SU1656349A1 - Apparatus to measure magnetic field parameters - Google Patents

Abstract

The invention relates to a measurement technique and is intended to measure the parameters of the magnetic field of outer space. The purpose of the invention is to improve the measurement accuracy - by introducing three windings 18, 19, 20 to compensate for a false magnetic field, three blocks of addition 13, 14, 15, three large-scale amplifiers 10, 11, 12 and three resistors 21 22, 23. The device also contains three magnetosensitive converter units 4, 5, 6, three switches of the range 7, 8, 9, the EMF variable generator 16, the recording device 171 Il.

Description

The invention relates to measuring technique and is intended to measure the parameters of the magnetic field of outer space, search for magnetized bodies in the seas and oceans, quality control of products from ferromagnetic materials, etc.

The purpose of the invention is improving the accuracy of the change.

The drawing shows a structural 1 diagram of a device for measuring magnetic field parameters.

The device consists of three magnetically sensitive transducers 1–3, three amplifier-transducer blocks 1–4–6, three switches 7–9 ranges, three large-scale amplifiers 10–12, three addition blocks 13–15, a variable emf generator 16, a recording device 17, and three windings 18-20 of compensation of the false 2 magnetic field, each of which is located on the corresponding magnetically sensitive transducer coaxially with its axis. The windings 18-20 are located on the converters 1-3, respectively. 2

The first inputs of each amplifier-converter block 4-6 are connected to the outputs of the magnetometric transducers 1-3, respectively, the outputs of the variable emf generator are connected to the first inputs of the converters 1-3 and to the second inputs of the blocks 4-6, the first outputs of blocks 4-6 are connected to to the recording device 17 and to the inputs of the switches of ranges 7–9, respectively, 3 a resistor 21 (R _x ) is connected between the second input of the converter 1 and the output of the scale amplifier 10, a resistor 22 (Rz) is connected between the second input of the converter 2 and the scale output amplifier 11, a resistor 4 side 23 (Ry) is connected between the second input of the converter 3 and the output of the scale amplifier 12, the first output of the 7 band switch is connected to the first input of the scale amplifier 10, and the second output 4 of this switch 7 is connected to the output of the scale amplifier 10 .the first output of the range switch 8 is connected to the first input of the scale amplifier 11, and the second output of this switch 8 is connected to the output 5 of scale amplifier 11, the first output of the range switch 9 is connected to the first input of scale amplifier 12, and the second the stroke of this switch 9 is to the output of the scale amplifier 12, the second 5 input of the scale amplifier 10 is connected to the second output of block 4, the second input of the scale amplifier 11 is connected to the second output of block 5. the second input of the scale amplifier 12 is connected to the second output of block 6. outputs large-scale amplifiers 7 and 8 are connected to the inputs of the addition unit 13, the outputs of which are connected to the inputs of the false signal compensation winding 18, the outputs of the large-scale amplifiers 8 and 9 are connected to the inputs of the addition unit 14, the outputs of which are connected to the inputs of the winding 19 kom ensatsii false signal, the outputs of scaling amplifiers 7 and 9 are connected to inputs of the summation unit 15, which outputs are connected to inputs of the compensation coil 20, a false signal. In addition, each amplifier-converter unit consists of a selective amplifier, a synchronous detector, and an ADC. In the proposed device, large-scale amplifiers 10-12 and addition units 13-15 are made on operational amplifiers.

The device operates as follows.

At the first inputs of the converters 1-3 is fed from the generator 16 variable EMF. exciting these transducers. As a result, at the output of each of the converters 1-3, the second-harmonic EMF appears, each of which is proportional to the projection value of the magnetic inductance vector acting on the corresponding converter. The output signals from converters 1-3 are amplified, detected and converted into a digital code in the corresponding amplifier-converter blocks 4-6 and are fed to the recording device 17. The analog signals coming from the outputs of blocks 4-6 are fed through the corresponding 'scale amplifiers' 10-12 and resistors 21-23 to the second inputs of the transducers 1-3, which provides negative feedback on the measured projections of the magnetic induction vector.

In the circuit of each large-scale amplifier 10-12, a corresponding switch 7-9 of the range is included. The voltage supplied to the input of each range switch, proportional to the measured projection of the magnetic induction vector, switches the resistors of the corresponding range switch, thereby changing the feedback depth of the scale amplifiers, and hence the magnitude of the feedback currents of the circuits, each of which consists of the scale amplifier with a range switch, a resistor and a feedback coil included in the magnetically sensitive transducer. With this inclusion, the output voltage of each large-scale amplifier is proportional to the magnitude of the measured magnetic induction by the converters 15

3. Independent of the range switch plug-in feedback resistor. Each resistor 21-23 is designed to remove voltage from the outputs of the corresponding large-scale amplifier and to weaken the bypass input circuits of the converters 1-3 low-impedance output resistance of large-scale amplifiers 10-12.

The voltages are proportional to the measured values of the magnetic induction on the same scale, from the magnetic amplifiers 10 and 11 are supplied to the input of the unit 13. The output signal from the unit 13 is fed to the false magnetic field compensation winding 20. The transmission coefficient of block 13 is set so that the winding 20 reproduces the magnetic field in the transducer 3, equal in magnitude but opposite in direction to the false signal of the magnetic field created by the magnetic field acting in the direction of the axes of the transducers 1 and 2.

Voltages proportional to the measured values of magnetic induction on the same scale are supplied from the amplifiers 11 and 12 to the input of block 14. The output signal from block 14 is fed to the false magnetic field compensation winding 18. The transmission coefficient of block 14 is set so that the winding 18 reproduces the magnetic field in the transducer 1, equal in magnitude but opposite in direction to the false signal of the magnetic field created by the magnetic field acting in the direction of the axes of the transducers 2 and 3.

Voltages proportional to the measured values of magnetic induction on the same scale, from scale amplifiers 1 and 3 are supplied to the input of block 15. The output signal from block 15 is fed to the false magnetic field compensation winding 19. The transmission coefficient of the block 15 is set so that the winding 19 reproduces the magnetic field in the transducer 2, equal in magnitude but opposite in direction to the false signal of the magnetic field created by the magnetic field acting in the direction of the axes of the transducers 1 and 3.

Claims (1)

Claim A device for measuring magnetic field parameters, containing three magnetosensitive transducers with mutually 10 orthogonal axes, the output of each of which is connected to the input of the corresponding range switch through an appropriate amplifier-converter unit, an EMF variable generator 15 connected to the first inputs of the corresponding magnetosensitive transducer and to the second the inputs of the amplifier-converter blocks, the first outputs of which are connected to the inputs of the recording device, I distinguish This is because, in order to increase the accuracy of measurements, three false magnetic field compensation windings, three addition blocks, three scale amplifiers25 and three resistors connected between the second inputs of the corresponding magnetically sensitive converters and the output of the corresponding scale amplifier are introduced into it, with the first output corresponding30 a range switch and with the first input of the corresponding addition unit, while the first false magnetic field compensation winding is connected to the outputs of the second addition unit, the second 35 winding - to the outputs of the third addition unit, the third winding - to the outputs of the first addition unit, the first input of which is connected to the second input of the third addition unit, the second input - to the first input of the second 40 addition unit, the second input of the second addition unit is connected to the first input the third addition unit, and the inputs of each large-scale amplifier are connected to the output of the corresponding range switch and to the second output of the corresponding amplifier-converter unit.