Abstract: A customizable glass wall system is disclosed. The system comprises at least two glazed, transparent panes mounted to a frame, creating an internal space less than approximately five inches thick. At least one upper roller is mounted to an upper portion of the frame, preferably on a removable headboard, and at least one lower roller is mounted to a lower portion of the frame, preferably to a removable tailboard. At least one partitioned film is attached to the upper and lower rollers. The partitioned film has partitions with varied properties and functions, ranging from thermal insulation to decoration, which can be selectively positioned behind the transparent panes by rotating the partitioned film by means of the rollers until a selected partition of film is displayed. The system can be automated based on time, weather, amount of sunlight, or user preference, and it may include window coverings or solar cells.

Abstract: A customizable glass wall system is disclosed. The system comprises at least two glazed, transparent panes mounted to a frame, which is preferably less than five inches thick. The frame includes a removable headboard whereon multiple rollers are mounted. A film is attached to each of the rollers. The films can be selectively extended and retracted behind the transparent panes in the glass wall system by means of the rollers. Each of the films can be controlled individually by a motor driving each of the rollers. The films can be arranged in any combination to perform various functions, but most importantly, to allow various amounts and types of light to pass through the window system in order to control the thermal insulation of the glass wall system. The system can be automated based on time, amount of sunlight, weather, temperature, and user preference.

Abstract: A customizable glass wall system is disclosed. The system comprises at least two glazed, transparent panes mounted to a frame, creating an internal space less than approximately five inches thick. At least one upper roller is mounted to an upper portion of the frame, preferably on a removable headboard, and at least one lower roller is mounted to a lower portion of the frame, preferably to a removable tailboard. At least one partitioned film is attached to the upper and lower rollers. The partitioned film has partitions with varied properties and functions, ranging from thermal insulation to decoration, which can be selectively positioned behind the transparent panes by rotating the partitioned film by means of the rollers until a selected partition of film is displayed. The system can be automated based on time, weather, amount of sunlight, or user preference, and it may include window coverings or solar cells.

Abstract: A customizable glass wall system is disclosed. The system comprises at least two glazed, transparent panes mounted to a frame, which is preferably less than five inches thick. The frame includes a removable headboard whereon multiple rollers are mounted. A film is attached to each of the rollers. The films can be selectively extended and retracted behind the transparent panes in the glass wall system by means of the rollers. Each of the films can be controlled individually by a motor driving each of the rollers. The films can be arranged in any combination to perform various functions, but most importantly, to allow various amounts and types of light to pass through the window system in order to control the thermal insulation of the glass wall system. The system can be automated based on time, amount of sunlight, weather, temperature, and user preference.

Abstract: A semi-autonomous underwater vehicle has (a) a hull; (b) one or more thruster motors; (c) a preprogrammed controller for controlling the motors and/or separate steering components to carry out a plurality of different maneuvers; and (d) a wireless signal receiver for providing instructions to the controller.

Abstract: Disclosed is an underwater vehicle that can be operated as a remotely operated vehicle (ROV) or as an autonomous vehicle (AUV). The underwater vehicle has a tether, which may be a fiberoptic cable, that connects the vehicle to a control console. The underwater vehicle has vertical and lateral thrusters, pitch and yaw control fins, and a propulsor, all of which may be used in an ROV-mode when the underwater vehicle is operating at slow speeds. The underwater vehicle may also be operated in a AUV-mode when operating at higher speeds. The operator may switch the vehicle between ROV-mode and AUV-mode. The underwater vehicle also has a fail-safe mode, in which the vehicle may navigate according to a pre-loaded mission plan if the tether is severed.

Abstract: An anti-biofouling seismic streamer casing (100,100?) is provided that is formed by a flexible tubing (110) coated with a layer of a two-part heat cured silicone elastomer (120). The seismic streamer casing (100, 100?) is formed by a method that includes steps of providing a flexible tubing (200) and pre-treating the outer surface of the tubing (210). Two parts of a two-part silicone elastomer are then mixed together (220). The method also includes coating the mixed two-part silicone elastomer on the flexible tubing (230), and heating the flexible tubing to cure the coating (240).

Abstract: An anti-biofouling seismic streamer casing (100,100?) is provided that is formed by a flexible tubing (110) coated with a layer of a two-part heat cured silicone elastomer (120). The seismic streamer casing (100, 100?) is formed by a method that includes steps of providing a flexible tubing (200) and pre-treating the outer surface of the tubing (210). Two parts of a two-part silicone elastomer are then mixed together (220). The method also includes coating the mixed two-part silicone elastomer on the flexible tubing (230), and heating the flexible tubing to cure the coating (240).