SU974132A1 - Inductive level indicator - Google Patents

Description

(54) INDUCTIVE LEVEL

The invention relates to instrumentation, namely, devices for remote control of the level of liquids.

A control device is known comprising a float with a permanent magnet and a transducer for moving the float into an electrical signal installed in the upper part of the control volume C.

The disadvantage of this device is its low sensitivity, due to which it is used only as a level switch.

The closest to the technical essence of the invention is a float gauge comprising a vertical guide tube of a non-magnetic material, a float with: an electromagnetic screen located inside the tube, and a differential transformer installed along the guide of height along the whole measured level 2.

The disadvantages of the known device are low reliability and sensitivity, due to the fact that the windings are directly in the object of CONTROL, can be exposed to the impact of the working phase, which can be aggressive, which determines their low quality factor.

The purpose of the invention is to increase reliability and sensitivity.

This goal is achieved. In the gauge containing a float sensitive element and a transducer for moving the float to an output signal made in the form of an inductor, inside the coil N cores of a soft material are installed parallel to its axis, and the sensitive element is made in the form of N floats different lengths, each of which is conjugated with a metallic CYLIN CYRN from a diamagnetic material and mounted for movement along the axis of the magnetic core.

20

FIG. 1 shows a level gauge with floats located at a minimum level of liquid; FIG. 2 shows a level gauge with 4 floats, Super-1 view of FIG. 3 - level view 25 measure with floats in the upper limit position.

In case 1, made of plastic, on the side wall there is an inductive coil winding30. 2, on top of the case, the base 3 is fixed, which has m holes (for a given N-4 ear) with Mii plastics 4 installed in them. A ferrite core of magnetically strong material 5 is placed in each cup 5. The axes of all cores are parallel to the axis of the sensor coil .

In cross-section, the seolechniki CAN have a ROUND, oval, in a rectangular shape.

A guide rod 6 made of a diamagnetic material is screwed into the bottom of each glass. On each rod there is a float 7 with a metal cyeldrome 8 disengaged in the upper part, made of a diamagnetic material, for example, aluminum.

The sensor winding has a length of 2. From above, the sensor is covered with a protective plastic shell / dry 9. The length of each cylinder 8 is chosen to be 28.

The length of movement of each float is equal. The length of the shortest float L is determined by its lift and can be

The length of each subsequent float is increased by the value of 2, So 1, -L + e; L ,, L, 2 + e I 1.4, etc.

The height of the measured level is H N2, where is the length of the sensor winding,

N is the total number of floats.

The device works as follows.

At the minimum level of liquid, all the floats are in a lower position on the guide rods x 6 and are held by nuts 10.

There are N magnetic ferrite cores in the field of the inductance, which increase the inductance of the coil v / times, where / tc 1. The coil has the maximum inductance. As the fluid level rises, the longest float rises, and a diamagnetic cylinder moves in the coil field, simultaneously shielding its ferrite core. The float rises to the height and abuts the base 3.

The inductive winding of the sensor decreases.

When the liquid level rises, the next float is raised, etc. At the maximum level, m diamagnetic cylinders are inserted in the coil field, which reduce the winding inductance by 10%, i.e. if the coil winding has an inductance LK, then

n, ok - to - i i L, n - to k ° 3 The coefficient of inductance change to

(H I -; fv l f /

where / l - affective Magnitya

core permeability, i.e. This design gives a large change in inductance, which allows to obtain high sensitivity with small coil sizes.

The coil winding is located above the measuring range, protected from environmental influences, which determines the quality and reliability and allows you to measure the inductance with high accuracy.

Claims (2)

1. USSR author's certificate No. 723379, class No. 01R 23/12, 1978. 2. USSR author's certificate 666435, class G 01 F 23/06, 1977 (prototypeJ.