SU1229504A1 - Water-hammer alleviator - Google Patents

Description

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The invention relates to mechanical engineering and can be used for damping hydraulic shocks in the petrochemical industry, energy, heat and water supply and sewage.

The purpose of the invention is to increase the efficiency of the device by reducing its inertia.

The drawing shows a hydraulic shock absorber,

The device comprises a housing 1 with an inlet 2 and an outlet 3 nozzles in which the diaphragm valve body 4 is placed with a water-air tank 5 communicated through an electro-magnetic valve 6, and an adjustable choke 7 with a discharge Dm and nozzle 3. Reset chamber 8 department installed

But from the Eau Air Capacity 5 and the joint pipelines 11 with the upper part

through the solenoid valve bis with the outlet pipe 3 through an adjustable choke 7. The reset chamber 8 is equipped with a float valve, which is a float 9 ,. installed with the ability to interact with the hole 10, made in the upper part of the discharge chamber. 8. The air-water tank 5 communicates with the inlet pipe 2 through the pipe 1I and the membrane sensor 2, which contains the valve 13 with the rod passing through opening 14 of the partition 15,

The valve 13 is adjusted by means of an adjusting spring 16. Through the valve 13 a water-air tank 5, for example, its upper part communicates with the drain.

The inlet pipe 2 of the extinguisher communicates with the protected discharge pipe of the pumping station (not shown). The extinguisher's water-air tank 5 is filled through the pipe 11 and the opening 14 of the membrane sensor 12. The spring 16 of the membrane sensor 12 is usually set for maximum hydraulic pressure, therefore the valve 13 is closed . During normal operation of the pumping station (not shown), the electromagnetic valve 6 is closed, therefore, after filling the water-air tank 5, the pressure in it is equal to the pressure in the inlet pipe 2, and the diaphragm valve 4 closes the cross section of the extinguisher.

Hydraulic shock absorber works as follows.

When an overpressure occurs in the pipeline to be protected (not shown) and in the inlet 2, the valve 13 of the membrane pressure sensor 12 opens and connects the water / air tank 5 to the drain, as a result of which the pressure in the latter drops and the diaphragm valve 4 opens. After that, the pressure in

the protected pipeline (not shown) drops, which causes the valve 13 to close the membrane pressure sensor 12 and the membrane valve 4 to close, and the presence of a throttling hole 14 in the pressure sensor allows to mitigate the effect of pressure fluctuations in the water inlet 2 tank 5. Connection of pressure sensor 12

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the water-evaporating tank 5, where air accumulation is usually observed, allows to increase the rate of pressure drop in the water-air tank 3, and 5 hence, the speed of opening the valve organ 4,

When aEnarious shutdown of the pumping station, there is a de-energization of the electromagnetic zentu 6, which opens, and the air and then water leaves the water-air tank 5 and fills the discharge chamber 8. Part of the water comes out of the water-air tank 5 through adjustable throttle 7. As a result, the water-air tank 5 falls and the membrane valve 4 opens, which causes a pressure drop in the inlet pipe 2,

The diaphragm valve 4 remains open until all the air leaves the discharge chamber 8 through the opening 10. Then the float 9 will block the opening 10 and the pressure in the water-air tank 5 begins to increase due to the flow of water through the opening 14 of the membrane sensor 12 pressure is greater than through an adjustable choke 7.

The diaphragm valve 4 closes smoothly. When electrical voltage is applied to the electromagnet valve 6, the latter closes and cuts off the discharge chamber 8 from the airborne tank 5. There is 5 water draining from the discharge chamber 8 through the adjustable choke 7, and the float 9 opens the 2dors 10. As a result, the hydraulic shock absorber again ready for work.

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Claims (1)

HYDRAULIC SHOCK ABSORBER, comprising a housing with inlet and outlet pipes, in which a membrane shut-off element with a water-air tank is placed, and an electromagnetic valve communicated with the latter through the solenoid valve and with a discharge pipe through an adjustable throttle, characterized in that, p. In order to increase its efficiency, the discharge chamber is equipped with a float valve communicating with the atmosphere, and a water-air tank is connected with. the supply pipe through an additionally installed membrane sensor, controlled by pressure in the supply pipe.