DE2334135A1 - Alternating current circuit breaker - is fitted with separate trip coil for each phase - Google Patents

Abstract

The application is to circuit breakers in the supply to unbalanced loads from a multiphase system. A current transformer in each supply lead feeds an individual trip coil, each coil separately having the ability to trip the circuit breaker. Adjustable shunting resistors may be included to alter the trip settings. If used for maximum demand limitation these resistors may be fitted with a seal to prevent unauthorised alteration. When the current is cut off, the trip coils produce no magnetic field and the circuit breakers can reset.

Description

PATENT ADVOCATE
DIPPING.

HELMUT GÖRTZ

6 Frank ' ^! : ri am Main 70
Schneckenhof *. 27- valley. 61 7079

July 3, 1973 Gzt / Ra.

Josef Dumser, Electronics and Heating Technology KG, 6745 Offenbach / Queich, Hauptstrasse 32

Overcurrent load shedding device

The invention relates to an overcurrent load shedding device one of the number of current transducers corresponding to the number of lines to be monitored in an electrical supply network and a switch-disconnector located in the supply lines with an electromagnetic release and retention system.

Such an overcurrent load shedding device should in particular can be used in a new type of cost calculation for the consumption of electrical energy from a supply network. While it has so far been common - at least for small consumers - the energy costs from a basic price corresponding to the number of rooms and a consumption value determined with an electricity meter, it has been proposed that the To make the basic price dependent on the maximum service provided instead of the number of rooms. Every household indicates its maximum power requirement, which depends on the existing electrical consumers and pays the corresponding basic price. Such a costing naturally presupposes that the maximum value registered by a household is not exceeded or is only exceeded for an extremely short period of time will.

409884/0202

Overcurrent shedding devices are available as fuses in different Executions known. The job of a fuse is to set a current value to protect the lines of a generator or to limit the transformer to a more or less precisely maintained maximum value. The usual ones today Automatic fuses generally have two systems, one of which is caused by heating to excessive continuous load responds, while the other responds due to electromagnetic effects in the event of a peak current, e.g. in the event of a short circuit interrupts the line. Both systems have considerable tolerances and are for this reason for the described Intended use unusable.

It is also already an electronic overload shedding device known (DAS 1 062 801), in which the line currents to be monitored are converted into signal voltages using current transformers are converted, which are fed to an electronic control circuit and when increasing via an adjustable Maximum value cause the actuation of a relay that sheds the load causing the overcurrent. The well-known The circuit is designed as an overcurrent protection device for electrical machines and requires a number of complex ones and expensive circuit elements.

It is therefore the object of the invention to provide an overcurrent load shedding device of the known type so that they have a very narrow overcurrent tolerance range and precisely defined Has response and recovery times and is still very economical and is compact to manufacture.

409884/0202

This object is achieved in that in an electronic overload shedding device of the type mentioned above electromagnetic release and holding system of the switch disconnector has a number of individual trip coils that correspond to the number the current transducer and thus corresponds to the number of lines to be monitored and that the trip coils each with the Measurement output of one of the current transducers are connected.

The switch-disconnector can also be one of the number of current transducers have a corresponding number of release and holding systems, each connected to one of the current transducers.

In addition, a replaceable one can be installed in parallel with each current transducer Fixed resistor are switched, which is advantageous

common
is designed as a plug-in and sealable resistance element. By exchanging this combination of plague resistors, the response threshold and thus the basic tariff can be varied in a few simple steps without any special prior knowledge. The seal prevents misuse. This embodiment has the further advantage that the devices according to the invention can be manufactured in series and the tariff is only determined by the plug-in resistor element.

The overcurrent shedding device can respond electronically, magnetically, pneumatically or hydraulically in the release and holding system of the switch-disconnector.

409884/0202

In a further advantageous embodiment of the invention, in which the output voltages of the current transducers are rectified and via a potentiometer having
Voltage divider circuit to a control circuit for a
Acting contactor, the control circuit having a trigger device, a timing element and a relay control amplifier
has, the timing element is designed as an amplifier connected to a capacitor and at the same time causes a
Control voltage gain. Furthermore, a thyristor is called
Relay control amplifier used.

The use of a conventional amplifier as a timing element, which is intended to prevent inrush current peaks from triggering the overcurrent load shedding device, enables
the use of a cheap and extremely compact integrated amplifier, which also amplifies the control voltage at the same time. The thyristor serving as a relay amplifier also enables the desired compact design.

In a further advantageous embodiment of the invention, the anode and cathode of the thyristor are connected in series with a resistor to the DC voltage terminals of a Graetz rectifier bridge, the AC voltage terminals of which are in series with an excitation coil of the contactor of an AC mains voltage. This simple circuit, known per se, in which the main section of the thyristor is in the direct current path of a Graetz rectifier bridge, enables the contactor to be controlled directly with the alternating mains voltage without additional switching elements. When using a
so-called triacs, which is able to handle alternating voltages

409884/0202

switching directly, the Graetz rectifier bridge could be omitted. However, triacs have hitherto been relatively unreliable and expensive switching elements, so that they will not be used for the time being became.

Another advantageous embodiment of the invention, drawings

behind the alignment is characterized by the fact that the outputs of the current transducers / in series are connected and the end points of the series circuit are connected to the fixed connections of the potentiometer, and that parallel to one of the fixed and the variable connection of the potentiometer, between which points the input voltage for the control circuit is tapped, the replaceable Fixed resistor is switched. Advantageously, the replaceable fixed resistor is also here as a plug-in and Sealable resistance element formed. The series connection of the rectified transducer outputs enables Recording of the total load of a multi-phase supply network required for tariff use. Depending on what you want The response threshold of the overcurrent load shedding device can be set using the subsequent voltage divider circuit has a larger or a smaller part of the signal voltage thus achieved the control circuit can be given.

It is also advantageous that between the variable connection of the potentiometer and the input of the as a timing element switched amplifier a parallel circuit of a resistor and a capacitor is provided and that in parallel Another capacitor is connected to the output of the amplifier.

409884 / Q202

Embodiments of the invention are shown in the drawings and are described in more detail below.

Show it:

the schematic

Fig. 1 / a rotary tr omnetzBS with the fiction according to the overcurrent glass drop device,

the schematic
Fig. 2, a Drehs tr omnetzas with a further embodiment of the overload shedding device according to the invention with potentiometer and control circuit for a contactor.

In Fig. 1, the lines of a three-phase network to be monitored for overcurrent are shown as an example with R, S, T. If a defined overcurrent occurs in one or more lines of the three-phase network, a connected Load to be thrown off.

_{Current measuring transformers W, W 2} , W are connected to each phase of the three-phase supply network, the measuring outputs of which are connected to three tripping coils A., Ap, A, of a switch-disconnector LTS. This means that the measuring circuit and the control circuit are galvanically separated from each other. The tripping coils A., A ₂ , A, are separate coils of a single release and holding system of the LTS switch-disconnector.

If the load current in one or more lines of the supply network exceeds a predetermined value, the due to the voltage induced in the corresponding trip coils

409884/0202

When the current flows, the tripping system responds and the switch-disconnector sheds the connected load.

The most compact and economical overcurrent shedding device possible To be able to produce, it is desirable to structurally integrate the current transformer into the switch-disconnector. A switch disconnector with a built-in ring current transformer is therefore preferably used, whereby the lines of the supply network are routed through the ring current transformer and each line is assigned a trip coil. That The trip system of the switch-disconnector preferably responds to currents of 0.03 A to 0.5 A.

To increase the response accuracy, instead of the

single

a / release and holding system of a switch disconnector associated with three tripping coils A., A ₂ , A- also use three separate release and holding systems in a switch disconnector of the sensitivity mentioned.

In order to be able to manufacture the overcurrent load shedding device according to the invention uniformly in series production and still be able to vary the basic tariff according to the energy consumption, replaceable fixed resistors RA., RA ₂ , RA- are provided in parallel to each current transducer, which are advantageously designed as plug-in and sealable resistance elements. In this way, for example, the same device can be used for load currents from 16 A to 63 A.

A tariff change by reconnecting and sealing the resistance elements does not require any specialist knowledge. An uncomfortable

409884/0202

Joint removal of the fixed resistors leads to the immediate triggering of the system.

If the load shedding device has switched off the load circuits, the circuit must be closed again manually. If this occurs frequently, the tariff must be changed on the device by replacing the resistance elements. In order to avoid accidents during the switch-off time, one or more purpose-related light circuits are not routed via the load circuit switching switch LTS, but only via one or more current transformers W ₁ , Wg, W ″. The load current of these light circuits is measured, but not switched.

In the circuit diagram of Fig. 2, there are also three current transformers ¥. , W ₂ , W- switched into each phase of a three-phase supply network R, S, T. Their outputs are rectified by rectifiers G ₁ ^G 2> ^G 3 and are connected in series to the fixed connections of a potentiometer RT, a fixed connection of the potentiometer RT at 2 and the variable connection at 1 being connected to a balancing resistor RA, the here, too, it is advantageously designed as a plug-in and sealable resistance element.

At the reference points 1 and 2, the control voltage for a control circuit ST controlling a solenoid contactor S is tapped, which includes a trigger device KS, a timing element C consisting of an amplifier V and a capacitor K, a _{relay control amplifier consisting of a resistor R 1} and a thyristor TH downstream bridge rectifier GB in Graetz circuit and a _{voltage stabilization consisting of a resistor R 2} and a Zener diode ZD.

40S884 / Ö202

The outputs of the current transducers W., ¥ ", W, are connected in series, in order to enable the recording of the total load of a multi-phase supply network, which is necessary for the use of tariffs. To change the response threshold of the device, the potentiometer serving as a pre-adjustment trimmer can be used RT and a larger or smaller part of the signal voltage achieved in this way by replacing the balancing fixed resistor RA are given to the control circuit ST.

The timing element Z, which consists of the capacitor K and the amplifier V, prevents, for example, low-resistance when switching on Consumers already lead and amplified inrush current peaks to trigger the overcurrent shedding device at the same time the control voltage. The timer is dimensioned so that when it exceeds ten times the total off sol eamplitude still triggers load shedding.

The control electrode of the thyristor TH is connected to the trigger device KS connected, while the cathode and anode of the thyristor are connected in series with the resistor R. to the DC voltage connections connected to the Graetz Gleiehrichterbrücke GB whose alternating voltage connections are in series with the excitation coil of the contactor S. This simple, A circuit known per se enables the switching protection to be controlled directly with the AC mains voltage.

The control circuit ST can also be fully integrated Execute circuit. This extensive miniaturization requires the overcurrent load shedding device according to the invention to be installed without additional space requirements and

Electricity without violating existing standards, directly below the / meter feasible on the existing standard plates and rails.

409884/0202

Claims (1)

Claims Γ 1.) Overcurrent load shedding device with one of the number of to be monitored lines of an electrical supply network corresponding number of current transducers and a switch-disconnector located in the supply lines with an electromagnetic release and cooling system, characterized in that the electromagnetic release and holding system of the switch disconnector has a number has individual trip coils, the number of current transducers and thus the number of lines to be monitored corresponds and that the trip coils are each connected to the measurement output of one of the current transducers. 2. Overcurrent load shedding device according to claim 1, characterized characterized in that the switch disconnector has a number of release and corresponding to the number of current transducers Has holding systems which are each connected to the measurement output of one of the current transducers. 3. Overcurrent load shedding device according to claims i and 2, characterized in that an exchangeable fixed resistor is connected in parallel to each current measuring transformer. k. Overcurrent load shedding device according to Claims 1 to 3, characterized in that the replaceable fixed resistor is designed as a plug-in and sealable resistor element. 409884/0202 -I- 5. Overcurrent load shedding device according to claims i to 4, characterized in that the disconnection (tripping) of the switch-disconnector is electronically delayed. 6. Overcurrent load shedding device according to claims 1 to h, characterized in that the switching off (triggering) of the Switch-disconnector is delayed magnetically, pneumatically or hydraulically. 7. Overcurrent load shedding device according to claims i to 5, in which the output voltages of the current transducers are rectified and via a voltage divider circuit having a potentiometer to a control circuit for a Acting switching protection, the control circuit having a trigger device, a timing element and a relay control amplifier , characterized in that the timing element is connected as a bit to a capacitor amplifier is designed and at the same time causes a control voltage gain and that a thyristor as a relay control amplifier serves. 8. Overcurrent load shedding device according to claim 7, characterized characterized in that the anode and cathode of the thyristor in series with a resistor at the DC voltage terminals a Graetz rectifier bridge are connected, their AC voltage connections in series with an excitation coil of the contactor is connected to the AC mains voltage. 9. Overcurrent load shedding device according to claims 7 «nd 8, characterized in that the outputs of the current transducers are connected in series and the end points of the series switching A09884 / 0202 device are connected to the fixed terminals of the potentiometer and that parallel to one of the fixed and the variable Connection of the potentiometer, between which points the input voltage for the control circuit is tapped the replaceable fixed resistor is switched. 10. Overcurrent load shedding device according to claims 7 to 9 » characterized in that between the variable connection of the potentiometer and the input of the as a timing element switched amplifier a parallel circuit of a resistor and a capacitor is provided and that a further capacitor is connected in parallel to the output of the amplifier. 409884/0202 43. Blank page