2009 Linear Collider Workshop of the Americas Amann - 10/01/09 Global Design Effort 1 Status Update 18MW ILC Beam Dump Design John Amann Mechanical Engineer.

Slides:

Advertisements

Similar presentations

Photon Collimation For The ILC Positron Target Lei Zang The University of Liverpool Cockcroft Institute 24 th March 2007.

Advertisements

RFQ End Flange Dipole Tuner Finger Cooling. Basis of Study Need multi-purpose end flange –Adjustable dipole mode suppression fingers –Beam current transformer.

First Wall Heat Loads Mike Ulrickson November 15, 2014.

Lh 2 target for an 11 GeV Møller - prospect - S. Covrig hall c, jlab 14 august 2008 hp lh 2 targets for pv q weak target design cooling.

Collimator Damage Adriana Bungau The University of Manchester Cockcroft Institute “All Hands Meeting”, January 2006.

Mercury Beam Dump Simulations Tristan Davenne Ottone Caretta STFC Rutherford Appleton Laboratory, UK November-2008.

Mike Fitton Engineering Analysis Group Design and Computational Fluid Dynamic analysis of the T2K Target Neutrino Beams and Instrumentation 6th September.

Thermo Fluid Design Analysis of TBM cooling schemes M. Narula with A. Ying, R. Hunt, S. Park ITER-TBM Meeting UCLA Feb 14-15, 2007.

R. ArnoldDumps - LCWS08, 19 Nov Heat and Radiation in the Water and Shielding in the18 MW Water Dump for ILC Preliminary Results from FLUKA, FLUENT.

Michael Butzek, Jörg Wolters, Bernhard Laatsch Mitglied der Helmholtz-Gemeinschaft Proton beam window for High Power Target Application 4th.

MARS15 Simulations of the MERIT Mercury Target Experiment Fermilab March 18, Neutrino Factory and Muon Collider Collaboration meeting Sergei.

Progress on the MICE Cooling Channel Solenoid Magnet System

Status of T2K Target 2 nd Oxford-Princeton High-Power Target Workshop 6-7 th November 2008 Mike Fitton RAL.

May 17-19, 2000 Catalina Island, CA Neutrino Factory and Muon Collider Collaboration Meeting 1 Target Support Facility for a Solid Target Neutrino Production.

Thermal Analysis of Helium- Cooled T-tube Divertor S. Shin, S. I. Abdel-Khalik, and M. Yoda ARIES Meeting, Madison (June 14-15, 2005) G. W. Woodruff School.

Harold G. Kirk Brookhaven National Laboratory Target System Update IDS-NF Plenary Meeting Arlington, VA October 18, 2011.

Harold G. Kirk Brookhaven National Laboratory Target Baseline IDS-NF Plenary CERN March 23-24, 2009.

Experimental Verification of Gas- Cooled T-Tube Divertor Performance L. Crosatti, D. Sadowski, S. Abdel-Khalik, and M. Yoda ARIES Meeting, UCSD (June 14-15,

The JPARC Neutrino Target

A discussion paper for the Absorber Review pre-meeting on February 11 th 2003 On 3-D Fluid Flow calculations on the 22cm Absorber Window By Stephanie Yang.

Mercury Chamber Considerations V. Graves IDS-NF Target Studies July 2011.

March 20-21, 2000ARIES-AT Blanket and Divertor Design, ARIES Project Meeting/ARR Status ARIES-AT Blanket and Divertor Design The ARIES Team Presented.

Norbert Tesch (DESY) – Design Studies for an 18 MW Beam Dump at TESLA – ICRS 10 / RPS 2004 – Madeira – May Norbert Tesch, A. Leuschner, M. Schmitz,

LCWS 2010 Amann - 3/26/10 Global Design Effort 1 Status Update 18MW ILC Beam Dump Design John Amann Mechanical Engineer SLAC National Accelerator Laboratory.

ISIS Second Target Station

23 Jan 2007 LASA Cryogenics Global Group 1 ILC Cryomodule piping L. Tavian for the cryogenics global group.

Pro-Science 4 th International Conference of Hydrogen Safety, September 12-14, 2011, SAN FRANCISCO, USA EXPERIMENTAL STUDY OF IGNITED UNSTEADY HYDROGEN.

Radiological Aspects of ILC Hee-Seock Lee Pohang Accelerator Laboratory 2 nd Workshop of Korean ILC at PAL.

Study of a new high power spallation target concept

Calorimeter Analysis Tasks, July 2014 Revision B January 22, 2015.

Summary Why consider a packed bed as a high power target?

Date Event Global Design Effort 1 Overview of Mechanical Engineering Design Progress for LC 18MW Beam Dump CLIC08 10/16/08 (From left) Dieter Walz, Ray.

LHC Phase II Collimator Compact jaw simulations New FLUKA => ANSYS mapping scheme New 136mm x 950mm jaw –60cm primary collimator –Helical cooling channel.

NML High Energy Beam Absorbers and Dump 29-August-2011 Beams-doc-3928.

Nuclear Thermal Hydraulic System Experiment

IAEA Meeting on INPRO Collaborative Project “Performance Assessment of Passive Gaseous Provisions (PGAP)” December, 2011, Vienna A.K. Nayak, PhD.

1 Parametric Thermal-Hydraulic Analysis of TBM Primary Helium Loop Greg Sviatoslavsky Fusion Technology Institute, University of Wisconsin, Madison, WI.

CLIC Prototype Test Module 0 Super Accelerating Structure Thermal Simulation Introduction Theoretical background on water and air cooling FEA Model Conclusions.

Contents Beam Dump Work Program submitted to UK funding agencies Motivation to study pressure waves Progress so Far -Energy Deposition -Pressure wave calculation.

Investigation of a “Pencil Shaped” Solid Target Peter Loveridge, Mike Fitton, Ottone Caretta High Power Targets Group Rutherford Appleton Laboratory, UK.

DCLL ½ port Test Blanket Module thermal-hydraulic analysis Presented by P. Calderoni March 3, 2004 UCLA.

Simple CFD Estimate of End Flange Tuner Finger Cooling.

Recent Studies on ILC BDS and MERIT S. Striganov APD meeting, January 24.

Parameters of the NF Target Proton Beam pulsed10-50 Hz pulse length1-2  s energy 2-30 GeV average power ~4 MW Target (not a stopping target) mean power.

Mitglied der Helmholtz-Gemeinschaft Jörg Wolters, Michael Butzek Focused Cross Flow LBE Target for ESS 4th HPTW, Malmö, 3 May 2011.

G.Kurevlev - Daresbury meeting Collimators Material Damage Study Previous results In our group - Adriana Bungau’s thesis - heat deposition on.

4/27/06 1 US LHC ACCELERATOR RESEARCH PROGRAM brookhaven - fermilab – berkeley - slac US LARP Inner Triplet Cryogenics and Heat Transfer LARP Collaboration.

R. ArnoldCLIC08, CERN, 16 Oct Heat and Radiation in the Water and Shielding in the18 MW Water Dump for ILC Preliminary Results from FLUKA and FLUENT.

WG3a Sources Update Jim Clarke on behalf of WG3a GDE Meeting, Frascati, December 2005.

F.Staufenbiel / EuCARD 2 / Heat load and stress studies of the ILC collimator G. Moortgat-Pick 1;2 S. Riemann 2, F. Staufenbiel 2, A. Ushakov.

Cryogenic scheme, pipes and valves dimensions U.Wagner CERN TE-CRG.

1 A Self-Cooled Lithium Blanket Concept for HAPL I. N. Sviatoslavsky Fusion Technology Institute, University of Wisconsin, Madison, WI With contributions.

Simulation of heat load at JHF decay pipe and beam dump KEK Yoshinari Hayato.

BENE/EURISOL-DS Joint Meeting, CERN, SwitzerlandFebruary 22, Progress in the Liquid Mercury Multi-MW Target Design Studies Y. Kadi On behalf of.

Chapter 8: Internal Forced Convection

G.Kurevlev - Manchester meeting1 Collimators Material Damage Study Previous results In our group - Adriana Bungau’s thesis - heat deposition on.

7/8/08 John Amann LC Mechanical Engineering LC 18M W Beam Dump Mechanical Engineering Design Updates.

704 MHz cavity design based on 704MHZ_v7.stp C. Pai

Chopper Beam Dump Thermal Problem 10/27/20101PX Linac FE Technical Discussions.

New nTOF target: Design Issues

ISIS TS1 Project: Target Design and Analysis

ILC main dump issue AWLC /26

WATER AND LEAD-BISMUTH EXPERIMENTS: FLUENT AND STAR-CD SIMULATION

2D Free Jet Simulations (FLUENT)

P. Sievers/CERN. A. Ushakov/Univ. Hamburg. S. Riemann/DESY-Zeuthen.

Dump Window Cooling Sleeve 3D Models for CFD

Beam Window Studies for Superbeams

CFD-Team Weekly Meeting - 8th March 2012

M. Calviani, A. Ferrari (EN/STI), P. Sala (INFN)

Beam Dump outline work plan (UK perspective)

Presentation transcript:

2009 Linear Collider Workshop of the Americas Amann - 10/01/09 Global Design Effort 1 Status Update 18MW ILC Beam Dump Design John Amann Mechanical Engineer SLAC National Accelerator Laboratory LC Beam Delivery Systems

Global Design Effort 2 Outline 2009 Linear Collider Workshop of the Americas Amann - 10/01/09 Introduction. Mechanical Design Concept. Beam Parameters used for FLUKA studies. FLUKA studies. FLUENT studies (conjugate heat transfer). Summary.

Global Design Effort 3 Introduction ILC Beam Dump Design Team SLAC National Accelerator Laboratory: J. Amann, R. Arnold, D. Walz, A. Seryi Bhabha Atomic Research Centre: P. Satyamurthy, P. Rai, V. Tiwari, K. Kulkarni Starting Point for Work SLAC 2.2 MW Water Dump, The Stanford Two-Mile Accelerator, R.B. Neal Ed, (1968). High Power Water Beam Dump for a LC, M. Schmitz, TESLA Collaboration Meeting, 16 Sept ILC Main Beam Dumps -- Concept of a Water Dump, D. Walz Snowmass, 18 Aug Dumps and Collimators, ILC Reference Design Report, 2007 T. Davenne, O. Caretta, C. Densham and R. Appleby, Pressure Transients in the ILC Beam Dump, LC-ABD Collaboration meeting, Birmingham University, 17 April Linear Collider Workshop of the Americas Amann - 10/01/09

Global Design Effort 4 The task force team studied the various aspects of the SLAC’s 2.2MW water beam dump and used it as the starting basic reference design for an ILC Beam dump, since it has all features required of an ILC beam dump (but at a lower power level) but proven design. This includes the use of a vortex-like flow pattern to dissipate and remove the energy deposited by the beam, the beam dump entrance window and its special cooling method, a remote window exchange mechanism, a hydrogen re-combiner, handling of radioactive 7 Be, a tail catcher to attenuate the residual beam energy remaining after the vortex flow region, as well as related primary and secondary cooling loops Linear Collider Workshop of the Americas Amann - 10/01/09 Introduction

Global Design Effort 5 Mechanical Design Concept The 18MW LC beam dump mechanical design is driven by parameters and constraints developed from FLUKA simulations, CFD thermal hydraulic simulations and analytic calculations. The existing 2.2MW SLAC beam dump provides a baseline mechanical design to consider features which might be incorporated into the 18MW beam dump mechanical design concept. The first step in creating a mechanical design concept for the beam dump is to establish the basic mechanical design parameters of the beam dump vessel and thin window. The beam dump is a pressurized vessel containing heated and radioactive water and consequently for operation within the USA, must conform to the design and safety standards of the American Society of Mechanical Engineers Boiler and Pressure Vessel Code Linear Collider Workshop of the Americas Amann - 10/01/09

Global Design Effort 6 Mechanical Design Concept Table of Beam Dump Design Parameters and Constraints Operating Parameters Maximum Operating Temperature200°C Maximum Operating Pressure20bar or 290psi Minimum Operating Pressure10bar or 145psi Beam Dump Vessel Internal diameter1.8m Length10m Beam Dump Inlet Headers Up beam end of vessel8” (203mm) ID with longitudinal slots Inlet header location0.7m from center on horizontal plane Beam Dump Outlet Header Up beam end of vessel10” (254mm) ID with perforations all around Outlet header locationCenter axis of vessel Beam Dump Thin Window Hemispherical shapePressure on concave side Internal diameter300mm Maximum thickness1mm Window location m from center of vessel vertical plane Window coolingSingle water jet 2009 Linear Collider Workshop of the Americas Amann - 10/01/09

Global Design Effort 7 Mechanical Design Concept 2009 Linear Collider Workshop of the Americas Amann - 10/01/09 Vessel Shell Outlet Header Inlet Headers Thin Window Flat Heads Window Cooling Nozzle Supply Pipe

Global Design Effort 8 Mechanical Design Concept 2009 Linear Collider Workshop of the Americas Amann - 10/01/09 Mechanical Design Parameters (ASME BPVC Div. VIII) Vessel Material – 316LN Minimum Shell Thickness – 21mm Minimum Flat Head Thickness – 70mm Window Material – Ti-6Al-4V Max. Design Pressure, 1mm Thick Hemispherical Window – 32bar or 464psi

Global Design Effort 9 Mechanical Design Concept 2009 Linear Collider Workshop of the Americas Amann - 10/01/09 Thin Window Window Cooling Nozzle

Global Design Effort 10 Mechanical Design Concept 2009 Linear Collider Workshop of the Americas Amann - 10/01/09

Global Design Effort 11 Beam Parameters The following beam parameters have been taken as reference for designing the beam dump: Electron/Positron energy: 500 GeV Number of electrons/positrons per bunch:2x10 10 Number of bunches per train:2820 Duration of the bunch train:0.95 ms Beam size:σ x = 2.42mm σ y = 0.27 mm Energy in one bunch train:4.5 MJ Number of bunch trains per second:4 Beam power:18 MW Beam sweep radius:6 cm 2009 Linear Collider Workshop of the Americas Amann - 10/01/09

Global Design Effort 12 Energy Density Modulation Around Sweep Path 2009 Linear Collider Workshop of the Americas Amann - 10/01/09 FLUKA Studies

Global Design Effort 13 FLUKA Studies 2009 Linear Collider Workshop of the Americas Amann - 10/01/09

Global Design Effort 14 FLUKA Studies Energy deposited by one bunch train in the water (beam travelling along z-axis) z=1.8m Radially integrated longitudinal linear power density z=2.9m 2009 Linear Collider Workshop of the Americas Amann - 10/01/09

Global Design Effort 15 FLUKA Studies Longitudinal Power Density in Vessel Wall (20mm thick 316L SS) r=35cm 2009 Linear Collider Workshop of the Americas Amann - 10/01/09

Global Design Effort 16 FLUKA Studies 2009 Linear Collider Workshop of the Americas Amann - 10/01/09 Heat Flux – Down Beam Head

Global Design Effort 17 FLUKA Studies 2009 Linear Collider Workshop of the Americas Amann - 10/01/09 A FLUKA analysis was carried out to determine the beam power distribution in the thin window. The total power deposited is ~25 W with a maximum power density of 21W/cm 3. Functional fitted data is the input for the CFD analysis. W/cm 3

Global Design Effort 18 FLUENT Studies Velocity contours at z = 2.9mSteady state temperature distribution at z = 2.9m (Max average temperature : C ) 2009 Linear Collider Workshop of the Americas Amann - 10/01/09 Total mass flow rate of water taken was 154kg/s. Water inlet was assumed to be at 50 0 C as dictated by the primary coolant loop. The bulk outlet temperatures would be 78 0 C for 18 MW average beam power. The water inlet velocity at the slit exit is 2.17 m/s.

Global Design Effort 19 FLUENT Studies Maximum temperature ~155 0 C and variation with time ~30 0 C Maximum temperature ~135 0 C and variation with time ~36 0 C Maximum temperature variation as a function of time at z = 2.9m Maximum temperature variation as a function of time at z = 1.8 m 2009 Linear Collider Workshop of the Americas Amann - 10/01/09

Global Design Effort 20 FLUENT Studies 2009 Linear Collider Workshop of the Americas 10/01/09 Variation of inlet velocity at inlet exit along length of header.

Global Design Effort 21 FLUENT Studies max vessel temperature C min vessel temperature C Temperature distribution in the vessel at z = 2.9m for the 0.45m radial beam location Temperature distribution in the vessel at z = 4.2m for the 0.45m radial beam location max vessel temperature C min vessel temperature C 2009 Linear Collider Workshop of the Americas Amann - 10/01/09

Global Design Effort 22 FLUENT Studies 2009 Linear Collider Workshop of the Americas Amann - 10/01/09 Window Cooling - Work In Progress

Global Design Effort 23 FLUENT Studies 2009 Linear Collider Workshop of the Americas Amann - 10/01/09 Window Cooling - Work In Progress

Global Design Effort 24 FLUENT Studies 2009 Linear Collider Workshop of the Americas Amann - 10/01/09 Flat Head Cooling - Work In Progress

Global Design Effort 25 FLUENT Studies 2009 Linear Collider Workshop of the Americas Amann - 10/01/09 Flat Head Cooling - Work In Progress

Global Design Effort 26 FLUKA Studies 2009 Linear Collider Workshop of the Americas Amann - 10/01/09 Preliminary Activation Studies – First Design Concept

Global Design Effort 27 Summary Mechanical design concept under development. –Basic mechanical parameters established. –Window sealing design and remote exchange system still needs work. –Preliminary process design complete. FLUKA and FLUENT studies nearly complete. –Beam dump parameters determined by physics. –Inlet headers, outlet header, and window locations optimized. –Working to finalize window cooling and down beam head cooling. Shielding design and overall system integration still needs work. Future work we feel is critical. –Build a scaled down version of beam dump to verify FLUENT studies. –Beam damage testing of thin window materials Linear Collider Workshop of the Americas 10/01/09

Global Design Effort 28 Bonus Slides 2009 Linear Collider Workshop of the Americas 10/01/09 Variation of inlet velocity at inlet exit along length of header.