Abstract: Various implementations include a low-drag smart tether system for measuring fluid speed and direction. The system includes a sleeve, a pressure sensor, and a tether. The sleeve has a longitudinal axis and an airfoil shaped cross-section as viewed in a plane perpendicular to the longitudinal axis. The sleeve has a leading edge. The sleeve defines a tether opening extending parallel to the longitudinal axis. The pressure sensor is disposed along a surface of the sleeve. The pressure sensor is configured to measure the pressure exerted on the pressure sensor by air moving over the surface of the sleeve. The tether extends through the tether opening defined by the sleeve. The tether has a tether longitudinal axis. The tether opening is positioned such that fluid flowing around the sleeve causes the sleeve to rotate about the tether longitudinal axis.

Abstract: An improved magnetic gear is provided that mitigates end-effect loss in cycloidal magnetic gears by adding axially magnetized cladding magnets to the ends of the magnet rotors that redirect the escaping magnetic flux back into the magnetic circuit. The most influential design factors defining the cladding magnet are identified as the height and depth ratio (ratios of dimensions in radial and axial directions, respectively) and the magnetization orientation or tilt of the cladding magnets. The ideal height ratio is found to be approximately 50-60%, while the optimal tilt is around 15 degrees for the cycloidal configuration.

Abstract: A method of welding a first layer of Ti alloy to a second layer of Ti alloy. The method includes disposing a metallic interlayer onto a first layer of Ti alloy, disposing the second layer of Ti alloy onto the metallic interlayer such that the metallic interlayer is disposed between the first layer of Ti alloy and the second layer of Ti alloy, and applying a horn of an ultrasonic device to the second layer of Ti alloy to weld the first layer of Ti alloy to the second layer of Ti alloy to form a welded material.

Abstract: A bayonet connector device including a female coupler including an annular wall defining a female coupler opening and a central axis, and a plurality of female coupler engagement structures extending radially inward from the annular wall toward the central axis, and a male coupler sized to be received within the female coupler opening and including a plurality of male coupler engagement structures shaped to mesh with the female coupler engagement structures. The female coupler engagement structures and the male coupler engagement structures define an inner length in an axial direction parallel with the central axis, and an outer length in the axial direction at a position radially farther away from the central axis than the inner length. The outer length is greater than the inner length.

Abstract: An exemplary axial cladding magnet magnetically-geared machine is disclosed comprising Halbach array cladding magnets located on the axial ends of the magnetically-geared machine. The Halbach array cladding magnets can be used to increase the magnetic efficiency and torque transmission of the magnetically-geared machine by mitigating end-effect losses.

Abstract: An ultrasonic additive manufacturing system may include a base structure, a sonotrode configured to rotate about an axis of rotation, and one or more transducers configured to vibrate the sonotrode. The sonotrode may include a welding surface extending along a circumference of the sonotrode, and the welding surface may have a contoured profile. At least one of the sonotrode and the base structure may be configured to translate relative to the other of the sonotrode and the base structure.

Abstract: According to one aspect, the present disclosure provides a system for manufacturing transition structures including fiber threads embedded within a metal component. The system may include a supply of base sheet metal. The system may include a conveyor supported on a plurality of rollers and configured to move the base sheet metal in a production direction. The system may include a plurality of stages arranged in the production direction. Each stage may include a channel forming device configured to form a channel in the base sheet metal, a fiber inserting device configured to insert a portion of a fiber material into the channel, and one or more ultrasonic welders configured to consolidate a layer of metal foil over the fiber. The disclosure includes methods of using the system to produce transition structures and reinforced components.

Abstract: An ultrasonic additive manufacturing system may include a base structure, a sonotrode configured to rotate about an axis of rotation, and one or more transducers configured to vibrate the sonotrode. The sonotrode may include a welding surface extending along a circumference of the sonotrode, and the welding surface may have a contoured profile. At least one of the sonotrode and the base structure may be configured to translate relative to the other of the sonotrode and the base structure.

Abstract: A transition structure includes a metallic portion, a fiber portion including a plurality of tows embedded within the metallic portion and extending out from the metallic portion forming a fabric, and a binding material forming a matrix surrounding the fiber portion embedded within the metallic portion. The fiber portion may be attached to or form part of a composite vehicle component. The transition structure may join a metallic component and a composite component. The transition structure may be manufactured by creating first channels within a layer of a metallic substrate, inserting fiber tows into the first channels, placing a first metallic layer over the metallic substrate and the fiber tows, consolidating the metallic layer to the metallic substrate, and binding the fiber tows within a resin. Prior to binding, additional layers of channels and fiber tows may be consolidated onto the first metallic layer.

Abstract: According to one aspect, the present disclosure provides a system for manufacturing transition structures including fiber threads embedded within a metal component. The system may include a supply of base sheet metal. The system may include a conveyor supported on a plurality of rollers and configured to move the base sheet metal in a production direction. The system may include a plurality of stages arranged in the production direction. Each stage may include a channel forming device configured to form a channel in the base sheet metal, a fiber inserting device configured to insert a portion of a fiber material into the channel, and one or more ultrasonic welders configured to consolidate a layer of metal foil over the fiber. The disclosure includes methods of using the system to produce transition structures and reinforced components.

Abstract: According to one aspect, the present disclosure provides a system for manufacturing transition structures including fiber threads embedded within a metal component. The system may include a supply of base sheet metal. The system may include a conveyor supported on a plurality of rollers and configured to move the base sheet metal in a production direction. The system may include a plurality of stages arranged in the production direction. Each stage may include a channel forming device configured to form a channel in the base sheet metal, a fiber inserting device configured to insert a portion of a fiber material into the channel, and one or more ultrasonic welders configured to consolidate a layer of metal foil over the fiber. The disclosure includes methods of using the system to produce transition structures and reinforced components.

Abstract: An exemplary axial cladding magnet magnetically-geared machine is disclosed comprising Halbach array cladding magnets located on the axial ends of the magnetically-geared machine. The Halbach array cladding magnets can be used to increase the magnetic efficiency and torque transmission of the magnetically-geared machine by mitigating end-effect losses.

Abstract: An ultrasonic additive manufacturing system may include a base structure, a sonotrode configured to rotate about an axis of rotation, and one or more transducers configured to vibrate the sonotrode. The sonotrode may include a welding surface extending along a circumference of the sonotrode, and the welding surface may have a contoured profile. At least one of the sonotrode and the base structure may be configured to translate relative to the other of the sonotrode and the base structure.

Abstract: A transition structure includes a metallic portion, a fiber portion including a plurality of tows embedded within the metallic portion and extending out from the metallic portion forming a fabric, and a binding material forming a matrix surrounding the fiber portion embedded within the metallic portion. The fiber portion may be attached to or form part of a composite vehicle component. The transition structure may join a metallic component and a composite component. The transition structure may be manufactured by creating first channels within a layer of a metallic substrate, inserting fiber tows into the first channels, placing a first metallic layer over the metallic substrate and the fiber tows, consolidating the metallic layer to the metallic substrate, and binding the fiber tows within a resin. Prior to binding, additional layers of channels and fiber tows may be consolidated onto the first metallic layer.

Abstract: A transition structure includes a metallic portion, a fiber portion including a plurality of tows embedded within the metallic portion and extending out from the metallic portion forming a fabric, and a binding material forming a matrix surrounding the fiber portion embedded within the metallic portion. The fiber portion may be attached to or form part of a composite vehicle component. The transition structure may join a metallic component and a composite component. The transition structure may be manufactured by creating first channels within a layer of a metallic substrate, inserting fiber tows into the first channels, placing a first metallic layer over the metallic substrate and the fiber tows, consolidating the metallic layer to the metallic substrate, and binding the fiber tows within a resin. Prior to binding, additional layers of channels and fiber tows may be consolidated onto the first metallic layer.

Abstract: According to one aspect, the present disclosure provides a system for manufacturing transition structures including fiber threads embedded within a metal component. The system may include a supply of base sheet metal. The system may include a conveyor supported on a plurality of rollers and configured to move the base sheet metal in a production direction. The system may include a plurality of stages arranged in the production direction. Each stage may include a channel forming device configured to form a channel in the base sheet metal, a fiber inserting device configured to insert a portion of a fiber material into the channel, and one or more ultrasonic welders configured to consolidate a layer of metal foil over the fiber. The disclosure includes methods of using the system to produce transition structures and reinforced components.

Abstract: A transition structure includes a metallic portion, a fiber portion including a plurality of tows embedded within the metallic portion and extending out from the metallic portion forming a fabric, and a binding material forming a matrix surrounding the fiber portion embedded within the metallic portion. The fiber portion may be attached to or form part of a composite vehicle component. The transition structure may join a metallic component and a composite component. The transition structure may be manufactured by creating first channels within a layer of a metallic substrate, inserting fiber tows into the first channels, placing a first metallic layer over the metallic substrate and the fiber tows, consolidating the metallic layer to the metallic substrate, and binding the fiber tows within a resin. Prior to binding, additional layers of channels and fiber tows may be consolidated onto the first metallic layer.