A pumping system, method and device for pumping from and to any two or more vessels in a multiple vessel process where all permutations of the source and destination vessels are possible, but only specific combinations are required as part of the regular, repeat, controlled process system.

The present invention pertains to a device for controlling a medical gas flow from a cylinder, wherein the device is configured to be releasably attachable to a gas cylinder and wherein the device is capable of identifying a gas cylinder in order to control the opening and closing of a valve comprised in the valve. Accordingly, the device comprises a valve for controlling a gas flow from a gas cylinder, a gas outlet, which is in fluid communication with said valve and positioned downstream of said valve, and a connecting means configured for receiving and releasably connecting a cylinder for providing a fluid connection between a cylinder and said valve. The device furthermore comprises an identifying means for identifying a cylinder, wherein the valve is in communication with the identifying means and is configured to be openable based on the identification of the cylinder.

A plurality of sensors detect a plurality of fuel temperatures at a filling station, and a controller communicates with the sensors to identify the fuel temperatures, uses the fuel temperatures to determine a plurality of candidate fill times, and compares the candidate fill times to identify a control value for controlling a delivery of fuel. The fuel temperatures include a first fuel temperature corresponding to a first location at the filling station and a second fuel temperature corresponding to a second location at the filling station, and the candidate fill times include a first candidate fill time corresponding to the first fuel temperature and a second candidate fill time corresponding to the second fuel temperature.

The invention relates to a method and a magnetoencephalography (MEG) measurement device. In the method there is determined the ending of a scheduled inactivity period of the MEG device. At the ending of the inactivity period a cryocooler of the MEG device is switched off. Helium is allowed to boil in the Dewar vessel of the MEG device when the MEG device is active and used to perform patient measurements. The boiled helium is collected via a compressor to an external storage tank. When a new inactivity period for the MEG device commences, the cryocooler is started anew and helium is let from the external storage tank in-to the Dewar vessel, where it is re-liquefied by the cryocooler. The compressor may be switched off when the cryocooler is switched on.

A pumping system, method and device for pumping from and to any two or more vessels in a multiple vessel process where all permutations of the source and destination vessels are possible, but only specific combinations are required as part of the regular, repeat, controlled process system.

A gas supply device includes a compressor for compressing gas, an in-flow side flow passage having a buffer tank for storing the gas and linked to the compressor, an in-flow side on-off valve for opening and closing the in-flow side flow passage on an portion of the in-flow side flow passage upstream of the buffer tank, an out-flow side flow passage linked to a discharge side of the compressor, and a control unit for executing a control to close the in-flow side on-off valve upon receipt of a stop signal for the compressor.

A method of temperature control in a cryogenic temperature control apparatus. The method includes operating the cryogenic temperature control apparatus in a first mode, and delivering a first flow rate of cryogen from a storage tank to an evaporator coil in the first mode. The cryogenic temperature control apparatus is operated in a second mode after operating the cryogenic temperature control apparatus in the first mode for a predetermined time duration. A second flow rate of cryogen that is lower than the first flow rate is delivered to the evaporator coil in the second mode.

A control unit for a pressure container system comprising at least one pressure container with a pressure container valve designed to conduct fuel from the pressure container into a removal line for supplying an energy converter. The control unit is designed to determine that a fueling procedure of the pressure container is occurring or has occurred. In response thereto, the control unit is additionally designed to cause the pressure container valve to open in a pulsed manner temporally prior to a removal request for fuel for operating the energy converter so that the pressure in the removal line approximates the pressure in the pressure container.

The invention relates to a system for providing a fluid, comprising at least a first and a second cryogenic container for storing the fluid, wherein the system comprises a first retrieval line connecting to the first cryogenic container for retrieving a first mass flow (M1) of fluid and a second retrieval line connecting to the second cryogenic container for retrieving a second mass flow (M2) of fluid, wherein the system comprises means, which are configured to establish two mass flows (M1, M2) of different dimensions such that in a first operational mode a hold time of the two cryogenic containers converges upon retrieval and/or in a second operational mode the hold time of the two cryogenic containers essentially decreases at the same rate if the hold times of the two cryogenic containers are essentially equal.