RU2734061C1 - Method of measuring total electrical resistance of a reinforced layer of articles made from metals using high frequency signals - Google Patents

Abstract

FIELD: quality control of the hardened surface of articles after high-energy treatments.

SUBSTANCE: method consists in measurement of voltage drop on hardened layer with subsequent calculation of total electric resistance as per specified value of electric current force and measured voltage drop, note here that high-frequency signal is used to create required measurement depth, its frequency being calculated proceeding from hardened layer thickness.

EFFECT: technical result is measurement of total electrical resistance of a reinforced layer of articles as an index of quality after processing.

1 cl, 1 dwg

Description

The invention relates to the research area, mainly to a set of measures to study the structure of the hardened surface of products after hardening treatments. It is designed to measure the total electrical resistance over the entire depth of the hardened layer of products, which is an indicator of changes in the structure (change in dispersion, absence or reduction in the number of structural defects) after hardening treatment.

The method can also be used in the field of measuring technology when creating devices for measuring the electrical resistance of a layer of material of arbitrary thickness.

1. Known bridge method for measuring electrical resistance (Fundamentals of metrology and electrical measurements: textbook for universities / B.Ya. Avdeev [and others]; under the general editorship of EM Dushin. - 6th ed., Revised. and additional - Leningrad: Energoatomizdat, 1987. - 480 p.). It is based on the inclusion of the measured resistance in the bridge circuit with the subsequent balancing of this circuit and determination of the unknown resistance by the condition of the balance of the bridge circuit.

Advantage: using this method, you can quite accurately determine the value of resistance in a wide range, in addition, it can be used both on direct current and on alternating current. The disadvantages of this method are that when measuring very low resistances (10-2-10-4 ohms), to ensure the necessary sensitivity of the bridge, very large currents (10-102 A) must be passed through the measured resistance, and when measuring large resistances ( more than 1 MOhm) - increase the voltage on the investigated product to a value of 102-103 V, which limits the scope of its application.

2. There is a known method for measuring electrical resistance (Patent RU 2137144 C1, G01R 27/00, publ. 09/10/1999), which consists in the fact that an electric current is passed through the measured resistance, after which the first measurement of the magnitude of the current and the voltage drop across the measured resistance , and their values determine the first resistance value; after the first measurement, the value of the current passing through the measured resistance is changed by connecting an additional resistance in series with the measured resistance, then the second measurement of the current value and the voltage drop across the measured resistance is performed and the second resistance value is determined from their values, and the measured resistance is determined by the given formula taking into account the values internal resistance of a resistance measuring device without additional resistance. The technical result consists in expanding the functionality of the known method.

The advantages of this method are: simplicity, good measurement accuracy and low implementation costs. The disadvantage of this method is the impossibility of determining the electrical resistance of the hardened surface layer of the material, which is an indicator of the quality of high-energy processing of metal products.

A known method for determining the electrical resistivity of the surface layer of the material (Patent RU 2426137 C1, G01R 27/16, publ. 08/10/2011, bull. No. 22), including measuring the electrical resistance of the contact of the surface layer of the material with a metal plate by the ammeter-voltmeter method, characterized by that additionally measure the pressing force of the surface layer of the material to the metal plate in contact, the roughness parameter and the hardness of the surface layer of the material, and determine the resistivity of the surface layer of the material according to the derived formula.

The advantage of this method is the ability to determine the surface quality after machining with high accuracy. The main disadvantage of this method is that the electrical resistance depends on the state of the surface (roughness), which does not allow talking about the quality of the hardened layer and the value of the total electrical resistance along the entire length of the product.

The above known methods are analogs of the present invention.

The closest way to measure electrical resistance is a method based on the ammeter-voltmeter method (Patent RU 2167392 C2, G01R 27/16, G01B 7/06, publ. 20.05.2001) and implemented using a housing made of dielectric material , in which two conductive electrodes and two measuring electrodes are installed, a cover made of dielectric material fixed to the body with screws, terminals, return springs and clamps, fixed to the body by screws. The technical result of the invention is to improve the accuracy of measuring the thickness of the surface conductive layer of the product. The connection of the device implemented according to this method is carried out from a direct current source, for example, a constant power source B5-47, through a rheostat R, a millivoltmeter, which can be used as an M 1202 device, a set of switches P ₁ , a reference rheostat R _e to the current supply electrodes. From the measuring electrodes through the P ₂ packet switch, the voltage is supplied to the constant current potentiometer.

The advantages of the considered method are: 1) ease of measuring the thickness of the conductive layer; 2) high contact rigidity of the connection of the measuring electrodes with the investigated surface. The disadvantages of this method are: 1) the impossibility of measuring the electrical resistance of the hardened layer of arbitrary thickness, since the measurement is carried out on direct current; 2) it is required to manufacture special installations-holders with strict dielectric isolation of four contacts; 3) limitations in determining the voltage drop at a depth of up to tenths of a millimeter, although the hardened layer of products after high-energy processing starts from a few micrometers.

Thus, the principle of measuring the voltage drop on the hardened surface layer with the possibility of calculating the electrical resistance (according to the known value of the current) gives the right to choose the used technique as a prototype.

Solved by the proposed invention, the technical problem is to measure the total electrical resistance throughout the depth of the hardened layer of products, which is an indicator of changes in structure (change in dispersion, absence or reduction in the number of structural defects) after hardening treatment.

The technical problem is solved by measuring the voltage drop on the hardened layer with the subsequent calculation of the total electrical resistance (directly proportional value) for a given value of the electric current, and during the measurement, a high-frequency alternating current probe signal is used, and for the measurement process, a parallel circuit for connecting the test sample to measuring circuit.

To implement the proposed measurement method, it is necessary to use a high frequency signal generator. When a high frequency voltage is applied to an electrically conductive article, the areas located inside the conductor will have a high inductive resistance. This phenomenon is known as skin effect. As a result of this effect, the alternating current of high frequency, when flowing through the conductor, is not distributed evenly over the section, but mainly in the surface layer. Since during hardening processing (magnetic-pulse, cold deformation, heat treatment, etc.), it is precisely the layers of the product close to the surface that are affected, in which the metal structure changes (dispersion changes, defects are eliminated, residual stresses are removed), then the change in the resistance of the surface layer of the product will indicate a change in the structure of the material near the surface. So, with an increase in dispersion (the number of grain boundaries increases), the electrical resistance increases, and with the elimination of defects and the removal of residual stresses (the homogeneity of the conductor improves), the electrical resistance decreases. Thus, it is possible to determine the correlation between the change in resistance and the change in the structure of the near-surface layers.

To implement the proposed method for measuring the total electrical resistance of a hardened layer of metal products using high frequency signals, it is proposed to use a parallel circuit for connecting the investigated product to the measuring circuit.

FIG. 1 shows a parallel circuit for connecting the product to the measuring circuit. It contains one RF signal generator, two ring contacts, one oscilloscope with a bandwidth that satisfies the 3: 1 frequency of the probing signal, a stabilizing resistor (50 ohms), a shunt resistor (5-10 ohms).

The following designations are introduced on the diagram: 1 - High frequency generator; 2 - oscilloscope; 3 - investigated product; 4 - ring contacts-clamps; 5 - stabilizing resistor; 6 - shunt resistor.

The signal output of the generator 1 is connected to the first terminal of the stabilizing resistor 5, which by its second terminal is connected to the first terminal of the shunt resistor 6, the first ring contact 4 and the signal input of the oscilloscope 2, the latter, in turn, is connected by its common wire to the second ring contact 4, the second terminal of the shunt resistor 6 and the common wire of the generator 1. The product 3 is connected with its ends between the first and second ring contacts 4.

Algorithm for measuring electrical resistance in a parallel circuit of connecting the product to the measuring circuit.

To obtain the total electrical resistance of the hardened layer of the product, it is necessary to measure the voltage drop across the product when a high-frequency signal passes. The selected frequency should provide a signal penetration depth corresponding to the thickness of the hardened layer:

where Δ is the thickness of the hardened layer (skin layer);

ρ is the resistivity of the workpiece material;

μ _r is the relative magnetic permeability;

ƒ - signal frequency.

When connected in parallel, before taking measurements on a hardened product, it is necessary to obtain a control oscillogram of the high-frequency signal voltage without installing the product into the measuring circuit and fix the amplitude value of the voltage of the impedance of the shunt resistor (U _{w full} ). According to the obtained value (U _{w full} ) using a given value of the current strength (I _z ) of the probing signal, it is necessary to calculate the total resistance of the shunt resistor:

Then it is necessary to install the product in the measuring circuit and make a repeated measurement with fixing the amplitude value of the voltage drop (U _and ) on the parallel connected shunt resistance and the tested product. Since the parallel connection, the U _and expressed by the formula:

wherein R _{is full} - the total electric resistance of the hardened product layer.

Then, at a given current value (I _s ) and expressing R _full from (3), the total electrical resistance of the hardened layer of the product is calculated:

Or given (2):

If, according to this algorithm, the total electrical resistance is measured before and after processing the product, then the information obtained indicates a change in the structure of the hardened layer (uniformity, fine dispersion, no curvature of the crystal lattice), which directly affects the value of the total electrical resistance.

Measurement principle with a parallel circuit of connecting the product to the measuring circuit.

Before starting to measure the resistance of the hardened layer of the product, a control recording of the high-frequency signal voltage oscillogram is performed (without installing the product). The probing signal is selected with a frequency that provides penetration to a depth equal to the thickness of the hardened layer of the product (formula 1). The signal output of the generator 1 is connected through a stabilizing resistor 5 (50 Ohm), which ensures the stability of the generation frequency (with such a measuring circuit scheme), to the first terminal of the shunt resistor 6 (5-10 Ohm), to which the oscilloscope 2 is connected in parallel. the value of the voltage drop across the full resistance of the shunt resistor (U _{w full} ).

Then the processed product 3 is installed in the ring contacts 4. The signal from the generator 1 through the stabilizing resistor 5 is fed to the parallel connection of the shunt resistor 6 and the test item 3 connected through the ring contacts 4. The signal passes through the parallel connection of elements 3 and 6 to the common wire. Oscilloscope 2 connected in parallel 3 and 6 makes it possible to measure the amplitude values of the voltage drop across the parallel shunt resistor 6 and the test item 3 (U _and ). Since the signal is high-frequency and the frequency is calculated taking into account the thickness of the hardened layer, the signal flows only through the required depth (skin effect appears). With the given value of the signal current (I _s ) of the generator 1, the impedance is calculated according to the formula 5.

The use of high-frequency alternating current in the proposed method for measuring the total electrical resistance of the hardened layer of products after hardening treatments, allows you to adjust the corresponding measuring devices for any thickness of the hardened layer.

Claims (5)

A method for measuring the total electrical resistance of a hardened layer of products made of conductive materials as an indicator of changes in the structure of the material after hardening treatments, which consists in measuring the voltage drop across the hardened layer with the subsequent calculation of the total electrical resistance for a given value of the electric current and the measured voltage drop, characterized in that to create the required depth of measurement, a high-frequency signal is used, the frequency of which

determined from the expression:

where ρ is the specific electrical resistance; Δ is the thickness of the hardened layer; μ _r is the relative magnetic permeability.

Images