A fluid swivel for fluid transfer across a rotary interface includes inner annular and outer annular elements, located with their adjacent surfaces in close proximity to define a chamber between the adjacent surfaces. The swivel inner annular element has a conduit connected to an end of an incoming fluid line. The outer annular element is connected to outgoing product piping and has a primary duct for transport of fluid from the chamber to the product piping. The swivel includes an outer reinforcing annular wall arranged adjacent to the outer peripheral wall of the outer annular element. The outer reinforcing annular wall has two peripheral centering surface portions for contacting and/or registering with the outer peripheral wall of the outer annular element. The outer reinforcing annular wall further has a central peripheral opening extending along a portion of the periphery for allowing the primary duct to pass through.

A mixer valve (1) having a body (2) and adapted to be connected to two fluid supplies. The mixer valve (1) has at least one connector (6) comprising a housing (8); a fluid delivery tube (10) within the housing, the fluid delivery tube (10) having at least one aperture (22); a slider (16) arranged around and slideable over the delivery tube (10) and having an interior chamber (18) in fluid communication with an interior (20) of the delivery tube by means of the at least one aperture (22); and a fluid inlet (14) connected to the slider (16) at an angle thereto, the fluid inlet (14) being connectable to a fluid supply pipe. The fluid inlet (14) is in fluid communication with the chamber (18), and the housing (8) has an external opening (12) within which the fluid inlet (14) is located and movable.

A rotary device having a housing, a rotating machine component, a rotating member associated with the rotating machine component, a non-rotating member disposed within the housing adjacent the rotating member, and a sensor array disposed in the housing. The sensor array includes a plurality of sensing elements that are integrated with a control device and a wireless communication device. The wireless communication device is configured to communicate with a central control that is remotely located relative to the housing using electromagnetic waves.

A rotary device having a housing, a rotating machine component, a rotating member associated with the rotating machine component, a non-rotating member disposed within the housing adjacent the rotating member, and a sensor array disposed in the housing. The sensor array includes a plurality of sensing elements that are integrated with a control device and a wireless communication device. The wireless communication device is configured to communicate with a central control that is remotely located relative to the housing using electromagnetic waves.

A vacuum coupling applies vacuum from a vacuum source to a rotating tool attached to a rotating end of a robotic arm. The vacuum coupling includes a rotating portion attaching the rotating tool to the rotating end of the robotic arm. The rotating portion communicates vacuum with the rotating tool. A fixed portion is positioned around the rotating portion such that the rotating portion is rotatable relative to the fixed portion. The fixed portion communicates vacuum to the rotating portion. At least one rotating vacuum seal is positioned between the fixed portion and the rotating portion.

A vacuum coupling applies vacuum from a vacuum source to a rotating tool attached to a rotating end of a robotic arm. The vacuum coupling includes a rotating portion attaching the rotating tool to the rotating end of the robotic arm. The rotating portion communicates vacuum with the rotating tool. A fixed portion is positioned around the rotating portion such that the rotating portion is rotatable relative to the fixed portion. The fixed portion communicates vacuum to the rotating portion. At least one rotating vacuum seal is positioned between the fixed portion and the rotating portion.

A swivel connector includes: an inner body having a first end and a second end opposite to the first end, the inner body defining an inner port at the second end for receiving a first fluid connection; and an outer body captively rotatable about the inner body, the outer body defining an outer port for receiving a second fluid connection, the inner body and the outer body cooperatively defining an annular passage therebetween, and the inner port extending within the inner body to the annular passage and the outer port extending within the outer body to the annular passage so as to form a passageway operable to permit a flow of fluid between the inner port and the outer port. The swivel connector of the present invention permits a first connected hose to swivel about a first axis that is perpendicular to a second axis with a second connected hose.

A swivel connector includes: an inner body having a first end and a second end opposite to the first end, the inner body defining an inner port at the second end for receiving a first fluid connection; and an outer body captively rotatable about the inner body, the outer body defining an outer port for receiving a second fluid connection, the inner body and the outer body cooperatively defining an annular passage therebetween, and the inner port extending within the inner body to the annular passage and the outer port extending within the outer body to the annular passage so as to form a passageway operable to permit a flow of fluid between the inner port and the outer port. The swivel connector of the present invention permits a first connected hose to swivel about a first axis that is perpendicular to a second axis with a second connected hose.

A vacuum coupling applies vacuum from a vacuum source to a rotating tool attached to a rotating end of a robotic arm. The vacuum coupling includes a rotating portion attaching the rotating tool to the rotating end of the robotic arm. The rotating portion communicates vacuum with the rotating tool. A fixed portion is positioned around the rotating portion such that the rotating portion is rotatable relative to the fixed portion. The fixed portion communicates vacuum to the rotating portion. At least one rotating vacuum seal is positioned between the fixed portion and the rotating portion.

A vacuum coupling applies vacuum from a vacuum source to a rotating tool attached to a rotating end of a robotic arm. The vacuum coupling includes a rotating portion attaching the rotating tool to the rotating end of the robotic arm. The rotating portion communicates vacuum with the rotating tool. A fixed portion is positioned around the rotating portion such that the rotating portion is rotatable relative to the fixed portion. The fixed portion communicates vacuum to the rotating portion. At least one rotating vacuum seal is positioned between the fixed portion and the rotating portion.