FAIR - Facility for Antiproton and Ion Research in Europe GmbH

FAIR Kapillarrohrleitungen für die lokale Kryoversorgung des SFRS

Electromagnetic steel material for the Super-FRS dipole magnets

Design, Development, engineering, manufacturing, shipment, installation and testing of an Anti-Cryostat set-up for application in magnetic field measurement of SIS100-Quadrupole Units at the magnet test facility at FAIR.

Design, Development, engineering, manufacturing, shipment, installation and testing of an Anti-Cryostat set-up for application in magnetic field measurement of SIS100-Quadrupole Units at the magnet test facility at FAIR.

The Plastic Scintillators detectors are part of the timing system of the Super-FRS. They will be used to provide the timing signals of the travelling ion beams. Being fast enough to allow for triggering, they will be used for performing in-beam (time) calibration of other Super-FRS detectors. Additionally, FMF2 and FHF1 systems will be used to provide measurements of the velocity of the ion/fragment beams on event-by-event basis, similarly as the ToF (Time of Flight) detectors. The Beam Diagnostic component Plastic Scintillators of the Super-FRS consists of 6 detector units and 1 spare unit. They are listed in Table 1. Their location along the Super-FRS is shown in Figure 1. Operating in vacuum (pressure p ? 1*10e-7 mbar) as start detectors at the stations (or focal planes) FPF2, FPF4 of the PS and FMF1, FMF2, FMF3, FHF1 of the MS, they provide the timing signals needed for triggering and calibrations, contributing to the identification of the slow-extracted Super-FRS ion beams. Each detector (drive) inside the Super-FRS vacuum chamber is vertically movable along the transversal beam cross section. The movement is conducted by pneumatic actuator on an installation flange. All detectors have to be handled from the top. While inserted they will provide the timing signals of the travelling ion beams. At FPF4 and FPF2 the design of the drive has to be compatible with the robot handling. Materials used for production must be radiation hard (e.g. cables, connectors), halogen free (e.g. cables), vacuum compatible (e.g. PMTs, cables, connectors).

The Plastic Scintillators detectors are part of the timing system of the Super-FRS. They will be used to provide the timing signals of the travelling ion beams. Being fast enough to allow for triggering, they will be used for performing in-beam (time) calibration of other Super-FRS detectors. Additionally, FMF2 and FHF1 systems will be used to provide measurements of the velocity of the ion/fragment beams on event-by-event basis, similarly as the ToF (Time of Flight) detectors. The Beam Diagnostic component Plastic Scintillators of the Super-FRS consists of 6 detector units and 1 spare unit. They are listed in Table 1. Their location along the Super-FRS is shown in Figure 1. Operating in vacuum (pressure p ? 1*10e-7 mbar) as start detectors at the stations (or focal planes) FPF2, FPF4 of the PS and FMF1, FMF2, FMF3, FHF1 of the MS, they provide the timing signals needed for triggering and calibrations, contributing to the identification of the slow-extracted Super-FRS ion beams. Each detector (drive) inside the Super-FRS vacuum chamber is vertically movable along the transversal beam cross section. The movement is conducted by pneumatic actuator on an installation flange. All detectors have to be handled from the top. While inserted they will provide the timing signals of the travelling ion beams. At FPF4 and FPF2 the design of the drive has to be compatible with the robot handling. Materials used for production must be radiation hard (e.g. cables, connectors), halogen free (e.g. cables), vacuum compatible (e.g. PMTs, cables, connectors).

Der Berater ist Mitglied der Joint Taskforce von supraleitenden Magneten in Zusammenarbeit mit dem CERN und berät in dieser Expertenrolle die Entscheidungsträger des Super-FRS bezüglich übergeordneter Fragen der Produktionsqualität und Lieferanten Strategie. Des Weiteren ist der Berater bei der Produktionsüberwachung des Lieferanten in Italien oder optional in Spanien zu mindestens 80% seiner Zeit vor Ort.

2 types of Gate Valve-Inflatable Bellow Structure + support frames, 3 pieces of each

Zu liefern, zu montieren und voll funktionsfähig in Betrieb zu nehmen ist ein elektronisches Schließsystem. Die elektronische Schließanlage (eSA) soll zur Erhöhung der Sicherheit beitragen und Folgekosten für Schlüsselverluste können reduziert/vermieden werden. Die elektronische Schließanlage reduziert darüber hinaus den bürokratischen Aufwand für die Schlüsselverwaltung. Aktuell verfügt GSI über eine mechanische Schließanlage mit ca. 5030 Schließzylindern. Durch den Neubau des FAIR Beschleunigerzentrums kommen noch einmal ca. 1500 Schließzylinder hinzu. Im Rahmen eines Gesamtkonzeptes wird ein elektronisches Schließsystem für den gesamten Campus eingeführt werden. Ein sehr kleiner Teil wird weiterhin über eine rein mechanische Schließanlage abgebildet. Das elektronische Schließsystem muss auch in Zukunft über die genannten 6530 Schließzylinder modular erweiterbar sein und eine flexible Anpassung an zukünftige Anforderungen ermöglichen. Erweiterungen müssen ohne Austausch der bestehenden Komponenten integriert werden können. Geben Sie dazu die maximale Anzahl an Schließungen und Schlüsseln/Transpondern an, die durch das angebotene System verwaltet werden können. Der Zugang auf den Campus und spezielle Schleusensteuerungen bleiben davon unberührt. Dafür wird das aktuelle Zutrittskontrollsystem mit passiven Legic-Prime-Karten fortgeführt.

The shielding concrete beams are needed as crucial infrastructure of the CBM Cave as they provide mounting positions for detectors and other infrastructure. They also act as cover for the electronics and control systems of the experiment and shield these components from high doses of radiation.

The shielding concrete beams are needed as crucial infrastructure of the CBM Cave as they provide mounting positions for detectors and other infrastructure. They also act as cover for the electronics and control systems of the experiment and shield these components from high doses of radiation.

External consulting services provided by a magnet expert

Development, production and delivery of specialised electronic software and few hardware for the control, data acquisition and monitoring of the accelerators. All these components need full software integration into the FAIR accelerator control system. Further, the services include upgrade of already existing operational systems. The services are expected to be delivered within a period of 24 months. For the construction of the first facility section of FAIR, special hardware and electronic components are required on the one hand, as well as support services for software integration into the accelerator's control system and beam diagnostic system. The hardware and software integration serves to ensure compatibility with the very complex and specific control system standards of the FAIR accelerator and is a main component of the scope of delivery. This includes the extension or development of so-called FESA classes with integrated LSA data supply by the accelerator control system as well as the connection to the campus-wide timing system based on a white-rabbit real-time network. In this context, special electronic and mechanical components are to be supplied, as well as programming and support services

In total two frames around a beam catcher chamber need to be filled. Each one contains about 100 plates of 100mm thickness. The shape must be cut to fit around a tube (d = 300mm) running inside the frame. There are around 14 different shapes. The total mass er frame is about 21 tons.

Expert in on-site production supervision for cryogenic systems, engineering and inspection of steel welds and brazings within large scale projects of research institutes. Support and forward-looking monitoring of suppliers on site in France throughout the entire course of the project. Monitoring of the production and Cryogenic Equipment. Advice and participation in the continuous optimization of processes and process organization.

SIS100 will be equipped with a halo collimation system to remove unwanted halo particles and catch systematic losses caused by the extraction process. It is required to protect sensitive accelerator components from unavoidable beam loss. Among other components, the halo collimation system consists of moveable collimator blocks. The movability is realized by stepper motor drives with linear guiding systems. This tender includes seven drive systems with collimator blocks and mounting system. The mounting system allows an active cooling of the collimator blocks.

The Plastic Scintillators detectors are part of the timing system of the Super-FRS. They will be used to provide the timing signals of the travelling ion beams. Being fast enough to allow for triggering, they will be used for performing in-beam (time) calibration of other Super-FRS detectors. Additionally, FMF2 and FHF1 systems will be used to provide measurements of the velocity of the ion/fragment beams on event-by-event basis, similarly as the ToF (Time of Flight) detectors. The Beam Diagnostic component Plastic Scintillators of the Super-FRS consists of 6 detector units and 1 spare unit. They are listed in Table 1. Their location along the Super-FRS is shown in Figure 1. Operating in vacuum (pressure p ? 1*10e-7 mbar) as start detectors at the stations (or focal planes) FPF2, FPF4 of the PS and FMF1, FMF2, FMF3, FHF1 of the MS, they provide the timing signals needed for triggering and calibrations, contributing to the identification of the slow-extracted Super-FRS ion beams. Each detector (drive) inside the Super-FRS vacuum chamber is vertically movable along the transversal beam cross section. The movement is conducted by pneumatic actuator on an installation flange. All detectors have to be handled from the top. While inserted they will provide the timing signals of the travelling ion beams. At FPF4 and FPF2 the design of the drive has to be compatible with the robot handling. Materials used for production must be radiation hard (e.g. cables, connectors), halogen free (e.g. cables), vacuum compatible (e.g. PMTs, cables, connectors).

At the GSI Helmholtz Centre for Heavy Ion Research, the international research facility FAIR (Facility for Antiproton and Ion Research) is under construction. The accelerator complex aims for the production of a wide spectrum of high-intensity primary ion beams for a diverse range of scientific research fields and applications. The spectrum covers proton up to Uranium beams with different energies and with time structures between 100 ns and tens of seconds.

Entwicklung und der Fertigung zweier schneller Halbleiter-Gapschalter auf Basis von Siliziumcarbid-Technologie (SiC), Ihr Einsatzgebiet ist das Kurzschließen von Hochfrequenzkavitäten in den Synchrotron- und Speicherringen bei GSI und FAIR für die Impedanzreduktion während des Strahlbetriebs mit hohen Intensitäten

A new international scientific research centre facility FAIR (Facility for Antiprotons and Ion Research) is under constructed next to the existing GSI Helmholtz Centre for Heavy Ion Research. FAIR will provide antiproton and ion beams of unprecedented intensity and quality. One of the essential parts of FAIR will be the Heavy Ion Synchrotron (SIS)100. High current Extraction Septa 2 and 3 magnets are components of the SIS100, which will be powered by 2 power converters. The current in the magnets must be ramped up to 13000 A with an absolute accuracy of 100 ppm. The maximum output voltage is of up to 100V. These power converters will be feed by 20kV supply system. In Table 4.1 of the Detailed Specification, ANNEX 3, the specified maximum available installation space for the power converters is to be understood as a preliminary guideline. Deviations from this requirement may be acceptable under certain circumstances and can be discussed during the negotiation phase, if necessary.