SU1151939A1 - Device for producing stable magnetic field of preset strength - Google Patents

Abstract

1. A DEVICE FOR ESTABLISHING A STABLE MAGNETIC FIELD OF A TARGET VOLTAGE, containing an electromagnet connected by magnetizing coils to the output of a controlled power source, including a regulating element, a differential amplifier, a comparison node and a rectifier, one output of which is the first output of a controlled power source, a reference node and a rectifier, one output of which is the first output of a controlled power source, a reference node and a rectifier, one output of which is the first output of a controlled power source, and the other is connected to the first terminal of the regulating element connected by a control input to the output of the differential amplifier, the input of which is connected to the output of the node compared to and a magnetic resonator converter including a low frequency generator, a magnetic resonance sensor, a phase detector, an amplitude detector and an adjustable high frequency generator, the low frequency generator connected to a magnetic resonance sensor located between the poles of the electromagnet and one of the inputs of the phase detector, the other input of which is connected with an output of an amplitude detector, an input connected to the output of an adjustable high-frequency generator, connected by an input to a magnetic resonance sensor a, characterized in that, in order to increase the stability of the magnetic field and the accuracy of its voltage setting, the comparison node consists of a reference current source, a controlled current divider, a pulse shaper, a capacitor, a current stabilizer, and a switch, with the reference current source being one terminal connected to the first output of the controlled power supply, another output to the first output of the controlled current divider, and the outputs of the reference current source are the outputs of the reference node; the first control input of the controlled divider the current is connected to the output of the phase detector, the second control input is connected to the terminal for connecting the field sweep node and via the pulse shaper to the outputs (L of the deep detector, the input is to the second output of the regulating element and the second output of the controlled power source, and the second the output to its first output is through a parallel-connected capacitor, a current stabilizer and a switch, the control input of which is connected to a terminal for connecting the field reset unit. 2. A device according to claim 1, characterized in that the controlled current divider is made on a composite transistor, between the emitter and the base of the output transistor of which are connected in parallel (; o controlled resistor and an additional key, and the emitter, collector and The base of the composite transistor is, respectively, the input, the first and second outputs of the controllable current divider, and the control inputs of the resistor and the auxiliary switch are the first and second control inputs of the controllable current divider.

Description

The invention relates to electrical engineering, in particular, to devices for creating stable magnetic fields with precisely predetermined magnetic induction, and can be used, for example, in testing magnetic measuring equipment or in studying magnetic resonance spectra of substances.

A device for creating a stable magnetic field is known that contains an electromagnet, a power source and a regulating element, the control input of which is connected to the output of a field stabilizer using two sensors, one of which is placed in the field of the reference magnet and the other in the field of stabilization 1.

The disadvantage of the described device is the low stability of the generated magnetic field due to the low stability of the sensors themselves.

The closest technical solution to the present invention is a device for creating a stable magnetic field containing an electromagnet with magnetizing and regulating coils, an adjustable current regulator connected to the magnetizing coils and a magnetic resonance transducer containing a sensor placed between the poles of an electromagnet, low and high frequency generators, amplitude a detector and a phase detector, the output of which through a DC amplifier is connected to the control coils of the electroma gnit 2.

The known device provides for a better magnetic field stability, which, however, is also not high enough due to its dependence on the stability of the supply current of the magnetizing coils, the drift of the direct current amplifier, the temperature of the electromagnet cores and the influence of external magnetic fields.

Measuring information about the magnitude of the field, which can be obtained from the magnetic resonance converter included in the stabilization circuit, does not have sufficient accuracy due to the presence of errors depending on the magnitude of the field and its drift, as a result of which a separate induction meter should be used. The presence of two independent stabilization circuits (the supply current and the field itself) makes it difficult to display a given field size and does not allow programmed regulation of the latter. The use of additional control coils, a dc amplifier with a malshi drift and a current stabilizer, the sensor of which requires special thermostating, complicates the device.

The purpose of the invention is to increase the stability of the magnetic field and the accuracy of its intensity setting.

The goal is achieved by the fact that in a device for creating a stable magnetic field of a predetermined intensity, containing an electromagnet connected by magnetizing coils to the output of a controlled power source including a regulating element, a differential amplifier, a reference node and a rectifier, one output of which is the first output a controlled power source, and the other is connected to the first output of the regulating element connected by a control input to the output of the differential amplifier, the input of which connected to the output of the reference node, a magnetic resonance transducer including a low-frequency generator, a magnetic resonance sensor, a phase detector, an amplitude detector and an adjustable high-frequency generator, the low-frequency generator connected to a magnetic resonance sensor located between the poles of an electromagnet and one of the inputs of the phase detector, another input of which is connected to an output of an amplitude detector, an input connected to an output of an adjustable high-frequency generator connected in one to the magnetic resonance sensor, the comparison node consists of a reference current source, a controlled current divider, a pulse shaper, a capacitor, a current stabilizer, and a key, the reference current source being connected to the first output of the controlled power source with one output the output of the controllable current divider, and the outputs of the current source are the outputs of the reference node, the first control input of the controllable current divider is connected to the output of the phase detector, the second control input is connected to the terminals to connect the field sweep node and through the pulse shaper to the output of the amplitude detector, the input to the second output of the regulating element and the second output of the controlled power source, and the second output to its first output through a parallel connected capacitor, current regulator and switch controlling the input of which is connected to the terminal for connecting the field reset unit.

In this case, the controlled current divider can be performed on a composite transistor, between the emitter and the base of the output transistor of which are connected in parallel, a controlled resistor and an additional key, while the emitter,

5, the collector and the base of the composite transistor are respectively the input, the first and second outputs of the controllable current divider, and the control inputs of the resistor and the auxiliary switch are the first and second control inputs of the controllable current divider.

FIG. 1 shows a block diagram of the device; in fig. 2 is a block diagram of a controlled current divider.

The device (Fig. 1) contains an electromagnet, the coils 1 of which are connected to the output of a controlled power source 2, connected by control inputs to the inputs for switching on the sweep and resetting the magnetic field and the outputs of the magnetic resonance converter 3, the sensor 4 of which is placed between the poles of the electromagnet. The power supply 2 includes a rectifier 5 connected to the regulating element 6, the control input of which is connected to the output of the differential amplifier 7, the comparison unit 8, designed as a reference current source 9 connected between the inputs of the amplifier 7, in parallel with which connected in series the output sensor 10 voltages (the function of which electromagnet coils 1 can perform) and output voltage adjuster 11.

The setting unit 11 of the output parameter (voltage or current) of the power source contains a controllable current divider 12 connected to the output control terminal 10 of the output parameter, the first output to a terminal connected to the reference current source 9, a second output to its first output through a parallel-connected capacitor 14, a stabilizer 15 of its discharge current and a switch 16, the control input of which is connected to the reset terminal pol. Shaper 13 can be made in the form of a chain of a diode and a capacitor, a stabilizer 15 of discharge current, a capacitor 14 - in the form of a reverse-biased diode, a switch 16 - in the form of a reed switch with electromagnetic control.

Magnetic resonance transducer contains a resonance sensor 4 connected to an adjustable high-frequency generator 17, the output of which is connected to the output of the measurement information and input. home amplitude detector 18, the output connected to one of the inputs of the phase detector 19, the other input of which is connected to the low-frequency generator 20 connected to the sensor 4. The first control input of the current divider 12 is connected to the output of the detector .19.

The controlled current divider (Fig. 2) is made on a composite transistor 21, between which is connected in parallel to the controlled resistor 22 between the emitter and the output transistor base, and

The auxiliary switch 23, with the emitter, collector and base of the composite transistor 21 being the input, the first and second outputs of the current divider 12 5, and the control inputs of the resistor 22 and the key 23 are the first and second control inputs of the current splitter 12.

The controlled resistor 22 can be performed on a transistor, the switch 23 on the thyristor or its analogue. In this case

10, the current stabilizer is a base-to-collector input transistor of the composite transistor 21.

The device works as follows.

15 The voltage at the output of the power supply 2 is always proportional to the voltage at the terminals of the setting device 11, which, in turn, is determined by the voltage at the capacitor 14. The reference current of the current source 9 is divided by the current divider 12 in a ratio

0 is determined by the transmission coefficient of the composite transistor 21, and the current of the first output of the divider 12 is the collector current, and the current of its second output is the base current of the composite transistor 21 and

5 by the charge current of the capacitor 14 and is chosen to be somewhat less than the discharge current of the latter at a zero signal level at the output of the phase detector 19.

In the initial state, the keys are 16 and 23

0 are closed, there are no signals at the control inputs of the current divider 12, the voltage on the capacitor 14 is zero, the voltage on the outputs of the setting device 11 is equal to the voltage drop on the saturated composite transistor 21, the magnetic field has a minimum value. After the frequency of the high-frequency generator 17, corresponding to a predetermined magnetic field, is shown, a pulse is applied to the sweep enable input, which opens the key 23 and

0 translates the ycJojtvpo to the magnetic resonance search mode. In this case, the transfer coefficient of the composite transistor 21 decreases abruptly and, accordingly, the charge current of the capacitor 14 increases, the voltage at which begins to increase rapidly. When a field passes a predetermined magnitude, a pulse appears at the output of the amplitude detector 18, which is converted by the driver 13 into a pulse closing the key 23. The capacitor 14 begins to discharge, which leads to a contraction of the magnetic field. When the field is reduced to a predetermined value, the output of the phase detector 19 is an error signal proportional to the deviation of the field from the predetermined value. I will affect the entrance

controlled resistor 22, the error signal changes the transmission coefficient of the composite transistor 21, i.e. dividing ratio of the current divider 12 so that the current

The charge of the capacitor 14 is equal to the current of its discharge with a minimum deviation of the field from the specified value. At the same time, the rate of coagulation of the field is chosen as small as is necessary for a confident "capture of magnetic resonance." Further, the device operates as a tracking system, providing changes in the magnetic field, corresponding to changes in the reference frequency of the high-frequency generator 17 of the magnetic resonance converter 3. By varying the frequency of the high-frequency generator 17 in any known way, software field control can be performed. Resetting the magnetic field and bringing the device to the initial state is carried out by applying to the reset input a pulse field temporarily opening the key 16.

The complete closure of the control loop and the introduction into it of a link with integrating properties, such as the unit driven by the reference current, gives the device the properties of an astatic system. As a result, a magnetic resonance transducer can be used not only to stabilize, but also to accurately measure the installed magnetic field.

Since the error of the measuring information coming from the output of its high-frequency generator can be essentially reduced to an arbitrarily small value, independent of the magnitude of the magnetic field. In addition, the stability of the installed field is improved, which ceases to depend on the stability of the power source, the influence of external magnetic fields, the temperature of the coils and electromagnet cores.

The invention allows to simplify the device by eliminating additional regulating coils of the electromagnet and

a DC amplifier and the replacement of a complex current stabilizer with a simpler voltage source, the stability of which is not subject to increased requirements and the sensor of the output parameter of which does not need to be thermostatically controlled. All nodes newly introduced into the device can be combined into a unit that does not require an additional source for its power supply and is structurally much simpler than the DC amplifier excluded from the device.

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Claims (2)

1. A device for creating a stable magnetic field of a given voltage, containing an electromagnet connected by magnetizing coils to the output of a controlled power source, including a control element, a differential amplifier, a comparison unit and a rectifier, one output of which is the first output of the controlled power source and the other is connected to the first the output of the control element connected by the control input to the output of the differential amplifier, the input of which is connected to the output of the comparison node, ma a nitroresonant converter including a low-frequency generator, magnetic resonance sensor, a phase detector, an amplitude detector and an adjustable high-frequency generator, the low-frequency generator being connected to a magnetic resonance sensor located between the poles of the electromagnet and one of the inputs of the phase detector, the other input of which is connected to the output an amplitude detector, an input connected to the output of an adjustable high-frequency generator, connected by an input to a magnetic resonance sensor, distinguishing In order to increase the stability of the magnetic field and the accuracy of setting its strength, the comparison unit consists of a reference current source, a controlled current divider, a pulse shaper, a capacitor, a current stabilizer and a key, and the reference current source is connected to the first output by one output controlled power supply, the other output is with the first output of the controlled current divider, and the outputs of the reference current source are the outputs of the comparison node, the first control input of the controlled current divider the output of the phase detector, the second control input to the terminal for connecting the field sweep unit and through the pulse shaper to the output of the amplitude detector, the input to the second output of the control element and the second output of the controlled power source, and the second output to its first output through parallel connected a capacitor, a current stabilizer, and a switch whose control input is connected to a terminal for connecting a field reset unit. 2. The device according to π. 1, characterized in that the controlled current divider is made on a composite transistor, between the emitter and the base of the output transistor which is connected in parallel connected controlled resistor and an additional key, while the emitter, collector and base of the composite transistor are, respectively, the input, the first and second outputs of the controlled divider current, and the control inputs of the resistor and additional key - the first and second control inputs of the controlled current divider. _h