SU657360A1 - Arbitrary shape voltage converter - Google Patents

Claims (2)

thermal converter, the other output terminal of which is connected to a DC voltage source, master oscillator, the output of the latter is connected to the control input of the modulator and a negative feedback circuit connected between the modulator output and the thermal converter's heater, and the corresponding terminals The depy, the thermal converter heater, the constant voltage source, and the modulator are connected to the common converter bus between the device input and the control input of the master oscillator. and connected in series-connected filter and detector. The drawing shows a functional diagram of the proposed converter. A free-form voltage converter contains an input terminal 1, a bus 2, a thermal converter 4, a source 5, a modulator 6, a generator 7, a negative feedback circuit 8, a filter 9, a detector 10, and an output terminal 11. The signal voltage from the input terminals 1 to the common bus 2 is supplied through the decoupling circuit 3 to the heater of the thermal converter 4, while the output of the thermal converter 4 produces a constant voltage. The difference between this voltage and the voltage of source 5 is fed to the input of modulator 6, which modulates this difference into an alternating voltage and, if necessary, amplifies it. The module is controlled by the master oscillator 7. The alternating voltage from the output of the modulator 6 through the negative feedback circuit 8 is supplied to the heater of the thermal converter 4, closing the negative feedback loop of the converter, which stabilizes the transfer characteristic of the converter. The unwinding circuit 3 is designed to prevent negative feedback from the alternating voltage acting on the heater of the thermal converter 4 to the input of the device. At any value of the input voltage of the converter from zero to the nominal value, the voltage of the source 5 causes the same negative voltage at the output of the thermocouple 4, which is possible with almost constant power on the heater of the thermoconverter 4 power on the heater thermocouple 4 provides increased accuracy of the converter. The frequency of the master oscillator 7 is selected in the normal frequency range of the converter (i.e., in the frequency region where the frequency error of the device is absent), the voltage from the input terminal 1 goes to the band-pass filter 9 tuned to the frequency of the master oscillator 7. If the frequency of the input voltage transducer or the harmonic frequency of the input voltage b. 1 is the frequency of the master oscillator 7, the input voltage passes the filter 9, is detected by the detector 10 and is fed to the control input of the master oscillator 7. Last channeling a way that on the occurrence at its control input DC voltage, it begins to operate at a different frequency, different from the fundamental frequency. Another frequency generator 7 is also selected in the normal frequency range of the converter, and both frequencies of the generator 7 must be chosen so that the frequency of the input voltage of the converter or the harmonic frequency of the input voltage does not coincide with one frequency of the generator 7, does not have to coincide with another frequency RATOR 7. The output terminal 11 of the converter is connected to the output of the modulator 6. Thus, when an arbitrary form of voltage transducer appears at the input, a certain form voltage (for example, sinusoidal) appears at the output of the converter. The relationship between the input and output voltages of the converter is determined by the negative feedback circuit 8. The converter has a higher accuracy than the known device, since both modulation frequencies are selected in the normal frequency range of the converter, i.e. where there is no frequency response of the device, while in the known device the modulation frequency is chosen outside the working frequency range of the converter, i.e. where the accuracy of the device is not even normalized. If necessary, to improve the accuracy of the device in the circuit: thermal converter 4 - modulator 6 - filter 9 - detector 10 g Amplifier control circuit 7 amplifiers can be added. Claims of the Arbitrary Voltage Converter containing a thermal converter, to the heater of which a device input, a modulator is connected through an uncoupling circuit, one output terminal of a thermal converter is connected to its input, the other output terminal of which is connected to a source of direct current voltage, and a master oscillator , the output of the latter is connected to the control input of the modulator in the negative feedback circuit connected between the output of the modulator and the heater of the thermal converter, n What are the corresponding clearances of the breaker circuit, the heater of the thermal converter, the constant voltage source and the modulator connected to the common bus of the converter, which, in order to improve the conversion accuracy, between the input of the device and the control input of the master oscillator connected in series filter and detector. Sources of information taken into account in the examination 1. US Patent No. 3521164, cl. 324-76, 1968. 2. Volgin L.I. Linear electric converters for measuring devices and systems. M., Sov. radio, 1971, p. 188.