FR2497013A1 - Automatic load shedding controller for electrical installation - uses overcurrent detectors on input supply to disconnect low priority loads if input current becomes excessive - Google Patents

Abstract

The load shedding controller is used to automatically cut off low priority loads in a low voltage electrical installation if an overcurrent occurs in the single supply which distributes current to the various loads. The controller is assembled in a moulded housing and has connections for the single incoming supply and the various loads derived from the supply. Current detectors (44) are fitted to each of the three phases of the incoming supply. An overcurrent results in an electronic circuit (58) switching a relay (68), removing the low priority load, and activating visual (60,56) and audible (54) warning signals. A timing circuit prevents operation under transient overload conditions.

Description

LOWERING DEVICE OF A LOW VOLTAGE ELECTRICAL INSTALLATIOtt.

The invention relates to a load shedding device for a low voltage electrical installation, having a main circuit provided with a molded case protection device provided with connection terminals arranged on two opposite faces and outgoing circuits supplied by the main circuit, at least one non-priority starting circuit being equipped with a cut-off device, said device comprising an overcurrent detector inserted in the main circuit, a load shedding relay controlled by said detector to issue a load shedding order transmitted to the 'cutoff device of said non-priority start to open said cutoff device during a predetermined overcurrent in said main circuit.

A known device of the kind mentioned allows disconnection of certain non-priority feeders in the event of an overload by maintaining a normal supply of priority feeders.

It is thus possible to choose a connection power lower than the sum of that of the various devices installed, the simultaneous operation of all the devices being prevented by the entry into action of the load shedding relay in the event of an overload. The known device comprises an independent programming block which issues tripping orders to circuit breakers or breaking devices protecting non-priority departures in the event of overload. It is understood that the issuance of a load shedding order must take place before any triggering of the main protection device if it is desired to maintain the supply of priority departures.

On the other hand, load shedding should only take place in the event of a trigger risk, that is to say at an overload threshold little lower than the trigger threshold. The known device does not ensure sufficient coordination between load shedding threshold and triggering threshold and the installation of the programming block requires wiring and special supports which complicate the installation and limit the possibilities of use.

 a prcsen .-- invention aims to remedy these drawbacks and to allow the production of a simple and reliable device.

The load-shedding device according to the invention is characterized by the ticking fact is arranged in a block capable of being attached to one of said faces of the protection device of the main circuit, said block having on the attached face of the terminals connecting to the adjacent conjugate terminals of the protection device in the adjoining position, and on the opposite face of the connection terminals, so as to connect the load-shedding block and the protection device, said block in series in the main circuit having an overcurrent indicator and a connection terminal of a conductor for connecting the cut-off device of the non-priority departure to said load shedding relay so as to transmit the load shedding order from said relay to 11 cut-off device.

By associating the load shedding block with the main circuit protection device, for example the main circuit breaker, it is possible to adjust or adapt the load shedding curve to the tripping curve while reserving only a small safety margin . The mechanical connection between the case of the circuit breaker and that of the load-shedding block simultaneously provides the electrical connection and the profile of the load-shedding block advantageously follows the circuit breaker to form a one-piece assembly. This assembly is connected by a pilot wire to the non-priority outgoing circuit breaker to transmit the load shedding order to this circuit breaker.
All the facilities for mounting the basic circuit breaker are retained, only the length of the case being increased.

The load shedding block preferably includes an audible and / or visual overload alarm device and a load shedding indicator. To avoid unwanted load shedding, the block advantageously includes a time delay so as to issue a load shedding order only if the overload persists for a predetermined duration, which is or may be a function of the value of the overload.

Other advantages and characteristics of the invention will emerge more clearly from the description which follows of an embodiment of the invention, given by way of nonlimiting example and shown in the accompanying drawing, in which
Figure 1 shows the single-line electrical diagram of an installation equipped with a load shedding device according to the invention;
Figure 2 is the diagram of the load shedding block;
Figure 3 is an elevational view of the circuit breaker assembly, load shedding block;
Figure 4 shows the trigger and load shedding curves.

alternative (single-phase or three-phase)
In FIG. 1, a distribution network / comprises a main supply circuit 10, protected by a main circuit breaker 12, which supplies two feeders, a priority feeder 14 and a non-priority feeder 16. Each feeder is protected by a circuit breaker or a cut-off device 18, 20, the circuit breaker 20 of the non-priority start comprising a relay 22 for remote trip control command. The relay 22 is connected by conductors 24, 26 to a load-shedding block 28, inserted in the main circuit, and to a current source 30 which may be the network. The load-shedding block 28 is arranged to detect an overload in the main circuit 10 and issue a load shedding order transmitted to relay 22 during an overload and before crossing the tripping threshold of the main circuit breaker 12.

 It is clear that the network may include a larger number of departures, several of which may be non-priority.

The main circuit breaker 12 is a standard molded case circuit breaker 30 having on the opposite lateral faces input 32 and outlet 34 terminals. The load-shedding block 28 comprises a molded case 36 of conjugate profile to connect without interruption to the face of the circuit breaker carrying the output terminals 34. The load shedding block 28 comprises input terminals 38 coming in the coupled position of the boxes 30, 36 opposite the terminals 34 to which they are mechanically and electrically connected by screws (not shown). On the opposite face, the load-shedding block 28 carries output terminals 40 and it is easy to see that the circuit breaker 12, load-shedding unit 28 forms a block having, in the usual way, input 32 and output 40 terminals. on two opposite sides facilitating connections. The installation conditions of this set are similar to that of the standard circuit breaker, only the length of the device being modified. It is thus possible to use all the accessories and assembly facilities of the standard device.

Referring more particularly to FIG. 2, illustrating the electrical diagram of the load shedding block, it can be seen that the power conductors 42, connecting the input terminals 38 to the output terminals 4U, each pass through a surrounding current transformer 44 carrying a secondary winding 46. The signals available at the terminals of the secondary windings 46 are proportional to the currents in the power conductors 42 and these signals are rectified and shaped in a block 48 before being applied to a comparator block 50, which comprises counter signals with an IN setpoint and issue an alarm signal as soon as the setpoint is exceeded. The output 52 of the comparator block 50 transmitting the alarm signal is connected to an audible alarm 54, to a visual alarm 56 and to the input of a timer block 58 whose output is connected to a visual load shedding indicator 60 and to the coil 62 of a relay 64. A power supply unit 66, connected to the power conductors 42, supplies the comparator 50 and timer 58 units.

The contacts 68 of the relay 64 are connected to the connection terminals of the conductors 24, 26. The timer block 58 includes a device 70 for adjusting the time delay tl, when this time delay tl is independent of the overload, and a reset button. zero 72. The curve 74 of the set value is shown in FIG. 4, which also shows the tripping curve 76 of the main circuit breaker 12, and it is easy to see that the load shedding threshold is reached before the tripping threshold.

The device works as follows
In normal operation, the feeders 14, 16 are supplied normally, the circuit breakers 12, 18, 20 being closed and the contacts 68 of the relay 64 open. When the current in the main circuit 10, measured by the current transformers 44, exceeds the set value IN indicated on the curve 74, the comparator block 50 emits an alarm signal, resulting in an audible and visual alarm 54, signaling to the attendant the presence of an overload. These alarms stop as soon as the current drops below the setpoint IN. The alarm signal is also applied to the timer block 58 and if it remains for a period greater than tl, the timer 58 sends a load shedding order to the relay 64 which closes the contacts 68. The indicator 60 signals the emission of a load shedding order. The closing of the relay 68 causes the supply of the trip relay 22 and the opening of the circuit breaker 20 which interrupts the supply of the non-priority start. Timer 58 stores the load shedding order, resetting to zero by pressing button 72.

Reclosing the circuit breaker 20 requires the intervention of the attendant, but it is clear that an automatic reclosing control device can be incorporated in the load shedding block 28 so as to intervene as soon as the current falls below a predetermined value. , lower than the set value. It should be noted that the load-shedding block 28 can be arranged to respond to a load-shedding curve 78 of a different type, for example substantially parallel to the triggering curve 76 by making use of a bimetallic strip or a static device. without departing from the scope of the present invention and that certain alarms or indicators can be suppressed or supplemented. The electrical circuit of the load shedding block 28 may be different.

The invention is of course by no means limited to the mode of implementation more particularly described, and it should be noted that the device can operate in single-phase and in three-phase. In three-phase the device intervenes in the event of a single- or three-phase overload, with the same threshold.

Claims (4)

Claims 1. Load shedding device for a low voltage electrical installation having a main circuit (10) provided with a protective device (12) with molded casing (30) provided with connection terminals (32, 34) arranged on two opposite faces , and starting circuits (14, 16) supplied by the main circuit (10), at least one non-priority starting circuit (16) being equipped with a cut-off device (20), said device comprising an overcurrent detector (44) inserted in the main circuit, a load shedding relay (64) controlled by said detector to issue a load shedding order transmitted to the cut-off device (20) of said non-priority start (16) to open said cut-off device of a predetermined overcurrent in said main circuit (10), characterized in that said load shedding device is arranged in a block (28) capable of being attached to one of said faces of the protection device (12) of the main circuit (10), said block (28) having su r the contiguous face of the terminals (38) connecting to the adjacent conjugate terminals (34) of the protection device (12) in the contiguous position, and on the opposite face of the connection terminals (40), so as to connect in series in the main circuit (10), the load-shedding block (28) and the protective device (12), said block (28) having an overcurrent indicator (54, 56) and a connection terminal of a conductor for connecting the cut-off device (20) of the non-priority start to said load shedding relay (64), so as to transmit the load shedding order from said relay to the cut-off device. 2. Load shedding device according to claim 1, characterized in that said protection device constituted by a circuit breaker (12) has a predetermined tripping characteristic and that the load shedding characteristic of said load shedding device (28) is offset from to the tripping characteristic so that in the event of an overcurrent a load shedding order is issued before the tripping of the circuit breaker (12). 3. Load shedding device according to claim 1 or 2, characterized in that said block (28) comprises an alarm device (34, 56) emitting an alarm signal as soon as the intensity of the current in the main circuit ( 10) is greater than the nominal current and a load shedding indicator (60) indicating the issuance of a load shedding order. 4. Load shedding device according to claim 3, characterized in that said block (28) includes a timer (58) for transmitting a load shedding order when said overcurrent persists for a predetermined duration.