SU1029728A1 - Versions of transmitting device for radio spectrometer - Google Patents

Abstract

1. A transmitting device of a radio spectrometer, containing a power amplifier and a resonant circuit connected to its output, consisting of an inductor and a tunable capacitor, characterized in that, in order to increase the measurement accuracy by increasing the stability of the output voltage, it additionally contains two stabilizing chains, each of which consists of sequentially unidirectionally connected diodes and successively unidirectionally included zener diodes, the diodes in the first stabilizing The moving chain S is connected in the opposite way to the diodes in the second stabilizing chain, (A, the zener diodes are connected in the opposite way to the diodes, and the stabilizing chains are connected by their opposite polarities in parallel to the inductance coil.

Description

2. A device according to claim 1, characterized in that each stabilizing circuit further comprises a capacitor connected in parallel to the zener diodes and a series-connected resistance

and a constant voltage source, the polarity of the switching sources in the stabilizing chains opposite, as well as the resistance, connected in parallel to each diode

3. The device according to claim 2, containing a power amplifier and a resonant circuit connected to its output, consisting of an inductor and a tunable capacitor, characterized in that, in order to increase the measurement accuracy by increasing the stability of the output voltage, the device additionally contains two stabilizing chains each

from one-directionally connected diodes and one-directionally connected stabilizers, the diodes in the first stabilizing chain are connected opposite to the diodes in the second stabilizing chain, the stabilizers are connected in the direction of the diodes, and the stabilizing chains are connected in parallel to the inductance.

4. The PS device of claim 3, characterized in that each stabilizing chain further comprises a capacitor connected in parallel to the stabilizers and series-connected resistance and a constant voltage source, the polarity of switching on the sources in the stabilizing chains is opposite.

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The invention relates to the field of; and radio-frequency spectroscopy and can be used in radio-magnetic spectrometers of nuclear magnetic and nuclear quadrupole resonances.

A transmitting device of a radio spectrometer is known, which contains a power amplifier and a resonant circuit connected to its output, which contains an inductance coil and a tunable capacitor.

A disadvantage of the known spectrometer is that when a long sequence of radio frequency pulses is generated, the output voltage of the device decreases over time, which is caused by a decrease in its gain due to the charge of the bias circuits by grid currents, a drop in the emission of lamps, a drop in the Q factor of the resonant circuit due to for heating the coil inductance. As a result, the amplitude of the radio frequency magnetic field generated in the inductor decreases, which does not allow the optimal experimental conditions to be maintained during the entire pulse sequence.

This impairs the basic performance of the radio spectrometer, in particular, reduces the accuracy of measurements, and in the case of solids, the resolution.

The closest technical solution to the invention is a transmitting device of a radio spectrometer that contains a power amplifier and a resonant circuit connected to its output, consisting of an inductance coil and a tunable capacitor.

The main disadvantage of the known device is the low stability of its output voltage. During a single sequence of radio frequency pulses, its output voltage drops by 2%, which leads to a corresponding decrease in the amplitude of the radio frequency magnetic field generated in the inductance coil.

The aim of the invention is to increase the measurement accuracy by increasing the stability of the output voltage. The goal is achieved by the fact that a transmitting device of a radio spectrometer, containing a power amplifier and a resonant circuit connected to its output, consisting of an inductance coil and a tunable capacitor, additionally contains two stabilizing circuits, each of which consists of a series of unidirectionally connected diodes and sequentially unidirectionally connected zener diodes, the diodes in the first stabilizing chain being connected opposite to the diodes in the second stabilizing chain, the zener diodes in They are connected in the opposite way to the diodes, and the stabilizing chains are connected with their opposite-polarity leads parallel to the inductance coil. In addition, in the transmitter of a radio spectrometer, each stabilizing circuit additionally contains a capacitor connected in parallel to the stabilizer and a connected resistance and a source of constant voltage in series, the polarity of switching on the sources in the stabilizing chains being opposite, as well as the resistance included in parallel to each diode . In an embodiment of the invention, this goal is achieved by transmitting a radio spectrometer device with a holding power amplifier and connected to its output a resonant circuit consisting of an inductance coil and a tunable capacitor, further comprising two stabilizing chains, each of which consists of a series of unidirectionally connected diodes and sequentially unidirectionally included stabistor, and the diodes of the first stabilizing chain are connected opposite to the diodes in the second stabilize The stabilizer is connected in the direction of the diodes, and the stabilizing circuits are connected in parallel with the inductor coil with their own polarized leads. In addition, in the variant of the transmitting device of the radio spectrometer, each stabilizing chain additionally contains a capacitor connected in parallel with the stabilizers and a series-connected resistance and a constant voltage source, the polarity of switching on the sources in the stabilizing chains is opposite, as well as the resistance connected in parallel to each diode. FIG. 1 shows a diagram of a transmitter of a radio spectrometer; in fig. 2 - stabilizing chains with zener diodes; in fig. 3 - stabilizing chains with stabistors. The transmitting device of a radio spectrometer contains a power amplifier 1, a resonant circuit 2 connected to its output, consisting of an inductor 3 and a tunable capacitor 4, two stabilizing chains 5, the first stabilizing chain contains first unidirectionally connected first diodes 6 and successively connected in the opposite direction first zener diodes 7, and the second - the second diodes 8 and the second zener diodes 9, included opposite to the first diodes 6 and the first zener diodes, respectively. 7. Art. each with their different polarity leads are connected parallel to the inductor 3. The resistance chains 10 and 11, capacitors 12 and 13, resistances 1D and 15 and sources of constant voltage 16 and 17 can be connected to stabilizing chains 5 (see Fig. 2) . Each of the resistances 10 and 11 is connected in parallel to one of the first diodes 6 and the second diodes 8, respectively, a capacitor 12 and a series-connected resistance 14 and a source 16 are connected in parallel to the first zener diodes 7, a capacitor 13 and a series-connected resistance 15 and source 17 are connected in parallel to the second zener diodes 9, and the polarity of the inclusion of voltage sources 16 and 17 in the stabilizing chains is opposite. A variant of the transmitting device of the radio spectrometer contains two stabilizing ichochka 18 (see Fig. 3), which differ from the stabilizing chains 5 in that instead of the first and second zener diodes, they include the first 19 and second 20, respectively, and the direction of their inclusion coincides with the direction of the inclusion of the corresponding diodes. The transmitting device of the radio spectrometer operates as follows. The input of the power amplifier 1 is given a signal with an amplitude U and a frequency U, which is set to be close to or equal to the nuclear resonance frequency in the test sample located in the inductor 3. The amplified signal from the output of amplifier 1 is fed to resonant circuit 2, which is tuned to frequency Ы with the help of capacitor 4. At the same time, the resistance of the resonant circuit 2 and the amplitude of the output voltage are maximum, and in RF 3 magnetic field 2H, Coswt, amplitude 2H. which is proportional to o) | x, the field excites the nuclear resonance in the sample under study and determines the operating characteristics of the radio spectrometer and its capabilities in measuring the parameters of the sample. K-gain amplifier amplitude and g); the input signal is set according to the CONDITION U „. II in X, U (,, where I (, j and U (, is the sum voltage of the stabilization of the zener diodes, the first 7 and second 9, respectively. With a positive half-wave Ug, the current I flows through the first diodes 6 The resultant capacitance From the first stabilizers 7 to the voltage U,. The capacitance C j can be tens or hundreds of picofarads. Since the direct resistance of the first diodes 6 is small, the reverse resistance of the zener diodes is large, the charging time the capacitance C of the zener diodes does not exceed tenths of a microsecond. As a result, automatically a constant stabilized voltage U is generated, which backs up the first diodes 6 and sets a threshold that determines the amplitude of the positive half-wave voltage and. As this half-wave increases above U (the shunting effect of the first diodes 6 on the resonant circuit 2 increases dramatically, and decreasing it sharply decreases, so that the amplitude of the positive half-wave remains equal to the value of U. As a result, 3Tofi half-wave is stabilized at the level of U:,.; which is determined by the parameters of the first zener diodes 7 and has a high okuyu stability. The second stabilizing chain of the second diodes 8 and the second zener diodes 9 acts in a similar way. The difference is that this chain stabilizes the negative half-wave of the output voltage at the -Uj level. equal to the total stabilization voltage of the second zener diodes 9. In order for the half-wave output voltage to be positive and negative to coincide in magnitude, the zener diodes in both chains are chosen from the condition. Up. . The type and number p of the zener diodes in the chains is chosen from the condition and U o o1k the required value of the amplitude of the output voltage of the transmitting device of the radio spectrometer; and, - voltage of stabilization of one zener diode. In order to effectively stabilize this amplitude, the first diodes 6, respectively, the second 8 are chosen so that their passage capacitance does not exceed several picofarads, and the total differential resistance of the diodes in each chain does not exceed the resistance of the resonant circuit 2. At the same time, the first 6 and second 8 diodes effectively controlling the value of Uftbix by maintaining it equal to Up,., and the capacitance of the zener diodes does not affect the resonant frequency of the resonant circuit 2, since the reverse voltage on the diodes in each stabilizing chain reaches the value, then the number of diodes m is chosen from the condition mU 2U,, (2) where is the allowable inverse of a single diode. Since the reverse resistance of the diodes is usually not the same, the reverse voltage is distributed unevenly across the diodes. This can lead to the breakdown of a diode with maximum inverse resistance, and then all the diodes in the chain. To prevent this, parallel to each of the diodes include one and the resistances 10 and 11, respectively, which have the same value, not exceeding the minimum inverse resistance of the diodes (see Fig. 2). To maximize stabilization of the output voltage of the device, parallel to the zener diodes in the chains include capacitors 12 and 13 and the displacement circuit, consisting of resistances 14 and 15 and and: DC voltage sources 16 and 17 and ensuring the displacement of the zener diodes in the opposite direction to the voltage U (see Fig. 2). The polarity of switching on sources 16 and 17 is mutually opposite, since the opposite polarity of switching on zener diodes, respectively, the first 7 and second 9. Resistances 14 and 15 are chosen to be such. the value exceeded the total differential resistance R of zener diodes in each chain. Sources 16 and 17 are chosen such that their emf exceeds the value of Up and provides such a bias current through zener diodes, at which the value of R ,, is minimal. In this case, the Zener diodes are acted upon by a constant voltage U and -U, respectively, for the first and second, which is given by the bias circuit, which backs up the corresponding diodes of the clock. It has maximum stability. This ensures maximum stability of the output voltage of the device. The capacitance C of the capacitors 12 and 13 is selected according to the condition. 1 / Ы (С Ср) "RCT ГГри this voltage ripple and" and 1, - on zener diodes with frequency fZ are minimal, which improves the stabilization of the output voltage of the device, For maximum suppression of the amplitude pulsations V of this voltage, caused, for example, noise or parasitic modulation with the frequency of the mains voltage, the capacitance C of the capacitors 12 and 13 is chosen according to the condition 1/5 (C + C) 3iRj, where si is the frequency of the specified pulsations. In this case, the ripple voltage -dt and U |. with a frequency n small, which increases the shunting effect of diodes at this frequency and provides maximum suppression of the amplitude pulsations of the output voltage of the device, chains of diodes and zener diodes (see figs 1 and 2) allow the amplitude of the output voltage of the transmitting device of the radio spectrometer to stabilize the level lying in the range from a few volts to several thousand h-vol. The quality of the output voltage amplitude stabilization was measured at the transmitting device of the radio spectrometer operating at 14 MHz and providing 500 V. The device in each chain contained 5 D817V zener diodes from 20 KD 509A diodes, each of which was l / shunted by 10 kΩ. m „,,„. “The measurement showed that with uninterrupted operation of the device for 10 s from the moment of its launch, the decrease in the amplitude U did not exceed 0%, 1%. This is 50 times less than with stabilizing chains of 5 turned off, and 20 times less than in the case of the prototype. The operation of another variant of the proposed transmitting device of a radio spectrometer, in which the chains are made up of diodes and stabilizers (see Fig. 3), is similar to the described embodiment. In this case, the stabistors,. The first 19 and second 20, work similarly to Zener diodes. The use of stabilizers makes it possible to stabilize the output voltage of the device at a level that ranges from volts to a few volts, since the stabilization voltage of the stabilizers lies in this range. This level of stabilization is necessary in radio spectrometers operating in a steady state, for example, in nuclear magnetic resonance spectrometers with crossed coils.

Claims (4)

1. The transmitting device of the radio spectrometer containing a power amplifier and a resonant circuit connected to its output, consisting of an inductor and a tunable capacitor, characterized in that, in order to increase the accuracy of measurements by increasing the stability of the output voltage, it additionally contains two stabilizing chains, each of which consists of sequentially unidirectionally connected diodes and sequentially unidirectionally connected zener diodes, and the diodes in the first stabilizing chain oppositely diodes included in the second stabilizing chain, zener diodes are included opposite and stabilizing its chain terminals of different polarities are connected in parallel inductor. FIG. one 2. The device according to claim 1, characterized in that each stabilizing circuit further comprises a capacitor connected in parallel to the zener diodes and a resistance and a constant voltage source connected in series, the polarity of switching on the sources in the stabilizing chains being opposite, as well as the resistance connected in parallel to each diode. 3. The device according to claim 2, containing a power amplifier and a resonant circuit connected to its output, consisting of an inductor and a tunable capacitor, characterized in that, in order to increase the accuracy of measurements by increasing the stability of the output voltage, the device further comprises two stabilizing chains, each of which consists of sequentially unidirectionally connected diodes and sequentially unidirectionally connected stabilizers, and the diodes in the first stabilizing chain are included Opposite to the diodes in the second stabilizing circuit, the stabilizers are turned on in the direction of switching on the diodes, and the stabilizing circuits are connected in parallel with the inductor with their bipolar leads. 4. The device pop.Z, characterized in that each stabilizing circuit further comprises a capacitor connected in parallel with the stabilizers and a series-connected resistance and a constant voltage source, and the polarity of the inclusion of sources in the stabilizing chains is opposite.