LT5967B - Hydraulic shock air compressor - Google Patents

Abstract

Invention relates to air compressors, where is used periodically induced hydraulic shock force. The compressor has a water supply channel (1), compressed air generation device with a water inlet (15) and output (16) openings with valves and compressed air output device connected to the air receiver (8). Air generating device has a cylindrical body (2), rotating in it hollow shaft (3), which contains minimum two bucket shape blades (4), shaft (3) rotation locking mechanism (9) and is connected to the air chambers of compressed air output device, which consists of space between the shoulder blades (4) and the elastic diaphragms (5), sandwiched between the shoulder blades (4), which are composed of radial plane (13), fixed on a hollow shaft (3), and a cylindrical surface (11), with an elongated hole, adherent to the inner surface of cylindrical body (2) where the cylindrical surface (11) is the water inlet (15) and output (16) opening valve. Compressed air output from the air chamber comprises if a hollow shaft (3) end, is equipped with air suction valve (18) and a transversal holes (6) shaft (3) wall that joins the air chambers to air receiver (8) through the shaft (3) channel (7).

Description

The invention relates to air compressors which use periodic hydraulic shock force.

Hydraulic stroke is a technique commonly used in hydraulic jacks, a water lifting device that is used to deliver water when the water supply is greater than the water requirement and when the device can be installed below the water source. Although the hydraulic taran is only 0.2-0.4 in efficiency, its biggest advantage is that it uses free water power.

A known hydraulic impact air compressor used in a hydraulic container (patent RU 2239102). This compressor has two water-supply pipes with blow-off valves connected by a pivoting lever and two water-air valves with inlet valves, in which one water-air valve is connected via a drain valve and a pressure pipe to a water overflow chamber and the other water-air valve has a drain valve connected to the impact valve by means of a lever mechanism and is connected to a water transfer chamber by an air supply pipe. In the first water-air enclosure, compressed air drives water to the water transfer chamber, and in the second, compressed air drives water from the transfer chamber to the water pressure vessel.

The main disadvantage of this compressor is that it can only be used for one purpose - water lifting and cannot be used as an independent source of compressed air power, which can be used for various purposes. In addition, it is difficult to select its optimum operating mode, since the pressure compression level and duration of the pressure cap cannot be controlled by a drain valve connected to the impact valve via a lever mechanism. Running water is irrationally used because much of it is simply discharged into the environment like other wastewater.

Another known hydraulic impact air compressor (SU 1652674) has a water supply pipe with a built-in impact valve and a hood that divides the diaphragm into the air and water cavities. The enclosure air cavity has a non-return air intake valve and is connected via a non-return valve to a compressed air supply pipe.

By converting the kinetic energy of the water stream into the compressed air, this air compressor expands the potential for water and kinetic energy at water level changes. The disadvantage of such a compressor is the insufficient utilization of the supplied water energy, since only a small part of the water flow is utilized to obtain compressed air.

The closest analogue is a hydraulic blow air compressor (patent LT5653), which has two water supply pipes with impact valves and two compressed air generators connected to the water tank via a water supply channel - air valves with water inlets and outlets with valves and air intake valves. Both compressor air hoods are connected to the air supply pipe and air receiver. The air outlet valves for air hoods are controlled depending on the pressure in the air hoods.

The main drawbacks of this hydraulic impact air compressor are its inefficiency and design complexity.

Compressor performance is limited by the fact that it cannot fully utilize the available water flow for compressed air and has a high idle time. The complexity of the design is determined by the need for two air hoods, to which water is fed via separate pipes, using commutated impact valves.

The object of the invention is to increase the operating efficiency of the hydraulic impact air compressor by making fuller use of the existing water flow, simplifying its construction and expanding its application possibilities.

The invention relates to the fact that in a hydraulic stroke air compressor having a water supply conduit, a compressed air generating device with valves for water inlet and outlet and a compressed air outlet connected to an air receiver, the air generating device has a cylindrical housing rotating in it a hollow shaft, on which are mounted at least two bucket-shaped blades, a hollow shaft locking mechanism, and air chambers connected to the compressed air outlet device comprising a cavity between said blades and between the elastic orifices disposed between said blades.

The bucket shape is provided by said blades having radial planes mounted on said hollow shaft and a cylindrical surface having an elongated opening which abuts the inner surface of the cylindrical housing, where the cylindrical surface serves as a valve for the water inlet and outlet ports.

The device for extracting compressed air from the air chambers consists of an air suction valve mounted at the end of the hollow shaft and transverse openings in the wall of the hollow shaft which connect the air chambers to the air receiver via a duct of this shaft.

The hollow shaft locking mechanism has a control device coupled to an air receiver that performs periodic hollow shaft angular locking and release.

This design of the air compressor allows the use of the full flow of water in the width and height of the compressed air, directing it from the water supply channel to the compressor water inlet. This compressor can be installed even at low water falls or below the hydroturbine already in use.

The water inlet and outlet openings in the cylindrical housing are rotated in the direction of rotation of the hollow shaft at an angle of 360 ° / 2n, where n is the number of blades. In addition, the cylindrical housing has an additional drainage opening away from the outlet opening in the direction of rotation of the hollow shaft at an angle of 360 ° / 2n, where n is the number of blades.

The water inlet and outlet openings may be equal to the width of said blades. This allows you to reduce the water filling and draining cycle as these operations occur simultaneously.

The water supply duct is located above the water inlet and has a non-return valve which stops the return wave.

The invention is schematically explained in the drawings, wherein:

FIG. 1 is a schematic diagram of a hydraulic impact compressor.

FIG. 2 - A-A compressor with a three-blade shaft.

FIG. 3 is a compressor according to FIG. 2 when the blades turn 30 °.

FIG. 4 is a compressor according to FIG. 2 when the blades turn 60 °.

FIG. 5 is a compressor according to FIG. 2 when the blades turn 90 °.

The hydraulic stroke air compressor has a closed water supply conduit 1, a compressed air generating device with a cylindrical body 2, comprising a rotating hollow shaft 3, on which at least two bucket-shaped blades 4 are mounted. the diaphragms 5 form air chambers.

The hollow shaft 3 has transverse openings 6 and a channel 7 connected to the air receiver 8, its locking mechanism 9 and a control device 10.

One part 11 of the blades 4 adjoining the inner surface of the cylindrical body 2 has a cylindrical shape and has an elongated opening 12. The other part 4 of the blades 4 mounted on a hollow shaft 3 forms a radial plane 13. The diaphragms 5 are fixed between the adjacent blades 4 14. The cylindrical body 1 has water inlet 15, outlet 16 and drainage openings 17.

In the compressed air chambers, the air outlet device comprises an air suction valve 18 mounted on a hollow shaft 3 and transverse openings 6 in the wall of the hollow shaft 3, which connect the air chambers to the receiver 8 through shaft 3 passage 7. Mechanical shaft 19 may be mounted on the shaft 3. 1 has a non-return valve 20 mounted on a shaft 21.

The hydraulic stroke air compressor operates as follows.

A flowing stream of water enters the cylindrical body 2 through the entire width of the closed supply channel 1 through the inlet opening 15 (Fig. 2) and out through the opening 12 of the blade 4 and the outlet 16.

When the flow of water accelerates, the locking mechanism 9 releases the hollow shaft 3, which together with the blades 4 (Fig. 3) rotates at an angle of 30 ° (36074η, where n is the number of blades) and the cylindrical part 11 of the blade 4 in the cavity between the blades 4, the radial plane 13, the inner surface of the cylindrical body 2, and the elastic diaphragm 5, a hydraulic impact occurs which compresses the diaphragm 5 and expels air from the said cavity through the transverse openings 6 and the size of the shock wave depends on the closing time of the outlet 16. In addition, the non-return valve 20 prevents the return wave from returning to the water reservoir, thereby further enhancing its effect on the diaphragm 5. The magnitude of the compressive force when the diaphragm 5 is compressed is not reduced as it rests on the radial planes 13 of the blade 4. reduces the volume of the air chamber itself.

As the air pressure in the receiver 8 decreases, the control device 10 releases the hollow shaft 3 and turns it at an angle of 60 ° (another 30 °) (Fig. 4). The water in the cylindrical body 2 flows through the outlet 16 and the diaphragm 5 partially recovers. The air is aspirated through valve 18. After rotation of 90 ° (Fig. 5), the water ends through the outlet 16 and drain 17 and the diaphragm 5 is fully restored. The water flow through the inlet port 15 is closed. The non-return valve 20 prevents the return wave from striking back into the water reservoir, thereby increasing the water pressure as the shaft rotates for a further 30 ° and restores water outflow with increased water outflow through the outlet. The cycle repeats itself.

Claims (8)

Definition of the Invention A hydraulic stroke air compressor having a water supply conduit (1), a compressed air generating device with valves for water inlet (15) and outlet (16), and a compressed air outlet device coupled to an air receiver (8), that the air generator comprises a cylindrical body (2) rotating in the body (2) a hollow shaft (3) on which at least two bucket-shaped blades (4) are mounted, a shaft (3) rotation locking mechanism (9) and connected to the compressed air outlet an air chamber formed by a cavity formed between the blades (4) and the elastic diaphragms (5) fixed between the blades (4). 2. Compressor according to claim 1, characterized in that said bucket-shaped blades (4) consist of a radial plane (13) mounted on a hollow shaft (3) and a cylindrical surface (11) having an elongated opening which fits into the cylindrical body. (2) an inner surface, wherein the cylindrical surface (11) serves as a valve for water inlet (15) and outlet (16). 3. Compressor according to claim 1, characterized in that the device for extracting compressed air from the air chambers comprises an air suction valve (18) mounted on the end of the hollow shaft (3) and a transverse opening (6) in the wall of the shaft (3). a receiver (8) through a passage (7) of the shaft (3). 4. Compressor according to claim 1, characterized in that the locking mechanism (9) of the hollow shaft (3) comprises a control device (10) connected to an air receiver (8) which performs periodic angular locking and release of the shaft (3). 5. Compressor according to claim 1, characterized in that the openings of the water inlet (15) and the outlet (16) in the cylindrical body (2) are arranged in the direction of rotation of the hollow shaft (3) at an angle of 360 ° / 2n, . 6. Compressor according to claim 5, characterized in that the cylindrical body (2) has an additional water drainage opening (17) away from the opening of the water outlet (16) in the direction of rotation of the hollow shaft at an angle of 360 ° / 2n, . 7. Compressor according to claim 1, characterized in that the openings of the water inlet (15) and outlet (16) are equal to the width of said blades (3). 8. Compressor according to claim 5, characterized in that the water supply channel (1) is located above the opening of the water inlet (15) and has a non-return valve (20).