RU1777632C - Wave-electric power plant - Google Patents

Abstract

SUMMARY OF THE INVENTION: A wave-receiving shield with returnable elements is pivotally connected to the rods of pneumatic cylinders. The discharge lines are connected to an air collector connected to the consumer. Guide rods are coaxially attached to the support. Holes are provided around the perimeter of the shield to accommodate the rods. The shield is mounted for reciprocating movement. Return elements are made in the form of deaf pneumatic cylinders attached to the support. The support is made in the form of a container filled with water. All pneumatic cylinders are submerged under water level. The support is rigidly fixed on the shore in the zone of action of the breaking wave. Pressure valves of pneumatic cylinders are equipped with a set of springs of different stiffness. 1 s P. f-ly, 4 ill.

Description

The invention relates to compressors producing compressed air from the energy of sea waves.

A well-known hydropower installation 1, including a float support, on which pneumatic cylinders are mounted with pivotally attached rods to a rectangular wave-receiving shield, discharge lines connected to an air collector connected to a consumer.

The disadvantage of this installation is the low efficiency of using the energy of the breaking sea wave and the complete loss of thermal energy of the air compressed by the pneumatic cylinders.

The purpose of the invention is to increase the efficiency of using the energy of the breaking sea wave during the operation of pneumatic cylinders, and also to utilize the heat energy when compressing air,

The goal is achieved in that the installation is equipped with guides

rods cantileverly attached to the support in the form of a container, and holes are made around the perimeter of the shield to accommodate the said rods, while the shield is mounted with the possibility of reciprocating movement, and its return elements are made in the form of additional blind pneumatic cylinders attached to the support, the last in the form of a container, while the capacity of the support is filled with water, and all pneumatic cylinders are submerged under the water level, while the support is rigidly attached on the shore in the zone of operation of the breaking wave, and the discharge valves are mon vmotsilindrov provided with a set of springs of different stiffness.

In FIG. 1 shows a hydropower installation, general view (section AA in FIG. 2 when free air is drawn in, dashed arrow), FIG. 2 - section bB in FIG. 1; in FIG. 3 - the same during the working stroke of the pneumatic cylinders (compressed air - arrow with a point); in FIG. 4 - general view

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WITH

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Y Yu

S

power plants as an option for using compressed air.

A hydroelectric power plant, comprising working pneumatic cylinders 1 (compressor type), horizontally mounted in a concrete support 2 having a tank, is last fixedly installed on the shore in the surf zone of a sea wave (see Fig. 1), and the ends of the rod 3 of working pneumatic cylinders 1 pivotally attached to a rectangular wave-receiving shield 4, which is reciprocating along the cantilever rods 5. In addition, the wave-receiving shield A is pivotally attached to the rods 6 of the blind return pneumatic cylinders 7 installed in the support - tanks 2 parallel to the working pneumatic cylinders 1 (see Fig. 2). The pistons 8 and 9 of the pneumatic cylinders are equipped with elastic compression cuffs (see Figs. 1-3), while the working pneumatic cylinders 1 have suction valves 10 and pressure valves 11, and the blind return pneumatic cylinders 7 have a compression chamber 12, and pressure valves 11 by means of a pipe 13 connected to the gas holder 14, and he through the pipe 15 - with a pneumatic turbine 16 in the unit with an electric generator 17.

Water is poured into the capacity of the support 2, washing the pneumatic cylinders to utilize the heat energy of the compressed air. And the pressure valves 11 are provided with springs of various stiffness for the purpose of efficient operation of the installation with a variable height of the breaking sea wave.

The bottom hydroelectric power plant operates as follows.

From the technical literature it is known that the energy of the breaking sea wave reaches the apogee of the shore v and amounts to 14,840 kg / m2) At a wave height of 1.8 m. This type of energy is converted by this unit into compressed air energy that can be used to generate electricity or mechanical operation of pneumatic machines.

  Through the nipple into the piston cavity. deaf return pneumatic cylinders 7 under pressure pump compressed air sufficient to move to the left extreme position along the cantilever rods 5 of the wave shield 4. In this case, the pistons 9 of the deaf return pneumatic cylinders 7 will make a stroke, and the pistons 8 of the working pneumatic cylinders 1 will produce through the suction valve 10 free air intake, air from the stock cavity

working pneumatic cylinders 1 are ejected

into the atmosphere through a breather pipe (not shown).

When the sea swells

creates pressure on the wave-receiving shield 4,

displacing it along the cantilever rods m 5 to the right extreme position (Fig. 3), while in the working pneumatic cylinders 1 the pistons 8 are shifted to the right, compressing the air, the suction valves 10 are closed, the pressure valves 11 are opened and compressed air from the working pneumatic cylinders 1 to the collector (not shown in Fig.) and then through the pipe 13 to the gas holder 14, and from there through the pipe 15 in the pneumatic turbine 16, which drives the electric generator 17 (see Figs. 3 and 4).

In addition, when the wave-receiving shield 4 moves to the right extreme position in the deaf return pneumatic cylinders 7

0 additionally compresses the air in the chamber 12, which, when the wave ebbs, again moves the wave-receiving shield 4 to the left extreme position, thereby making a reciprocating movement in accordance with the periods of sea waves, while the working pneumatic cylinders 1 are put into operation.

Due to the fact that the working pneumatic cylinders 1 are immersed in water located in the container of the support 2 (see Figs. 1 and 3), the heat energy released by compressing the air heats the water that can be used for swimming pools, greenhouses, etc. .

5

Claims (2)

1. A bottom hydroelectric power plant comprising a support, a wave receiving shield with return elements, Q pivotally connected to the rods of pneumatic cylinders, discharge lines that are connected to an air collector connected to a consumer, characterized in that to increase the efficiency of the installation by utilizing heat during compression of the air and rigidly supporting the support, the installation is equipped with guide rods cantileverly attached to the support, and around the perimeter -n of the shield, holes are made to accommodate the said rods, while the shield is mounted with the possibility of reciprocating movement, its return elements are made in the form of additional blind pneumatic cylinders attached to the support, the latter in the form of a container filled with water, and all pneumatic cylinders are submerged water, while the support is rigidly fixed on the shore in the zone of action of the breaking wave. 2. Installation pop. 1, characterized in that the pressure valves of the pneumatic cylinders are provided with a set of springs of different stiffness. Wave g in about 0 0 " | ..-.- i3 ° o in to - S-b V / 3 -4 in oh oh oh j in about 0 0 "  in ° about oh a / V 7 / Tv, //  x / /,, /// MI I V 4, // / Ж3X -v / //// /// , // / /. // // s