1. Overview of the RFCC Module and 201-MHz Cavity Design
RFCC Module RF Cavity Design Review
October 21, 2008
Derun Li
Lawrence Berkeley National Laboratory

2. Outline
Introduction of RFCC module of MICE cooling channel and charge of the review
Review of the 201-MHz cavity design
MuCool 201-MHz prototype cavity: baseline design for MICE
Physics design and cavity fabrications
Cavity body
RF coupler
Be windows
Tuners
Recent progress
Vendor identification
Engineering CAD model and FEA analysis
Tuners and cavity support
Integration and interface
Schedule
Overview of the RFCC Module and 201-MHz Cavity Design
Derun Li - Lawrence Berkeley National Lab - October 21, 2008

3. Eight 201-MHz Cavities for MICE
Eight 201-MHz RF cavities
MICE Cooling Channel
Courtesy of S. Q. Yang, Oxford Univ.
RFCC modules
Overview of the RFCC Module and 201-MHz Cavity Design
Derun Li - Lawrence Berkeley National Lab - October 21, 2008

4. RFCC Module SC coupling Coil Curved Be window Cavity Couplers
Vacuum Pump
201-MHz cavity
Curved
Be window
Overview of the RFCC Module and 201-MHz Cavity Design
Derun Li - Lawrence Berkeley National Lab - October 21, 2008

5. Charge of this Review
Evaluate the engineering design of RFCC module and the RF cavity
Evaluate engineering design and fabrication schemes of the 201-MHz cavity
Spinning of cavity shells
e-beam welding
Port extruding
Tuners
Cavity support
Cavity assembly
Evaluate overall module concept
Interface with other modules
Site interfaces
Integration and shipping
Detailed design of CC is not part of this review
CC design review scheduled: Dec. 6-8, 2008 at ICST of HIT, Harbin
Overview of the RFCC Module and 201-MHz Cavity Design
Derun Li - Lawrence Berkeley National Lab - October 21, 2008

6. RFCC & Cavity Design Review Agenda
15:300 – 18:30 October 21, 2008 at RAL
Overview of RFCC Module and Recent Progress Li
201 MHz Cavity Fabrication Plan DeMello
Assembly, Installation and Interface Virostek
Coffee break
RFCC Module and Subcomponents Mechanical Design DeMello
Schedule and Manpower Virostek
Discussion
Executive Session Committee
Closeout
Overview of the RFCC Module and 201-MHz Cavity Design
Derun Li - Lawrence Berkeley National Lab - October 21, 2008

7. MICE RF Cavity Summary
MICE RF cavity design is based on the successful prototype cavity for the US MuCool program
Fabrication of the prototype cavity was successful
A slight reduction in cavity diameter to raise the frequency has been specified and analyzed
The fabrication techniques used to produce the prototype will be used to fabricate the MICE RF cavities
Preliminary cavity design was reviewed at CM21 at DL
Copper sheets have been ordered and expected to arrive mid-December 2008
A detailed WBS schedule for the design and fabrication of the MICE RF cavities has been developed
Overview of the RFCC Module and 201-MHz Cavity Design
Derun Li - Lawrence Berkeley National Lab - October 21, 2008

8. MICE RF Cavity Design
3-D Microwave Studio RF parameterized model including ports and curved Be windows to simulate frequency, Epeak, etc.
Hard to reach the design frequency by spinning technique
Frequencies between cavities should be able to achieve within  100 kHz
Approaches
Modification the prototype spinning form
Targeting for higher frequency
Fixed tuner to tune cavity close to design frequency (deformation of cavity body)
Tuners are in push-in mode  lower frequency
Overview of the RFCC Module and 201-MHz Cavity Design
Derun Li - Lawrence Berkeley National Lab - October 21, 2008

9. Cavity Design Parameters
The cavity design parameters
Frequency: MHz
β = 0.87
Shunt impedance (VT2/P): ~ 22 MΩ/m
Quality factor (Q0): ~ 53,500
Be window diameter and thickness: 42-cm and 0.38-mm
Nominal parameters for MICE and cooling channels in a neutrino factory
8 MV/m (~16 MV/m) peak accelerating field
Peak input RF power: 1 MW (~4.6 MW) per cavity
Average power dissipation per cavity: 1 kW (~8.4 kW)
Average power dissipation per Be window: 12 watts (~100 watts)
Overview of the RFCC Module and 201-MHz Cavity Design
Derun Li - Lawrence Berkeley National Lab - October 21, 2008

10. 201 MHz Cavity Concept
Spinning of half shells using thin copper sheets and e-beam welding to join the shells; extruding of four ports; each cavity has two pre-curved Beryllium windows, but also accommodates different windows
Overview of the RFCC Module and 201-MHz Cavity Design
Derun Li - Lawrence Berkeley National Lab - October 21, 2008

11. RF Cavity Fabrication Overview
The same fabrication techniques used to make the prototype cavity will be used for the MICE RF cavities
Engineering CAD Model of the RF Cavity
Cavity half-shells to be formed by metal spinning
Precision milling of large parts (1.2 m diameter)
Precision turning of mid-sized parts (0.6 m dia.)
Precision manufacture of smaller parts
CMM measurements throughout the process
To limit any annealing and maintain cavity strength, e-beam welding will be used for all cavity welding
cavity equator, stiffener rings, nose rings, port annealing and port flanges
Cavity inside surfaces are finished by electro-polishing
Prototype RF Cavity
Overview of the RFCC Module and 201-MHz Cavity Design
Derun Li - Lawrence Berkeley National Lab - October 21, 2008

12. Progress Summary RF Cavities Cavity tuners Material to arrive 12/08
Fabrication steps identified
RF, thermal, structural analyses done
Detailed design complete
Fabrication drawings nearly done
Vendor qualification under way
Be windows being ordered
Final vendor selection not complete
Electropolish not fully defined
Cavity tuners
RF, structural analyses complete
Actuation cylinder type identified
Detailed design, drawings not complete
Overview of the RFCC Module and 201-MHz Cavity Design
Derun Li - Lawrence Berkeley National Lab - October 21, 2008

13. Progress Summary (cont.)
Cavity Struts
Structural analysis complete
LBNL standard detailed design
Fabrication, installation dwgs not done
Coupling Coil Interface
Magnet gusset mod sent to ICST
Additional interface details TBD
Cavity Cooling Water
Feedthrough concept developed
Detailed design not complete
Overview of the RFCC Module and 201-MHz Cavity Design
Derun Li - Lawrence Berkeley National Lab - October 21, 2008

14. Progress Summary (cont.)
Module Vacuum Vessel
Conceptual design/CAD model complete
Structural analysis not complete
Detailed design, drawings not complete
Module Vacuum System
Conceptual design complete
Lumped parameter analysis soon
Failure analysis not complete
RF Couplers
Design previously developed for MuCool cavity
Modifications for MICE not complete
vacuum
Overview of the RFCC Module and 201-MHz Cavity Design
Derun Li - Lawrence Berkeley National Lab - October 21, 2008

15. Progress: Other Module Components
Beryllium Window
Dynamic Tuners
Cavity Suspension
Vacuum System
RF Coupler
Module Support
DeMello’s talk for more details
Overview of the RFCC Module and 201-MHz Cavity Design
Derun Li - Lawrence Berkeley National Lab - October 21, 2008 15

16. Liquid Nitrogen Cooling Considerations
Suspension of cavities on struts provides low heat leak from cavity to vacuum vessel
Beryllium window FEA thermal analysis will need to be performed with new parameters
The cavity frequency will be shifted (approximately 600 kHz), therefore tuning system or RF power source modifications will be needed
Insulators will need to be added to the RF couplers
Coaxial LN feedthrough tubes will be needed to insulate the connection outside of vacuum
Overview of the RFCC Module and 201-MHz Cavity Design
Derun Li - Lawrence Berkeley National Lab - October 21, 2008

17. Summary
Good progress since last CM and review, details of technical designs, interface and schedules (DeMello and Virostek)
Responses to last review (DeMello)
RFCC & Cavity Design Review Agenda
(15:30 – 18:30 October 21, 2008 at RAL)
Overview of RFCC Module and Recent Progress Li
201 MHz Cavity Fabrication Plan DeMello
Assembly, Installation and Interface Virostek
Coffee break
RFCC Module and Subcomponents Mechanical Design DeMello
Schedule and Manpower Virostek
Discussion
Executive Session Committee
Closeout
Overview of the RFCC Module and 201-MHz Cavity Design
Derun Li - Lawrence Berkeley National Lab - October 21, 2008