RU2766423C1 - Apparatus for recording the position and sizes of small-sized metal inclusions in articles made of non-conductive materials - Google Patents

Abstract

FIELD: testing.

SUBSTANCE: invention relates to non-destructive testing methods for recording the position and measuring the size of small-sized metal inclusions (SMI). The apparatus for recording the position and sizes of small-sized metal inclusions in articles made of non-conductive materials is equipped with an additional eddy-current transducer identical to the first eddy-current transducer, the outputs of the measuring coils whereof are connected with the corresponding inputs of the first switch, and is equipped with an additional switch, the first and second outputs whereof are connected with the corresponding inputs of the eddy-current transducers, which are the inputs of the exciting coils, and the input of the additional switch is connected with the output of the harmonic oscillation generator, wherein an algorithm for determining the position and sizes of small-sized metal inclusions is implemented in the microprocessor by recording the values of the signals of maximum inserted voltage U_max and minimum inserted voltage U_min and comparing said values with values from a set of planes of state in the memory of the microprocessor.

EFFECT: increase in the efficiency of monitoring due to the recorded position and measured sizes of SMI.

1 cl, 6 dwg, 1 tbl

Description

The invention relates to non-destructive testing methods for fixing the position and measuring the size of small-sized metal inclusions (MMI) with sizes from 0.1 to 2 mm in products made of non-conductive materials, in particular polymer composite materials (PCM), and can be used in food, textile , pharmaceutical industries.

Known metal detector (patent RU No. 2366982, IPC G01V 3/11, publ. 10.09.2009, bull. No. 25), designed to detect metal objects in various environments, containing an induction transducer, consisting of two resonant circuits, including respectively radiating and partially receiving coil overlapping it, balancing circuits, three amplifiers, a synchronous detector and an indicator, and the output of the induction converter, the first amplifier and the input of the first synchronous detector, the fourth amplifier, the second synchronous detector, a two-channel analog-to-digital converter and a microprocessor are connected in series, the first output of the microprocessor is connected in series connected to the second amplifier and the input of the induction converter, the second and third outputs, respectively, to the reference inputs of the synchronous detectors, connected by the outputs, respectively, to the third and fourth amplifiers, connected by the outputs to the inputs of the two-channel analog-to-digital converter connected to microprocessor connected to the indicator, the input of the second synchronous detector is connected to the output of the first amplifier.

The disadvantage of this technical solution is the fixation of the presence of only large objects (weapons, gold jewelry, etc.), as well as the low accuracy of determining the position of the object.

The closest in technical essence to the proposed invention is a device for determining the position of small-sized metal inclusions in products made of composite materials (patent RU No. 2710080, IPC G01V 3/11, G01N 27/82, publ. 24.12.2019, bull. No. 3) , including amplifiers, synchronous detectors, a two-channel analog-to-digital converter, a processing unit, an indicator and an induction converter, a switch is connected between the induction converter and the first amplifier. The inductive transducer includes an exciting inductance coil and measuring inductance coils.

The disadvantage of this technical solution is the low information content of the control, and, as a result, its low efficiency.

The technical objective of the invention is to increase the information content of the detection of MMW in non-conductive objects.

The technical result consists in increasing the efficiency of control by fixing the position and measuring the dimensions of the MMV.

This is achieved by the fact that the device for fixing the position and dimensions of small-sized metal inclusions in products made of non-conductive materials, containing a generator of harmonic oscillations, a processing unit connected in series with the microprocessor and the results presentation unit, the first eddy current transducer, including measuring coils, the outputs of which are connected to the corresponding the inputs of the first switch, which is connected to the processing unit with its output, and the exciting coil, is equipped with an additional eddy current transducer, identical to the first eddy current transducer, the outputs of the measuring coils of which are connected to the corresponding inputs of the first switch, and is equipped with an additional switch, the first and second outputs of which are connected to the corresponding inputs of eddy current transducers, which are the inputs of the excitation coils, and the input of the additional switch is connected to the output of the generator of harmonic oscillations, while the mic The roprocessor implements an algorithm for determining the position and size of small-sized metal inclusions by fixing the signal values of the maximum input voltage U _max and the minimum input voltage U _min and comparing them with the values from the set of state planes stored in the microprocessor memory.

The essence of the invention is illustrated by drawings, where in Fig. 1 shows a block diagram of a device for fixing the position and size of small-sized metal inclusions in products made of non-conductive materials; Fig. 2 is a block diagram of eddy current transducers, in Fig. 3 - the position of the eddy current transducers relative to the controlled product, in Fig. 4 is a graph of the change in the modulus of the introduced voltage during the movement of an object in the form of a ball with a radius of 0.29 mm along the X axis with a fixed depth h=1 mm, in Fig. 5 - shows the state plane (for balls with a radius of 0.29 1 mm, at a depth h=1÷4 mm; Fig. 6 - image of the entire controlled product with located inclusions.

The transducer device 2 and an additional second eddy current transducer 3, fixing the position and size of small-sized metal inclusions in products made of non-conductive materials, contains a harmonic oscillation generator 1, the first eddy current generator connected through a switch 4 with a processing unit 5, to which a microprocessor 6 and a results presentation unit 7 are connected in series The inputs of the first eddy current transducer 2 and the additional second eddy current transducer 3 are connected to the generator of harmonic oscillations 1 through the corresponding first and second outputs of the additional switch 8.

где Т_ОК - толщина контролируемого изделия 13.The first eddy current transducer 2 is made in the form of an exciting coil (L ₁ ) - 9 and measuring coils (L ₁₁ , L ₁₂ , ... L _1n ) 10.1, 10.2, ... 10.n, and an additional second eddy current transducer 3 is also made in the form driving coil (L ₂ ) - 11 and measuring coils (L ₂₁ , L ₂₂ , ..., L _2n ) - 12.1, 12.2, ... 12.n, where n is an integer, n≥1. The inputs of the exciting coils 9 and 11 are the inputs of the respective eddy current transducers 2 and 3, and the outputs of the measuring coils 10.1-10.n and 12.1-12.n are the outputs of the respective eddy current transducers 2 and 3. In this case, the measuring coils 10.1-10.n and 12.1 -12.n are located inside the respective excitation coils 9 and 11. The eddy current transducers 2 and 3 are made with the possibility of consonant or counter switching by means of an additional switch 8. The radius of the exciting coils 9 and 11 of the eddy current transducers 2 and 3 R _B is selected from the condition

where T _OK is the thickness of the controlled product 13.

The device for fixing the position and size of small-sized metal inclusions in products made of non-conductive materials works as follows.

The generator of harmonic oscillations 1 generates signals through an additional switch 8 to eddy current transducers 2 and 3. Eddy current transducers 2 and 3 are located coaxially on the upper and lower parallel surfaces of the controlled product 13, the measuring coils 10.1-10.n and 12.1-12.n are connected in opposite directions, in this case, in the processing unit 5, signals of only eddy currents (introduced voltage) are recorded. The signals of the measuring coils 10.1-10.n and 12.1-12.n (introduced voltage) are measured continuously and when scanning the controlled product 13 (with their mutual displacement), the maximum (U _max ) and minimum (U _min ) signal values are recorded. The microprocessor 6 analyzes the signals of all measuring coils 10.1-10.n and 12.1-12.n, for each of them in the memory of the microprocessor 6 there is a set of state planes built on the basis of experimental data or by modeling a two-coordinate calibration grid in the axes U _max - U _min for the entire range of change in the size of inclusions and their depth in the controlled product 13 from the plane of location of the eddy current transducers 2 and 3, the number and size of conductive inclusions and their location inside the controlled product 13 are determined.

At each moment of time, the result presentation unit 7 forms an image of the control zone of the controlled product 13, for example, in the form of a transparent luminous rectangular parallelepiped (or in the form of another form of the controlled product 13), which displays inclusions in accordance with their coordinates and sizes. The number and size of inclusions are displayed, while inclusions of different sizes can be displayed in different colors.

If a particle, for example, an inclusion in the form of a ball with a radius of 0.29 mm, moves to a distance (depth of occurrence) h=1 mm from the plane of location of the eddy current transducer 2 or 3 when scanning the surface of the controlled product 13, then the magnitude of the change in the signal of one of the measuring coils 10.1 -10.n or 121-12.n is changed as shown in FIG. 4. In this case, the shape of the curve can be characterized by the values of the maximum input voltage U _max and the minimum input voltage U _min .

On a plane with a coordinate system U _max and U _min , the curve in Fig. 4 will be displayed as point A (Fig. 5). If points for other values of inclusion diameters and occurrence depth h are set aside on this plane, then a state plane will be obtained, that is, a two-dimensional calibration area. If an unknown inclusion is displayed on the plane of Fig. 5, point B, then using a linear approximation, we obtain h _B =3.45 mm (radius of inclusion (ball) 0.81 mm).

It has been experimentally proven that the error in measuring the position and size of small-sized metal inclusions in products made of non-conductive materials by a device for fixing the position and size in determining the size of inclusions is ~10%, fixing the position is up to 20% (Table 1).

The use of a device for fixing the position and size of small-sized metal inclusions in products made of non-conductive materials increases the efficiency of control by simultaneously fixing the position and determining the size of the MMW.

Claims (1)

A device for fixing the position and dimensions of small-sized metal inclusions in products made of non-conductive materials, containing a generator of harmonic oscillations, a processing unit connected in series with a microprocessor and a unit for presenting results, the first eddy current transducer, which includes measuring coils, the outputs of which are connected to the corresponding inputs of the first switch, which is connected by its output to the processing unit, and an excitation coil, characterized in that it is equipped with an additional eddy current transducer identical to the first eddy current transducer, the outputs of the measuring coils of which are connected to the corresponding inputs of the first switch, and is equipped with an additional switch, the first and second outputs of which are connected to the corresponding inputs of eddy current transducers, which are the inputs of the excitation coils, and the input of the additional switch is connected to the output of the generator of harmonic oscillations, while in the micro The processor implements an algorithm for determining the position and size of small-sized metal inclusions by fixing the signal values of the maximum input voltage U _max and the minimum input voltage U _min and comparing them with the values from the set of state planes stored in the microprocessor memory.

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