SU1153278A1 - Device for measuring magnetic fraction content of pulp flow - Google Patents

Abstract

A DEVICE FOR MEASURING THE CONTENT OF A MAGNETIC FRACTION IN A PULSE FLOW, containing measuring and compensating sensing elements in the form of inductance coils, connected via a first controlled switch to a measuring generator, the output of which is connected to the frequency meter input, the first power supply and control generator connected to the control input of the first controllable switch, characterized in that, in order to improve measurement accuracy, it comprises a second power source, a second and a third controllable switches, a signal processing unit, a frequency divider into two and an indicator; the output of the frequency meter is connected via a second controlled switch to the first and second inputs of the signal processing unit, the output of which is connected to the indicator input, the outputs of the first and second power sources through a transceiver the control switch is connected to the power input of the measuring generator, and the control inputs of the second and third control switches are connected via a frequency divider by two to the control output generator.

Description

1I

The invention can be used to measure the content of magnetite iron in iron ore beneficiation products at concentration plants for wet magnetic separation.

A device for measuring the magnetic susceptibility of a pulp flow based on densitometers of the type IRFR containing a measuring volume in the form of a section of a pipeline, one end of which is fixed and the other capable of moving and connected to a differential transformer, is in a magnetic field of a permanent magnet connected to the inputs of a secondary device. l.

However, the known device is characterized by low reliability, due to the presence of moving parts.

The closest in technical essence. The invention is a device for measuring the content of the magnetic fraction in the pulp stream, containing measuring and compensating sensing elements in the form of inductors coils connected through a first controlled switch to a measuring generator, the output of which is connected to the input of the frequency meter, the first source power supply and control generator connected to the control input of the first controlled switch 2j.

This device has low accuracy.

The purpose of the invention is to improve accuracy.

This goal is achieved by the fact that a device for measuring the content of magnetic fractions in a pulp stream, containing measuring and compensating sensitive elements in the form of inductors, connected through a controlled first switch to a measuring generator, the output of which is connected to the frequency meter input, the first power source and control A generator, connected to the control input of the first controlled switch, contains a second power source, a second and third controlled switches, a processing unit signal retractions, frequency divider for two and an indicator, while the output of the frequency meter is connected via the second control 5: 27s3 2

The seventh switch with the first and second input of the signal processing unit, the output of which is connected to the input of the indicator, the outputs of the first and second. 5. The power supply source 13 via the third control switch is connected to the power supply input of the measuring generator, and the control inputs of the second and third control switches are connected through a frequency divider to two with the control generator output.

The drawing shows a block diagram of the device.

5 The device contains a measuring sensitive element I, a compensating sensitive element 2 made in the form of inductors, a first controlled switch 3, a measuring generator 4, a controlling generator 5, a frequency meter 6, a second controlled switch 7, a signal processing unit 8, a third controlled switch 9, first power supply 10, second power supply 11, indicator 12, frequency divider 13 into two.

The device works as follows.

At the first moment of time, measuring sensing element I is connected to measuring generator 4 through the first controlled switch 3, the first power source 10 is connected through the third control 5 switch 9, and the output of the frequency meter 6 is connected to the first input of the processing unit 8 through the second controlled switch 7 signals. The first controlled switch 3 operates at a frequency significantly lower than the frequency of the measuring generator 4. The switching frequency of the second and third controlled switches 7 and 9 is two times lower than the switching frequency of the first controlled switch 3, the synchronous operation of which is provided by the control generator 5. The first input of the K processing unit

signals corresponds to the first calibration characteristic, in which the frequency at the output of the measuring generator 4 is equal to

5 f, K4, T ° Кдэ (/.) -К ,, .- fo, where f is the measuring frequency

generator 4 when the first source is connected to it; 10 pigi and measuring chu pet liiiTOiib ak a l l 1t 1; К „is the coefficient, the characteristic change in the inductance of the sensitive element from the ambient temperature and other factors; K ,,, (P, S) is the coefficient characterizing the change in induction. ti measuring sensitive element I due to the presence of a null with a density S and the content of the magnetic fraction Co the coefficient characterizing the change in frequency from the measuring generator 4 nodes by the influence of ambient temperature and other factors; fg- frequency of measuring generator 4 under normal environmental conditions and the absence of null in measuring element 1. The frequency of measuring generator 4 is measured by frequency meter 6, and the digital code from frequency meter 6 through the input switch of computing device 7 is fed to the input of signal processing unit 8 and remembered. I At the second moment of time, the first controlled switch 3 connects to the measuring generator 4 a compensation sensitive element 2. At the same time, the frequency f on the course of the measuring generator 4 is 2 gt ° o) The digital code from frequency meter 6 goes to block 8. signal processing where a 1G dividing operation is performed. . at the time of the next connection of the measuring sensitive element MO-Hia I to the N-morito-lyum generator 4, the frequency meter is connected to the second input of the signal processing unit 8, which corresponds to the second graded characteristic, when the second power source 1I is connected to the measuring generator L. Further, the operation of the device proceeds as previously described, the result of the counting S is memorized by the signal processing unit 8. On the basis of the calibration characteristics previously obtained during calibration of the device, as well as the obtained values and S; j, the CHI-processing unit 8 solves the obtained system of two equations with two unknowns B and S, for example, of the form fs a + a, p + a, 5 + , 1.82 bo -t b + b, 8 + b, p where I and b; with, ... .3-- constant coefficients. The DZ-28 Electronics computer can be used as a signal processing unit 8, solving technological process control problems based on measurements of the magnetic fraction content in the pulp y and its density S. The resulting magnetic content fraction y and the density of the pulp are outputted to the indicator input 12. The tests of the device showed that the measurement error of the content of the magnetic fraction of ft decreases 3-, 7 times. The use of the device by proposing; tnoj fraction in the pulp stream. The additionally introduced elements of the device make it possible to eliminate the effect of pulp density on the measurement result by using the calibration characteristics.

Claims (1)

DEVICE FOR MEASURING THE CONTENT OF MAGNETIC FRACTION IN A PULSE FLOW, containing measuring, measuring, and compensating sensitive elements in the form of inductors connected via a first controlled switch to a measuring generator, the output of which is connected to the input of the frequency meter, the first power source and a control generator connected with the control input of the first controlled · switch, characterized in that, in order to improve the measurement accuracy, it contains a second power source, a second and third control switchable devices, a signal processing unit, a frequency divider into two and an indicator, while the output of the frequency meter is connected via a second controllable switch to the first and second input of the signal processing unit, the output of which is connected to the input signal of the indicator, the outputs of the first and second power sources are through the third the controlled switch is connected to the power input of the measuring generator, and the control inputs of the second and third controlled switches are connected through a frequency divider into two with the output of the control generator.