CS212874B1 - Connection of oscillator amplitude stabilization - Google Patents

Abstract

The invention relates to basic electronic circuits. It solves the connection of amplitude stabilization of oscillations of acoustic frequencies used for powering alternating bridges and detectors in electronic length measurement. The connection is characterized by the fact that the non-inverting input of the differential amplifier of the deviation is connected via rectifier diodes and a filter capacitor and further via separation resistors directly to both symmetrical terminals of the working winding of the transformer. The inverting input of the differential amplifier of the deviation is connected to the reference voltage source via a compensation diode. The compensation diode is placed in a common thermally conductive housing β with the rectifier diodes. The invention can be used in the electrical industry.

Description

The invention relates to the amplitude stabilization of acoustic frequency oscillators used to power AC bridges and detectors in electronic length measurement.

Until now, the alternating voltages of the oscillator for the amplitude stabilization control circuits are either upstream of the output transformer, whose secondary working winding forms two branches of the AC bridge, or from a separate secondary secondary winding of the transformer. A disadvantage of the first arrangement is that the secondary winding of the transformer is not included in the control loop, thereby resulting in a decrease in the AC voltage amplitude under load exhibiting ee deviation from the desired value. In the second embodiment, an auxiliary secondary winding is included in the control loop circuit, but even in this case, due to the variation in the magnetic field of the transformer, a decrease in amplitude between the terminals of the working secondary winding of the transformer occurs. In addition, ae also exhibits the temperature dependence of the rectifier in the control voltage acquisition circuit to stabilize the amplitude of the oscillator.

These drawbacks are largely eliminated by incorporating the amplitude stabilization of the oscillator according to the invention, which is characterized in that the non-inverting differential amplifier input is connected via rectifier diodes and filter capacitor and further via isolation resistors directly to both symmetrical terminals of the transformer working winding. The inverting differential amplifier input is connected to a reference voltage source via a compensation diode. This compensation diode is housed in a common thermally conductive housing with rectifier diodes.

In the described connection, all basic characteristics of the AC bridge are captured with the maximum limitation of the influence of the two-phase rectifier on the shape and harmonic distortion of the output voltage from the bridge. The control is reliable from no load to load, given by the load capacity of the output stage of the oscillator depending on the distortion of the output signal from the oscillator.

The drawing shows the subject of the invention according to the invention. The signal for controlling the amplitude of the oscillator 0 is taken directly from the output of the working portion of the secondary winding of the transformer Tr via the separating resistors B1. R2. The magnitude of these decoupling resistors R1. 52 depends on the amount of residual interference voltage with balanced bridge. The rectified voltage is filtered by a low-pass filter formed by separating resistors R1, R2 and a filter capacitor C1. This rectified voltage is applied through the input resistor R3 to the non-inverting differential amplifier 10 input and is compared to the reference voltage applied through the compensation diode 03 and through the other resistor R4 to the inverting differential amplifier 10 input. A member consisting of feedback resistor Rg and feedback capacitor 02 serves to filter the amplified deviation £ and to stabilize the control loop. Temperature dependence of rectifier diodes D1, D2 wired by separating resistors R1. R2 and the non-inverting input of the deviance amplifier 10 is compensated by the diode D3. The rectifier diodes D1, D2 are located in a common housing and with a compensation diode D3. The amplification deviation θ controls the amplification and hence the amplitude of the oscillator 0, consisting of a pair of amplifiers and a frequency-dependent element.

The circuitry according to the invention can also be used to replace a transformer with an amplifier and a symmetrical output.

Claims (1)

Oscillator amplitude stabilization circuit used for powering AC bridges and detectors for electronic length measurement, characterized in that the non-inverting differential amplifier input (10) is connected via a diode (D1, D2) and a filter capacitor (C1) and data and isolation resistors (R1, R2) directly to both the ayetric transformer working winding terminals (Tr), while the inverting differential amplifier input (10) is connected to a reference voltage source (U _re f) and a compensation diode (D3) housed in a common thermally conductive housing (a) and rectifying diodes (D1, D2),