18 research outputs found
UPDATE ON THE JRA1 PROJECT RESULTS OF ELECTRO-POLISHING OF MULTI-CELL SUPER CONDUCTING RESONATORS
Abstract Under the contract RII3-CT-2003-506395 of the European Union improvement on the electro-polishing (EP) of multi cell resonators are made. Several methods to improve resonator performances are studied. Improvement of electrode shape, simulated by numerical computer codes and test set ups are presented. With respect to reproducible cavity performances and industrialization of the EP process, a study for quality control by acid management is started. An automated EP system is developed at INFN Legnaro / Italy and within the collaboration of Legnaro and DESY this automated steering will be integrated into the DESY EP facility. We will report on the status of the WP 5.2.2.and the progress of the transfer of the automated E
The Superconducting TESLA Cavities
The conceptional design of the proposed linear electron-positron collider
TESLA is based on 9-cell 1.3 GHz superconducting niobium cavities with an
accelerating gradient of Eacc >= 25 MV/m at a quality factor Q0 > 5E+9. The
design goal for the cavities of the TESLA Test Facility (TTF) linac was set to
the more moderate value of Eacc >= 15 MV/m. In a first series of 27
industrially produced TTF cavities the average gradient at Q0 = 5E+9 was
measured to be 20.1 +- 6.2 MV/m, excluding a few cavities suffering from
serious fabrication or material defects. In the second production of 24 TTF
cavities additional quality control measures were introduced, in particular an
eddy-current scan to eliminate niobium sheets with foreign material inclusions
and stringent prescriptions for carrying out the electron-beam welds. The
average gradient of these cavities at Q0 = 5E+9 amounts to 25.0 +- 3.2 MV/m
with the exception of one cavity suffering from a weld defect. Hence only a
moderate improvement in production and preparation techniques will be needed to
meet the ambitious TESLA goal with an adequate safety margin. In this paper we
present a detailed description of the design, fabrication and preparation of
the TESLA Test Facility cavities and their associated components and report on
cavity performance in test cryostats and with electron beam in the TTF linac.
The ongoing R&D towards higher gradients is briefly addressed.Comment: 45 pages (Latex), 39 figures (Encapsulated Postscript), 53 Author
Superconducting magnet package for the TESLA test facility
The magnetic lattice of the TeV electron superconducting linear accelerator (TESLA) will consist of superconducting quadrupoles for beam focusing and superconducting correction dipoles for beam steering, incorporated in the cryostats containing the superconducting cavities. This report describes the design of these magnets, presenting details of the magnetic as well as the mechanical design. The measured characteristics of the TESLA Test Facility (TTF) quadrupoles and dipoles are compared to the results obtained from numerical computations
Results of the Magnetic Measurements of the Superconducting Magnets for the European XFEL
A new linear accelerator, i.e., the European X-ray Free-Electron Laser (XFEL), is under construction at DESY in Hamburg. The construction started in early 2009, and the commissioning is planned for 2016. The design energy of the electron beam is 17.5 GeV (0.05-4.7 nm wavelength), and more than 27000 flashes/s are expected. The accelerator contains 102 cryomodules equipped with a string of eight superconducting RF cavities and one superconducting magnet package. Each magnet consists of two cos -θ-type correction dipoles, horizontal and vertical deflecting. They are glued onto the surface of the beam pipe and are surrounded by a superferric quadrupole magnet. The package is mounted inside of a compact stainless steel vessel with a length of 30 cm and a diameter of 20 cm. Each package and current lead assembly was tested separately at room temperature and together at 2 K in a dedicated superfluid helium cryostat at DESY. A summary of the results is reported here. During the cold test, special emphasis was given to hysteresis and persistent current effects, as the operating current varies from very low currents at the beginning of the accelerator to the full design current 50 A at the end
The superconducting TESLA cavities Dedicated to the memory of Bjoern H. Wiik
The conceptional design of the proposed linear electron-positron collider TESLA is based on 9-cell 1.3 GHz superconducting niobium cavities with an accelerating gradient of E_a_c_c #>=# 25 MV/m at a quality factor Q_0 #>=# 5 . 10"9. The design goal for the cavities of the TESLA test facility (TTF) linac was set to the more moderate value of E_a_c_c #>=# 15 MV/m. In a first series of 27 industrially produced TTF cavities the average gradient at Q_0 = 5 . 10"9 was measured to be 20.1 #+-# 6.2 MV/m, excluding a few cavities suffering from serious fabrication or material defects. In the second production of 24 TTF cavities additional quality control measures were introduced, in particular an eddy-current scan to eliminate niobium sheets with foreign material inclusions and stringent prescriptions for carrying out the electron-beam welds. The average gradient of these cavities at Q_0 = 5.10"9 amounts to 25.0#+-#3.2 MV/m with the exception of one cavity suffering from a weld defect. Hence only a moderate improvement in production and preparation techniques will be needed to meet the ambitious TESLA goal with an adequate safety margin. In this paper we present a detailed description of the design, fabrication and preparation of the TESLA test facility cavities and their associated components and report on cavity performance in test cryostats and with electron beam in the TTF linac. The ongoing R and D towards higher gradients is briefly addressed. (orig.)47 refs.SIGLEAvailable from TIB Hannover: RA 2999(00-031) / FIZ - Fachinformationszzentrum Karlsruhe / TIB - Technische InformationsbibliothekDEGerman