CS234135B1 - Insulation voltage converter connection - Google Patents

Abstract

The invention falls within the measurement and control techniques and its purpose is to increase the accuracy and range of the insulation converter a voltage consisting of a source AC voltage connected via diodes on the split primary winding separator transformer the middle outlet is connected via controlled resistance to non-inverted input an operational amplifier whose output yeah connected to the control input of the controlled resistor. This purpose is achieved by that the isolation transformer (6) is provided with a feedback secondary winding (14) connected to the rectifier input (19), the output of which is associated with operational amplifier inputs (10).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to the connection of an insulating voltage transducer, in particular to ensure operator safety when measuring DC voltage in measuring and control technology.

In some cases, for example when testing pumps, vacuum pumps, hydraulic circuits and other devices driven by the same directional motors, the power input of the machines under test is measured along with the power input of the engine. The motor power converter includes a pulse multiplier that multiplies the current and voltage signals and converts the resulting power signal into a voltage signal proportional to the motor power. However, this voltage signal is usually galvanically connected to the phase conductor of the grid, so it is necessary to isolate it from the grid by an insulating voltage converter for safety reasons. It is known to provide an isolation converter comprising an isolation line transformer with a direct current source for supplying an operational amplifier. The output of the mains transformer is also connected via rectifier diodes to the input of the isolation isolating transformer with a split primary winding, to whose central outlet the collector of the transistor is connected. The base of this transistor is connected to the output of the operational amplifier, while its emitter is connected to the positive pole of the converter input. The DC power supply is equipped with a voltage divider, the output of which is connected to the positive input of the operational amplifier. At the same time, the positive input of the converter is connected to this input, while the negative input of the operational amplifier is connected both to the negative terminal of the converter input and to the emitter of the transistor. The output of the decoupling transformer is provided with a rectifier and a low-pass filter. The disadvantage of this solution is the small operating voltage range and considerable non-linearity, which is due to the choice of the transistor operating point. In addition, the operating point of the transistor is negatively affected by the ambient temperature, which is not compensated by the circuit. The consequence of this is low equipment operability and considerable measurement error.

The above-mentioned disadvantages essentially overcome the invention, which is the connection of an insulating voltage converter, in particular to ensure operator safety when measuring DC voltage in the measuring and control technology, consisting of an AC voltage source connected via diodes to a split primary winding of the isolation transformer. through a controlled resistor to the non-inverting input of an operational amplifier to which the inverting input is connected via the input resistor to the first pole of the converter input, to the non-inverting input

234 135

- 2 input of operational amplifier is connected to the second pole of converter input, output of operational amplifier is connected to control input of controlled resistor, where isolating transformer is equipped with output secondary winding, and its essence from decoupling transformer is provided with feedback secondary winding connected to input of second rectifier. the output is connected to the input of the second smoothing filter, whose output pole with the polarity opposite to the polarity of the first pole of the converter input is connected via a feedback resistor to the inverting input of the operational amplifier;

The higher effect of the invention is given by the high linearity and the wide operating range of the input voltage, since any deviation from the linearity is only due to the characteristics of the opamp and the variations in the identity of the feedback and output circuits. The new feedback solution also eliminates the effect of temperature.

An example of a particular embodiment of the invention is shown schematically in the accompanying drawing, in FIG. 1, a basic block diagram of a converter according to the invention, and FIG. 2 a diagram of the converter of FIG. 1 in an alternative embodiment with two separating transformers and reverse transistor polarity.

in

The insulating voltage converter according to FIG. 1 consists of a mains transformer 1 whose power secondary winding 2 is split with a grounded middle terminal and with the outer terminals connected both to the input of the symmetrical power supply 2 and through the first and second diodes 41. 42. The primary diode 41 and the second diode Š are oriented in the forward direction from the line ¹ to the isolation transformer 6. The middle terminal of the power supply 2 d ^is grounded, while the middle terminal of the split primary winding 2 of the isolation transformer 6. it is connected to the input of the controlled resistor 2 formed by the collector of the transistor 8 with the conductivity pnp. The controlled resistor 2 outside transistor 8 further comprises a protective resistor 2 connected to the emitter of transistor 8. The base of transistor 8 is grounded. The protective resistor 2 is connected to the output of the operational amplifier 10. The inverting input of the operational amplifier 10 is connected via the input resistor 11 to the positive first pole 121 of the converter input 12 and the non-inverting input of the operational amplifier 10

- 3 234 135 either directly or by means of resistors (not shown). The operational amplifier 10 is connected to the output of the power supply 2. The isolation transformer 6 is provided with an output secondary winding 12 and an electrically separated feedback secondary winding 14. The output secondary winding 13 is connected to an input in V of the first rectifier 15 whose output is connected with the input of the first smoothing filter 16, the output of which is also the output 17 of the converter, is connected in parallel with the first load resistor 18. The secondary secondary winding 14 is connected to the input of the second rectifier 19 whose output is connected to the input of the second smoothing filter 20 to which the second load resistor 21 is connected in parallel. The first smoothing filter 16 and the second smoothing filter 20 are composed, for example, of capacitors (not shown) and resistors (not shown). The negative pole of the output of the second smoothing filter 20 is connected via a feedback resistor 22 to the inverting input of the operational amplifier 10, the positive pole of the output of the second smoothing filter 20 being grounded. The ohmic value of the feedback resistor 22 is identical to the ohmic value of the input resistor 11. The input secondary winding 13 and the feedback secondary winding 14, the first and second rectifiers 15, 19 and the first and second smoothing filters 16, 20 are identical. the first and second load resistors 18, 21.

In Fig. 2, the isolation transformer 6 comprises an output isolation transformer 61 and a feedback isolation transformer 62. The output isolation transformer 6l is provided with a first split primary winding 51 and an output secondary winding 13. The feedback isolation transformer 62 is provided with a second split primary winding 52 and a feedback secondary. winding 14. The first split primary winding 51 and the second split primary winding 52 are connected in parallel to each other. The difference from the diagram in FIG. 1 is further that a n-p-n polarity transistor 8 is used, corresponding to the opposite polarity of the first and second diodes 41, 42 and the first and second poles 121, 122 of the converter input 12. A bias source 23 is connected to the inverting input of the operational amplifier 10, which may also be used in the circuit of FIG. 1.

Before starting the measurement a the mains transformer 1 is connected to the mains. If the potential bias source 23 and the measured voltage are disconnected, there are zero voltage differences at the outputs of the first and second smoothing filters 16, 20, at the converter input 12 and at the inputs of the operational amplifier 10. There is therefore zero voltage at the output of the operational amplifier 10, the voltage difference between the base and the emitter of the transistor 4 234 135 in FIG. 1 is also zero, and thus the transistor 8 is in the

The collector-base is closed. The positive voltage halfwaves appearing alternately at the upper and lower ends of the split primary winding 2 of the isolation transformer 6 are thus separated from the converter frame, no current flows through the split winding 2, and therefore zero voltage remains at the output and feedback secondary windings. When the measured voltage is connected to the converter input 12, for example, the full input positive voltage appears on the inverting input of the operational amplifier 10, and the full negative input voltage on its non-inverting input. The difference in voltage at the inputs of the operational amplifier 10 is reflected at its output in the form of a full negative voltage of the power supply, on the basis of which the emitter current flows through the transistor 8. This emitter current causes a substantial reduction in the resistance between the collector and the base of the transistor 8 and the collector current starts to flow through the divided primary winding 2.

This causes the respective windings 13, 14 to induce the respective voltages and currents, which, after rectifying, charge the capacitors (not shown) of the first and second smoothing filters 16, 20, and the negative voltage after the second smoothing filter 20 is transferred via the feedback resistor 22 to. an inverting input of the operational amplifier 10 where it adds to the positive input voltage. This reduces the positive voltage at the inverting input of the operational amplifier 10 and at the same time decreases the voltage difference at its inputs. Due to its infinite amplification, the operational amplifier 10 does not react to reduce the voltage difference at its inputs and the voltage at its output remains unchanged. Therefore, the collector current of the transistor 8 at the original level continues to flow through the split primary winding 2, and the voltage at the outputs of the first second smoothing filter 16, 20 increases. When the voltage at the outputs of the first and second smoothing filters 16, 20 reaches the input voltage value, the voltage at the inverting input of the amplifier 10 drops to a virtual zero value. Based on a zero voltage difference at its inputs, the operational amplifier 10 closes its output. The output voltage of the operational amplifier 10 drops to zero, and thus no emitter current flows through the transistor 8. This causes it to close in the collector-base direction and the isolation transformer 6 stops supplying current to the first and second smoothing filters 16, 20. The voltage at their outputs due to the discharge of their capacitors through the first and second load resistors 18, 21 begins to decrease. This drop occurs again in the form of a positive voltage at the inverting input of the operational amplifier 10, the transistor 8 opens again and the capacitors of the first and second smoothing filters 16, 20 are again

P 234 135 recharge. In this way, the feedback voltage is maintained at the input voltage level of the transmitter. Since the output and feedback circuits are the same, the output voltage of the converter is the same as in

feedback ^ and thus also the input voltage. If, for example, the input voltage drops, a negative voltage appears at the inverting input of the operational amplifier 10, thereby generating a positive voltage at its output, which closes the emitter transition of the transistor 8 as well as the previously described zero voltage. In this case, therefore, the voltage at the outputs of the first and second smoothing filters 16, 20 decreases to a new level of input voltage due to the discharge. If the input voltage of the converter changes polarity, a positive voltage of the appropriate level must be set at the inverting input of the operational amplifier 10 prior to measurement by the connected bias source 23. Permanently opposite polarity of the input voltage can be solved in addition to the polarity at the converter input 12 also by using the circuit according to Fig. 2, where the transistor 8 is the reverse polarity, i.e. npn, the polarity of the first and second diodes 41, 42. . The first load resistor 18 and the second load resistor 21 may be formed by trimers, whereby any deviations between the output and feedback circuits may be corrected. If the converter is to have not only an insulating function but also to reduce or increase the voltage, this effect can be achieved, for example, by a different ohmic value of the input and feedback resistor 11, 22 by different parameters of the output and feedback circuits, respectively. The first smoothing filter 16 and the second smoothing filter 20 may alternatively be used, for example, electronic, where the use of first and second load resistors 18, 21 is not necessary. Such a transducer functions the same as described, with the difference that it transfers the voltage changes more quickly.

The function according to Fig. 2 proceeds similarly to the connection according to Fig. 1, the differences result only from reversed polarities. The operation of the output isolation transformer 61 and the feedback isolation transformer 62 in the circuit of FIG. 2 is identical to that of the isolation transformer 6 in the circuit of FIG. 1. However, the isolation transformer 6 of FIG. 2 is easier to reach than the atypical isolation transformer 6 of FIG. 1.

The invention can be used wherever electrical DC signals need to be isolated from one another. Alternatively, however, the output signal can be monitored in the form of an AC voltage directly in the 6,232,135 degrees secondary winding, eliminating the need for a first rectifier and a first smoothing filter.

Claims (1)

SUBJECT OF THE INVENTION 234 135 Connection of an insulating voltage converter, in particular to ensure operator safety when measuring DC voltage in measuring and control technology, consisting of an AC power supply connected via diodes to a split primary winding of the isolation transformer, the middle of which is connected via controlled resistance to the non-inverting input of the operational amplifier the inverting input of which is connected via the input resistor to the first pole of the converter input, to the non-inverting input of the operational amplifier the second pole of the converter input is connected, the output of the operational amplifier is connected to the control input of the controlled resistor; the isolating transformer (6) is provided with a feedback secondary winding (14) connected to the input of the second rectifier (19), the output of which is only with the input of the second smoothing filter (20) whose output pole with polarity opposite to the polarity of the first pole (121) of the converter input (12) is connected via a feedback resistor (22) to an inverting input of the operational amplifier (10); the second smoothing filter (20) is coupled to the non-inverting input of the operational amplifier (10).