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October 24, 2001 1 1. Remaining Action Items on Dry Chamber Wall 2. “Overlap” Design Regions 3. Scoping Analysis of Sacrificial Wall A. R. Raffray, J.

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Presentation on theme: "October 24, 2001 1 1. Remaining Action Items on Dry Chamber Wall 2. “Overlap” Design Regions 3. Scoping Analysis of Sacrificial Wall A. R. Raffray, J."— Presentation transcript:

1 October 24, 2001 1 1. Remaining Action Items on Dry Chamber Wall 2. “Overlap” Design Regions 3. Scoping Analysis of Sacrificial Wall A. R. Raffray, J. Pulsifer, M. S. Tillack, X. Wang, M. Zaghloul University of California, San Diego ARIES E-Meeting October 24, 2001

2 2 Accuracy of Simplified Assumption Used to Estimate Temporal Distribution of Energy Depositions Photons Debris Ions Time 10ns 0.2  s 1s1s 2.5  s Fast Ions Energy Deposition Temporal Distribution of Energy Depositions from Ions for Direct Drive Spectra and Chamber Radius of 6.5 m Simplified Temporal Distribution of Energy Depositions from Photons and Ions Assumed in Early Calculations

3 October 24, 2001 3 Spatial Temperature Profiles in Example Flat Carbon Wall at Different Times Under Energy Deposition from Photons and Ions for Direct Drive Target Simple Assumption Case Accurate Temporal Distribution Case Temperature Profiles are Very SimilarMax. C Temp. for Simple Assumption Case (~1530°C) > More Accurate Case (~ 1460°C)Simple Assumption Adequate for Scaling Analysis

4 October 24, 2001 4 Reminder: Please Send Me Your Contributions on the Dry Wall Paper ASSESSMENT OF IFE DRY CHAMBER WALL (TO BE PUBLISHED IN FUSION ENGINEERING & DESIGN ) A. R. Raffray, R. R. Peterson, M. Billone, L. El-Guebaly, G. Federici, D. Goodin, A. Hassanein, D. Haynes, R. Moore, F. Najmabadi, D. Petti, R. Petzoldt, M.S. Tillack, X. Wang, M. Zaghloul Last Reminder Sent on October 2, 2001, Including Latest Outline and Expected Contributions Contributions Due by the End of October

5 October 24, 2001 5 Overlap Points Simple self consistent calculationDriver parameters Chamber geometry and chamber wall design Power to chamber wall Coolant outlet temperature Cycle efficiency Thermal-hydraulic parameters Maximum temperature of chamber wall -Chamber wall power assumed to be spread over the complete period between successive shots (optimistic assumption) Run a few example cases with the goal of maintaining SiC f /SiC T max at the wall < 1000°C -Results will show acceptable combination of parameters (design window) -e.g. limit on chamber size for a given power output

6 October 24, 2001 6 Example Temperature History for Tungsten Flat Wall Under Energy Deposition from Indirect-Drive Spectra Chamber Wall Coolant Inlet Energy Front Assume Channel L =  R 4-mm SiC f /SiC Wall Chamber Wall Coolant Outlet 5-mm Cooling Channel Max. SiC f /SiC Temp. 1-mm W Armor Direct Drive: Driver Energy = 1.2 MJ Gain = 128 Yield = 153.6 MJ Driver Efficiency = 0.07 Indirect Drive: Driver Energy = 3.3 MJ Gain = 139 Yield = 458.7 MJ Driver Efficiency = 0.25

7 October 24, 2001 7 Parametric Studies for Dry Wall with Direct Drive Target Under Constraint: T max,SiC/SiC < 1000°C

8 October 24, 2001 8 Combination of Parameters to Maintain T max,SiC/SiC < 1000°C for Direct Drive Target Adjust coolant outlet temperature (and hence cycle eff.) as a function of chamber radius to maintain SiC f /SiC Temp. < 1000°C Fusion power = 1690 MW Direct Drive: Driver Energy = 1.2 MJ Gain = 128 Yield = 153.6 MJ Driver Efficiency = 0.07 Example trade-off - What is preferable: a 5.2-m chamber with 7 Hz rep rate and 500 MWe or a 7.3-m chamber with 14.2 Hz rep rate and 1000MWe? Preferable to operate with higher cycle efficiency for given fusion power

9 October 24, 2001 9 Parametric Studies for Dry Wall with Indirect Drive Target Under Constraint: T max,SiC/SiC < 1000°C

10 October 24, 2001 10 Combination of Parameters to Maintain T max,SiC/SiC < 1000°C for Indirect Drive Target Adjust coolant outlet temperature (and hence cycle eff.) as a function of chamber radius to maintain SiC f /SiC Temp. < 1000°C Indirect Drive: Driver Energy = 3.3 MJ Gain = 139 Yield = 458.7 MJ Driver Efficiency = 0.25 Example trade-off - What is preferable: a 5-m chamber with 2 Hz rep rate and 500 MWe or a 6.9-m chamber with 4 Hz rep rate and 1000MWe?

11 October 24, 2001 11 Choice of Strawman Parameters See strawman file -Parameters correspond to 1000MWe -It is not clear if a smaller chamber with lower electrical power would provide cost benefit -However, if a smaller chamber size is required by other considerations (e.g. target injection) we should change the parameters to accommodate this

12 October 24, 2001 12 liquid vapor X-ray, gamma & neutron preheating phase: Ion heating phase: background2-phase Transport phase: radiation convection Scoping Analysis of Chamber Recovery Time for Sacrificial Wall Concept Concern about creating quiescent atmosphere in time for next shot : Time scale of recovery mechanisms, e.g: -Condensation -Clearing -Aerosol evacuation Initial effort on scoping analysis of time scale for recondensation

13 October 24, 2001 13 Schematic of RECON Model for Estimating Evaporation/Recondensation Following Chamber Micro-Explosion Simple 1-D Model Initially Developed for PROMETHEUS Analysis (M. Tillack) - Conduction through wall and convection to coolant -Wall temperature estimated from quasi steady-state heat flux and coolant temperature -Evaporation/condensation at liquid wall surface -X-ray energy attenuated in chamber gas and in liquid wall -Radiation between chamber vapor and wall -Ion energy assumed to be deposited in chamber vapor only Coolant Vapor Wall Convection Conduction Film Radiation

14 October 24, 2001 14 Using RECON to Help in Sacrificial Wall Analysis and Assessment Major issue about “long term” chamber dynamics e.g. How long does it take for chamber to return to desired pre-shot conditions Key processes and parameters include: -vapor condensation -vapor radiation -heat transfer to coolant (influencing liquid wall temperature) -Pressure of chamber gas -Rep rate -Chamber size -Coolant temperature Proposed Action Plan -Validation case from one remaining run from PROMETHEUS -Try to adapt RECON to provide solutions for the DD and ID target parameters -Assess accuracy and usefulness of results -Perform initial parametric analysis to assess relative importance of various parameters -Make assessment of combinations of parameters (design window analysis)

15 October 24, 2001 15 Comparison of RECON Run with PROMETHEUS Results for Pb Pb vapor temperature history Pb vapor pressure history

16 October 24, 2001 16 Example Parametric Runs for Pb Film Effect of background gas pressure on Pb vapor pressure history following shot -Affects vapor recondensation rate Effect of background gas pressure on Pb vapor temperature history following shot

17 October 24, 2001 17 Effect of coolant temperature on Pb vapor pressure history Effect of Coolant Temperature and of Wall Heat Transfer Capability on Pb Vapor Pressure History Following Shot Effect of wall conduction and convection to coolant on Pb vapor pressure history

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