RU2231900C2 - Device for electrical isolation of signals - Google Patents

Abstract

FIELD: measurement technology.

SUBSTANCE: device has free-running blocking-oscillator 1 with loading winding 2 and compensating winding 3, two resistive dividers 4 and 5, five capacitors 6 through 10, terminals 11.1, 11.2, 16.1, 16.2 for connecting signal source and signal receiver, respectively, first terminal 11.2 meant for signal source being connected to series-interconnected resistor 12 and first capacitor 6, as well as three diodes 13, 14, 15. Anode of first diode 13 is connected to starting lead of loading winding 2 and cathode, to first leads of second capacitor 7 and first resistive divider 4 whose second lead is connected to that of second capacitor 7 and to finishing leads of loading winding 2. Starting lead of compensating winding 3 is connected to anode of second diode 14 whose cathode is connected to first leads of third capacitor 8 and second resistive divider 5; second lead of the latter is connected to anode of third diode 15, cathode of the latter is connected to second lead of third capacitor 8 and to finishing leads of compensating winding 3. Midpoint of first resistive divider 4 is connected to first terminal 16.1 of signal receiver and through fourth capacitor 9, to midpoint of second resistive divider 5 and to finishing lead of loading winding 2. Terminals 16.1 and 16.2 meant for signal receiver are interconnected through fifth capacitor 10. Resistor 12 and first capacitor 6 are connected to plus power lead of blocking-oscillator 1; minus power lead is connected to second lead of first capacitor 6 and to terminal 11.2 meant for power supply. Second terminal 16.2 meant for signal receiver is connected to cathode of third diode.

EFFECT: simplified design, reduced power requirement of device.

2 cl, 2 dwg

Description

The invention relates to measuring technique and is intended for galvanic separation of input and output signals.

A device for decoupling potentials is known (see. Advanced production and technical experience. Intersectoral abstract collection. VIMI, T9 series, issue 3, 1986, pp. 50-52, PPTO T9.03. W 53371 (S.464-83 ) containing an input signal source connected to an input stage with a differential output connected to a balancer modulator, the control inputs of which are connected to the inverse outputs of the master oscillator.The transformer output of the master oscillator is connected to the control input of the synchronous demodulator, whose transformer input is It is connected to the transformer output of the balance modulator.The output of the synchronous demodulator is connected to the input of the active RC filter, the power supply circuit of the master oscillator is connected to the first power source.The power supply circuits of the input stage of the balanced modulator, the synchronous detector and the active RC filter are connected to the first and second power sources.

The disadvantages of this device are the complexity and high power consumption due to two additional to the input signal source, power sources, two pulse transformers, a large number of digital and analog microcircuits, and other radio elements.

The closest set of essential features and the proposed invention is a device for galvanic separation of signals (see Practical circuitry in industrial automation. MV Halperin, M., Energoatomizdat, 1987, p. 272, Fig. 7.4), containing a self-oscillating master a blocking generator with two load windings, the power circuit of which is connected to the positive and negative terminals of the power source, the first load winding of which is connected to the base-emitter circuits of the transistor modulator, the second the narrow winding of which is connected to the base-emitter circuits of the transistor demodulator connected to the terminals for connecting the signal receiver. The transistor modulator contains two transistors, a four-winding pulse transformer. The first and second modulator resistors are connected to the signal source connection terminals. Other outputs of these resistors are connected to the modulator windings and the first and second capacitors connected in series, the third, fourth, fifth, sixth capacitors and the third, fourth, fifth resistors of the transistor demodulator. The control input and signal output of the modulator are connected to the first and second resistive dividers, respectively.

The disadvantage of this device is the complexity and high power consumption due to the presence (additional to the input signal source) of a power source, two pulse transformers, a large number of active and passive electro-radio elements.

The task to which the invention is directed is to simplify the device and reduce the power consumption of the device.

The technical result, which consists in simplifying and reducing energy consumption, is achieved by the fact that the device for galvanic separation of signals contains a self-oscillating blocking generator with a load winding, two resistive dividers, five capacitors, terminals for connecting the signal source and signal receiver, respectively, the first terminal for connecting the signal source is connected to a resistor and a first capacitor connected in series, three diodes are introduced, and a self-oscillating blocking generator is supplied a compensating winding, the anode of the first diode is connected to the beginning of the load winding of the blocking generator, the cathode is connected to the first terminals of the second capacitor and the first resistive divider, the second terminal of which is connected to the second terminal of the second capacitor and the end of the load winding of the blocking generator, the beginning of the compensating winding of which is connected to the anode of the second diode, the cathode of which is connected to the first terminals of the third capacitor and the second resistive divider, the second terminal of which is connected to the anode of the third diode, the cathode is cat It is connected to the second terminal of the third capacitor and the end of the compensation winding of the blocking generator, the midpoint of the first resistive divider is connected to the first terminal for connecting the signal receiver and through the fourth capacitor to the midpoint of the second resistive divider and the end of the load winding of the blocking generator, terminal for connecting the receiver the signal through the fifth capacitor are interconnected, the connection point of the resistor and the first capacitor is connected to the positive power output of the blocking generator, min oic supply terminal of which is connected to the second terminal of the first capacitor and a second terminal for connecting a signal source, a second terminal for connecting the receiver signal is connected to the cathode of the third diode. In addition, the self-oscillating blocking generator contains a pnp transistor, a pulse transformer with a base and collector windings, a diode, a capacitor and two resistors, and the positive output terminal of the blocking generator is connected to the emitter of the pnp transistor and through the capacitor to the beginning of the base winding of the pulse transformer and one of the terminals of the first resistor, the other terminal of which is connected to the negative terminal of the power supply of the blocking generator and the end of the collector winding of the pulse transformer, the end of the base winding of which key via a second resistor to the base of p-n-p transistor, the collector of which is connected to the top of the collector winding of the pulse transformer and the cathode of the diode, the anode of which is connected with the end of the winding of the pulse transformer and the collector terminal of the power supply self-oscillation of the blocking oscillator.

The specified set of features allows us to simplify the device for galvanic separation of signals and reduce power consumption by reducing a significant number of electro-radio elements and eliminating the power source.

The resistor in the base circuit of the rnp transistor of the self-oscillating blocking generator provides an increase in the voltage drop across the load and compensating windings.

Figure 1 shows the structural diagram of a device for galvanic separation of signals.

Figure 2 shows the timing diagram of its operation.

A device for galvanic separation of signals (see figure 1) contains a self-oscillating blocking generator 1 with load 2 and compensating 3 windings, the first 4 and second 5 resistive dividers, the first 6, second 7, third 8, fourth 9, fifth 10 capacitors. Terminals 11.1, 11.2 for connecting a slowly varying positive voltage signal source, the first terminal 11.1 for connecting a signal source is connected to a resistor 12 and a first capacitor 6 connected in series, the connection point of which is connected to the positive power terminal of the blocking generator 1, whose negative power terminal connected to the second terminal of the capacitor 6 and the second terminal 11.2 for connecting the signal source. The anode of the first diode 13 is connected to the beginning of the load winding 2, the cathode is connected to the first terminals of the capacitor 7 and the resistive divider 4, the second terminal of which is connected to the second output of the capacitor 7 and the end of the load winding 2. The start of the compensating winding 3 of the blocking generator is connected to the anode of the second diode 14, the cathode of which is connected to the first terminals of the capacitor 8 and the resistive divider 5, the second terminal of which is connected to the anode of the third diode 15, the cathode of which is connected to the second terminal of the capacitor 8 and the end of the compensation winding 3. Medium Thread point of the resistive divider 4 is connected to the receiver for connecting the first signal terminal 16.1 and via a capacitor 9 to the middle point of the resistive divider 5 and the end of the loading coil 2. The terminals 16.1, 16.2 for connecting the receiver signal through the capacitor 10 are interconnected. The second terminal 16.2 for connecting the signal receiver is connected to the cathode of the diode 15.

Self-oscillating blocking generator 1 contains a pnp transistor 18, a pulse transformer 18, a diode 19, a capacitor 20, the first 21 and second 22 resistors. The positive power terminal of the blocking generator 1 is connected to the emitter of the pnp transistor 17 and through the capacitor 20 to the beginning of the base winding 23 and one of the terminals of the resistor 21, the other terminal of which is connected to the negative power terminal of the blocking generator 1 and the end of the collector winding 24 The end of the base winding 23 is connected through a resistor 22 to the base of the pnp transistor 17, the collector of which is connected to the beginning of the collector winding 24 and the cathode of the diode 19, the anode of which is connected to the end of the collector winding and the negative output terminal of the self-oscillating blocking 1 for generators.

Resistive divider 5 is made on two series-connected resistors 24, 25.

A device for galvanic separation of signals operates as follows.

The transformation ratios of the pulse transformer 18 of the self-oscillating blocking generator are 2: 1: 2: 1 for collector 24, base 23, load 2 and compensating 3 windings, respectively.

During the calculation and experimental work, it was found that when applying different input voltages U ₁₁ to terminals 11.1, 11.2 for connecting a signal source (see U ₁₁ , figure 2), the blocking generator 1 generates voltage pulses U ₁ from the collector winding 24 (see U ₁ , figure 2). In this case, the magnitudes of the voltages U ₁ at the collector winding 24 and the voltages U ₁₁ at the terminals 11.1, 11.2 are equal in amplitude. The voltage pulses U ₂ on the load winding 2 (see U ₂ , figure 2) is less than the input voltage U ₁₁ by the value Δ U ₂ losses. The voltage pulses U ₃ on the compensating winding 3 (see U ₃ , figure 2) are half the number of pulses U ₂ , which is determined by the transformation coefficient. The voltage U ₇ (see U ₇ , FIG. 2) on the capacitor 7 of the peak detector formed by the diode 13 and the capacitor 7 is less than the input voltage U ₁₁ by the value U ₁₃ of the voltage drop across the diode 13 and a value proportional to the current J ₁ in the resistive divider 4 and the windings of the blocking generator, as well as the resistance to losses in it, R _no .

U ₇ = U ₁₁ -U ₁₃ -J ₁ × R _no

Here, the magnitude of the voltage U ₁₃ depends on the magnitude of the input voltage U ₁₁ through the current in the winding 2 and depends on the ambient temperature. The temperature coefficient of voltage U _{7 is} approximately equal to the temperature coefficient of diode 13. This is 2-3 MV / ° C. The loss resistance R _no reflects the reduced resistance of the signal source at terminals 11.1, 11.2, the small resistance of the resistor 12, the resistance of the open transistor 17, the resistance of the windings and losses in the core of the pulse transformer 18.

которые детектируются пиковым детектором, образованным диодом 14 и конденсатором 8.Compensating winding 3 generates voltage pulses

which are detected by a peak detector formed by a diode 14 and a capacitor 8.

Its voltage provides a current J ₂ at the resistive divider 5 and diode 15, the value of which, like the current value J ₁ , is proportional to the value of the input voltage U ₁₁ . The selection of the resistances R ₂₄ , R ₂₅ formed by the resistors 24, 25 of the divider 5 and the type of diode 15 (by the value of the temperature coefficient of voltage) provides such a current J ₂ that the sum of the voltage U ₁₅ on the diode 15 and the voltage U ₂₅ on the resistor 25 (U ₁₅ + U ₂₅ , FIG. 2) compensated for the sum of voltages U ₁₃ + J ₁ × R _no . In all operating conditions, U ₁₃ = U ₁₅ , J ₁ × R _no = J ₂ × R ₂₅ = U ₂₅ . In this case, the maximum total output voltage U ₁₆ at terminals 16.1, 16.2 for connecting a signal receiver is determined by the formula

U ₁₆ = U ₁₁ -U ₁₃ -J ₁ × R _no + U ₁₅ + J ₂ × R ₂₅ = U ₁₁

and therefore, equal to the input voltage U ₁₁ . If necessary, an increase or decrease in voltage u _{16 is} achieved by changing the resistance of the resistors of the divider 4, it also sets the specified gear ratio. Capacitors 9 and 10 smooth out the voltage ripple at terminals 16.1, 16.2 to connect the signal receiver to acceptable values.

At the moment of formation of short positive pulses U _{1, the} blocking generator 1 selects a short current pulse from capacitor 6. At the time of a long pause, the transistor 17 is locked, and the capacitor 6 is recharged through the resistor 12 to the full input voltage U _{11 with a} small current. The circuit formed by the resistor 12 and the capacitor 6 unloads the signal source (not shown in FIG. 1) from large pulsed currents when the transistor 17 is unlocked, increases and stabilizes the transmission coefficient of the device as a whole, and reduces the influence of the output resistance of the signal source on terminals 11.1, 11.2.

Due to the transfer of the limiting resistor 22 from the emitter circuit to the base circuit, the voltage drop across the collector of the pnp transistor is increased, which means the transmission coefficient of the device as a whole. The collector-emitter saturation voltage is small, and its temperature coefficient (40 μV / ° C) is small. The voltage drop during the transition from the "closed" to the "saturation" mode is greater.

The claimed invention allows to simplify the device for the galvanic separation of signals and reduce power consumption by eliminating the power source and reducing a significant number of electro-radio elements.

The device picks up a small current from the signal source. The current value is small due to the greater duty cycle of the pulses and the greater resistance of the resistors of the dividers 4, 5. A large duty cycle allows more efficient stabilization of the transmission coefficient from the influence of the resistance of the signal source using resistor 12 and capacitor 6, which form a smoothing, integrating circuit.

The stability of the transmission coefficient in the range of input voltages, operating temperatures, aging is provided by diode-resistive circuits together with a compensating winding. The limiting resistor 22 in the base circuit also stabilizes the gain of the device.

The device for galvanic separation of signals used domestic electro-radio elements. Input voltage at terminals 11.1, 11.2. varied from 1.1 to 10 V, the output (galvanically isolated) voltage at terminals 16.1, 16.2 varied from 1.1 to 10 V, respectively, with a transmission coefficient equal to 1.0 unit. Resistive dividers 4, 5 set the transmission coefficient equal to 1.0 unit. The instability of the transmission coefficient over the input signal range is ± 0.2%, the instability in the temperature range (-40 + 50 ° C) is ± 0.4%. The input current at terminals 11.1, 11.2 of the signal source is 0.2 mA at an input voltage of U ₁₁ equal to 10 B. The input current at terminals 11 of the signal source is 60 μA at an input voltage of U ₁₁ equal to 1.1 V. The device does not need a source power, the number of elements is halved, dimensions and weight are reduced.

The reduced power consumption of the device and the high resistance of the signal receiver reduced losses and eliminated the influence of changes in losses in the transformer and pnp transistor on the transmission coefficient.

Claims (2)

1. A device for galvanic separation of signals, comprising a self-oscillating blocking generator with a load winding, two resistive dividers, five capacitors, terminals for connecting a signal source and a signal receiver, respectively, the first terminal for connecting a signal source is connected to a resistor and a first capacitor connected in series, characterized in that three diodes are introduced into it, and the self-oscillating blocking generator is equipped with a compensating winding, the anode of the first diode is connected to the beginning of the load the main winding of the blocking generator, the cathode - to the first terminals of the second capacitor and the first resistive divider, the second terminal of which is connected to the second terminal of the second capacitor and the end of the load winding of the blocking generator, the beginning of the compensating winding of which is connected to the anode of the second diode, the cathode of which is connected to the first the conclusions of the third capacitor and the second resistive divider, the second output of which is connected to the anode of the third diode, the cathode of which is connected to the second output of the third capacitor and the end of the compensated blocking generator winding, the midpoint of the first resistive divider is connected to the first terminal for connecting the signal receiver and through the fourth capacitor to the midpoint of the second resistive divider and the end of the load winding of the blocking generator, the terminals for connecting the signal receiver through the fifth capacitor are interconnected, point the connection of the resistor and the first capacitor is connected to the positive power terminal of the blocking generator, the negative power terminal of which is connected to the second terminal of the first condensate ora and the second terminal for connecting the signal source, the second terminal for connecting the signal receiver is connected to the cathode of the third diode. 2. The device according to claim 1, characterized in that the self-oscillating blocking generator contains a pnp transistor, a pulse transformer with a base and collector windings, a diode, a capacitor and two resistors, and the positive terminal of the power supply of the blocking generator is connected to the emitter of the transistor and through the capacitor to the beginning of the base winding of the pulse transformer and one of the terminals of the first resistor, the other terminal of which is connected to the negative terminal of the power supply of the blocking generator and the end of the collector winding of the pulse transformer, the end of the bases the new winding of which is connected through the second resistor to the base of the transistor, the collector of which is connected to the beginning of the collector winding of the pulse transformer and the cathode of the diode, the anode of which is connected to the end of the collector winding of the pulse transformer and the negative power output of the blocking generator.

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