Specification Changes of 316 LN ESR after Higher Temperature Procedure - Vacuum Firing and Vacuum Brazing

316 LN ESR unlimited material

Translation from 3D Simulations to Realization

• Requirements • Design with Simulations • Prototyping and Measurements • Selection of Companies • Series Production and Quality Tests • Summary --- Example with Beam Positions Monitors (BPMs) focused on mechanical aspect

BPMs From Design to Real Measurement

Beam Position Monitors (BPM) are an essential tool for the operation of an accelerator. Therefore BPM systems have to be already included from the beginning in the design of a new machine. This contribution describes the development of a new BPM system up to the operation with a focus on the mechanical design. It includes the collection of the requirements and boundary conditions which defines the kind of BPM system. Following the mechanical designing process is described where simulations are used to predict the signals. These results are input parameters for the design and optimization of the electronics. Several contributions are considered which can modify the BPM signal like feedhroughs, heating due to wake losses, holders, cables and so on. The steps from the design, the prototypes and series production including laboratory and test accelerator measurements up to the commissioning are described as well

Using of New Sealing Technology for High Precision Wide Open Vacuum Flanges and Waveguide Connections

What have long-playing records for music and the large rectangle flanges of the BPMS- and the OTRS-Flanges at DESY in common

Production of Cavity Beam Position Monitors for the ARES Accelerator at DESY

The SINBAD facility (Short and INnovative Bunches and Accelerators at DESY) hosts various experiments in the field of production of ultra-short electron bunches and novel high gradient acceleration techniques. The SINBAD facility, also called ARES (Accelerator Research Experiment at SINBAD), is a conventional S-band linear RF accelerator allowing the production of low charge ultra-short electron bunches within a range between 0.5 pC and 1000 pC. The positions of the low charge bunches will be detected by cavity beam position monitors. The principal design is based on the experience from the EU-XFEL cavity beam position monitors. It consists of a 316 LN stainless steel body with a design loaded quality factor of 70, a resonance frequency of 3.3 GHz and a relative wide gap of 15 mm to reach a high peak position sensitivity of 4.25 V/(nC mm). This poster covered, the manufacture of the individual mechanical parts, as well as presents the special features in the manufacture of customer designed UHV feedthroughs

A New Sealing Technology for High Precision Wide Open UHV Vacuum lange and Waveguide Connections with Metal Gaskets

The European-XFEL X-Ray laser facility is located in Hamburg. Since its commissioning in September 2017, this large X-ray laser opens new research opportunities for industrial users and scientists. For many beam diag-nostic devices ultra-high vacuum components with high mechanical precision and additional strict requirements on particle cleanliness were produced. A vacuum chamber for the bunch compressor (BC) with a cross section of 400 mm*40.5 mm made of stainless steel blocks 1.4429 (316 LN) has been installed. These chambers have inte-grated flange-connections for large VATSEAL® gaskets. The tolerances for these flanges are extremely tight to ensure save vacuum tight sealing.This contribution will report of a new technology for such large rectangular or other large flange surfaces. Furthermore this contribution will compare the present with this new technology. This new technology can be used as well for other vacuum flange metals like alumini-um or titanium. Using of this technology for applications under special conditions, like particle free applications due to the non-lubricated conditions, are conceivable

Test Methodology and First Evaluation of PETRA IV Button-Type BPM Prototypes

General overview. RF measurements. BPMs as part of diagnostic syste

Design of a Cavity Beam Position Monitor for the ARES Accelerator at DESY

The SINBAD facility (Short and INnovative Bunchesand Accelerators at DESY) is foreseen to host various experiments in the field of production of ultra-short electron bunches and novel high gradient acceleration techniques.The SINBAD linac, also called ARES (Accelerator ResearchExperiment at SINBAD), will be a conventional Sband linear RF accelerator allowing the production of low charge (within a range between 0.5 pC and 1000 pC) electron bunches. To detect the position of low charge bunches, a cavity beam position monitor is being designed based on the experience from the European XFEL. It will consist of a stainless steel body with a quality factor of 70, a resonance frequency of 3.3 GHz and a relative wide gap of 15mmto reach a high position sensitivity of 4.25 V/(nC mm) of the dipole resonator. The design considerations and simulation results of the dipole and reference resonator will be presented