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PIP-II Solenoid Focusing lens for SSR2 Cryomodule Kumud Singh, Affiliation: Bhabha Atomic Research Centre PIP-II Technical Meeting 19 Jan 2016.

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Presentation on theme: "PIP-II Solenoid Focusing lens for SSR2 Cryomodule Kumud Singh, Affiliation: Bhabha Atomic Research Centre PIP-II Technical Meeting 19 Jan 2016."— Presentation transcript:

1 PIP-II Solenoid Focusing lens for SSR2 Cryomodule Kumud Singh, Affiliation: Bhabha Atomic Research Centre PIP-II Technical Meeting 19 Jan 2016

2 Outline K.Singh- SSR2 Focusing Lens Design201/19/2016  Introduction  EM design and parameters  Fringe field on cavity surface  Tolerance studies for Bucking coil Geometrical parameters  Operating curve  Quench Analysis  Quench Initiated in MC coil  Quench Initiated in BC coil  Scope and Schedule  Test and Measurement Plan  Summary and next steps  References

3 SSR2 Cryomodule For PIP-II Each cryomodule of the SSR2 section of the PIP-II linac contains five 325 MHz superconducting single spoke cavities and three solenoid-based focusing lenses operating at 2 K. The total number of SSR2 focusing lenses to be built for the PIP-II accelerator is 25 (including four spare devices). 01/19/2016K.Singh- SSR2 Focusing Lens Design3 Magnet Cavity string arrangement for SSR2 cryomodule for PIP-II (Figure shown for representation purpose only ; not true scale drawing) 0.75m

4 Functional requirement Specifications K.Singh- SSR2 Focusing Lens Design401/19/2016 ParametersSpecified SSR1 Specified SSR2 Focusing Strength 4 T 2 m5 T 2 m Bending strength of Dipole correctors 2.5 mT-m5 mT-m Beam pipe aperture30 mm40 mm Uncertainty in the location of magnetic axis w.r.t Reference points (Transverse and angular alignment) <0.5 mm RMS <1 mrad RMS <0.1mm RMS <0.5 mrad RMS Effective length of solenoid (FWHM) Not constrained<15 cm Active magnetic shielding requirements 0.5Q 0 criterionminimal Maximum current in the solenoid 100A Maximum current in the dipole correctors 50A  Main design features of the SSR2 lens are quite similar to SSR1 Focusing lens.  A new design is suggested and verified to meet the main requirements because of increased beam aperture and focusing strength for SSR2.  Focusing strength and Fringe field on the SSR2 cavity surface has been optimized for PIP-II.

5 K.Singh- SSR2 Focusing Lens Design501/19/2016 EM design and parameters 60.6 mm 44.4mm 50 mm 145 mm 169 mm Beam pipe aperture 40 mm 105.5 mm 150 mm Sr. noParameterValueUnit 1. Designed value of focusing strength 5.33T2mT2m 2. Magnetic Field Integral1.01T-m 3. Peak transverse Magnetic field in the lens aperture 6.22T 4. Peak Magnetic field on the wire strand 6.878T 5. Nominal current77.4A 6. Nominal Current Density260A/mm 2 7. B max at the cavity Surface0.179 Gauss 8. Field Integral (along the radial line 0 to 0.3m) at axial Distance of 0.5 mm 3.9G-cm

6 Fringe Field on cavity surface 01/19/2016K.Singh- SSR2 Focusing Lens Design6

7 Tolerance studies on Bucking Coil Geometrical parameters K.Singh- SSR2 Focusing Lens Design701/19/2016  Tight tolerance is required for the bucking coil winding dimensions and its placement w.r.t main coil.  The positional inaccuracy of the Bucking coil effects the fringe magnetic field on the cavity surface.

8 Operating Curve for the SSR2 focusing lens 01/19/2016K.Singh- SSR2 Focusing Lens Design8

9 Dipole Corrector Coil K.Singh- SSR2 Focusing Lens Design901/19/2016 Sr. noParameterValueUnit 1. Designed value of Bending strength of corrector coils 5.25mT-m 2. Designed value of integrated Gradient of focusing quadrupole 0.2T 3.Nominal current~39.2A

10 Combined Field Simulation 01/19/2016K.Singh- SSR2 Focusing Lens Design10 Fringe field on the cavity surface increases slightly when DC coil powered on with MC coil but field values are still within the acceptable limits

11 Quench Analysis 01/19/2016K.Singh- SSR2 Focusing Lens Design11

12 Quench Initiated in Main Coil K.Singh- SSR2 Focusing Lens Design1201/19/2016 Quench initiated at t=0.1s Quench propagation at t=0.175s Quench propagation at t=0.105s Quench propagation at t=0.3s Quench propagation at t=0.5s Quench propagation at t= 20 s

13 Quench Initiated in Main Coil 01/19/2016K.Singh- SSR2 Focusing Lens Design13 Temperature rise in main coil after quench initiation Energy Dissipation in main coil

14 Quench Initiated in Main Coil K.Singh- SSR2 Focusing Lens Design1401/19/2016 Coil resistance growth in main coil after quench initiation di/dt across main coil and bucking coil after quench initiation Current decay in main coil and bucking coil after quench initiation V mc = Ldi main /dt = 744Volts V bc = Ldi BC /dt = 79.35V

15 Quench Initiated in Bucking Coil Most severe quenching scenario takes place when the quench is initiated in Bucking coil and a large dI/dT introduces interlayer voltage in the main coil. K.Singh- SSR2 Focusing Lens Design1501/19/2016 Quench initiated at t=0.1s Quench propagation at t=0.125s Quench propagation at t= 0.3 s Quench propagation at t= 10s Quench propagation at t= 20 s

16 Quench Initiated in Bucking Coil 01/19/2016K.Singh- SSR2 Focusing Lens Design16 Temperature Rise in Bucking coil after quench initiation Quench Energy released in form of heat

17 Quench Initiated in Bucking Coil K.Singh- SSR2 Focusing Lens Design1701/19/2016 Coil resistance growth in Bucking coil after quench initiation di/dt across main coil and bucking coil after quench initiation Current decay in main coil and bucking coil after quench initiation V mc = Ldi main /dt = 1080 Volts V bc = Ldi BC /dt = 34.5V

18 Technical Deliverables (as part of PIP-II IIFC collaboration) –SSR2 Focusing Solenoids Electromagnetic/Mechanical and quench protection design of solenoid and current leads by BARC. 4 no's of SSR2 solenoids to be delivered in R&D phase. BARC to lead the Development effort. FNAL Test and measurement infrastructure will be used for qualification of prototype and series magnets at 2K. Intermediate milestones (R&D Phase) –Completion of 1 prototype Solenoid assembly – Q2-CY17 –Qualification of Prototype Solenoid at 4 K @BARC – Q3-CY17 –Qualification of Prototype Solenoid at 2 K @FNAL – Q4-CY17 –Completion of 4 no.s solenoid magnet assemblies – Q1-CY18 –Qualification of series magnet assemblies – Q2-CY18 01/19/2016K.Singh- SSR2 Focusing Lens Design18 Scope and Schedule

19 Test and measurement Plan The following measurements shall be made after training the cold mass at 4K:  Axial magnetic field along the axis of the solenoid at the nominal current;  Position of the magnetic axis at 4K using Hall probe technique.  Transverse magnetic field of each steering coil (dipole mode) along the axis at nominal current. After the cold mass is assembled with LHe vessel, the following measurements shall be made:  Quench currents at 4 K for the solenoid and steering coils in the dipole mode.  Position of the magnetic axis at 4K using Hall probe technique.  Quench current at 2 K (only for the solenoid and only for prototype magnets). 01/19/2016K.Singh- SSR2 Focusing Lens Design19

20 Summary and next steps The latest SSR2 focusing lens design satisfies the project needs in term of EM performance and Fringe field requirements. Quench Analysis has been completed and maximum temperature and voltage in case of Quench are found to be within specified limits and of same order as in SSR1 which has been successfully tested. Bending strength of corrector coils and Quadrupole gradient in case of skew quadrupole arrangement meets the main requirement and the operating point is well within the range of specified current limit. Mechanical design of Coil former and He vessel has been initiated. Prototype Lens development to be initiated once the mechanical design is complete and approved. K.Singh- SSR2 Focusing Lens Design2001/19/2016

21 References PIP-II Reference Design Report V1.00, June 2015 FRS for the SSR2 cryomodule, Team Centre Document ED0001829 FOCUSING LENS FOR SSR2 CRYOMODULE Functional Requirements Specification Document #: (Teamcenter ED0003642) I. Terechkine, Design Configurations of Focusing Lenses for PXIE SSR1 Cryomodule, TD Note: TD-12-006 T. Khabiboulline, D. Sergatskov, I. Terechkine, SSR1 CAVITY QUENCHING IN THE PRESENCE OF MAGNETIC FIELD, TD note: TD-12-008 G. Chlachidze, et al, “Focusing Lenses for the SSR1 Cryomodule of the PXIE Test Stand” FNAL TD note TD-15-021, Dec 21, 2015 https://web.fnal.gov/organization/TDNotes https://web.fnal.gov/organization/TDNotes K. Singh, I.Terechkine EM design Report for SSR2 Focusing lens, Team Centre Document ED0004354 K.Singh, Quench Analysis report for SSR2 focusing lens for PIP-II, Team Centre Document ED0004355. 01/19/2016K.Singh- SSR2 Focusing Lens Design21

22 Acknowledgement Iouri Terechkine Valeri Lebedev Sanjay Malhotra Mike Tartaglia Shekhar Mishra Don Mitchel Arun Saini 01/19/2016K.Singh- SSR2 Focusing Lens Design22

23 Thank you for your kind Attention 01/19/2016K.Singh- SSR2 Focusing Lens Design23

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