ONE AXIS SHUTTER WITH A PIN-BASED BUS SYSTEM FOR MINIATURE CIRCUIT BREAKER LOAD CENTERS
Apparatus for substantially eliminating exposure to live parts in a load center includes a bus assembly with male-terminal stabs which are capped with nonconductive material. A nonconductive structure covers the bus assembly and allows only the stabs to pass into the interior of circuit breaker compartments. A shutter assembly in each circuit breaker compartment has a nonconductive shutter plate that moves only in the Z axis to provide access to the stabs when a circuit breaker is inserted with a Z axis motion. Inserting the circuit breaker in the load center causes a shutter plate latch to open and depress the shutter. When the circuit breaker is removed from the load center, the shutter plate is biased upward and latched in a position over the stabs. No live touch points are available in the load center.
The present disclosure relates to methods and systems for inserting and removing a circuit breaker from an electrical panel or panelboard, and more particularly to a method and apparatus for reducing the chances of exposure to live parts in the panelboard.
BACKGROUND OF THE INVENTIONAn electrical panel or panelboard, has a main bus and individual connection points on the bus that are connectable to electrical devices, such as circuit breakers for branch conductors and any other electrical devices designed to be installed for a branch circuit. Because the circuit breakers, sometimes referred to herein simply as “breakers” for convenience, and other branch electrical devices are typically mounted directly to the panelboard, an operator and/or tools may come in contact with exposed conductors in the panelboard when installing or removing the circuit breakers from the panelboard. Thus, it is recommended that power be shut off to the panelboard as a precaution when electrical devices are being installed or removed. However, it may be considered desirable in some cases to keep the panelboard energized to prevent an electrical hazard as a consequence of deenergization, or operators may intentionally keep the power on in the interest of saving time. Moreover, shutting off power to the panelboard can be a major inconvenience, especially for data centers, hospitals, and other critical applications that require a high availability power source.
Thus, a need exists for an improved way to safely insert and remove a circuit breaker or other switching equipment from an electrical panel as part of a larger scheme for installing and removing branch circuit devices without deenergizing the electrical panel. Measures to prevent unintentional contact with live, i.e. energized, conductors are often known as “finger safe” provisions. Work on energized equipment will be known herein as “live work”. Particular panelboards, oftentimes called load centers, are front-accessible, wall-mounted panelboards, and typically for low voltage light, heat or power circuit applications, which have miniature circuit breakers to define and protect each branch circuit. Due to their size, design, and economic constraints, load center-type panel boards can present unique challenges for the above considerations.
SUMMARY OF THE DISCLOSED EMBODIMENTSThe embodiments disclosed herein are directed to methods and systems for reducing or eliminating the possibility of exposure to live parts in a panelboard, and particularly in the load center variety of panelboard, and safely installing and removing a circuit breaker or other branch electrical devices from the energized panelboard. While the illustrated embodiments are explained with load centers in mind, and the terms “load center” and “panelboard” may sometimes be used interchangeably herein, the present invention is not necessarily limited to the miniature circuit breaker load center environment.
The disclosed embodiments provide a shutter assembly for the panelboard that automatically closes off access to the conductors in the panelboard until a circuit breaker is inserted in the panelboard. A shutter assembly is attached in the circuit breaker mounting compartments, sometimes referred to herein as “wells,” of the panelboard and serves as one part of a protective barrier for the busses of the panelboard. The circuit breaker is designed so that inserting it in the complementary panelboard in a Z-axis motion unlocks and depresses a shutter plate of the shutter assembly in a Z-axis motion and allows the circuit breaker to access the conductors in the panelboard, which also extend in the Z-axis. When the circuit breaker is removed from the panelboard, the shutter plate rises, locks and again closes off access to the conductors. Such a shutter assembly helps operators to safely insert and remove a circuit breaker or other electrical device from the panelboard while also minimizing the potential for exposure to live parts in the panelboard.
In some implementations, the shutter assembly comprises one moving part which is a perforate shutter plate with biasing towards the raised, or protective position. One or more springs at the sides of the shutter plate comprise a latching mechanism holding the shutter plate in the raised position in the absence of a circuit breaker interacting therewith. Thus the shutter assembly is robust and economical. The bus system of the panelboard is laid out to have power delivery and neutral return terminals, i.e. stabs, extended in the Z axis so that the stabs pass closely through the perforations of the shutter plate when it is depressed by an insertion of the breaker. The bus system of the load center beneath the stabs is covered with a nonconductive layer such as the bottom of a circuit breaker well structure. Each stab preferably sits beneath the top level of the shutter plate and is also capped with a nonconductive material to further prevent access to electrically live touch points. The line and neutral terminals of the complementary circuit breaker are female receptacles in the bottom of the breaker which cover and electrically connect to the bus stabs upon insertion of the breaker.
Each branch circuit breaker slot of the load center is a compartment for a circuit breaker, desirably being a well-like structure with sides that extend in the Z axis to substantially cover the depth of the breaker when inserted to further minimize access to live conductors. The load side power and neutral connections for a branch circuit are prewired into the breaker interior before insertion of the breaker into the compartment. These load side connections extend from a side panel of the breaker through a slot in the breaker compartment leading to a wire gutter at the side of the load center. The wire gutter may be separately covered. The shutter plate will have the necessary length and width to safely cover the portion of the circuit breaker compartment conveying power and may include a mechanism that allows the shutter assembly to be firmly retained in the breaker compartment of the panelboard. The breakers are preferably equipped with positive retention interlocks providing a hold down mechanism and an interlock which will not allow the breaker to be inserted to, or removed from, the compartment in the ON position. Such interlocks were illustrated previously in Applicant's U.S. patent application Ser. No. 14/449,881 [CRC-0298].
Inserting the circuit breaker in the panelboard forces the shutter plate to slide from the raised, or protective, position into an lowered, or unprotected, position where the stabs extend through openings, i.e. throughholes, in the shutter plate aligned therewith, thereby allowing the female terminals of the circuit breaker to contact, i.e. electrically connect to, the male conductor stabs in the panelboard.
In some implementations, the circuit breaker may have inclined planes on portions of an outer casing of the circuit breaker, for example, on the side walls thereof. As the circuit breaker is inserted in the panelboard, the inclined planes act as a keying mechanism to line up with latches holding the shutter plate in the protective raised position, until the flat sides of the breaker engage with and release the latches allowing the shutter plate to be moved into the lowered unprotected position. When the circuit breaker is removed from the panelboard, the shutter plate is forced upward by a biasing coil spring on the bottom side thereof and the latches, which are separate flat spring mechanisms, move back into the well to latch the shutter plate in the protective position.
In one aspect, the disclosed embodiments are directed to a breaker compartment in a panelboard, and a shutter assembly in the breaker compartment, the shutter assembly disposed over the live conductor contacts and movable in one axis by a circuit breaker insertion in the same axis between a closed position in which the shutter assembly blocks access to the conductors of the panelboard and an open position in which the shutter assembly allows access to the conductors in the panelboard. Inserting a circuit breaker in the panelboard automatically puts the shutter assembly in the open position and removing the circuit breaker from the panelboard automatically puts the shutter assembly in the closed position.
In another aspect, the disclosed embodiments are directed to an electrical panelboard having a bus layout with pin-shaped stabs. Laid over the pin-shaped stabs is a circuit breaker compartment structure in the form of an open-faced box, with the bottom surface of the box, or an interstitial insulation layer, or both, covering all the bus structure but the stabs. The circuit breaker compartment structure provides individual compartments for the breakers and allows the stabs to protrude into the compartments; with each compartment having a shutter assembly including a shutter plate with throughholes for the stabs, a bias spring urging the shutter plate to the closed position, and preferably a latch for holding the shutter plate to the raised protective position wherein access to the stabs is closed off
In another aspect, the disclosed embodiments are directed to a panel board assembly, including a power bus in a first plane with vertical stabs extending 90-degrees from the power bus in a first axis; a neutral bus in the first plane with vertical stabs extending 90-degrees from the neutral bus in the first axis; the stabs of each of the power bus and the neutral bus being arranged in a respective line; the stabs having a free end being distal from the busses, the free ends having caps of nonconductive material and extending through a nonconductive layer; circuit breaker compartments for receiving circuit breakers inserted along the first axis; the circuit breaker compartments overlaying the nonconductive layer and having the stabs protruding therein; a shutter plate in each of the circuit breaker compartments, each shutter plate having a throughhole for receiving a stab of the power bus and a throughhole for receiving a stab of the neutral bus; and the shutter plate having a raised position overlaying all pin-shaped stabs in a circuit breaker compartment and having a lowered position allowing the stabs of the circuit breaker compartment to protrude therethrough.
The foregoing and other advantages of the disclosed embodiments will become apparent upon reading the following detailed description and upon reference to the exemplary explanatory drawings offered to illustrate the invention according to one or more embodiments disclosed herein, wherein:
As an initial matter, it will be appreciated that the development of an actual, real commercial application incorporating aspects of the disclosed embodiments will require many implementation specific decisions to achieve the developer's ultimate goal for the commercial embodiment. Such implementation specific decisions may include, and likely are not limited to, compliance with system related, business related, government related and other constraints, which may vary by specific implementation, location and from time to time. While a developer's efforts might be complex and time consuming in an absolute sense, such efforts would nevertheless be a routine undertaking for those of skill in this art having the benefit of this disclosure.
It should also be understood that the embodiments disclosed and taught herein are susceptible to numerous and various modifications and alternative forms. Thus, the use of a singular term, such as, but not limited to, “a” and the like, is not intended as limiting of the number of items. Similarly, any relational terms, such as, but not limited to, “top,” “bottom,” “left,” “right,” “upper,” “lower,” “down,” “up,” “side,” and the like, used in the written description are for clarity in specific reference to the drawings and are not intended to limit the scope of the invention.
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While particular aspects, implementations, and applications of the present disclosure have been illustrated and described, it is to be understood that the present disclosure is not limited to the precise construction and compositions disclosed herein and that various modifications, changes, and variations may be apparent from the foregoing descriptions without departing from the scope of the disclosed embodiments as defined in the appended claims.
Claims
1. A panel board assembly, including
- a power bus in a first plane with vertical stabs extending 90-degrees from the power bus in a first axis;
- a neutral bus in the first plane with vertical stabs extending 90-degrees from the neutral bus in the first axis;
- the stabs of each of the power bus and the neutral bus being arranged in a respective line;
- the stabs having a free end being distal from the busses, the free ends having caps of nonconductive material;
- circuit breaker compartments for receiving circuit breakers inserted along the first axis; the circuit breaker compartments having the stabs protruding therein;
- a shutter plate in each of the circuit breaker compartments, each shutter plate being nonconductive and having a throughhole for receiving a stab of the power bus and a throughhole for receiving a stab of the neutral bus; and
- the shutter plate having a raised position overlaying all stabs in its circuit breaker compartment and having a lowered position allowing the stabs to protrude through the shutter plate.
2. The panel board assembly of claim 1, wherein the stabs are pin-shaped.
3. The panel board assembly of claim 1, further comprising: a layer of nonconductive material covering the busses and allowing the stabs to protrude therethrough.
4. The panel board assembly of claim 3, wherein the layer of nonconductive material is a nonconductive plate with throughholes for the stabs.
5. The panel board assembly of claim 4, wherein the nonconductive plate is a wall of a one-piece unitary assembly of nonconductive material having the circuit breaker compartments formed therein.
6. The panel board assembly of claim 1, further comprising: the shutter plate being part of a shutter assembly having a biasing spring for urging the shutter plate to the raised position.
7. The panel board assembly of claim 6 further having a latch for retaining the shutter plate in the raised position.
8. The panel board assembly of claim 7, wherein the latch includes a U-shaped flat spring with tabs on the arms of the U to engage the shutter plate.
9. The panel board assembly of claim 8, wherein the arms of the U have a first position extending the tabs into contact with the shutter plate and a second position upon contact with a complementary-shaped circuit breaker wherein the tabs are forced towards side walls of circuit breaker compartment, thereby releasing the latch.
10. The panel board assembly of claim 1, further comprising: the circuit breaker compartments each being a well whose sides extend in the Z axis to substantially cover the depth of the breaker when inserted.
11. The panel board assembly of claim 5, further comprising: a wiring gutter in the one-piece unitary assembly.
12. The panel board assembly of claim 11, further comprising: a slot in the circuit breaker compartment on that side of the circuit breaker compartment leading to the wiring gutter.
13. The panel board assembly of claim 1, wherein the panel board is a load center.
14. The panel board assembly of claim 13, wherein the circuit breaker compartments are sized for miniature circuit breakers.
Type: Application
Filed: Jul 17, 2015
Publication Date: Jan 19, 2017
Inventor: Chad R. MITTELSTADT (Cedar Rapids, IA)
Application Number: 14/802,483