SU1126910A1 - Device for measuring relative magnetic permeability of loose material having weak ferromagnetic characteristics - Google Patents

Abstract

DEVICE FOR MEASURING THE RELATIVE MAGNETIC PERMEABILITY weakly ferromagnetic LOOSE MATERIALS comprising symmetrical differential magnetic system with air gaps, and coil excitation coil feedback serially connected amplifier and an indicator, characterized in that, in order to increase the sensitivity and accuracy of measuring the relative magnetic permeability of the magnetic the system is made of C-shaped and T-shaped magnetic conductors rigidly and magnetically connected in one node, winding ozbuzhdeni located on the middle rod-shaped magpitoprovoda T, two identical sections of the measuring coil are connected posledovatelnovstrechno and connected to the input of Wuxi (A divisor, wherein they are located. C-shaped magnetic core symmetrically to its axis. P2

Description

The invention relates to a technique of magnetic measurements and can be used, in gastric, in determining the relative content of magnetic inclusions in the calcined calcined gas during roasting of pyrites. A device is known for measuring the relative magnetic permeability of weakly ferromagnetic materials containing a differential magnetic system, in air gaps of which a moving system is placed Ij, A known device of complex design, the measurement being made in an unbalanced state, the differential second magnetic system, which leads to low accuracy of measurement. The closest to the proposed technical essence and the achieved result is a device for measuring the relative magnetic permeability of weakly ferromagnetic suspensions, containing a symmetric differential magnetic system, made in the form of a double box, to which branch has an air gap and is equipped with a magnetizing coil. In the air gap branches placed sample. In addition, the device contains an indicator located in the measuring diagonal of the sigfriche differential magnetic system and connected in series feedback feedback located in the branch of the magnetic system WI5 and the receiver, whose input is connected to the indicator of the magnetic field. The indicator consists of a ferromagnetic core with a frame, fixed on the axis, which rotates on two ball-shaped supports and is connected to the shaft of a synchronous micro-electric motor. Contact axes are also placed on the axis, to which the frame outlets are attached to which, by means of contact brushes and connecting wires, are connected to the amplifier input. The output of the amplifier via a milliammeter is connected to the feedback coil Zj. A disadvantage of the known devices is the complexity of the design and low reliability due to the presence of a movable system and current collection contacts, low sensitivity due to the small working gap, as well as low accuracy due to the influence of external fields and temperature tolerance, which limits its area - application. The purpose of the invention is to increase the sensitivity and accuracy of measuring the relative magnetic permeability while simplifying the design,. The goal is achieved by the fact that in a device for measuring the relative magnetic permeability of weakly ferromagnetic granular materials containing symmetric differential magnetic systems with air gaps and an excitation winding, a feedback coil, are connected in series; an amplifier and an indicator; the magnetic system is made of C-shaped and The T-shaped magnetic cores 5 are rigidly and magnetically connected in one node, the field winding is located on the middle core of the T-shaped magnetic circuit, two identical The measuring sections of the measuring winding are connected sequentially and connected to the amplifier input, while they are located on the C - shaped magnetic core symmetrically to its axis. The drawing schematically shows the device, a general view. The device contains a symmetric differential magnetic system made in the form of a C-shaped magnetoproduct with an air gap of 2 and a T-shaped magnetic core 3 with a Goljusky tip 4. The magnetic cores} 3 are rigidly and magnetically coupled in the node 5. A rigid motionless connection of the magnetogrowses I and 3 A detachable design of the device eliminates the possibility of the symmetry breaking of the magnetic system under the action of vibration, tochgchkov, etc. The magnetic coupling of G-plug and DON 1 and 3 3 to node 5 eliminates the influence of the air gap in this connection (for example, by connecting the EH of planes by symmetrical connection) .- Symmetrical working air gaps 6 to 7 disassembled the pole with tip 4 and the upper part of the magnetic section. Yes . In the air 7 times:; sample 8. On the rod of the T-shaped magnet duct, 3 are ODKC-TK-J, 3 are excited. The ip, the same sekii 0 and the measuring one; - g c) is metrically located on the pitch; -: mag- ny 3p26910 of the conduit 1 and is located at equal distance from the air gap. The feedback coil 12 is located 3 magnetic branches, where the sample 8 is placed. In addition, device j contains amplifier 13 and indicator 4. The device operates as follows. The winding 9 of the building is connected to a power source and creates a working flux magnetic flux. The path length of the working flows F, and g remains unchanged for the left and right and right parts of this symmetric magnetic system, which ensures that the magnetic induction is uniform along the length of 2 working air gaps 6 and 7. Identical sections 10 and 11 of the measuring winding are connected in series and go, since the magnetic system is symmetric, then in the absence of weakly ferromagnetic granular materials in the product pipeline and by virtue of the equality of the magF, the emf at the fluxes of the input of force 13 will be equal to zero, i.e. uE If, - Ец2 О When applying bulk materials containing co ferromagnetic particles through the product pipeline, the equilibrium of the differential magnetic system is disturbed and EMF and Ец appear at the input of amplifier 13, the value of which is directly proportional to the value and f, i.e. & E, H, 44f,) - E ", - E", where f is the frequency of the supply voltage; О T and maximum values of magnetic fluxes Ф, ИФ2. in turn, the EMF values E and EJJ 5 induced in the identical 5 sections of the measuring winding are determined by the formulas: E, -W CG -bGg + G,); (2) E, /: -IgW3-W, (G,), (3) 50 where la is the current in the field winding; Wn the number of turns of the winding excite a day; W is the number in the section of the measured 55 winding winding; GQ is the total magnetic conductivity of the left or right G-to-Ny1. ray moc and s zor where 8 С satures where С meri mow weakly catch bodies of the body of the cutter part of the air gap except for its working part of length f; Gg is the conductivity in the path of magnetic fluxes from the ribs and the side faces of one half of the symmetric magnetic circuit; and Gg, respectively, of the conduit of the product pipeline and equal to it along the length of the working part of the symmetric vzdushnogo gap. l reduce the fluxes of the polysk tip A and the upper part of the magnetic circuit 1 are round A substitution (2) and (3) in () per E, ig. Wg. W, (,) the formula for determining the conduction of a calibrated product line of an air-tight it takes the form r (WofUry-, С, (and "| -, Pld - absolute magnetic npoHH- air persistence; Shr - relative magnetic permeability of ferromagnetic granular material -h - area the horizontal section of the air gap between the polar tip 4 and the upper part of the magnetic circuit 1 is equal to the product of the working length of the calibrated product pipeline and the THICKNESS of the set h of the magnetic conductor b - the size of the air gap taking into account (5) n (6) equation (4) in the total u- - ; i TiB B- n | yo | ((u, -0-Ci (Ur-i), С Ij, Wg. W, .., Uef, consequently, the emf at the output of the winding depends on the individual magnetic permeability of ferromagnetic bulk materials matter This EMF is fed to the input of the amplification of the 13 following system, where it is absorbed by current and voltage, and is switched on. From the output of the output, the output current goes to the feedback circuit 12 and creates

magnetomotive force that balances a symmetric differential magnetic system. The output current passing through the coil 12 of the feedback is recorded by means of an indicator 14, the scale of which is calibrated in terms of the relative magnetic permeability.

Compared with the prototype, the device has a simpler design; hypersensitivity; higher accuracy.

The simplicity of the design is ensured by the fact that the proposed device has no rotating elements; reduced the number of prefabricated parts and assemblies, as well as due to the absence of movable collector contacts.

The increase in the sensitivity of the device is achieved by the fact that the design of the magnetic system allows within wide limits to change the working length E of the air gaps and, consequently, the area of the pipeline depending on the magnetic permeability of bulk materials.

Indeed, the sensitivity of the proposed device is directly proportional to the area S of the horizontal cross section of the pipeline, which follows from determining sensitivity using dependencies (4) - (6). Consequently, an increase in the parameters determining S (in particular, 1) will lead to an increase in sensitivity.

The higher accuracy of the proposed device is due to the reduction of the effect of temperature error.

It is known that as the temperature changes, the parameters of the excitation winding and the magnetic circuit change. This leads to a change in the magnetic flux TI created by the excitation winding, and consequently, fluxes and p2

In the device, when Φ varies, the flux Φ, change in the same way, since the winding is located on the middle core of the T-shaped magnetic circuit. therefore

the difference of 4 flows P, and P2 is equal to U P P - 2 S with temperature fluctuations, does not change. In the prototype, the excitation winding consists of two sections, so the inaccuracy of their manufacture inevitably leads to additional error in case of temperature fluctuations.

Claims (1)

DEVICE FOR MEASURING RELATIVE MAGNETIC PERMEABILITY OF WEAK-FERROMAGNETIC BULK MATERIALS, containing a symmetric differential magnetic system with air gaps and an excitation coil, a feedback coil, an amplifier and an indicator connected in series, characterized in that, with a view to increasing the relative sensitivity and magnetic sensitivity, the system has a magnetic sensitivity made of C-shaped and T-shaped magnetic cores, rigidly and magnetically connected in one node, the excitation winding The unit is located on the middle rod of the T-shaped magnetic circuit, two identical sections of the measuring winding are connected in series and connected to the input of the amplifier, while they are located. on a C-shaped magnetic circuit symmetrically to its axis. Oh ~ Oh