ARIES Technology and Physics Assessment – Aggressive and Conservative Tokamaks (ACT)

ARIES Technology and Physics Assessment – Aggressive and Conservative Tokamaks (ACT)

ACT-I: Aggressive technology (SiC blanket) and aggressive physics

ARIES Systems Code Outputs for SiC blanket – ACT-I

V.30 (SVN version control), Printed: LCC 4/08/11

Point # 289722 from raw sysout.data sic806 database

UPDATED 6/8/11, revised to ACT-Ib:

V.32 (SVN version control), Printed: LCC 6/08/11

- Same strawman point as V.30 but corrected maintenance port volumes and costing, slight increase in COE.

- Corrected plasma surface areas and NWL to use more accurate discretized geometry formulas.

- Most hard-wired numbers have been removed and placed in the specific input files; formatting improved.

PDF file of this webpage

Input data:

Material Properties – density, cost, cost base

Inflation Factor

Output data:

Engineering summary

- Plasma parameters

- Vertical build

- IB/OB builds

- Geometric data – volumes

- Geometric data – surface areas

- Liquid metal mass

- Material-based component costs

2D CAD drawing from systems code – PNG, TIF

Setup

***************************

Select Divertor Design *

type "1" to use, *

"0" to turn off *

1) J. Burke T-tube design *

0 *

2) X. Wang plate design *

1 *

3) X. Wang finger design *

0 *

***************************

Select Blanket Design *

type "1" to use, *

"0" to turn off *

1) SiC blanket *

1 *

2) DCLL blanket *

0 *

***************************

Select Output Format *

type "1" to use, *

"0" to turn off *

1) "COE" production mode *

for scanning parameters *

0 *

2) "SYSTEM" detailed mode *

for analysis on single pt*

1 *

***************************

Builds

0 1 2 3 4 5 6 7 8 9 10 11 *

IB SOL First Wall Gap Blanket Gap HT Shield Gap Vac. Vessel Gap TF Coil Gap Bucking Cy*

1.000E-01 1.400E-02 0.000E+00 3.360E-01 1.000E-02 2.400E-01 1.000E-02 4.000E-01 2.000E-02 0.000E+00 0.000E+00 0.000E+00 *

OB SOL First Wall Gap Blanket Gap Blanket II HT Shield Gap Vac. Vessel - - - *

1.000E-01 1.400E-02 0.000E+00 2.860E-01 0.000E+00 4.500E-01 1.500E-01 2.000E-02 2.500E-01 0.000E+00 0.000E+00 0.000E+00 *

VB Div Plate Repl HTS Gap HT Shield Gap Vac. Vessel Cryodome - - - - - *

3.350E-02 1.500E-01 0.000E+00 3.000E-01 2.000E-02 4.000E-01 4.000E-01 0.000E+00 0.000E+00 0.000E+00 0.000E+00 0.000E+00 *

Costing

Real Discount Rate *

5.000E-02

Economic Life of Plant (Years) *

4.000E+01

Neutron Fluence Life ( W*year/(m^2) ) *

1.800E+07

Annual Escalation Rate *

5.000E-02

Construction Period (Years) *

6.000E+00

Plant Capacity Factor *

8.500E-01

Annual Fuel Cost (M$) *

1.000E+06

Decontamination & Decomm. Allowance (mills/kWh) *

2.000E+00

Reference/base year for cost basis *

2.009E+03

Projected year for cost basis *

2.009E+03

Magnets

Maximum stress in protective sheath around strands [Pa]*

8.000E+08

Maximum allowed stress in the coil casing [Pa] *

4.000E+08

Current density in copper [A/m^2] *

2.24E+08

Volume fraction of He coolant [-] *

2.500E-01

Volume fraction of the insulator [-] *

1.000E-01

Nominal current in TF coil [A] *

4.000E+04

Side thickness of the coil casing X 2 [m] *

2.000E-02

Clearance between V Vessel and TF coil outmost edge [m]*

1.000E-01

Yield stress for the PF coil case [Pa] *

1.000E+09

Upper limiter of the current (qmax) *

4.500E+00

Lower limiter of the current (qmin) *

3.150E+00

Maximum allowed magnetic field on PF coils [T] *

1.800E+01

Quench protection parameter J2tau *

5.000E+16

Quench time [s] *

2.000E+00

Number of TF coils *

1.600E+01

Powerflow

Fraction of loss of alpha particles [-] *

0.000E+00

Fraction of alpha loss to divertor [-] *

0.500E+00

Fraction of edge radiation (typical range 0.75-0.9) [-]*

0.900E+00

Fraction of edge radiation to divertor [-] *

0.900E+00

Neutron energy multiplication factor FW/blanket inboard*

1.100E+00

Neutron energy multiplication factor FW/blanket outb. *

1.100E+00

Neutron energy multiplication factor shield inboard *

1.100E+00

Neutron energy multiplication factor shield outboard *

1.100E+00

Neutron energy multiplication factor divertor plates *

1.100E+00

Neutron energy multiplication factor divertor blanket *

1.100E+00

Neutron energy multiplication factor divertor shield *

1.100E+00

Efficiency of the He pump/blower [-] *

0.900E+00

Generic current drive source efficiency [-] *

0.500E+00

Current drive source efficiency (NB) [-] *

0.680E+00

Current drive source efficiency (LH) [-] *

0.680E+00

Current drive source efficiency (ICRF) [-] *

0.840E+00

Current drive source efficiency (EC) [-] *

0.430E+00

Power to all auxiliary functions [W] *

5.000E+07

Cryogenic power [W] *

2.000E+06

Efficiency of plasma heating [-] *

0.430E+00

Outboard fraction of incoming power [-] *

0.600E+00

Inboard fraction of incoming power [-] *

0.400E+00

Fraction of neutron flux absorbed by FW/blanket [-] *

0.900E+00

Fraction of neutron flux absorbed by the shield [-] *

0.100E+00

Fraction of neutron pow. to divertor in div. plates [-]*

0.500E+00

Fraction of neutron pow. to divertor in div. blnkt. [-]*

0.400E+00

Fraction of neutron pow. to divertor in div. shield [-]*

0.100E+00

Up-down symmetry factor. 1 for symmetric, 0 otherwise *

1.000E+00

Fraction of conducted power to divertor => outboard [-]*

0.800E+00

Fraction of conducted power to divertor => inboard [-] *

0.200E+00

Fraction of radiated power to divertor => outboard [-] *

0.800E+00

Fraction of radiated power to divertor => inboard [-] *

0.200E+00

Poloidal magnetic flux expansion on outboard [-] *

1.000E+01

Poloidal magnetic flux expansion on inboard [-] *

1.000E+01

Efficiency of the LM MHD pump [-] *

0.400E+00

Efficiency of the LM mechanical pump [-] *

0.900E+00

NB (neutral beam) power in use [W] *

0.000E+00

NB (neutral beam) unit cost [M$] *

3.450E+00

LH (lower hybrid) power in use [W] *

3.442E+07

LH (lower hybrid) unit cost [M$] *

1.490E+00

FW (fast wave) power in use [W] *

3.284E+06

FW (fast wave) unit cost [M$] *

0.000E+00

FW (fast wave) frequency in use [W] *

9.500E+07

Penetration Shielding Thickness [% of HT shielding] *

2.500E-01

Fraction of neutron power from plasma to div (A=4) [-] *

1.000E-01

Fraction of neutron power from plasma to blanket IB [-]*

2.500E-01

Fraction of neutron power from plasma to blanket OB [-]*

6.500E-01

Plasma outer squareness [-] *

1.000E-06

Plasma inner squareness [-] *

-1.000E-06

Material Properties

Material Properties used in ASC:

All properties updated 12/08/10 'Fabrication Costs per kgRevN(01192011).xls' (L. Waganer)

Material Name	Density (kg/m3)	$/kg	Cost basis year
B-FS	7800	35.54	2009
PbLi	8897	8.79	2009
RAFS	9500	43.44	2009
SiC-comp	3200	584.64	2009
SS	7800	81.46	2009
Void	0	0	2009
W	19300	120.37	2009
WC	15600	34.39	2009
TF-coil	7500	50.912	1992
PF-coil	7500	82.919	1992
Nb3Sn	7500	92.7	1992
Cu	7300	65.4	1992
YBCO	6200	92.7	1992
Ag	10500	201.1	1992
CeO2	7130	16.516	1992
Polyamide	1920	16.516	1992
Inconel	8440	96.02	2009
JK2LB	8000	95	2009
SS316	7860	68.657	1992
FS	7800	89.42	2009
He	0.1786	70	2011
RAFS-div	7800	111.77	2009
RAFS-cryost	7800	28.06	2009

*PbLi is 'Li17Pb83, liquid (90% Li6 enrichment) @ 650C'
*Helium is 99.999% pure, cost $70.0/kg
*Helium cost is zero in the table since it is added at startup and not part of the building contract

Inflation Factor

GDP Inflation Factors used in ASC:

All factors updated 12/02/10 per 'GDP current(103010)(2005 basis).xls' L. Waganer
Year used:	2009

Year	Inflation Factor
1970	0.2432
1971	0.2553
1972	0.2663
1973	0.2811
1974	0.3067
1975	0.3356
1976	0.3549
1977	0.3775
1978	0.404
1979	0.4376
1980	0.4775
1981	0.5222
1982	0.5541
1983	0.576
1984	0.5977
1985	0.6158
1986	0.6294
1987	0.6476
1988	0.6699
1989	0.6952
1990	0.722
1991	0.7476
1992	0.7653
1993	0.7822
1994	0.7987
1995	0.8154
1996	0.8309
1997	0.8456
1998	0.8551
1999	0.8677
2000	0.8865
2001	0.9065
2002	0.9212
2003	0.941
2004	0.9677
2005	1
2006	1.0326
2007	1.063
2008	1.0862
2009	1.0961
2010	1.1071

*2005 basis

Engineering summary

Defining Power Plant Parameters:
SVN Rev # 32; Printed on Wed Jun 8 15:09:06 2011

Plasma major radius [m]:	5.5
Plasma aspect ratio [-]:	4
Toroidal mag. field at plasma major radius [T]:	5.5
Plasma current [MA]:	10.58
Normalized Beta [-]:	4.5
MHD safety factor [-]:	4.4
Cylindrical safety factor [-]:	2.609
Plasma triangularity [-]:	0.7
Exponent on plasma density profile [-]:	0.3
Exponent on plasma temperature profile [-]:	0.8
Greenwald density fraction [-]:	0.95
Fusion gain [-]:	40
Plasma elongation [-]:	2.2
H98(y,2) multiplier on energy confinement scaling [-]:	1.441
Current diffusion time [s]:	221.3
Energy confinement time [s]:	1.536
Ratio of effec. particle conf. time to energy conf. time [-]:	5.091
Volume average electron density [m^-3]:	1.52E+20
Volume average temperature [KeV]:	16.56
Flattop time [s]:	1.00E+30
L to H-mode threshold power [MW]:	44.4
Ave neutron wall load (at plasma surface) [MW/m^2]:	3.07317
Bremsstrahlung radiation loss [MW]:	50.64
Bootstrap current fraction [-]:	0.8998
Current drive efficiency for generic heating/CD source [-]:	0.27
Power from generic CD source (steady-state) [MW]:	26.9
Total aux. heating power into plasma for power balance [MW]:	45.1
Cyclotron radiation loss [MW]:	12.02
Ohmic power in plasma [MW]:	0.0584
Line radiation loss [MW]:	29.24
Fast alpha beta [-]:	0.9679
Effective charge [-]:	2.064
Ratio of plasma temperature at center to edge [-]:	0
Ratio of plasma density at center to edge [-]:	0
Eta_CD for source 1 [-]:	5.89E-44
Eta_CD for source 2 [-]:	-4.32E-26
Eta_CD for source 3 [-]:	0
Eta_CD for source 4 [-]:	0
Impurity fraction 1 [-]:	0.003
Impurity fraction 2 [-]:	0
Impurity fraction 3 [-]:	0
Peak temperature [keV]:	26.75
External CD fraction of total plasma current [-]:	0.1002
Total non-inductive fraction of total plasma current [-]:	1
Density fraction of helium (frac. of electron density) [-]:	0.07288
Density fraction of DT fuel (frac. of electron density) [-]:	0.8002
Plasma stored energy [MJ]:	513.2
Poloidal flux swing required to raise plasma current [?]:	300
Loop voltage in plasma [V]:	0
Density profile peak-to-volume average [-]:	1.295
Temperature profile peak-to-volume average [-]:	1.796
Poloidal beta [-]:	2.348
Toroidal beta [-]:	6.295
Alpha power in plasma [MW]:	361.3
Ratio of loss power to L-H threshold power [-]:	7.525
Plasma surface area [m^2]:	470.264
Maximum magnetic field in the TF coil [T]:	10.1896
Maximum IB heat flux on divertor [MW/m^2]:	2.9255
Maximum OB heat flux on divertor [MW/m^2]:	6.70536
Maximum heat flux to the first wall [MW/m^2]:	0.274874
Gross electrical power [MW]:	1181.54
Net electric power [MW]:	1007.49
Recirculated power (Pgross - Pnet) [MW]:	174.048
Thermal power [MW]:	2065.4
Fusion power [MW]:	1804
Cost of electricity [mills/kWh]:	58.3027
Data point number from plasma physics output file [-]:	289721


===============================================================
Defining Parameters for Plasma Closed Surface Equation:

Plasma major radius [m]:	5.5
Plasma minor radius [m]:	1.375
Elongation [-]:	2.2
Triangularity [-]:	0.7
Outer Squareness [-]:	6.32404e-322
Inner Squareness [-]:	0
Scrape-off layer [m]:	0.1

Vertical Build [m]:
Divertor Plate:	0.0335
Replaceable HT Shield:	0.289777
Gap:	0
HT Shield:	0.3
Gap:	0.02
Vacuum Vessel:	0.4

Inboard/Outboard Radial Build in TETRA Format [m]:
	Thickness	Radius
Device Centerline	0.0000	0
Bore	2.27598	2.27598
Central Solenoid	0.139506	2.41548
Gap	0.02	2.43548
Bucking Cylinder	0.206699	2.64218
Gap	0	2.64218
TF Coil Annulus	0.326523	2.9687
Gap	0.0136666	2.98237
Vacuum Vessel	0.4	3.38237
Gap	0.066292	3.44866
HT Shield IB	0.229777	3.67844
Gap	0.01	3.68844
Blanket IB	0.32256	4.011
Gap	0	4.011
First Wall IB	0.014	4.025
Scrape-Off Layer IB	0.1	4.125
Plasma Centerline	1.375	5.5
Plasma Outer Edge	1.375	6.875
Scrape-Off Layer OB	0.1	6.975
First Wall OB	0.014	6.989
Gap	0.000340877	6.98934
Blanket OB	0.274549	7.26389
Gap	0.01	7.27389
Blanket II	0.430831	7.70472
Gap	0.0100091	7.71473
HT Shield OB	0.289777	8.00451
Gap	0.4	8.40451
Vacuum Vessel	0.25	8.65451
Gap	3.15477	11.8093
TF Coil	0.326523	12.1358
Gap	0.949361	13.0852
Cryostat	0.4	13.4852


===============================================================
Geometric Data: Volumes [m^3]:

Plasma:
Plasma_AT:	400.646
First Wall:
FirstWallInboard:	1.87531
FirstWallOutboard:	5.97294
Total First Wall:	7.84825
Blankets:
BlanketInboard:	41.3975
BlanketOutboard:	104.923
BlanketII:	175.005
Total Blankets:	321.325

Divertor Plates (6):
Div1:	0.558501
Div2:	1.17735
Div3:	1.05001
Div4:	1.05417
Div5:	1.18835
Div6:	0.554716
Total Divertor:	5.58309

Replaceable HT Shields:
RepHTShieldTop:	20.3655
RepHTShieldBottom:	20.3655
Total Repl. HT Shields:	40.731

HT Shields:
HTShieldInboard:	24.9345
HTShieldOutboard:	220.09
Penetration Shielding Thickness:	61.2562
Total HT Shields:	306.281

Vacuum Vessel:
VacuumVesselMain:	89.7315
VacuumVesselOutboard:	185.531
Total Vacuum Vessel:	275.262

Maintenance Ports (16):
MaintenancePort:	301.466
UpperVVDuctBottomWall:	22.7948
UpperVVDuctTopWall:	12.6746
UpperVVDuctSideWall:	48.5187
Total All Ports:	385.454

TF Coils (16):
Total TF Coils:	185.44

BuckingCylinder:	33.1309
TF Coil Upper Cap:	52.9419
TF Coil Lower Cap:	52.9419
Cryostat:	1076.31

PF Coils (36 active, 14 spares [preliminary]):
PFCoil_0:	2.5825
PFCoil_1:	2.58375
PFCoil_2:	2.585
PFCoil_3:	2.58626
PFCoil_4:	1.35707
PFCoil_5:	1.51535
PFCoil_6:	1.67251
PFCoil_7:	2.05531
PFCoil_8:	2.2034
PFCoil_9:	2.2129
PFCoil_10:	2.0627
PFCoil_11:	1.69199
PFCoil_12:	1.17736
PFCoil_13:	0.35272
PFCoil_14:	0.484511
PFCoil_15:	0.69244
PFCoil_16:	0.82236
PFCoil_17:	0.847845
PFCoil_18:	0.848256
PFCoil_19:	0.822758
PFCoil_20:	0.692775
PFCoil_21:	0.484744
PFCoil_22:	0.352889
PFCoil_23:	1.17793
PFCoil_24:	1.6928
PFCoil_25:	2.0637
PFCoil_26:	2.21397
PFCoil_27:	2.20446
PFCoil_28:	2.05629
PFCoil_29:	1.67331
PFCoil_30:	1.51606
PFCoil_31:	1.35771
PFCoil_32:	2.58751
PFCoil_33:	2.58626
PFCoil_34:	2.585
PFCoil_35:	2.58375
Active PF Coil Vol. (36):	58.9862
Spare PF Coil Vol. (14):	19.1485
Total PF Coils Vol.:	78.1346

Total FW and Blankets:	329.173
(IB, OB FW & Blanket, Blanket II)

Total Power Core (FPC) Vol:	1220.61
(IB, OB FW & Blanket, Blanket II, Divertor, TF & PF magnets,
VV, HT & Repl. Shield w/ Penetration Shielding)

Support Structure Volume:	244.121
(20% of FPC vol)


===============================================================
Surface Areas [m^2]:

Plasma Surface Area:	470.264
Plasma Surface Area including SOL:	502.269
(using discretized geometry formulas)
Scrape-off layer (SOL) thickness:	0.1

FirstWallInboard:	132.633
FirstWallOutboard:	372.212
Total First Wall:	504.845

Div1:	18.6167
Div2:	39.2449
Div3:	35.0002
Div4:	35.139
Div5:	39.6118
Div6:	18.4905
Total Divertors:	186.103


===============================================================
Liquid Metal Mass [tonne]

FirstWallInboard:	4.50485
FirstWallOutboard:	14.3481
BlanketInboard:	305.7
BlanketOutboard:	774.805
BlanketII:	1198.9
Div1:	0
Div2:	0
Div3:	0
Div4:	0
Div5:	0
Div6:	0
Total Divertors:	0
RepHTShieldTop:	18.1192
RepHTShieldBottom:	18.1192
Total Repl HT Shields:	36.2384
HTShieldInboard:	22.1842
HTShieldOutboard:	195.814
Total HT Shields:	217.999

Total Mass Liquid Coolant:	2552.5
Total w/ 2.5x BOP Factor:	6381.25


===============================================================
Material-based Component Costs [M$]:

FirstWallInboard:	2.43309
FirstWallOutboard:	7.74949
BlanketInboard:	12.5079
BlanketOutboard:	31.7017
BlanketII:	74.4042
Divertors:	0.525676

RepHTShieldTop:	9.66353
RepHTShieldBottom:	9.66353
HTShieldInboard:	14.3823
HTShieldOutboard:	104.434
Total HT Shield:	118.816

VacuumVesselMain:	34.5401
VacuumVesselOutboard:	22.9695
Total Vacuum Vessel:	57.5096

MaintenancePort:	110.733
UpperVVDuctBottomWall:	8.37289
UpperVVDuctTopWall:	4.6556
UpperVVDuctSideWall:	17.8217
Total All Ports = 141.584

Total TF Coils Cost:	141.776

BuckingCylinder:	13.6725
TF Coil Upper Cap:	21.8481
TF Coil Lower Cap:	21.8481
CryoDome:	42.4027

PF Coil Costs (36 active, 14 spares [preliminary]):
PFCoil_0:	2.30024
PFCoil_1:	2.30136
PFCoil_2:	2.30247
PFCoil_3:	2.30359
PFCoil_4:	1.20875
PFCoil_5:	1.34973
PFCoil_6:	1.48972
PFCoil_7:	1.83068
PFCoil_8:	1.96258
PFCoil_9:	1.97104
PFCoil_10:	1.83726
PFCoil_11:	1.50706
PFCoil_12:	1.04868
PFCoil_13:	0.314169
PFCoil_14:	0.431557
PFCoil_15:	0.61676
PFCoil_16:	0.73248
PFCoil_17:	0.75518
PFCoil_18:	0.755546
PFCoil_19:	0.732834
PFCoil_20:	0.617058
PFCoil_21:	0.431764
PFCoil_22:	0.31432
PFCoil_23:	1.04919
PFCoil_24:	1.50779
PFCoil_25:	1.83815
PFCoil_26:	1.97199
PFCoil_27:	1.96352
PFCoil_28:	1.83155
PFCoil_29:	1.49043
PFCoil_30:	1.35037
PFCoil_31:	1.20932
PFCoil_32:	2.30471
PFCoil_33:	2.30359
PFCoil_34:	2.30247
PFCoil_35:	2.30136
Active PF Coil Cost (36):	52.5393
Spare PF Coil Cost (14):	17.0556
Total PF Coil Cost:	69.5949

Total First Wall, Blankets:	128.796
Total HT Shield:	138.143
Total Power Core:	266.94

Powers

Powers [MW]:
Printed on Wed Jun 8 15:09:06 2011

Plasma Power:	406.4
Alpha Power:	361.3
Neutron Power:	1445.2
Thermal Power:	2065.4
Fusion Power:	1806.5
Gross Electrical Power:	1181.54
Net Electrical Power:	1007.49

Divertor in use:	plate-type, helium-cooled
He pump/blower efficiency:	0.9
Divertor pumping power (He only):	19.6173
Recovered power from He pump:	11.8458
(P_he_pump_recovered = P_pump_divertor / eta_pump_he * eta_pump_he_recovered * eta_brayton)

Blanket in use:	SiC blanket, PbLi-cooled
LM pump in use:	mechanical LM pump
LM pump efficiency:	0.9
Blanket pumping power (LM only):	5.85626
Recovered power from LM pump:	3.53626
(P_lm_pump_recovered = P_pump_blanket / eta_pump_lm_mech * eta_pump_lm_mech_recovered * eta_brayton)

TF magnets in use:	low-temp SC magnet technology
Nb3Sn at 4.2 K, 'Next Step, conservative costing'


Additional Parameters:
Gross Cycle Efficiency (Brayton):	0.572061
Plasma Heating [MW]:	18.2
Plasma Heating Efficiency:	0.43
Current Drive Power [MW]:	26.9
Current Drive Efficiency:	0.5
Aux. Functions Power [MW]:	63
Cryo Power [MW]:	2

Neutron Power Distribution: (A=4)
Divertors:	0.1
IB Blanket:	0.25
OB Blanket:	0.65

Power to Divertor [MW]:	295.385
Divertor Heat Flux max [MW/m2]:	6.70536

NWL ave (plasma surface) [MW/m2]:	3.07317
NWL max (plasma surface) [MW/m2]:	4.76341
NWL ave (incl. SOL) [MW/m2]:	2.87734
NWL max (incl. SOL) [MW/m2]:	4.45988
Peaking factor:	1.55

Power to FW [MW]:	111.015
FW Heat Flux ave [MW/m2]:	0.219899
FW Heat Flux max [MW/m2]:	0.274874

Costing Accounts

Costing Accounts with SiC Blanket
Costs are M$ in 2009$
Printed on Wed Jun 8 15:09:06 2011


20.0 Land and Land Rights:	24.0468
20.1 Land and Privilege Acquistion:	20.0448
20.2 Relocation of Buildings, Utilities, Highways, and Other Services:	4.002

21.0 Structures and Site Facilities:	428.356
21.1 Site Improvements and Facilities:	27
21.2 Power Core Building:	159.914
21.3 Turbine - Generator Building:	76.9584
21.4 Heat Rejection Structures and Facilities:	11.6031
21.5 Electrical Equipment and Power Supply Building:	23.0114
21.6 Plant Auxiliary Systems Building (including Switchgear):	21.6522
21.7 Hot Cell Building (incl. Maintenance and Radioactive Material Storage and Reprocessing):	54.3709
21.8 Power Core Service Building (Non-Radioactive Service?):	4.32567
21.9 Service Water Building:	1.51839
21.10 Fuel Handling and Storage Building:	25.2006
21.11 Control Room Building:	7.12
21.12 On-Site A/C Power Supply Building:	4.72055
21.13 Administration Building:	2
21.14 Site Service Building:	2
21.15 Cryogenics and Inert Gas Storage Building:	2.09
21.16 Security Building:	0.71
21.17 Ventilation Stack:	4.16

22.0 Power Core Equipment:	1381.57
22.1.0 Fusion Energy Capture and Conversion:	297.169
22.1.1 First Wall and Blanket, replaceable, inboard and outboard:	54.3922
22.1.2 Second Blanket, life of plant:	74.4042
22.1.3 Divertor Assembly, upper and lower, replaceable:	0.525676
22.1.4 High Temperature Shield, outside of blanket and/or divertor, replaceable:	19.3271
22.1.5 High Temperature Shield, outside of replaceable HT shield, life of plant:	118.816
22.1.6 Penetration Shielding (low temperature, active and passive):	29.704
22.1.7 Shield cooling, low temperature:	0
22.2.0 Plasma Confinement:	311.142
22.2.1 Toroidal Field Coils (conductor, case, bucking cyl., cryostat, struts, structure):	241.547
22.2.1.1 Conductor and Cable:	36.405
22.2.1.2 Structural Coil Case:	105.371
22.2.1.3 Bucking Cylinder:	13.6725
22.2.1.4 Cryostat and Thermal Shield:	42.4027
22.2.1.5 Thermal Isolation Struts:	0
22.2.1.6 Anti-torque structure (upper + lower cap):	43.6962
22.2.2 Poloidal Field Coils (central solenoid and outer poloidal), lower spares incl:	69.5949
22.2.3 Feedback Control Coils (normal conducting):	0
22.2.4 Cryogenicics for Plasma Confinement (incl dewar vacuum pumping):	0
22.2.5 Power Supplies for Plasma Confinement:	0
22.3.0 Plasma Formation and Sustainment:	78.0624
22.3.1 Heating and Current Drive with power supplies (Primarily Steady State):	55.0624
22.3.1.1 Ion Cyclotron Resonance Frequency (ICRF) Fast Wave Heating and CD:	3.7766
22.3.1.2 Lower Hybrid (LH) Wave Plasma Heating and Current Drive:	51.2858
22.3.1.3 Electron Cyclotron Resonance Frequency (ECRF) Plasma Heating and CD:	0
22.3.1.4 Neutral Particle Beam Plasma Heating, Current Drive and Rotation:	0
22.3.2 Startup subsystems with power supplies:	7
22.3.2.1 Electron Cyclotron Resonance Freq. (ECRF) Wave Plasma Breakdown:	0
22.3.2.2 Ion Cyclotron Resonance Freq. (ICRF) Wave Current Initiation, Ramp-Up:	0
22.3.2.3 Lower Hybrid (LH) Wave Current Initiation and Ramp-Up:	0
22.3.3 Stability Control subsystem with power supplies (Primarily Transient):	0
22.3.3.1 Electron Cyclotron Resonance Frequency (ECRF) Wave Plasma Control:	0
22.3.3.2 Neutral Particle Beam Plasma Control:	0
22.3.4 Plasma Fueling and Constituent Control:	16
22.3.4.1 Pellet Injection Fueling and Constituent Control:	0
22.3.4.2 Neutral (Particle) Beam Injection (NBI) Fueling and Constituent Control:	0
22.4.0 Vacuum, Power Core:	215.599
22.4.1 Vacuum Vessel:	168.243
22.4.2 Helium Liquefier-Refrigerators:	15
22.4.3 Primary Vacuum Pumps (cryocondensation, cryosorption, cryodiffusion, and/or turbo-molecular):	0
22.4.4 Roughing or Backing Pumps:	0
22.4.5 Vacuum Pumping Ducts (vac duct shielding in 22.01.06):	32.3555
22.4.6 Plumbing, Cryogenic:	0
22.5.0 Primary Structure and Support, Power Core:	48.8242
22.5.1 Carry-Through Structure:	0
22.5.2 Structural Pedestal:	0
22.5.3 Equipment Support Structure:	0
22.6.0 Main Heat Transfer and Transport (MHTT):	175.261
22.6.1 Dual-Coolant System: PbLi servicing FW, Blanket, HT shield, He servicing Divertor, and Nb IHX:	175.261
22.6.2 Primary (Helium) Heat Transfer Loop (Servicing FW, blanket, and HT shield):	0
22.6.3 Limiter or Divertor Primary Heat Transfer Loop (May tie into same IHX, SG):	0
22.6.4 Intermediate Heat Transfer Loop (Sodium or Helium):	0
22.7.0 Radioactive Materials Treatment and Management (off-line):	15.3302
22.7.1 Liquid Materials Processing Equipment (including final detritiation):	0
22.7.2 Gaseous Materials Processing Equipment (including final detritiation):	0
22.7.3 Solid Materials Processing Equipment (including detrititation):	0
22.8.0 Fuel Handling and Storage (on-line):	71.5407
22.8.1 Chamber Exhaust Gas Handling and Processing Equipment:	0
22.8.2 Purge and Cover Gas Handling Processing Equipment:	0
22.8.3 Primary Coolant Stream Handling and Processing Equip. (incl. on-line adj. of Li enrichment):	0
22.8.4 Other Liquid and Gaseous Coolant Stream Handling and Processing Equipment:	0
22.8.5 Purification and Isotope Separation Equipment:	0
22.8.6 Tritium, Deuterium, and DT Storage Equipment:	0
22.8.7 Atmospheric Tritium Recovery Equipment (Power Core, Hot Cell, Fuel Handling Bldgs.):	0
22.9.0 Maintenance Equipment:	100.599
22.9.1 Power Core Maintenance Equipment:	0
22.9.2 Hot Cell Maintenance Equipment:	0
22.9.3 Fuel Handling Maintennace Equipment:	0
22.9.4 Other Plant Equipment Maintenance Equipment:	0
22.10.0 Instrumentation and Control:	60
22.10.1 Power Core Instrumentation & Control Equipment:	0
22.10.2 Radiation Monitoring Equipment:	0
22.10.3 Isolated Indicating & Recording Equipment:	0
22.10.4 Data Acquisition and Recording Equipment:	0
22.10.5 Communications Equipment:	0
22.11.0 Other Power Core Equipment:	8.04789
22.11.1 Special Heating Equipment:	0
22.11.2 Special Cooling Equipment (low temp shield, vacuum vessel, other structures):	0
22.11.3 Coolant Receiving, Storage and Makeup Equipment:	0
22.11.4 Gas Systems Equipment:	0
22.11.5 Inert Atmosphere Equipment (Power Core, Hot Cell, and Fuel Handling Buildings):	0
22.98.0 Spare Parts Allowance (include in individual costs):	0
22.99.0 Contingency Allowance (include in Acct 96):	0

23.0 Turbine - Generator Equipment:	352.187
23.1.0 Turbine - Generators:	0
23.2.0 Main Steam or other Main Heat Transfer Fluid System:	0
23.3.0 Condensing or Heat Sink Heat Exhanger Systems:	0
23.4.0 Feedwater Heating or Heat Recovery System:	0
23.5.0 Other Turbine Plant Equipment:	0
23.6.0 Turbine Plant Instrumentation & Control:	0
23.98.0 Spare Parts Allowance (include in individual costs):	0
23.99.0 Contingency Allowance (include in Acct 96):	0

24.0 Electric Plant Equipment:	185.556
24.1.0 Switchgear:	0
24.2.0 Station Service Equipment:	0
24.3.0 Switchboards:	0
24.4.0 Protective Equipment:	0
24.5.0 Electrical Structures and Wiring Containers:	0
24.6.0 Power and Control Wiring:	0
24.7.0 Electrical Lighting:	0
24.98.0 Spare Parts Allowance (include in individual costs):	0
24.99.0 Contingency Allowance (include in Acct 96):	0

25.0 Heat Rejection Equipment:	34.2671
25.1.0 Water Intake Common Facilities:	0
25.2.0 Circulating Water Systems:	0
25.3.0 Cooling Towers:	0
25.4.0 Other Heat Rejection Systems:	0
25.98.0 Spare Parts Allowance (incl. in individual costs):	0
25.99.0 Contingency Allowance (incl. in Acct 96):	0

26.0 Miscellaneous Plant Equipment:	84.2128
26.1.0 Transportation and Lifting Equipment:	0
26.2.0 Air and Water Service Systems:	0
26.3.0 Communications Equipment:	0
26.4.0 Furnishings and Fixtures:	0
26.98.0 Spare Parts Allowance (incl. in individual costs):	0
26.99.0 Contingency Allowance (incl. in Acct 96):	0

27.0 Special Materials:	57.0995
27.1.0 Primary coolant (PbLi) w/ 2.5x BOP factor:	56.0911
27.2.0 Divertor coolant (Helium) incl. storage & pressurization subsystem:	0.00238281
27.3.0 Intermediate Loop Coolant:	0
27.4.0 Turbine cycle Working Fluids:	0
27.98.0 Other Special Materials:	0.603591
27.99.0 Argon Power Core Cover Gas:	0.402394


90.0 Total Direct Cost:	2547.3

91.0 Construction Facilities, Equipment and Services:	287.845
91.1.0 Temporary Facilities:	0
91.2.0 Construction Equipment:	0
91.3.0 Construction Services:	0

92.0 Home Office Engineering and Services:	132.46
92.1.0 Systems Engineering:	0
92.2.0 Management Services:	0
92.3.0 Quality Assurance:	0
92.4.0 Safety and Environmental Engineering:	0

93.0 Field Office Engineering and Services:	132.46
93.1.0 Construction Management:	0
93.2.0 Inspection:	0
93.3.0 Pre-Operational Training:	0

94.0 Owner's Cost:	465.009
94.1.0 Project Administration:	0
94.2.0 Staff Training and Plant Startup:	0
94.3.0 Inventories and Spares Administration:	0

95.0 Process (design) Contingency:	0

96.0 Project Contingency:	522.283

97.0 Interest During Construction (IDC):	532.582

98.0 Escalation During Construction (EDC):	0

99.0 Total Project Capital Cost:	4619.94


Cost of Electricity (COE) [mills/kWh]:	58.3027

Subcosts of COE normalized to mills/kWh:
... capital return:	35.8905
... operation and maintenance:	13.0946
... component replacement:	7.13895
... fuel cost:	0.178638
... decontamination and decommissioning:	2

Costing Algorithms

Costing Algorithms: every account is multiplied by 'inflation(yearOrig, yearNew)' with a cost credit factor

Printed on Wed Jun 8 15:09:06 2011

c_20[1] = 20.0e6*pow(Pe/1000.0, 0.3)

c_20[2] = (20.01e6)*0.2

Pe = (*Machine).net_electrical_power()

c_21[1] = 27.0e6*pow(Asite/1000.0, 0.2)

c_21[2] = 111.846e6*pow(Vrb/80.0e3, 0.62)

c_21[3] = 79.03e6*pow(Pet/1246.0, 0.5)

c_21[4] = 16.832e6*pow((Pth-Pet)/1860.0, 0.5)

c_21[5] = 22.96e6*pow(Pe/1000.0, 0.3)

c_21[6] = 22.00e6*pow(Pet/1246.0, 0.3)

c_21[7] = 0.34*c_21[2]

c_21[8] = 4.316e6*pow(Pe/1000.0, 0.3)

c_21[9] = 1.515e6*pow(Pe/1000.0, 0.3)

c_21[10] = 25.0e6*pow(Pfusion/1759.0, 0.3)

c_21[11] = 7.12e6

c_21[12] = 4.71e6*pow(Pe/1000.0, 0.3)

c_21[13] = 2.00e6

c_21[14] = 2.00e6

c_21[15] = 2.09e6

c_21[16] = 0.71e6

c_21[17] = 4.16e6

Asite = 1000.0 [acres]

Pet = (*Machine).gross_electrical_power()

Pth = (*Machine).thermal_power()

Pfusion = (*Machine).fusion_power()

Vrb = (*Machine).volume() = 142404

vol_reactor_bldg = (pow((ksihi + 9.0), 2.0)*6.0*etahi + 1.55e5)*cATfit

ksihi = (*Core).bounding_box(2, 'outer')

etahi = (*Core).bounding_box(3, 'outer')

cATfit = 138698.0/181655.0

c_22_1[1] = ( (*FWInboard).cost() + (*FWOutboard).cost() + (*BlanketInboard).cost() + (*BlanketOutboard).cost() )*16.0

c_22_1[2] = (*BlanketII).cost()*16.0

c_22_1[3] = DivCost*16.0

c_22_1[4] = ( (*RepHTShield)[0].cost() + (*RepHTShield)[1].cost() )*16.0

c_22_1[5] = ( (*HTShield)[0].cost() + (*HTShield)[1].cost() )*16.0

c_22_1[6] = pen_shielding*c_22_1[5]

c_22_1[7] = 0.0

DivCost = for(int i=0; i<6; i++) { DivCost = DivCost + (*Div)[i].cost() }

c_22_2_1[1] = (*TFCoil).sub_cost(0)*16.0

c_22_2_1[2] = (*TFCoil).sub_cost(1)*16.0

c_22_2_1[3] = (*BuckingCylinder).cost()*16.0

c_22_2_1[4] = (*CryoDome).cost()*16.0

c_22_2_1[5] = 0.0*16.0

c_22_2_1[6] = ((*UpperCap).cost() + (*LowerCap).cost())*16

(*TFCoil).sub_cost(0) = 2.27531e+06

(*TFCoil).sub_cost(1) = 6.58568e+06

c_22_2[1] = ((*TFCoil).cost() + (*BuckingCylinder).cost() + (*UpperCap).cost() + (*LowerCap).cost() + (*CryoDome).cost())*16.0

c_22_2[2] = PFCoilCost*16.0

c_22_2[3] = 0.0

c_22_2[4] = 0.0

c_22_2[5] = 0.0

PFCoilCost (main): for(int i=0; i<36; i++) { PFCoilCost = PFCoilCost + (*PoloFCoil)[i].cost() }

PFCoilCost (spares): for(int i=4; i<18; i++) { PFCoilCost = PFCoilCost + (*PoloFCoil)[i].cost() }

c_22_3_1[1] = (*Machine).cd_fast_wave_cost()

c_22_3_1[2] = (*Machine).cd_lower_hybrid_cost()

c_22_3_1[3] = 0.0

c_22_3_1[4] = (*Machine).cd_neutral_beam_cost()

c_22_3_2[1] = 0.0

c_22_3_2[2] = 0.0

c_22_3_2[3] = 0.0

c_22_3_3[1] = 0.0

c_22_3_3[2] = 0.0

c_22_3_4[1] = 0.0

c_22_3_4[2] = 0.0

c_22_3_4[0] = 16.0e6

c_22_3[1] = (*Machine).cd_cost()

c_22_3[2] = 7.0e6

c_22_3[3] = 0.0

c_22_3[4] = 16.0e6

c_22_4[1] = (cVV + cMP)*16.0

c_22_4[2] = 15.0e6

c_22_4[3] = 0.0

c_22_4[4] = 0.0

c_22_4[5] = cDuct*16.0

c_22_4[6] = 0.0

cVV = (*VacuumVessel)[0].cost() + (*VacuumVessel)[1].cost()

cMP = (*MPort).cost()

cDuct = (*Duct)[0].cost() + (*Duct)[1].cost() + 2.0*(*Duct)[3].cost()

c_22_5[1] = 0.0

c_22_5[2] = 0.0

c_22_5[3] = 0.0

c_22_5[0] = support_structure_volume*0.20e6

support_structure_volume = 0.20*fpc_vol

fpc_vol = ((*FWInboard).volume() + (*FWOutboard).volume() + (*BlanketInboard).volume() + (*BlanketOutboard).volume() + (*BlanketII).volume() + (*RepHTShield)[0].volume() + (*RepHTShield)[1].volume() + 1.1*((*HTShield)[0].volume() + (*HTShield)[1].volume()) + (*VacuumVessel)[0].volume() + (*VacuumVessel)[1].volume() + DivVol + (*TFCoil).volume() + PoloFCVolume + PoloFCVolumeSpares) *16.0

DivVol: for(int i=0; i<6; i++) { DivVol = DivVol + (*Div)[i].volume(); }

PoloFCVolume: for(int i=0; i<36; i++) { PoloFCVolume = PoloFCVolume + (*PoloFCoil)[i].volume() }

PoloFCVolumeSpares: for(int i=4; i<18; i++) { PoloFCVolumeSpares = PoloFCVolumeSpares + (*PoloFCoil)[i].volume() }

c_22_6[1] = 125.0e6*pow(Pth*f_LiPb/2000, 0.55) + 0.01e6*Pth*f_LiPb + 110.0e6*pow(Pth*f_He/2000, 0.55)

c_22_6[2] = 0.0

c_22_6[3] = 0.0

c_22_6[4] = 0.0

f_LiPb = 0.8

f_He = 0.2

c_22_7[1] = 0.0

c_22_7[2] = 0.0

c_22_7[3] = 0.0

c_22_7[0] = 15.0e6*pow(Pfusion/1758.0, 0.8)

c_22_8[1] = 0.0

c_22_8[2] = 0.0

c_22_8[3] = 0.0

c_22_8[4] = 0.0

c_22_8[5] = 0.0

c_22_8[6] = 0.0

c_22_8[7] = 0.0

c_22_8[0] = 70.0e6*pow(Pfusion/1758.0, 0.8)

c_22_9[1] = 0.0

c_22_9[2] = 0.0

c_22_9[3] = 0.0

c_22_9[4] = 0.0

c_22_9[0] = 100.0e6*pow(Pe/1000.0, 0.8)

c_22_10[1] = 0.0

c_22_10[2] = 0.0

c_22_10[3] = 0.0

c_22_10[4] = 0.0

c_22_10[5] = 0.0

c_22_10[0] = 60.0e6

c_22_11[1] = 0.0

c_22_11[2] = 0.0

c_22_11[3] = 0.0

c_22_11[4] = 0.0

c_22_11[5] = 0.0

c_22_11[0] = 8.0e6*pow(Pe/1000.0, 0.8)

c_23[1] = 0.0

c_23[2] = 0.0

c_23[3] = 0.0

c_23[4] = 0.0

c_23[5] = 0.0

c_23[6] = 0.0

c_23[7] = 0.0

c_23[8] = 0.0

c_23[0] = 360.0e6*pow(P_thermal/2000,0.8)*(eta_brayton/0.6)

eta_brayton = (*Machine).gross_electrical_power()/Pth

c_24[1] = 0.0

c_24[2] = 0.0

c_24[3] = 0.0

c_24[4] = 0.0

c_24[5] = 0.0

c_24[6] = 0.0

c_24[7] = 0.0

c_24[8] = 0.0

c_24[9] = 0.0

c_24[0] = 187.0e6*pow(Pet/1200.0, 0.5)

c_25[1] = 0.0

c_25[2] = 0.0

c_25[3] = 0.0

c_25[4] = 0.0

c_25[5] = 0.0

c_25[6] = 0.0

c_25[0] = 89.17e6*((Pth-Pet)/2300.0)

c_26[1] = 0.0

c_26[2] = 0.0

c_26[3] = 0.0

c_26[4] = 0.0

c_26[5] = 0.0

c_26[6] = 0.0

c_26[0] = 85.0e6*pow(Pet/1200.0, 0.6)

c_27[1] = (PbLi_cost/1000.0)*m_LM_total*1.0e6

c_27[2] = (he_vol_in_div + he_vol_in_storage)*he_cost*4.215

c_27[3] = 0.0

c_27[4] = 0.0

c_27[5] = 0.6e6*pow(Pe/1000.0, 0.8)

c_27[6] = 0.4e6*pow(Pe/1000.0, 0.8)

4.215 = ave He density between STP and 700C, 15 MPa

he_cost = (*Div)[0].cost_unit_mass('He')

m_LM_total = BOP*(m_LM + m_LM_div + m_LM_rhts + m_LM_hts)*16.0/1000.0

m_LM = (*FWInboard).liquid_metal_mass() + (*FWOutboard).liquid_metal_mass() + (*BlanketInboard).liquid_metal_mass() + (*BlanketOutboard).liquid_metal_mass() + (*BlanketII).liquid_metal_mass()

m_LM_div: for(int i=0; i<6; i++) { m_LM_div = m_LM_div + (*Div)[i].liquid_metal_mass() }

m_LM_rhts: for(int i=0; i<2; i++) { m_LM_rhts = m_LM_rhts + (*RepHTShield)[i].liquid_metal_mass() }

m_LM_hts: for(int i=0; i<2; i++) { m_LM_hts = m_LM_hts + (*HTShield)[i].liquid_metal_mass() }

BOP = 2.5

he_vol_in_div = div_vol*16.0*BOP*he_frac_div

he_frac_div = 0.526

div_vol: for(int i=0; i<6; i++) { div_vol = div_vol + (*Div)[i].volume(); }

he_vol_in_storage = he_vol_in_div*0.10

mhtt_vol = ((*FWInboard).volume() + (*FWOutboard).volume() + (*BlanketInboard).volume() + (*BlanketOutboard).volume() + (*BlanketII).volume() + (*RepHTShield)[0].volume() + (*RepHTShield)[1].volume() + pen_shielding*((*HTShield)[0].volume() + (*HTShield)[1].volume()) )*16.0*BOP

c_90 = c_20[0] + c_21[0] + c_22[0] + c_23[0] + c_24[0] + c_25[0] + c_26[0] + c_27[0]

c_91[1] = 0.0

c_91[2] = 0.0

c_91[3] = 0.0

c_91[0] = 0.1130*c_90

c_92[1] = 0.0

c_92[2] = 0.0

c_92[3] = 0.0

c_92[4] = 0.0

c_92[0] = 0.052*c_90

c_93[1] = 0.0

c_93[2] = 0.0

c_93[3] = 0.0

c_93[0] = 0.052*c_90

c_94[1] = 0.0

c_94[2] = 0.0

c_94[3] = 0.0

c_94[0] = 0.15*(c_90 + c_91[0] + c_92[0] + c_93[0])

c_95 = 0.0*c_90

c_96 = 0.1465*(c_90 + c_91[0] + c_92[0] + c_93[0] + c_94[0] + c_95)

c_97 = fidc*(c_90 + c_91[0] + c_92[0] + c_93[0] + c_94[0] + c_95 + c_96)

fidc = 0.1303

c_98 = fedc*c_90

fedc = 0.0

c_99 = c_90 + c_91[0] + c_92[0] + c_93[0] + c_94[0] + c_95 + c_96 + c_97 + c_98

cost_Of_Electricity = (c_AC + (c_OM + c_SCR + c_F) * pow(1.0 + y,Y)) / (8760.0*Pe*pf) + c_DD

** See input file costing.data for input parameters: Xrdr, Lecon, neutron_fluence_life, y, Y, pf, c_F, c_DD.

fcr = Xrdr/( 1.0 - pow(1.0+Xrdr, -Lecon))

c_AC = fcr*c_99

Pe = (*Machine).net_electrical_power()

c_OM = 80.0e6*pow(Pe/1200.0, 0.5)

FWB_life = neutron_fluence_life/nwlmax

nwlmax = (*Machine).neutron_wall_load('maximum')

c_SCR = (c_22_1[1] + c_22_1[3] + c_22_1[4] + c_22_3_1[0] + c_22_3_4[0] + c_22_4[5]) / (FWB_life/pf)

c_AC = fcr*c_99

coe_subcost[0] = c_AC /(8760.0*Pe*pf)

coe_subcost[1] = c_OM*pow(1.0+y, Y) /(8760.0*Pe*pf)

coe_subcost[2] = c_SCR*pow(1.0+y, Y) /(8760.0*Pe*pf)

coe_subcost[3] = c_F*pow(1.0+y, Y) /(8760.0*Pe*pf)

coe_subcost[4] = c_DD

Part Compositions

Part Compositions for Tokamak Power Plant using SiC Blanket Module:

Part	Material	Volume Frac	Density Frac	Den (kg/m3)	Cost/unit mass	Cost Base Year
----------------------------------------------------------------------------------------------------------------------
FirstWallInboard	SiC-comp	0.73	0.95	3200	584.64	2009
FirstWallInboard	PbLi	0.27	0	8897	8.79	2009
FirstWallOutboard	SiC-comp	0.73	0.95	3200	584.64	2009
FirstWallOutboard	PbLi	0.27	0	8897	8.79	2009
BlanketInboard	SiC-comp	0.17	0.95	3200	584.64	2009
BlanketInboard	PbLi	0.83	0	8897	8.79	2009
BlanketOutboard	SiC-comp	0.17	0.95	3200	584.64	2009
BlanketOutboard	PbLi	0.83	0	8897	8.79	2009
BlanketII	SiC-comp	0.2	0.95	3200	584.64	2009
BlanketII	PbLi	0.77	0	8897	8.79	2009
BlanketII	W	0.03	1	19300	120.37	2009
Div1	RAFS-div	0.108	1	7800	111.77	2009
Div1	W	0.359	1	19300	120.37	2009
Div1	He	0.526	0	0.1786	70	2011
Div1	Void	0.07	0	0	0	2009
Div2	RAFS-div	0.108	1	7800	111.77	2009
Div2	W	0.359	1	19300	120.37	2009
Div2	He	0.526	0	0.1786	70	2011
Div2	Void	0.07	0	0	0	2009
Div3	RAFS-div	0.108	1	7800	111.77	2009
Div3	W	0.359	1	19300	120.37	2009
Div3	He	0.526	0	0.1786	70	2011
Div3	Void	0.07	0	0	0	2009
Div4	RAFS-div	0.108	1	7800	111.77	2009
Div4	W	0.359	1	19300	120.37	2009
Div4	He	0.526	0	0.1786	70	2011
Div4	Void	0.07	0	0	0	2009
Div5	RAFS-div	0.108	1	7800	111.77	2009
Div5	W	0.359	1	19300	120.37	2009
Div5	He	0.526	0	0.1786	70	2011
Div5	Void	0.07	0	0	0	2009
Div6	RAFS-div	0.108	1	7800	111.77	2009
Div6	W	0.359	1	19300	120.37	2009
Div6	He	0.526	0	0.1786	70	2011
Div6	Void	0.07	0	0	0	2009
RepHTShieldTop	SiC-comp	0.15	0.95	3200	584.64	2009
RepHTShieldTop	PbLi	0.1	0	8897	8.79	2009
RepHTShieldTop	B-FS	0.75	1	7800	35.54	2009
RepHTShieldBottom	SiC-comp	0.15	0.95	3200	584.64	2009
RepHTShieldBottom	PbLi	0.1	0	8897	8.79	2009
RepHTShieldBottom	B-FS	0.75	1	7800	35.54	2009
HTShieldInboard	SiC-comp	0.15	0.95	3200	584.64	2009
HTShieldInboard	PbLi	0.1	0	8897	8.79	2009
HTShieldInboard	W	0.05	1	19300	120.37	2009
HTShieldInboard	B-FS	0.7	1	7800	35.54	2009
HTShieldOutboard	SiC-comp	0.15	0.95	3200	584.64	2009
HTShieldOutboard	PbLi	0.1	0	8897	8.79	2009
HTShieldOutboard	B-FS	0.75	1	7800	35.54	2009
VacuumVesselMain	RAFS	0.13	1	9500	43.44	2009
VacuumVesselMain	Void	0.22	0	0	0	2009
VacuumVesselMain	WC	0.65	0.95	15600	34.39	2009
VacuumVesselOutboard	RAFS	0.3	1	9500	43.44	2009
VacuumVesselOutboard	Void	0.7	0	0	0	2009
TFMagnet	SS316	0.735174	1	7860	68.657	1992
TFMagnet	Nb3Sn	0.020899	1	7500	92.7	1992
TFMagnet	Cu	0.124391	1	7300	65.4	1992
TFMagnet	Inconel	0.0266081	1	8440	96.02	2009
TFMagnet	Polyamide	0.0264458	1	1920	16.516	1992
BuckingCylinder	RAFS	1	1	9500	43.44	2009
UpperCap	RAFS	1	1	9500	43.44	2009
LowerCap	RAFS	1	1	9500	43.44	2009
MaintenancePortOpening	TF-coil	1	1	7500	50.912	1992
PFCoil_0	PF-coil	1	1	7500	82.919	1992
PFCoil_1	PF-coil	1	1	7500	82.919	1992
PFCoil_2	PF-coil	1	1	7500	82.919	1992
PFCoil_3	PF-coil	1	1	7500	82.919	1992
PFCoil_4	PF-coil	1	1	7500	82.919	1992
PFCoil_5	PF-coil	1	1	7500	82.919	1992
PFCoil_6	PF-coil	1	1	7500	82.919	1992
PFCoil_7	PF-coil	1	1	7500	82.919	1992
PFCoil_8	PF-coil	1	1	7500	82.919	1992
PFCoil_9	PF-coil	1	1	7500	82.919	1992
PFCoil_10	PF-coil	1	1	7500	82.919	1992
PFCoil_11	PF-coil	1	1	7500	82.919	1992
PFCoil_12	PF-coil	1	1	7500	82.919	1992
PFCoil_13	PF-coil	1	1	7500	82.919	1992
PFCoil_14	PF-coil	1	1	7500	82.919	1992
PFCoil_15	PF-coil	1	1	7500	82.919	1992
PFCoil_16	PF-coil	1	1	7500	82.919	1992
PFCoil_17	PF-coil	1	1	7500	82.919	1992
PFCoil_18	PF-coil	1	1	7500	82.919	1992
PFCoil_19	PF-coil	1	1	7500	82.919	1992
PFCoil_20	PF-coil	1	1	7500	82.919	1992
PFCoil_21	PF-coil	1	1	7500	82.919	1992
PFCoil_22	PF-coil	1	1	7500	82.919	1992
PFCoil_23	PF-coil	1	1	7500	82.919	1992
PFCoil_24	PF-coil	1	1	7500	82.919	1992
PFCoil_25	PF-coil	1	1	7500	82.919	1992
PFCoil_26	PF-coil	1	1	7500	82.919	1992
PFCoil_27	PF-coil	1	1	7500	82.919	1992
PFCoil_28	PF-coil	1	1	7500	82.919	1992
PFCoil_29	PF-coil	1	1	7500	82.919	1992
PFCoil_30	PF-coil	1	1	7500	82.919	1992
PFCoil_31	PF-coil	1	1	7500	82.919	1992
PFCoil_32	PF-coil	1	1	7500	82.919	1992
PFCoil_33	PF-coil	1	1	7500	82.919	1992
PFCoil_34	PF-coil	1	1	7500	82.919	1992
PFCoil_35	PF-coil	1	1	7500	82.919	1992
CryoDome	RAFS-cryost	0.18	1	7800	28.06	2009
CryoDome	Void	0.82	0	0	0	2009
MaintenancePort	B-FS	0.13	1	7800	35.54	2009
MaintenancePort	Void	0.22	0	0	0	2009
MaintenancePort	WC	0.65	0.95	15600	34.39	2009
UpperVVDuctBottomWall	B-FS	0.13	1	7800	35.54	2009
UpperVVDuctBottomWall	Void	0.22	0	0	0	2009
UpperVVDuctBottomWall	WC	0.65	0.95	15600	34.39	2009
UpperVVDuctTopWall	B-FS	0.13	1	7800	35.54	2009
UpperVVDuctTopWall	Void	0.22	0	0	0	2009
UpperVVDuctTopWall	WC	0.65	0.95	15600	34.39	2009
UpperVVDuctSideWall	B-FS	0.13	1	7800	35.54	2009
UpperVVDuctSideWall	Void	0.22	0	0	0	2009
UpperVVDuctSideWall	WC	0.65	0.95	15600	34.39	2009

2D CAD drawing – PNG

2D CAD drawing – TIF