The present invention relates generally to a connection structure between a watt-hour meter socket base and one or more plug-in type circuit breakers, also referred to as plug-on circuit breakers. It is known to those in the trade that the connection path must consist of an electrically conductive material. Very often insulated copper or aluminum cables are employed, requiring the use of tested and approved electrical wire connectors. These connectors require mounting fasteners, typically a bolt, spring washer, and nut. Additionally, the cable requires preparation. Namely the insulation must be carefully removed so as not to reduce the conductor cross section, and the wire must be shaped or formed so that its ends are cooperatively received by the aforementioned wire connectors.
Another known connection structure commonly employs the use of bus bars such as copper or aluminum with rectangular cross sections. As an example, a 200 A (ampere) circuit breaker connection using copper bus bar may have a cross section of 0.188 inch by 1.000 inch (0.48 cm by 2.54 cm) or an aluminum bus bar with a cross section of 0.250 inch by 1.000 inch (0.64 cm by 2.54 cm). This method requires various manufacturing operations, typically, cut to length, drilled or punched holes, and forming. Due to the rigidity of the bus bar, the forming must be very accurate to ensure alignment of the meter socket base and circuit breaker base. Furthermore, for a bus bar, an element must be added to receive the circuit breaker. The circuit breaker is typically mounted to a receiving spades or lugs 0.093 inch (2.36 mm) thick, thus requiring the use of an additional part and fasteners. Additionally, regulatory agencies require tin or silver plating be applied on areas where connections are made.
The prior art construction described above has disadvantages. First, the use of additional components acts to increase both material and labor costs. Second, the additional connections contribute to the heating of the device.
The present invention provides a power meter socket to circuit breaker connection structure for connecting load-side watt-hour meter socket terminals to a plug-in or plug-on type of circuit breaker unit. An embodiment of the connection structure generally includes an elongated, generally Z-shaped conductor member having a connection plate at a top end, an angled extension section, an elongated trunk section, and a spade section. The connection plate is planar and has a fastener receiving aperture formed through it. The connection plate may include additional features for controlling the orientation of the connector plate with respect to a socket terminal jaw. The extension and trunk sections may be formed by a central web with backwardly extending flanges for stiffening purposes. The extension section is oriented at an angle which positions the connection plate forward of the web of the trunk section. The trunk section may have an aperture formed therethrough for securing the connection structure to an insulating circuit breaker base. The spade section is positioned at a lower end of the trunk section and has a pair of laterally spaced circuit breaker receptacle receiving spades extending forward of a web of the spade section.
For a two conductor AC service, an identical pair of the connection structures are secured to the circuit breaker base in laterally spaced, parallel relation. The circuit breaker base may have slide-in retainers which engage the apertures through the trunk section and a lower edge of the spade section web. The connection plates of the structures are fastened to a pair of laterally spaced load-side meter socket jaws which receive a pair of load-side spades of a conventional type of watt-hour meter. The circuit breaker base positions the connection structures such that an adjacent pair of the two connection structures are properly spaced to receive the spaced apart receptacles of a standard type of plug-in circuit breaker.
Each of the connection structures is formed of a single blank of sheet metal having a uniform thickness. The selected thickness is the same thickness specified for spades to receive the spade receptacles of the circuit breakers, typically 0.093 inch (2.36 mm) thick. The metal employed combines high conductivity with high strength and good economy, such as aluminum, copper, or alloys thereof.
The present invention reduces the number of components required to manufacture meter sockets with provision for plug-in circuit breakers of 125 to 225 ampere ratings. One embodiment of the invention reduces part count of the connection between the meter socket base assembly to the plug-in circuit breaker by 11 unique parts and 17 total parts for the bus version or 11 unique parts and 28 total parts for the wired version. This embodiment of the invention is comprised of 3 total parts and 2 unique parts. Assembly costs are in direct proportion to the number of components used.
The present invention also reduces the number of manufacturing operations required to manufacture meter sockets with provision for plug-in circuit breakers of 125 to 225 ampere ratings. The conventional bus bars 202 (
The present invention reduces the material cost required to manufacture meter sockets with provision for plug-in circuit breakers of 125 to 225 ampere ratings. The implementations illustrated in
Various objects and advantages of this invention will become apparent from the following description taken in conjunction with the accompanying drawings wherein are set forth, by way of illustration and example, certain embodiments of this invention.
The drawings constitute a part of this specification and include exemplary embodiments of the present invention and illustrate various objects and features thereof.
As required, detailed embodiments of the present invention are disclosed herein; however, it is to be understood that the disclosed embodiments are merely exemplary of the invention, which may be embodied in various forms. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a basis for the claims and as a representative basis for teaching one skilled in the art to variously employ the present invention in virtually any appropriately detailed structure.
Referring to the drawings in more detail, the reference numeral 1 (
Referring to
The illustrated circuit breaker receiving assembly 4 includes an insulating circuit breaker assembly base 32 which is fastened or otherwise secured to the enclosure wall 14 in a position below the meter socket assembly 3. The base 32 positions a plug-in circuit breaker and conductors connected thereto at a required distance from the enclosure wall 14. The illustrated circuit breaker base 32 includes a molded body 34 having a front surface 36 (
In the embodiment illustrated in
Each of the illustrated connection members 1 is secured to the circuit breaker base 32 by aligning and engaging the trunk web opening 59 with an upper slide-in retainer 40 and a lower edge 74 of the spade section with a lower slide-in retainer 42. Such alignment also aligns one of the trunk flanges 58 with one of the vertical slots 38 in the circuit breaker base 32. The connection plate 50 of the structure 1 should then be aligned with the load-side end of one of the socket jaw bases 10. The connection plate 50 is secured to the socket jaw base 10, along with a load-side jaw 20 and a blade guide 26 by a screw 76 and nut 78 (
The relative positions of meter socket jaws 20 and 26 are prescribed by ANSI C12.7, Requirements for Watt-hour Meter Sockets, to be 2.875 inches (7.3 cm) apart. The relative positions of the circuit breaker mounting spades 80 are prescribed by industry standard at 1.00 inch (2.54 cm) apart. The thickness of the circuit breaker mounting spades 72 are also prescribed by industry standard at 0.093 inches thick. To achieve the 0.093 inch thickness at the circuit breaker mounting spade 72, the entire connection structure 1 is made from a 0.093 inch thick conductive material. Material selection is an important cost consideration. Aluminum, although only 75% as conductive as copper, is ⅙ the cost on an equal cross section basis. To achieve a 200 A capability at 0.093 thick, the invention must be considerably wider than the copper bus bars 202.
The formed trunk side flanges 58 are provided to maintain proper clearances from opposite electrical phases and strengthen the invention in the plane perpendicular to the flanges. The large surface area of the connection structures 1 in comparison to the bus bars 202 employed in the assembly 200 (
Although the circuit breaker receiving assembly 4 has been shown employing two connection structures 1, it is foreseen that other numbers of structures 1 could be employed, for example, in a multi-phase electrical power service. It is also foreseen that an assembly 4 could be configured such that the circuit breaker receiving spades 72 are positioned in vertically spaced relation instead of horizontal. Additionally, it is foreseen that the connection structures 1 could be configured to provide multiple sets of spaced apart spades 72 to receive multiple plug-in circuit breaker units.
It is to be understood that while certain forms of the present invention have been illustrated and described herein, it is not to be limited to the specific forms or arrangement of parts described and shown.
This application claims priority under 35 U.S.C. 119(e) and 37 C.F.R. 1.78(a)(4) based upon copending U.S. Provisional Application Ser. No. 60/965,412 for NEW INTERCONNECTION METHOD BETWEEN WATT-HOUR METER SOCKET BASE AND PLUG-IN CIRCUIT BREAKER, filed Aug. 20, 2007, which is incorporated herein by reference.
Number | Date | Country | |
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60965412 | Aug 2007 | US |