SU739445A1 - Device for measuring coercive force of ferromagnetic materials in flow - Google Patents

Description

(54) DEVICE FOR MEASUREMENT. KOERISHGIYNOY. FORCES OF FERROMAGNETIC MATERIALS The invention relates to the enrichment of ferrous metals, can be used in the beneficiation plants to control the magnetic characteristics of the ore during its transportation with a conveyor belt or aqueous medium. Devices for measuring the coercive force of materials are known, which contain a magnetizing winding, a phase-matching bpok and a sensitive element. A disadvantage of the known devices is a low measurement accuracy. Closest to the proposed device for measuring the coercive force of ferromagnetic materials, comprising a magnetizing winding, a phase-shifting unit, a sensing element and a ferrrdynamic compensating unit. A disadvantage of the known device is low measurement accuracy. The purpose of the invention is higher measurement accuracy. This goal is achieved by inserting a device that contains a magnetizing POTBKE. the winding connected to the input of the phase-shifting unit, as well as the successively connected sensing element and the ferrodynamic compensating unit, the power terminals of which are connected to the output of the phase-shifting unit, the phase-measuring unit, the input of the amplifier, which is connected in parallel with the amplifier of the ferrodynamic compensating unit, is inserted; - another unit; at the same time, the reichord engine is connected to the output of the ferrodynamic compensator. The drawing shows a circuit diagram of the device. The device contains magnetizing. winding 1, sensing element 2, ferrodynamically and compensating unit 3, fauna coupling unit 4, phase shifting unit 5, installation reohfd 6. The device works as follows. The magnetic field is excited by the magnetizing winding 1. The difference between the same sensitive element 2 and the errodynamic compensating block 3 is applied to the parallel-connected inputs of the amplifiers of the block 3 and the phase-measuring unit 4, fed by mutual Shtolnitelnye voltages, removed from the input and output of the phase-shifted circuit. unit 4 is a precision rheochord 6 (electrically connected to the phase-shifting unit 5) / the engine of which is moved by the electric motor of the unit 4, controlled by m amplifier.

In the absence of ore in the sensing element 2, the voltage at its output is zero. The frame of the ferrodynamic Compensating block 3 is automatically set by its electric motor and amplifier to the position corresponding to zero output compensating voltage of block 3. The circuit is in balance at any position of the arrow and the reichord of block 4, since there is no signal at the inputs of the amplifiers of blocks 2 and 4 any phase of the voltage that feeds block 3. This situation is explained by the fact that in the absence of a magnetic flux vector in the ore, its phase is equal to uncertainty.

When ore is formed in the sensing element 2, the voltage at its output is leaked. The frame of the ferrodynamic compensating unit 3 is automatically rotated by an electric motor and amplifier at an angle that is necessary to compensate for the voltage of element 2. If the phases of the voltage vectors of the frame h and the sensitive elec- tovfpRTa do not match, a differential vector is applied to the inputs of the amplifiers of blocks 3 and 4. This difference. the vector is orthogonal to the voltage vector of the frame of block 3 and therefore does not cause rotation of its electric motor. Due to the fact that unit 4 is powered by a voltage shifted in phase by 9O relative to the phase of the supply voltage of unit 3, this differential vector causes the rotation of the electric motor and the reichord of unit 4 to rotate. The direction of rotation of the electric motor of unit 4 is chosen so that when it rotates, the differential vector umenyyals and eventually disappeared. If the difference vector is equal to zero, the scheme approaches the complete equilibrium. The magnitude vector of the flux in the ore is reflected on

the scale of the block is 3, and the phase is on the scale of the block 4. The scale of the block 3 is graduated, except for degrees, in units of coercive force - Oersteds. Graduations in grades are overhead and are used to tune and calibrate the device.

invention formula

A device for measuring the coercive force of ferromagnetic materials in a flow, containing a magnetizing winding connected to the input of the phase-shifting unit, as well as series-connected sensing element and a ferrodynamic compensating unit, the power terminals of which are connected to the output of the phase-shifting unit, that

increase measurement accuracy into it

A phase-measuring unit is introduced, the amplifier input of which is connected in parallel to the amplifier of the ferrodynamic compensating unit, and the phase-measuring unit's reochord is connected to the phase-shifting unit, while the rheochord slider is connected to the output of the ferrodynamic compensator. m

Stream matvriapa

Claims (1)

SUMMARY OF THE INVENTION ²⁵ A device for measuring the coercive force of ferromagnetic materials in a stream, comprising a magnetizing winding connected to the input of the phase-shifting unit, as well as series-connected ³⁰ sensing element and a ferrodynamic compensating unit, the power terminals of which are connected to the output of the phase-shifting unit, characterized in that, with the aim of 35 to increase the accuracy of measurement, a phase measuring unit is introduced into it, the input of the amplifier of which is connected in parallel with the amplifier of the ferrodynamic compensating unit, and the rechord of the phase measuring unit 40 is connected to the phase shifting unit, while the rechord slider is connected to the output of the ferrodynamic compensator. material