SU627384A1 - Pneumohydraulic device for measuring liquid density - Google Patents

Description

one

The invention relates to computational pneumatic-hydraulic devices and can be used in piezometric difference density meters to measure the difference between the variable densities of liquids at several points in a continuous chemical or physical process.

To sum up the air pressures, which are information about any technological parameters, devices using bellows ij are used.

However, they are designed for use in pneumatic automation schemes associated with high pressures (up to 1 kgf / cm) and are unsuitable for accurately summing the small pressures of air that occur in piezometric densitometers.

The closest to the technical essence of the invention is a pneumatic-hydraulic device for measuring the density of a liquid, containing p-geometrical tubes connected by inlets to an air preparation unit, one of the piezometric tubes being connected to a pressure gauge 2.

The aim of the invention is to expand the field of application of the device.

The goal is achieved due to the fact that communicating buffer and measuring vessels of the same diameter and filled to half the height with liquid are installed, the upper cavities of the buffer vessels being connected to. corresponding piezometric tubes, and the upper cavity of the measuring vessel is connected to the atmosphere.

Diagram of the device shown in the drawing.

The device contains an air preparation unit 1, piezometric tubes 2 and 3, hermetic buffer 4 and 5, and measuring b vessels communicating with each other. Vessels 4-6 are filled to half the height of the liquid and have the same diameter. The upper cavity of the measuring vessel is in communication with the atmosphere. A piezometric tube 7 and a pressure gauge 8 also enter the device.

The device works as follows.

Tubes 2 and 3 are overpressure relative to atmospheric air pressure, proportional to the density of liquids. and d, in the supra-fluid spaces of the buffer vessels 4 and 5, such excessive air pressures are established. When the pressures in piezometric tubes 2 and 3 are zero (when air is blown out of the system, which is equivalent to zero density of liquids or their absence), the fluid levels in the buffer and measuring vessels are the same, and the piezometric tube 7 only touches the surface of the fluid in the vessel 6.

The air pressure in the piezometer tube 7 is zero.

When the piezometric tube 3 appears, and, consequently, in the buffer vessel 4, an overpressure of air P; oil from this vessel is displaced into vessels 5 and 6, creating in them a drop in fluid levels that balances the pressure P (. Excess fluid distributes It is equal between vessels 5 and b, i.e. an increase in level in vessels 5 and 6 is two times less than a decrease in level in vessel 4.

The increase in the level of liquid in vessel b will be 1/3 of the total level difference, and the air pressure in the piezometric tube 7 will be

7 V3 P,

When installed in the piezometric tube 2 and in the air pressure vessel 5 PJ, the picture is similar. The increase in pressure in piezometric tube 7 will be

WG 1/3 P

The total air pressure in the piezometer tube 7 and the pressure gauge reading will be

P 1/3 (P + Pj)

If there are three summable pressures, then to implement the summation

three buffer vessels will be required instead of two, and the pressure in the piezometric tube 7 will be

. P 1/4 (P Pg + РЗ) In the general case, for n total pressure, the expression for the value of air pressure in the piezometric tube 7

p.-L (r p; i-f

The measurement range of the differential densitometer can be increased to 2-5 mm, which corresponds to the measurement limits by a difference in density of 0.05-0.010 g / cm (mm with a measurement error i; .0,0004 / c (± 4%. From the range ).

Claims (2)

1.jvtorskoe certificate of the USSR 217721, class G 01 N 9/24, 1969. 2. Glybin IsP, Automatic density meters, Kiev, Technique, 1965, p. 79.