SU696287A1 - Displacement-to-dc transducer - Google Patents

Description

(54) MOVEMENT TRANSMITTER E DC VOLTAGE

one

This invention relates to automatic control systems and. regulation.

Converters to direct current 1 are known. However, multiple conversion of the sensor signal greatly complicates such converters and reduces the stability of the transfer coefficient.

The closest in technical cyni is a direct current displacement transducer containing a differential inductive displacement transducer with primary and secondary windings, a blocking generator with transformer positive-feedback, a sensor output amplifier with negative feedback for alternating current and rectifier Press output 2.

However, such a converter has an error near zero due to the presence of a devi ate degree component of the sensor unbalance signal.

To improve the conversion accuracy, the primary winding of the displacement sensor is switched on in a positive feedback circuit of the blocking generator and an additional capacitor is connected to the same circuit, and the secondary winding of the displacement sensor is connected in parallel with the primary winding through an additional resistor, the resistance value is several times greater impedance of sensor windings.

The drawing shows the proposed Converter.

The converter contains a differential inductive sensor 1, with a primary winding 2 and a secondary winding 3, a compensation resistor 4, a positive feedback locking generator 5 used to power the sensor, a sensor 6 output amplifier with a negative current register 7 7, amplifier 8 output rectifier and load circuit 9.

The primary winding 2 of the sensor is connected to the positive feedback circuit of the block ng-generator 5 and an additional capacitor 10 is connected to the same circuit.

0, the capacitor 10 is selected so that the capacitor 10 and the inductance of the primary winding 2 of the sensor 1 form an oscillating circuit.

(iiii ;;; iiif; n / KCH; iSj fiHTannsi and the mode of operation of the trs ii3f CTopo8. This fits the stability of K.; e (lf1; i.pe;: t; persdmic sensor;) i ;, c.k don; gge ,, iscero 1 Former in general.

Well, fishery. The sensor's unbalance signal at its output consists of the devast-degree component of the main signal and the HIGH-ORI.H harmonics. The compensatory den nostogra / sushiyu constitute the yupgey of the actions.

When threading x atchik 1 from the generator and at the increased frequency of 5, the limit of the juli in nolio .m the resistance of the sensor windings is an inductive component. Therefore, when the secondary winding 3 is turned on, it is opposed to the primary winding Z through a resistor 4, the resistance of which is an order of magnitude greater than the resistance of the windings, but a current flows, actually coinciding in c)) voltage with the voltage on the nervous winding, and the voltage drop from it The current on the secondary winding is in the frontal phase with the posto centigrade component of the unbalance voltage of the sensor output. The resistance value of the resistor 4 is chosen as follows. so that the voltage drop on the secondary winding 3 from the primary current 2 is equal to the value of the unstage component of the unbalance voltage at the sensor output.

d

Tests of the proposed converter showed that the magnitude of the error at zero .1 can be reduced by a factor of 3-5 compared with the known converter.

Claims (2)

1. Kaplunov I. B. Mironov V. D. Normalizing transformers of the VTI system. ML, “Energie, 1964, p. 32. 2.Stunel F.A. Electro.mechanical sensors and transducers of non-electrical quantities. M-L., “Energie, 1965, p. 40 (prote) tii).