RU2630049C1 - Hydraulic ram - Google Patents

Abstract

FIELD: machine engineering.

SUBSTANCE: hydraulic ram has a working chamber 3, 4, an air cap 7, 8 with a rod 11, 12 of discharge valve 9, 10, an elastic diaphragm, a pipeline and power supply contacts 39, 40. The elastic diaphragm is made in form of membrane impact valve 15, 16 on the end side of the chamber inner space 3, 4, is isolated from the environment by a cover 19, 20. The shaft 11, 12 is located in the cap 7, 8 with an air duct 23, 24, a cover 33, 34 which has a guide hole 21, 22 made coaxially to the valve 9, 10, which free end is located in an opening 21, 22 with possibility for opening in water supply cycle from the chamber 3, 4. The rod 11, 12 in the upper part is provided with an open movable contact with a limiter. The valve 15, 16 is made with rigid center. The chamber 3, 4 is provided with an electromagnet 17, 18 fixed to its end, with the possibility of contacting the valve 15, 16 and connected to the power supply unit 39, 40 and a normally open contact 41, 42 adapted to interact with the open movable contact of the rod 11, 12.

EFFECT: increased operation efficiency, expanded field of application, reduced material consumption, increased reliability and quick action.

4 cl, 3 dwg

Description

The invention relates to pump engineering, in particular to the design of pulsed water-lifting devices, and can be used in the design of water-lifting systems in industry and agriculture.

Known electro-hydraulic ram containing a main pipeline, a discharge compartment housing with electrodes and a movable working body with contact plates and stops, the discharge compartment is separated from the main pipeline by a working body, which is made in the form of a piston mounted in the discharge compartment housing (Copyright certificate SU No. 1196537, F04F 7/02 of 12/07/1985).

A disadvantage of the known ram is the complexity and low value of the coefficient of performance. When the working body moves in the body of the discharge compartment in the form of a piston, it can jam, in particular, working in an aggressive environment (in water), i.e. insufficient reliability of the piston in the housing of the discharge compartment, which means that it is necessary to apply a high voltage to the discharge electrodes in the housing of the discharge compartment, respectively, there is a delay for closing the main pipeline as a whole.

Known hydraulic ram containing the main pipeline, the housing of the discharge compartment with electrodes, a movable working body that separates the discharge compartment from the main pipeline, and an air cap, while the working body is made in the form of elastic diaphragms (Copyright certificate SU No. 1242652, F04F 7 / 02 dated 07/07/1986).

However, this ram is not effective enough in operation due to the fact that the mobile working body is regulated in an additional housing filled with water, in which small soil particles accumulate, the reliability decreases, therefore, under this condition, its efficiency is not achieved for the pressure pulse of hydraulic shocks . In addition, the large inertia associated with the rods, leading the return of the diaphragm to its original position, reduces the performance of the ram. In this case, the unreliability of the elastic compression and tension diaphragms due to the operation of the rods is lost in time, a breakage is possible, i.e. fatigue of such elastic diaphragms.

The closest analogue (prototype) is a hydraulic ram containing a working chamber with a shock valve having a housing and a plate placed in it, connected to a pressure and collection tank, an air cap with a discharge valve and a pipeline, the working chamber is equipped with discharge electrodes and an elastic diaphragm connected with a shock valve, which is equipped with contact plates for power supply, located on the valve body and plate (Copyright certificate SU No. 1173078, F04F 7/02 of 08/15/1985).

The disadvantage of the closest analogue is the complexity of the design, the small value of the efficiency of the ram. In addition, this device is not efficient enough due to the fact that the regulation occurs by changing the dead weight of the shock valve and the elastic diaphragm. However, the diaphragm with stuffing box seals of the shock valve, although it does not allow idle discharge, but the device is unreliable in the diaphragm itself for a long time, breakage (rupture, i.e. fatigue of such elastic diaphragms) is possible.

The objective of the invention is to increase the efficiency of its action due to additional energy in the form of a pressure pulse of hydraulic shocks and increase reliability in operation.

To solve this problem, in a hydraulic ram containing a working chamber with a shock valve, an air cap with a discharge valve stem, an elastic diaphragm, a pipeline and contacts of a power supply unit, an elastic diaphragm is made in the form of a membrane shock valve on the side of the end face of the working chamber inner space, isolated from the surrounding medium with a cover, the discharge valve stem is located in an air cap with an air duct, the cover of which has a guide hole made coaxially with the discharge cell apana, the free end of which is located in the opening of the lid with the possibility of opening the water supply from the working chamber on the stroke, the discharge valve stem in the upper part having an open movable contact with a limiter, while the membrane shock valve is made with a rigid center and the working chamber is equipped with an electromagnet, fixed at its end with the possibility of contacting with a membrane shock valve and connected to the power supply and a normally-open contact, configured to interact with an open IG Petritskaya contact stem of the discharge valve.

In addition, the cap cavity in the upper part is provided with a housing covering the closure of open contacts.

In addition, the hole in the cap cover is connected to a compressed air supply system.

In addition, the duct is equipped with a check valve that is installed with the possibility of opening the exhaust air in the cap at the discharge stroke.

The aforementioned task, which the invention is directed to, is also to increase work efficiency by supplying additional air through an air duct with a non-return valve and a cap cover, which increases the height of the water rising above the calculated for a certain level of the working chamber in front of the shock valve (flexible diaphragm with an electromagnet )

The effectiveness of a ram is that it is simple in design and technologically advanced in production.

In FIG. 1 is a diagram of a working chamber (supply pipe) with a discharge valve and an open movable contact in the cavity of the air cap; in FIG. 2 - arrangement of a hydraulic ram; in FIG. 3 is a diagram of a flexible diaphragm and electromagnet assembly for supplying the latter (side view).

The hydraulic ram contains a supply pipe 1 and 2, which has working chambers 3 and 4 with valves 5 and 6 connected to the air cap 7 and 8 and equipped with a discharge valve 9 and 10. The discharge valve 9 and 10 is connected to the rod 11 and 12 with a spring 13 and 14, and the ram has a water hammer drive. The hydropercussion drive consists of an elastic diaphragm made in the form of a membrane shock valve 15 and 16 with a rigid center, and electromagnets 17 and 18, mounted in the end of the working chamber 3 and 4, isolated from the environment by a cover 19 and 20. The air cap 7 and 8 is fixed on top of the working chamber 3 and 4. A hole 21 and 22 connects the inner cavity of each cap 7 and 8 through the duct 23 and 24 with the compressed air supply system. Both caps 7 and 8 are interconnected with the compressor 25 through a pipe 26 with valves 27 and 28. A hole 29 and 30 connects the cavity of the cap 7 and 8 with the cavity 31 and 32 of the working chamber 3 and 4 and from the side of the cap 5 and 6, the hole 29 and 30 is made in the form of a seat designed for the discharge valve 9 and 10, which is made in the shape of a plate and connected to the stem 11 and 12 with a spring 13 and 14.

The rod 11 and 12 with its upper end enters the hole 21 and 22 of the cap 33 and 34 of the cap 7 and 8 and is equipped with a contact 35 and 36 with a stopper 37 and 38. The hole 21 and 22 in the cap 33 and 34 serves as guides for the rod 11 and 12 . The power circuit connecting the electromagnet 17 and 18 with the power supply 39 and 40 includes a normally-open contact 41 and 42 mounted in the air cap 7 and 8.

The stem 11 and 12 of the valve 9 and 10 with the spring 13 and 14 is designed to act on the normally open contact 41 and 42 on the contact 35 and 36 when the discharge valve 9 and 10 is closed, i.e. the position of the valve 9 and 10 in the seat of the cavity 31 32 of the working chamber 3 and 4.

With the shutter 5 and 6 closed, the discharge valve 9 and 10 is in its lowest position and, under the influence of its own weight and tension of the spring 13 and 14, tightly closes the hole 29 and 30. The power supply unit 39 and 40 of the electromagnet 17 and 18 is turned off when the shutter 5 and 6 are closed from electricity.

If the working chamber 3 and 4 has more than two air hoods, then in this case the normally open contact 41 and 42 is mounted in one of them.

The cap 7 and 8 is connected by a pipe 43 to the receiving tank 44.

Hydraulic ram operates as follows.

With the valve 5, 6 open, water enters the working chamber 3 and 4. Valve 9 and 10 is in its lowest position and, under the action of its own weight and the spring 13 and 14 connected with the stem 11 and 12, the valve 9 and 10 tightly closes the hole 29 and 30. In this case, the rod 11 and 12 controls a system of contacts turning the electric circuit on and off.

The inner cavity of the cap 7 and 8 is filled with air received from the compressor 25. Both caps 7 and 8 are interconnected with the compressor 25 by means of a pipe 26 with valves 27 and 28. The power supply unit 39 and 40 of the electromagnet 17 and 18 is turned off when the shutter 5 and 6 are closed from the mains.

With the open valve 5 and 6, the energy of the water flow creates water pressure in the working chamber 3 and 4, which is fixed by a cover 19 and 20, and presses on the membrane shock valve 15 and 16 with a rigid center, in the cavity between them there is an electromagnet 17 and 18 connected to power supply 39 and 40 with normally open contact 41 and 42.

Since the weight of the discharge valve 9 and 10 with the rod 11 and 12 and the compression spring 13 and 14 exceeds the pressure in the working chamber 3 and 4, the hole 29 and 30 are closed by the valve 9 and 10. At this moment, the contacts are closed, the electromagnet 17 and 18 is activated and actuates the membrane shock valve 15 and 16. When the electromagnet 17 and 18 are actuated, the rod 11 and 12 acts on an elastic membrane (working body), which is made of a membrane shock valve 15 and 16, made with a rigid center. A sharp movement of the membrane shock valve 15 and 16, directed against the movement of water in the working chamber 3 and 4, causes a water hammer. At the time of the direct shock wave, a sharp increase in pressure is observed in the working chamber 3 and 4. This leads to the discharge valve 9 and 10 rising upward from the seat of the hole 29 and 30. As a result of the increased pressure, a certain portion of water will flow from the cavity 31 and 32 into the cavity of the cap 7 and 8, compressing the air there, which accumulates the energy of the water hammer and the pumping stroke occurs, and the water moves through the pipe 43 to the receiving tank 44. When the pressure valve 9 and 10 moves upward, the action of the rod 11 and 12 on The open contact 41 and 42 is removed, contact 35 and 36 opens and the electromagnet 17 and 18 is disconnected from the power supply 39, 40. When the direct shock wave decays and the electromagnet 17 and 18 is turned off, the membrane shock valve 15 and 16 acts on the electromagnet rod 17 and 18, the membrane shock valve in the form of an elastic diaphragm returns to its original position, the pressure valve 9 and 10 due to its weight and compression spring 13 and 14 lowers and closes the hole 29 and 30 tightly, the rod 11 and 12 closes the normally open contact 41 and 42 which vk The electromagnet 17 and 18, the movement of the membrane percussion valve 15 and 16 with a rigid center causes a new water hammer and the next portion of water from the working chamber 3 and 4 flows under high pressure into the cap 7 and 8 and the pumping stroke again and the water moves to the receiving tank 44 .

During long-term operation of the hydraulic ram, the air supply in the cap 7 and 8 decreases due to its dissolution in water and subsequent removal into the receiving tank 44. In order to prevent this phenomenon, the air supply is replenished by the compressor 25 through the duct 23 and 24.

As the input energy accumulates in compressed air, the pressure in the cap 7 and 8 increases and significantly exceeds the pressure created only in the working chamber 3 and 4 and water to a height of elevation to replenish the receiving tank 44.

With repeated repetition of cycles with water hammer, a steady-state flow rate of chambers 3 and 4 will form to move water into the receiving tank 44.

In order for the replenishment of air to be constant pressure, a pressure reducing valve (not shown) can be installed for this purpose, passing air from the compressor under a certain constant pressure.

Therefore, it can be assumed that the calculation of pneumatic installations with variable pressure to replenish the hood with air is to determine the maximum air pressure as

(P _max +1) W _air = (P _min +1) (W _air + W _water ),

where P _max - maximum gauge air pressure in the cap; P _min - the minimum gauge pressure required by calculation; W _air - the volume of the hood for air; W _water - the volume of water in the cap.

When installing pneumatic units in all cases, it is advisable to use automation, which can significantly ensure the reliability of the ram.

Thus, the solubility of air in water increases with increasing pressure, therefore, at high discharge pressures, the air supply becomes especially important.

The coordination of the ram operation is carried out by the operation unit of the hydropercussion unit (drive), as well as by the presence of a rod with a spring, a valve and a normally open contact. The device has wide application possibilities for foothill and lowland areas, for example, a river or stream. This ensures the achievement of the goal - increasing the efficiency of the device, which is manifested in an increase in consumption from the working chamber, i.e. leads to increased efficiency of the hydraulic ram. The use of a hydraulic ram also extends the functionality and reduces operating costs. The device completely eliminates the loss of discharge air flow. To stop ramming, it is necessary to close the valve on the feed pipe and disconnect the power supply unit of the electromagnet from the mains.

Claims (4)

1. A hydraulic ram containing a working chamber with a shock valve, an air cap with a discharge valve stem, an elastic diaphragm, a pipeline and contacts of a power supply unit, characterized in that the elastic diaphragm is made in the form of a membrane shock valve on the side of the end face of the working chamber inner space isolated from environment by a cover, the discharge valve stem is located in the air cap with an air duct, the cover of which has a guide hole made coaxially with the discharge valve, free the bottom end of which is located in the opening of the lid with the possibility of opening on the water supply stroke from the working chamber, and the discharge valve stem in the upper part is provided with an open movable contact with a limiter, while the membrane shock valve is made with a rigid center, and the working chamber is equipped with an electromagnet fixed in its end with the possibility of contacting with a membrane shock valve and connected to the power supply and a normally-open contact, made with the possibility of interaction with an open moving con stroke of the discharge valve stem. 2. The hydraulic ram according to claim 1, characterized in that the cap cavity in the upper part is provided with a housing covering the closure of open contacts. 3. The hydraulic ram according to claim 1, characterized in that the hole in the cap cover is connected to a compressed air supply system. 4. The hydraulic ram according to claim 1, characterized in that the duct is equipped with a check valve installed with the possibility of opening the expended air in the cap at the discharge stroke.

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