Optical waveguides – With disengagable mechanical connector – Structure surrounding optical fiber-to-fiber connection
Reexamination Certificate
1998-09-04
2001-04-24
Lee, John D. (Department: 2874)
Optical waveguides
With disengagable mechanical connector
Structure surrounding optical fiber-to-fiber connection
C385S060000
Reexamination Certificate
active
06220763
ABSTRACT:
FIELD OF THE INVENTION
The invention relates generally to a device for coupling optical fibers. More particularly, the invention relates to an optical fiber buildout system having a narrow footprint that permits a greater number of optical fiber connections per unit area.
BACKGROUND OF THE INVENTION
Often times it becomes necessary to arrange a plurality of optical fiber connectors in a connection panel to facilitate multifiber connections. Typically, devices for holding connectors are mounted in the panel, but the connectors themselves are not connected to incoming or outgoing fiber paths until needed to provide service. Commonly used devices which are used to accommodate interconnections are generally referred to as couplings. One type of coupling which is mounted in a connection panel is known as a buildout system.
Coupling components of buildout systems such as buildout bases and caps can be received in the connection panels to accommodate the optical fiber connectors to be installed at a fixture time. This permits the installer to connect a first connector, which terminates an incoming or outgoing fiber path, to a buildout base and await future connection of a second connector which terminates another outgoing or incoming fiber path.
One frequently used optical fiber connector is the ST® connector, ST being a registered trademark of the AT&T Corporation. The ST connector is disclosed, for example, in U.S. Pat. No. 4,934,785, which was issued on Jun. 19, 1990, in the names of Mathis and Miller. Other popular optical fiber connectors include the SC connector and the FC connector.
One known buildout system capable of accommodating ST, SC, and FC connectors is disclosed in U.S. Pat. No. 5,274,729, which issued on Dec. 28, 1993, in the names of King et al. The King et al. system includes a plurality of buildout bases, identified in the patent as “blocks,” that are adapted for mounting to a panel through a plurality of openings provided therein. Further disclosed is a plurality of buildout caps, identified in the patent as “buildouts,” that are adapted to be removably attached to the buildout bases mounted to the connection panel. The bases are provided with front apertures that each form a keyway that is adapted to align and receive a cylindrical sleeve housing of the caps. Both the bases and caps are open-ended such that they can receive the optical fiber connectors to be coupled within the buildout. Inside the cylindrical barrel of each cap is an attenuator element which is used to attenuate the signal traveling from one fiber to the next.
Although the King et al. system described above functions adequately well, demand for increasing numbers of optical fiber connections has prompted the design of smaller optical fiber coupling systems that occupy less space. For instance, one recently developed optical fiber connector is the LC® connector, LC being a registered trademark of Lucent Technologies, Inc. This connector is disclosed, for example, in U.S. Pat. No. 5,481,634, which was issued on Jan. 2, 1996, in the names of Anderson et al. The design of the LC connector is advantageous because the connector has a smaller footprint than each of its predecessor connectors and therefore requires less panel space.
Although development of the LC connector has shown that optical fiber connectors can be successfully reduced in size, similar size reduction of buildout systems is more problematic. In particular, reducing the size of the buildout creates a number of difficulties that do not exist or that are not as significant in the larger buildout systems currently used with the ST, SC, and FC connectors. One problem is that buildout manufacture processes become much more difficult as the buildout components and the structural features of these components become smaller. For example, the molding of extremely small structural details can be difficult.
Another problem with buildout size reduction relates to buildout strength and durability. Again, if the size of the buildout is substantially decreased, the strength and durability of the buildout likewise decreases and the likelihood of buildout failure increases. For instance, the design of the cylindrical sleeve housing of the buildout cap must be such that it can flex sufficiently to permit insertion of the attenuator and attenuator retention means, but must not permanently deform to the point at which the attenuator element could dislodge or be damaged. Furthermore, despite its reduced size, the buildout must withstand a certain degree of side loading applied to the buildout caps via the fiber cables to protect the fragile optical fibers contained therein.
A further complication created by reduced size occurs in the buildout assembly process. Specifically, assembly of the buildout cap and the attenuation means can be difficult when the constituent components of the buildout system are small, especially when such assembly is conducted out in the field. Therefore, provision must be made for structural features that permit the technician to manipulate more easily the components of the system to avoid structural damage to the buildout and optical fibers and to prevent delays in servicing.
Accordingly, it can be appreciated that it would be desirable to have a buildout system that can accommodate ST, SC, and FC connectors as well as LC connectors, which has a relatively narrow footprint such that connection panel space may be optimized. Furthermore, it would be desirable to have such a buildout system that can be relatively easily manufactured and assembled. Moreover, it would be desirable to have such a buildout system which is adequately strong and durable. The present disclosure discloses one such buildout system.
SUMMARY OF THE INVENTION
The present invention relates to a buildout system generally comprising a buildout base, a buildout cap, an attenuator element, and a ferrule sleeve. The base includes a pair of opposed lateral sides that typically extend beyond the top and bottom sides of the base to form upper and lower side flanges. Extending outwardly from the upper and lower side flanges are upper and lower panel flanges. Each of the panel flanges normally is provided with a central notch defined by opposed side surfaces. Protruding from the front side of the buildout base is a plurality of gussets.
The buildout cap comprises top and bottom sides that include elongated latch tabs that extend outwardly therefrom. Typically, each latch tab has an arcuate, relatively wide base portion that is adapted for receipt between the lateral flanges of the base, and a relatively narrow upper portion that is adapted for receipt by the central notches of the base panel flanges. Normally formed at the juncture of the lateral side with the top and bottom sides of the cap are recesses that are adapted to receive the gussets of the base.
The front side of the cap supports a sleeve housing which is adapted to contain a ferrule sleeve that is used to align the ferrules of two optical fiber connectors within the buildout. The sleeve housing extends both outwardly and inwardly from the front side of the cap and has a substantially cylindrical passage that extends from a first opening formed at the front end of the sleeve housing to a second opening formed at the rear end of the sleeve housing. The front and rear ends of the sleeve housing passage are provided with inner flanges. Normally the flange at the rear end of the sleeve housing is formed as a continuous inner flanges that retain the ferrule sleeve in place. Formed at the tip of the sleeve housing is a top notch which joins an attenuator element travel slot that extends through the front side of the cap. Positioned opposite the top notch is a bottom notch also formed at the tip of the sleeve housing.
The attenuator element is adapted for insertion into a ferrule sleeve which, as identified above, is adapted for insertion into the cap sleeve housing. The ferrule sleeve has a continuous longitudinal slot that coincides with the attenuator element travel slot of the cap when the sleeve is disposed wit
Connelly-Cushwa Michelle R.
Lee John D.
Lucent Technologies - Inc.
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