SU1259103A1 - Method for measuring cross-sectional geometry of continuous articles - Google Patents

Abstract

The invention relates to a measurement technique and makes it possible to improve the accuracy of the method for measuring the geometric parameters of the cross section of long objects, consisting in measuring the ohmic resistance of two sections of a test object of different lengths when placed in an electrolytic neutral cell and making electrical contact between the measuring electrodes of the cell. and in these areas and in the subsequent measurement after disconnecting the supply of electrolyte jets of electrical capacity ol-polarized electrolyte layers on the boundary of the object. Based on the measurement results, the geometrical parameters of the object are calculated taking into account the specific capacity of the polarized electrolyte layers. 1 il. i (L

Description

The invention relates to a measuring technique and can be used in the metallurgical and radio engineering industry to control the parameters of the cross section of wire, tubes of small sizes, tapes, etc.

The aim of the invention is to improve the accuracy of measuring the geometric parameters of the cross section of long objects, determined by the values of the ohmic resistance of two sections of different lengths of the test object, placed between the electrodes of the electrochemical cell, and

the electrical capacitance of the polarized electrolyte layers at the boundary with the object due to the elimination of the instability effect of the specific capacitance of the polarized electrolyte layers due to its contamination and the electrical contact of the object with the electrochemical cells during the measurement of the ohmic resistance.

The drawing shows a diagram of the implementation of the method.

The circuit contains an electrochemical cell 1 with measuring electrodes 2-4 placed in it, between which a controlled long-dimensional object is drawn. The electrochemical cell 1 is filled with a neutral electrolyte, for example a 5% solution, and is equipped with means for supplying 5 and discharging 6 jets 7 of electrolyte to the zones where the measuring electrodes are located. The controlled areas 8 and 9 of a long object are located between the measuring electrodes 2-4 of the electrochemical cell and have a different length of 6 and g, respectively.

A section 10 of an object with a length of .1 located in the zone, for example, of: electrode 2, is used to measure the electrical capacitance C of a polarized electrolyte layer at its boundary with the object after stopping the supply of a jet of electrolyte between it; and this electrode. The impedance meter 11 is connected to the electrodes 2-4 of the electrochemical cell 1.

The method is carried out as follows.

ten

15

1259103

After placing the monitored object in the electrochemical cell

1, jets 7 of electrolyte are delivered to the locations of the measuring electrodes 2-4 and using the impedance meter 11 to determine the ohmic resistance R between electrodes 2 and 3 in the area 8 of the object having a length of 6, and ohmic resistance R between the electrodes

3 and 4 cells in section 9, having a length of Bj. Electrolyte jets 7 form fixed zones under the electrodes, which ensure electrical contact of the controlled areas of the object with these electrodes. From the difference between the measured resistances R, and Rj, the value of the ohmic resistance of the object in its section is calculated: 8 6 | -Bj, which is equal to R R, after which, based on Ohm's law, an area of 5 is calculated, the cross section of the INN object. Then stop the flow of the electrolyte between the electrode

2 and section 10 of the object to be monitored, and the capacitance C between this electrode and the indicated part of the object is measured by means of a meter 11. Using the Rbeaudates of measurements R, on site 8, С

on section 10 and calculation of I on section 6 (- Bj, calculate ohmic resistance 1, layer of electric; litas between electrode 2 and section 10

20

25

thirty

35

Kat

R, R .B,

lay

40

v. e,

and resistivity p electrolyte - about

with to and

.., 0

where „8,83-10-H / m.

The obtained values of Rt Rl

45

50

With the known geometric shape of the electrode 2 of the electrochemical cell, it is possible to calculate, based on Ohm's law, the area Sj of the lateral surface of the object in its area 10 with a length of 2.

The obtained values of areas 5, and Sg of the cross section and the lateral surface of the object on its section of known length can be calculated using known formulas corresponding to the geometric shape of the object being monitored, such cross-section parameters as, for example, the diameter and ovality of the wire or rod , indoor and outdoor

on section 10 and calculation of I on section 6 (- Bj, calculate ohmic resistance 1, layer of electric; litas between electrode 2 and section 10

five

Kat

R, R .B,

lay

0

v. e,

and resistivity p electrolyte - about

with to and

.., 0

where „8,83-10-H / m.

The obtained values of Rt Rl

five

0

With the known geometric shape of the electrode 2 of the electrochemical cell, it is possible to calculate, based on Ohm's law, the area Sj of the lateral surface of the object in its area 10 with a length of 2.

The obtained values of areas 5, and Sg of the cross section and the lateral surface of the object on its section of known length allow to calculate, using known formulas corresponding to the geometric shape of the object being monitored, such cross-section parameters as, for example, the diameter and ovality of the wire or rod , indoor and outdoor

3

diameter and thickness - tube walls, longitudinal thickness variation, etc.

The creation of an electrical contact of a controlled object with measuring electrodes using electrolyte jets allows the use of a simpler electrochemical cell without separate compartments where the controlled object must enter through the holes. The electrolyte line forms a fixed zone where the controlled object is electrically contacted with the electrode. Thus, the actions associated with bringing the monitored object into electrical contact with the electrode are greatly simplified, since now they consist only in placing the monitored object in a jet or several electrolyte jets. At the same time, it is not necessary to periodically charge the electrochemical cell with electrolyte and control his condition that Cheaper process technology.

ten

2591034

Claims (1)

By taking into account the specific capacitance of the polarized electrolyte layers, the accuracy of the control of geometric parameters is increased compared to 5 with a known method, amounting to about 1%. Invention Formula A method for measuring the geometrical parameters of the cross section of long objects, namely, measuring the ohmic resistance of two sections of different length of an object enclosed between the electrodes of an electrochemical cell, and the electrical capacitance between the electrodes of this cell and the object, and calculating the geometric parameters from the measurement results that differ the fact that, in order to increase accuracy, the measurement of the ohmic resistance is carried out while ensuring electrical contact between the controlled participants the object’s strings and electrodes with the help of electrolyte jets supplied between them, and the measurement of the electrical capacitance is carried out after the supply of the electrolyte jet is stopped. f5 20 25 Ш 6 Editor I. Shulla Compiled by S. Skrypnik Tehred I. Popovich Order 5112/39 Circulation 670 Subscription VNIIPI USSR State Committee for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., 4/5 Production and printing company, Uzhgorod, st. Project, 4 Proofreader T. Kolb