High Current Superconducting RF and RF Control - PowerPoint PPT Presentation

1 / 21
About This Presentation
Title:

High Current Superconducting RF and RF Control

Description:

... have greatly reduced the cost of similar high tech systems ... MRI-magnetic resonance imaging (GE Medical Systems) Cancer Therapy (Varian Medical Systems) ... – PowerPoint PPT presentation

Number of Views:38
Avg rating:3.0/5.0
Slides: 22
Provided by: NSCL2
Category:

less

Transcript and Presenter's Notes

Title: High Current Superconducting RF and RF Control


1
High Current Superconducting RFand RF Control
  • Terry L. Grimm
  • Niowave
  • Michigan State University

2
Outline
  • SRF working group charge
  • Cost impediment and mass production
  • Requirements
  • Synergy
  • Critical items and discussion
  • Conclusion

3
Working Group Charge
  • Challenges for the application of SRF to ERLs
  • Identify critical SRF items
  • Evaluate readiness of SRF
  • Organize RD effort internationally

4
High Cost
  • Primary impediment to the application of SRF to
    ERLs is cost
  • Time
  • Money
  • SRF technology already shown to work
  • Progress and advancements are ongoing

Assembly Line Mass Production
One of a Kind State of the Art
5
Examples of Cost Savings
  • Commercialization and competition have greatly
    reduced the cost of similar high tech systems

Microwave Oven
MRI-magnetic resonance imaging (GE Medical
Systems)
Cancer Therapy (Varian Medical Systems)
6
Requirements
  • Moderate gradients (10-20 MV/m)
  • High current (milliamp to ampere level)
  • Continuous wave (cw) operation
  • Low cryogenic load
  • Efficient use of RF power
  • Affordable

7
Synergy
  • SRF advances being made for other applications
  • High energy physics (ILC, neutrino source)
  • Nuclear physics
  • Light sources (ring based)
  • Heavy ion linacs (neutron source, radioactive
    beam facility, transmutation)
  • Capitalize on those investments and advancements

8
Critical SRF items
  • Affordable cost
  • Cavity design
  • Cryogenic load
  • RF power source
  • RF control
  • Cryomodule design
  • Assembly method
  • Power coupler
  • HOM damping
  • Frequency tuner
  • Microphonics
  • Lorentz force detuning
  • Cryogenic distribution

9
Affordable Cost
  • Typical/rough cost of an ERL facility
  • 25 Cryomodules beamlines
  • 25 RF and magnet power/controls
  • 25 Cryoplant distribution
  • 25 Civil infrastructure
  • Must consider all aspects and their implications
    on the other systems to minimize the cost

10
Cavity Design 1
  • Material
  • High purity bulk niobium (RRR300)
  • More vendors entering the market so the price
    will continue to drop
  • Fine and large grain
  • Cutting material directly from the ingot may
    reduce costs
  • In the future advanced materials may help
  • Nb/Cu, Nb3Sn, MgB2,
  • Type
  • Elliptical, reentrant, half-reentrant
  • Consider designs with higher Ep/Ea lower cryo
    losses
  • Lower Bp/Ea
  • Higher G(R/Q)

11
Cavity Design 2
Fill
Drain
Flip 180
Has the potential to achieve gt50
MV/m Initial tests reached 24.6 MV/m
Positioned to avoid gas pockets
Acid/water can drain
Electric Magnetic field contours
12
Cavity Design 3
  • Frequency
  • Tradeoff with many parameters
  • Existing machines and typical frequencies
  • Lower frequency requires less cells, has lower
    BCS losses, and has less HOM issues
  • Cell to cell coupling
  • 1.5 to 1.9 to maintain field flatness
  • HOM requirements will likely require a larger
    value

13
Cavity Design 4
  • Number of cells
  • Consider more cells if higher cell to cell
    coupling low coupler power
  • Accelerating gradient
  • 10-20 MV/m based on cost minimization with the
    cryoplant
  • Use simple chemical etching (BCP) since not
    pushing the limit
  • Quality factor, Q
  • Plan on residual resistance less than 10 n?
  • Design value based on choice of temperature and
    safety margin

14
Cryogenic Load
  • Cryoplant costs are a significant fraction of an
    ERL
  • Typically 2 K (super-fluid, sub-atmospheric) or
    4.5 K (above atmospheric pressure)
  • 2 K plant has lower mechanical and Carnot
    efficiency, and costs more per watt, but needed
    for high frequency
  • Portable applications would benefit from
    operation at 4.5 K (above atmospheric pressure)
  • Above atmospheric pressure and simpler, with the
    option to just supply liquid via a storage Dewar
  • Push to lower frequency (lt500 MHz)

15
RF Power Source
  • Many options
  • Solid state, tetrode, IOT, klystron, magnetron
  • Industrial cw frequencies (klystron magnetron)
  • 500 MHz
  • 900 MHz
  • 2.45 GHz
  • May choose the frequency based on the
    availability and cost of the RF sources

16
Cryomodule Design 1
  • Assembly method
  • Method of putting the ship in the bottle will
    drive the entire design
  • Insert the cold mass axially into the cylindrical
    vacuum vessel
  • Assemble shields (thermal and magnetic) and
    vaccuum vessel around the cold mass
  • Power coupler
  • Coaxial or waveguide
  • Ceramic window (disc or tube typically)
  • Consider better integration with the rf source
    and its output power coupler
  • HOM damping
  • Ferrites, waveguide and lumped circuit HOM
    couplers
  • Consider using the power coupler for HOM damping

17
Cryomodule Design 2
  • Frequency tuner
  • cw operation does not require a rigid tuner
  • Consider placing the stepper motor and piezo
    actuator at room temperature outside the vacuum
    via a mechanical linkage
  • Microphonics
  • Vibrations caused by rotating machinery
  • Discrete frequencies so easy to cancel
  • Damp source, transmission or use adaptive
    feedforward cancellation
  • Already demonstrated loaded-Qs of 107- 108

18
Cryomodule Design 3
  • Lorentz force detuning
  • cw operation so not a major concern
  • Consider simpler stiffening of the cavity and
    tuner
  • Cryogenic distribution
  • 2 K JT valve and heat exchanger location
  • Bayonets or welded connections
  • Bayonets large thermal load, double O-ring with
    guard vacuum and interlocks to avoid
    contamination of the liquid He
  • Welded connections requires cutting/grinding
    for removal, single vacuum break

19
RF Controls
  • Digital control systems continue to improve with
    higher speed and capability
  • Feedback to control beam instabilities
  • Feedback for transients
  • Simplify tuning and operation
  • No longer a critical item, especially for cw
    applications
  • Well established
  • Cost will continue to decrease

20
Conclusion
  • Superconducting RF is ready to be applied to
    Energy Recovery Linacs
  • Capabilities cost will continue to improve
  • RD for other applications will advance ERLs
  • RD specifically for ERLs is needed
  • This biannual workshop is an excellent start to
    organize international effort

21
Examples of Cost Savings
  • Commercialization and competition have greatly
    reduced the cost of similar high tech systems

Microwave Oven
MRI-magnetic resonance imaging (GE Medical
Systems)
Cancer Therapy (Varian Medical Systems)
Write a Comment
User Comments (0)
About PowerShow.com