SU807401A1 - Contact-free end-face change-over switch - Google Patents

Description

one

The invention relates to the automatic control of electrical systems and can be used primarily in mechanical engineering, machine-tool construction for track control and for monitoring the position of workpieces or various components and mechanisms without direct, mechanical contact with them.

Circuits of contactless grounding switches are known, which contain an electric oscillation transistor oscillator, a position sensor with an inductance circuit, made in an open cup of a ferrite core, a detector, a trigger, and a voltage stabilizer l.

However, the switch circuits are subject to lateral influence of metallic masses, which impairs the stability of the switching point (i.e.), i.e. the stability of the accuracy characteristics depends on the presence of metallic masses located on the periphery of the position sensor. The relativity of the output characteristics is not enough, which leads to instability of the accuracy characteristics. The value of the load resistance of the executive apparatus is limited. The two-stage transistor amplifier is controlled by the variable component of the input signal, which requires the introduction of a detector and, accordingly, an additional inductance winding placed in the core of the position sensor, which causes an increase in the dimensions of the core and switch.

The closest in technical essence to the present invention is a non-contact limit switch that contains an electrical oscillator, a position sensor with an inductance circuit made in the open cup of the ferrite core, a detector, a trigger with a power amplifier and a stabilizer.

0 voltage, made on the basis of a zener diode.

However, the circuit breaker is subject to the influence of metallic masses located on the periphery

5 of the position sensor, which degrades the stability of accuracy characteristics, and the presence of a detector complicates the generator matching circuit with a trigger. In addition, a significant drawback of known devices is in violation of the unambiguity of the output signal when the control element is on the edge or (the difference along the path between the points of switching on and off, i.e. between the breakdown and the occurrence of a switch generation) when the supply voltage is turned on or when it changes in an abrupt change in the allowable limit This is caused by interference from the power supply circuit from electromagnetic devices operating in parallel from the same source. The purpose of the invention is to improve the stability of the device in the area of the travel differential, the stability of the accuracy parameters and the noise immunity of the circuit. The goal is achieved by the fact that the switch is equipped with a capacitor and a voltage divider connected between the inductance circuit of the position sensor and the anode of the voltage stabilizer's zener, with the positive capacitor plate connected to the stabilizer cathode and the negative plate to the voltage divider middle point. In addition, in order to increase the stability of the switch-on point (disconnection), it is equipped with a leakage capacitor, with the case of the open cup of the ferrite core of the position sensor being connected to the anode of the voltage stabilizer zener diode through the leakage capacitor. At the same time, in order to increase the noise immunity, a resistor is included in the base circuit: the electrical oscillator transistor. The drawing shows a circuit diagram of the proposed non-contact end switch. A proximity switch contains a position sensor made from inductive circuit 1 placed in an open plate 2 of a ferrite core, the casing of which through a leakage capacitor 3 is connected to the anode of a zener diode 4 a pair of metric voltage regulator Part 5 of an inductance circuit with a capacitor b forms an oscillating circuit, the output of which is through a series-connected zener diode 7, connected in the forward direction and shunted by a capacitor 8, and a resistor 9 is connected at the base of an electrical generator base of the common ranges made on the transistor 1 Resistor 11, connected to the emitter circuit of transistor 10, and the second part 12 of the circuit and duct, connected by another output through a capacitor 13 to the zener diode 4, are connected to a common point of inductive circuit 1. , through a voltage divider consisting of resistors. 14 and 15, to the anode of the Zener diode 4, as well as to the input of the trigger 16 assembled on transistors 17 and 18 with a Uurog resistor 19. The middle point of the voltage divider 14, 15 is connected to the negative plate of the capacitor -20, the positive plate of which is connected to the cathode of the zener diode 4. The operating point of the electrical oscillator transistor 10 is established by the resistor 21. The transistor electrical oscillator and the trigger 16 are covered by a stabilizing cell consisting of a resistor 22 and a zener diode 4. The output of the trigger 16 is coordinated a power amplifier, assembled on the transistor 23, a collector circuit of which is connected a load impedance 2.4. Contactless end switch operates as follows. When the supply voltage is applied and there is no control element in the zone of the differential of the stroke, in which the controlled object or a steel plate is used, the generator transistor .10 opens due to the bias resistor 21. The current pulse flowing through the half-open transistor 10 and part 12 of the inductance circuit, defined mainly by the grain of the resistor 11, excites the oscillating circuit 5.6. The generator goes into self-oscillation mode with maximal amplitude. In self-oscillation mode, a generator circuit consisting of an open transistor 10, resistor 11, part 12 of the winding circuit of the inductance and voltage divider 14, 15 is flowing, the constant component of which high-frequency oscillations creates a voltage on the divider 14, 15 exceeding the threshold value of the switching element (trigger) 16, and the variable component is blocked by the capacitor 13. In this case, the trigger 16 goes into one of the stable states; the transistor 17 is open and the transistor 18 is closed. The threshold value of the trigger 16 is determined by the resistance value of the resistor 19 in the E1 "1-circuit of the transistor 17. Since the power amplifier is performed on the transistor 23 of direct conduction (pnp), and the trigger 16 on transistors 17 and 18 of the inverse conductivity pp), then connecting the power amplifier input to the trigger output provides good matching circuit conditions and allows electromagnetic relays with a wide range of winding resistance values to be used as a load. Transistor 23 repeats the state of transistor 18, i.e. in this state it is closed, and no current flows through the load 24. Connecting in series with the oscillatory circuit 5,6 3 the base circuit of the transistor 10 of the Zener diode 7 in the forward direction, shunted by the capacitor 8, contributes to the compensation of the temperature error, since the Zener diode has a negative TKN, which ensures the stabilization of the switch point. In addition, the shunting of the Zener diode 7 by the capacitor 8 provides a relay of breakdown and generation, reduces the magnitude of the travel differential, and also simplifies the matching circuit of the generator with the trigger 16, which also contributes to the stability of the accuracy parameters and increased reliability of the device. When the control element is introduced into the zone of action of the electric field formed at the end of the cup 2 of the ferrite core of the position sensor by the inductance circuit, the oscillation amplitude changes (decreases) in the oscillation amplitude due to the attenuation of the oscillator circuit 5.6. the element from the end of part 2 of the ferrite core, the amplitude of the generated oscillations abruptly decreases to the value at which the trigger 16 changes to another stable state. In this case, the input of the base-emitter transistor 10 with the resistor 11, the bias resistor 21 is shunted by a stable 7 and a part 5 of the inductance circuit, whereby the transistor 10 is closed. Thus, the voltage drop on the divider 14, 15 is sharply reduced due to a tenfold decrease in the current flowing through the circuit: plus a source of stabilized voltage — resistor 21 Zener diode 7 — inductance circuit 5.12 — divider 14, 15 — minus stabilized voltage, which causes the trigger 16 to switch to another steady state; the transistor 17 is closed, and the transistors 18 and 23 respectively open, turning on the load 24. This position of the control element corresponds to the switching point of the switch. When the control element returns from the trigger point for a certain distance, due to a decrease in insertion loss, the amplitude of the generated oscillations increases, and when the voltage on the divider 14, 15 is equal to the threshold value of the trigger 16, the amplitude of oscillations increases abruptly to the value at which trigger 16 goes to the initial state. This position of the control element corresponds to the switch off (return) point of the switch. The difference in distance between the return point and the switch actuation point constitutes the stroke differential zone. If the control element is in the area of the travel differential or in its boundary positions, there are false switchings caused by the presence of interference, an abrupt change in the voltage of the transmitter within acceptable limits (for example, in the proposed device from 20 to 30 V) and during repeated power supply and re-supply, i.e. the switches do not have a one-to-one switch (do not remain only in the disabled or only in the on state). The introduction of a capacitor 20, the negative lining of which is connected to the midpoint of the voltage divider 14, 15, and the positive lining to the cathode of the Zener voltage stabilizer, eliminates this disadvantage. If the control element is in the area of the stroke differential, then when the supply voltage is removed and then re-applied to the current pulse switch along the circuit: plus stabilized voltage - capacitor 20 - resistor 14, voltage divider 14.15 - base-emitter junction transistor 17 - resistor 19 - minus stabilized voltage pushes transistor 17 (for a few ms). At the same time, voltage divider 14, 15 is shunted by a pn junction of the base-emitter of transistor 17 and thresholds connected in series to the emitter circuit of transistor 17 resistor 19, a trigger 16, which causes an abrupt increase in the amplitude of oscillations of the generator. The relay increased - the amplitude of self-oscillations increases the constant component of the current flowing through the divider 14, 15, i.e. the increased voltage drop across it, which has reached the threshold value of the trigger 16, confirms the on state of the trigger 16 (transistor 17 is open, transistor 18 and, accordingly, transistor 23 are closed, load 24 is de-energized). This state is confirmed every time when the switch is de-energized and energized at the switch at any point of the stroke differential when the control element is removed (returned) to the return point and then (attenuation introduced

in the circuit of the switch with a steel plate, decreases).

If the control element is located at the switching point of the switch, the described chain creates a small delay (several ms) for switching on the load 24.

With a constant voltage across the switch, the capacitor 20 does not affect the operation of the switch circuit.

When the control element is located in the area of the stroke differential, the same processes also occur in case of a sudden change in the supply voltage at a predetermined interval or when interference occurs from electromagnetic devices powered by the same power source. Interference immunity of the switch circuit in any position of the control element is achieved by including in the base of the transistor 10 an oscillator of electrical oscillations in series with the oscillating circuit 5, 6 and the zener diode 7, the fused capacitor 8, fused 8, the resistor 9.

The inclusion of a ferrite core between the case of chgyika 2 and the anode of the Zener diode 4 of the voltage stabilizer of the leakage capacitor 3 provides for an increase in the stability of the switch-on point when the controlled object is brought close to the switch-on point. In such a position, in the case of the presence of ferrymagnetic masses located on the periphery of the sensor, the position, a premature actuation of over- can occur. key due to the presence of a charge formed between the inductance circuit 1 of the position sensor and the cup, 2 ferrite cores. The introduction of a leakage capacitor 3 removes this charge from the surface of the ferrite cup, thereby ensuring that the turn-off point is stable.

The use of the proposed device will improve the stability of the accuracy parameters, eliminate the influence of ferromagnetic masses located around the periphery of the position sensor, ensure the unambiguity of the output signal when the control element is on the verge or

in the area of the stroke differential, with repeated disconnection and supplying of the supply voltage or with its sudden change in the allowable range of oscillations, to increase the noise immunity of the circuit, which leads to increased reliability of the device as a whole.

Claims (3)

1. A non-contact end switch containing a transistor electric oscillator, a position sensor, the inductance circuit of which is made in an open cup of a ferrite core, a trigger with a power amplifier and a voltage stabilizer rypolnenny based on a zener diode that differs from stability of operation in the area of the stroke differential, it is equipped with a capacitor and a voltage divider, VC, Schychenny between the output of the inductance circuit of the position sensor and the anode a voltage stabilizer diode, with a positive capacitor plate attached to the stabilizer diode cathode, and a negative  lining - to the midpoint of the divider  tension 2. The switch according to claim 1, wherein in order to increase the stability of the switching point (h), it is provided with a leakage capacitor, the housing of the open cup of the ferrite core of the position sensor being connected to the voltage stabilizer zener diode through the leakage capacitor. 0 3. The switch according to claim 1, that is, in order to increase the immunity, it is equipped with an additional resistor included in the basic circuit of the transistor of the electrical oscillator. Sources of information taken into account in the examination 1. USSR author's certificate 484641 ,. cl. H 03, K 17/56, 1972. 2. Catalog of the company Gebhavd Balluff. Germany, Cologne, 1975.