DE2061295A1 - Voltage decrease time relay - Google Patents

Description

S »annual decrease time relay The invention relates to a voltage decrease time relay, a delayed control signal when the voltage falls below the nominal value outputs, the delay depending on the size of the undervoltage.

It is a voltage drop time relay with a Ferraris measuring mechanism known, in which a mercury ring tube contact actuated by the Ferraris measuring mechanism and triggers a switching command.

This relay has several disadvantages. So must because of the mercury ring tube contact a certain installation position must be adhered to. Furthermore, the mercury ring tube contact after the Perraris measuring mechanism responds prematurely as a result of vibrations close or open and thus cause false tripping. By the mechanically moving parts of this known relay is a relatively short life conditional. In addition, the production of such relays requires a great deal of Precision.

The invention is based on the object of a voltage drop time relay to create the type described above, which can be installed in any position can, is vibration-proof, has a long service life and is easy to manufacture is. The solution to the problem is achieved according to the invention in that a Integrating element connected to an auxiliary voltage source when the actual value drops below the setpoint, an electrical variable proportional to the setpoint / actual value difference is fed and controlled by the integrating element, a threshold value element, which in turn affects a circuit.

After an output of the invention, a particularly simple one results Relay in that the soil actual value difference is achieved by an active semiconductor element proportional current generated and a measuring capacitor with parallel resistance is supplied, at whose terminal poles connected to the semiconductor element the control input of the threshold value element is connected. Suitable as such a semiconductor element especially a field-effect transistor, one of which has a load electrode across the measuring capacitor and the parallel resistance with one pole and the other load electrode a resistor is connected to the other pole of the voltage source to the furthermore, the control electrode of the field-effect transistor is connected directly and at which the actual value is fed to the load electrode connected to the resistor. In the same advantageous manner, a control transistor can also be used as the semiconductor element are provided, the collector of which via the measuring capacitor and the parallel resistor to one pole and its emitter to the other via an emitter resistor Pole of the auxiliary voltage source is connected, furthermore the emitter of the control transistor the actual value and the base value of the measuring voltage are supplied.

The supply of the actual and setpoint is expediently carried out by that the emitter of the control transistor via an adjustable resistor to the Measurement voltage connected and the base of the control transistor to the cathode of a Zener diode connected to the auxiliary voltage source via a series resistor connected is.

The usability of the relay according to the invention for a measurement exchange voltage is achieved in a simple manner in that a rectifier bridge is provided is, at whose DC voltage poles the measurement voltage is tapped and a smoothing capacitor connected.

A separate auxiliary voltage source is not necessary if connected in series a parallel capacitor is provided for the Zener diode and the series resistor and the second circuit part fed by the capacitor through a decoupling diode is decoupled from the first circuit part acted upon by the measuring voltage.

A particularly high level of reliability in terms of triggering a Switching command is achieved in that as a threshold value element one bistable transistor KipstUfe is provided in which a first transistor with the measuring capacitor and the parallel resistor is in control connection, the emitter of the first and a second transistor via a common emitter resistor connected to one pole of the auxiliary voltage source, the collector of the first Transistor via a collector resistor with the other pole of the auxiliary voltage source is connected, in which further between the one pole of the auxiliary voltage source and the collector of the first transistor is a further consisting of two partial resistors Voltage divider is connected to the tap of the base of the second transistor and its collector-emitter path with the control winding of a switching relay in Is connected in series.

To avoid rocking oscillations, it can also be useful to that the first transistor via a, with its base to the measuring capacitor and the parallel resistor connected pre-transistor is controlled, with the base of the first transistor to the one via a further emitter resistor Pole of the auxiliary voltage source connected emitter of the pre-transistor and the Collector of the first transistor connected to the collector of the pre-transistor is. The response time of the voltage drop time relay can be set using an adjustable common emitter resistance can be changed.

Based on an exemplary embodiment shown in the drawing the subject matter of the invention is described in more detail below.

It shows: FIG. 1 a block diagram of the voltage drop time relay according to the invention, Fig. 2 is a circuit diagram of the voltage drop time relay according to the invention.

In Fig. 1, Uist is an actual value source and Usoll is a setpoint source for the measuring voltage, both with the inputs of an integrator 1 are connected. The output of the integrator is connected to the input of a level value element 3 connected, which via its output a relay Re affects whose Contact member 2 is arranged in a circuit. Dss, integrator 1 and that Threshold value element 3 are fed by an auxiliary voltage source UHilf.

In the circuit diagram according to FIG. 2, one is connected to the AC voltage poles Rectifier bridge G applied a measuring voltage UM. At the same voltage output this Rectifier bridge G is the series connection of an adjustable resistor R1 and an emitter resistor R3 and one in parallel with this series circuit Smoothing capacitor C1 connected. A decoupling diode Dl is also a capacitor C2 serving as an auxiliary voltage source to the DC voltage output the rectifier bridge G connected. A zener diode is attached to this capacitor C2 Z1 and a series resistor R4 lying in series with this are connected in parallel. The common connection point a of the adjustable resistor Rl and the emitter resistor R3 is connected to the emitter of a control transistor Tl, the base of which to the The cathode of the Zener diode Z1 is connected. With its collector is the control transistor T1 via one formed from a measuring capacitor C3 and a parallel resistor R2 Integrating element at the first designated +, connected to the decoupling diode D1 Connection pole of the capacitor C2 serving as an auxiliary voltage source is connected. Likewise, this first connection pole can be set via a common one Emitter resistance R6 is the emitter of a first and second transistor T3 and T4 connected to a bistable Transissby flip-flop. Via a collector resistor R7 is the first transistor T3 with the second terminal pole of the designated - Capacitor C2 connected. A voltage divider consisting of two partial resistors R8 and R9 lies between the first terminal of the capacitor C2 and the collector of the first transistor T3. The base of the second is at the tap of this voltage divider Connected transistor T4, which with its collector-Rmitter path with the control winding a switching relay Re is connected in series. There is a freewheeling diode for the control winding D2 connected in parallel. Via a contact element designed as a normally open contact rl switches the switching relay a consumer V. To avoid tilting vibrations is the first transistor T3 of the transistor flip-flop a pre-transistor T2 assigned. The base of the first transistor T3 is connected to the via a further emitter resistor R5 connected to the first terminal of the capacitor C2 emitter of the pre-transistor T2 connected. The collector of the first transistor T3 and the collector are the same of the pre-transistor T2 connected to each other. The base of the pre-transistor T2 is connected to the collector of the control transistor 21.

In the through the adjustable resistor Rl and the emitter resistor R3 and the series connection of the series resistor R4 and the Zener diode Z1 are formed The bridge is created by the Zener voltage of the Zener diode Z1 in one branch of the bridge a fixed setpoint voltage is specified. In the other branch of the bridge, the adjustable Resistor R1 a certain actual value can be set. As long as the tension is on the emitter resistor R3 is higher than the Zener voltage of the Zener diode Z1, remains the control transistor T1 is blocked and the measuring capacitor C3 is not charged. If the applied measuring voltage UM decreases and with it the actual voltage at the emitter resistor R3 so far that it is smaller than that caused by the Zener voltage of the Zener diode Z1 is given setpoint voltage, the control transistor Ti is turned on and the Measuring capacitor C2 charged. The strength of the charge depends on the size of the difference between the nominal voltage and the actual voltage applied to the emitter resistor R3 away. As soon as the response voltage of the transistor flip-flop is reached at the measuring probe C3 is, the pre-transistor T2 and via this the first transistor 23 is turned on. As a result, the emitter potential of the second transistor T4 is opposite to the potential its base negative, so that the second transistor T4 blocks. The switching relay Re drops out and interrupts the electrical circuit of the consumer by means of its contact element rl V.

The charging current of the capacitor is proportional to the drop Measured voltage controlled, (l.h. with an utultktfn Al) uLrlken of the measured voltage received the capacitor has a high charging current and its voltage already reaches very short time the response value of the transistor multivibrator, on the other hand is with one less sharp drop in the measuring voltage, the charging current correspondingly smaller and the time until the response value is reached longer. So it depends the switch-off time of the voltage drop time relay according to the invention on the size of the voltage drop.

The parallel resistor R2 causes a leakage current of the Control transistor T1 possible charging of the measuring capacitor C3 to a low level Limited value. In addition, the measuring capacitor C3 can be connected via the parallel resistor R2 discharged when partial charging as a result of a temporary voltage drop of the measuring capacitor has taken place without the response value of the transistor multivibrator was achieved.

When the voltage drop timer relay on via a rectifier an alternating measuring voltage is connected, is because of the Wel ligkeit of the rectified Measuring voltage a smoothing capacitor is necessary to ensure that the relay responds to avoid the ripple. The capacitance of the smoothing capacitor should be dimensioned in this way be that the voltage at the smoothing capacitor changes as quickly as possible the measuring voltage follows.

The capacitor C2 has the task of reducing the measurement voltage for the second circuit part 20, the measuring capacitor from the parallel resistor R2 C3, the voltage threshold element 3, the series connection of the series resistor R4 with the Zener diode Z1 and the Sohaitrelais Re keep the supply voltage to deliver. It is therefore due to the decoupling diodes Dl from that due to the measurement voltage influenced, from the adjustable resistor R1, the emitter resistor R3 and the smoothing capacitor C1 existing first circuit part 10 is decoupled.

Instead of the capacitor C2, a direct voltage source can also be used, for example can be used. The decoupling diode can be omitted if the circuit is separated at this point.

Instead of the bistable transistor trigger stage, another Voltage threshold value element, such as a unijunction transistor or a programmable one Unijunction transistor can be used with appropriate adaptation of the circuit.

There is also the possibility, instead of the Zener diode Z1 and of the series resistor R4 a DC voltage source supplying the setpoint voltage to be connected to the base of the control transistor Tl.

10 patent claims 2 figures

Claims (10)

Claims: 1. Voltage drop time relay, which when falling below of the setpoint of a measurement voltage emits a delayed control signal, the Delay depends on the size of the undervoltage, characterized in that an integrating element (1 or R2, C3) when the actual value falls below the setpoint one of the setpoint / actual value difference proportional electrical quantity and supplied by the integrator (1 or R2, C3) a threshold value element (3) is controlled, which in turn has a circuit (Re) influenced. 2.) Relay according to claim 1, characterized in that by a Active half-parent element (T1) a current proportional to the target / actual value difference generated and fed to a measuring capacitor (C3) with a parallel resistor (1t2), on the other hand the control input is connected to the terminal element (T1) of the threshold value element () is connected. 3.) Relay according to claim 2, characterized in that the semiconductor element is a Beld effect transistor, one of which is a load electrode across the measuring capacitor (C3) and the parallel resistor (R2) with one pole and its other load electrode Find via a resistor with the other pole of the auxiliary voltage source (C2) is to which the control electrode of the field-effect transistor is also directly connected and at which the actual value is fed to the load electrode connected to the resistor is. 4.) Relay according to claim 2, characterized in that the semiconductor element is a control transistor (T1), the collector of which via the measuring capacitor (C3) and the parallel resistor (R2) to one pole and its emitter via an emitter resistor (5.3) is connected to the other pole of the auxiliary voltage source (C2), where furthermore the emitter of the control transistor the actual value and the base the desired value the measuring voltage (U) is supplied. 5.) relay according to claim 4, characterized in that the Brnitter des Control transistor (m1) via an adjustable resistor (Ri) to the measuring voltage (U.i) connected and the base of the control transistor with the cathode one over a series resistor (R4) connected to the auxiliary voltage source (C2) Zener diode (Z1) is connected. t.) Relay according to claim 5, characterized in that a uieichrichterbrücke (G) is provided, at whose DC voltage poles the measuring voltage (U) is tapped and a smoothing capacitor (ci) is connected. 7.) Relay according to claim 5 or 6, characterized in that as Auxiliary voltage source on to the series connection of the Zener diode (Z1) and the series resistor (R4) parallel capacitor (02) is provided and the one fed by the capacitor second circuit part (2) by a decoupling diode (D1) from that by the measuring voltage act on the first circuit part (1) is decoupled. 8.) Relay according to one of claims 2 to 7, characterized in that that a bistable transistor multivibrator is provided as the threshold value element, at a first transistor (T3) with the measuring capacitor (C3) and the parallel resistor (R2) is in control connection, the emitter of the first transistor (23) and the Emitter of a second transistor (T4) via a common emitter resistor (R6) are connected to one pole of the auxiliary voltage source and the collector of the first transistor (T3) via a collector resistor (R7) to the other Pole of the auxiliary voltage source is connected, in which also between the one pole the auxiliary voltage source and the collector of the first transistor (T3) one of two Partial resistances (R8, R9) of existing voltage divider lies, with its tap the base of the second transistor (T4) connected and its collector-emitter path is connected in cihe with the control winding of a switching relay (Re). 9.) Relay according to claim 8, characterized in that the first Transistor (T3) via eien, with its base to the measuring capacitor (C3) and the parallel resistor (R2) connected pre-transistor (T2) is controlled, the base of the first Transistor (T3) with the one via another emitter resistor (R5) Pole of the auxiliary voltage source connected to the emitter of the Vortranslstors (22) and the collector of the first transistor (T3) with the collector of the pre-transistor (T2) connected is. 10.) Relay according to claim 8 or 9, characterized in that the common emitter resistance (R6) is adjustable.