SU636510A1 - Liquid density meter - Google Patents

Description

one

The invention relates to a measurement technique, in particular, to densitometers.

A fluid density meter 1 is known in which the dependences of the natural frequency of torsional vibrations of an elastic-fixed vibrating element immersed in a controlled fluid on the density of this fluid are used.

This densitometer has low sensitivity and low accuracy due to:

the non-sinusoidal nature of the force of interaction of the coil of the electromagnet with permanent magnets rigidly mounted on the rod, due to the variable air gap between them;

an additional moment of inertia of the sensing element, created by the structural elements of the vibration exciter.

The closest in technical essence to the proposed is a vibrating density meter of liquid 2, in which the torsional vibrations of the vibrating element are excited as a result of the interaction of circular and longitudinal magnetic fluxes in a magnetoelastic tubular rod.

A known densitometer contains a torsional-oscillating element with blades mounted on a hollow magnetoelastic rod, excitation windings, a converter of torsional oscillations into a periodic electric signal of induction type and an electronic device. The field windings are mounted perpendicularly perpendicular, with one winding being toroidal and passing through the rod, and the other winding being coaxial and enclosing the rod. The toroidal winding is connected to the DC source, and the coaxial winding is connected to the output of the electronic device.

The torsional vibration transducer into a periodic electric signal contains two permanent magnets, diametrically mounted on the torsion-oscillating element with blades, and two measuring windings wound on cores of a magnet of a soft material fixedly mounted on the body of the vibration meter. The axes of the permanent magnets and measure the spiral windings are mutually perpendicular.

The disadvantage of this subnumber is that the sensitivity is low due to the significant intrinsic moment of inertia of the torsional-vibrating element due to the placement of two permanent magnets on the converter of the torsional-vibrating torsional-vibrating element into a periodic electrical signal.

The purpose of the invention is to increase the sensitivity of the density meter.

The goal is achieved by the fact that a permanent magnet, equipped with a measuring winding, is rigidly installed in the densitometer body perpendicular to the plane of one of the blades, made two-layer, with the layer facing the permanent magnet made of ferromagnetic material.

The drawing shows a diagram of the proposed liquid densitometer.

The fluid meter contains a twisted-oscillating element 1 (for example, a cylinder) with blades fixed to one of the ends of the tubular magnetoelastic rod 2, the other end of which is cantilevered on the base 3. The excitation winding 4 is toroidal. It passes through the tubular rod and is connected to a direct current source. The field winding is coaxial. It covers the magnetically operated tubular rod 2 and is connected to the output of amplifier 6. Constant magnet 7 with the measuring winding 8 wound around the base is fixedly fixed at the base 9, and the axis of the magnet is perpendicular to the plane of the dBuchs layer blades of a torsional-oscillating element. . The layer of the blade of the torsional-oscillating element facing the permanent magnet 7 with the winding 8 is made of a ferromagnetic material, for example, a ferromagnetic foil. The measuring winding 8 is connected to the input of the amplifier 6. The toroidal 4 and the coaxial 5 windings, as well as the permanent magnet 7 with the measuring winding 8, are sealed. Closed sealed cavities are formed by tubes 10-14, bases 3 and 9, and covers 15 and 16. The lead ends of windings 4, 5, 8 pass through connector 17.

The meter number of the liquid works as follows.

The torsional vibrating element 1 of the fluid meter is immersed in a controlled fluid. When the amplifier 6 is turned on in the winding 5, an impulse of current arises, causing the appearance of a longitudinal magnetic flux in the rod 2. In addition to the longitudinal magnetic flux, the rod 2 has a circular magnetic note created by the current of the toroidal winding 4. As a result of the interaction of the circular and longitudinal

is created

magnetic flux in the rod

the resulting helicoidal magnetic flux and, as a result, torsional vibrations appear. The rod 2 in this case will tend to perform torsional vibrations.

with its own frequency. The torsional vibration transducer converts these oscillations into a periodic electric signal due to the changing air gap between the ferro-metallized surface of the torsional-vibrating blade of the element and the stationary magnet 7 with the winding 8. The periodic electric signal is fed to the input of the amplifier 6 feeding the excitation winding 5. Thereby sustained oscillations are maintained.

5 sterols 2, the frequency of which is a measure of the density of the controlled liquid.

Claims (2)

1. The patent of Germany .Nb 1291138, cl. 42 E 1/03. 2. Author's certificate L 356520, cl. G 01 .N 9/10, 970. 15