Patent application number | Description | Published |
20090323701 | ROUTING ENGINE FOR TELECOMMUNICATIONS NETWORK - A system for automated installation of a communication line using an optimal route between a source location and a destination location is disclosed. The system includes a routing engine providing an automated design process for rendering the optimal route. The routing engine utilizes a routing algorithm to select the optimal route from a graph of capacity links defining a plurality of possible routes between the source and destination locations. If, at any time during the design process, the optimal route or capacity links defining the optimal route are detected as unavailable for any reason, the routing engine re-initiates the design process and thereafter selects a new optimal route based upon a new capacity graph built without the previously unavailable capacity link. Once designed, the available optimal route is provided to a command and control engine, which, in turn, manages the installation of the communication line using the optimal route. The command and control engine manages the process for assigning the optimal route in the provisioning system. | 12-31-2009 |
20090323702 | ROUTING ENGINE FOR TELECOMMUNICATIONS NETWORK - A system for automated installation of a communication line using an optimal route between a source location and a destination location is disclosed. The system includes a routing engine providing an automated design process for rendering the optimal route. The routing engine utilizes a routing algorithm to select the optimal route from a graph of capacity links defining a plurality of possible routes between the source and destination locations. If, at any time during the design process, the optimal route or capacity links defining the optimal route are detected as unavailable for any reason, the routing engine re-initiates the design process and thereafter selects a new optimal route based upon a new capacity graph built without the previously unavailable capacity link. Once designed, the available optimal route is provided to a command and control engine, which, in turn, manages the installation of the communication line using the optimal route. The command and control engine manages the process for assigning the optimal route in the provisioning system. | 12-31-2009 |
20100020695 | ROUTING ENGINE FOR TELECOMMUNICATIONS NETWORK - A system for automated installation of a communication line using an optimal route between a source location and a destination location is disclosed. The system includes a routing engine providing an automated design process for rendering the optimal route. The routing engine utilizes a routing algorithm to select the optimal route from a graph of capacity links defining a plurality of possible routes between the source and destination locations. If, at any time during the design process, the optimal route or capacity links defining the optimal route are detected as unavailable for any reason, the routing engine re-initiates the design process and thereafter selects a new optimal route based upon a new capacity graph built without the previously unavailable capacity link. Once designed, the available optimal route is provided to a command and control engine, which, in turn, manages the installation of the communication line using the optimal route. The command and control engine manages the process for assigning the optimal route in the provisioning system. | 01-28-2010 |
Patent application number | Description | Published |
20080233785 | Electrical connector assemblies and joint assemblies and methods for using the same - An electrical joint assembly for connecting a plurality of conductors includes a busbar hub and a plurality of limiter modules. The busbar hub includes an electrically conductive busbar body and a plurality of conductor legs extending from the busbar body. The limiter modules each include a fuse element. Each of the limiter modules is connected to a respective one of the conductor legs and is connectable to a respective conductor to provide a fuse controlled connection between the respective conductor leg and the respective conductor. Each of the limiter modules is independently removable from the respective one of the conductor legs. | 09-25-2008 |
20100124454 | SEALANT-FILLED ENCLOSURES AND METHODS FOR ENVIRONMENTALLY PROTECTING A CONNECTION - A sealant-filled enclosure for environmentally sealing a connection includes a first cover member and a second cover member. The first cover member defines a first cavity having a first bottom. The second cover member is pivotally connected to the first cover member for movement between an open position and a closed position. The second cover member defines a second cavity having a second bottom. A first sealant is positioned in the first cavity and extends up to a first level relative to the first bottom without a connection disposed in the first cavity. A second sealant is positioned in the second cavity and extends up to a second level relative to the second bottom without a connection disposed in the second cavity. The first and second levels together exceed a height from the first bottom to the second bottom in the closed position. The first and second sealants may be gels. | 05-20-2010 |
20100149715 | High Amperage Surge Arrestors - Embodiments of the present invention include a T-body elbow arrestor having an elbow body. A surge arrestor is positioned in one portion of the elbow body extending from an intermediate portion of another portion of the elbow body. An end cap assembly is coupled to the elbow body that is electrically connected to the surge arrestor. A bushing receiving region is positioned in the elbow body extending from the intermediate section towards a first end of the elbow body that is configured to receive a bushing. An insulating plug is positioned in the elbow body extending from the intermediate section towards a second, opposite end of the elbow body. The insulating plug has an end in the intermediate section configured to be coupled to the bushing to secure the T-body elbow arrestor in an assembled condition. | 06-17-2010 |
20100218373 | ELECTRICAL CONNECTOR ASSEMBLIES AND JOINT ASSEMBLIES AND METHODS FOR USING THE SAME - An electrical joint assembly for connecting a plurality of conductors includes a busbar hub and a plurality of limiter modules. The busbar hub includes an electrically conductive busbar body and a plurality of conductor legs extending from the busbar body. The limiter modules each include a fuse element. Each of the limiter modules is connected to a respective one of the conductor legs and is connectable to a respective conductor to provide a fuse controlled connection between the respective conductor leg and the respective conductor. Each of the limiter modules is independently removable from the respective one of the conductor legs. | 09-02-2010 |
20100276196 | COVER ASSEMBLIES FOR CABLES AND ELECTRICAL CONNECTIONS AND METHODS FOR MAKING AND USING THE SAME - An integral, unitary cover assembly for covering an electrical connection between first and second electrical cables each having a primary conductor and a neutral conductor includes an inner elastomeric sleeve, an outer elastomeric sleeve and an integral jumper assembly. The inner sleeve defines a cable passage to receive the electrical connection and the primary conductors of the first and second cables. The outer sleeve surrounds the inner sleeve. The jumper assembly includes an electrically conductive jumper conductor, a first jumper connector and a second jumper connector. The jumper conductor is interposed between the inner and outer sleeves and has first and second opposed ends. The first jumper connector is mounted on the first end of the jumper conductor and is configured to mechanically and electrically couple the neutral conductor of the first cable to the jumper conductor. The second jumper connector is mounted on the second end of the jumper conductor and configured to mechanically and is electrically couple the neutral conductor of the second cable to the jumper conductor. | 11-04-2010 |
20140216778 | Holdout Devices and Cover Assemblies and Methods Incorporating the Same - A cover assembly for covering an elongate substrate includes a holdout device and a resilient, elastically radially expanded sleeve member. The holdout device includes a core having an axially extending slit defined therein and defining a core passage to receive the substrate, and a designated target region. The sleeve member defines an axially extending sleeve passage. The sleeve member is mounted on the core such that the core is disposed in the sleeve passage and the sleeve member exerts a radially compressive recovery force on the core. When the substrate is disposed in the core passage and a radially directed release force is applied to the target region, the core will reduce in circumference and collapse around the substrate under the recovery force of the sleeve member to a collapsed position. | 08-07-2014 |
20140262500 | Cover Assemblies and Methods for Covering Electrical Cables and Connections - A method for protecting a cable splice connection including a cable, the cable including an electrical conductor surrounded by a cable insulation layer, includes providing a splice body assembly including: an electrically insulative, elastomeric splice body having an interior surface defining an interior passage; and a layer of a conformable medium pre-mounted on the interior surface of the splice body. The conformable medium is a flowable, electrically insulative material. The method further includes mounting the splice body assembly on the cable splice connection such that the layer of the conformable mastic is interposed between and engages each of the interior surface of the splice body and an opposing interface surface of the cable insulation layer. | 09-18-2014 |
20140338953 | JOINT BODIES AND METHODS FOR COVERING ELECTRICAL CABLES AND CONNECTIONS - A joint body for protecting an electrical cable connection including an electrical cable includes an expandable, elastomeric bladder sleeve and an electrically insulating gel. The bladder sleeve defines a gel cavity and a cable passage to receive the electrical cable. The gel is disposed in the gel cavity and surrounds at least a portion of the cable passage. The joint body is configured to be installed on the connection such that the connection is disposed in the cable passage and is surrounded and electrically insulated by the gel. | 11-20-2014 |