SU789940A1 - Coersive force measuring method - Google Patents

Description

The invention relates to non-destructive methods of product quality control based on measurements of coercive force, and can be used to control the quality of heat treatment of ferromagnetic products. ⁵

A known method of measuring coercive force, which consists in the fact that the test portion of the sample is magnetized to saturation. Then, the magnetizing current is turned off and the demagnetizing current is turned on. The magnitude of the demagnetizing current is a measure of the coercive force of the test site is figurative [1].

The disadvantages of this method are the complexity of the method and the limited scope.

The closest in technical essence and the achieved result is a method of measuring coercive force _Μ by the magnitude of the demagnetizing current.

This method consists in the fact that the test site is figuratively magnetized to saturation. Then, the magnetizing current is turned off and the demagnetizing current is turned on. Even harmonics are isolated from the useful signal of the ferro sensor. The demagnetizing current increases smoothly from zero to a value at which the useful signal in the measuring winding of the ferro sensor is zero. This value of the demagnetizing current is a measure of the coercive force [2].

The disadvantage of this method is that the measurement results are very dependent on changes in the gap between the product and the tips of the electromagnet. This leads to an increase in the measurement error of the coercive force of the product.

The purpose of the invention is to improve the accuracy of measuring coercive force.

The goal is achieved by magnetizing figuratively to saturation and demagnetizing it to zero, in the core excitation winding, in which the direction of the field of excitation coincides with the direction of the field of residual magnetization

789940, sample. The value of the magnetizing and exciting currents is set 1.5 to 4 times less than in the excitation winding of the second core.

The drawing shows an electrical circuit diagram of a device for implementing the method.

The device comprises a toggle switch 1, a power transformer 2, semiconductor diodes 3 and 4, a rectifier bridge 5, a millivoltmeter 6, a toggle switch 7, a potentiometer 8, a milliammeter 9, a button 10, a demagnetization winding 11, an excitation winding for a ferrosensor 12 and 13, a magnetization winding 14, potentiometer 15, and the cores of the ferro sensors 16 and 17, the magnetic circuit of the attached electromagnet 18 and 19, controlled is formed 20.

The method is as follows. When the toggle switch 1 is turned on, a voltage is supplied to the bridge-type ferro-sensor, consisting of two diodes 3 and 4 of the field windings and 13 and potentiometer 15. Through a winding 12 and a ferrosensor a half-wave 25 pulsating current flows, t. ' e. in addition to the alternating exciting "current, the windings' 12 and 13 of the ferro sensor also have a constant magnetizing current.

By means of a potentiometer 15, the value of the magnetizing and exciting currents is set for the core of the detector 16, at which the influence of the change in the gap on the magnitude of the demagnetizing current is minimized. Οίο is determined experimentally by the following method.

For different positions of the slider of potentiometer 15 for two samples with the minimum and maximum values of the measured coercive forces, certified in the established order, the dependences of the demagnetizing current on the change in the gap between the sample and the magnetic circuit of the electromagnet 18 and 19 are determined. indirectly using a millivoltmeter 6 connected to points a and b. The voltage value at which the dependence of the demagnetization current on the gap is constant is considered optimal. This voltage value is set when measuring the coercive force of sample 20.

Then, the electromagnets 18 and 19 are installed on the controlled portion of the sample 20. Press the button 10 and the sample 20 is magnetized to saturation. Toggle switch 7. The pointer of the millivoltmeter 6 deviates dright to the extreme position.

Using the potentiometer 8, the demagnetization current is gradually increased until the arrow of the millivolt meter 6 is set to zero.

At this moment, the milliammeter 9 is read, which corresponds to the coercive force of the product.

Claims (2)

The invention relates to non-destructive methods of quality control of products based on measurements of the coercive force, and can be used to control the quality of heat treatment of ferromagnetic products. A known method for measuring the coercive force is that the test portion of the sample is magnetized to its point of view. Then the magnetizing current is turned off and the demagnetizing current is switched on. The magnitude of the demagnetizing current is a measure of the coercive force of the test area of the sample l. The disadvantages of this method are the complexity of the implementation of the method and the limited scope of application. The closest in technical essence and the achieved result is a method of measuring the coercive force by the magnitude of the demagnetizing current. This method consists in that the test area of the sample is magnetized to saturation. Then the magnetizing current is turned off and the demagnetizing current is switched on. Even harmonics are extracted from the useful ferrodat signal. The unwinding current increases smoothly the drift to the value at which the useful signal in the measuring winding of the ferrodate is zero. This value of the demagnetizing current is a measure of the coercive force 2. The disadvantage of this method lies in the fact that the measurement results are very dependent on the change in the gap between the product and the electromagnet tips. This leads to an increase in the measurement error of the coercive force of the product. The purpose of the invention is to improve the accuracy of measurement of co-epithelial force. The goal is achieved by magnetizing the sample to saturation and demagnetizing it to zero in the excitation winding of the core, in which the direction of the excitation field coincides with the Q direction of the residual magnetization field of the 3789 sample. The value of the magnetizing and exciting currents is set 1.5 to 4 times less than in the excitation winding of the second core. The drawing shows an electronic {schematic diagram of an apparatus for carrying out the method. The device contains a toggle switch 1, a power transformer 2, semiconductor diodes 3 and 4, a rectifying bridge 5, millivoltmeter b, toggle switch 7, potentiometer 8, milliammeter 9, button 10, demagnetization winding 11, winding winding (1 and ferro sensor 12 and 13, magnetizing winding 14, potentiometer 15, ferro sensor cores 16 and 17, MatHH- conductor of an attached electromagnet 18 and 19, test sample 20. The method is implemented as follows. When the toggle switch 1 is turned on, a bridge ferro sensor, consisting of two diodes 3 and 4 field windings 12 and 1 3 and the potentiometer 15, a supply voltage is supplied. and excitant current, with co 6p (W1, the influence of the change in the gap on the magnitude of the demagnetizing current is minimized. It is determined experimentally by the following method. If the slider of the potengometer 15 is different for two samples with the minimum and maximum values of the measured coercive forces, attestation & nfc in steady-state order, determine the dependences of the demagnetizing current on the change in the gap between the sample and magnesium by the electromagnet 18 and 19. 3ia, 4 The voltage of the magnetizing and exciting currents is controlled indirectly using a millivoltmeter 6 connected to points a and b. Values: For example, the NIN, at which the dependence of the demagnetization current on the gap is constant, is considered optimal. This voltage value is set when measuring the coercive force of sample 20. Then electromagnets 18 and 19 are installed on the test section of sample 2O. A button 1O is pressed and the sample 20 is magnetized to saturation. The toggle switch 7 is switched. The arrow of the meter 6 is deflected to the right to the JtpafHero position. With the help of the potentiometer of the potentiometer 8, the sweep current smoothly increases until the arrow of the millivoltmtra 6 is set to zero. At this moment, the painters of milpiampermeter 9, which correspond to the coercive force of the given object, are removed: d. The invention The method of measuring the coercive force, based on magnetization about () with two cores to saturation, demagnetizing it to zero, is different and, with 4TOj for the purpose of accuracy, in the excitation winding of the core, in which the direction of the field of excitation coincides with the direction The gender of the residual magnetization of the sample, sets the value of the magnetizing of the primary and stimulating toxj 1.5 to 4 times less than in the excitation winding of the second core. Sources of information taken into account during the examination 1. Flaw detector. 197O, / vfc 4, p. 91. 2. Authors testimony of the USSR № 407252, cl. Q 01 R 33 / O2, 1971.