A connector element (1), for a quick connect coupling to a terminal (3) having an interface (33) with a cylindrical enclosure, the connector element with a body delimiting an inner passage (43) for the fluid. In order for the connector to be able to be coupled reliably with terminals of variable dimensions and interface quality, the invention provides that the body has a conical portion (45) and that the connector element (1) has a movable bush (5), an elastic return member (8), which applies an elastic return force (F8) on the bush (5), and clamping pads (6) received in a respective housing (51) of the bush (5), the clamping pads being translated radially relative to the bush by mechanical cooperation with the conical portion, between a radial withdrawn position and a radial clamping position, to cooperate mechanically with the interface.

A cryogenic transfer line assembly and cryogenic transfer line coupling for a cryostat is presented. The cryogenic transfer line assembly includes an induction tube communicatively coupled to a cryostat, a cryogenic transfer line having defined as a portion thereof a second portion of a bayonet coupling and a cryogenic transfer line coupling, The cryogenic transfer line coupling communicatively couples the induction tube and the cryogenic transfer line and has defined as a portion thereof a first portion of the bayonet coupling and a gate valve. The gate valve prevents the ingress of environmental air passing through the first portion of the bayonet coupling to a cryogenic fluid disposed within a cryogenic vessel of the cryostat upon disengagement of the cryogenic transfer line from the cryogenic transfer line coupling.

A cryogenic transfer line assembly and cryogenic transfer line coupling for a cryostat is presented. The cryogenic transfer line assembly includes an induction tube communicatively coupled to a cryostat, a cryogenic transfer line having defined as a portion thereof a second portion of a bayonet coupling and a cryogenic transfer line coupling, The cryogenic transfer line coupling communicatively couples the induction tube and the cryogenic transfer line and has defined as a portion thereof a first portion of the bayonet coupling and a gate valve. The gate valve prevents the ingress of environmental air passing through the first portion of the bayonet coupling to a cryogenic fluid disposed within a cryogenic vessel of the cryostat upon disengagement of the cryogenic transfer line from the cryogenic transfer line coupling.

A connector assembly for connection and disconnection between ports of fluid lines for administering fluids into a human body from a route other than the oral route. The connector assembly includes a catheter dock, a cap removal dock, a fluid line dock, and a new cap dock. The catheter dock can receive an inlet port of a catheter secured by a catheter cap. The cap removal dock can aseptically remove the catheter cap from the inlet port. The catheter dock can be switched consecutively between the cap removal dock, the fluid line dock, and the new cap dock. Upon removal of the catheter cap, the catheter dock can be switched to the fluid line dock, and the fluid can flow from the fluid line to the catheter. Upon administering the liquid, the catheter dock can be switched from the fluid line dock to the new cap dock, wherein a new catheter cap is secured into the inlet port under aseptic conditions.

A connector assembly for connection and disconnection between ports of fluid lines for administering fluids into a human body from a route other than the oral route. The connector assembly includes a catheter dock, a cap removal dock, a fluid line dock, and a new cap dock. The catheter dock can receive an inlet port of a catheter secured by a catheter cap. The cap removal dock can aseptically remove the catheter cap from the inlet port. The catheter dock can be switched consecutively between the cap removal dock, the fluid line dock, and the new cap dock. Upon removal of the catheter cap, the catheter dock can be switched to the fluid line dock, and the fluid can flow from the fluid line to the catheter. Upon administering the liquid, the catheter dock can be switched from the fluid line dock to the new cap dock, wherein a new catheter cap is secured into the inlet port under aseptic conditions.

A bag connector system includes a first coupling element, with a self-closing seal and a housing having a fluid inlet port and a fluid outlet port, and a second coupling element, with a housing having a fluid inlet end and a fluid outlet end. The fluid inlet end is configured to displace the self-closing seal when inserted into the fluid outlet port of the first coupling element. A bag connector system optionally includes a locking mechanism to maintain the first coupling element and second coupling element in a coupled state. Uncoupling of the first and second coupling elements results in minimal fluid contamination on the outer surfaces of the coupling elements. The bag connector systems provided herein are included in medical appliances for waste management.

A safety coupler for an air hose terminating in a plug. The plug has a passageway between its first and second ends for the passage of air there through. The coupler member has upstream and downstream ends and first body coupler passageway sized for receiving a first cylindrical section of the plug and terminating in a washer. A sleeve coupler and spring for biasing the sleeve coupler towards the coupler member upstream end, the sleeve coupler terminating at its coupler member upstream end by a bushing plug being sized to create a shoulder for abutting a raised stop of the plug. A reduced diameter plug receiving passageway is located downstream of the sleeve coupler and is sized to receive the plug and for receiving pressurized air passing through the plug passageway, and a sleeve slide valve threadably engageable to the washer such that when the plug enters the coupler member, the plug having a raised stop abuts the first body coupler resulting in the washer being displaced towards the coupler member downstream end whereupon the sleeve slide valve threadably captures the washer preventing the plug from disconnecting from the coupler member.

A cryogenic transfer line assembly and cryogenic transfer line coupling for a cryostat is presented. The cryogenic transfer line assembly includes an induction tube communicatively coupled to a cryostat, a cryogenic transfer line having defined as a portion thereof a second portion of a bayonet coupling and a cryogenic transfer line coupling, The cryogenic transfer line coupling communicatively couples the induction tube and the cryogenic transfer line and has defined as a portion thereof a first portion of the bayonet coupling and a gate valve. The gate valve prevents the ingress of environmental air passing through the first portion of the bayonet coupling to a cryogenic fluid disposed within a cryogenic vessel of the cryostat upon disengagement of the cryogenic transfer line from the cryogenic transfer line coupling.

A cryogenic transfer line assembly and cryogenic transfer line coupling for a cryostat is presented. The cryogenic transfer line assembly includes an induction tube communicatively coupled to a cryostat, a cryogenic transfer line having defined as a portion thereof a second portion of a bayonet coupling and a cryogenic transfer line coupling, The cryogenic transfer line coupling communicatively couples the induction tube and the cryogenic transfer line and has defined as a portion thereof a first portion of the bayonet coupling and a gate valve. The gate valve prevents the ingress of environmental air passing through the first portion of the bayonet coupling to a cryogenic fluid disposed within a cryogenic vessel of the cryostat upon disengagement of the cryogenic transfer line from the cryogenic transfer line coupling.

The present invention relates broadly to a fluid coupling assembly (10) comprising a fluid nozzle sub-assembly (12) arranged to releasably couple to a fluid receiver sub-assembly (14). The fluid nozzle sub-assembly (12) includes a nozzle assembly body (16) defining a pressurised and upstream fluid passageway (18) having a fluid discharge opening (20), and a sleeve (22) slidably mounted to the nozzle body (16) and arranged on sliding movement for opening of the fluid discharge opening (20). The fluid receiver sub-assembly (14) includes a receiver body (26) defining a downstream fluid passageway (28), a hydraulically-actuated poppet valve (30) mounted within the receiver body (26), and a receiver poppet valve (48) including a receiver poppet (54) mounted within the receiver body (26). On coupling of the nozzle sub-assembly (12) to the receiver sub-assembly (14), the following steps occur: 1. the receiver body (26) abuts the sleeve (22) displacing it axially relative to the nozzle body (16) exposing and thus opening the fluid discharge opening (20) permitting fluid to flow through the upstream fluid passageway (18); 2. the fluid flowing through the upstream fluid passageway (18) enters the downstream fluid passageway (28) hydraulically actuating the hydraulically-actuated poppet valve (30) to open it wherein the fluid flows through the downstream fluid passageway (28) exiting the receiver sub-assembly (14).