SU1283614A1 - Vibration-frequency type densimeter - Google Patents

Abstract

The invention relates to a measuring technique, namely, vibration-frequency converters, and can be used to measure the density of a fluid flowing through a pipeline. The aim of the invention is to increase the sensitivity and stability of the conversion and reduce the effect of temperature and pressure on the measurement accuracy. The pipe through which the analyzed fluid flows is fixedly fixed at the ends and is a mechanical vibrator. The mass is installed in the center of the pipe, in the place of the antinodes of the first mode and in the node of the second mode of oscillation of the pipes. Electromagnetic receiving transducers located near the antinodes of the second mode of oscillation are connected to the in-phase (summing) input of the excitation amplifier and to the antiphase input of the excitation amplifier. The excitation electromagnet of the first mode is connected to the end of the excitation amplifier, and the output of the excitation amplifier – electromagnets of the second mode of oscillation of the vibrator. The excitation electromagnets are located near the antinodes of the vibrator oscillation mode excited by them. 2 Il. I (rt y 00 oo O)

Description

The invention relates to a measurement technique, namely, vibration frequency transducers, and can be used to measure the density of a fluid flowing through a pipeline.

The aim of the invention is to increase the sensitivity and stability of the conversion and reduce the influence of temperature and pressure on the measurement accuracy.

FIG. 1 schematically shows the proposed device; in fig. 2- two first eigenmodes of oscillation. pipes.

The pipe 1, through which the analyzed fluid flows, is fixedly fixed at the ends and is a mechanical vibrator. Weight 2 set10

and the antiphase input of amplifier 5 only for oscillations of the second mode, therefore both self-oscillatory systems work independently, and pipe 1 simultaneously oscillates on the first and second modes of oscillations with the corresponding resonant frequencies,: oscillating with the mass determining the frequency of natural oscillations, the second mode, is formed from the mass of the pipe and the mass of the liquid filling it. Mass 2 practically does not participate in the oscillations of this mode, since it is located in the oscillation node. But mass 2 oscillates the maximum amplitude in the first oscillation mode and, thus, determines the overwhelming part of the oscillating mass in the first oscillation mode. At the same time, the effect is changed in the center of the pipe, in the place of the beam as the mass density changes

and the antiphase input of amplifier 5 only for oscillations of the second mode, therefore both self-oscillatory systems work independently, and pipe 1 simultaneously oscillates on the first and second modes of oscillations with the corresponding resonant frequencies,: oscillating with the mass determining the frequency of natural oscillations, the second mode, is formed from the mass of the pipe and the mass of the liquid filling it. Mass 2 practically does not participate in the oscillations of this mode, since it is located in the oscillation node. But mass 2 oscillates the maximum amplitude in the first oscillation mode and, thus, determines the overwhelming part of the oscillating mass in the first oscillation mode. At the same time, the influence of the mass

These first forms and in the node of the second waveform of the tube 1. Electromagnetic receiving transducers 3 located near the antinodes of the second mode of oscillation are connected to the in-phase (summing) excitation amplifier 4 and to the antiphase differential input of the excitation amplifier 5. To the output of the excitation amplifier 4 an excitation electromagnet 6 of the first mode 5 is connected to the output of the excitation amplifier 5 — electromagnets 7 are excited, and the second mode of vibration of the vibrator. Excitation electromagnets are located near the antinodes of the vibrator oscillation mode excited by them.

The device works as follows

The tube 1 forms together with variable exciter-VIA converters 3, amplifier 4 a self-oscillating system of the first oscillation mode, and together with receiving converter 3, excitation amplifier 4 and electromagnet 7 excitation of the second vibrator oscillation mode of the second oscillation mode. The induced signals in the receiving transducers with the 3 oscillations of the first mode are in phase, and with the oscillations of the second mode and the pressure for the measurement accuracy, the mode swarm are antiphase. The common-mode vibrator is provided with an additional mass input of the excitation amplifier 4 with a reaction concentrated in the node of one and only draws on the oscillations of the first mode, the antinodes of the other oscillation mode.

fluid to the total mass and, thus, to the oscillation frequency is significantly reduced.

The relative change in the natural frequencies of the first and second modes when exposed to temperature or aging of the vibrator material is the same. Therefore, the ratio of the oscillation frequencies la of the first and second modes does not depend on these changes. Since the relative change in the frequency of oscillation of the vibrator on these modes due to pressure is different, but close in magnitude, the effect of pressure on the reading also decreases significantly.

Claims (1)

Invention Formula Vibration-frequency type density meter containing a tubular vibrator, amplifier, exciter and receiver of mechanical oscillations providing vibrator vibrations in at least two of its own modes, characterized in that, in order to increase the sensitivity and stability of the conversion and reduce the effect of temperature / s. Have FIG. 2 Editor M. Kelemesh Compiled by V. Alekseev Tehred V. Kadar Proofreader and. Muska Order 7430/40 Circulation 776 VNIIPI USSR State Committee for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., 4/5 Phie.1 Subscription