SU1569557A2 - Apparatus for measuring consumption of suspension in flow of liquid or gas - Google Patents

Abstract

The invention relates to the field of measurement technology and can be used in studies of the hydromechanics of two-phase flows. The aim of the invention is to improve the measurement accuracy due to the precise orientation of the sampling tube towards the flow. After the device is installed in the flow, the inlet of the intake tube 1 is pre-oriented towards the flow. To do this, static pressures are made in opposite to the axis of the annular gap between the tubes 1.2 in the tube 1 which is opposite to the axis of tube 1. Controlling the pressure drop in the corresponding pair of cavities with the differential pressure gauges 8.9, turns the axis of the tubes 1,2,3 in two planes to eliminate the pressure difference. After the exact orientation of the axis of the intake tube, a vacuum source of the sample suction system is turned on, by adjusting the suction intensity using a gas flow rate reducer 11, a differential pressure meter 10 is set to zero. Continuously sampled two-phase medium enters the cyclone 12, from where the gas phase is sucked through the gas inductive micro-flow meter 13 and the reduction gear 11, and the solid phase is collected in the accumulator 14. At equal intervals of time, the solid phase is poured from the accumulator 14 into the torsion balance cups 15, output signals proportional to the mass of the solid phase and the volume of pure gas are transferred from the balance 15 and the microaccumulator 13 to the indicator device 16. 2 Il.

Description

The invention relates to a measurement technique, can be used in studies of two-phase flow mechanics and is an improvement of the invention according to the author. -N 877333.

The aim of the invention is to improve the measurement accuracy due to the precise orientation of the device inlet tube towards the flow.

Figure 1 shows the proposed device; FIG. 2 is a section A-A in FIG. 1. FIG.

The device contains three concentric tubes 1-3, connected to each other at the ends tightly and motionless. In the wall of the outer sampling tube 1, holes 4 are evenly spaced around the circumference at a distance less than one diameter of this tube from its inlet. In the wall of the outer tube 3, at a distance of not less than three diameters of this tube from its end, on the side of the inlet of the intake tube, there are holes 5, also evenly spaced around the circumference. In the annular cavity between the outer and middle tubes, in two mutually perpendicular diametrical planes inclined to the vertical axis of symmetry of the device at an angle of 45, the longitudinal flat partitions 6 are hermetically and stationary along the entire length of tubes 2 and 3. The cavities, formed by partitions and walls of tubes 2 and 3, which are located opposite to the longitudinal axis of the device, are connected in pairs by tubes 7 to the cavities of membrane differential pressure gauges 8 and 9. One of these cavities is also connected in parallel about with membrane membrane hollow

0

five

about o 5 o

five

gauge 10 of the system for controlling the intensity of suction of samples from the stream. The other cavity of the differential pressure gauge 10 is connected to the annular cavity between the tubes 1 and 2 of the device.

The outlet of the intake tube 1 is connected to a sample suction system, part of which i is schematically shown in FIG. This system includes a gas flow reducer 11, a cyclone 12, an inductive micro gas flow meter 13, a solid phase accumulator 14, an automatic solid phase torsion balance 15, and an indicator device 1 6.

The device works as follows.

After installing device E, the flow of the two-phase medium is pre-orienting the inlet of the sampling tube 1 towards the flow, and using differential gauges 8 and 9, the static pressures are matched in pairs opposite to the cavity of the annular gap between the tubes 1 and 2 relative to the axis of tube 1. With oblique flow around the tubes 1-3, due to the presence of an angle of attack between the axis of the sampling tube 1 and the velocity vector of the incident flow, 1 violation of the symmetry of the static distribution occurs. pressure across the outer surface of the tube 3. The corresponding misalignment of pressures in the cavities of the annular gap between tubes 1 and 2 is fixed by differential pressure gauges 8 and 9, by controlling the pressure drop in the corresponding pair of cavities by differential pressure gauges 8 and 9, two planes to eliminate the difference davlekly. The coincidence of the signals from the pressures in the corresponding pair of cavities leads to a zero reading of the differential pressure gauge, which corresponds to the same flow conditions oppositely located on the outer portions of the outer surface of the tube 3. Such successive actions achieve the symmetry of the flow around the intake device, i.e. coincidence of the axis of the intake tube 1 and the velocity vector of the incident flow. This eliminates measurement errors associated with inaccuracy in the orientation of the axis of the intake tube with respect to the flow of a two-phase medium,

After the exact orientation of the intake tube axis, a vacuum source of the sample suction system is turned on. Regulating the intensity of the suction using a gas flow reducer 11, set the reading of the differential pressure gauge 10 to zero. This means that the static pressure of the sample flow inside the intake tube 1 is equal to the static pressure in the flow outside the device, i.e. The condition of isokinetic sampling is observed.

A continuously selected two-phase medium enters the cyclone 12, from where the gas phase is sucked through the injection

a 3 Gzta microcirculation meter and a gearbox 11, and a solid veil is collected in the accumulator 14. Periodically, at regular intervals, the solid phase is poured over the accumulator

14c automatic torsion balance cups 15. Output signals proportional to the mass of the solid phase and the volume of pure gas are transmitted from the balance.

15 and microcontroller 13 on the display device 16.

Claims (1)

Invention Formula A device for measuring the flow / suspension in liquid flows or i aza according to avt.S. No. 877333, characterized in that, in order to improve measurement accuracy, in the annular cavity between the outer and middle tubes, hermetically and stationary longitudinal flat partitions are installed in two mutually perpendicular 5 diametrical flat kx the formation of four closed cavities, while the cavities located opposite to the longitudinal axis of the device are connected in pairs with the inputs of the corresponding differential pressure gauges. Compiled by T.Sergeeva Editor And, Gorna Tehred L. Serdyukova Proofreader M.Sharoshi Order 1436 Circulation 551 VNIIPI State Committee for Invention and Discovery at the State Committee for Science and Technology of the USSR 4/5, Moscow, Zh-35, Raushsk nab. 113035 Figg Subscription