In a device for transmitting optical signals between a first subassembly and a second subassembly, which rotatable about an axis relative to the first subassembly. The first subassembly includes a first optical waveguide, and the second subassembly includes a second optical waveguide. The device includes a first sleeve enclosing the first optical waveguide, a first bushing enclosing the first sleeve, a housing, a second sleeve enclosing the second optical waveguide, a second bushing enclosing the second sleeve. Furthermore, the device includes a bearing arrangement, including at least one first ring and rolling elements, rollingly supported on a conical surface. The housing encloses the first bushing, the second bushing, and the bearing arrangement, the bearing arrangement is axially displaceable relative to the housing, and the second bushing is axially preloaded with respect to the first bushing via the bearing arrangement. The rolling elements are radially preloaded with respect to the housing by their support on the conical surface.

An inventive rotatable optical short-range transceiver has: a support which is rotatable around a rotation axis, an optical receiver which is arranged at the support on the rotation axis to receive an optical reception signal from a first direction, an optical transmitter which is arranged at the support to be adjacent to the optical receiver to emit an optical transmission signal in a second direction, and an optical transmission/reception unit which is configured to allow interruption-free rotatable optical data communication, wherein the optical transmission/reception unit is arranged at the support above the optical receiver and extends over the optical receiver and the optical transmitter, and wherein the optical transmission/reception unit has a support structure for mounting at the support, which is implemented integrally with the optical transmission/reception unit.

An optical rotary joint having a housing, a hollow shaft, a bevel gear, a prism and two collimators. The housing includes two sections, each holding a collimator and separated by a gap in an axial direction from each other and rotatable against each other and around the center axis. The hollow shaft is aligned with the center axis, and has two ends extending into the housing sections. The housing sections are supported via bearings by the hollow shaft. The hollow shaft further contains a prism holder with a Dove prism. The bevel gear is located in the gap between the housing sections and includes two wheels at the housing sections in mesh with two third wheels, which have an axis oriented radially to the center axis and fixedly attached to the hollow shaft, such that a rotation of the housing sections against each other results in a rotation of the hollow shaft with half of the angular speed.

A suspension arm assembly including at least two members relatively rotatable about each other at a joint, with at least one of the joints comprising an infinite rotation joint. The infinite rotation joint allows the members at the infinite rotation joint to have unlimited rotation relative to one another. The infinite rotation joint is configured to pass at least an optical signal therethrough. The infinite rotation joint includes a stator and a rotor. At least two portions of the infinite rotation joint are separable and can automatically form a unit when adjacent arms are connected together such that the infinite rotation joint can be separated into the at least two portions. The at least two portions are configured to be automatically connected to allow the optical signal to pass therethrough once the at least two portions are engaged.

An optical rotary joint having a housing, a hollow shaft, a bevel gear, a prism and two collimators. The housing includes two sections, each holding a collimator and separated by a gap in an axial direction from each other and rotatable against each other and around the center axis. The hollow shaft is aligned with the center axis, and has two ends extending into the housing sections. The housing sections are supported via bearings by the hollow shaft. The hollow shaft further contains a prism holder with a Dove prism. The bevel gear is located in the gap between the housing sections and includes two wheels at the housing sections in mesh with two third wheels, which have an axis oriented radially to the center axis and fixedly attached to the hollow shaft, such that a rotation of the housing sections against each other results in a rotation of the hollow shaft with half of the angular speed.

The current disclosure is regarding an electrical slip ring assembly that transmit signals, data, and power across rotary platforms, especially for high frequency applications. The high frequency slip ring assembly with through bore may include a first stage slip ring, a second stage slip ring, a gear assembly, and an internal cable assembly. Rings may have an angled notch on a circumference to break said rings and have the same diameter. The first stage slip ring and second stage slip ring may be connected in series sequence, i.e., the stator in first stage slip ring is mechanically connected with the rotor in second stage slip ring. The internal cable assembly electrically connects the brush assembly in first stage slip ring with the ring assembly in said second stage slip ring in each channel respectively.

The current invention is regarding an electrical slip ring system for high speed applications, which require slip rings to operate at speeds more than 60,000 RPM. It consists of multiple single stage slip rings and multiple gear devices, where all the stators, except the last one, are rotational. The speed limit on the slip ring market, by using the advanced fiber brush bundles, is about 10,000 RPM without cooling, or lubricating. The basic idea is that by designing gears, we can always can make sure the relative speed between the rotor and the stator in each stage is <=10000 rpm.

An optical fiber connector configured to rotationally align a first optical fiber with a second optical fiber is provided. The connector can include at least two rotational alignment features. At least one of the two rotational alignment features can include at least one ferrule configured to hold at least the first optical fiber.

The current disclosure shows a fiber optic slip ring with through bore, or an off-axis fiber optic rotary joint to provide transmission of optic data between mechanically rotational interface with a through bore. Said fiber optic slip ring with through bore may include a ring assembly and a brush block assembly within a rotor and a stator. Said ring assembly may include a ring, a ring holder and a fiber. Said brush block assembly may include a fiber brush, a brush block, an optic index matching fluid, and shaft seals. Said ring may be a donut-shaped waveguide with flat surface on one side. Said fiber brush may have an angled-surface, which is fully contacted with said flat surface on said ring at any time so that during the rotation of said rotor, the optic signal can be transmitted between said fiber and said fiber brush in either direction.

A device for achieving a mechanical link and optical and/or electrical and/or fluidic transmission between a first element (E1) and a second element (E2), including: a first connection part designed to be fixed to the first element (E1), a first joining member connected optically and/or electrically and/or in fluidic communication with the first element (E1) and mounted on the first connection part, a second connection part designed to be fixed to the second element (E2), and arranged at least in part between the first connection part and the first joining member and defining a ball joint link between the first and second elements, and a second joining member connected optically and/or electrically and/or in fluidic communication with the second element (E2), arranged in the second connection part, the first and second joining members being configured to allow an optical and/or electrical and/or fluidic transmission from one to the other.