HIGH RADIATION TO MATERIALS: EXPERIMENTAL AREA DESIGN Ans Pardons HiRadMat review, 26 th of May 2011 Outline  Location of experimental area & services.

Slides:

Advertisements

Similar presentations

HIGH RADIATION TO MATERIALS WG3 – E XPERIMENTAL A REA HiRadMat project Team Meeting 03/0/2011 T9 transformation Repeatability test of experimental area.

Advertisements

Brio 2000 / Brio 2000-M E-Learning Service Manual Rev. 0.0.

André Augustinus 16 June 2003 DCS Workshop Safety.

CERN TS Department / Civil Engineering Group 8 February 2008 Civil Engineering Layouts & Tunnel Cross Section 1 CLIC/ILC Collaboration Meeting 8 Feb 2008.

NUMI NuMI Hot Handling Jim Hylen (FNAL) NBI02 March 13, 2002 Page 1 NuMI Target Hall Radioactive Component Handling NuMI Target Hall Utilizes Three Basic.

HIRADMAT IN THE WANF TUNNEL I. E FTHYMIOPOULOS, EN/MEF  HIRADMAT-Exp.Area Working Group  EN/MEF : I. Efthymiopoulos, A. Pardons, M.Lazzaroni, N. Gilbert.

RD51 Common Test Beam: Status RD51 collaboration week Kolymbari, June 2009 Yorgos Tsipolitis NTUA.

Collimation Remote Handling Highlights from work for collimation remote handling and remote survey. Plans Keith Kershaw EN-HE 14 June 2011.

EA meeting, Wednesday 6 Dec 2006 TT installation, Jeroen van Tilburg 1 TT installation Installation of the TT station.

S. Evrard — EN/MEF IEFC Workshop, March 08, 2012 TCC2/TDC2 Shutdown Activities and Consolidation Plans On behalf of the TDC2/TCC2.

Remote Handling design progress for the Collimation Upgrade project Keith Kershaw EN-HE 6 June 2011.

Warm magnets and the remote handling system in the J-PARCν beam line E. Hirose, K. H. Tanaka, Beam Channel Group.

Addendum to EDMS document “Instruction Manual for inserting the CMS ZDCs using the HXTC crane” In addition to the ZDC detectors in the TAN instrument.

LUMI 1 LUMI Mechanical Design Details Bill Ghiorso.

CRYOGENICS AND POWERING

Lessons learnt from WANF (*) dismantling Outline  Introduction  WANF/HiRadMat location  WANF operation  WANF dismantling  Preparation  Dismantling.

(1/15) 08/05/13 – RadWG meeting J. Mekki M. Brugger PS East Area Update Outline Layout updates of the facility Conveyer options Mock-up preparation and.

TS Department / Civil Engineering Group 17 October 2007 Civil Engineering Layouts & Tunnel Cross Section 1 CLIC workshop – Working group: Two beam hardware.

FUNCTIONAL SPECIFICATION Dorothea Pfeiffer Dennis Haasler GIF++ User Meeting

Utilities 14 October 2008 Martin Nordby, Gordon Bowden.

1 5 December 2012 Laurent Roy Infrastructure / Electronics Upgrade -Cabling (long distance) -Rack and Crate (space, electrical distribution, cooling) -Detector.

- Hearing Session - Marion Picard - July 28 th, 2011 S TATUS OF H I R AD M AT S AFETY F ILE Outline  Safety file Descriptive part Hazard inventory  Demonstrative.

Collimation Meeting Tests on a Fully Assembled TCT Collimator in the HiRadMat Facility M. Cauchi, D. Deboy, on behalf of the Collimation Team.

Integration, Installation & Infrastructure Ans Pardons, with input from the WP4 members September 2014.

RADIATION SOURCE Design Review Dmitry Gudkov BE-BI-ML.

 A brief history of time  In the years BC.  My years at CERN  Current position  What is a Technical Coordinator?  The different type of intervention.

John Osborne : GS-SEM Civil Engineering 19 May 2009 Report on behalf of CLIC Civil Engineering and Services (CES) WG CTC 19 May 2009 Tunnel Cross Section.

1 Target Station Design Dan Wilcox High Power Targets Group, Rutherford Appleton Laboratory EuroNu Annual Meeting 2012.

Lau and Niels, NA62 TD meeting, 17 March Complete the crane consolidation in TCC8 Reinstall front-end after alignment checks Consolidation of T10.

Transport of the CLIC Modules and Elements CLIC Workshop October 2007 Two Beam Hardware and Integration Working Group Keith Kershaw (CERN)

HRMT "RodTarg“ Technical Board – Feb. 2 nd 2015 Claudio Torregrosa Martin, Marco Calviani, Antonio Perillo-Marcone, Mark Butcher (EN/STI), Luca.

1 Target Station Design for Neutrino Superbeams Dan Wilcox High Power Targets Group, Rutherford Appleton Laboratory NBI 2012, CERN.

Workshop Chamonix XV27-January-2006 DivonneMassimiliano Ferro-Luzzi 1 State of LHCb for the Sector Test  Overview  Agreement  Status of –VELO –exit.

First radiological estimates for the HIRADMAT project H. Vincke and N. Conan 1.

Radiation Protection aspects for SHIP Doris Forkel-Wirth, Stefan Roesler, Helmut Vincke, Heinz Vincke CERN Radiation Protection Group 1 st SHIP workshop,

TAS at IP5 Present situation and plans François BUTIN TS/LEA.

Activities related to Experiments during TS3 and YETS th November, 2015 M. Bernardini, M. Barberan With the support of S. Chemli and Experiments.

Transport & Handling of Detectors TAN Workshop S. Prodon –

Overview of the main events related to TS equipment during 2007 Definition Number and category of the events Events and measures taken for each machine.

HIGH RADIATION TO MATERIALS: EXPERIMENTAL AREA HiRadMat Users meeting, 14/7/2011 Outline  Location  Test zone  Test tables geometry and position  Services.

HiRadMat – Users Meeting 29/5/2015 Adrian Fabich EuCARD-2 is co-funded by the partners and the European Commission under Capacities 7th Framework Programme,

HIGH RADIATION TO MATERIALS: HIRADMAT STATUS HiRadMat Scientific Board, 23/4/2012 Outline  Location  Status  Beam line  Infrastructure  Exp. Area.

Plan for test station Marta Bajko For the Technical Review of FReSCa2 June 2015 Saclay Paris.

H. Katajisto RE EDR 10/10/02 Enclosures for the RPC Link Boards Outline Introduction Periphery General Services Components, materials Manufacture, Assembly.

Installation of the T600 at Fermilab CSN2, September 22,

HIGH RADIATION TO MATERIALS Ans Pardons for the HiRadMat project team IEFC Workshop, March 22, 2011 Outline  The HiRadMat facility – Why, What, When,

The HiRadMat Facility Outline  Location  Status  WANF dismantling  Beam line  Experimental area  Schedule  Project management S. Evrard – EN/MEF.

1 st LTEX meeting Protecting the experimental caverns and personnel from a "sector 34 like" incident: work planned in the LHC tunnel Prepared by M GASTAL.

T2K Remote Handling T. Sekiguchi (KEK) on behalf of Tada (KEK) 2012/11/10.

D.Macina TS/LEATOTEM Meeting25/02/2004 Roman Pot test at the SPS Test of the Roman Pot prototype in the SPS proposed in December 2003 (CERN/LHCC ):

HiRadMat status report Adrian Fabich HiRadMat EAM, 4. March 2016 EuCARD-2 is co-funded by the partners and the European Commission under Capacities 7th.

SECONDARY BEAM HANDLING AND INFRASTRUCTURE DESIGN STATUS BRUNO FERAL (CERN/EN) DIAMANTO SMARGIANAKI (CERN/EN) Project Leader: I.Efthymiopoulos (Cern/EN)

PRESENT AND FUTURE TEST FACILITIES FOR HIGH- INTENSITY TARGETRY CERN I.Efthymiopoulos, CERN with input from Jacques Lettry & Rende Steerenberg.

High Energy Dump of the Super Proton Synchrotron at CERN – Present and Future designs A. Perillo-Marcone (EN-STI) Contributions from several colleagues.

HIRADMAT/ IRRADITION facilities Overall view with the biggest object to irradiat, T9 shielding with TED inside and the beam dump with 12 meters of cast.

The target handling concept of the pbar- separator at FAIR M. Helmecke, V. Gostishchev, R. Hettinger, K. Knie 6th High Power Targetry Workshop Oxford.

Status of the FAIR pbar target: Target handling study (M. Helmecke)

Test beam check list Michael JECKEL EN-EA-EC. Content: Safety & Radiation Protection Arrival Access Installation Departure Michael JECKEL EN-EA-EC.

V. Raginel, D. Kleiven, D. Wollmann CERN TE-MPE 2HiRadMat Technical Board - 30 March 2016.

Test beam check list Michael JECKEL EN-EA-EC.

Dielectric Oil Installations

TDI Coating test at HiRadMat Proposal 1605 HRMT-35 HiRadMat Technical Board Meeting 15th September 2016 EDMS I. Lamas Garcia, M. Butcher,

Components for the Machine-Interface Regions

N-TOF EAR2 - Vertical beam design & construction - Irradiation facility proposal S. Girod EN-EA.

Radiation-safe area for electronics, or laser or

The Quench Detection-Wire-Feedthrough Plug-In of W7-X

Experimental Areas – LS2 planning

BRAN: LS2-plans TREX M. Palm, E. Bravin, BE-BI-PM.

Polarized 3He target installation

Presentation transcript:

HIGH RADIATION TO MATERIALS: EXPERIMENTAL AREA DESIGN Ans Pardons HiRadMat review, 26 th of May 2011 Outline  Location of experimental area & services  Test zone  Test tables  Plug-in connectors  Integration cabling  Cooling test tables  Handling  Overhead crane  Handling of test tables  TED-type beam dump EDMS

Location of the experimental area HiRadMat Review, 26 th of May Beam line elements TA7 TNC  To TCC6 TNC TJ7 Sarcophagus with WANF collimator blocks (2011) HiRadMat cool down zone for test tables Primary beam line Test tables Cooled collimator Cooled beam dump Shielding 10 m Overhead crane (seen at downstream limit) All items in red will be treated in detail further-on Beam direction

Monitoring Location of test zone HiRadMat Review, 26 th of May Test stands, services & monitoring in test zone On passage-side wall opposite to test stand: - Gas connector for neutral gas (He or N 2 ) All along TNC: - Lighting - Compressed air - Overhead crane In TA7- TJ7, at ~25m from test stands - Overhead crane remote control - Power (220V) - Patch panel in signal rack Radiation Monitoring Beam Loss Monitors Beam Focal Points Test tables Services available in irradiation area Directly on test table: - Cooling circuit (30kW, 3m 3 /h, 9bar) - Power (4 kV/2.5kA) - Signal cables (50V/2A e.g. for camera, motorization, vibration measurement )

Test tables HiRadMat Review, 26 th of May Mobile table: geometry and services  Test table geometry  Mostly aluminium  Weight 450kg  Base plate 50mm thick  Available for test object:  Volume: 2 m x 0.7 m x (H) 1.5m (or cylinder of R=0.35m around beam)  Weight: 2000kg  Plug-in connectors  Remote handling with overhead crane  Test object mounted in surface lab Mobile table Connectors Test object (e.g. LHC collimator) mounted on table as in lab

Table assembly HiRadMat Review, 26 th of May  In surface lab: dummy base table to mount and align test object and to test all connectors (copy of tunnel table)  In tunnel: same base table as surface lab – stays in tunnel and its position is checked yearly (and copied on surface)  Remote plug-in connector types  Cooling circuit (LHC collimator-type, “Staubli”)  Signal “type 1” (LHC collimator-type, “Hypertac”)  Power (SPS magnet-type)  Signal “type 2” (spare, SPS magnet- type)  Auto-aligned in tunnel 4 4 Base table with connectors

Table assembly in tunnel HiRadMat Review, 26 th of May Integration in tunnel Reminder: Test objects must be contained, cable feed-throughs and portholes must be tight (user’s design, with CERN approval) Installation of table is 100% remote (overhead crane & camera system) Tables compatible with different sizes and types of test objects Cables arrive on the passage side and pass over to the test tables

Test tables HiRadMat Review, 26 th of May Mechanical guides  Base table: mechanical guides for remote installation  3 V- shaped supports per mobile table (Extra V-shaped supports allow for different table sizes)  Lab-tested (<0.1mm), tunnel exercises planned

Test table connectors HiRadMat Review, 26 th of May  Type 2 signal connector only on base table (seen as future upgrade for mobile tables)  Power connector only on central table Cooling water Signal “type 1” Signal “type 2” (spare) Power 4kV

Test table connectors 9 Signal “type 1” connector box on mobile table  Signal connector box a. Burndy 28 pin round connector (F) b. Burndy 50 pin rect. connector (F) c. Coax BNC (F)  Replacement or repair  On mobile table (M)  in surface lab  On base table (F): dismount connector locally as bloc and disconnect at 1.5m  Remote connection is lab-tested, exercises in tunnel planned c ba connected approach Overview 3D-View of mechanical guides, water connector and signal connector

Integration cabling HiRadMat Review, 26 th of May parallel cooling circuits All cables from 3 test tables Spare cables Quick connector (LHC collimator-type) at 1.5m from table for easier dismounting or cable exchange Cable guides: Structure for passage of cables / personnel / vehicles TJ7 TNC Coax CK50 (plug-in under development)

Integration cabling HiRadMat Review, 26 th of May Cable guides  Cable guides:  Aluminium comb guides cables of all tables  Aluminium ramps and steel cover allow for safe passage  Cover and ramps in one piece, remote handling with magnetic lifting beam  Comb has hooks for remote dismantling

Integration cabling HiRadMat Review, 26 th of May Racks near TJ7 Cables from BA7 Cables from TNC TJ7 patch panel TJ7 TNC Cooling circuit rack (flow meters, valves) where 3 parallel circuits join Rack in TJ7 At TJ7 patch panel: Possibility for users to test connections and signals locally before start of beam (later no tunnel access anymore and only observation from control room) All cables from 3 test tables cooling circuits front To control room in BA7

Integration cabling HiRadMat Review, 26 th of May  Control room location in BA7 known, detailed study ongoing Control Room Entrance to HiRadMat Cables from TJ7 patch panel Radioprotection Unit Room Users Control Room BA7 Surface building

Cooling test tables IEFC Workshop Mar. 22, (more details in presentation of Paul Pepinster/Magali Mendez) Ans Pardons Detection pressure drop  safety valves close B. Lacarelle, Y. Lupkins TJ7 TNC TA7, 9 bar

Handling equipment HiRadMat Review, 26 th of May  7.5T suspended overhead crane with remote controller  Equipped with remote shielding block hook  Installed in 1994, completely renovated in  Extensive experience from WANF dismantling  Risk analysis done, followed by safety measures  Found to be very reliable Overhead crane TJ7 TNC

Handling equipment HiRadMat Review, 26 th of May  Set of 5 PZT optic fibre network cameras on crane frame (also on lifting beam)  Cameras installed right before intervention  Viewing station with 4 screens in TJ7 Remote viewing system TNC TJ7 To material lift and BA7

Handling of test tables HiRadMat Review, 26 th of May From lab to test zone (non-radioactive object)  Surface lab: overhead crane to trailer  Trailer: from BA7  material lift  TJ7  TJ7: transfer to overhead crane  Remote with crane: TJ7  test zone in TNC Lab to test zone Custom-made trailer

Handling of test tables HiRadMat Review, 26 th of May Cool-down zone  Cool-down zone for test tables with test objects  Downstream in TNC, within reach of crane  5 places (supports) foreseen for 2011, 3 more for 2012 Downstream end of TNC  Test table supports  100% Aluminium  Mechanical guides for remote installation (also remote dismantling)  Handling exercises in tunnel planned

Handling of test tables HiRadMat Review, 26 th of May Test zone to cool-down zone 2. From test zone to cool-down zone (radioactive object)  Remote with crane: TJ7  cool-down zone in TNC  Remote with crane: place on cool-down zone supports

Handling of test tables HiRadMat Review, 26 th of May Cool-down zone to surface 3. From cool-down zone to surface (radioactive object)  Remote, with crane: cool-down zone in TNC  TJ7  Remote, with crane: place on trailer  Manually, protected by distance (and shielding if needed): TJ7  material lift  surface  Manually and in truck with container (and shielding if needed): surface  CERN radioactive lab for disassembly  When needed, followed by waste disposal (CERN)  If dose rate negligible  empty mobile table can be re-used

TED-type beam dump HiRadMat Review, 26 th of May Geometry, Location and Handling  Beam dump geometry and integration  Cooled and under nitrogen atmosphere (beam interlock)  Custom-made lifting beam  Pre-guiding upstream support  Guiding traces on shielding  Cameras on overhead crane  Procedures tested and optimized  Beam dump exchange: 100% remote

HiRadMat Review, 26 th of May Thank you for your attention – Any questions? High Radiation to Materials: EXPERIMENTAL Area DESIGN

Technical documentation HiRadMat Review, 26 th of May

Alignment plug-in HiRadMat Review, 26 th of May

Water connector – part 1 HiRadMat Review, 26 th of May Seal = EPR (ethylene propylene rubber)

Water connector – part 2 HiRadMat Review, 26 th of May

Power connector HiRadMat Review, 26 th of May  Material: Copper, aluminium (Antico 100), ceramic  Mass: 3.3 kg for the fix part and 9.1 kg for the mobile part.  Quantity: 2 (on table 2 only)  Maximum current: 2.5kA, maximum voltage 4kV  Maximum voltage: 4kV  Available only on stand B.  System: plug-in (standard SPS magnet supply).

Signal connector 50V (type 1) HiRadMat Review, 26 th of May Material:  Box: aluminuim EN AW-6082  Hypertac connectors : zamac and steel  Screws: steel  Cables : copper with kapton insulation (RadHard cabling) Maximum current: 3A Maximum voltage: 50V

Signal connector 50V (type 2) HiRadMat Review, 26 th of May Material:  Stainless steel: box, screws  Insulating material (stumatite, kapton, glass fiber) Mass: 3.5 kg for the fixed part and 3.5 kg for the mobile part Maximum current: 2A Maximum voltage: 50V

Overhead crane HiRadMat Review, 26 th of May