SU885809A1 - Gas flowmeter - Google Patents

Description

one

The invention relates to a technique for measuring gas flow and can be used in automated control systems for experimental research as gas flow meters.

gas flow meters are known that contain a vessel with a liquid, gas supply and discharge pipelines and a measuring device, and the supply pipe 1 fills the liquid in them.

However, such gas flow meters have insufficient accuracy in measuring gas flow due to the large dependence of gas volume on temperature.

The flow meter (enzymes) is the closest to the preferred one, contains a separating vessel with a flexible partition, one cavity (filled with liquid) that is connected to the measuring vessel, and the other to the supply line, and through the valve and pressure follower with shift - with the power source of the measured environment 2.

The disadvantage of such a device is that the accuracy of the measurement of gas flow is strongly influenced by the change in pressure of the medium being measured.

The purpose of the invention is to improve the accuracy of measuring gas flow over a wide range of operating pressures.

The goal is achieved due to the fact that in the meter, the gas flow rate containing a separating vessel with a flexible partition, one (filled with liquid) cavity which is connected to the measuring vessel, and the other with the supply line and with a shift and pressure source with the measured medium, a pressure regulator was additionally introduced, the inlet of which is connected to the supply line, and the outlet to the air cavity of the measuring vessel and the control cavity of the pressure follower with a shift.

The drawing shows a schematic diagram of the meter gas flow.

Gas meter is

25 of the pressure follower 1 with a shift, the valve 2, the supply line 3 connected to the consumer 4, the separation vessel 5 with the flexible tie-rod, the measuring vessel 6 and the pressure regulator 7.

The device works as follows.

Gas from the power source is supplied to the inlet fitting of the pressure follower 1 and after leaving its gas chamber through the open valve 2 via the supply line 3 enters consumer 4, while part of the gas flows to consumer 4, and part fills the gas cavity of the separation vessel 5, displace the liquid from it into the measuring vessel 6. In the steady state (at a given value of gas pressure in the supply line 3), the liquid is installed in a certain place of the measuring vessel b. This position of the fluid is determined by the scale of the latter.

In order to determine the gas flow value, the valve 2 is closed. At the same time, the gas supply from the repeater 1 pressure stops, and the gas consumption by consumer 4 continues and the gas pressure in the supply line 3 starts to decrease. If the pressure in the supply line 3 deviates from the setpoint, the pressure regulator will change the pressure in the air part of the measuring vessel of the control chamber of the pressure follower 1. When this happens, the liquid from the measuring vessel b will begin to flow into the separation vessel 5, deflecting the flexible partition and displacing the gas into the supply line 3 and thereby increasing the gas pressure therein to a predetermined value.

The amount of gas consumed in one cycle of operation of the meter is determined on the scale of measuring vessel 6, since the volume of gas consumed

equal to the volume of fluid displaced from the measuring vessel 6.

To measure the average gas flow rate, the stopwatch measures the flow time of the liquid from the measuring vessel 6.

The presence in the proposed gas flow meter of a pressure regulator 7 makes it possible to increase the accuracy of measuring the gas flow rate in a wide range of operating gas pressures.

Claims (2)

1. Kremlevsky P.P. Flowmeters and quantity counters, l., Machino5 Building, 1975, p. 718 / pic. 377378. 2. USSR author's certificate number 436981, cl. G 01 F 11/00, 1972.