SU945631A1 - Method of measuring hollow ferromagnetic object parameters - Google Patents

Description

(54) METHOD OF MEASUREMENT OF PARAMETRES OF HOLLOW FERROMAGNETIC OBJECTS

Claims (2)

The invention relates to non-breaking control and MOJKBT to be used for measuring the internal diameter of hollow phytomagnetic objects, mainly with 9 sets of machines. There is a known method for measuring the internal diameter of hollow ferromagnetic objects, which consist in placing it in a pot of controlled o6tiocTa and an inductor, subsequently setting gaps in two mutually V perpendicular axes and 1 total inductor magnetic resistance l. The disadvantage of the method lies in the accuracy of measuring the internal diameter, since the asymmetry of the magnetic circuit is large. The error closest to the invention according to the technical essence is sent. A method of measuring the parameters of hollow ferromagnetic objects consists in coaxially entering the object The ring inductor, filled with the possibility of a radial radial dimension in the object cavity, changes the air gap between the inductor in the object being controlled, by sweeping the radial pasMeiAi and duktora and MepsooT magnetic resistance of the inductor. The disadvantage of the method is the impossibility of measuring the internal diameter of the object being monitored. The purpose of the invention is to measure also the internal diameter of the object. The delivered pellet is achieved by the method of measuring the parameters of hollow ferromagnetic objects, which means that an annular inductor, adapted to change the radial dimensions in the cavity of the object, changes the air gap between the inductor and the coaxial object. the magnetic resistance of the inductor is measured by the object to be monitored, the magnetic resistance of the inductor is measured before 3945 directly after inserting it into the cavity of the object, the air gap from ene was calibrated with the aid of the compression of the inductor is determined difference between two measured values of the magnetic resistance, and it is determined by the inner diameter of the controlled object. The drawing shows a diagram of an apparatus for carrying out the method. The device consists of an annular inductor 1, made with the possibility of changing its radial dimensions in the cavity of a controlled ferromagnetic object 2, with the exciting winding 3 and i-. measuring winding 4, the system 5 of fixation of the object and the system 6 of calibrated compression. The method is implemented as follows. The inductor 1 is inserted into the cavity of the object 2, fixed by the fixing system 5. The excitation winding 3 is measured by the excitation winding 3 and the air gap between inductor 1 and object 2 is changed by calibrated compression of the inductor by calibrated compression system 6, the second magnetic resistance value of inductor 1 in the compressed state is measured from MepsnoT, the difference between the two measured magnetic resistance values and it determines the internal diameter of the object to be controlled 2. The magnetic resistance of the inductor 1 depends on the parameters of the control object interacting with it, and the difference obtained is uniquely related to t rennim diameter controlled object 4 thus predpagaemy method poevop is accurately measure the internal diameter of the hollow ferromagnirnyh objects. Claims of Invention A method for measuring hollow ferromagnet objects, which consists in introducing a coil coaxially into the cavity of the object under test with a possibility of changing the radial dimensions in the cavity of the object. they change the air gap between the inductor and the controlled object and from MnozoT Magnetic resistance. inductor, in order to measure the internal diameter of the object, also measure the magnetic resistance of the inductor directly after introducing it into the object cavity, air rifle is changed with the aid of calibrated compression of the inductor, the difference of two measured magnetic values is determined. resistances and by it determine the internal diameter of the object being monitored. Sources of information taken into account during the examination 1. Ageikin D. I. Sensors of systems of automatic control and regulation. M., Mashgiz, 1952, p.19-49. 2. USSR author's certificate NO 783731, cl. G01R 33/12, 1978, (prototype).