Abstract: A splice enclosure for providing a space for receipt of a plurality of spliced optical fibers of a plurality of cables may include a cabinet including a rear wall, a first side wall coupled to the rear wall, and a second side wall coupled to the rear wall. The cabinet may also include a lower wall coupled to the first side wall, the second side wall, and/or the rear wall. The splice enclosure may further include a splice tray assembly, which may include a splice tray housing pivotally coupled to the cabinet, and a plurality of splice trays pivotally coupled to the splice tray housing and configured to provide a space for receipt of a plurality of spliced optical fibers of a plurality of cables. The splice tray housing may be pivotally coupled to the cabinet, such that the splice tray housing pivots.

Abstract: A fiber terminal rack mount with front-to-back fiber routing management is disclosed herein. The terminal rack mount is configured to be mounted in a remote terminal to facilitate fiber management of fiber optic cables routed from fiber optic equipment. In exemplary aspects disclosed herein, the fiber terminal rack mount comprises two vertically oriented panels with a plurality of horizontally oriented shelves positioned therebetween. The panels are configured to mount to vertical rails of a remote terminal cabinet of the fiber terminal. The panels and shelves also define routing channels for routing fiber optic cables therethrough, thereby facilitating front-to-back fiber routing between fiber optic equipment mounted in the fiber terminal. In this manner, as an example, the fiber terminal rack mount may more easily support fiber routing between back-to-back mounted fiber optic equipment, which may increase as fiber optic connectivity density increases.

Abstract: A splice enclosure for providing a space for receipt of a plurality of spliced optical fibers of a plurality of cables may include a cabinet including a rear wall, a first side wall coupled to the rear wall, and a second side wall coupled to the rear wall. The cabinet may also include a lower wall coupled to the first side wall, the second side wall, and/or the rear wall. The splice enclosure may further include a splice tray assembly, which may include a splice tray housing pivotally coupled to the cabinet, and a plurality of splice trays pivotally coupled to the splice tray housing and configured to provide a space for receipt of a plurality of spliced optical fibers of a plurality of cables. The splice tray housing may be pivotally coupled to the cabinet, such that the splice tray housing pivots.

Abstract: Embodiments of the disclosure are directed to a fiber optic spool drawer with a translatable and/or removable drawer for deployment of fiber optic cable. In exemplary aspects disclosed herein, the fiber optic spool drawer includes a housing with a translatable drawer and a rotatable spool disposed within an interior area of the housing. The translatable drawer includes a selective locking mechanism and is bidirectionally translatable within and bidirectionally removable from the housing. The rotatable spool is mounted to the translatable drawer and configured to rotate to deploy fiber optic cable. Still further, the fiber optic deployment assembly also includes front and back routing guides to manage and prevent damage to the fiber optic cables deployed. Accordingly, as an example, the fiber optic spool drawer may facilitate easy, efficient, and versatile fiber routing while preventing damage to the fiber optic cable.

Abstract: A fiber terminal rack mount with front-to-back fiber routing management is disclosed herein. The terminal rack mount is configured to be mounted in a remote terminal to facilitate fiber management of fiber optic cables routed from fiber optic equipment. In exemplary aspects disclosed herein, the fiber terminal rack mount comprises two vertically oriented panels with a plurality of horizontally oriented shelves positioned therebetween. The panels are configured to mount to vertical rails of a remote terminal cabinet of the fiber terminal. The panels and shelves also define routing channels for routing fiber optic cables therethrough, thereby facilitating front-to-back fiber routing between fiber optic equipment mounted in the fiber terminal. In this manner, as an example, the fiber terminal rack mount may more easily support fiber routing between back-to-back mounted fiber optic equipment, which may increase as fiber optic connectivity density increases.

Abstract: A fiber terminal rack mount with front-to-back fiber routing management is disclosed herein. The terminal rack mount is configured to be mounted in a remote terminal to facilitate fiber management of fiber optic cables routed from fiber optic equipment. In exemplary aspects disclosed herein, the fiber terminal rack mount comprises two vertically oriented panels with a plurality of horizontally oriented shelves positioned therebetween. The panels are configured to mount to vertical rails of a remote terminal cabinet of the fiber terminal. The panels and shelves also define routing channels for routing fiber optic cables therethrough, thereby facilitating front-to-back fiber routing between fiber optic equipment mounted in the fiber terminal. In this manner, as an example, the fiber terminal rack mount may more easily support fiber routing between back-to-back mounted fiber optic equipment, which may increase as fiber optic connectivity density increases.

Abstract: Embodiments of the disclosure are directed to a fiber optic spool drawer with a translatable and/or removable drawer for deployment of fiber optic cable. In exemplary aspects disclosed herein, the fiber optic spool drawer includes a housing with a translatable drawer and a rotatable spool disposed within an interior area of the housing. The translatable drawer includes a selective locking mechanism and is bidirectionally translatable within and bidirectionally removable from the housing. The rotatable spool is mounted to the translatable drawer and configured to rotate to deploy fiber optic cable. Still further, the fiber optic deployment assembly also includes front and back routing guides to manage and prevent damage to the fiber optic cables deployed. Accordingly, as an example, the fiber optic spool drawer may facilitate easy, efficient, and versatile fiber routing while preventing damage to the fiber optic cable.

Abstract: A fiber terminal rack mount with front-to-back fiber routing management is disclosed herein. The terminal rack mount is configured to be mounted in a remote terminal to facilitate fiber management of fiber optic cables routed from fiber optic equipment. In exemplary aspects disclosed herein, the fiber terminal rack mount comprises two vertically oriented panels with a plurality of horizontally oriented shelves positioned therebetween. The panels are configured to mount to vertical rails of a remote terminal cabinet of the fiber terminal. The panels and shelves also define routing channels for routing fiber optic cables therethrough, thereby facilitating front-to-back fiber routing between fiber optic equipment mounted in the fiber terminal. In this manner, as an example, the fiber terminal rack mount may more easily support fiber routing between back-to-back mounted fiber optic equipment, which may increase as fiber optic connectivity density increases.

Abstract: VTOL amphibious aircraft comprising two fuselages spaced apart to enable the placement of single center wing and split ailerons, engine and rotor or fan such that they may be rotated from vertical flight to horizontal flight and back while center wing ailerons counter rotor torque. Out board wings remain fixed and the twin fuselages provide buoyant hulls to facilitate water landings. Standard aircraft components are employed such as a vertical tails and horizontal stabilizers.

Abstract: VTOL amphibious aircraft comprising two fuselages spaced apart to enable the placement of center wing and ailerons, engine and rotor or fan such that they may be rotated from vertical flight to horizontal flight and back while center wing ailerons counter rotor torque. Out board wings remain fixed and the twin fuselages provide hulls to facilitate water landings. Standard aircraft components are employed such as a vertical tails and horizontal stabilizers.

Abstract: A cableway with suspended tram and remote bogie is disclosed. This includes a self-contained motor, traction and support sheaves with provision for adjusting the height of the tram below said cable for limiting vertical acceleration caused by travel along the cantenary curve of the cableway.

Abstract: A cableway with suspended tram and remote bogie is disclosed. This includes a self-contained motor, traction and support sheaves with provision for adjusting the height of the tram below said cable for limiting vertical acceleration caused by travel along the cantenary curve of the cableway.

Abstract: An improved boat or ship with a combination planing and displacement hull, fins mounted near the aft section provide increased planing area while still permitting a tapered aft of favorable prismatic ratio for when the boat or ship is in the displacement mode.