A vacuum chamber may include an ambient side and a vacuum side. The vacuum chamber may be configured to carry a feedthrough that may include a hollow tube, a first O-ring captured by a first recess within the hollow tube and a rod extending through the hollow tube. The outer circumference of the rod may be configured to contact an entirety of an inner circumference of the first O-ring. A vacuum fitting having an inner circumference may be fixedly secured to the hollow tube. The rod may be operable to be linearly movable within the hollow tube and may be rotatably movable about an axis within the hollow tube. An object may be secured to the rod and may be linearly and rotatably moved within the vacuum chamber.

A feedthrough for use in a vacuum chamber is provided and includes a hollow tube having a length, an inner circumference, and a first recess located within the inner circumference. The feedthrough also includes a first O-ring captured by the first recess within the hollow tube. The feedthrough further includes a rod extending through an entirety of the length of the hollow tube. An outer circumference of the rod is configured to contact an entirety of an inner circumference of the first O-ring, and a vacuum fitting is fixedly secured to the hollow tube.

A system for treatment of a biomass material, said system comprising: a first vessel (3) in which said biomass material is treated under a first pressure; a second vessel (5) in which said biomass material is received and held at a second pressure which is lower than the first pressure; a transporting pipe (7) connecting an outlet (9) of the first vessel (3) with an inlet (11) of the second vessel (5) for transporting the biomass material from the first vessel to the second vessel; and a valve (15; 15′; 15) arranged in said transporting pipe (7), said valve being configured for controlling the flow of biomass material and fluid in the transporting pipe (7), wherein said transporting pipe (7) is asymmetrically connected to an outlet (33′; 33) of said valve (15; 15′; 15) such that a generated jet stream of biomass material delivered out from the outlet (33′; 33) of the valve (15; 15′; 15) is received closer to a transporting pipe longitudinal central axis (A1) than if the outlet (33′; 33) of the valve (15; 15′; 15) and the transporting pipe (7) would have been connected symmetrically.

A bulk HPP container (10) includes a flexible body portion (12) having closed off ends (14), at least one of which is depicted as being recessed to enable the containers (10) to be positioned end-to-end in an efficient manner, for example, when placed into an HPP pressure vessel, such as a wire wound vessel. One or more openings are provided in the body portion of the container with n appropriate closure for pumpable product to enter and exit the container. In this regard, an inlet valve (16) or other type of closure may be located at the opening in one or both of the ends of the container. Also, one or more outlet valves (18) or other type of closure are located at an opening on the body portion (12) of the container for emptying the container, for example, after HPP. The body portion 12) is composed of sufficient flexural strength and sufficient flexural modulus to enable the container to reduce in volume by from 0 to at least 30% while being rigid enough for reuse over a desired number of HPP cycles.

Examples of a device for gettering and surface conditioning are disclosed. The device comprises an elongated tube with a closed first end, a second end and a body extending between the first end and the second end. The body defines an inner cavity of the tube in which a heating device is inserted. The tube is inserted into a vessel so that the first end is positioned within the vessel. A solid metal is mounted closely to the tube in a region surrounding the heating device and a meshed screen is mounted over the solid metal and secured to the tube. When the heating device is on, the heat transfers through the tube's wall into the solid metal melting and vaporizing it, so that the metal vapors travel and coat onto vessel's surfaces. The device can also be used in producing metal alloys such as lead lithium alloys.

A CVD or PVD coating device comprises a housing and a gas inlet organ secured to the housing via a retaining device, the gas inlet organ having a gas outlet surface with gas outlet openings. The retaining device is only secured at its horizontal edge to the housing so as to stabilize the retaining device with respect to deformations and temperature. The gas inlet organ is secured, at a plurality of suspension points, to the retaining device by means of a plurality of hanging elements distributed over the entire horizontal surface of the retaining device. The retaining device has mechanical stabilization elements formed by a retaining frame having vertical walls that are interconnected at vertical connection lines. An actively cooled heat shield is situated between the retaining device and the gas inlet organ.

A CVD or PVD coating device comprises a housing and a gas inlet organ secured to the housing via a retaining device, the gas inlet organ having a gas outlet surface with gas outlet openings. The retaining device is only secured at its horizontal edge to the housing so as to stabilize the retaining device with respect to deformations and temperature. The gas inlet organ is secured, at a plurality of suspension points, to the retaining device by means of a plurality of hanging elements distributed over the entire horizontal surface of the retaining device. The retaining device has mechanical stabilization elements formed by a retaining frame having vertical walls that are interconnected at vertical connection lines. An actively cooled heat shield is situated between the retaining device and the gas inlet organ.

A vessel system for high-pressure reactions is disclosed. The system includes a plugged polymer cylinder reaction vessel with a pressure vent opening extending radially through the wall of the reaction vessel and a supporting frame into which the vessel is received. Complementing keying structure elements on the vessel and on the frame limit the orientation of the reaction vessel in the supporting frame and the radially extending vent opening to a defined single position.

A graphene manufacturing device using Joule heating includes: a chamber having a space provided therein so as to synthesize graphene; and a first roller portion and a second roller portion disposed inside the chamber to be spaced from each other such that same support a catalyst metal penetrating the interior of the chamber and are supplied with an electric current for graphene synthesis, thereby Joule-heating the catalyst metal. In order to compensate for a temperature deviation of the catalyst metal passing between the first roller portion and the second roller portion, a first area of the catalyst metal, which is close to the first roller portion, and a second area of the catalyst metal, which is close to the second roller portion, are disposed to have movement paths facing each other.

A device for synthesising and studying compounds under controlled temperatures and pressures includes: a body delimiting a vacuum chamber including temperature-regulation means and vacuum-application means, and having one or more viewing windows enabling the inside of the chamber to be observed from the outside; temperature-regulation means that are intended for regulating the temperature inside the vacuum chamber; and vacuum-application means that are intended for regulating the pressure in the vacuum chamber; wherein it includes, inside the vacuum chamber, a sealed structure delimiting a sealed chamber having one or more viewing window facing said one or more windows in said body, and at least one pipe that is in fluid communication firstly with the inside of said sealed chamber and secondly with an outlet that is made in the body and provided in order to be connected to one or more sources of gas for synthesising said compound or sample.