SU1061859A1 - Device for flashing cavities and channels - Google Patents

Abstract

1. A device for flushing cavities and channels, comprising a housing with tongs for supplying the working agent, a piston housed in the housing, and a hydraulic nozzle mounted coaxially with it, an axial drill with a nozzle hole and a supporting spring, and This is due to the fact that, in order to increase reliability in operation, the piston has a nozzle channel, a valve and springs acting on the valve of the axis of the piston in opposite directions, as well as an adjusting element connected to the valve through one of the springs, and another spring is set phenomenon between the piston and the valve, and an additional spring-loaded valve disposed in the inner cavity of the piston for closing the nozzle Kaya in the piston, and the spool is located on one RCI between the piston and the nozzle head. 2. The device according to claim 1, about tl and. The fact that, in order to increase the washing ability of the working agent, the additional spring-loaded valve contains cavitation S grooves. (L 3. The device according to claim 1, which is based on the fact that, in order to increase the service life, it is equipped with a by-pass orifice between the channels and the working agent.

Description

about 00

SP

f.

The invention relates to the field of cleaning and can be used, for example, for flushing through and dead-end channels in products of fuel and oil supply equipment of aviation and automobile engines.

A device for cleaning products is known, comprising a housing with channels for supplying a working agent, a piston housed in a housing and a hydraulic nozzle mounted coaxially with it, a spool with a nozzle hole and a supporting spring Cl.

However, the presence of a large number of movable parts reduces the reliability of the device.

The aim of the invention is to increase the reliability of the device.

This goal is achieved by the fact that in a device for washing cavities and channels, including a housing with channels for supplying a working agent, a piston located in the housing, and a hydraulic nozzle mounted coaxially with it, a spool with a nozzle hole and a supporting spring, the piston has a nozzle channel valve and springs acting on the valve along the axis of the piston in opposite directions, as well as an adjusting element connected to the valve through one of the springs, with the other spring mounted between the piston and the valve SG, and an additional spring-loaded valve disposed in the inner cavity of the piston for closing the nozzle channel in the piston, and the valve is located on the same axis between the piston and the nozzle head.

In addition, the additional spring loaded valve contains cavitation grooves.

In this case, the device is equipped with a bypass jet between the channels for the working agent.

FIG. 1 shows a device, a vertical section / in FIG. 2 section A-A in FIG. 1 / in FIG. 3 section bb in fig. 1 (cavitational grooves spring-loaded valve).

The device for washing cavities and channels (Fig. 1) contains a pump 1, a channel 2 with pressure P supplying working fluid to the openings 3 of the spool 4 fixed on the piston 5, and a hydraulic nozzle U fixed on the spool 4, body 7 inside which a nozzle 8 is placed connecting the channel 2 of pressure P with a cavity 9 loaded with pressure P, inside which a valve 10 is placed, blocking the nozzle channel 11 in the piston 5, springs 12 and 13, between which valve 10 is installed, support 14 of spring 12 connected to movable yoke bearing 15 mounted on one shaft with an adjusting element 16, an additional spring-loaded valve 17 with cavitation grooves 18 (Fig. 3), blocking the channel 11 (Fig. 1) under the influence of the spring 19, and the spring support 20 19. The support spring 21 of the piston 5 is connected to the movable stop bearing 22 installed in the housing 7, the stop valve 23 closes the channel with pressure R.

The device works as follows.

Fluid under pressure P from pump 1 through channel 2 enters the apertures 3 of spool 4 and passes inside the hydraulic nozzle b, from which it enters the object. A fluid with pressure P whose value is greater than pressure P loads the channel in front of the stop valve 23.

At this time, the cavity 9 of the command pressure is energized by the pressure P through the jet 8, leveling off. the most pressure drop on the piston 5 and the weighted valve 10, which statically blocks the nozzle channel 11. Initial conditions (pressure and frequency of the device in the pulsation mode of pressure and flow are adjusted by the adjusting element 16, which through the bearing 15 and the support 14 acts on the spring retention 12 and 13, between which a valve 10 is mounted relative to the piston 5 and the nozzle channel 11.

When the shut-off valve 23 is opened, the pressure Pj loads the command chamber 9. The pressure in the cavity 9 increases sharply, and the valve 10 with the piston 5 causes a pressure differential, by which the system valve 10 - the piston 5 moves towards the nozzle head 6. At the same time, the spring 12 is tightened decreases, the tightening of the spring 13 remains unchanged (as the valve 10 is pressed against the nozzle channel 11), and the tightening of the spring 21 increases.

The system displaces the valve 10 - piston 5 until the spring 12 n "e reduces its tightening so that the spring 13 overcomes the pressing force; valve 10 to the valve bore 5 (channel 5 11 (pressure drop) and returns valve 10 to the original position.

The pressure fluid é instantly fills the nozzle channel 11 and displaces the spring-loaded auxiliary valve 17 with cavitation grooves 18 in the direction of the hydraulic nozzle b, compressing the spring 19. Through the nozzle channel 11, the liquid with pressure P from the cavity 9 passes through the cavitation grooves 18 where it vortexes and sprays to form a cavitation cloud, which impulsively bursts into the flow with pressure P., forms a hydraulic shock surge i in it, and through hydraulic accumulator 6 hits the pumped surface, exposing it to rapid pulsating bombardment by bursting bubbles of a cavitation cloud, which dramatically increases the processing efficiency. The pressure in the cavity 9 drops, the pressure drop across the piston 5 decreases sharply and under the action of the compressed spring 21 it returns to its initial position, where the nozzle channel 11 is blocked by the valve 10, and simultaneously the inner part of the nozzle channel 11 is blocked by an additional spring-loaded valve 17 under the action of the spring 19. The cycles repeat automatically until the stop valve 23 blocks the access of the fluid with the pressure Po to the cavity 9. After this, the pumping takes place in the usual way and only from the pressure P 22 and J 2019 Access of fluid with pressure P into cavity 9. Nozzle 6 I performs reciprocating movements with respect to body 7 with frequency and amplitude determined by spring tightening 12 by adjusting element 16. At the same time, the system valve 10 is piston 5 is spool 4 hydraulic nozzle 6 - simultaneously with the reciprocating motion, it makes a rotational motion relative to the housing 7 under the action of the reaction of the jets of the hydraulic nozzle 6 (FIG. 2), facilitated by the bearings 15 and 22. The proposed device provides the effect of liquid jets on all parts of the flushed surface of the channels and cavities without areas of dead zones, guaranteeing high processing efficiency. 5 L 13 JO 12} if / 5 J.,

bb

Claims (3)

1. A device for flushing cavities and channels, comprising a housing with channels for supplying a working agent, a piston placed in the housing, and installed coaxially with it | a hydraulic nozzle nozzle, a spool with a nozzle hole and a support spring, with the exception that, in order to increase reliability, the piston has a nozzle channel, a valve and springs acting on the valve along the piston axis in opposite directions, as well as an adjustment element connected to the valve through one of the springs, the other spring being installed between the piston and the valve, and an additional spring-loaded valve located in the internal cavity of the piston to block the nozzle channel in the piston, and the ash Nick is one yards between the piston and nozzle extension. 2. The apparatus of claim. 1, on t l u .chayuscheesya in that, in order to increase detergency working agent, _with optional podpruzhi- nenny valve comprises kavitatsionnye® groove. 1_ 3. The device according to π. 1, due to the fact that, in order to increase the service life, it is equipped with an IV but bypass nozzle between the channels for the working agent. TO