SU1695129A1 - Gas or liquid expense measuring device - Google Patents

Abstract

The invention relates to a measurement technique and can be used, in particular, to measure the flow of liquid and gaseous media. The aim of the invention is to increase the sensitivity of the device. When the medium moves along the knee-shaped nozzle 1 at the pressure take-off holes 2 and 3, a dynamic head is created equal to the difference of the static pressures of points 2 and 3. At these points the static pressures decrease due to centrifugal forces. The total pressure drop characterizes the flow rate. To determine the flow rate for each particular implementation of the nozzle 1, a flow coefficient is entered. The flow rate is recorded through the differential pressure gauge 7 by the computer 8. The flow is recorded if the flow rate is zero. At low speeds of the medium, the flow measurement takes place with the help of a correction unit 6, the sensitive element 5 of which is used as a pressure sensor. 1 il. 7 HHChChchchchch SP with a yu ago th yu

Description

The invention relates to a measurement technique and can be used, in particular, to measure the flow of liquid and gaseous media.

 The purpose of the invention is to increase the sensitivity of the device.

The drawing shows a diagram of the flow meter.

The flow meter contains a knee-shaped nozzle 1, on the inside of which, symmetrically to the plane of the knee's bend, pressure ports 2 and 3 are placed. At the beginning of the outer generatrix, there is a hole 4 in which the sensitive element 5 of the correction unit 6 is mounted perpendicular to the longitudinal axis of the knee. Tubes connected to the differential pressure gauge 7 are connected to the holes 2 and 3. The output of the differential pressure gauge is connected to the first input of the computing device 8, the second input of which is connected to the output of the correction unit 6.

The flow meter works as follows.

When the medium moves along the nozzle 1 in the direction indicated by the arrow, a dynamic pressure equal to the difference of the static pressures of points 2 and 3 is created on the pressure extraction ports 2 and 3. The static pressure is determined by the formulas:

Rst Rst.2 + V PCT.I or

Rst Rst.Z + V Rst.1, (1)

where V PCT.I is the gradient of the static pressure along the length of the knee, and Pct.2.z is the static pressure at 2 and 3 sampling points.

Dynamic pressure is defined as the difference:

9 Rst.2 - Rst.3. (2)

At openings 2 and 3, the static pressures Pst.1 and Pst.2 are reduced by the amount of AP due to centrifugal forces acting on the flow in nozzle 1. The total pressure drop across the openings 2 and 3 PS, characterizing the flow rate Q, is determined by according to the formula

Ps g - Rst. AR + VPCT.I. (3)

Since this pressure drop includes not only pressure drop from centrifugal forces acting on the flow, but also a gradient of static and dynamic pressures along the length of the knee, the value of which depends on the radius, angle of rotation of the knee, etc., for each particular case a flow nozzle to determine the flow rate is entered.

Thus, the flow rate measured by the flow meter is described by the expression

Q а (d - Рст. - А Р + V Рст. |) (4)

and is registered through a differential meter by a computing device.

Flow recording occurs when the flow rate is non-zero, which is indicated by the correction unit.

The flow meter provides an increase in sensitivity when measuring the flow rate of a fluid due to the fact that at low flow rates of the medium, when static pressure sensors become insensitive to the pressure acting on them, flow measurement can be performed using a correction unit, the sensitive element of which is used as dynamic pressure sensor.

Claims (1)

Invention Formula A flow meter comprising an elbow with a pressure tapping hole formed on its inner generatrix and connected to one of the inputs of a differential pressure gauge, characterized in that, in order to increase sensitivity, it is provided with a second pressure tapping hole formed on the internal knee bend and connected to the tube the second input of the differential pressure gauge, as well as the correction unit, the sensitive element of which is installed at the beginning of the elbow, the outputs of the differential pressure gauge and the correction unit are connected the inputs of the computing device, and the pressure ports are made on the nozzle symmetrically to the plane of the knee bend.