SU51551A1 - Hydraulic valve - Google Patents

Description

The known systems of hydraulic valves for gas storages have a very significant and important drawback, namely, the oil from the valve is systematically discharged either on the roof of the tank or inside it. Phenomena of oil release are particularly frequent in the summer, when the amount of vapor released from gasoline in tanks is especially high. As a result, the operation of the hydraulic valves is completely unreliable, since with each release of oil, some of its oil is permanently lost and the valve starts to operate at pressures well below the calculated ones. In addition, at the moment of gas breakthrough through the oil seal, part of the gasoline is absorbed by the oil, which causes the specific gravity of the oil to decrease, as a result of which the valve also starts to operate at pressures lower than what is set.

The proposed hydraulic valve is designed to eliminate the above disadvantages and ensure normal trouble-free operation.

The drawing shows an exemplary embodiment of a valve.

In the oil bath 8, there is a hydraulic shutter of mineral

the oil into which the end of the nozzle 7 is immersed. When the pressure inside the reservoir increases (the pressure in the drawing is shown by arrows), gases passing through the openings 5 of the external valve nozzle will begin to exert pressure on the oil, due to which the oil from the bath S will be squeezed into which will rise up to the upper reservoir 3, which represents the broadening of the nozzle 7.

Having entered the upper reservoir 5, the oil is thrown by gases to the walls of this reservoir, after which, having received an open passage, the gases will begin to freely leave the reservoir through the openings 2 to the outside. The outflow of gases to the outside will continue until all the oil escapes from the inclined planes of the tank 3 through the nozzle 7 down into the oil bath 8 and takes its original position, in which it will be until the pressure of the gases inside the reservoir does not rise again.

The opposite is true if the pressure of the gases inside the tank drops. In this case, the outside air, passing through the openings 2, will begin to exert pressure on the oil layer, whereby the oil, under the influence of the air pressure, will begin to be squeezed out into the external connection 9, where it will rise upwards to the cone-shaped reservoir b, when the oil enters, and in the upper tank it is thrown against the walls of tank b, and the air, having a free passage, will flow into the tank through the holes 5.

The intake of air into the reservoir will continue until all the oil has drained from the cone-shaped planes of the reservoir b into the oil bath 8, where, if the pressure inside the reservoir and the outside air is balanced, it will remain at rest, closing the air inlet to the reservoir.

The use of screw plug 7 gives

the ability to measure oil in the valve.

Thus, supplying the internal and external connections 9 and 7, which form the hydraulic valve, with the widths of 5 and 5, prevents the valve from losing the barrier oil, and placing the oil bath inside the gasoline storage facility prevents the oil from heating by sunlight.

The subject matter of the invention.

A hydraulic valve, characterized in that both the external and internal nozzles forming the valve have a width of 5 and 5, which prevent the barrier fluid from being ejected from the valve when the pressure in the tank increases or decreases.