A sliding door assembly (50) for an inductively coupled plasma torch box (40) reduces the risk of heat related injuries and facilitates the handling of the torch box. The door assembly (50) comprises a door and a guiding mechanism (6) for allowing movement of the door in a first direction along an opening (45) of the torch box (40) so as to be able to open and close the torch box, and allowing movement of the door in a second direction, substantially perpendicular to the first direction, so as to move the door or at least a part thereof towards the opening when closing the torch box. The door may comprise an inner door panel interconnected with an outer door panel, so that only the inner door panel moves in the second direction, towards the opening (45) of the torch box (40) to tightly close it, while the outer door panel can maintain a safe temperature during operation.

An integrated and modular air and lighting plenum that is the primary directional lighting mounting apparatus and laminar flow diffuser of an HVAC system in a healthcare setting. The plenum provides laminar air flow from the ceiling to the room in which it is located in accordance with HVAC requirements for healthcare environment settings, by using a plurality of cylindrical airflow outlets. The use of cylindrical airflow outlets promotes laminar airflow by reducing sharp boundaries that induce turbulence (e.g., the corners of rectangular or square outlets) and creates a highly sterile environment around the patient and staff in the operating room. The surgical lights used in the integrated air and lighting plenum allow the beam direction, spot size, focal point, brightness, and color temperature of the emitted light to be controlled.

A method and a device connects a partially flexible protective cover (2) sealed against the environment and forming a barrier between a contaminated area (12) and an uncontaminated area, to a partially flexible safety cover (20) by transferring the protective cover (2) out of the contaminated area (12) inverting the protective cover (2) over an opening such that its inside is turned out and then severing it from the safety cover (20) and closing the opening; or transferring the protective cover (2) from the contaminated area (12) by sheathing the protective cover (2) with the safety cover (20) as it is pulled through a passage and subsequently severing of both covers (2, 20) from the safety cover (20) and closing the sheathing; or pulling the protective cover (2) back into the contaminated area (12) and then sealing the ends shut to sever the safety cover (20) by forming a further sealed joint between adjacent film parts.

The present application relates to a transfer device (60) for transferring a plurality of objects (O) through a transfer port (R), comprising a container (61) with an internal space (67) configured to accommodate the plurality of objects (O) to be transferred through the transfer port (R). The container (61) has at least one extraction opening (62) at an end portion of the container (61) in an axial direction (X) dimensioned such that the objects (O) can be removed from the container (61) at least individually, a door (63) configured to selectively close the at least one extraction opening (62) and seal the internal space (67) from the environment, and a piston (64) arranged in the container (61) so as to be movable in a translational motion in the axial direction (X) towards/away from the at least one extraction opening (62) to move the objects (O) accommodated in the container (61).

The present application relates to a transfer device (60) for transferring a plurality of objects (O) through a transfer port (R), comprising a container (61) with an internal space (67) configured to accommodate the plurality of objects (O) to be transferred through the transfer port (R). The container (61) has at least one extraction opening (62) at an end portion of the container (61) in an axial direction (X) dimensioned such that the objects (O) can be removed from the container (61) at least individually, a door (63) configured to selectively close the at least one extraction opening (62) and seal the internal space (67) from the environment, and a piston (64) arranged in the container (61) so as to be movable in a translational motion in the axial direction (X) towards/away from the at least one extraction opening (62) to move the objects (O) accommodated in the container (61).

The present invention provides systems, apparatuses, and methods for the treatment of containerized waste, such as hazardous, radioactive and/or mixed waste. The apparatuses and methods employ a combination of thermal decomposition and specialized lances.

A radioactive source removing and introducing tooling includes a first support frame, a shield door disposed on the first support frame, a shield cover located on the shield door, and a first pull rod device. The shield door includes a movable first shield block. The shield cover is able to be separated from the shield door, and the shield cover includes one opening and one accommodation space. The first pull rod device includes a pull rod and a first connection portion disposed on the pull rod, and the pull rod is able to extend into the shield cover and drive the first connection portion to move inside the accommodation space of the shield cover.

A radioactive source removing and introducing tooling includes a first support frame, a shield door disposed on the first support frame, a shield cover located on the shield door, and a first pull rod device. The shield door includes a movable first shield block. The shield cover is able to be separated from the shield door, and the shield cover includes one opening and one accommodation space. The first pull rod device includes a pull rod and a first connection portion disposed on the pull rod, and the pull rod is able to extend into the shield cover and drive the first connection portion to move inside the accommodation space of the shield cover.

A vessel electrical penetration assembly for a feed-through of nuclear reactor vessel, the assembly including: a docking tube to form an extension of the secondary containment barrier of the reactor, the docking tube including: a first end to be positioned in the interior of the vessel and to be mechanically and sealably connected to an actuator in the interior of the vessel, and a second end to be mechanically and sealably secured to the vessel; a seal-tight electrical bar that passes through the docking tube and having on either side seal-tight connectors ensuring an electrical link between the actuator and the exterior of the reactor; the seal-tight electrical bar including a system for limiting a leakage of primary liquid to the exterior of the vessel if the secondary containment barrier extension fails; and a mechanical maintaining system for securing, under the required pressure conditions, the electrical bar to the vessel.

Transfer system for sealed enclosure, said sealed enclosure defining a first closed volume and comprising at least one device for sealed connection to a second closed volume, said transfer system being intended to be arranged in said enclosure (E) and to be fixed to a wall thereof, said transfer system comprising at least one arm, a first rotating hinge between the arm intended to be arranged between the arm and said wall of the enclosure, said first rotating hinge comprising a first axis of rotation, a chute and a second rotating hinge between the arm and the chute, said second rotating hinge comprising a second axis of rotation, the chute comprising a docking edge configured to cooperate with the device for sealed connection.