric motors, with the help of which the installation changes its position when the direction of the wave and its amplitude change.

The main disadvantage of the known wave power plant is that the generator and electric motors are arranged with the possibility of water entering them, which reduces the reliability and durability of the installation.

Also known wave power plant according to the patent of the Russian Federation No. 2150021 IPC 8 F 03 13/12, the closest in its technical essence and adopted as the closest analogue. The wave power plant according to the patent of the Russian Federation No. 2150021 is as follows: on the surface of the water from the components a rigid volumetric frame is assembled in the form of the same type of modules, a plurality of floats are installed in several rows both along and perpendicular to the working shaft with one-way rotation couplings for each float and floats

bind to couplings with flexible connections. The secondary shafts of the gears of the various modules are connected by cardan gears. The area of the power plant, the parameters and the number of floats are determined by the derived formula, depending on the design capacity. Floats of two optimal shapes are used for two suspension options - on a two-arm lever and on a vertical section of a connection closed through four pulleys. Windmills, solar energy converters, industrial and residential buildings are placed on the frame. The utilized energy of waves and wind in the form of mechanical energy of a rotating shaft through clutch mechanisms, transfer cases, etc. They are used to drive electric generators, pumps, vacuum distillation plants, reverse osmosis desalination plants, mills, etc. Primary electricity with unstable parameters is used to heat steam, charge batteries, as well as to operate an electrolyzer and produce hydrogen, it is stored in tanks and used for work internal combustion engine to drive another generator with stabilization of parameters using feedback. With pumps, sea water is pumped into reservoirs above sea level and is used to operate a hydroelectric unit according to the principle of a pumped storage power plant. The power station is installed on a hinged support, or on piles, or on pontoons with the ability to control the height of the frame relative to the water level, equipped with water wheels for maneuvering.

The disadvantage of a single module of the known wave power plant is the possibility of destruction of the structure of this module, and especially the strut, float design and suspension of the float to the common frame by the strut or pulleys, when exposed to a wave load exceeding the calculated one, for example, during a strong storm, they can collapse, which reduces stability of the installation to adverse external factors and its reliability.

The claimed utility model has the task of increasing the stability of the wave power plant to adverse external factors, thereby increasing the reliability and durability of its operation in an unfavorable environment.

The problem is solved as follows: a wave power plant containing a vertical, reinforced at the bottom of the support, swinging rod mounted on the support with the possibility of rotation around the axis of the support, a float mounted on one of the ends of the swinging rod and the float has an inlet bottom and an outlet on top equipped with remotely controlled valves, and an electric generator, while the vertical, fixed at the bottom of the support, has a length such that its upper end is under water at any wave force, the wave force sensor is connected to remotely controlled valves, the float is connected to a pneumatic line connected to a pressure source, the swinging rod is connected to a pump, which is connected by a pipeline to the hydropotential energy accumulator on the shore, the electric generator is located on the shore and connected to a hydraulic turbine connected to hydropotential energy accumulator

The accumulator of hydropotential energy can be made in the form of a water tower.

The accumulator of hydropotential energy can be made in the form of a hydro-pneumatic accumulator.

Hydroturbine, pump and accumulator of hydropotential energy can be combined in a closed loop

A vertical open cup can be worn on a vertical support, mounted on a vertical support with the help of bearing bearings located in an air cushion formed between the glass and the vertical support.

The wave force sensor can be made in the form of a hydrostatic pressure sensor located on a swinging rod near the mounting of the rod on a support

The wave force sensor can be made in the form of an angular position sensor located on the axis of rotation of the rod.

The wave force sensor can be made in the form of an angular acceleration sensor and is located in the inner cavity of the rod;

The wave force sensor can be made in the form of a pressure sensor in the pump

Thus, the claimed utility model allows to obtain a technical result, namely, to increase the reliability and durability of the wave power plant in an unfavorable environment.

Fig. 1 shows a general view of the installation location in a pond, and the positions of the float in working and safe positions

Figure 2 shows the type of support with the equipment located on it.

Fig. 3 shows the view of the float and the attachment point of the swinging rod to the support

Wave power plant (figure 1) contains a vertical support 1 mounted on the bottom of the reservoir. The vertical support 1 is installed in such a way that its upper cut, with the swinging bar 2 fixed on it, is under water at any possible force of excitement. The swing rod 2 is mounted on the vertical support 1 so that the ratio between the shoulders of the swing rod 2 is approximately 10 to 1. At the long end of the rod, a float 3 is fixed. A vertical open cup 1 (Fig. 2) is fitted with a glass 4 open from below that is mounted on a vertical support 1 with the help of bearing units 5 located in the air cushion formed between the glass and the vertical support. Also outside the cup 4 is fixed pump 6, mechanically connected with a short

by the arm of the swinging rod 2. The pump 6 is connected via a pipeline 7 to a hydro-pneumatic accumulator 8 located on the shore in a place protected from adverse environmental factors. The turbine 9 is connected to the hydro-pneumatic accumulator 8 through a constant pressure valve. The drain pipe 10 is connected at one end to the outlet of the turbine 9, and at the other ends into a reservoir. In the float 3 (figure 3) there are upper and lower openings equipped with adjustable valves 11 and 12. Also in the float 3 there is an opening with a pneumatic line 13 connected to it, which is connected to a compressed air source 14. The adjustable valves 11 and 12 are connected to the sensor waves of excitement, made in the form of a hydrostatic pressure sensor 15 located on a swinging rod 2 near the mounting of the swinging rod 2 to the vertical support 1.

The drain pipe 10 can be combined with a pump 6 and a hydro-pneumatic accumulator 8 in a closed loop, which will slightly reduce the efficiency system, but will allow the use of a chemically neutral liquid, such as fresh water, which will increase the durability of the installation.

Also, the wave force sensor can be implemented as a sensor of the angular position of the swinging rod, or in the form of angular acceleration sensors located in the rod or in the float. The wave force sensor can be implemented as a pressure sensor in the pump. Due to the fact that the generator can be isolated from the adverse effects of the external environment on the shore, the reliability of the entire installation increases.

The wave power plant operates as follows:

Under normal environmental conditions, the swinging rod 2 with the float 3 freely rotates and swings relative to the vertical support 1, while the upper and lower adjustable valves 11 and 12 are closed. In this mode, the underwater part of the installation, due to mechanical movements of the float 3, pumps water through a pipeline 6 into a hydro-

a pneumatic accumulator 8, and then a stream of water passing through a turbine 9 generates energy. In the event of adverse external conditions, for example, excessive waves or wind, a signal is received from the sensor 15, to open the adjustable valves 11 and 12 in the float 3. the float 3 is filled with water, acquires negative buoyancy, and the swinging rod 2 with the float 3 plunges into the non subjected to significant dynamic loads from excitement. When the wave strength is reduced to an acceptable force, the sensor 15 gives a signal to close the upper valve 12 and to supply compressed air to the float 3 via a pneumatic line 13 from the compressed air source 15, water is forced out of the float 3, the float 3 acquires positive buoyancy and starts to work in normal mode. Some time after the start of the supply of compressed air to the float 3, the lower adjustable valve 11 closes. Thus, when the permissible loads are exceeded, the wave power plant switches to safe mode. In safe mode, all the main components of the structure are below the level of maximum impact of the waves, which helps to increase the reliability of the installation. Also, the wave power plant, which is in safe mode, is more dynamically stable due to the float filled with water.

Thus, the claimed utility model made it possible to obtain a technical result, namely, to increase the reliability and durability of the wave power plant in an unfavorable environment.

Claims (9)

1. A wave power plant comprising a vertical, bottom-mounted support, swinging rod mounted on the support with the possibility of rotation around the axis of the support, a float mounted on one of the ends of the swinging rod, moreover, the float has an inlet bottom and outlet top provided with controllable remotely by valves, and an electric generator located on the shore and connected to a hydraulic turbine connected to a hydropotential energy accumulator, characterized in that it is a vertical support fixed to the bottom, has a length such that its upper end is under water at any possible force of excitement, the excitation force sensor associated with remotely controlled valves, the float is connected to a pneumatic line connected to a pressure source, the swinging rod is mechanically connected to a pump, which is connected by a pipeline to the battery hydropotential energy on the shore. 2. The wave power plant according to claim 1, characterized in that the accumulator of hydropotential energy is made in the form of a water tower. 3. The wave power plant according to claim 1, characterized in that the accumulator of hydropotential energy is made in the form of a hydro-pneumatic accumulator. 4. The wave power plant according to claim 1, characterized in that the hydraulic turbine, pump and accumulator of hydropotential energy are combined in a closed loop. 5. The wave power plant according to claim 1, characterized in that the vertical support is equipped with a glass open from below that is mounted on a vertical support by means of bearing assemblies located in an air cushion formed between the glass and the vertical support. 6. The wave power plant according to claim 1, characterized in that the wave force sensor is made in the form of a hydrostatic pressure sensor located on a swinging rod near the node for attaching the rod to the support. 7. The wave power plant according to claim 1, characterized in that the wave force sensor is made in the form of an angular position sensor located on the axis of rotation of the swinging rod. 8. The wave power plant according to claim 1, characterized in that the wave force sensor is made in the form of an angular acceleration sensor located in the inner cavity of the swinging rod. 9. The wave power plant according to claim 1, characterized in that the wave force sensor is made in the form of a pressure sensor in the pump.