CS225931B3 - Circuitry for monitoring power input growth in electric - Google Patents

Description

BACKGROUND OF THE INVENTION The present invention relates to an electrical current monitoring circuit for electrical appliances with a current transformer with primary winding input terminals for connection to the electrical appliance being monitored and its secondary winding output terminals connected to a load resistor, a first rectifier and a potenoiometer. connected to the actuator via a monostable flip-flop circuit, where a voltage drop correction circuit consisting of input terminals, a second rectifier and a variable resistor is connected to the first rectifier.

It is known to monitor the increase in electric current in electrical appliances according to the. This connection monitors, for example, in electric motors, the build-up of electric current when its load increases. The use in normal practice may vary depending on the nature of the monitoring, as in the case of machine tools for monitoring the blunting of tools. By connecting, a wide range of electrical currents of the electrical appliance can be monitored, from the lowest to hundreds of amperes, and can operate at low voltages and almost without delay. It is designed for common undemanding measurements.

An improvement in the solution of this problem is provided by the circuitry for monitoring the increase in electric current of the electrical appliances according to the invention, which consists in that a fourth resistor is connected to the lower terminal of the potenoiometer, the second terminal of which is connected

225 931

225 931 ae a monostable flip-flop input and a second rectifier output, and alce its negative pole is connected to the second terminal of the fourth resistor, while its positive pole is connected via a variable resistor to the negative pole of the first rectifier, the actuator output is connected to the input terminal correction circuit.

An advantage of the circuitry according to the invention is that the voltage drop correction circuit is more sensitive and accurate. This means that even monitoring the increase in electrical current will be more sensitive and accurate.

An example of wiring to monitor the increase in electrical current of electrical appliances is shown schematically in the drawing.

The input terminals S1, S2 of the primary winding of the current measuring transformer T are connected to the electrolux under observation (not shown). A load resistor R1 and a first rectifier U1 are connected between the output terminals 33. S4 of the secondary winding of the measuring transformer T. The first rectifier U1 consists of a capacitor 01 connected to the positive pole ± and the negative pole χ of the DC output of the first rectifier U1, and a first diode D1 connected to the positive pole + between the first capacitor 01 and the load resistor R1. A potenoiometer R2 is connected between the positive pole + and the negative pole χ of the DC output of the first rectifier U1. Its running is connected to input 1 of the mono-stable flip-flop MKO. The output 01 of the mono-stable flip-flop MKO is connected to input 2 of the AC actuator. Lower outlet of the R2 potenoiometer. connected to the negative pole - of the first rectifier U1, it is further connected via the fourth resistor R4 to the third input 2 of the monostable flip-flop MKO. whose output 03 is connected by the input £ of the actuator e. There are input terminals S5 in the voltage drop correction circuit. S6 can be connected to a power supply (not shown) which is proportional to the power supply voltage of the electrical appliance of interest. Between input terminals S5. S6 is connected to a second rectifier U2 formed by a second capacitor 02 connected to the positive pole + and negative pole - of the DC output of the second rectifier U2. A zener diode D3 located downstream of the second capacitor 02 and connected to the positive pole + and negative pole χ of the DC output of the second rectifier U2. It is further formed by a second diode D2 connected to the + terminal between the second capacitor 02 and the input terminal S5. The output of the second rectifier U2, its negative pole is connected to the fourth resistor R4. At the output of the second rectifier U2, sioe to its positive pole +, a variable resistor 52 is connected, the second terminal of which is connected to the negative pole χ of the first rectifier U1. Input 2 of the mono-stable flip-flop MKO is connected to the negative pole - the second rectifier U2. The output 03 of the mono-stable flip-flop MKO is connected to the input 6 of the actuator AC, while the output 02 of the actuator AC is connected to the input terminal S5 of the correction circuit.

In the circuit described, for example, a transistor or a thyristor relay can be used as an AC actuator.

The electrical current flowing through the electrical consumer being monitored is sensed by a current transformer T. A voltage proportional to the value of the electric current is generated at the load resistor R1. This voltage is rectified and smoothed in the first rectifier U1. The voltage output at the DC output of the first rectifier U1 can be further adjusted by the potentiometer R2.

225 931

The resulting voltage together with the β magnitude of the voltage from the voltage drop correction circuit is applied to inputs 1 and} to flip the monostable flip-flop MKO. and consist of two stress components. The first is supplied from said potentiometer R2, the second is proportional to the magnitude of the line voltage at the terminals S5. S6 rectified in the second rectifier U2, the size of which is limited by the Zener diode 22 · ^T °, this voltage is adjusted by a variable resistor R3 and applied via a fourth resistor R4 to the input 2 of the mono-stable flip-flop MKO.

Voltage variations in the correction circuit are fed to the fourth resistor R4 in the range of 0 to 100% to flip the monostable flip-flop MKO. With 100% correction, the voltage from the fourth resistor R4 is applied via the potentiometer R2 to the monostable flip-flop MKO.

If the correction is lower, the voltage at the mono-stable flip-flop MKO is given by the sum of the voltages supplied from the fourth resistor R4 and the potenoi R2, as already mentioned. Both values are 100% for flipping of the mono-stable flip-flop MKO. Its output voltage is then actuated by the actuator AC, which actuates the signaling device or actuator.

* disconnects the electrical appliance from the power supply or gives an impulse to another suitable measure. The response time is given by the capacitor value C1 and the speed of the AC actuator.

The connection can be used for single-phase electrical appliances and three-phase electric motors, where the voltage reduction circuit is connected to the secondary winding of another transformer (not shown), eg for the signaling voltage of a 24V machine. as the wiring, either to the remaining arbitrary phase. In this way, the operating state of the electric motor can be monitored, for example that the electric motor is running idle, at rated load or that it is overloaded. .

Claims (1)

FIELD OF THE INVENTION Electrical current monitoring wiring for electrical appliances with a current transformer with primary winding input terminals for connection to the electrical appliance being monitored and its secondary winding output terminals connected to a load resistor, a first rectifier and a potentiometer whose runner and bottom outlet are connected via a monostable flip-flop a circuit for an actuator wherein a voltage drop correction circuit comprising input terminals, a second rectifier and a variable resistor is connected to the first rectifier, characterized in that a fourth resistor (R4) is connected to the lower terminal of the potenoiometer (R2), the second terminal of which is connected to the input (3) of the monostable flip-flop (MKO) and the output of the second rectifier (U2), its negative pole (-) is connected to the second terminal of the fourth resistor (R4), while its positive pole (+) is connected via resistance (R3) with negative p hem (-) of the first rectifier (Ul), the output (02) of the actuator (AC) is connected to the input terminal (S5) correction circuit.