U.S. patent application number 15/089650 was filed with the patent office on 2017-10-05 for breaker motorized secondary connector - field installable kit.
This patent application is currently assigned to Eaton Corporation. The applicant listed for this patent is Eaton Corporation. Invention is credited to Koustubh Ashtekar, James Jeffrey Benke, Douglas Michael Brandt, Ronald Dale Hartzel, Brad Robert Leccia, Daniel Evan Palmieri, David Andrew Schreiber, Hongbin Wang, Cory Robert Weeks.
Application Number | 20170287654 15/089650 |
Document ID | / |
Family ID | 59886097 |
Filed Date | 2017-10-05 |
United States Patent
Application |
20170287654 |
Kind Code |
A1 |
Ashtekar; Koustubh ; et
al. |
October 5, 2017 |
BREAKER MOTORIZED SECONDARY CONNECTOR - FIELD INSTALLABLE KIT
Abstract
A circuit breaker installation including a frame assembly and a
circuit breaker assembly is provided. The frame assembly includes a
conductor assembly and the frame assembly defines an enclosed
space. The frame assembly conductor assembly includes a primary
contact assembly and a movable secondary contact assembly. The
circuit breaker assembly is movably disposed in the frame assembly
enclosed space. The contact assemblies are configurable electrical
components. The configurable electrical components move between a
connect configuration, a test configuration, and, a disconnect
configuration.
Inventors: |
Ashtekar; Koustubh;
(Coraopolis, PA) ; Palmieri; Daniel Evan;
(Coraopolis, PA) ; Benke; James Jeffrey;
(Pittsburgh, PA) ; Leccia; Brad Robert;
(Coraopolis, PA) ; Hartzel; Ronald Dale; (Butler,
PA) ; Brandt; Douglas Michael; (Wampum, PA) ;
Schreiber; David Andrew; (Pittsburgh, PA) ; Wang;
Hongbin; (Novi, MI) ; Weeks; Cory Robert;
(Atlanta, GA) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
Eaton Corporation |
Cleveland |
OH |
US |
|
|
Assignee: |
Eaton Corporation
Cleveland
OH
|
Family ID: |
59886097 |
Appl. No.: |
15/089650 |
Filed: |
April 4, 2016 |
Current U.S.
Class: |
1/1 |
Current CPC
Class: |
H01H 9/22 20130101; H01H
71/02 20130101; H02B 11/133 20130101; H02B 11/10 20130101 |
International
Class: |
H01H 9/22 20060101
H01H009/22; H01H 71/02 20060101 H01H071/02 |
Claims
1. A frame assembly secondary contact assembly for a circuit
breaker installation, said circuit breaker installation including a
frame assembly and a circuit breaker assembly, said frame assembly
including a conductor assembly, said frame assembly defining an
enclosed space, said frame assembly enclosed space including a
front side and a rear side, said frame assembly conductor assembly
including a primary contact assembly, said frame assembly primary
contact assembly including a number of primary contacts, said
circuit breaker assembly including a housing assembly and conductor
assembly, said circuit breaker assembly conductor assembly
including a number of primary contacts, a number of secondary
contacts, said circuit breaker assembly movably disposed in said
frame assembly enclosed space, wherein said circuit breaker
assembly moves between an inserted, first position and a withdrawn,
second position, said frame assembly secondary contact assembly
comprising: a case assembly; a number of secondary contacts; said
number of secondary contacts disposed in said case assembly; a
slider assembly, said slider assembly structured to be movably
coupled to said frame assembly; said case assembly fixed to said
slider assembly; a carriage assembly, said carriage assembly
structured to be coupled to said frame assembly; said case assembly
moves between a connect, first position, a test, second position,
and a disconnect, third position; wherein said case assembly moves
between a connect configuration, wherein said circuit breaker
assembly primary contacts are coupled to, and in electrical
communication with, said frame assembly primary contacts and said
circuit breaker assembly secondary contacts are coupled to, and in
electrical communication with, said frame assembly secondary
contacts, a test configuration, wherein said circuit breaker
assembly primary contacts are not coupled to, and are not in
electrical communication with, said frame assembly secondary
contacts and said circuit breaker assembly secondary contacts are
coupled to, and in electrical communication with, said frame
assembly secondary contacts, and, a disconnect configuration,
wherein said circuit breaker assembly primary contacts are not
coupled to, and are not in electrical communication with, said
frame assembly primary contacts, and, said circuit breaker assembly
secondary contacts are not coupled to, and are not in electrical
communication with, said frame assembly secondary contacts; and
wherein, when said case assembly is moved into said test
configuration, said circuit breaker assembly remains in said second
position, and, said case assembly moves from one of said first
position or said third position to said second position.
2. The frame assembly secondary contact assembly of claim 1
wherein: when said case assembly is in said connect configuration,
said case assembly is adjacent to said frame assembly enclosed
space rear side; when said case assembly is in said test
configuration, said case assembly is adjacent said frame assembly
enclosed space front side; and when said case assembly is in said
disconnect configuration, said case assembly is between said first
position and said second position.
3. The frame assembly secondary contact assembly of claim 1
wherein: when said case assembly is in said connect configuration,
said case assembly is in said first position; when said case
assembly is in said test configuration, said case assembly is in
said second position; and when said case assembly is in said
disconnect configuration, said case assembly is in said third
position.
4. The frame assembly secondary contact assembly of claim 3
wherein: when said case assembly is in said connect configuration,
said circuit breaker assembly is in said first position; when said
case assembly is in said test configuration, said circuit breaker
assembly is in said second position; and when said case assembly is
in said disconnect configuration, said circuit breaker assembly is
in said second position.
5. The frame assembly secondary contact assembly of claim 1
wherein: said carriage assembly including a first actuator and a
second actuator; said carriage assembly first actuator movable
between a test position and a disconnect position; said carriage
assembly second actuator movable between a disengaged position and
an engaged position; said frame assembly and said circuit breaker
assembly include a number of interlock assemblies; said number of
interlock assemblies includes a first interlock assembly and a
second interlock assembly; said first interlock assembly structured
to maintain said carriage assembly first actuator in said test
position when said configurable electrical components are in said
connect configuration and to allow said carriage assembly first
actuator to move between said test position and said disconnect
position when said configurable electrical components are in one
of, or in between, said test configuration or said disconnect
configuration; and said second interlock assembly structured to
maintain said carriage assembly second actuator in said disengaged
position when said configurable electrical components are in one of
said test configuration and said disconnect configuration, and to
allow said carriage assembly second actuator to move into said
engaged position as said configurable electrical components are
moving between said test configuration and said disconnect
configuration.
6. The frame assembly secondary contact assembly of claim 5
wherein: said carriage assembly includes a front plate, a motor, a
threaded rod, and a rear plate; said carriage assembly front plate
defining a number of latching surfaces; said carriage assembly
motor including a rotating output shaft; said carriage assembly
motor coupled to said carriage assembly rear plate; said carriage
assembly motor output shaft operatively coupled to said carriage
assembly threaded rod; said carriage assembly threaded rod
extending between, and rotatably coupled to, said carriage assembly
front plate and said carriage assembly rear plate; carriage
assembly first actuator including a body having a number of
interlock member mountings and a number of biasing device
mountings; carriage assembly first actuator body defining a
threaded passage; said carriage assembly threaded rod operatively
coupled to said carriage assembly first actuator body threaded
passage; said first interlock assembly including a number of
interlock members and a number of biasing devices; each first
interlock assembly interlock member including a body having a slot,
a biasing device mounting, a latching portion, and a number of
interlock member operator portions; each first interlock assembly
interlock member body movably coupled to said carriage assembly
first actuator body and structured to move between a latched, first
position and an unlatched second position; each first interlock
assembly interlock biasing device extending between, and coupled to
both, one said carriage assembly first actuator body biasing device
mounting and one said first interlock assembly interlock member
body biasing device mounting, wherein each said first interlock
assembly interlock biasing device biases said each first interlock
assembly interlock member body to the latched, first position; and
said carriage assembly first actuator body movable between a test
position and a disconnect position.
7. The frame assembly secondary contact assembly of claim 6
wherein: said slider assembly fixed to said frame assembly
secondary contact assembly number of secondary contacts; said
slider assembly movably coupled to said circuit breaker housing
assembly; said slider assembly including a number of interlock
member operators; each interlock member operator structured to
operatively engage a first interlock assembly interlock member body
interlock member operator portion; wherein, when said circuit
breaker assembly is in said first position, each interlock member
operator does not operatively engage a first interlock assembly
interlock member interlock member body operator portion; and
wherein, when said circuit breaker assembly is in said second
position, each number of interlock member operator operatively
engages a first interlock assembly interlock member interlock
member body operator portion.
8. The frame assembly secondary contact assembly of claim 7
wherein: said slider assembly includes a housing; said slider
assembly housing includes a drive cavity; said second interlock
assembly includes a number of interlock members, a number of
biasing devices, and a number of elongated rails; each second
interlock assembly rail defining a multi-level path; each second
interlock assembly rail multi-level path including a number of
release portions and a drive portion; each second interlock
assembly rail extending between, and coupled to, said carriage
assembly front plate and said carriage assembly rear plate; each
said second interlock assembly interlock member including a body
with a slot, a biasing device mounting, a rail follower, and a
drive member; wherein said second interlock assembly interlock
member drive member is said carriage assembly second actuator; each
said second interlock assembly interlock member body movably
coupled to said carriage assembly first actuator body and
structured to move between a release, first position and a drive,
second position; each said second interlock assembly interlock
member body rail follower movably coupled to an associated second
interlock assembly rail; each second interlock assembly interlock
biasing device extending between, and coupled to both, one said
carriage assembly first actuator body biasing device mounting and
one said second interlock assembly interlock member body biasing
device mounting, wherein each said second interlock assembly
interlock biasing device biases said each second interlock assembly
interlock member body to the drive, second position; wherein, when
said configurable electrical components are in one of said test
configuration and said disconnect configuration, each said second
interlock assembly interlock member body rail follower is disposed
on one said second interlock assembly rail release portion wherein
each said second interlock assembly interlock member drive member
is spaced from said frame assembly secondary contact assembly
housing, and, as said configurable electrical components are moving
between said test configuration and said disconnect configuration,
each said second interlock assembly interlock member body rail
follower is disposed on said second interlock assembly rail drive
portion, wherein said each said second interlock assembly interlock
member drive member is disposed in said frame assembly secondary
contact assembly housing drive cavity; and wherein said second
interlock assembly rail drive portion operatively engages said
frame assembly secondary contact assembly housing.
9. The frame assembly secondary contact assembly of claim 1
wherein: said carriage assembly includes a sensor assembly, a front
plate and a rear plate; said sensor assembly including a number of
sensors; each said sensor structured to detect a proximate object;
said number of sensors include a disconnect limit switch and a test
limit switch; said disconnect limit switch coupled to said carriage
assembly rear plate, wherein said disconnect limit switch is
structured to detect a proximate object when said configurable
electrical components are in said disconnect configuration; and
said test limit switch coupled to said carriage assembly front
plate, wherein said test limit switch is structured to detect a
proximate object when said configurable electrical components are
in said test configuration.
10. The frame assembly secondary contact assembly of claim 1
wherein said carriage assembly is an added assembly.
11. A circuit breaker installation comprising: a frame assembly
including a conductor assembly, said frame assembly defining an
enclosed space; said frame assembly enclosed space including a
front side and a rear side; said frame assembly conductor assembly
including a primary contact assembly and a movable secondary
contact assembly; said frame assembly primary contact assembly
including a number of primary contacts; said frame assembly
secondary contact assembly including a number of secondary
contacts; a circuit breaker assembly including a housing assembly
and conductor assembly; said circuit breaker assembly conductor
assembly including a primary contact assembly and a secondary
contact assembly; said circuit breaker assembly primary contact
assembly including a number of primary contacts; said circuit
breaker assembly secondary contact assembly including a number of
secondary contacts; wherein said frame assembly conductor assembly
and said circuit breaker assembly conductor assembly are
configurable electrical components; said circuit breaker assembly
movably disposed in said frame assembly enclosed space; wherein
said circuit breaker assembly moves between an inserted, first
position and a withdrawn, second position; wherein said frame
assembly secondary contact assembly moves between an inserted,
first position, a test, second position, and a disconnect, third
position; wherein said configurable electrical components move
between a connect configuration, wherein said circuit breaker
assembly primary contacts are coupled to, and in electrical
communication with, said frame assembly primary contacts and said
circuit breaker assembly secondary contacts are coupled to, and in
electrical communication with, said frame assembly secondary
contacts, a test configuration, wherein said circuit breaker
assembly primary contacts are not coupled to, and are not in
electrical communication with, said frame assembly secondary
contacts and said circuit breaker assembly secondary contacts are
coupled to, and in electrical communication with, said frame
assembly secondary contacts, and, a disconnect configuration,
wherein said circuit breaker assembly primary contacts are not
coupled to, and are not in electrical communication with, said
frame assembly primary contacts, and, said circuit breaker assembly
secondary contacts are not coupled to, and are not in electrical
communication with, said frame assembly secondary contacts; and
wherein, when said configurable electrical components are moved
into said test configuration, said circuit breaker assembly remains
in said second position, and, said frame assembly secondary contact
assembly moves from one of said first position or said third
position to said second position.
12. The circuit breaker installation of claim 11 wherein: when said
configurable electrical components are in said connect
configuration, said frame assembly secondary contact assembly is
adjacent to said frame assembly enclosed space rear side; when said
configurable electrical components are in said test configuration,
said frame assembly secondary contact assembly is adjacent said
frame assembly enclosed space front side; and when said
configurable electrical components are in said disconnect
configuration, said frame assembly secondary contact assembly is
between said first position and said second position.
13. The circuit breaker installation of claim 11 wherein: when said
configurable electrical components are in said connect
configuration, said frame assembly secondary contact assembly is in
said first position; when said configurable electrical components
are in said test configuration, said frame assembly secondary
contact assembly is in said second position; and when said
configurable electrical components are in said disconnect
configuration, said frame assembly secondary contact assembly is in
said third position.
14. The circuit breaker installation of claim 13 wherein: when said
configurable electrical components are in said connect
configuration, said circuit breaker assembly is in said first
position; when said configurable electrical components are in said
test configuration, said circuit breaker assembly is in said second
position; and when said configurable electrical components are in
said disconnect configuration, said circuit breaker assembly is in
said second position.
15. The circuit breaker installation of claim 11 wherein: said
frame assembly includes a carriage assembly; said carriage assembly
including a first actuator and a second actuator; said carriage
assembly first actuator movable between a test position and a
disconnect position; said carriage assembly second actuator movable
between a disengaged position and an engaged position; said frame
assembly and said circuit breaker assembly include a number of
interlock assemblies; said number of interlock assemblies includes
a first interlock assembly and a second interlock assembly; said
first interlock assembly structured to maintain said carriage
assembly first actuator in said test position when said
configurable electrical components are in said connect
configuration and to allow said carriage assembly first actuator to
move between said test position and said disconnect position when
said configurable electrical components are in one of, or in
between, said test configuration or said disconnect configuration;
and said second interlock assembly structured to maintain said
carriage assembly second actuator in said disengaged position when
said configurable electrical components are in one of said test
configuration and said disconnect configuration, and to allow said
carriage assembly second actuator to move into said engaged
position as said configurable electrical components are moving
between said test configuration and said disconnect
configuration.
16. The circuit breaker installation of claim 15 wherein: said
carriage assembly includes a front plate, a motor, a threaded rod,
and a rear plate; said carriage assembly front plate defining a
number of latching surfaces; said carriage assembly motor including
a rotating output shaft; said carriage assembly motor coupled to
said carriage assembly rear plate; said carriage assembly motor
output shaft operatively coupled to said carriage assembly threaded
rod; said carriage assembly threaded rod extending between, and
rotatably coupled to, said carriage assembly front plate and said
carriage assembly rear plate; carriage assembly first actuator
including a body having a number of interlock member mountings and
a number of biasing device mountings; carriage assembly first
actuator body defining a threaded passage; said carriage assembly
threaded rod operatively coupled to said carriage assembly first
actuator body threaded passage; said first interlock assembly
including a number of interlock members and a number of biasing
devices; each first interlock assembly interlock member including a
body having a slot, a biasing device mounting, a latching portion,
and a number of interlock member operator portions; each first
interlock assembly interlock member body movably coupled to said
carriage assembly first actuator body and structured to move
between a latched, first position and an unlatched second position;
each first interlock assembly interlock biasing device extending
between, and coupled to both, one said carriage assembly first
actuator body biasing device mounting and one said first interlock
assembly interlock member body biasing device mounting, wherein
each said first interlock assembly interlock biasing device biases
said each first interlock assembly interlock member body to the
latched, first position; and said carriage assembly first actuator
body movable between a test position and said disconnect
position.
17. The circuit breaker installation of claim 16 wherein: said
frame assembly secondary contact assembly includes a slider
assembly; said slider assembly fixed to said frame assembly
secondary contact assembly number of secondary contacts; said
slider assembly movably coupled to said circuit breaker housing
assembly; said slider assembly including a number of interlock
member operators; each interlock member operator structured to
operatively engage a first interlock assembly interlock member body
interlock member operator portion; wherein, when said circuit
breaker assembly is in said first position, each number of
interlock member operator does not operatively engage a first
interlock assembly interlock member interlock member body operator
portion; and wherein, when said circuit breaker assembly is in said
second position, each number of interlock member operator
operatively engages a first interlock assembly interlock member
interlock member body operator portion.
18. The circuit breaker installation of claim 17 wherein: said
slider assembly includes a housing; said slider assembly housing
includes a drive cavity; said second interlock assembly includes a
number of interlock members, a number of biasing devices, and a
number of elongated rails; each second interlock assembly rail
defining a multi-level path; each second interlock assembly rail
multi-level path including a number of release portions and a drive
portion; each second interlock assembly rail extending between, and
coupled to, said carriage assembly front plate and said carriage
assembly rear plate; each said second interlock assembly interlock
member including a body with a slot, a biasing device mounting, a
rail follower, and a drive member; wherein said second interlock
assembly interlock member drive member is said carriage assembly
second actuator; each said second interlock assembly interlock
member body movably coupled to said carriage assembly first
actuator body and structured to move between a release, first
position and a drive, second position; each said second interlock
assembly interlock member body rail follower movably coupled to an
associated second interlock assembly rail; each second interlock
assembly interlock biasing device extending between, and coupled to
both, one said carriage assembly first actuator body biasing device
mounting and one said second interlock assembly interlock member
body biasing device mounting, wherein each said second interlock
assembly interlock biasing device biases said each second interlock
assembly interlock member body to the drive, second position;
wherein, when said configurable electrical components are in one of
said test configuration and said disconnect configuration, each
said second interlock assembly interlock member body rail follower
is disposed on one said second interlock assembly rail release
portion wherein each said second interlock assembly interlock
member drive member is spaced from said frame assembly secondary
contact assembly housing, and, as said configurable electrical
components are moving between said test configuration and said
disconnect configuration, each said second interlock assembly
interlock member body rail follower is disposed on said second
interlock assembly rail drive portion, wherein said each said
second interlock assembly interlock member drive member is disposed
in said frame assembly secondary contact assembly housing drive
cavity; and wherein said second interlock assembly rail drive
portion operatively engages said frame assembly secondary contact
assembly housing.
19. The circuit breaker installation of claim 11 wherein: said
carriage assembly includes a sensor assembly, a front plate and a
rear plate; said sensor assembly including a number of sensors;
each said sensor structured to detect a proximate object; said
number of sensors include a disconnect limit switch and a test
limit switch; said disconnect limit switch coupled to said carriage
assembly rear plate, wherein said disconnect limit switch is
structured to detect a proximate object when said configurable
electrical components are in said disconnect configuration; and
said test limit switch coupled to said carriage assembly front
plate, wherein said test limit switch is structured to detect a
proximate object when said configurable electrical components are
in said test configuration.
20. The circuit breaker installation of claim 11 wherein said
carriage assembly is an added assembly.
21. A method of utilizing a circuit breaker installation including
a number of configurable electrical components comprising:
providing a frame assembly including a conductor assembly, said
frame assembly defining an enclosed space, said frame assembly
enclosed space including a front side and a rear side, said frame
assembly conductor assembly including a primary contact assembly
and a movable secondary contact assembly, said frame assembly
primary contact assembly including a number of primary contacts,
said frame assembly secondary contact assembly including a number
of secondary contacts; providing a circuit breaker assembly
including a housing assembly and conductor assembly, said circuit
breaker assembly conductor assembly including a primary contact
assembly and a secondary contact assembly, said circuit breaker
assembly primary contact assembly including a number of primary
contacts, said circuit breaker assembly secondary contact assembly
including a number of secondary contacts, said circuit breaker
further including a number of fixed contacts and a number of
movable contacts, each movable contact movable between an open,
first position, wherein each movable contact is not coupled to and
is not in electrical communication with, an associated fixed
contact, and a closed, second position, wherein each movable
contact is coupled to and is in electrical communication with, an
associated fixed contact; wherein said frame assembly conductor
assembly and said circuit breaker assembly conductor assembly are
configurable electrical components; wherein said circuit breaker
assembly movably disposed in said frame assembly enclosed space;
wherein said circuit breaker assembly moves between an inserted,
first position and a withdrawn, second position; wherein said frame
assembly secondary contact assembly moves between an inserted,
first position, a test, second position, and a disconnect, third
position; wherein said configurable electrical components move
between a connect configuration, wherein said circuit breaker
assembly primary contacts are coupled to, and in electrical
communication with, said frame assembly primary contacts and said
circuit breaker assembly secondary contacts are coupled to, and in
electrical communication with, said frame assembly secondary
contacts, a test configuration, wherein said circuit breaker
assembly primary contacts are not coupled to, and are not in
electrical communication with, said frame assembly secondary
contacts and said circuit breaker assembly secondary contacts are
coupled to, and in electrical communication with, said frame
assembly secondary contacts, and, a disconnect configuration,
wherein said circuit breaker assembly primary contacts are not
coupled to, and are not in electrical communication with, said
frame assembly primary contacts, and, said circuit breaker assembly
secondary contacts are not coupled to, and are not in electrical
communication with, said frame assembly secondary contacts;
providing a control assembly structured to control said
configurable electrical components; and utilizing said control
assembly to configure said configurable electrical components in a
selected configuration.
22. The method of claim 21 wherein providing a control assembly
include providing a remote control assembly.
23. The method of claim 21 wherein utilizing said control assembly
to configure said configurable electrical components in a selected
configuration includes moving said configurable electrical
components into said test configuration by moving said frame
assembly secondary contact assembly from one of said first position
or said third position to said second position while said circuit
breaker assembly remains in said second position.
24. The method of claim 21 wherein utilizing said control assembly
to configure said configurable electrical components in a selected
configuration includes moving said frame assembly secondary contact
assembly into said third position that is disposed between said
first position and said second position.
25. The method of claim 21 wherein utilizing said control assembly
to configure said configurable electrical components in a selected
configuration includes moving the circuit breaker assembly movable
contacts between the open, first position and the closed, second
position.
Description
BACKGROUND OF THE INVENTION
Field of the Invention
[0001] The disclosed and claimed concept relates to a circuit
breaker installation and, more specifically, to a circuit breaker
installation including a circuit breaker assembly having a primary
contact assembly and a secondary contact assembly, and a frame
assembly having a primary contact assembly and a secondary contact
assembly wherein the secondary contact assemblies move between a
connect, test, and disconnect configuration.
Background Information
[0002] A circuit breaker installation includes a frame assembly, or
housing assembly, that defines an enclosed space. The frame
assembly also includes a contact assembly with a primary contact
assembly and a secondary contact assembly. The frame assembly
primary contact assembly is in electrical communication with a line
and a load, as is known. A circuit breaker installation also
includes a circuit breaker assembly which also has a contact
assembly with a primary contact assembly and a secondary contact
assembly. In use, the circuit breaker assembly is disposed in the
frame assembly enclosed space with the circuit breaker assembly
primary contact assembly in electrical communication with the frame
assembly primary contact assembly. The circuit breaker assembly, in
an exemplary embodiment, is moved from the frame assembly enclosed
space; in this configuration, the circuit breaker assembly primary
contact assembly is not in electrical communication with the frame
assembly primary contact assembly.
[0003] The circuit breaker installation also includes additional
assemblies such as, but not limited to, testing and monitoring
devices. Testing and monitoring devices include, but are not
limited to, input and output devices, sensors and actuators. The
input and output devices are located outside the frame assembly
and, in an exemplary embodiment, are electronically coupled to
other, remote input and output devices. The sensors and actuators,
as well as other devices, are located inside the frame assembly as
well as inside the circuit breaker assembly. The input and output
devices are coupled to, and in electronic communication with, the
sensors and actuators via the frame assembly secondary contact
assembly and the circuit breaker secondary contact assembly. That
is, the circuit breaker secondary contact assembly is in
electromechanical communication between control signals, various
sensors, actuators and other devices within the frame assembly and
the circuit breaker assembly. The frame assembly secondary contact
assembly is a system to allow the input and output devices to
communicate. When the frame assembly secondary contact assembly and
the circuit breaker secondary contact assembly are coupled this
allows for there to be electromechanical communication. Input is
provided to the actuators and data from the sensors is provided to
the output devices.
[0004] The additional control and monitoring devices are, in an
exemplary embodiment, used when the circuit breaker assembly is not
in service. Thus, the frame assembly secondary contact assembly and
the circuit breaker secondary contact assembly are structured to be
in contact with each other even after the circuit breaker assembly
primary contact assembly and the frame assembly primary contact
assembly are separated. That is, the frame assembly primary contact
assembly is disposed at the rear of the frame assembly enclosed
space. The circuit breaker assembly primary contact assembly is
disposed on the rear side of the circuit breaker assembly. The
frame assembly secondary contact assembly and the circuit breaker
secondary contact assembly were arranged in a similar manner, i.e.,
with the frame assembly secondary contact assembly facing (exposed
to) the front side of the frame assembly enclosed space, and the
circuit breaker secondary contact assembly facing the rear side of
the frame assembly enclosed space. The frame assembly secondary
contact assembly and the circuit breaker secondary contact assembly
were, however, movable along with the circuit breaker assembly.
[0005] In this configuration, and when the circuit breaker assembly
was disposed substantially within the frame assembly enclosed
space, the circuit breaker assembly primary contact assembly is in
electrical communication with the frame assembly primary contact
assembly. When the circuit breaker assembly was removed from the
frame assembly enclosed space, the circuit breaker assembly primary
contact assembly separated from, and was no longer in electrical
communication with, the frame assembly primary contact assembly.
Because the frame assembly secondary contact assembly and the
circuit breaker secondary contact assembly moved along with the
circuit breaker assembly, the secondary contact assemblies remained
in electronic communication while the circuit breaker assembly
moved. When the circuit breaker assembly was substantially removed
from the frame assembly enclosed space, the frame assembly
secondary contact assembly and the circuit breaker secondary
contact assembly also separated. Thus, the circuit breaker assembly
was to have three configurations: (1) a "connect" configuration,
wherein the circuit breaker assembly primary contact assembly is
coupled to, and in electrical communication with, the frame
assembly primary contact assembly and the circuit breaker assembly
secondary contact assembly is coupled to, and in electrical
communication with, the frame assembly secondary contact assembly,
(2) a "test" configuration, wherein the circuit breaker assembly
primary contact assembly is not coupled to, and is not in
electrical communication with, the frame assembly secondary
contacts and the circuit breaker assembly secondary contacts are
coupled to, and in electrical communication with, the frame
assembly secondary contact assembly, and, (3) a "disconnect"
configuration, wherein the circuit breaker assembly primary contact
assembly is not coupled to, and is not in electrical communication
with, the frame assembly primary contact assembly, and, the circuit
breaker assembly secondary contact assembly is not coupled to, and
is not in electrical communication with, the frame assembly
secondary contact assembly. Further, there is an "isolation"
configuration wherein the circuit breaker assembly is completely
removed from the frame assembly.
[0006] The disadvantage to this configuration is that an arc may
form when the circuit breaker assembly primary contact assembly is
separated from the frame assembly primary contact assembly, and/or
when the circuit breaker assembly primary contact assembly is near
to the frame assembly primary contact assembly. Because the known
circuit breaker assemblies move through the configurations in this
order connect to test, test to disconnect, during removal (and in
the opposite order during installation), the circuit breaker
assembly primary contact assembly and the frame assembly primary
contact assembly are close enough to each other to generate an arc
when in the "test" configuration.
[0007] There is, therefore, a need for a circuit breaker
installation that avoids this disadvantage. There is a further need
for an added assembly that overcomes this disadvantage in
preexisting circuit breaker installations.
SUMMARY OF THE INVENTION
[0008] These needs, and others, are met by at least one embodiment
of the disclosed and claimed concept which provides a frame
assembly secondary contact assembly including a case assembly, a
number of secondary contacts, the number of secondary contacts
disposed in the case assembly, a slider assembly, the slider
assembly structured to be coupled to the circuit breaker assembly,
and a carriage assembly. The case assembly is fixed to the slider
assembly. The carriage assembly is structured to be coupled to the
frame assembly. The case assembly moves between an inserted, first
position, a medial position, and a second position. The case
assembly moves between a connect configuration, wherein the circuit
breaker assembly primary contacts are coupled to, and in electrical
communication with, the frame assembly primary contacts and the
circuit breaker assembly secondary contacts are coupled to, and in
electrical communication with, the frame assembly secondary
contacts, a test configuration, wherein the circuit breaker
assembly primary contacts are not coupled to, and are not in
electrical communication with, the frame assembly secondary
contacts and the circuit breaker assembly secondary contacts are
coupled to, and in electrical communication with, the frame
assembly secondary contacts, and, a disconnect configuration,
wherein the circuit breaker assembly primary contacts are not
coupled to, and are not in electrical communication with, the frame
assembly primary contacts, and, the circuit breaker assembly
secondary contacts are not coupled to, and are not in electrical
communication with, the frame assembly secondary contacts. When the
case assembly is moved into the test configuration, the circuit
breaker assembly remains in the second position, and, the case
assembly moves from one of the first position or the second
position to the medial position.
[0009] In another embodiment, the disclosed and claimed concept
provides a circuit breaker installation including a frame assembly
and a circuit breaker assembly. The frame assembly includes a
conductor assembly and the frame assembly defines an enclosed
space. The frame assembly enclosed space includes a front side and
a rear side. The frame assembly conductor assembly includes a
primary contact assembly and a movable secondary contact assembly.
The frame assembly primary contact assembly includes a number of
primary contacts. The frame assembly secondary contact assembly
includes a number of secondary contacts. The circuit breaker
assembly includes a housing assembly and conductor assembly. The
circuit breaker assembly conductor assembly includes a number of
primary contacts and a number of secondary contacts. The frame
assembly conductor assembly and the circuit breaker assembly
conductor assembly are configurable electrical components. The
circuit breaker assembly is movably disposed in the frame assembly
enclosed space. The circuit breaker assembly moves between an
inserted, first position and a withdrawn, second position. The
frame assembly secondary contact assembly moves between an
inserted, first position, a medial position, and a second position.
The configurable electrical components move between a connect
configuration, wherein the circuit breaker assembly primary
contacts are coupled to, and in electrical communication with, the
frame assembly primary contacts and the circuit breaker assembly
secondary contacts are coupled to, and in electrical communication
with, the frame assembly secondary contacts, a test configuration,
wherein the circuit breaker assembly primary contacts are not
coupled to, and are not in electrical communication with, the frame
assembly secondary contacts and the circuit breaker assembly
secondary contacts are coupled to, and in electrical communication
with, the frame assembly secondary contacts, and, a disconnect
configuration, wherein the circuit breaker assembly primary
contacts are not coupled to, and are not in electrical
communication with, the frame assembly primary contacts, and, the
circuit breaker assembly secondary contacts are not coupled to, and
are not in electrical communication with, the frame assembly
secondary contacts. When the configurable electrical components are
moved into the test configuration, the circuit breaker assembly
remains in the second position, and, the frame assembly secondary
contact assembly moves from one of the first position or the second
position to the medial position.
[0010] The configuration and positioning of the elements and
assemblies described below solve the stated problems. That is, for
example, the position of the secondary contact assembly is closer
to the front of the frame assembly enclosed space when in the test
configuration and closer to the rear of the frame assembly enclosed
space when in the disconnect configuration solve the stated
problems.
BRIEF DESCRIPTION OF THE DRAWINGS
[0011] A full understanding of the invention can be gained from the
following description of the preferred embodiments when read in
conjunction with the accompanying drawings in which:
[0012] FIG. 1 is an isometric view of a circuit breaker
installation with configurable electrical components in a connect
configuration.
[0013] FIG. 2 is an isometric view of a circuit breaker
installation with configurable electrical components in a test
configuration.
[0014] FIG. 3 is an isometric view of a circuit breaker
installation with configurable electrical components in a
disconnect configuration.
[0015] FIG. 4 is an isometric view of a slider assembly and
carriage assembly in a connect configuration.
[0016] FIG. 5 is an isometric view of a slider assembly and
carriage assembly in a test configuration.
[0017] FIG. 6 is an isometric view of a slider assembly and
carriage assembly in a disconnect configuration.
[0018] FIG. 7 is a side view of a slider assembly and carriage
assembly in a connect configuration.
[0019] FIG. 8 is a detail view of the carriage assembly of FIG.
7.
[0020] FIG. 9 is a side view of a slider assembly and carriage
assembly in a test configuration.
[0021] FIG. 10 is a side view of a slider assembly and carriage
assembly moving between a test configuration and a disconnect
configuration.
[0022] FIG. 11 is a side view of a slider assembly and carriage
assembly in a disconnect configuration.
[0023] FIG. 12 is an exploded isometric view of a carriage
assembly.
[0024] FIG. 13 is an isometric view of a carriage assembly.
[0025] FIG. 14 is a front view of a carriage assembly.
[0026] FIG. 15 is a bottom view of a carriage assembly.
[0027] FIG. 16 is an exploded isometric view of a carriage assembly
first actuator with interlock assemblies.
[0028] FIG. 17 is an isometric view of a carriage assembly first
actuator with interlock assemblies.
[0029] FIG. 18 is a side view of a carriage assembly first actuator
with interlock assemblies.
[0030] FIG. 19 is a front view of a carriage assembly first
actuator with interlock assemblies.
[0031] FIG. 20 is an isometric view of a portion of a slider
assembly.
[0032] FIG. 21 is a schematic view of another embodiment.
[0033] FIG. 22 is a flowchart of the disclosed method.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0034] It will be appreciated that the specific elements
illustrated in the figures herein and described in the following
specification are simply exemplary embodiments of the disclosed
concept, which are provided as non-limiting examples solely for the
purpose of illustration. Therefore, specific dimensions,
orientations, assembly, number of components used, embodiment
configurations and other physical characteristics related to the
embodiments disclosed herein are not to be considered limiting on
the scope of the disclosed concept.
[0035] Directional phrases used herein, such as, for example,
clockwise, counterclockwise, left, right, top, bottom, upwards,
downwards and derivatives thereof, relate to the orientation of the
elements shown in the drawings and are not limiting upon the claims
unless expressly recited therein.
[0036] As used herein, the singular form of "a," "an," and "the"
include plural references unless the context clearly dictates
otherwise.
[0037] As used herein, the statement that two or more parts or
components are "coupled" shall mean that the parts are joined or
operate together either directly or indirectly, i.e., through one
or more intermediate parts or components, so long as a link occurs.
As used herein, "directly coupled" means that two elements are
directly in contact with each other. It is noted that moving parts,
such as but not limited to circuit breaker contacts, are "directly
coupled" when in one position, e.g., the closed, second position,
but are not "directly coupled" when in the open, first position. As
used herein, "fixedly coupled" or "fixed" means that two components
are coupled so as to move as one while maintaining a constant
orientation relative to each other. Accordingly, when two elements
are coupled, all portions of those elements are coupled. A
description, however, of a specific portion of a first element
being coupled to a second element, e.g., an axle first end being
coupled to a first wheel, means that the specific portion of the
first element is disposed closer to the second element than the
other portions thereof.
[0038] As used herein, a "coupling assembly" includes two or more
couplings or coupling components. The components of a coupling or
coupling assembly are generally not part of the same element or
other component. As such, the components of a "coupling assembly"
may not be described at the same time in the following
description.
[0039] As used herein, a "coupling" or "coupling component(s)" is
one or more component(s) of a coupling assembly. That is, a
coupling assembly includes at least two components that are
structured to be coupled together. It is understood that the
components of a coupling assembly are compatible with each other.
For example, in a coupling assembly, if one coupling component is a
snap socket, the other coupling component is a snap plug, or, if
one coupling component is a bolt, then the other coupling component
is a nut.
[0040] As used herein, a "removable coupling assembly" means a
coupling that is structured to be separated with minimal effort. As
a non-limiting example, a threaded coupling is structured to be
separated by rotating the elements relative to each other. A
coupling such as a weld, although separable with effort, is not a
"removable coupling assembly." Similarly, to be "removably coupled"
means to be coupled by a "removable coupling assembly." That is,
when a number of elements are "removably coupled" it means that the
elements can be separated with minimal effort such as, but not
limited to, decoupling a threaded coupling.
[0041] As used herein, a "removable component" is an element or
assembly that is coupled to other elements by a "removable coupling
assembly." For example, a threaded element that is threadably
coupled to another element is a "removable component." As used
herein, being a "removable component" is an inherent feature of any
element or assembly that is coupled to other elements by a
"removable coupling assembly."
[0042] As used herein, "correspond" indicates that two structural
components are sized and shaped to be similar to each other and are
structured to be coupled with a minimum amount of friction. Thus,
an opening which "corresponds" to a member is sized slightly larger
than the member so that the member is structured to pass through
the opening with a minimum amount of friction. This definition is
modified if the two components are said to fit "snugly" together or
"snuggly correspond." In that situation, the difference between the
size of the components is even smaller whereby the amount of
friction increases. If the element defining the opening and/or the
component inserted into the opening is made from a deformable or
compressible material, the opening in an exemplary embodiment, is
slightly smaller than the component being inserted into the
opening. This definition is further modified if the two components
are said to "substantially correspond." "Substantially correspond"
means that the size of the opening is very close to the size of the
element inserted therein; that is, not so close as to cause
substantial friction, as with a snug fit, but with more contact and
friction than a "corresponding fit," i.e., a "slightly larger"
fit.
[0043] As used herein, the statement that two or more parts or
components "engage" one another shall mean that the elements exert
a force or bias against one another either directly or through one
or more intermediate elements or components. Further, as used
herein with regard to moving parts, a moving part "engages" another
element during the motion from one position to another and/or
"engages" another element once in the described position. Thus, it
is understood that the statements, "when element A moves to element
A first position, element A engages element B," and "when element A
is in element A first position, element A engages element B" are
equivalent statements and mean that element A either engages
element B while moving to element A first position and/or element A
either engages element B while in element A first position.
[0044] As used herein, "operatively engage" means "engage and
move." That is, "operatively engage" when used in relation to a
first component that is structured to move a movable or rotatable
second component means that the first component applies a force
sufficient to cause the second component to move. For example, a
screwdriver is structured to be placed into contact with a screw.
When no force is applied to the screwdriver, the screwdriver is
merely "coupled" to the screw. If an axial force is applied to the
screwdriver, the screwdriver is pressed against the screw and
"engages" the screw. However, when a rotational force is applied to
the screwdriver, the screwdriver "operatively engages" the screw
and causes the screw to rotate.
[0045] As used herein, the word "unitary" means a component that is
created as a single piece or unit. That is, a component that
includes pieces that are created separately and then coupled
together as a unit is not a "unitary" component or body.
[0046] As used herein, the term "number" shall mean one or an
integer greater than one (i.e., a plurality).
[0047] As used herein, "associated" means that the elements are
part of the same assembly and/or operate together, or, act
upon/with each other in some manner. For example, an automobile has
four tires and four hub caps. While all the elements are coupled as
part of the automobile, it is understood that each hubcap is
"associated" with a specific tire.
[0048] As used herein, and in the phrase "[x] moves between a first
position and a second position corresponding to [y] first and
second positions," wherein "[x]" and "[y]" are elements or
assemblies, the word "correspond" means that when element [x] is in
the first position, element [y] is in the first position, and, when
element [x] is in the second position, element [y] is in the second
position. It is noted that "correspond" relates to the final
positions and does not mean the elements must move at the same rate
or simultaneously.
[0049] That is, for example, a hubcap and the wheel to which it is
attached rotate in a corresponding manner. Conversely, a spring
biased latched member and a latch release move at different rates.
That is, as an example, a latch release moves between a first
position, wherein the latched member is not released, and a second
position, wherein the latched member is released. The spring-biased
latched member moves between a first latched position and a second
released position. The latch release, in this example, is moved
slowly between positions and, until the release is in the second
position, the latched member remains in the first position. But, as
soon as the latch release reaches the second position, the latched
member is released and quickly moves to the second position. Thus,
as stated above, "corresponding" positions mean that the elements
are in the identified first positions at the same time, and, in the
identified second positions at the same time.
[0050] As used herein, in the phrase "[x] moves between its first
position and second position," or, "[y] is structured to move [x]
between its first position and second position," "[x]" is the name
of an element or assembly. Further, when [x] is an element or
assembly that moves between a number of positions, the pronoun
"its" means "[x]," i.e., the named element or assembly that
precedes the pronoun "its."
[0051] As used herein, "in electronic communication" is used in
reference to communicating a signal via an electromagnetic wave or
signal. "In electronic communication" includes both hardline and
wireless forms of communication; thus, for example, a "data
transfer" or "communication method" via a component "in electronic
communication" with another component means that data is
transferred from one computer to another computer (or from one
processing assembly to another processing assembly) by physical
connections such as USB, Ethernet connections or remotely such as
NFC, blue tooth etc. and should not be limited to any specific
device.
[0052] As used herein, "in electric communication" means that a
current passes, or can pass, between the identified elements. Being
"in electric communication" is further dependent upon an element's
position or configuration. For example, in a circuit breaker, a
movable contact is "in electric communication" with the fixed
contact when the contacts are in a closed position. The same
movable contact is not "in electric communication" with the fixed
contact when the contacts are in the open position.
[0053] As used herein, a "path of travel" or "path" includes the
space an element moves through when in motion.
[0054] As used herein, an "added assembly" is an assembly or
element that is not included with the initial installation of a
circuit breaker assembly or frame assembly. That is, an "added
assembly" is an assembly or element that is added onto, or
retrofitted, into a circuit breaker assembly or frame assembly. It
is noted that, as used herein, an assembly or element that is
"capable" of being added onto, or retrofitted, into a circuit
breaker assembly or frame assembly is not an "added assembly." That
is, to establish an assembly or element as an "added assembly" it
must be shown, or otherwise proven, that the assembly or element
was not part of an original installation and has been added onto,
or retrofitted, into a circuit breaker assembly or frame
assembly.
[0055] As used herein, any indication of a "position" or a
"configuration" relates to the element identified immediately
before the reference to the "position" or "configuration." For
example, in the phrase "moving the frame assembly secondary contact
assembly 34 from one of the first position or the third position to
the second position while the circuit breaker assembly 14 remains
in the second position," the reference the "first position" and the
initial reference to the "second position" relate to the "frame
assembly secondary contact assembly 34" which is the element
identified immediately before the reference to the "position" or
"configuration." Further, the second reference to a "second
position" relates to the "circuit breaker assembly 14" which is the
element identified immediately before the reference to the
"position" or "configuration."
[0056] As used herein, "structured to [verb]" means that the
identified element or assembly has a structure that is shaped,
sized, disposed, coupled and/or configured to perform the
identified verb. For example, a member that is "structured to move"
is movably coupled to another element and includes elements that
cause the member to move or the member is otherwise configured to
move in response to other elements or assemblies. As such, as used
herein, "structured to [verb]" recites structure and not function.
Further, as used herein, "structured to [verb]" means that the
identified element or assembly is intended to, and is designed to,
perform the identified verb. Thus, an element that is merely
capable of performing the identified verb but which is not intended
to, and is not designed to, perform the identified verb is not
"structured to [verb]."
[0057] A circuit breaker installation 10 is shown in FIGS. 1-3. The
circuit breaker installation 10 includes a frame assembly 12, a
circuit breaker assembly 14, and a racking assembly 16. The frame
assembly 12 defines an enclosed space 20. That is, the frame
assembly 12 includes a number of elongated, rigid members (not
numbered) and/or a number of sidewalls (not numbered) that define
the frame assembly enclosed space 20. The frame assembly enclosed
space 20 includes a front side 22 and a rear side 24. The frame
assembly 12, in an exemplary embodiment, includes a door (not
numbered) that is movably coupled to the frame assembly 12 at the
frame assembly enclosed space front side 22. The door is movable
between an open position, wherein the circuit breaker assembly 14
can be moved in and out of the frame assembly enclosed space 20,
and a closed position, wherein the circuit breaker assembly 14 is
substantially enclosed within the frame assembly enclosed space
20.
[0058] The frame assembly 12 also includes a conductor assembly 30.
As is known, the frame assembly conductor assembly 30 includes
conductive elements that are structured to be in electric, or
electronic, communication with other conductive elements, as
described below. The frame assembly conductor assembly 30, in an
exemplary embodiment, includes a primary contact assembly 32
(hereinafter "frame assembly primary contact assembly" 32) and a
movable secondary contact assembly 34 (hereinafter "frame assembly
secondary contact assembly" 34). The frame assembly primary contact
assembly 32 is, in an exemplary embodiment, disposed at the frame
assembly enclosed space rear side 24. As is known, the frame
assembly primary contact assembly 32 is in electrical communication
with a line and a load, neither shown. The frame assembly primary
contact assembly 32 includes a number of primary contacts 36 (which
are also be identified as "stabs" 36) and external bus members 38.
As used herein, an electrical "contact" is a terminal structured to
be placed in a number of configurations including a configuration
wherein the "contact" is in electrical communication with other
conductive elements, and a configuration wherein the "contact" is
not in electrical communication with other conductive elements. The
frame assembly primary contact assembly number of primary contacts
36 (hereinafter "frame assembly primary contacts" 36) are, in an
exemplary embodiment, structured to be in a "connect configuration"
and a "disconnect configuration," as discussed below. The frame
assembly primary contact assembly external bus members 38 are
structured to be in electrical communication with a line and a
load, neither shown.
[0059] The frame assembly secondary contact assembly 34, in an
exemplary embodiment, includes a case assembly 40 and a number of
secondary contacts 42 (FIG. 9). The frame assembly secondary
contact assembly case assembly 40, (hereinafter "case assembly" 40)
is a non-conductive enclosure structured to maintain the frame
assembly secondary contact assembly secondary contacts 42
(hereinafter "frame assembly secondary contacts" 42) in a generally
fixed relationship relative to each other. The case assembly 40, in
an exemplary embodiment, is a common serial bus connector 41, or
similar construct. The case assembly 40, i.e., the frame assembly
secondary contact assembly 34, is movably coupled to the frame
assembly frame members or sidewall members and, as discussed in
detail below, is coupled, directly coupled, or fixed to a slider
assembly 120. The case assembly 40, i.e., the frame assembly
secondary contact assembly 34, is structured to, and does, move
between a "connect, first position," a "test, second position," and
a "disconnect, third position," as discussed below.
[0060] As is known, the frame assembly secondary contact assembly
34 (and the case assembly 40) is coupled to, and is in electrical
and/or electronic communication with, a flexible conductor 26, such
as, but not limited to wire(s), cable(s), or a ribbon cable. The
flexible conductor 26 is further coupled to, and is in electrical
and/or electronic communication with, the circuit breaker assembly
14, and the racking assembly 16. That is, the flexible conductor is
further coupled to, and is in electrical and/or electronic
communication with sensors and control devices (not shown) on the
circuit breaker assembly 14. Similarly, the flexible conductor is
further coupled to, and is in electrical and/or electronic
communication with sensors and control devices on the racking
assembly 16. The flexible conductor is further coupled to, and is
in electrical and/or electronic communication with, a control
and/or monitoring assembly 28 (hereinafter "control assembly" 28).
As is known, the control assembly 28 is structured to actuate the
racking assembly 16, and therefore structured to move, the circuit
breaker assembly 14 as well as other configurable electrical
components 100, discussed below. As used herein, the control
assembly 28 and the flexible conductor 26 are associated with, and
can be considered part of, any of the frame assembly 12, circuit
breaker assembly 14, the frame assembly secondary contact assembly
34, slider assembly 120 and/or the carriage assembly 150, discussed
below. The control assembly 28 is structured to control the
configurable electrical components 100 in a manner similar to the
remote control assembly 428, discussed below.
[0061] The circuit breaker assembly 14 includes a housing assembly
50 and conductor assembly 60. In an exemplary embodiment, the
circuit breaker assembly housing assembly 50 encloses the conductor
assembly 60, which includes a number of fixed contacts 54, a number
of movable contacts 56, an operating mechanism 58 (elements shown
schematically), and a trip unit (not shown) as is generally known.
As is known, the operating mechanism 58 is structured to move the
movable contacts 56 between an open, first position, wherein each
movable contact 56 is not coupled to and is not in electrical
communication with, an associated fixed contact 54, and a closed,
second position, wherein each movable contact 56 is coupled to and
is in electrical communication with, an associated fixed contact
54.
[0062] The circuit breaker assembly conductor assembly 60 further
includes a primary contact assembly 62. The circuit breaker
assembly conductor assembly primary contact assembly 62
(hereinafter "circuit breaker assembly primary contact assembly"
62) includes a number of primary contacts 64. The circuit breaker
assembly primary contact assembly number of primary contacts 64
(commonly known as "finger cluster assembly," hereinafter "circuit
breaker assembly primary contacts" 64) are coupled, directly
coupled, or fixed to the circuit breaker assembly housing assembly
50. In an exemplary embodiment, the circuit breaker assembly
primary contacts 64 are fixed to the circuit breaker assembly
housing assembly 50 and move therewith.
[0063] The circuit breaker assembly conductor assembly 60 also
includes a secondary contact assembly 66. The circuit breaker
assembly conductor assembly secondary contact assembly 66
(hereinafter "circuit breaker assembly secondary contact assembly"
66) includes a number of secondary contacts 68 (FIG. 9). The
circuit breaker assembly secondary contact assembly number of
primary contacts 68 (hereinafter "circuit breaker assembly
secondary contacts" 68) are coupled, directly coupled, or fixed to
the circuit breaker assembly housing assembly 50. In an exemplary
embodiment, the circuit breaker assembly secondary contacts 68 are
fixed to the circuit breaker assembly housing assembly 50 and move
therewith. It is understood that, in an exemplary embodiment, the
circuit breaker assembly secondary contact assembly 66 maintains
the circuit breaker assembly secondary contacts 68 in a generally
fixed relationship relative to each other. For example, the circuit
breaker assembly secondary contact assembly 66 includes a rigid
housing (not numbered) such as, but not limited to a common serial
bus connector 70, or similar construct, as shown in FIGS. 5 and 6.
It is understood that the frame assembly secondary contacts 42 and
the circuit breaker assembly secondary contacts 68 are disposed in
a corresponding pattern so that the frame assembly secondary
contact assembly 34 and the circuit breaker assembly secondary
contact assembly 66 can be moved into, or separated from,
electrical and/or electronic communication with each other, as
described below.
[0064] The following discussion shall address the various positions
and "configurations" in which the circuit breaker assembly 14 and
the number of contact assemblies 32, 34, 62, 66 are disposed.
Initially, it is noted that the frame assembly conductor assembly
30 and the circuit breaker assembly conductor assembly 60 are, as
used herein, "configurable electrical components" 100. That is, as
used herein, "configurable electrical components" 100 are elements
in which the identified "configuration" depends upon the position
and status (in or not in electrical/electronic communication) of
other elements. Thus, the "configuration" of an identified
configurable electrical component is a characteristic of the
configurable electrical component even if the "configuration"
depends upon the position and status of other elements. Further, in
the following discussion, it is assumed that the circuit breaker
assembly 14 is in operation, i.e., in an inserted, first position
within the frame assembly enclosed space 20, and is being removed
and tested. Further, the conductor assembly movable contacts 56 are
also "configurable electrical components" 100 which are movable
between the open, first positions and closed, second positions
discussed above.
[0065] That is, in an exemplary embodiment, the circuit breaker
assembly 14 is movably disposed in the frame assembly enclosed
space 20. That is, the racking assembly 16 is structured to move
the circuit breaker assembly 14 between an inserted, first position
and a withdrawn, second position. These positions are also
identified as the "connect configuration" and "test configuration,"
respectively. Further, for the circuit breaker assembly 14 and the
"test configuration" is the same position as the "disconnect
configuration," as discussed below. In the first position, the
circuit breaker assembly primary contact assembly 62, i.e., the
circuit breaker assembly primary contacts 64, are coupled, or
directly coupled, and are in electrical communication with, the
frame assembly primary contact assembly 32, i.e., the frame
assembly primary contacts 36. In the second position, the circuit
breaker assembly primary contact assembly 62, i.e., the circuit
breaker assembly primary contacts 64, are spaced from, and are not
in electrical communication with, the frame assembly primary
contact assembly 32, i.e., the frame assembly primary contacts 36.
The circuit breaker assembly secondary contact assembly 66, i.e.,
the circuit breaker assembly secondary contacts 68, move with the
circuit breaker assembly housing assembly 50 and therefore move
between an inserted, first position and a withdrawn, second
position. As before, these positions are also identified as the
"connect configuration" and "test configuration," respectively, for
the circuit breaker assembly secondary contacts 68. Further, for
the circuit breaker assembly secondary contacts 68, the "test
configuration" is the same position as the "disconnect
configuration," as discussed below. The frame assembly primary
contact assembly 32, in an exemplary embodiment, does not move. As
noted above, the frame assembly secondary contact assembly 34 is
movable between a "connect, first position," a "test, second
position," and a "disconnect, third position" (also identified
hereinafter as a frame assembly secondary contact assembly 34
"first position," "second position," and "third position"). As set
forth below, the configurable electrical components 100 are each
configurable in a "connect configuration," a "test configuration,"
and a "disconnect configuration" which is also identified as a
"connect, first configuration," a "test, second configuration," and
a "disconnect, third configuration," respectively.
[0066] Generally, as noted above, when the circuit breaker assembly
14 is in the inserted, first position, the circuit breaker assembly
primary contact assembly 62, i.e., the circuit breaker assembly
primary contacts 64, are coupled, or directly coupled, and are in
electrical communication with, the frame assembly primary contact
assembly 32, i.e., the frame assembly primary contacts 36. Further,
when the circuit breaker assembly 14 is in the inserted, first
position, the frame assembly secondary contact assembly 34, i.e.,
the case assembly 40 and the frame assembly secondary contacts 42,
are coupled, or directly coupled, and are in electrical
communication with, the circuit breaker assembly secondary contact
assembly 66, i.e., the circuit breaker assembly secondary contacts
68, as shown in FIG. 4. Thus, this is the "connect configuration"
for the circuit breaker assembly 14 and the number of contact
assemblies 32, 34, 62, 66 and subcomponents. It is noted that when
the circuit breaker assembly 14 and the number of contact
assemblies 32, 34, 62, 66 are in the "connect configuration" the
frame assembly secondary contact assembly 34, i.e., the case
assembly 40, is "adjacent" to the frame assembly enclosed space
rear side 24. That is, as used herein, and in relation to the frame
assembly secondary contact assembly 34 (and the case assembly 40),
"adjacent" is a relative term meaning closer than when the frame
assembly secondary contact assembly 34 (and the case assembly 40)
is in another position(s), as describe below. Thus, when the
circuit breaker assembly 14 is in the inserted, first position, and
when the frame assembly secondary contact assembly 34 is in the
connect, first position, the configurable electrical components 100
are each in a "connect configuration."
[0067] When the circuit breaker assembly 14 is initially moved to
the withdrawn, second position, the circuit breaker assembly
primary contact assembly 62, i.e., the circuit breaker assembly
primary contacts 64, are spaced from, and are not in electrical
communication with, the frame assembly primary contact assembly 32,
i.e., the frame assembly primary contacts 36, as noted above.
Further, initially, the movable frame assembly secondary contact
assembly 34 (and the case assembly 40) move into the test, second
position, as shown in FIG. 5. When in the second position, the
movable frame assembly secondary contact assembly 34 (and the case
assembly 40) is adjacent the frame assembly enclosed space front
side 22. As before, the term "adjacent" as used herein, and in
relation to the frame assembly secondary contact assembly 34 (and
the case assembly 40), means closer than when the frame assembly
secondary contact assembly 34 (and the case assembly 40) is in
another position(s). In this position, the frame assembly secondary
contact assembly 34, i.e., the case assembly 40 and the frame
assembly secondary contacts 42, are still coupled, or directly
coupled, and are in electrical, or electronic, communication with,
the circuit breaker assembly secondary contact assembly 66, i.e.,
the circuit breaker assembly secondary contacts 68. Thus, when the
circuit breaker assembly 14 is in the withdrawn, second position,
and when the frame assembly secondary contact assembly 34 is in the
test, second position, the configurable electrical components 100
are each in a "test configuration."
[0068] The frame assembly secondary contact assembly 34 (and the
case assembly 40) then move into the disconnect, third position, as
shown in FIG. 6. That is, the frame assembly secondary contact
assembly 34 (and the case assembly 40) is moved away from the
circuit breaker assembly secondary contact assembly 66, and toward
the frame assembly enclosed space rear side 24. The circuit breaker
assembly secondary contact assembly 66 remains in the second
position with the circuit breaker assembly 14. Thus, to separate
the frame assembly secondary contact assembly 34 and the circuit
breaker assembly secondary contact assembly 66, the frame assembly
secondary contact assembly 34 moves toward the frame assembly
enclosed space rear side 24. When the frame assembly secondary
contact assembly 34 (and the case assembly 40) is moved away from
the circuit breaker assembly secondary contact assembly 66, the
frame assembly secondary contact assembly 34 and the circuit
breaker assembly secondary contact assembly 66 are separated and
are not in electric, or electronic, communication. Thus, when the
circuit breaker assembly 14 is in the withdrawn, second position,
and when the frame assembly secondary contact assembly 34 is in the
disconnect, third position, the configurable electrical components
100 are each in a "disconnect configuration." It is noted that when
the configurable electrical components 100 are each in a
"disconnect configuration," the frame assembly secondary contact
assembly 34 (and the case assembly 40) is, in an exemplary
embodiment, at a location between the first and second
positions.
[0069] That is, unlike the known art in which the both the circuit
breaker and the secondary contact assemblies move in a single
direction between a connect configuration, a test configuration,
and a disconnect configuration, in the disclosed and claimed
embodiment, the circuit breaker assembly 14 moves between two
positions, and the frame assembly secondary contact assembly 34
reverses direction between the second and third positions.
[0070] In an exemplary embodiment, the insertion of the circuit
breaker assembly 14 into the frame assembly enclosed space 20 is
generally the reverse of the removal. That is, the configurable
electrical components 100 are each in a "disconnect configuration."
The frame assembly secondary contact assembly 34 (and the case
assembly 40) is then moved into the test, second position, wherein
the configurable electrical components 100 are in the "test
configuration," as described above. Then, the circuit breaker
assembly 14, as well as the other configurable electrical
components 100 are returned to the connect configuration, as
described above. Thus, when the frame assembly secondary contact
assembly 34 (and the case assembly 40) is moved into the test
configuration, the circuit breaker assembly 14 remains in the
second position, and, the frame assembly secondary contact assembly
34 (and the case assembly 40) assembly moves from one of the first
position or the third position to the second position.
[0071] Further, and again noting that as defined herein a
"configuration" of an element is determined by the location of
other elements, it is noted that when the frame assembly secondary
contact assembly 34 (and the case assembly 40) is in said connect
configuration, the frame assembly secondary contact assembly 34
(and the case assembly 40) is adjacent to the frame assembly
enclosed space rear side 24, as shown in FIGS. 7 and 8. When the
frame assembly secondary contact assembly 34 (and the case assembly
40) is in the test configuration, the frame assembly secondary
contact assembly 34 (and the case assembly 40) is adjacent the
frame assembly enclosed space front side 22, as shown in FIG. 9.
When the frame assembly secondary contact assembly 34 (and the case
assembly 40) is in the disconnect configuration, the frame assembly
secondary contact assembly 34 (and the case assembly 40) is
disposed between the first position and the second position, as
shown in FIG. 11. Further, when the frame assembly secondary
contact assembly 34 (and the case assembly 40) is in the connect
configuration, the circuit breaker assembly 14 is in the first
position. When the frame assembly secondary contact assembly 34
(and the case assembly 40) is in the test configuration, the
circuit breaker assembly 14 is in the second position. When the
frame assembly secondary contact assembly 34 (and the case assembly
40) is in the disconnect configuration, the circuit breaker
assembly 14 is in the second position.
[0072] As shown in FIGS. 12-20, the circuit breaker installation 10
above further includes a number of interlock assemblies 240
structured to ensure selected elements are in the desired positions
when the configurable electrical components 100 move between the
identified configurations. In an exemplary embodiment, the number
of interlock assemblies 250, 270 are included in a carriage
assembly 150 that is operatively engaged by a slider assembly 120.
It is understood that, and as used herein, "interlock assemblies"
operate between a number of components and/or assemblies. Thus, as
used herein, the "interlock assemblies" comprise elements that are
described below as part of the carriage assembly 150 and the slider
assembly 120.
[0073] That is, in an exemplary embodiment, the frame assembly
secondary contact assembly 34 includes a slider assembly 120 and a
carriage assembly 150. The slider assembly 120, in an exemplary
embodiment, includes a number of tracks (rails) 122, a number of
track followers 124, an elongated support member 126, a housing 128
and a number of interlock member operators 130. The slider assembly
tracks 122 are coupled, directly coupled, or fixed to the frame
assembly 12. The slider assembly support member 126 is, in an
exemplary embodiment, a planar member having two lateral ends. That
is, the elongated slider assembly support member 126 extends
generally laterally in the frame assembly enclosed space 20. A
slider assembly track follower 124 is disposed at each lateral end
of the slider assembly support member 126. Each slider assembly
track follower 124 defines a race sized and shaped to correspond to
a slider assembly track 122. Each slider assembly track follower
124 is movably coupled to a slider assembly track 122. The frame
assembly secondary contact assembly 34 (and the case assembly 40)
is coupled, directly coupled, or fixed to the slider assembly
support member 126. The slider assembly housing 128, in an
exemplary embodiment, is a block-like body defining a drive cavity
136 (FIG. 11) and supporting the number of slider assembly
interlock member operators 130 (FIG. 4). In an exemplary
embodiment, the slider assembly interlock member operators 130 are
generally planar members 138 generally disposed in a vertical plane
and wherein the end facing the frame assembly enclosed space front
side 22 is tapered being longer at the upper side, as shown in FIG.
20.
[0074] The slider assembly 120 is assembled by coupling the slider
assembly tracks 122 to the frame assembly 12. As shown, the slider
assembly tracks 122 are fixed to a frame assembly top sidewall (not
shown for clarity). The slider assembly support member 126 is
movably coupled to the slider assembly tracks 122 by positioning
the slider assembly tracks 122 within each slider assembly track
follower 124. The slider assembly 120 is further coupled, in one
configuration, to the circuit breaker assembly 14. That is, the
frame assembly secondary contact assembly 34 (and the case assembly
40), which are coupled, directly coupled, or fixed to the slider
assembly support member 126, is disposed in the connect
configuration. That is, the frame assembly secondary contact
assembly 34 is coupled to, and is in electrical communication with,
the circuit breaker assembly secondary contact assembly 66. In this
configuration, the slider assembly 120 moves with the circuit
breaker assembly 14 between the connect position and the test
position. These are the connect, first position and the test,
second position of the slider assembly 120. Further, the slider
assembly 120 moves between the test position and the disconnect
position along with the frame assembly secondary contact assembly
34, as described above. This is the disconnect, third position of
the slider assembly 120. That is, the slider assembly 120 moves
from the connect position forwardly in the frame assembly enclosed
space 20 to the test position. The slider assembly 120 moves from
the test position rearwardly in the frame assembly enclosed space
20 to the disconnect position, as shown in FIG. 10. As with the
frame assembly secondary contact assembly 34, the installation
process is, essentially, the reverse of the removal process.
[0075] The carriage assembly 150 includes support assembly 152, a
motor 154, a threaded rod 156, a first actuator 158, a second
actuator 160 and, in an exemplary embodiment, a sensor assembly
162. The carriage assembly 150, and in an exemplary embodiment the
carriage assembly support assembly 152, is structured to be, and
is, coupled, directly coupled, or fixed to the frame assembly 12.
The carriage assembly support assembly 152, in the example shown,
includes a front plate 170, a rear plate 172, a top plate 174, and
two lateral side plates, i.e., a first lateral side plate 176 and a
second lateral side plate 178. In an exemplary embodiment, each
"plate" is a generally planar member. The carriage assembly support
assembly 152 generally defines an operating space 153 for the
carriage assembly first actuator 158 and the carriage assembly
second actuator 160.
[0076] In an exemplary embodiment, the carriage assembly support
assembly front plate 170 (hereinafter "carriage assembly front
plate" 170) and the carriage assembly support assembly rear plate
172 (hereinafter "carriage assembly rear plate" 172) are disposed
in a spaced relation. The carriage assembly front plate 170 is
disposed generally adjacent to the frame assembly enclosed space
front side 22. The carriage assembly motor 154 is coupled, directly
coupled, or fixed to the carriage assembly rear plate 172. The
carriage assembly motor 154 includes a rotating output shaft 180.
The carriage assembly motor output shaft 180 is operatively
coupled, directly coupled, or fixed to the carriage assembly
threaded rod 156. The carriage assembly motor output shaft 180 and
the carriage assembly threaded rod 156 share an axis of rotation.
The carriage assembly threaded rod 156 is rotatably coupled to, and
extends between the carriage assembly front plate 170 and the
carriage assembly rear plate 172.
[0077] Further, in an exemplary embodiment, the carriage assembly
front plate 170 defines a number of latching surfaces 179. As
shown, the carriage assembly front plate latching surfaces 179 are
disposed adjacent vertical slots 177 in the carriage assembly front
plate 170. The carriage assembly front plate latching surfaces 179
are part of the first interlock assembly 250.
[0078] In an exemplary embodiment, the carriage assembly support
assembly 152 includes a number of elongated rails 181 (which are
part of the second interlock assembly). Each carriage assembly
support assembly rail 181 (hereinafter "second interlock assembly
rail" 181) includes a generally planar body 182 which defines a
"multi-level path" 184. That is, each second interlock assembly
rail 181 defines a path over which a rail follower 280, discussed
below, travels. As shown, each rail planar body 182 is disposed in
a generally vertical plane and extends between, and is coupled,
directly coupled, or fixed to the carriage assembly front plate 170
and the carriage assembly rear plate 172.
[0079] In this orientation (as shown for example in FIG. 10), (and
with a rail follower 280 biased downwardly as described below) the
upper surface of each rail planar body 182 defines the "multi-level
path" 184. As used herein, and with each rail planar body 182 in
the orientation described above, a "multi-level path" is a path
that includes portions at different elevations. It is understood
that the "multi-level path" includes transitory portions between
specific elevations. It is understood that the rail multi-level
path 184 on different rails 181 generally correspond to each other.
In an exemplary embodiment, each rail multi-level path 184 includes
a number of release portions 186, 188 and a drive portion 190. In
the embodiment shown, the rail multi-level path release portions
186, 188 are each generally planar and are disposed at about the
same elevation. The rail multi-level path drive portion 190 is
disposed at a lower elevation. Further, the rail multi-level path
release portions 186, 188 are disposed on either side of the rail
multi-level path drive portion 190. The rail multi-level path
release portions 186, 188 and rail multi-level path drive portion
190 have a sufficient length to cause the motion of the second
interlock assembly interlock member body 274, as described
below.
[0080] Generally, the carriage assembly first actuator 158 and
carriage assembly second actuator 160 are structured to be
operatively coupled to the slider assembly 120 and move the slider
assembly 120, and therefore the frame assembly secondary contact
assembly 34, between the test, second position and the disconnect,
third position. In an exemplary embodiment, the carriage assembly
first actuator 158 is structured to travel over a path extending in
a direction between the frame assembly enclosed space front side 22
and the frame assembly enclosed space rear side 24. Further, the
carriage assembly second actuator 160 is structured to be
selectively coupled to the slider assembly 120. That is, the
carriage assembly second actuator 160 moves between a disengaged
(or release) position, wherein the carriage assembly second
actuator 160 is not operatively engaged to the slider assembly 120,
and an engaged (or drive) position, wherein the carriage assembly
second actuator 160 is operatively engaged to the slider assembly
120.
[0081] The carriage assembly first actuator 158 includes a body 200
having a number of interlock member mountings 202 and a number of
biasing device mountings 204. Further, the carriage assembly first
actuator body 200 defines a threaded passage 206 that corresponds
to the carriage assembly threaded rod 156. In an exemplary
embodiment, the carriage assembly first actuator body 200 includes
a generally planar upper surface (not shown). Further, the carriage
assembly first actuator body 200 generally corresponds to the
carriage assembly support assembly operating space 153. Thus, when
assembled, the carriage assembly first actuator body upper surface
is disposed immediately adjacent the carriage assembly support
assembly top plate 174. As described below, the carriage assembly
first actuator body 200 is operatively coupled to the carriage
assembly threaded rod 156. In this configuration, interference
between the carriage assembly first actuator body upper surface and
the carriage assembly support assembly top plate 174 prevent
rotation of the carriage assembly first actuator body 200 when
carriage assembly threaded rod 156 is rotated.
[0082] Alternately, or additionally, the carriage assembly support
assembly 152, in an exemplary embodiment, includes guide rods 155.
That is, the carriage assembly support assembly guide rods 155 are
coupled, directly coupled, or fixed to, and extend between the
carriage assembly front plate 170 and the carriage assembly rear
plate 172. The carriage assembly support assembly guide rods 155
extend generally parallel to the carriage assembly threaded rod 156
axis of rotation. In this embodiment, the carriage assembly first
actuator body 200 also includes guide rod passages 210 that
correspond to the carriage assembly support assembly guide rods
155. The carriage assembly first actuator body guide rod passages
210 extend generally parallel to the carriage assembly first
actuator body threaded passage 206.
[0083] Each carriage assembly first actuator body interlock member
mounting 202 is structured to have an interlock member 252, 272
movable coupled thereto. In an exemplary embodiment, each carriage
assembly first actuator body interlock member mounting 202 is
structured to allow an interlock member 252, 272 to move over a
generally straight path. Thus, in an exemplary embodiment, each
carriage assembly first actuator body interlock member mounting 202
includes two spaced rods 212 extending laterally from each lateral
side of the carriage assembly first actuator body 200. In this
configuration, each interlock member 252, 272 includes a slot
through which the carriage assembly first actuator body interlock
member mounting rods 212 extend, as described below. Alternatively,
each carriage assembly first actuator body interlock member
mounting 202 is an elongated lug and each interlock member 252, 272
defines a race into which each lug is disposed.
[0084] Each carriage assembly first actuator body biasing device
mounting 204 is, in an exemplary embodiment, a laterally extending
rod 220 structured to be coupled to a spring 263.
[0085] In an exemplary embodiment, the carriage assembly second
actuator(s) 160 are a number of tabs, i.e., generally protruding
planar members, that are sized and shaped to fit within the slider
assembly housing drive cavity 136. In an exemplary embodiment, the
carriage assembly second actuator(s) 160 are unitary with the
second interlock assembly interlock member 272 and are discussed in
more detail below.
[0086] In an exemplary embodiment, the number of interlock
assemblies 240 includes a first interlock assembly 250 and a second
interlock assembly 270. As used herein, an "interlock assembly" is
an element or assembly for preventing a mechanism from being set in
motion when another mechanism is in such a position that the two
operating simultaneously might produce undesirable results. As
noted above, the first interlock assembly 250 and the second
interlock assembly 270 interact with, and therefore include,
elements of the slider assembly 120 and the carriage assembly
150.
[0087] The first interlock assembly 250 is structured to
substantially ensure the carriage assembly first actuator 158 is in
the "test position," as discussed below, prior to the carriage
assembly first actuator 158 moving toward the "disconnect
position," as discussed below. Generally, the first interlock
assembly 250 latches the carriage assembly first actuator 158 to
the carriage assembly front plate 170. The first interlock assembly
250 includes a number of interlock members 252 and a number of
biasing devices 254. In an exemplary embodiment, the first
interlock assembly interlock members 252 are substantially similar
and are movably coupled to each lateral side of the carriage
assembly first actuator body 200. As the first interlock assembly
interlock members 252 are substantially similar, only one will be
described. It is understood that the other first interlock assembly
interlock member 252 is substantially similar, but is, in an
exemplary embodiment, a mirror image thereof.
[0088] The first interlock assembly interlock member 252 includes a
body 256 having a slot 258, a number of biasing device mounting
260, a latching portion 262, and a number of interlock member
operator portions 264. In an exemplary embodiment, the first
interlock assembly interlock member body 256 is a unitary body. As
shown, in an exemplary embodiment, the first interlock assembly
interlock member body 256 is movably coupled to the carriage
assembly first actuator body 200 with the carriage assembly first
actuator body interlock member mounting 202, as shown, carriage
assembly first actuator body interlock member mounting rods 212
disposed in the first interlock assembly interlock member body slot
258. In an exemplary embodiment, and when installed, the first
interlock assembly interlock member body slot 258 extends generally
vertically. In this configuration, the first interlock assembly
interlock member body 256 is movable between a latched, first
position and an unlatched second position.
[0089] That is, the first interlock assembly interlock member body
latching portion 262 includes a forwardly extending member 266 with
a latching surface 268. In an exemplary embodiment, the first
interlock assembly interlock member body latching portion forwardly
extending member 266 is generally planar and is sized and shaped to
pass through the carriage assembly front plate vertical slots 177.
The first interlock assembly interlock member body biasing device
mounting(s) 260 are laterally extending rods 261. The first
interlock assembly interlock member body interlock member operator
portion(s) 264 are, in an exemplary embodiment, planar members
generally disposed in a horizontal plane. The first interlock
assembly biasing device(s) 254 are, in an exemplary embodiment,
springs 263.
[0090] The first interlock assembly 250 operates, generally, as
follows. The carriage assembly first actuator body interlock member
mounting rods 212 are disposed in the first interlock assembly
interlock member body slot 258. In this configuration, the first
interlock assembly interlock member body 256 is movable between an
upper, latched, first position and a lower, unlatched second
position. The first interlock assembly biasing device(s) 254 are
coupled, directly coupled, or fixed to, and extend between the
carriage assembly first actuator body 200 biasing device
mounting(s) 204 and the first interlock assembly interlock member
body biasing device mounting(s) 260 and are structured to bias the
first interlock assembly interlock member body 256 to the first
position.
[0091] When the carriage assembly first actuator body 200 is in the
test position, the first interlock assembly interlock member body
latching portion 262 is disposed through the carriage assembly
front plate vertical slots 177. Further, when the first interlock
assembly interlock member body 256 is in first position, the first
interlock assembly interlock member body latching portion 262, and
in an exemplary embodiment, the first interlock assembly interlock
member body latching portion latching surface 268 is disposed
adjacent to the carriage assembly front plate latching surfaces
179. If the carriage assembly first actuator body 200 attempts to
move from the test position to the disconnect position, the first
interlock assembly interlock member body latching portion latching
surface 268 engages the carriage assembly front plate latching
surfaces 179 and prevents the carriage assembly first actuator body
200 from moving toward the disconnect position.
[0092] The first interlock assembly interlock member body 256 is
moved to the second position by the slider assembly 120. That is,
as the slider assembly 120 moves from the connect, first position
to the test, second position, the slider assembly interlock member
operators 130 operatively engage the first interlock assembly
interlock member body interlock member operator portion(s) 264
causing the first interlock assembly interlock member body 256 to
move to the second position. When first interlock assembly
interlock member body 256 is in the second position, the first
interlock assembly interlock member body latching portion 262, and
in an exemplary embodiment, the first interlock assembly interlock
member body latching portion latching surface 268 is disposed
adjacent carriage assembly front plate vertical slots 177. Thus,
when the carriage assembly first actuator 158 moves to the
disconnect position, the first interlock assembly interlock member
body latching portion 262 passes through the carriage assembly
front plate vertical slots 177.
[0093] Generally, when the carriage assembly first actuator body
200 moves from the disconnect, third position to the test, second
position, then as the slider assembly 120 moves from the test,
second position to the connect, first position, the reverse actions
are accomplished. That is, for example, as the carriage assembly
first actuator 158 moves from the disconnect, third position to the
test, second position, the first interlock assembly interlock
member body latching portion 262 passes through the carriage
assembly front plate vertical slots 177. Further, as the slider
assembly 120 moves from the test, second position to the connect,
first position, the slider assembly interlock member operators 130
disengage the first interlock assembly interlock member body
interlock member operator portion(s) 264 causing the first
interlock assembly interlock member body 256 to move to the first
position.
[0094] Thus, the first interlock assembly 250 is structured to
maintain the carriage assembly first actuator 158 in the test
position when the configurable electrical components 100 are in the
connect configuration and to allow the carriage assembly first
actuator 158 to move between the test position and the disconnect
position when the configurable electrical components 100 are in one
of, or in between, the test configuration or the disconnect
configuration.
[0095] The second interlock assembly 270 includes a number of
interlock members 272, a number of biasing devices 273, and a
number of elongated rails which are, in an exemplary embodiment,
carriage assembly support assembly rails 181 which are also
identified as a "second interlock assembly rail" 181. The second
interlock assembly interlock members 272 are substantially similar,
only one will be described. It is understood that the other second
interlock assembly interlock member 272 is substantially similar,
but is, in an exemplary embodiment, a mirror image thereof. The
second interlock assembly number of biasing devices 273 are, in an
exemplary embodiment, springs 275.
[0096] In an exemplary embodiment, the second interlock assembly
interlock member 272 includes a body 274 with a slot 276, a biasing
device mounting 278, a rail follower 280, and a drive member 282.
In an exemplary embodiment, the second interlock assembly interlock
member body 274 is a unitary body. Further, the second interlock
assembly interlock member body drive member 282 is the carriage
assembly second actuator 160. Thus, the second interlock assembly
interlock member body drive member 282 is a tab, i.e., generally
protruding planar members, that are sized and shaped to fit within
the slider assembly housing drive cavity 136. In an exemplary
embodiment, and when installed, the second interlock assembly
interlock member body slot 276 extends generally vertically. In
this configuration, the second interlock assembly interlock member
body 274 is movably coupled to said carriage assembly first
actuator body 200 and structured to move between a disengaged (or
release), first position, wherein the second interlock assembly
interlock member body drive member 282 is not operatively engaged
to the slider assembly 120, and an engaged (or drive), second
position, wherein the second interlock assembly interlock member
body drive member 282 is operatively engaged to the slider assembly
120. The second interlock assembly interlock member body biasing
device mounting(s) 278 are laterally extending rods 290. The second
interlock assembly interlock body rail follower 280 is an inverted
channel sized to correspond to the second interlock assembly rail
181.
[0097] The second interlock assembly 270 is assembled as follows.
Each second interlock assembly rail 181 is coupled to the frame
assembly 12 as described above. Each second interlock assembly
interlock member body 274 is movably coupled to an associated
second interlock assembly rail 181. A second interlock assembly
biasing device(s) 273 are coupled, directly coupled, or fixed to,
and extend between the carriage assembly first actuator body 200
biasing device mounting(s) 204 and a second interlock assembly
interlock member body biasing device mounting(s) 278 and are
structured to bias the second interlock assembly interlock member
body 274 to the second position. That is, the second interlock
assembly interlock member body 274 is generally biased
downwardly.
[0098] The second interlock assembly 270 operates as follows. When
the carriage assembly first actuator body 200 is in the test
position, the second interlock assembly interlock member body 274,
and as shown, the second interlock assembly interlock body rail
follower 280, is disposed over the forward rail multi-level path
release portion 186. As the forward rail multi-level path release
portion 186 is at a relatively higher elevation, the second
interlock assembly interlock member body 274 is in the first
position. As the carriage assembly first actuator body 200 moves
from the test position to the disconnect position, i.e., toward the
frame assembly enclosed space rear side 24, the second interlock
assembly interlock body rail follower 280 moves over a transition
portion of the rail multi-level path 184 to the rail multi-level
path drive portion 190. Due to the bias of the second interlock
assembly biasing device(s) 273, the second interlock assembly
interlock member body 274 is biased, and moves, downwardly. As the
second interlock assembly interlock member body 274 moves
downwardly, the second interlock assembly interlock member body
drive member 282 moves into the slider assembly housing drive
cavity 136. As noted above the carriage assembly first actuator
body 200 can only move between the test position and the disconnect
position when the slider assembly 120 is in the test position. It
is understood that when the slider assembly 120 is in the test
position, the slider assembly housing drive cavity 136 is disposed
generally below the second interlock assembly interlock member body
drive member 282. Further, when the second interlock assembly
interlock member body drive member 282 is in the slider assembly
housing drive cavity 136, the carriage assembly first actuator body
200 operatively engages the second interlock assembly interlock
member body 274 and causes the second interlock assembly interlock
member body 274 to move rearwardly in the frame assembly enclosed
space 20. That is, the second interlock assembly interlock member
body 274, and the second interlock assembly interlock member body
drive member 282, operatively engage the slider assembly 120
causing the slider assembly 120, and the frame assembly secondary
contact assembly 34 (and the case assembly 40), to the disconnect
position. As the carriage assembly first actuator body 200 nears
the disconnect position, the second interlock assembly interlock
body rail follower 280 moves over a transition portion to the
rearward, rail multi-level path release portion 188 of the rail
multi-level path 184 to the rail multi-level path drive portion
190. As the second interlock assembly interlock body rail follower
280 moves over rearward, rail multi-level path release portion 188,
the second interlock assembly interlock member body 274, and the
second interlock assembly interlock member body drive member 282,
no longer operatively engage the slider assembly 120 causing the
slider assembly 120 to cease moving. Generally, when the carriage
assembly first actuator body 200 moves from the disconnect, third
position to the test, second position, then as the slider assembly
120 moves from the test, second position to the connect, first
position, the reverse actions of the second interlock assembly 270
are accomplished.
[0099] Thus, the second interlock assembly 270 is structured to
maintain the carriage assembly second actuator 160 in the
disengaged position when the configurable electrical components 100
are in one of the test configuration and the disconnect
configuration, and to allow the carriage assembly second actuator
160 to move into the engaged position as the configurable
electrical components 100 are moving between the test configuration
and the disconnect configuration. Further, when the configurable
electrical components are in one of the test configuration and the
disconnect configuration, each of the second interlock assembly
interlock member body rail follower 280 is disposed on one of the
second interlock assembly rail release portion 186 wherein each the
second interlock assembly interlock member drive member 282 is
spaced from the frame assembly secondary contact assembly 34
housing, and, as the configurable electrical components are moving
between the test configuration and the disconnect configuration,
each the second interlock assembly interlock member body rail
follower 280 is disposed on the second interlock assembly rail
drive portion, wherein each the second interlock assembly interlock
member drive member 282 is disposed in the frame assembly secondary
contact assembly housing drive cavity 136.
[0100] In an exemplary embodiment, the carriage assembly sensor
assembly 162 includes a number of sensors 300 such as, but not
limited to, sensors structured to detect the proximity of another
element. For example, a sensor 300, in an exemplary embodiment,
includes an actuator disposed in the path of travel of any movable
element, such as, but not limited to any configurable electrical
component, described above. The sensors 300 are positioned so that
the sensor is actuated when a movable element is in a specific
position. For example, a sensor is, in an exemplary embodiment,
disposed adjacent the path of travel of carriage assembly first
actuator body 200 and is positioned to be actuated when the
carriage assembly first actuator body 200 is in the disconnect
position. Thus, the carriage assembly sensor assembly 162 is
structured to provide data as to the position of any movable
element, such as, but not limited to any configurable electrical
component, described above. In an exemplary embodiment, the
carriage assembly sensor assembly number of sensors 300 includes a
disconnect limit switch 302 and a test limit switch 304. The
disconnect limit switch 302 is coupled to the carriage assembly
rear plate 172, wherein the disconnect limit switch 302 is
structured to detect a proximate object when the configurable
electrical components 100 are in the disconnect configuration.
Similarly, the test limit switch 304 is coupled to the carriage
assembly front plate 170, wherein the test limit switch 304 is
structured to detect a proximate object when the configurable
electrical components 100 are in the test configuration.
[0101] Further, in an exemplary embodiment, the slider assembly 120
and the carriage assembly 150 are each an added assembly, as
defined above.
[0102] In another exemplary embodiment, shown in FIG. 21, the
control assembly 28 is a remote control assembly 428. That is, in
an exemplary embodiment, the remote control assembly 428 further
includes a programmable logic circuit assembly 430 (hereinafter
"PLC assembly" 430) including wireless input/output assemblies,
sensors, memory (none shown), as well as wiring and/or wireless
communication with the frame assembly 12, circuit breaker assembly
14, the frame assembly secondary contact assembly 34, slider
assembly 120 and/or the carriage assembly 150. The PLC assembly
430, in an exemplary embodiment, is in wireless communication with
the remote control assembly 428. The remote control assembly 428 is
in electronic communication with the racking assembly 16 and the
carriage assembly motor 154 and is structured to move the
configurable electrical components 100 to be placed in a selected
configuration. The remote control assembly 428 is also in
electronic communication with the carriage assembly sensor assembly
162 as well as other sensors.
[0103] The remote control assembly 428 also includes input elements
440 and output elements 442. In an exemplary embodiment, the input
elements 440 are buttons 444 which, when actuated cause the remote
control assembly 428 to move the circuit breaker assembly 14 and
the frame assembly secondary contact assembly 34, as well as the
slider assembly 120 and the carriage assembly 150, to the various
configurations discussed above. That is, in an exemplary
embodiment, the remote control assembly 428 includes a "connect"
input element 440A, a "test" input element 440B, and a "disconnect"
input element 440C. The remote control assembly 428 also includes
an "open" input element 440D and a "close" input element 440E which
control the configuration of the contacts within the circuit
breaker assembly 14 to open and close. When a selected input
element 400 is actuated, the remote control assembly 428 causes the
configurable electrical components 100 to be placed in the
identified configuration.
[0104] For example, if the configurable electrical components 100
are in the connect configuration, as described above, and a user
actuates the "test" input element 440B, then the remote control
assembly 428 actuates the racking assembly 16 to move the circuit
breaker assembly 14 from the inserted, first position to the
withdrawn, second position. A further actuation of the "disconnect"
input element 440C causes the carriage assembly motor 154 to
actuate and move the slider assembly 120 from the test, second
position to the disconnect, third position.
[0105] The remote control assembly output elements 442 are, in an
exemplary embodiment, lights 446 that are structured to receive the
output from the sensor assembly 162. That is, for example, a remote
control assembly output element 442 disposed adjacent the "test"
input element 440B is structured to receive output from test limit
switch 304. Thus, when the test limit switch 304 is actuated by the
configurable electrical components 100 being in the test
configuration, the remote control assembly output element 442
disposed adjacent the "test" input element 440B is illuminated.
[0106] Thus, a method of utilizing the circuit breaker installation
10 including a number of configurable electrical components 100
includes, providing 1000 a frame assembly 12 as described above,
providing 1002 a circuit breaker assembly 14, as described above,
providing 1004 a control assembly 28, and utilizing 1006 the
control assembly 28 to configure the configurable electrical
components 100 in a selected configuration, as described above.
[0107] Providing 1004 a control assembly 28 includes providing 1008
a remote control assembly 428.
[0108] Utilizing 1006 the control assembly 28 to configure the
configurable electrical components 100 in a selected configuration
further includes the following. Moving 1010 the configurable
electrical components 100 into the test configuration (described
above) by moving the frame assembly secondary contact assembly 34
from one of the first position or the third position (as described
above) to the second position (as described above) while the
circuit breaker assembly 14 remains in the second position. Moving
1012 the frame assembly secondary contact assembly 34 into the
third position that is disposed between the first position and the
second position. Moving 1016 the circuit breaker assembly movable
contacts 54 between the open, first position and the closed, second
position. While specific embodiments of the invention have been
described in detail, it will be appreciated by those skilled in the
art that various modifications and alternatives to those details
could be developed in light of the overall teachings of the
disclosure. Accordingly, the particular arrangements disclosed are
meant to be illustrative only and not limiting as to the scope of
invention which is to be given the full breadth of the claims
appended and any and all equivalents thereof.
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