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Description  |
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BACKGROUND OF THE INVENTION
The invention relates to a solid-state trip device of a molded case
electrical circuit breaker having per pole a pair of contacts, elastically
urged into contact in the closed position of the circuit breaker and
capable of separating by the action of an automatic operating mechanism on
a fault, comprising sensors which generate fault signals which are a
function of the currents flowing in the conductors protected by the
circuit breaker, and a processing unit to which said fault signals are
applied to generate a circuit breaker tripping order, when preset
thresholds are exceeded, said order being time-delayed according to the
value of the fault signals.
The contacts of an electrical circuit breaker must open cleanly to avoid
any intermediate contact repulsion position, the contacts nevertheless
being insufficiently separated for the arc drawn between the contacts to
be extinguished. Continuance of the arc between the partially open
contacts causes overheating and damage to the circuit breaker. Repulsion
of the contacts takes place due to the effect of the electrodyanmic forces
when the current exceeds a preset repulsion threshold, this threshold
depending on the configuration of the current in the circuit breaker and
on the pole setting characteristics.
To be sure that a circuit breaker does not remain in an intermediate
contact repulsion position, the tripping threshold on a fault is generally
set to a value lower than that of the repulsion threshold. It is difficult
and costly to achieve circuit breakers having perfectly defined repulsion
and tripping threshold 20 to 50% lower than the repulsion threshold is
frequently selected, which results in a considerable loss of selectivity.
The object of the present invention is to achieve a trip device whose
tripping threshold and the repulsion threshold are the same.
Another object of the invention is to achieve a trip device providing
instantaneous tripping when the circuit breaker detects a fault.
SUMMARY OF THE INVENTION
The trip device according to the invention is characterized in that an arc
detector is associated with each pair of contacts to detect the light
emitted by the arc drawn when the contacts separate, the arcing signals
emitted by said arc detectors being applied to said processing unit to
bring about instantaneous tripping when at the same time the fault signals
exceed said preset threshold.
Any separation of the contacts, notably by electrodyanmic repulsion forces,
causes a spark or an arc to form emitting a light which can easily be
detected by optical sensors such as photoelectric components which are
preferably located away from the arcing zone and connected to the latter
by light conductors such as optical fibers. By locating, according to the
invention, the arc sensors or detectors inside the molded case,
disturbances due to outside light are avoided in a particularly simple
manner. Subjecting instantaneous tripping of the circuit breaker to the
simultaneous presence of an arcing signal and of a fault signal prevents
spurious tripping due to the arcs drawn between the contacts when normal
circuit breaker make and break operations are performed. It can easily be
understood that detection of an arc and detection of a fault current do
not require any great accuracy, since the light emitted by the arc is
superabundant and the difference between a current capable of causing
repulsion of the contacts and the rated circuit breaker current is very
great. According to the configuration of the current or the pole
characteristics, electrodynamic repulsion can occur on a single pair of
circuit breaker contacts and it is important that this repulsion be
detected by associating an arc detector with each pair of circuit breaker
contacts. In the case of an optical fiber, the light emitted by any one of
the circuit breaker poles can be collected by running this fiber through
the various arcing compartments near the pairs of contacts, but it is
conceivable to fit a detector at a location of the molded case enabling
the light emitted by any one of the pairs of contacts to be seen through
orifices made in the internal partitions of the molded case. Each pair of
contacts can have associated with it an optical fiber transmitting the
light to the processing unit.
By using light to detect contact repulsion, tripping before the contacts
are separated by the effect of electrodyanmic repulsion is prevented and
inversely instantaneous tripping of the circuit breaker is ensured as soon
as repulsion of any one of the pairs of circuit breaker contacts occurs.
The trip device on contact repulsion is advantageously associated, or
performs in addition the usual long delay and short delay protective
tripping on an overload or a fault of an amplitude lower than the circuit
breaker repulsion threshold.
The solid-state trip device according to the invention comprises analog
and/or digital processing circuits, since the instantaneous tripping
circuit on contact repulsion is advantageously analog in order to have a
very short response time. Subordination of instantaneous tripping to the
simultaneous presence of an arcing signal and a fault signal can be
accomplished by suitable means, notably by an AND circuit, which receives
the two arcing and fault signals on its inputs.
The solid-state trip device according to the invention also provides
instantaneous protection when the circuit breaker detects a fault. In this
case it is important to achieve immediate breaking of the circuit breaker,
independently from the short delay and long delay tripping circuits which
provide a time delay compatible with the tripping selectivity. Making on a
fault automatically gives rise to an arc on the contacts which is detected
by the arc detectors and to an overcurrent indicated by a fault signal,
causing the circuit breaker to break. The device according to the
invention advantageous replaces time-delayed contacts which inhibit the
instantaneous trip device after a certain time.
BRIEF DESCRIPTION OF THE DRAWINGS
Other advantages and features will become more clearly apparent from the
following description of an illustrative embodiment of the invention,
given as a non-restrictive example only and represented in the
accompanying drawing in which the single FIGURE represents the block
diagram of a trip device according to the invention.
DESCRIPTION OF THE PREFERRED EMBODIMENT
In the figure, an electrical power distribution system with 3 conductors R,
S, T, supplying a load (not shown) comprises a circuit breaker 10 capable
of interrupting the circuit in the break position. The mechanism 12 of the
circuit breaker 10 is controlled by a polarized relay 14 controlling
tripping of the circuit breaker in the event of an overload or
short-circuit occurring. An auxiliary contact 16, associated with the main
contacts 17R, 17S, 17T, of the circuit breaker 10 indicates the position
of these main contacts 17R, 17S, 17T. Each conductor R, S, T has
associated with it a current transformer 18 which delivers a signal
proportional to the current flowing in the associated conductor, this
signal being applied to a full-wave rectifier bridge 20. The outputs of
the 3 rectifier bridges 20 are connected in series in a circuit comprising
a resistor 22, a zener diode 24 and a diode 26 to produce at the terminals
of the resistor 22 a voltage signal proportional to the maximum value of
the current flowing in the conductors R, S, T, and at the terminals of the
diode 24, a voltage supplying the electronic circuits. The voltage signal
is applied to the input of the amplifier 28, whose output is connected to
an analog to digital converter 30. The output of the analog to digital
converter 30 is connected to an input 1 of a microprocessor 32. The
microprocessor 32 comprises in addition an output 2 connected to the
polarized relay 14, an input 3 receiving the signals from a clock 34, an
input 4 connected to a keypad 36 with keys 44, an input 6 connected to a
read-only memory ROM 38, an input-output 5 connected to a random access
memory NOVRAM 40, an output 7 connected to a display device 42 and an
input 8 connected to the auxiliary contact 16.
The trip device according to FIG. 1 performs the protection function,
notably long delay tripping and/or short delay tripping, respectively,
when an overload or fault occurs in the circuit of the conductors R, S, T.
The digital signal representative of the maximum value of the current in
the conductors R, S, T, is applied to the input 1 of the microprocessor 32
and compared with threshold values stored in a memory to detect any
overshoot of these thresholds and to generate a delayed or instantaneous
tripping order, which is transmitted to the relay 14 to bring about
opening of the circuit breaker 10. The trip device can naturally perform
other functions, notably earth protection. A trip device of the kind
mentioned is well-known to those specialized in the art and is for example
described in the U.S. patent application No. 07/077.420 filed on July 24,
87, which should be referred to advantageously.
The invention can be used in any solid-state trip device and is in no way
limited to the trip device of the type described hereinabove. To give a
non-restrictive example, the current detection means can comprise current
sensors supplying analog signals representative of the current derivative
di/dt and whose output is connected to integrated circuits, the output
signals from the integrated circuits being transmitted to the
microprocessor via an analog to digital converter. The solid-state trip
device can also be of the analog type. According to the present invention,
the circuit breaker 10 comprises an enclosure of the molded case type
inside which the main contacts 17R, 17S, 17T, of the three circuit breaker
poles are disposed. The three poles R, S, T are separated by walls
defining internal compartments of the molded case and each pole has
associated with it an arc detector 46R, 46S, 46R located in proximity to
the main contacts 17R, 17S, 17T. The light collected by the arc detectors
46R, 46S, 46T is transmitted by an optical fiber 48 to a photoelectric
component 50 which emits an electrical signal proportional to the light
collected, this electrical signal being applied to an input of an AND
circuit 52. The other gate of the AND circuit 52 is connected to a
threshold circuit 54 connected to the output of the amplifier 28. The
output of the AND circuit 52 is connected via a diode 56 to the polarized
relay 14. A diode 58 is inserted in the connection between the output 2 of
the microprocessor 32 and the polarized relay 14 to avoid any interference
between the tripping signals applied to the polarized relay 14,
respectively by the microprocessor 32 and by the instantaneous arc
repulsion tripping circuit.
The solid-state trip device according to the invention operates as follows:
When an overload or fault occurs, the microprocessor 32 causes the circuit
breaker 10 to trip in the usual manner, with a possible time delay. The
separation of the contacts 17R, 17S, 17T, causes light to be emitted,
detected by the arc detectors 46R, 46S, 46T, and transmitted by the
optical fiber 48 to the photoelectric component 50 which applies a signal
to the AND circuit 52. This AND circuit 52, which receives a fault signal
on its other input, sends a superfluous tripping order to the polarized
relay 14, the latter having already brought about tripping of the circuit
breaker 10. This additional order does not disturb operation of the trip
device.
In the event of a short-circuit current of high intensity greater than the
repulsion threshold of the contacts 17R, 17S, 17T, or of any arc detected
by the sensors 46R, 46S, 46T. The arcing signal applied to the AND circuit
52, which at the same time receives the fault signal transmitted by the
amplifier 28 and the threshold circuit 54, generates a tripping order
transmitted to the polarized relay 14. This tripping takes place
instantaneously and causes the contacts of the circuit breaker 10 to open
immediately thus avoiding any intermediate position of the contacts liable
to cause overheating and damage to the circuit breaker. The detectors 46R,
46S, 46T located inside the molded case are shielded from the outside
light and there is no risk of them causing spurious trips. They do however
detect sparks or arcs occurring on the main contacts 17T, 17S, 17T, when
normal make or break operations of the circuit breaker 10 are performed,
notably by manual control, but the arcing signal is blocked by the AND
gate 52, which does not receive a fault signal on its other input. Any
spurious tripping and re-opening of the circuit breaker 10 is thus avoided
and instantaneous tripping takes place only when repulsion of the main
contacts 17R, 17S, 17T occurs. The short delay and long delay tripping
thresholds can be selected close to the contact repulsion threshold, any
operator error being excluded by the arc detection device according to the
invention.
Inhibition of the instantaneous tripping arcing signal can of course be
achieved by different means, notably by overload detectors independent
from the sensors controlling the short delay and long delay tripping. The
light conductor can be an optical fiber made of plastic material whose end
close to the main contacts 17R, 17S, 17T is bared over a short length to
pick up the arc light, the bared end of the fiber constituting the arc
detector. Three independent fibers can of course be used, each one
associated with one of the pairs of contacts, these three fibers
controlling the light-sensitive electronic component 50 which can for
example be a photodiode or a phototransistor. The bared end of the optical
fiber 48 which constitutes the arc detector is preferably located in a
zone shielded from the pollution due to the arc, or this end is arranged
in such a way that it is cleaned by any appropriate means, for example
mechanically, each time the circuit breaker operates.
The instantaneous arc detection trip device according to the invention can
naturally be used in different types of standard trip devices, notably of
the analog type.
The trip device according to the invention also provides instantaneous
protection in the following way when the circuit breaker detects a fault :
When the circuit breaker 10 detects a fault, an arc occurs on the main
contacts 17R, 17S, 17T and this arc is detected by the detectors 46R, 46S,
46T which emit an arcing signal applied to the AND gate 52. As detection
of a fault takes place, the fault current is detected by the circuit 54
which sends a fault signal to the AND gate causing instantaneous tripping
of the circuit breaker 10. In normal operation, the detectors 46R, 46S,
46T do not emit any signal and only the long delay and short delay trip
devices provide protection.
The invention is naturally in no way limited to the embodiment particularly
described hereinabove.
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