Low Energy RHIC e - Cooling Meeting Minutes – 11/19/14 1. Cooling Section Magnets and Power Supplies –Most of power supplies will be from ERL (R. Lambiase).

Slides:

Advertisements

Similar presentations

Can we re-use existing magnets to build a 350(450) keV beam line? No.Type 115 deg dipole 1Spectrometer dipole 1NEG solenoid (2.5” ID) 5SW/CW solenoid 1Wien.

Advertisements

11-13/10/2007 ILC BDS Kick-Off Meeting, SLAC, US 1 BDS Vacuum System Dr. Oleg B. Malyshev ASTeC Daresbury Laboratory.

Summary of the discussion for the commissioning session 2 nd ATF2 Project Meeting KEK, Tsukuba, Japan 6/ 1/ 2006 T.Okugi (KEK)

February 17-18, 2010 R&D ERL Ady Hershcovitch R&D ERL Beam Dump Ady Hershcovitch February 17-18, 2010 Beam Dump.

Preliminary result on Quarter wave transformer simulation a short lens with a high magnetic field and a long solenoidal magnetic field. Field profile of.

Low Energy RHIC e - Cooling LEReC-I (1.6-2MeV): Gun to dump SRF gun used as a booster cavity 704 MHz SRF gun converted to booster cavity 5-cell 704 MHz.

1 Low-energy RHIC electron Cooler (LEReC) Update November 17, 2014.

Scientific Goals: V. Litvinenko’s RHIC retreat talk Commissioning Goals: I. Pinayev presentation last week Run 14 Goals: Complete assembly of 112 MHz SCRF.

1 Presented at ColUSM by D. Ramos on behalf of the Cold Collimator Feasibility Study Working Group Longitudinal.

Thomas Roser RHIC Open Planning Meeting December 3-4, 2003 RHIC II machine plans Electron cooling at RHIC Luminosity upgrade parameters.

Low Energy RHIC e - Cooling Meeting Notes 1 –LF Solenoids & HF (Matching) Solenoids: Out for bid??? –20 o Dipole  Magnet gap is 4 inches/transport lines.

DR Vacuum Component Overview April 25, 2012 Joe Conway.

Discussion on the magnetic shielding: The magnetic shielding will not be installed until the 2016 shutdown. The magnetic shielding test fixture will be.

1 Low-energy RHIC electron Cooler (LEReC) cost estimate December 2, 2014.

1 LEReC Funded! From: Fedotov, Alexei Sent: Thursday, May 14, :04 PM Subject: LEReC project approved Dear All, FYI. The LEReC project is now formally.

Low Energy RHIC e - Cooling Meeting Minutes – 1/14/15 1 –Magnet Design  During DOE Review there was concern for magnet field quality of LF Solenoids.

1 BROOKHAVEN SCIENCE ASSOCIATES Abstract Magnet and Girder Integration Lewis Doom, NSLS-II Project National Synchrotron Light Source II (NSLS-II) will.

October 4-5, Electron Lens Overall Design Alexander Pikin October 4, 2010 Electron Lens.

Low Energy RHIC e - Cooling LEReC-I (1.6-2MeV): Gun to dump SRF gun used as a booster cavity 704 MHz SRF gun converted to booster cavity 5-cell 704 MHz.

G5 Beam Instrumentation D. Gassner, E. Pozdeyev 4-09.

Beam Line Layout – Cooling Section There seems to be two options for energy measurement: at the 180 dipole and/or in a diagnostic branch at the end of.

EBIS ARR Jim Alessi May 4- 7, 2010 Technical Overview.

1. Beam Line Layout – Cooling Section (CS) Mu Metal shield design – G. Mahler is assembling a mock-up of beam line for field measurements to evaluate.

ERHIC design status V.Ptitsyn for the eRHIC design team.

Low Energy RHIC e - Cooling Meeting Minutes – 11/5/14 1.J. Tuozzolo will schedule a visit to NSLS next week to evaluate available magnets, power supplies,

Vacuum, H-C. Hseuh January 4, 2007 RHIC II Project Internal Cost Review Vacuum Systems H.-C. Hseuh January 4, 2007 Vacuum Systems.

G5 Design Review, April 24, 2009 Gun to 5cell Cavity Test: Overview Dmitry Kayran G5 test Design Review April,

Low Energy RHIC e - Cooling Meeting Minutes – 11/5/14 1.Funding is available to purchase magnets. 2.Comment during presentation of attached slides: 180.

Low Energy RHIC e - Cooling LEReC-I (1.6-2MeV): Gun to dump SRF gun used as a booster cavity 704 MHz SRF gun converted to booster cavity 5-cell 704 MHz.

Low Energy RHIC e - Cooling 1 IP2 64 m LEReC-I (1.6-2MeV): Gun to dump SRF gun used as a booster cavity.

Overall Layout 1 IP2 64 m LEReC-I (1.6-2MeV): Gun to dump SRF gun used as a booster cavity.

Low Energy RHIC e - Cooling LEReC-I (1.6-2MeV): Gun to dump SRF gun used as a booster cavity 704 MHz SRF gun converted to booster cavity 5-cell 704 MHz.

A Fedotov, K Hamdi, D Kayran, L Snydstrup, K Smith, J Tuozzolo, A Zaltsman Transport Beam Line Design development of beam line will be from the Booster.

Low Energy RHIC e - Cooling Meeting Minutes – 12/23/ Cooling Section: –LF Solenoids:  At PPM, G. Woods has assigned buyer, SOW will be revised,

July LEReC Review July 2014 Low Energy RHIC electron Cooling Jorg Kewisch, Dmitri Kayran Electron Beam Transport and System specifications.

LEReC. COOLING in Blue RHIC ring COOLING in Yellow RHIC ring 63.9 m to IP2 Beam Dump 20° Bending Magnets DC e - Gun 704 SRF Booster Cavity 2.1 GHz Cu.

The Introduction to CSNS Accelerators Oct. 5, 2010 Sheng Wang AP group, Accelerator Centre,IHEP, CAS.

Vacuum, H-C. Hseuh January 4, 2007 RHIC II Project Internal Cost Review H.-C. Hseuh Vacuum Systems January 4, 2007 Project Overview.

Overall Layout 1 IP2 64 m LEReC-I (1.6-2MeV): Gun to dump SRF gun used as a booster cavity Booster Cavity and Gun move (next slide)

MeRHIC Internal Cost Review October, Dmitry Kayran for injector group MeRHIC Internal Cost Review October 7-8, 2009 MeRHIC: Injection System Gun.

Bob Lambiase May 21, The purpose of eRHIC is to have the capability to collide heavy ions with leptons, such as electrons and polarized electrons.

Booster bpm’s Jim Crisp 3/29/06. Plate width and linearity with the response linearized along the axis 60 and 20 degree plates become nonlinear in the.

Update: Puck and Gun Magnet March 1, Magnetized Gun 2 K 2 CsSb Preparation Chamber HV Chamber.

Beam Line Layout – Cooling Section (to be installed by 1 Dec ember 2015) J. Kewisch wants to move the 20 dipole, yellow (to the right) toward the triplet.

LHC Beampipes Ray Veness / AT-VAC FP XII 08Beam Vacuum- R.Veness.

Meeting Minutes: LEReC DC Gun, Transport Lines, and Dump Installation 2016, May 26, 2016 D. Kayran, A. Fedotov, T. Miller, D. Gassner, D. Weiss, G. Mahler,

LEReC. COOLING in Blue RHIC ring COOLING in Yellow RHIC ring 63.9 m to IP2 Beam Dump 20° Bending Magnets DC e - Gun 704 SRF Booster Cavity 2.1 GHz Cu.

LEReC Electron beam requirement for cooling Kinetic energy, MeV 1.6

LEReC System 1. Project Schedule 2015 shutdown COMPETE! Move beam line equipment from IP 01:00 Install cooling section beam line 2016 shutdown Install.

Low Energy RHIC e - Cooling Meeting Minutes – 12/17/ For the matching energy of electron and ion beams methods for electron energy measurement were.

ECOOL Meeting 03/26/10 1 Electron beam transport for FNAL electron cooler E-cooling is referred as “non-magnetized” OVERVIEW Material is taken from FNAL’s.

Minutes meeting Mapes, Miller, Kayran, Fedotov, Gassner, Hamdi, Bruno, Mahler, Weiss, Hammons, Arno, Nayak, Fite, Bellavia The layout shown in.

LEReC System 1. LEReC Injection section 2016 CeC Beam Dump 45°dipole (CeC) Profile Monitor (ERL HE) No SRF Cavity DC e - Gun ERL Solenoid ERL Halo Monitors.

Interaction Region and Detector

Page Headline CBETA Splitter.

PROGRESS REPORT OF A NLNS-FFAG ADS MAGNET

EBTF Design Review Technical Meeting Group

Main magnets for PERLE Test Facility

Engineering Status.

Yingshun Zhu Accelerator Center, Magnet Group

Compact and Low Consumption Magnet Design The DESY Experience

Challenges for FCC-ee MDI mechanical design

Electron Source Configuration

LCLS Injector/Diagnostics David H. Dowell, SLAC April 24, 2002

RHIC Magnets for JLEIC Yuhong Zhang May 11, 2018.

Electron Collider Ring Magnets Preliminary Summary

MEIC Shifting Magnet Tim Michalski August 6, 2015.

IR Beam Transport Status

Fanglei Lin, Yuhong Zhang JLEIC R&D Meeting, March 10, 2016

Fanglei Lin JLEIC R&D Meeting, August 4, 2016

Presentation transcript:

Low Energy RHIC e - Cooling Meeting Minutes – 11/19/14 1. Cooling Section Magnets and Power Supplies –Most of power supplies will be from ERL (R. Lambiase). Originally, all ERL PS’s were available for use, now all except egun-to-dump PS’s can be used. –RL said that he still does not know all the magnets (e.g., chicane(s) and before the beam dump). –Compensating Solenoids  Blue LF magnets (6) powered in series with 1 PS; Yellow (6) powered in series with 1 PS. R. Lambiase said that he may not have power supply for the 6 solenoids in each cooling section beam line. He will pick number of turns to match existing power supplies; he may select turns ratio suitable for adding shunts. This needs to be reviewed with G. Mahler and K. Hamdi (drawings or SOW updated?).  Primary field to be 100 ppm; bucking and correctors to be 1000 ppm.  Correctors located at each compensating solenoid will have individual PS’s. R Lambiase said that we have these PS’s. 1

Low Energy RHIC e - Cooling Meeting Minutes – 11/19/14 –Matching Solenoids  Specifications finalized from W. Meng (sheet 7)  Matching solenoids have individual PS’s -eBeam Transport (smaller diameter) Solenoids  Option suggested by G. Mahler: Use existing design (purchased) 800 Gauss ERL solenoids (could these be suitable for 1.0 kG?) instead of planned 1.5 kG water-cooled by using 3 magnets at 1.0 kG to replace 2 at 1.5kG. 2. Q4 Region 45 degree dipoles to be replaced by 20 degree dipoles. This line to be 4.5 m long. See sheet 5. 2

Low Energy RHIC e - Cooling 3

11/17/14 LEReC-I (2MeV): Gun to dump DC gun 5-cell 704 MHz SRF cavity 9MHz 704 MHz warm cavity 2.1 GHz warm cavity Beam dump 180 deg bending magnet e-e- e-e- e-e- IP2 64 m Fixed Distance – 4.5M Revised Magnet Angle

Low Energy RHIC e - Cooling Revised Cooling Section 5 Q3 Details: valve, bellows, 10 Hz corrector, RHIC BPM, ion pump, transition chamber, survey points. NSLS I compensating dipoles and PS: specifications?

Low Energy RHIC e - Cooling Compensating Solenoids 1.Compensating Solenoid: Presently based on W. Meng’s design for 0.20kG with bucking coils. 2.Compensating Solenoid : The separate leads for the bucking solenoid coils and the main solenoid coil on the magnet assembly terminal block. 3.Compensating Solenoid Power Supplies: It has not been determined whether each solenoid will require 1, 2, or 3 power supplies. 4.Spacing: Compensating solenoids will be spaced 3 meters apart. Complete SCD’s checked, SOW in review Layout BPM, Bellows, Chamber Flange. 6 Attached files show the modified design, by mainly increasing the width (in radial direction R). Since the physical length along the Beam did not change, so that previous Horizontal/Vertical dipole correction coils design will remain the same. From the Excel file, the Bz < 1 Gauss starts at Z = 19.7 cm., where cooling will be effective. The B**2 integral meets the required value (4E5 Gauss^2 - cm). The Bz integral is much more than 2000 Gauss-cm. Please comment. Wuzheng

Low Energy RHIC e - Cooling Magnet Analysis Matching Solenoid w/corrector 1.5 kG, magnetic length?? Water cooled 2 required in cooling section w/o bucking coil Corrector 100 Gcm, present specification. 7 Attached files show the present status of 1.5 kG solenoid design by using water cooled conductor. If copper area is 50%, then the current density will be below 5 A/mm2 in the copper. I calculated both Bz and Bz**2 along the Z-axis. Bz becomes less than 1 Gauss at Z = 37 cm. Please comment. Wuzheng

Low Energy RHIC e - Cooling Cooling Section BPM’s Phone conference with MPF Larger diameter buttons on pick-up – 27 to 30 mm diameter Machined vacuum chamber, 304L, no threaded holes on flanges. Button hole size TBD microwave studio (D. Gassner). 8

Low Energy RHIC e - Cooling Dipole correction A-T Per coil; Straight section Half-length: H1=6 cm 13 turns/.8 amps = 1 amp PS (AWG #18 = 0.98 A/mm2) Compensating Solenoid Corrector

Low Energy RHIC e - Cooling Vacuum Chamber/System Requirements: 5” (12.7 cm) OD vacuum chamber, bake-out temperature ID button BPM (from CeC) No ion pump tees in the cooling section. One RHIC shielded bellows per solenoid Transitions to 10 cm aperture dipole magnets. Dipole magnet vacuum chambers. 6 Profile Monitors, screen size?? 10 Magnetic Shields