SU1581950A1 - Device for damping hydraulic shocks - Google Patents

Abstract

Stable to absorb hydraulic shocks, comprising a housing with an inlet, outlet and drainage pipe in which a movable supply and a receiving nozzle is placed, characterized in that, in order to increase the efficiency of operation, it is additionally equipped with a bypass pipe communicated with the inlet and outlet nozzles, receiving the nozzles are made with an internal annular groove, and the supply is equipped with a control cavity that can communicate with the inlet pipe, and is installed with the possibility of blocking the bypass pipe interrogation, with the last reported groove inlet pipe.

Description

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The invention relates to mechanical engineering and can be used to protect pipeline systems from hydraulic shocks.

The purpose of the invention is to increase the efficiency of the device for damping hydraulic shocks,

The drawing shows a device for damping hydraulic shocks.

The device comprises a housing 1, an inlet 2, an outlet 3 and a drainage 4 nozzles, a movable supply nozzle 5 and a receiving nozzle 6, a bypass pipeline 7, an annular groove 8, a control cavity 9, an end 10 of an inlet nozzle 2, an end 11 of a conical receiving nozzle 6, end.12 nozzle 5, outlet 13, piston 14, conical nozzle 15, cavity 16, inlet end 17 nozzle 5, orifice 18G hydraulic distributor 19 and channels 20 and 21.

The device for damping hydraulic shock works as follows.

Pressure water through the inlet 2 is fed into the supply nozzles 5. At the same time, the pressure water through the channel 20 and the valve 19 enters the cavity 9. Due to the fact that the area of the piston 14 in the cavity 9 is larger than the area of the right end 17 of the moving supply nozzle 5, the latter under some force pressed to the end 10 of the inlet 2 and blocks the access of water into the bypass pipe 7 directly from the inlet 2. After that, the entire flow enters through the conical nozzle 15 in the form of a jet into the receiving nozzle 6, the passage between in nozzle 15 and the receiving nozzle 6. Since the jet in the gap is in contact with the atmospheric air through the drain pipe 4, it should be considered free undrowned. The boundary layer of such a jet is saturated.

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by air. The entrance to the receiving nozzle 6, having a diameter equal to or greater than the diameter of the conical nozzle 15, is more saturated with air at the walls of the receiving nozzle 6, the passage in which air is picked up by the annular collector 8 and is directed through the outlet 13 to the bypass pipe 7 located above the housing 1. At the end of the branch pipe 13, the flow turbulence is caused by a change in direction, and a part of the nascent in the air flow leaps (due to its smaller volume, Hb rQ weight than that of water) and accumulates Cavities with a bypass line 7.

In addition, pressure is lost in the flow through the gap, and as a result, dissolved air is released from the water in the form of bubbles, which also partially enters the bypass pipe 7. At the indicated position of the moving nozzle 5, hydraulic shock is activated booster, in the pipeline of which there is either a flow deceleration or its acceleration with a change in pressure (water hammer). At the same time, the pneumo-hydroaccumulator, which in this case is the bypass pipe 7, accumulates

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It emits energy during the period of deceleration of the flow, gives it away during the period of acceleration and partially damps the pressure fluctuations in the outlet nozzle 3. The final suppression of the pressure oscillations propagating in the opposite direction to the inlet flow occurs in the receiving nozzle 6 and in the free stream in the gap. To prepare the device for operation in stationary mode, the mobile

nozzles 5 must be moved to the left extreme position before meeting with the receiving nozzle 6, i.e. until the ends 11 and 12 are in contact. This is accomplished with the help of the hydraulic distributor 19, which connects the cavity 9 with the atmosphere through the channel 21. The force acting from the right end 17 of the nozzle of the feeding nozzle 5 moves it to the extreme left position, and the water to the output pipe 3 and then to the consumer comes mainly through

the bypass line 7, forced out immediately from it compressed air. The partially pressurized water enters the outlet nozzle 3 through the nozzle 15. Since the resistance of the bypass pipe is much less than the resistance of the nozzle 15 and the receiving nozzle b, then when the feed nozzle 6 is closed, the pressure loss through the proposed device is minimal.

Claims (1)

(54X57) A DEVICE FOR EXTINGUISHING HYDRAULIC SHOCKS, containing a housing with inlet, outlet and drainage nozzles, in which a movable supply and receiving nozzle are located, characterized in that, in order to increase the efficiency of operation, it is additionally equipped with a bypass pipe in communication with the input and output nozzles, the receiving nozzle is made with an internal annular groove, and the supply is equipped with a control cavity that is able to communicate with the inlet pipe, and is installed with the possibility of overlapping bypass th pipeline, with the latter communicating a groove of the receiving pipe.