Method and apparatus for circuit breaking

A junction box architecture includes a main circuit breaker, plurality of branch circuit breakers, and an arc detection unit. The main circuit breaker input is connected to main power supply lines, e.g., phase 1 and phase 2 power lines. The main circuit breaker output is connected to respective inputs of branch circuit breakers and to an input of the arc detection unit. The arc detection unit includes an enable output and is configured to generate an enable signal on the enable output. The enable output is coupled to enable inputs of each branch circuit breaker. When no enable signal is present on an enable input of any one branch circuit breaker, the one breaker will not trip. In general, for any one circuit breaker to trip, the breaker must simultaneously detect a high frequency current in the associated branch circuit and receive an enable signal from the arc detection unit.

FIELD OF THE INVENTION 
This invention relates generally to arc-detecting circuit breakers and, 
more particularly, to performing arc-detecting circuit breaking functions 
with high reliability. 
BACKGROUND OF THE INVENTION 
A residential power circuit, e.g., for a house, typically is divided into a 
number of branches, and in the U.S. each power circuit branch is coupled 
to one of two 110 volt power lines, e.g., phase 1 or phase 2 power lines, 
extending to the house from a power distribution transformer. The phase 
lines are coupled to the respective power circuit branches in a junction 
box usually located inside the residence, and circuit breakers are 
physically located in the junction box. Each circuit breaker is 
electrically connected in series with one branch circuit and one phase 
line. 
Known residential circuit breakers include a detection device which 
determines whether excess current is flowing in the branch circuit for 
longer than an allowable time period. Such excess current flow sometimes 
is referred to as an "overcurrent condition". In the presence of an 
overcurrent condition in a particular branch circuit, the associated 
circuit breaker disconnects the branch circuit from the phase line. The 
circuit breaker protects the branch circuit and facilitates identification 
of a fault, i.e., the fault will be located on the branch circuit 
associated with the tripped circuit breaker. 
A conventional circuit breaker does not include an arc detection unit. 
Although detection of arcs is desirable to reduce the possibility of a 
fire being started by an arc and to protect house wiring and consumer 
wiring, e.g., extension cords, appliance cords and appliances, known 
residential arc detection units generally are expensive and inconvenient 
to use. More specifically, arcs generally can be identified by the high 
frequency content of current flowing in a branch circuit. High frequency 
current, e.g., current having a frequency in the range of 1 KHz to 10 MHz, 
can be introduced into the branch circuit through benign apparatus such as 
universal motors in hair driers, drills and vacuum cleaners. Such motors 
can produce significant high frequency energy due to arcing of the brush 
motor commutation. Silicon controlled rectifier lamp dimmers and advanced 
electronic devices can also generate high frequency energy, intentionally 
or unintentionally. Discriminating between actual arcing faults and benign 
sources of high frequency energy therefore is much more difficult than 
merely sensing a high frequency current. A residential arc detection unit, 
however, must have a low nuisance trip, i.e., false alarm, rate. Known arc 
detection units having the necessary low false alarm rate are expensive. 
A residence can be completely protected against arc currents by placing arc 
detecting mechanisms in every branch breaker. When a breaker opens, the 
fault is partially located by identifying the interrupted branch. Even 
while the one branch is interrupted, power continues to be supplied to the 
other branch circuits. Of course, this architecture is very high in cost 
because accurate arc detection units are required for each branch circuit. 
In an attempt to keep costs low, a residence wiring could be completely 
protected by having one arc detection unit coupled to the main circuit 
breaker, or interrupter, for the entire residence. Rather than one arc 
detection unit for each branch circuit breaker, which may require more 
than ten (10) arc detection units, only one arc detection unit is 
required. Such architecture is lower in cost. However, when a fault 
occurs, the main circuit breaker is opened and all power is cut-off to the 
residence with no indication of where the fault occurred. Such operation 
is inconvenient in that it unnecessarily cuts-off power to an entire 
residence and does not facilitate location of a fault. 
Rather than using only one arc detection unit to trip the main breaker or 
separate arc detection units for each branch circuit, a residence can be 
partially protected by installing arc detection units in selected ones of 
the branch circuits. While this architecture is lower in cost as compared 
to having separate arc detection units for each branch circuit, some of 
the residence is unprotected from arcs, which is undesirable. 
It would be desirable to provide complete protection for a residence from 
arc type faults, as well as to provide fault isolation and location. It 
would also be desirable to provide such complete protection at a low cost 
as compared to the cost associated with using sophisticated arc detection 
units in each branch circuit. 
SUMMARY OF THE INVENTION 
According to one aspect of the invention, a junction box architecture is 
provided which, in one embodiment, includes a main circuit breaker, a 
plurality of branch circuit breakers, and an arc detection unit. The main 
circuit breaker input is connected to main power supply lines, e.g., phase 
1 and phase 2 power lines. The main circuit breaker output is connected to 
respective inputs of branch circuit breakers and to an input of the arc 
detection unit. 
The arc detection unit includes an enable output and is configured to 
generate an enable signal on the enable output. The enable output is 
coupled to enable inputs of each branch circuit breaker. In general, for 
any one circuit breaker to trip, two conditions must be satisfied; 
specifically, the breaker must detect a high frequency current in the 
associated branch circuit and simultaneously receive an enable signal from 
the arc detection unit. When no enable signal is present on an enable 
input of one branch circuit breaker, or if the one circuit breaker does 
not detect a high frequency current, the one breaker will not trip. 
The junction box architecture described above has many significant 
advantages. Particularly, in such architecture, only one high accuracy arc 
detection unit is required for the many circuit branches. Such structure 
provides high accuracy arc detection without the added cost of a dedicated 
arc detection unit for each branch. In addition, fault isolation and 
location are facilitated because a branch circuit breaker trips only when 
it detects a high frequency current and receives an enable signal. 
Therefore, power is not cut-off to the other branch circuits and the fault 
typically can be found on the branch circuit associated with the tripped 
circuit breaker.

DETAILED DESCRIPTION OF THE DRAWINGS 
FIG. 1 illustrates a junction box 10 which includes a main circuit breaker 
12, a plurality of branch circuit breakers 14, and an arc detection unit 
16. Main circuit breaker 12 includes an input 18 and an output 20. Main 
circuit breaker input 18 is connected to main power supply lines, e.g., 
phase 1 and phase 2 power lines (not shown). Main circuit breaker output 
20 is connected to respective inputs of branch circuit breakers 14 and to 
an input of arc detection unit 16. Each branch circuit breaker 14 is 
coupled to a respective power circuit branch of, for example, a residence. 
Arc detection unit 16, upon detecting existence of an arc in current 
received from main circuit breaker 12, is configured to generate an enable 
signal on an enable output line 22, coupled to enable inputs of each of 
branch circuit breakers 14. When no enable signal is present on an enable 
input of one of branch circuit breakers 14, that circuit breaker will not 
trip in the presence of only high frequency current if no other anomaly 
exists. 
In general, and for any one of branch circuit breakers 14 to trip for arc 
suppression, two conditions must be satisfied. Specifically, such one of 
breakers 14 must simultaneously detect a high frequency current in the 
associated branch circuit and receive an enable signal from arc detection 
unit 16. 
The architecture of junction box 10 described above provides many 
significant advantages. Particularly, only one high accuracy arc detection 
unit 16 is required for the many circuit branches. Each branch therefore 
has the added benefit of arc protection without the added requirement of a 
dedicated arc detection unit for each branch. The present invention is not 
directed to any particular arc detection unit since it is believed that 
any arc detection unit which reliably differentiates an arc from a benign 
source of high frequency energy on a branch circuit can be used in 
implementing a junction box in accordance with the architecture described 
above. An example of such an arc detection unit is described in U.S. Pat. 
No. 5,477,150. 
FIG. 2 is a block diagram of a junction box circuit 50 for junction box 10 
illustrated in FIG. 1. Specifically, with reference to FIG. 2, junction 
box circuit 50 is configured to be electrically connected between a first 
main power line, i.e., PHASE1, a second main power line, i.e., PHASE2, and 
a plurality of first and second branch circuits, generally designated 
BC1A, BC1B, etc. (for the first branch circuits) and BC2A, BC2B, etc. (for 
the second branch circuits). 
PHASE1 and PHASE2 lines, which typically are 110 volt power distribution 
lines in the U.S., are electrically connected to main circuit breaker 12. 
A first output line 52, which is coupled to the PHASE1 line, and a second 
output line 54, which is coupled to the PHASE2 line, extend from main 
circuit breaker 12 through current transformers 56 and are connected to 
respective breakers 14. Specifically, first output line 52 is connected to 
first branch circuit breakers 1A, 1B, etc. and second output line 54 is 
connected to second branch circuit breakers 2A, 2B, etc. 
Outputs of current transformers 56 are coupled to arc detection circuit, or 
unit, 16. By way of example, and in one embodiment, a first current 
transformer is positioned to sense current in first output line 52 and a 
second current transformer is positioned to sense current in second output 
line 54. The first and second current transformers provide separate 
signals to arc detection unit 16, and using such signals, arc detection 
unit 16 may generate an enable signal. It will be appreciated that, in the 
alternative, voltage sensors may be utilized instead of current 
transformers 56. 
Arc detection unit 16 generates a first enable signal on first enable 
output line 58 based on current from the current transformer associated 
with first output line 52. Arc detection unit 16 generates a second enable 
signal on second enable output line 60 based on current from the current 
transformer associated with second output line 54. 
First branch circuit breakers 1A, 1B, etc. are connected to first enable 
output line 58 of arc detection unit 16. Second branch circuit breakers 
2A, 2B, etc. are connected to second enable output line 60 of arc 
detection unit 16. Each branch circuit breaker 1A, 1B, etc. and 2A, 2B, 
etc. is operable so that it will not trip in the presence of an arc in its 
respective branch circuit when no enable signal is present on its 
respective enable output lines 58 and 60. However, the normal overcurrent 
trip function remains operative even when the enable signal is not 
present. 
In general, and as explained above, for any one branch circuit breaker 1A, 
1B, etc. and 2A, 2B, etc. to trip, such breaker 1A, 1B, etc. and 2A, 2B, 
etc. must simultaneously detect a high frequency current in the associated 
respective branch circuit BC1A, BC1B, etc. or BC2A, BC2B, etc. and receive 
an enable signal on enable line 58 or 60 from arc detection unit 16. For 
example, when breaker 1B detects a high frequency current in its 
associated branch circuit BC1B, if arc detection unit 16 does not provide 
an enable signal to breaker 1B via enable line 58, breaker 1B will not 
trip. Such condition generally means that benign arcing is occurring on 
branch circuit BC1B. If, however, breaker 2A detects a high frequency 
current in its associated branch circuit BC2A, and if arc detection unit 
16 does provide an enable signal to breaker 2A via enable line 60, breaker 
2A will trip, cutting-off power to branch circuit BC2A. Such condition 
generally indicates that a fault occurred within branch circuit BC2A. 
Therefore, in addition to providing high accuracy arc detection, junction 
box circuit 50 also facilitates identification and location of a fault, 
e.g., location of a fault within a particular branch circuit. 
FIG. 3 is a block diagram of circuit breaker 1A in accordance with one 
embodiment of the present invention. Of course, other types of circuit 
breakers could be utilized in connection with the present invention, and 
the present invention is not limited to practice with circuit breaker 1A. 
Circuit breaker 1A, as illustrated in FIG. 3, is substantially similar to 
well known GFCI (Ground Fault Current Interrupter) breakers in common use 
today. 
More specifically, circuit breaker 1A includes a detection unit 100 having 
a current transformer 102 and a high pass filter 104. As shown by way of 
example in FIG. 3, current transformer 102 is connected to the PHASE1 line 
and is also coupled to high pass filter 104 which passes signals within a 
predetermined frequency range, e.g., 1 KHz to 1 MHz. 
Breaker 1A further includes an interrupt unit 106 having a gated amplifier 
108 coupled to high pass filter 104. Gated amplifier 108 is enabled by a 
signal on output line 58 from arc detection unit 16 (FIG. 2). The output 
of gated amplifier 108 is coupled to a rectifier 110. A solenoid 
controlled switch 112 including a coil 114 and a magnetic arm (permanent 
magnet) 116 is connected to the output of rectifier 110. Interrupt unit 
106 further includes a fixed contact 118 and a moveable contact 120. Fixed 
contact 118 is connected to the PHASE1 power line, and moveable contact 
120 is connected to magnetic arm 116 of switch 112. Moveable contact 120 
has a first, circuit-making condition in which it abuts fixed contact 118, 
and has a second, circuit-breaking condition in which moveable contact 120 
is separated from fixed contact 118. Movable contact 120 is biased by a 
spring 122 into the first circuit making condition. 
In operation, movable contact 120 is normally in the first circuit-making 
condition and power supplied on the PHASE1 line is provided to branch 
circuit BC1A via breaker 1A. Breaker 1A monitors power, or current, on the 
PHASE1 line and on branch circuit BC1A. Under normal conditions, no high 
frequency current is present on such lines. Therefore, high pass filter 
104 does not provide a signal to amplifier 108, and movable contact 120 
remains in the first circuit-making condition. 
If a high frequency current is present on the PHASE1 line or on branch 
circuit BC1A, however, then high pass filter 104 passes this high 
frequency current to amplifier 108. However, if at this time amplifier 108 
is not receiving an enabling signal on line 58 (its gating terminal) from 
arc detection unit 16, the amplifier does not supply an output signal to 
rectifier 110. Such circumstance generally indicates that the high 
frequency current in branch circuit BC1A originated at a benign high 
frequency source. However, if the high frequency current is present and, 
simultaneously, an enabling signal on line 58 is received by amplifier 
108, then an amplified high frequency signal is provided to rectifier 110, 
which converts the high frequency signal into a DC signal which is 
supplied to coil 114 of switch 112. When solenoid controlled switch 112 is 
thus energized, coil 114 produces a magnetic field which couples with the 
magnetic field of arm 116 and drives movable contact 120 from the first, 
circuit-making condition to the second, circuit-breaking condition. Under 
such circumstances, power is cut off to branch circuit BC1A. Thus, power 
is cut off when a high frequency signal is detected by breaker 1A and 
simultaneously a harmful arc is detected by arc detection unit 16 (FIG. 
2). Moveable contact 120 remains in the second, circuit-breaking condition 
until it is manually reset. 
In one embodiment, the structure and operation of all branch circuit 
breakers 14 are identical to the structure and operation of circuit 
breaker 1A described above in connection with FIG. 3. However, circuit 
breakers 2A, 2B, etc. are coupled to second enable line 60 of arc 
detection unit 16. Therefore, an arc detected in one of second branch 
circuits BC2A, BC2B, etc. does not affect operation of first branch 
circuits BC1A, BC1B, etc. Similarly, an arc detected in one of first 
branch circuits BC1A, BC1B, etc. does not affect operation of second 
branch circuits BC2A, BC2B, etc. 
The above described junction box architecture provides complete protection 
for a residence from arc type faults, including fault isolation and 
location, at a low cost compared to the cost of using sophisticated arc 
detection units in each branch circuit. 
While only certain preferred features of the invention have been 
illustrated and described, many modifications and changes will occur to 
those skilled in the art. It is, therefore, to be understood that the 
appended claims are intended to cover all such modifications and changes 
as fall within the true spirit of the invention.