Apparatus for compressing cryogenic fluid in at least one compression stage comprising at least one piston and at least one sleeve delimiting at least one compression chamber, a shaft that is able to move in translation along a longitudinal axis (A), the shaft being connected to the piston(s) or sleeve(s) and being able to move with an alternating movement in two opposite directions to ensure phases of compression and intake of fluid into the at least one compression chamber by moving the at least one piston and the at least one sleeve in a relative manner, characterized in that the shaft comprises a portion of reduced cross section in the longitudinal direction (A), said portion of reduced cross section separating two adjacent parts of the shaft, the shaft also comprising at least one linking element made of material that is less thermally conductive than the constituent material of the shaft, in particular a composite material, said at least one linking element having two ends connected respectively to the two adjacent parts of the shaft.

A cryopump includes a cryopump including: a refrigerator; a first cryopanel including a radiation shield; and a second cryopanel enclosed by the first cryopanel and cooled to a lower temperature than that of the first cryopanel. The radiation shield includes an attaching pedestal located lateral to the second cryopanel for attachment of the refrigerator to the radiation shield, and a shield portion adjacent to the attaching pedestal and enclosing the second cryopanel. A lateral gap is formed between the second cryopanel and the attaching pedestal. A gap part continuing into the lateral gap is formed between the second cryopanel and the shield portion. The second cryopanel is shaped and/or located such that the lateral gap is comparable in width to the gap part.

A cryopump includes a cryopump including: a refrigerator; a first cryopanel including a radiation shield; and a second cryopanel enclosed by the first cryopanel and cooled to a lower temperature than that of the first cryopanel. The radiation shield includes an attaching pedestal located lateral to the second cryopanel for attachment of the refrigerator to the radiation shield, and a shield portion adjacent to the attaching pedestal and enclosing the second cryopanel. A lateral gap is formed between the second cryopanel and the attaching pedestal. A gap part continuing into the lateral gap is formed between the second cryopanel and the shield portion. The second cryopanel is shaped and/or located such that the lateral gap is comparable in width to the gap part.

An end closure for a superconductive electric cable which has at least one superconductive conductor which is surrounded by a tubular cryostat serving for conducting a cooling agent, which at its end is surrounded by a housing. The housing (G) has two walls (7, 8) which are separated from each other by an intermediate space (9) and having insulating material, wherein a thermal insulation containing gas is placed in the intermediate space. The pressure in the intermediate space (9) of the housing (G) is adjusted to a value of between 10.sup.9 mbar and 1000 mbar and, connected to the intermediate space (9) are a pressure measuring device (12) and a vacuum pump (11) which serve for adjusting the pressure prevailing in the intermediate space (9) of the housing (G).

Systems and methods that facilitate forming and maintaining FRCs with superior stability as well as particle, energy and flux confinement and, more particularly, systems and methods that facilitate forming and maintaining FRCs with elevated system energies and improved sustainment utilizing multi-scaled capture type vacuum pumping.

A GM cryocooler includes a first cold head including a first displacer that is reciprocable in an axial direction, a first drive piston that drives the first displacer in the axial direction, and a first drive chamber that houses the first drive piston; a second cold head including a second displacer that is reciprocable in the axial direction, and a second cylinder that houses the second displacer; a first intake valve that is connected to both the first drive chamber and the second cylinder so as to supply working gas in parallel to the first drive chamber and the second cylinder; and a first exhaust valve that is connected to both the first drive chamber and the second cylinder so as to collect the working gas in parallel from the first drive chamber and the second cylinder.

Systems and methods that facilitate forming and maintaining FRCs with superior stability as well as particle, energy and flux confinement and, more particularly, systems and methods that facilitate forming and maintaining FRCs with elevated system energies and improved sustainment utilizing neutral beam injectors with tunable beam energy capabilities.

A cryopump system includes a cryopump, and a regeneration control unit that controls the cryopump according to a regeneration sequence including a discharge process of rough pumping the cryopump to discharge condensate from it. The regeneration control unit includes a pressure drop rate computation unit that computes a pressure drop rate for the cryopump during the rough pumping of the cryopump, and a pressure drop rate monitoring unit that detects diminishment in the pressure drop rate during the rough pumping.

A cryopump system includes a cryopump, and a regeneration control unit that controls the cryopump according to a regeneration sequence including a discharge process of rough pumping the cryopump to discharge condensate from it. The regeneration control unit includes a pressure drop rate computation unit that computes a pressure drop rate for the cryopump during the rough pumping of the cryopump, and a pressure drop rate monitoring unit that detects diminishment in the pressure drop rate during the rough pumping.

The disclosure describes various aspects of a vibrationally isolated cryogenic shield for local high-quality vacuum. More specifically, the disclosure describes a cryogenic vacuum system replicated in a small volume in a mostly room temperature ultra-high vacuum (UHV) system by capping the volume with a suspended cryogenic cold finger coated with a high surface area sorption material to produce a localized extreme high vacuum (XHV) or near-XHV region. The system is designed to ensure that all paths from outgassing materials to the control volume, including multiple bounce paths off other warm surfaces, require at least one bounce off of the high surface area sorption material on the cold finger. The outgassing materials can therefore be pumped before reaching the control volume. To minimize vibrations, the cold finger is only loosely, mechanically connected to the rest of the chamber, and the isolated along with the cryogenic system via soft vacuum bellows.