SU849118A1 - Device for measuring energy loss for rotating hysteresis - Google Patents

Description

The invention relates to the intent of magnetic quantities, and more specifically to the intent and study of the physics of hysteresis in a magnetic field, and can be used (for the study of various magnetic materials, used in instrumentation to prepare navigation equipment for various purposes, besides , it can be used in electrical engineering when creating hysteresis electric motors. A device is known for measuring a rotating mechanical moment of a newly minted memory sample, including An integrated system with a mirror and a frame with calibration and compensating omopses, a permanent magnet, an electromagnet, a light source, an angle of rotation of an electromagnet, a photoelectric amplifier, to the output of which is connected 4x sensing frame winding and a measuring device l. direct measurement of the magnitude of the PEG, for which it is necessary to measure the parameters of the electrical signal, which is rotated by that mechanical moment of the sample, on two-dimensional This is a samopvgotse recorded on normalized paper, planimeterization of the hysteresis curve or its cutting and weighing on analytical scales, calculation. With a n (f) plane of the planimeter, it is not possible with sufficient accuracy to calculate the area of the hystereois curve for materials with small losses for rotational hysteresis (.VHG) or complex crystal structure, in which the shape of the curve practically does not allow using the planimeter. precise and fast measurement of the amount of energy lost on the rotational hysteresis in magnetic materials.

The specified Dep is achieved in the device, which contains a suspension system with a mirror and a frame with a graduated winding and a sensation winding, a permanent magnet, a magnetic magnet, a source, a nickname of light, an angle of rotation of the electromagnet, a dual photoelectric sensor and a photoelectric amplifier associated with it, To the output of the terminal there is connected to the psadnadnnaya winding of the frame, the measuring device, introduced in series with the output of the photoelectric amplifier, a large-scale amplifier and integrator, with its output connected to a nefflO My input is a measuring device, 15 as well as a timing unit, the input of which is engaged with the sensor of the angle of rotation of the electromagnet, and the output is with the second input of the tegrator and Eimeter.

In the drawing, a functional scheme of the device for measurement is presented.

The device contains a permanent agnit 1, psmdaysnuyu: Subject 2, the mirror 3 and the frame 4 with x zadirovochnoy winding 5, the magnetic sample under test 6, the electromagnet 7 for magnetizing the sample, the point 8 of the light, the angle sensor 9 of the electromagnet , differential photoelectric lO, photoelectric device 11, x9plashes 1 slon 12, large-scale amplifier 13, intetrasr 14, clocks 15, measuring rtpyt-bor 16.

In the preferred embodiment, as a measuring instrument (and a Digital Voltmeter is used, the integrator is analog and is based on a DC amplifier.

The device works as follows obra3C vI.

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When a sample 6 magnetically mounted on a suspension system e 2 is placed in a constant uniform magnetic field created by an electromagnet 7, a rotating moment acts on the sample, which tends to cause the sample so that the axis of easy magnetization is parallel to the vector magnetic field. Owing to the rotation of sample 6, the entire suspension system 2 is rotated, on which mirror 3 and frame 4 with winding are also located. At the turning of the mirror 3, the irradiated beam produces an imbalance of the bridge, the shoulders of which is a differential photocell 1O. The error voltage is applied to the photoelectric amplifier 11, the load of which is the compensating winding 12 of the frame 4. As a result of the interaction of the field of the continuous field of the winding 12, through which the current proportional to the voltage of the bridge unbalance, with the field of the constant magnet 1, the frame 4 creates The current moment is equal and opposite in the direction of the torque of the sample 6. The output voltage of the photoelectric amplifier 11, which is axial to the torque of the sample, is fed through the large-scale amplifier 13 by 1 piece. automatic telephone exchange 14 and on the measuring device 16, for example ifrs®, oh volt meter.

Scale amplifier 13 It has several dynamic amplitude ranges with a smooth tuning of the gain, which is chosen for each sample specifically depending on the signal amplitude and sample volume, the magnet rotation speed and taking into account the matching of the output of the scale amplifier to the DC amplifier power input a, the linear section of the input x of the actorsticks is limited.

The integrator 14 produces an analog integration of the voltage from the output of the scale amplifier 13 only during the rotation of the electromagnet 7 around the sample, which provides a storage unit 15 associated with the sensor 9 of the angle of the electromagnet. The signal from sensor 9, corresponding to the angle O, i.e. the start of rotation, is formed by the timing unit J.5 into the control signal, which unlocks the integrator’s DC amplifier 14, and the signal, by completing the remagnetization cycle, disconnects the integrator 14 from the scale amplifier 13 and resolves the digital voltmeter of the integrator; voltage equal in magnitude to the loss of energy per rotational hysteresis in the unit volume of the material under investigation.

Carried out a mathematical justification of the direct measurement by proposing the magnitude of the device for rotational hysteresis, which in the material & material in one cycle of the magnetization reversal is determined as follows

A QR —J-I dy, I)

Claims (1)

Where V is the sample volume. M is the mechanical torque of the sample; Z is the current angle. , -, The voltage of the integrator 14 at the time T is determined by the VzvS1 expression of where | R. and C are the elements of the integral circuit, the voltage at the input of the integrator. The voltage at the output of the photoelectric amplifier AND is proportional to the gate moment of the sample. where K0 is the graduated constant of the device. The voltage at the output of the large-scale amplifier 13 is proportional to the sample moment of the sample in the input voltage for the integrator) where tC; j is the scale gain factor & From here —fT dviiJ f and hh--. Mil., RCu) R where W f- is the rotational speed of the romagnet efect. By setting the scale gain factor to equal weells outside the expression am. to.-. - M, we obtain Ugbix.R Thus, the proposed arrangement, compared with conventional devices, provides fast, accurate, and direct measurement of the magnitude (losses in magnetic materials. The loss time for a rotating GE site of one sample and the construction of a trophic dependence, for example, on the magnetic field strength approximately one hour, whereas according to the previous method, the measurement of the rotational moment and the calculation of losses takes at least ten hours. Formula of the invention The device for measuring the energy loss by time hysteresis containing a suspended luminary with tempering and a frame with calibration and compensating windings, a permanent magnet, an electromagnet, a light source, an angle-of-rotation sensor- electr (Agnetha, d | ferensh (val photocell associated with it photoelectric Usklktel, to which is connected with a coaxial winding of the frame of the windshield warmer, which is due to the fact that: increase of accuracy and speed of speed and speed of fire, it is introduced in series with 1 &1; Tel and integrator connected to its vyhopom - "x vhoou measuring device and hroniruk Pius block kototorogo input coupled to claim angle sensor (Orochi electromagnet, and an output - to the second inputs BHTerpaTqia and meter. Sources of information taken into account during the examination 1. Sevatov B.K. and Kharakhatn E.G. Torsion scales with offset compensation are obtained by direct current. Instruments and Experimental Technique, I960, No. 5.