SU1661534A1 - Automatic disconnecting device - Google Patents

Abstract

The invention relates to valves, mainly to gas energy systems. The purpose of the invention is to increase the reliability of operation due to throttle-free penetration of the reverse flow and cleaning it from ice inclusions. In the initial position, the spring 13 presses the cup 10 against the ring 11. With an increase in the flow rate of the medium in the throttling gap 21, the velocity of the medium and the pressure drop across the plates 5 increase, under the action of which it sits on the saddle 9, blocking the flow of the medium. In order to ensure a guaranteed low flow through the device, inclined holes 15 are made in the saddle 9, which also clears the stream from ice. When the medium moves in the opposite direction under the action of the flow, the cup 10 moves to the stop at the end of the groove of the housing 1, while the collar 12 is located in the area of the cone of the plate 5, which ensures unhindered flow of the medium. 1 hp f-ly, 5 ill.

Description

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The invention relates to reinforcement, mainly to gas power systems.

The purpose of the invention is to improve reliability in operation due to the throttle-free flow of the reverse flow and the cleaning of the gas flow from ice inclusions.

Figure 1 shows the device at the working position of the plunger under normal operating conditions for flow and flow of the medium, a general view; figure 2 is the same, when the plunger is closed when the device is triggered and the medium flows; fig.Z - the same, in the open position with a countercurrent environment; 4 and 5 show the holes of the saddle and the blades of the cylinder.

The device includes a housing 1 with an inlet 2 and an outlet 3 with nozzles interconnected by a plunger 4 with a plate 5 and a piston 6. The piston 6 is placed in the cylinder 7 and loaded with a spring 8. In the case 1 there is a seat 9 and a movable cup 10, between which there is a ring 11 with collar 12, Glass 10 is loaded with spring 13 and through holes 14 are made in it. In hole 9, holes 15 are made. Seat cylinder 7 has vanes 16 and non-return valve 17, and hole 18 is made at its end 18 Plate 5 of plunger 4 has a sealing ring 19 eg from soft polymer The oil is placed on the face surface of the plunger. The plunger 4 at one end is installed in the beaker 10, the other (piston 6) in the cylinder 7. The cylinder 7 is installed in the housing 1 in the region of the expansion of the flow part. A gap 21 is formed between the cylindrical surface 20 of the plunger 4 and the collar 12. There is a gap 23 between the sealing ring 22 of the seat 9 and the ring 19. There is a labyrinth seal 24 on the piston 6.

The device works as follows.

The medium is supplied to the device through the pipe 2. The gas passes through the holes 14, the gap 21, the gap 23 and then through the intercostal space and the pipe 3. The equilibrium of the plunger 4 in the position shown in Fig. 1 is determined by the ratio of the operating forces of the springs 13 and 8. The spring 13 creates a greater force, so the cup 10 is pressed against the ring 11. As the gas flow rate through the device increases beyond the value determined by the force of the spring 8 (for example, due to depressurization of the pipeline behind the device), the flow velocity increases in the throttling gap 21 the pressure difference across the plunger 4 increases. Under the effect of the pressure difference, the plunger 4 moves to the seat 9 (Fig. 2), and leakage through the depressurized pipeline is stopped. In case the conditions of operation require guaranteed

gas leaks when the device is closed, holes 15 in the saddle are made to ensure a strictly fixed gas flow. At the same time, no leakage through the seat and plate seals is provided by using a soft, for example, polymer ring 19.

If the device is used in systems that require a counter-flush or gas supply of the gas source by

5 counter pressure, the gas is supplied from the side of the outlet nozzle 3. In this case, under the action of the counter pressure, the plunger 4 moves toward the nozzle 2, acts on the cup 10, compresses the spring 13. The cup 10 moves to the stop at the end of the body groove (Fig. 3) . Thus, with this mode of use, the device provides a significant increase in the gap between the shoulder

5 12 and plunger 4, which reduces the hydraulic resistance of the device and allows for increased gas flow. In this mode, the collar 12 is located in the area of the conical surface of the plate 5

0 plunger 4.

The operating conditions of the device often require a delay in closing the plunger to eliminate false positives during short throws.

5 pressures or flow rates in the systems and shorten the opening time when refueling with a counter, to blow off. For this purpose, the device is additionally equipped with a check valve, which, when moving the piston 6 in the cylinder 7, closes the opening 18 for closing and, when opened, opens the passage through this opening. In the first case, the time of movement is determined by the small flow of the medium through the gap.

5 between the piston 6 and the cylinder 7 with a labyrinth seal 24. In the second case, a high flow rate is provided by opening the additional bore 18.

When using a device for supplying gas of increased moisture content, high pressure, at a temperature close to the dew point, to remove the solid phase (ice) from the stream, the hole 15 is made at an angle to the axis of the saddle. Occurs at.

5 In this case, the inertial force throws ice particles to the periphery of the internal cavity of the channel, where freezing moisture accumulates on c, a shade in the form of a frost in the zone providing heat exchange with the external environment. This is also achieved by twisting the gas flow on the blades 16 installed at an angle to the channel section. The implementation of the channel in this zone with expansion ensures a decrease in the flow rate and an increase in the contact area with metal, which promotes evaporation through heat exchange with the environment. In order to intensify heat exchange, it is advisable to build the device in the region of the channel extension with finning. The blades 16 of the cylinder 7 also help to stabilize the flow of the medium and provide the centering of the cylinder 7 in the channel.

Claims (2)

Claim 1, Automatic disconnecting device comprising a housing placed between the inlet and outlet of the housing of a spring-loaded plunger with end, cylindrical and conical surfaces, interacting with the saddle and rigidly connected with a piston located in the cylinder, spring-loaded glass with stor0 five 0 the inlet pipe in the cylindrical bore of the housing with the possibility of axial displacement joint with the plunger, and a throttle ring with a collar stationary in the housing between the saddle and the cup, the displacement of the cup being limited by the end of the groove and the throttle ring, The interacting saddle area of the plunger is located on its end surface, a throttling gap is formed between its cylindrical surface and the collar of the throttle ring, and its horses The cusp surface is arranged to form a throttle-free gap when the glass is in contact with the end of the groove. 2. Device pop. 1, characterized in that there are holes in the saddle that communicate the inlet and outlet pipes, and their radius is smaller on the side of the inlet pipe than on the outlet side. 4 & .2 t ten eleven t figs FIG L 7