FR2595515A1 - Load-shedding apparatus with modification of the order of priority of the load shedding of non-priority circuits - Google Patents

Abstract

Load-shedding relay 10 having a priority circuit 12, and a plurality of non-priority circuits 14, 16 each equipped with a switch 36, 38 operated by a coil 32, 34. Each switch 36, 38 is associated with a load-shedding path VD1, VD2 containing an operational amplifier A1, A2 and a timing device with resistor R1, R2 and capacitor C1, C2. A resistive voltage divider R01, R02 makes it possible to set the load-shedding threshold, and a selector relay 66 cooperating with the load-shedding paths VD1, VD2 in order to invert the order or priority of the load shedding of the non-priority circuits 14, 16. The relay 66 includes a coil 70 with supply terminals B1, B2 and an inverting contact 68 able to connect up a resistor R5 in parallel with one of the resistors R1 or R2 of the timing device.

Description

RELIEF APPARATUS WITH CHANGE OF PRIORITY
RELIEF FROM NON-PRIORITY CIRCUITS
The invention relates to a load shedding apparatus, in particular a load shedding contactor or a load shedding relay, for an alternating current electrical energy distribution installation, having a priority circuit with permanent supply, and a plurality of non-priority circuits, each provided with a switch for temporarily interrupting the supply of the load shedding apparatus comprising - a sensor of the total current absorbed by the installation, - an electronic device for processing the signal emitted by the sensor, having a threshold adjustment circuit load shedding, a plurality of load shedding channels intended to send opening signals of said switches associated with non-priority circuits, when said signal exceeds the load shedding threshold, and a delay device capable of generating discrimination in response time of each lane causing progressive load shedding of non-priority circuits.

The operation of load-shedding contactors and load-shedding relays has several non-priority outputs dw: the electrical distribution installation generally operates according to a chronometric selectivity cycle carried out by means of different time constants at the input of the load-shedding channels of the device processing electronics.

The staggering of the teaps constants makes it possible to obtain a successive load shedding in cascade of non-priority circuits, when the current absorbed by the installation exceeds the load shedding threshold which corresponds to the adjustment of the rating of the connection circuit breaker. Such an arrangement has an invariable order of priority which systematically causes load shedding in the same way in the first place, which can lead to operating discomfort, for example by always cooling the same zone after the supply of the convectors is cut off. of the first non-priority circuit.

The object of the invention is to provide a load shedding device capable of modifying the priority order of load shedding of non-priority circuits.

The load-shedding apparatus according to the invention is characterized in that selection means cooperate with the load-shedding channels to modify the times of emission of the opening signals of the switches associated with the non-priority circuits, so as to hold a change in the order of priority of load shedding.

The selection means comprise a relay having a control coil of a switching contact cooperating with the timing device to reverse the response time of each load shedding channel during said priority order arrangement. When the selection relay coil is not energized, the operation with the load shedding device on these load shedding channels is conventional, resulting in successive load shedding of the first non-priority circuit and the second non-priority circuit. of the relay coil, the change of state of the changeover contact reverses the order of priority of load shedding, first causing an interruption in the supply of the second non-priority circuit, then that of the first non-priority circuit.

The excitation circuit of the relay coil comprises a system with supply terminals which can be electrically connected to a manual control member, or to a remote control device. A first terminal is connected to one end of the relay coil, while the second terminal is connected to a power source ALIM of the electronic processing device, incorporated in the load shedding device. The closing of the supply circuit by shunting the first and second terminals causes the excitation of the selection relay coil, and the inversion of the load shedding priority order.

The selection relay can also be formed by a bistable switching device with impulse control, in particular a remote control switch.

According to an alternative embodiment, an astable multivibrator circuit with adjustable frequency is connected to the terminal system to obtain an alternative priority of load shedding of the channels.

According to another variant, the supply circuit of the selection relay comprises two terminals to which a relay or a flip-flop bistable controlled by a third terminal electrically connected to the output of the operational amplifier of each load shedding path can be connected. intermediary of an iodine, the assembly being arranged such that the emission of a pulse on said third terminal, upon unlocking with the operational amplifier, causes a change of state of said flip-flop, causing excitation or l absence of excitation that the selection relay coil @.

 Other advantages and characteristics will emerge more clearly from the description which follows of different embodiments, given by way of nonlimiting examples.

Referring to the figure, a load shedding device. in particular a celestor contactor or a load shedding relay 10 of a mon @ phased electrical installation, supplies a priority circuit 12 and two non-priority circuits 14. 16.

The installation is connected to a single-phase alternating network having a phase conductor 18 and a neutral conductor 20. The load-shedding relay 10 is arranged just after the connection circuit breaker 22 of the installation, and is traversed by the total current absorbed . This current is measured by a sensor 24, in particular a current transformer associated with the phase conductor 1 @, the secondary of the transformer delivering a measurement signal proportional to the total current absorbed, to an electronic processing block designated by the general reference 26. Two outputs 28, 30, of the processing block 26 are respectively connected to coils 32 34, o control of switches 36. 38, inserted upstream of the departures of the non-priority circuits 14, 16.

The excitation of the coils 32 ,. 34, respectively causes the opening of the switches 36 38, and the interruption of the supply of the associated non-priority circuits 14. 16
The block that processes 26 is connected to an auxiliary power source (ALIM) connected to the active conductors 18. 20. by a transformer 40. The power source LI con. carries a rectifier bridge 42 a filter capacitor 44, and a voltage stabilizer circuit comprising a transistor 45 controlled by a Zener diode 4 o'. The stabilized DC voltage Vcc supplies the processing block 26 of the load shedding relay 10 and a divider bridge 50 supplies a fixed reference voltage to the phase-shift input (-) of two operational amplifiers (A1, A2).

The processing block 26 comprises a resistive voltage divider, constituted by a fixed resistor R01 connected between the secondary winding of the sensor 25, and a plurality of adjustable resistors R02, either manually by means of a switch 52 with studs or automatically at by means of a remote-controlled rotary selector. The resistive voltage divider can also be formed by a simple potentiometer with adjustment cursor.

The adjustment of the resistive voltage divider allows local or remote selection or load shedding threshold of the relay 10. which is generally set to the rating of the circuit breaker 22. The midpoint 54 of the resistors R01 R02 is connected to the switch 52 and to two identical load shedding channels VD1, VD2 respectively associated with outputs 23, 30. The first load shedding channel VD1 includes a diode 56 for rectifying the measurement signal @ delivered by the sensor 24. The cathode of diode 56 is connected to 1 non-phase shifting input (+) of the operational amplifier A1, while the anode @e the dione 56 is connected by a resistor R1 at the midpoint 54. A capacitor C1 and a bias resistor R3 are connected in parallel between the non-phase-shifting input (+) of amplifier A1 and ground. Resistor Ri and capacitor C1 constitute a timing circuit having a predetermined time constant
The other input (-) of the operational amplifier A1 receives the reference voltage supplied by the power supply ALIM.

The output of the operational amplifier A1 is connected via a light-emitting diode LED1 to the boDine 32 of the switch 36. A feedback circuit comprising a capacitor 58 and a resistor 60, is interposed between the output of the LD diode and the input (+) of the amplifier Ai. This feedback circuit makes it possible to maintain the state of interruption of the non-priority circuit 14 for a predetermined duration.

The second load-shedding channel VD2 is identical to the first channel VD1, and includes timing resistors R2 and polarization R41 and a capacitor C2 having values identical to those of the resistors R1 and R3 and of the capacitor
C1. The processing block 26 includes other elements, in particular a Zener diode 62 for clipping the signal delivered by the sensor 2, and a diode 64 connects to the feedback circuit to suppress negative voltage peaks.

The signal put by the midpoint 54 of the voltage divider (R01
R02) is proportional to the current flowing through the pnase conductor i 8. This signal is rectified by the diode 56 and is used to gradually charge the capacitor C1. C2 of each channel VD1, VD2.

According to the invention. a resistor R5 is connected in parallel to the terminals of one of the resistors R1 or R2 via a selection relay 56, with the change-over contact 68 being controlled
Jar an auxiliary coil 70 The excitation circuit of the coil 70 comprises two terminals B1 and B2 accessible from the outside by fixing to the housing of the load shedding relay 1 @. One of the terminals B1 is connected to the coil 70, while the other terminal B2 is connected to the potential Vcc of the power source ALIM. The shunting of terminals B1 and B2 excites the coil 73 or relay 65 and changes the position of the change-over contact 68.

The shunting of terminals B1 and 32 can be carried out in various ways: - either by means of a pluggable conductive jumper - or by means of a manually controlled switch allowing a system to operate at will - or by means of a switch programmable timetable or any other scheduler having pilot contact with a clock.

The circuit according to the invention operates in the following manner - when terminals 1 and 2 are not shunted (case of the figure). the change-over contact 68 of the selection relay 66 is located on the upper pin Pi. The coil 70 is not energized, and the resistor R5 is placed in parallel on the resistor Ri.

The equivalent resistance arranged in series in the first load shedding channel VD1 is always less than the resistance R2 of the second load shedding channel VD2.

The time constant at the timing circuit of the operational amplifier A1 of the first channel VD1 is lower than that of the timing circuit of the amplifier A2 of the second channel VD2. If the admissible current is exceeded by the subscribed power, the operational amplifier A1 is released first. The light-emitting diode LED1 lights up, and the coil 32 is energized, causing the switch to open 36 and the interruption of the supply of the first non-priority circuit 14. If the overload persists, the unlocking of this operational amplifier A2 takes place in a second phase, as soon as the voltage across the terminals of the capacitor C2 reaches the voltage of reference applied to the phase shift input (-).

The excitation of the coil 34 causes the switch 38 to open and the supply of the second non-priority circuit 16 to be interrupted. This second load shedding is signaled by the light-emitting diode LED2. Such a chronometric selectivity operation allows on the one hand a cascade load shedding in order of priority of the first non-priority circuit 14, then of the second non-priority circuit 16, and on the other hand a step-by-step relestage in order of priority. The successive load shedding avoids cutting the example of non-priority circuits 14, 16, when the load shedding of the first circuit 14 by the channel vD1 is sufficient to reduce the power absorbed to a value below the threshold selected by the switch 52.

 linked s @ untage of the terminals @ 1 and 2 ensures the excitation of the coil 70 of the selector relay 66, and 1 change of position of the change-over contact 68 @ which is actuated on the lower pad P2.

The resistor R5 is connected in parallel to the resistor R2, and the value of the equivalent resistor is laughed with the second load-shedding channel VD2 is then less than the nominal value of the resistor R1 of the first channel VD1. The time constant at the timing circuit of the operational amplifier A2 of the second channel VD2 is less than that of the amplifier A1 of the first channel VD1.

When the current exceeds the load shedding threshold, the amplifier A2 sends a first opening signal to the cattle 34 yes opens the switch 38 of the non-priority circuit 16. The amplifier Ai then delivers a second setting opening signal in time at the coil 32 for the opening of the switch 35 of the non-priority circuit 11.

It is noted that the presence of the selection relay 66 per @ and of reversing the order of priority of the load shedding channels VD1, VD2.

This modification of the load shedding order of the non-priority circuits 14, 16, by snapping terminals 31 and B2 can be operated, either locally by means of a manual switch, or remotely by means of a programmable time switch. or any other remote control device.

According to a variant not shown, the selection relay 66 is formed by a bistable switching member with impulse control, such as a remote control switch. The terminal is no longer connected to the potential Vcc of the ALI power source, but is connected directly to ground. It then suffices to inject a control signal at the terminal B1 to cause the change of state of the remote control switch, and the modification of the load shedding order of the channels VD1 and VD2.

According to a development of the invention illustrated in the figure, a multivibrator circuit as table 80 (dotted line) can be electrically connected to the terminals B1 and B2. The beat frequency of the multivibrator circuit B0 is adjustable. This circuit is of the flasher relay type with an alternative priority for load shedding of channels VD1 and VD2. The multivibrator circuit 80 is supplied by the power supply source ALIM of the load shedding relay 10, and makes it possible to obtain a random distribution as priority.

According to another variant in which a random distribution of priority is not admissible, it is possible to connect to the terminals B1 and 32, a relay or a flip-flop bistable, controlled by a third terminal B3, itself connected to the outputs 2 @ , 30 of the operational amplifiers A1 and A2 by means of diodes 82, 34. At each pulse recorded on the third terminal B3, the bistable relay changes state, and the terminals 31 and 32 are short-circuited or not, causing the excitation or the absence of excitation of the coil 70.

Claims (8)

1. Load shedding apparatus, in particular a load shedding contactor or a load shedding relay, for an installation for distributing electrical energy with alternating current, having a priority circuit (12) with permanent supply, and a plurality of non-priority circuits (14, 16) each has a switch (36. 38) for temporarily interrupting the supply, said load shedding apparatus comprising - a sensor (24) of the total current absorbed by the installation. - an electronic processing device (26) to the signal zanis by the sensor (24), having an adjustment circuit (R01, R02, 52) of the load shedding threshold, a plurality of load shedding channels (VD1. VD2) intended to send opening signals of said switches (36, 38) associated with non-priority circuits (14, 16) when said signal exceeds the load shedding threshold, and a delay device (R1, C1 R2, C2) capable to generate a discrimination in the response time of each channel leading to progressive load shedding of the non-priority circuits (14, 16), characterized in that selection means (R5, 66, 68, 70) cooperate with the load shedding channels ( VD1, VD2) to modify the instants of transmission of the opening signals of the switches (36, 38) associated with the non-priority circuits (14, 16) so as to obtain a change in the priority order of load shedding. 2. Load shedding apparatus according to claim 1, characterized in that the selection means comprise a relay (66) having a coil (70) for controlling a selector contact (68) cooperating with the timing device for reversing the time response of each load shedding channel VD1, VD2 during said change of order of priority. 3. Load shedding apparatus according to claim 2, characterized in that the excitation circuit of the coil 70 of the relay (66) comprises a system with supply terminals (31, B2) which can be electrically connected to a connection member. manual control, or to a remote control device. 4. Load shedding apparatus according to claim 3, characterized in that a first terminal B1 is connected to one end of the coil (70) of the relay (66), while the second terminal 32 is connected to a power source ALIM of the electronic processing device (26) incorporated in the load shedding apparatus, and that an auxiliary contact, in particular of a manually operated switch or of a programmable normal switch, causes the shunting of the first and second terminals 31 and 32 for excitation of the coil (70). 5. Load shedding apparatus according to claim 3, characterized in that the relay (66) is formed by a bistable switching member with impulse control, and that the device @ remote control delivers a control signal to one of the terminals (B1 ) to cause the change of state of the relay (66) and the modification of the priority order of load shedding. 6. Load shedding apparatus according to claim 3, characterized in that an astable multivibrator circuit (80d) with adjustable frequency is connected to the terminal system (B1, B2) to obtain an alternative priority for load shedding of the channels (VD1 and VD2) . 7. Load shedding apparatus according to one of claims 2 to, each load shedding channel (VD1, VD2) comprising an operational amplifier (A1, A2) with a time delay determined by a resistor (R5, R1, R2) and a capacitor ( C1, C2), characterized in that the output of the operational amplifier (A1, A2) delivers an opening signal to a coil (32, 34) for controlling this switch (36, 38) of the non-priority circuit associated (14, 16), and that a light-emitting diode (LED1, LED2) for signaling load shedding is inserted in each channel VD1, VD2 between the output of the operational amplifier (A1, A2) and said coil (32, 34 ). 8. similar load shedding according to claim 7, characterized in that the supply circuit of the relay (66) for selection comprises two terminals (B1, B2) to which a relay or a flip-flop bistable controlled by a third terminal B3 can be connected electrically connected to the output of the operational amplifier (A1,, A2) of each load shedding channel (VD1, VD2) by means of a diode (82, 64), the whole being an agency such as the transmission of a pulse on said third terminal B3 when the operational amplifier Al, A2 is released causes a change of state of said flip-flop, causing excitation or absence of excitation of the coil (70) of the relay ( 66) of selection.