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IDS120h: Be WINDOW DETAILED CALCULATION, SHIELDING VESSELS, RESULTS FOR DIFFERENT GLOBAL STEPS Nicholas Souchlas (9/20/2011) 1.

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Presentation on theme: "IDS120h: Be WINDOW DETAILED CALCULATION, SHIELDING VESSELS, RESULTS FOR DIFFERENT GLOBAL STEPS Nicholas Souchlas (9/20/2011) 1."— Presentation transcript:

1 IDS120h: Be WINDOW DETAILED CALCULATION, SHIELDING VESSELS, RESULTS FOR DIFFERENT GLOBAL STEPS Nicholas Souchlas (9/20/2011) 1

2 IDS120h:detailed calculation of TDP for Be window, studies with different STEPEM, STEPH global steps, and introducing shielding vessels. >mars1510/MCNP >10 -11 MeV NEUTRON ENERGY CUTOFF >SHIELDING: 60%WC+40%H 2 O >4 MW proton beam, Np=100,000 >PROTONS ENERGY E=8 GeV. >GAUSSIAN PROFILE: σ x =σ y =0.12 cm. 2

3 IDS120h geometry. SC#1 NOW THE BIGGEST COIL EXTENDED FURTER UPSTREAM RS FURTER AWAY FROM Hg POOL GAP, JET AND PROTON BEAM 3

4 4 Be Window detail: 1 cm vacuum regions before and after the window (VAC1, VAC2) used for detail studies of the TDP in Be Window. SAME LOCAL STEPS USED IN ALL THREE REGIONS AND ON THE Be/VAC INTERFACES: FOR LOCAL MTSM=0.001 cm MTSH=0.001 cm TDP=3.82 kW BEFORE FOR GLOBAL STEPEM=0.01 cm STEPH=3.0 cm TDP=0.86 kW FLUCKA TDP=2.1 kW (P6 UN-OPTIMIZED POINT, OLD POOL GEOMETRY,IDS120f) SH=SHIELDING AREAS SC=SUPER CONDUCTING COIL 6 mm Be Window VAC1VAC2 6 mm Be Window Hg Pool SC8 SC 7 SC 6 SH 2 SH 4 SH 3

5 IDS120h:SHIELDING VESSELS. RESULTS FOR 0.5 cm THIKNESS VESSELS KEEPING BP SC1: 0.645 kW SC2: 0.01 kW SC3: 0.016 kW SC TOT: 0.823 kW Peak SC1: 0.04 mW/g SC3: 0.013 mW/g BP2(1 cm)~191 kW DETAILS TO BE ADDED... W 10 cm 6 cm 2 cm 3 cm 10 cm 15 cm 3 cm 10 cm 2 cm 1 cm 5 Bob Weggel(7/26/11) 4 cm 5 cm 2 cm 5 cm SH2 SC7 SH1 SH4 SH3 RS:1-5 SC1 SC2 SC3 SC4 SC5 SC6 #WHAT IS THE DISTANCE BETWEEN VESSELS WALLS AND RS? #THE SH3 VESSEL HAS 2 cm WALLS? #BP IS NOW PART OF SHIELDING VESSELS SH1, SH2, SH3 WITH THE GIVEN THIKNESS? #IF NOT, IS THERE SOME SPACE BETWEEN BP AND VESSELS WALLS? BP1? BP3 BP2? 2 cm

6 STUDIES WITH DIFFERENT STEPS STEPEM, STEPH STEPEM=FOR THE ACCURACY OF LOCALIZATION OF BOUNDARIES FOR THE PARTICLE TRANSPORT CODE=0.01 cm (DEFAULT) STEPH=GLOBAL PILOT STEP LENGTH FOR PARTICLES TRACKING=3.0 cm SC=SUPER COND. COILS, RS=RESISTIVE COILS, SH=SHIELDING, BP=BEAM PIPE +/-=MORE/LESS THAN THE STANDARD CASE. 1. STEPEM=0.001 cm, STEPH=3.0 cm---->SC~+0.08 kW ---->RS, BP, HgTarg, HgPool.~SAME±2-4 kW, BeWind.~SAME ---->SH~-7.5 kW, ---->SH1 Peak~-0.022 mW/g 2. STEPEM=0.1 cm, STEPH=3.0 cm ---->SC~-0.07 kW ---->RS, BP, HgTarg, HgPool~SAME±2-4 kW ---->SH~-6.6 kW, BeWind.~+0.5 kW ---->SH1 Peak~-0.023 mW/g 3. STEPEM=0.01 cm, STEPH=1.0 cm ---->SC~-0.07 kW ---->RS, HgTarg, HgPool~SAME±2-4 kW ---->SH~-15 kW, BeWind.~+0.5 kW, BP~+15.5 kW ---->SH1 Peak~-0.01 mW/g 4. STEPEM=0.01 cm, STEPH=5.0 cm ---->SC~-0.05 kW ---->BP, HgTarg, HgPool~SAME±2-4 kW, BeWind.~SAME ---->SH~-28 kW, RS~+24.0 kW ---->SH1 Peak~-0.02 mW/g STEPEM=FOR THE ACCURACY OF LOCALIZATION OF BOUNDARIES FOR THE PARTICLE TRANSPORT CODE=0.01 cm (DEFAULT) STEPH=GLOBAL PILOT STEP LENGTH=3.0 cm SC=SUPER COND. COILS, RS=RESISTIVE COILS, SH=SHIELDING, BP=BEAM PIPE 1. STEPEM=0.001 cm STEPH=3.0 cm---->SC, RS, HgTarg, HgPool, BeWind.~SAME, ---->SH~50 kW LESS STEPEM=FOR THE ACCURACY OF LOCALIZATION OF BOUNDARIES FOR THE PARTICLE TRANSPORT CODE=0.01 cm (DEFAULT) STEPH=GLOBAL PILOT STEP LENGTH=3.0 cm SC=SUPER COND. COILS, RS=RESISTIVE COILS, SH=SHIELDING, BP=BEAM PIPE 1. STEPEM=0.001 cm STEPH=3.0 cm---->SC, RS, HgTarg, HgPool, BeWind.~SAME, ---->SH~50 kW LESS STEPEM=FOR THE ACCURACY OF LOCALIZATION OF BOUNDARIES FOR THE PARTICLE TRANSPORT CODE=0.01 cm (DEFAULT) STEPH=GLOBAL PILOT STEP LENGTH=3.0 cm SC=SUPER COND. COILS, RS=RESISTIVE COILS, SH=SHIELDING, BP=BEAM PIPE 1. STEPEM=0.001 cm STEPH=3.0 cm---->SC, RS, HgTarg, HgPool, BeWind.~SAME, ---->SH~50 kW LESS STEPEM=FOR THE ACCURACY OF LOCALIZATION OF BOUNDARIES FOR THE PARTICLE TRANSPORT CODE=0.01 cm (DEFAULT) STEPH=GLOBAL PILOT STEP LENGTH=3.0 cm SC=SUPER COND. COILS, RS=RESISTIVE COILS, SH=SHIELDING, BP=BEAM PIPE 1. STEPEM=0.001 cm STEPH=3.0 cm---->SC, RS, HgTarg, HgPool, BeWind.~SAME, ---->SH~50 kW LESS 1. STEPEM=0.001 cm STEPH=3.0 cm---->SC, RS, HgTarg, HgPool, BeWind.~SAME, STEPEM=FOR THE ACCURACY OF LOCALIZATION OF BOUNDARIES FOR THE PARTICLE TRANSPORT CODE=0.01 cm (DEFAULT) STEPH=GLOBAL PILOT STEP LENGTH=3.0 cm SC=SUPER COND. COILS, RS=RESISTIVE COILS, SH=SHIELDING, BP=BEAM PIPE 1. STEPEM=0.001 cm STEPH=3.0 cm---->SC~0.08 kW MORE ---->RS, HgTarg, HgPool, BeWind.~SAME±2-3 kW ---->SH~50 kW LESS 2. STEPEM=0.1 cm STEPH=3.0 cm ---->SC~0.07 kW LESS ---->SH,RS, HgTarg, HgPool~SAME±2-3 kW ---->BeWind.~0.5 kW MORE 2. STEPEM=0.01 cm STEPH=3.0 cm ---->SC~0.07 kW LESS ---->SH,RS, HgTarg, HgPool~SAME±2-3 kW ---->BeWind.~0.5 kW MORE STEPEM=FOR THE ACCURACY OF LOCALIZATION OF BOUNDARIES FOR THE PARTICLE TRANSPORT CODE=0.01 cm (DEFAULT) STEPH=GLOBAL PILOT STEP LENGTH=3.0 cm SC=SUPER COND. COILS, RS=RESISTIVE COILS, SH=SHIELDING, BP=BEAM PIPE 1. STEPEM=0.001 cm STEPH=3.0 cm---->SC~+0.08 kW ---->RS, BP, HgTarg, HgPool.~SAME±3-4 kW ---->SH.~-7.5 kW ---->BeWind.~SAME ---->SH1 Peak~-0.022 mW/g 2. STEPEM=0.1 cm STEPH=3.0 cm ---->SC~-0.07 kW ---->RS, HgTarg, HgPool~SAME±3-4 kW ---->BeWind.~+0.5 kW ---->SH1 Peak~-0.023 mW/g 3. STEPEM=0.01 cm STEPH=1.0 cm ---->SC~-0.07 kW ---->SH~-15 kW RS, HgTarg, HgPool~SAME±2-3 kW ---->BeWind.~0.5 kW MORE 4. STEPEM=0.01 cm STEPH=5.0 cm ---->SC~0.07 kW LESS ---->SH,RS, HgTarg, HgPool~SAME±2-3 kW STEPEM=FOR THE ACCURACY OF LOCALIZATION OF BOUNDARIES FOR THE PARTICLE TRANSPORT CODE=0.01 cm (DEFAULT) STEPH=GLOBAL PILOT STEP LENGTH=3.0 cm SC=SUPER COND. COILS, RS=RESISTIVE COILS, SH=SHIELDING, BP=BEAM PIPE +/-=MORE/LESS THAN THE STANDARD CASE. 1. STEPEM=0.001 cm STEPH=3.0 cm---->SC~+0.08 kW ---->RS, BP, HgTarg, HgPool.~SAME±2-4 kW, ---->SH~-7.5 kW, BeWind.~SAME ---->SH1 Peak~-0.022 mW/g 2. STEPEM=0.1 cm STEPH=3.0 cm ---->SC~-0.07 kW ---->RS, BP, HgTarg, HgPool~SAME±2-4 kW ---->SH~-6.6 kW, BeWind.~+0.5 kW ---->SH1 Peak~-0.023 mW/g 3. STEPEM=0.01 cm STEPH=1.0 cm ---->SC~-0.07 kW ---->RS, HgTarg, HgPool~SAME±2-4 kW ---->SH~-15 kW, BeWind.~+0.5 kW, BP~+15.5 kW ---->SH1 Peak~-0.01 mW/g 4. STEPEM=0.01 cm STEPH=5.0 cm ---->SC~-0.05 kW ---->HgTarg, HgPool~SAME±2-4 kW, BeWind.~SAME ---->SH~-28 kW, BeWind.~SAME, BP~+15.5 kW, BP~+15.5 kW STEPEM=FOR THE ACCURACY OF LOCALIZATION OF BOUNDARIES FOR THE PARTICLE TRANSPORT CODE=0.01 cm (DEFAULT) STEPH=GLOBAL PILOT STEP LENGTH=3.0 cm SC=SUPER COND. COILS, RS=RESISTIVE COILS, SH=SHIELDING, BP=BEAM PIPE +/-=MORE/LESS THAN THE STANDARD CASE. 1. STEPEM=0.001 cm STEPH=3.0 cm---->SC~+0.08 kW ---->RS, BP, HgTarg, HgPool.~SAME±2-4 kW, ---->SH~-7.5 kW, BeWind.~SAME ---->SH1 Peak~-0.022 mW/g 2. STEPEM=0.1 cm STEPH=3.0 cm ---->SC~-0.07 kW ---->RS, BP, HgTarg, HgPool~SAME±2-4 kW ---->SH~-6.6 kW, BeWind.~+0.5 kW ---->SH1 Peak~-0.023 mW/g 3. STEPEM=0.01 cm STEPH=1.0 cm ---->SC~-0.07 kW ---->RS, HgTarg, HgPool~SAME±2-4 kW ---->SH~-15 kW, BeWind.~+0.5 kW, BP~+15.5 kW ---->SH1 Peak~-0.01 mW/g 4. STEPEM=0.01 cm STEPH=5.0 cm ---->SC~-0.05 kW ---->HgTarg, HgPool~SAME±2-4 kW, BeWind.~SAME ---->SH~-28 kW, BeWind.~SAME, BP~+15.5 kW, BP~+15.5 kW 6

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