SU404034A1 - B - Google Patents

Description

one

The invention relates to a pattern recognition technique based on resonant measurements of the electrical and magnetic properties of media, such as rocks, and can be used to expressly determine the quality of ores in the pieces and the mass.

The known device contains autogenerating measuring cells, sets of triggers and indicator diodes.

However, the known device has a narrow recognition range and a lack of accuracy in the recognition of heterogeneous anisotropic media.

The aim of the invention is to expand the range of recognition and improve the recognition accuracy of anisotropic media and media with complex surface relief.

For this, between the output circuits of autogenerating measuring cells, separated from each other by a screen having a circle shape in cross section divided into five sectors, and trigger inputs are switched off log-rhyme detectors, overhead sensors are made movable, protruding, beyond the surface the enclosures of the device and are located around the circumference in such a way that the sensors with the maximum difference in frequency are adjacent.

The invention is illustrated in the drawings.

FIG. 1 shows a block diagram of the device; in fig. 2 - external view of the device; in fig. 3 is a section along A-A in FIG. 2

The device contains (Fig. 1) autogenerating measuring cells 1, 2, 3, assembled in a single-circuit with sensors 4 in the form of overhead-coils for measuring electrical conductivity and media at three discrete points of the frequency range - 0.88 MHz,

5.28 MHz and 40.68 MHz, respectively, an autogenerating measuring cell 5 assembled by a dual-circuit BO, with a sensor 6 made in the form of a coil on an open-magnetic conductor for measuring magnetic permeability c, an auto-generating measuring cell 7, assembled by a dual-circuit, the sensor 8, made in the form of a surface capacitor for measuring the dielectric constant e, logarithmic

the detectors 9, the triggers 10, the LEDs II, and the reset device 12. In the nearest area of the sensors is recognizable environment 13.

The device contains a cylindrical body

14 (Fig. 2 and 3), sensors 15 protruding above the upper surface, screen 16, handle 17, in which the sources of pitapi are located, measuring blocks 18, spring 19, blo: K 20, in which the trigger circuits are located, nano 21, cover 22.

The design of the device is portable. The circumferential measuring units 18 comprise autogenerating measuring cells 7, logarithmic detectors 9 and sensors 15; the measuring units 18 are supported by a spring 19 and are divided among themselves by a screen 16, having a cross-sectional shape divided into five sectors; The LEDs 11 (Fig. 1) are located on the panel 21 and are closed with a cover 22.

Before starting the measurements, the output signals of the measuring cells correspond to the level. When the device is brought up by sensors 4 to a recognizable medium 13 due to the free running of the measuring units 18, all the sensors will adjoin to the surface. The levels of the output signals of the measuring cells I, 2, 3, 5.7 (Fig. 1) depend on the electrical and magnetic properties of the recognized medium 13. Each set of triggers 10 connected through a logarithmic detector 9 to the output circuits from the measuring cells I, 2, 3, 5, 7 is set to five: different levels of operation depending on the magnitude of the signals. Therefore, in the output circuits of each measuring channel, the corresponding number of indicator diodes is illuminated and one of the 3125 five-digit pixel codes is displayed on the panel 211 (Fig. 3).

Comparison of the obtained code with a generalized portrait in the form of a field of numerical codes obtained as a result of preliminary training (static processing) allows one to recognize a controlled heterogeneous environment.

Subject invention

A device for detecting electrical and magnetic properties of a medium, such as a rock, based on self-oscillating resonant measurements, containing three auto-oscillating measurement cells with overlapping induction sensors to monitor the electrical conductivity of the medium at discrete points in the frequency range, an autogenerator cell with an overhead sensor in

a coil with an open magnetic circuit for monitoring the magnetic permeability of media, an autogenerator cell with an overlaid capacitive sensor for monitoring the dielectric permeability of the media, as well as a block of flip-flops and light-emitting diodes, in order to widen the recognition range and improve recognition accuracy between the output circuits self-measuring measuring cells separated from each other by a screen that has a circle shape divided into five sectors in cross section and the inputs of the flip-flops are logarithmic The treads, overhead sensors are made movable, protruding beyond the surface of the device body, and are arranged around the circumference so that the sensors with the maximum difference in frequency are adjacent.