Keyword: vacuum
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TUPDP009 Mobile Pumping Units for Particle Free Beam Vacuum controls, cryomodule, interface, PLC 494
 
  • T.J. Joannem, S. Berry
    CEA-DRF-IRFU, France
  • Q. Bertrand, C. Boulch, G. Monnereau
    CEA-IRFU, Gif-sur-Yvette, France
 
  For 10 years our Institute CEA Saclay Irfu has been involved in several in-kind collaboration contracts with ESS at Lund (Sweden) and one of these includes the test of numerous cryomodules in a dedicated test bench designed at Saclay. The cryomodules start to be assembled cavity per cavity in a clean room and must be low pressure pumped, without adding particles and always in a clean room. This is the purpose of the mobile pumping units for particle free beam vacuum. These units are also designed for vacuum automatic procedures, residual gas analysis and can provide conformity reports. Furthermore, a connectable industrial touch panel is added for a mobile operator interface. Only few buttons have to be panel touched by an operator to start automatic procedures in order to get a very high quality vacuum. The embedded control system is PLC based and manages many communications, especially with the spectrometer embedded in the unit. Only one CPU manages all the communications (Profinet, Profibus, TCP-IP ASCII and even Modbus) and sensors or actuators are controlled by four input-output cards. This small-scale control system is innovative because it is versatile, very convenient to use, deploy and maintain. Nine mobile pumping units are operational and continuously used, frequently moved to different locations, controlled locally or remotely and are still reliable. The paper describes the control architecture and functionalities of this small but full of possibilities device.  
poster icon Poster TUPDP009 [2.568 MB]  
DOI • reference for this paper ※ doi:10.18429/JACoW-ICALEPCS2023-TUPDP009  
About • Received ※ 29 September 2023 — Revised ※ 11 October 2023 — Accepted ※ 09 December 2023 — Issued ※ 15 December 2023
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TUPDP032 Reference Measurement Methods for Planar and Helical Undulators undulator, FEL, radiation, electron 575
 
  • S. Karabekyan
    EuXFEL, Schenefeld, Germany
 
  The modern permanent magnet undulators are usually equipped with motors that have integrated feedback electronics. These are essentially rotary encoders that indicate the position of the motor axis. In addition, undulators are also equipped with linear encoders that provide the absolute value of the gap between the magnetic structures or the position of the magnetic girders relative to the undulator frame. The operating conditions of undulators should take into account the risks of failure of electronic equipment under the influence of radiation. In case of encoder failure, the motor or encoder must be replaced. To avoid the need to return the undulator to the magnetic measurement laboratory, reference measurements are required to restore the position of the magnetic structure after replacement. In this article, reference measurement procedures for planar and helical APPLE-X undulators used at the European XFEL are presented.  
poster icon Poster TUPDP032 [1.358 MB]  
DOI • reference for this paper ※ doi:10.18429/JACoW-ICALEPCS2023-TUPDP032  
About • Received ※ 06 October 2023 — Revised ※ 10 October 2023 — Accepted ※ 14 December 2023 — Issued ※ 17 December 2023
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TUPDP038 Status of Vacuum Control System Upgrade of ALPI Accelerator controls, PLC, EPICS, interface 595
 
  • L. Antoniazzi, A. Conte, C.R. Roncolato, G. Savarese
    INFN/LNL, Legnaro (PD), Italy
 
  The vacuum system of ALPI (Acceleratore Lineare Per Ioni) accelerator at LNL (Laboratori Nazionali di Legnaro), including around 40 pumping groups, was installed in the 90s. The control and supervision systems, composed by about 14 control racks, were developed in the same period by an external company, which produced custom solutions for the HW and SW parts. Control devices are based on custom PLCs, while the supervision system is developed in C and C#. The communication network is composed of multiple levels from serial standard to Ethernet passing true different devices to collect the data. The obsolescence of the hardware, the rigid system infrastructure, the deficit of spares parts and the lack of external support, impose a complete renovation of the vacuum system and relative controls. In 2022 the legacy high level control system part was substituted with a new one developed in EPICS (Experimental Physics and Industrial Control System) and CSS (Control System Studio)*. After that, we started the renovation of the HW part with the installation and integration of two new flexible and configurable low level control system racks running on a Siemens PLC and exploiting serial server to control the renewed pumping groups and pressure gauges. The plan for the next years is to replace the legacy hardware with new one retrieving spare parts, provide service continuity, improve PLC software and extend the EPICS control system with new features. This paper describes the adopted strategy and the upgrade status.
* G. Savarese et al., Vacuum Control System Upgrade for ALPI
accelerator, in Proc. IPAC-22, Bangkok, Thailand, doi:10.18429/JACoW-IPAC2022-MOPOMS045
 
poster icon Poster TUPDP038 [3.286 MB]  
DOI • reference for this paper ※ doi:10.18429/JACoW-ICALEPCS2023-TUPDP038  
About • Received ※ 04 October 2023 — Accepted ※ 11 December 2023 — Issued ※ 17 December 2023  
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TUPDP080 Automated Procedure for Conditioning of Normal Conducting Accelerator Cavities cavity, controls, DTL, linac 699
 
  • E. Trachanas, G.S. Fedel, S. Haghtalab, B. Jones, R.H. Zeng
    ESS, Lund, Sweden
  • C. Baltador, L. Bellan, F. Grespan
    INFN/LNL, Legnaro (PD), Italy
  • A. Gaget, O. Piquet
    CEA-DRF-IRFU, France
 
  Radio frequency (RF) conditioning is an essential stage during the preparation of particle accelerator cavities for operation. During this process the cavity field is gradually increased to the nominal parameters enabling the outgassing of the cavity and the elimination of surface defects through electrical arcing. However, this process can be time-consuming and labor-intensive, requiring skilled operators to carefully adjust the RF parameters. This proceeding presents the software tools for the development of an automatized EPICS control application with the aim to accelerate and introduce flexibility to the conditioning process. The results from the conditioning process of the ESS Radio-Frequency Quadrupole (RFQ) and the parallel conditioning of Drift-Tube Linac (DTL) tanks will be presented demonstrating the potential to save considerable time and resources in future RF conditioning campaigns.  
poster icon Poster TUPDP080 [17.411 MB]  
DOI • reference for this paper ※ doi:10.18429/JACoW-ICALEPCS2023-TUPDP080  
About • Received ※ 04 October 2023 — Accepted ※ 12 December 2023 — Issued ※ 13 December 2023  
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TUPDP098 Automatic Conditioning of High Voltage Pulsed Magnets kicker, controls, PLC, simulation 780
 
  • C.A. Lolliot, M.J. Barnes, N. Magnin, S. Pavis, P. Van Trappen
    CERN, Meyrin, Switzerland
  • C. Monier
    INSA Lyon, Villeurbanne, France
 
  Fast pulsed kicker magnets are used across the various accelerators of CERN complex to inject and extract the beam. These kicker magnets, powered by high voltage pulsed generators and under vacuum, are prone to electrical breakdown during the pulse. To prepare the kicker magnet for reliable operation, or in case an electrical breakdown occurred, a conditioning is necessary: the magnet is pulsed gradually increasing the pulse voltage and length up to a value beyond operational conditions. This is a lengthy process that requires kicker experts on site to manually control the pulse voltage and length, and monitor the vacuum activity. For the start of LHC operation, a first automatic conditioning system was deployed on injection kicker magnet (MKI). Configurable voltage and pulse length ramps are automatically performed by the controller. In case abnormal vacuum activity occurs, the voltage is reduced and then the process continues. Based on this experience, a standardised algorithm has been developed, adding new features such as logarithmic ramp, or simulation of the whole conditioning cycle with test of reaction to vacuum activity. This new automatic conditioning system was deployed on several kicker systems across various CERN accelerators, allowing smoother conditioning, and great reduction on manpower. It also offers the possibility for further automate kicker system operation, starting automatically a magnet conditioning when needed without intervention of kickers experts, similarly as what was deployed for SPS Beam Dump System.  
poster icon Poster TUPDP098 [0.328 MB]  
DOI • reference for this paper ※ doi:10.18429/JACoW-ICALEPCS2023-TUPDP098  
About • Received ※ 06 October 2023 — Revised ※ 21 October 2023 — Accepted ※ 05 December 2023 — Issued ※ 17 December 2023
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TUSDSC04 State Machine Operation of Complex Systems operation, linac, cryomodule, controls 929
 
  • P.M. Hanlet
    Fermilab, Batavia, Illinois, USA
 
  Operation of complex systems which depend on one or more other systems with many process variables often operate in more than one state. For each state there may be a variety of parameters of interest, and for each of these, one may require different alarm limits, different archiving needs, and have different critical parameters. Relying on operators to reliably change 10s-1000s of parameters for each system for each state is unreasonable. Not changing these parameters results in alarms being ignored or disabled, critical changes missed, and/or possible data archiving problems. To reliably manage the operation of complex systems, such as cryomodules (CMs), Fermilab is implementing state machines for each CM and an over-arching state machine for the PIP-II superconducting linac (SCL). The state machine transitions and operating parameters are stored/restored to/from a configuration database. Proper implementation of the state machines will not only ensure safe and reliable operation of the CMs, but will help ensure reliable data quality. A description of PIP-II SCL, details of the state machines, and lessons learned from limited use of the state machines in recent CM testing will be discussed.  
slides icon Slides TUSDSC04 [6.117 MB]  
poster icon Poster TUSDSC04 [1.031 MB]  
DOI • reference for this paper ※ doi:10.18429/JACoW-ICALEPCS2023-TUSDSC04  
About • Received ※ 06 October 2023 — Revised ※ 23 October 2023 — Accepted ※ 11 December 2023 — Issued ※ 17 December 2023
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WE1BCO04 The LCLS-II Experiment System Vacuum Controls Architecture controls, interface, experiment, EPICS 962
 
  • M. Ghaly, T.A. Wallace
    SLAC, Menlo Park, California, USA
 
  Funding: This work is supported by Department of Energy contract DE-AC02-76SF00515.
The LCLS-II Experiment System Vacuum Controls Architecture is a collection of vacuum system design templates, interlock logics, supported components (eg. gauges, pumps, valves), interface I/O, and associated software libraries which implement a baseline functionality and simulation. The architecture also includes a complement of engineering and deployment tools including cable test boxes or hardware simulators, as well as some automatic configuration tools. Vacuum controls at LCLS spans from rough vacuum in complex pumping manifolds, protection of highly-sensitive x-ray optics using fast shutters, maintenance of ultra-high vacuum in experimental sample delivery setups, and beyond. Often, the vacuum standards for LCLS systems exceeds what most vendors are experienced with. The system must maintain high-availability, while also remaining flexible and handling ongoing modifications. This paper will review the comprehensive architecture, the requirements of the LCLS systems, and introduce how to use it for new vacuum system designs. The architecture is meant to influence all phases of a vacuum system lifecycle, and ideally could become a shared project for installations beyond LCLS-II.
 
slides icon Slides WE1BCO04 [3.154 MB]  
DOI • reference for this paper ※ doi:10.18429/JACoW-ICALEPCS2023-WE1BCO04  
About • Received ※ 31 October 2023 — Revised ※ 20 November 2023 — Accepted ※ 08 December 2023 — Issued ※ 12 December 2023
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TH2BCO01 Synchronized Nonlinear Motion Trajectories at MAX IV Beamlines detector, controls, target, synchrotron 1160
 
  • P. Sjöblom, H. Enquist, A. Freitas, J. Lidón-Simon, M. Lindberg, S. Malki
    MAX IV Laboratory, Lund University, Lund, Sweden
 
  The motions at beamlines sometimes require components to move along non-trivial and non-linear paths. This type of motion can be achieved by combining several simple axes, typically linear and rotation actuators, and controlling them to perform synchronized motions along individual non-linear paths. A good example is the 10-meter-long spectrometer at MAX IV Veritas beamline, operating under the Rowland condition. The system consists of 6 linked axes that must maintain the position of detectors while avoiding causing any damage to the mechanical structure. The nonlinear motions are constructed as a trajectory through energy or focus space. The trajectory changes whenever any parameter changes or when moving through focus space at fixed energy instead of through energy space. Such changes result in automated generation and uploading of new trajectories. The motion control is based on parametric trajectory functionality provided by IcePAP. Scanning and data acquisition are orchestrated through Tango and Sardana to ensure full motion synchronization and that triggers are issued correctly.  
slides icon Slides TH2BCO01 [0.884 MB]  
DOI • reference for this paper ※ doi:10.18429/JACoW-ICALEPCS2023-TH2BCO01  
About • Received ※ 05 October 2023 — Revised ※ 24 October 2023 — Accepted ※ 14 December 2023 — Issued ※ 22 December 2023
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TH2BCO03 The LCLS-II Experiment Control System controls, EPICS, PLC, experiment 1172
 
  • T.A. Wallace, D.L. Flath, M. Ghaly, T.K. Johnson, K.R. Lauer, Z.L. Lentz, R.S. Tang-Kong, J. Yin
    SLAC, Menlo Park, California, USA
 
  Funding: Work supported by the U.S. Department of Energy under contract number DE-AC02-76SF00515.
The Linac Coherent Light Source (LCLS) has been undergoing upgrades for several years now through at least two separate major projects: LCLS-II a DOE 403.13b project responsible for upgrading the accelerator, undulators and some front-end beam delivery systems, and the LCLS-II Strategic Initiative or L2SI project which assumed responsibility for upgrading the experiment endstations to fully utilize the new XFEL machine capabilities to be delivered by LCLS-II. Both projects included scope to design, install and commission a control system prepared to handle the risks associated with the tenfold increase in beam power we will eventually achieve. This paper provides an overview of the new control system architecture from the LCLS-II and L2SI projects and status of its commissioning.
 
slides icon Slides TH2BCO03 [2.700 MB]  
DOI • reference for this paper ※ doi:10.18429/JACoW-ICALEPCS2023-TH2BCO03  
About • Received ※ 04 November 2023 — Accepted ※ 11 December 2023 — Issued ※ 16 December 2023  
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THPDP086 LCLS-II Cryomodule Isolation Vacuum Pump System controls, PLC, cryomodule, operation 1551
 
  • S.C. Alverson, D.K. Gill, S. Saraf
    SLAC, Menlo Park, California, USA
 
  Funding: Work supported by the U.S. Department of Energy under contract number DE-AC02-76SF00515
The LCLS-II Project at SLAC National Accelerator is a major upgrade to the lab’s Free Electron Laser (FEL) facility adding a new injector and superconducting linac. In order to support this new linac, a vacuum pumping scheme was needed to isolate the liquid helium lines cooling the RF cavities inside the cryomodules from outside ambient heat as well as to exhaust any leaking helium gas. Carts were built with support for both roughing and high vacuum pumps and read back diagnostics. Additionally, a Programmable Logic Controller (PLC) was then configured to automate the pump down sequence and provide interlocks in the case of a vacuum burst. The design was made modular such that it can be manually relocated easily to other sections of the linac if needed depending on vacuum conditions.
* https://lcls.slac.stanford.edu/lcls-ii
 
poster icon Poster THPDP086 [18.556 MB]  
DOI • reference for this paper ※ doi:10.18429/JACoW-ICALEPCS2023-THPDP086  
About • Received ※ 03 October 2023 — Revised ※ 27 October 2023 — Accepted ※ 06 December 2023 — Issued ※ 15 December 2023
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THPDP090 LCLS-II Accelerator Vacuum Control System Design, Installation and Checkout controls, PLC, status, interface 1564
 
  • S. Saraf, S.C. Alverson, S. Karimian, C. Lai, S. Nguyen
    SLAC, Menlo Park, California, USA
 
  Funding: Work supported by the U.S. Department of Energy under contract number DE-AC02-76SF00515
The LCLS-II Project at SLAC National Accelerator Laboratory has constructed a new superconducting accelerator which occupies the first kilometer of SLAC’s original 2-mile-long linear accelerator tunnel. The LCLS-II Vacuum System consists of a combination of particle free(PF) and non-particle free vacuum(non-PF) areas and multiple independent and interdependent systems, including the beamline vacuum, RF system vacuum, cryogenic system vacuum and support systems vacuum. The Vacuum Control System incorporates controls and monitoring of a variety of gauges, pumps, valves and Hiden RGAs. The design uses a Programmable Logic Controller (PLC) to perform valve interlocking functions to isolate bad vacuum areas. In PF areas, a voting scheme has been implemented for slow and fast shutter interlock logic to prevent spurious trips. Additional auxiliary control functions and high-level monitoring of vacuum components is reported to global control system via an Experimental Physics and Industrial Control System (EPICS) input output controller (IOC). This paper will discuss the design as well as the phased approach to installation and successful checkout of LCLS-II Vacuum Control System.
https://lcls.slac.stanford.edu/lcls-ii
 
poster icon Poster THPDP090 [1.787 MB]  
DOI • reference for this paper ※ doi:10.18429/JACoW-ICALEPCS2023-THPDP090  
About • Received ※ 06 October 2023 — Revised ※ 10 October 2023 — Accepted ※ 19 December 2023 — Issued ※ 21 December 2023
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