RF thermal and new cold part design studies on a TTF-Ⅲ input coupler for Project-X

PEI Shi-Lun; Chris E; LI Zeng-Hai; Nikolay A; Ivan V

doi:10.1088/1674-1137/36/2/013

Chinese Physics C> 2012, Vol. 36> Issue(2) : 173-178 DOI: 10.1088/1674-1137/36/2/013

RF thermal and new cold part design studies on a TTF-Ⅲ input coupler for Project-X

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An RF power coupler is one of the key components in a superconducting (SC) linac. It provides RF power to the SC cavity and interconnects different temperature layers (1.8 K, 4.2 K, 70 K and 300 K). The TTF-Ⅲ coupler is one of the most promising candidates for the High Energy (HE) linac of Project X, but it cannot meet the average power requirements because of the relatively high temperature rise on the warm inner conductor, so some design modifications will be required. In this paper, we describe our simulation studies on the copper coating thickness on the warm inner conductor with RRR values of 10 and 100. Our purpose is to rebalance the dynamic and static loads, and finally lower the temperature rise along the warm inner conductor. In addition, to get stronger coupling, better power handling and less multipacting probability, one new cold part design was proposed using a 60 mm coaxial line; the corresponding multipacting simulation studies have also been investigated.

References

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Project X Research Design Development Plan. Version2.2, 2009. 32 Solyak N. Power Couplers for ILC and Project X. DOESRF Review, 2009. 53 Solyak N, Yakovlev V. Project X Coupler Requirements.Project X Collaboration Meeting, FNAL, 2008. 114 Moeller W. High Power Coupler for the TESLA Test Facil-ity. Proc. of the 9th Workshop on RF Superconductivity.Santa Fe, USA, 1999. 577-5815 Dohlus M, Kostin D, Moeller W. TESLA RF Power Cou-pler Thermal Calculations. Proc. of LINAC 2004. Lubeck,Germany, 2004. 174-1766 ANSYS is a trademark of SAS Inc., (www.ansys.com)7 Li Z, Akcelik V, Candel A et al. Towards Simulation of Elec-tromagnetics and Beam Physics at the Petascale. Proc. ofPAC07. Albuquerque, New Mexico, USA, 2007. 889-8938 Somersalo E, Yla-Oijala P. Analysis of Multipacting inCoaxial Lines. Proc. of PAC95. Dallas, Texas, USA, 1995.1500-15029 Ge L, Adolphsen C, Ko K et al. Multipacting Simulationsof TTF-0 Power Coupler Components. Proc. of PAC07.Albuquerque, New Mexico, USA, 2007. 2436-243810 Veshcherevich V, Belomestnykn S, Quigley P et al. HighPower Tests of Input Couplers for Cornell ERL Injector.Proc. of SRF Workshop 2007. Beijing, China, 2007. 517-519

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PEI Shi-Lun, Chris E, LI Zeng-Hai, Nikolay A and Ivan V. RF thermal and new cold part design studies on a TTF-Ⅲ input coupler for Project-X[J]. Chinese Physics C, 2012, 36(2): 173-178. doi: 10.1088/1674-1137/36/2/013

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Received: 2011-04-18
Revised: 2011-05-06

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通讯作者: 陈斌, bchen63@163.com

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沈阳化工大学材料科学与工程学院沈阳 110142

RF thermal and new cold part design studies on a TTF-Ⅲ input coupler for Project-X

Corresponding author: PEI Shi-Lun,

Received Date: 2011-04-18

Accepted Date: 2011-05-06

Available Online: 2012-02-05

Abstract: An RF power coupler is one of the key components in a superconducting (SC) linac. It provides RF power to the SC cavity and interconnects different temperature layers (1.8 K, 4.2 K, 70 K and 300 K). The TTF-Ⅲ coupler is one of the most promising candidates for the High Energy (HE) linac of Project X, but it cannot meet the average power requirements because of the relatively high temperature rise on the warm inner conductor, so some design modifications will be required. In this paper, we describe our simulation studies on the copper coating thickness on the warm inner conductor with RRR values of 10 and 100. Our purpose is to rebalance the dynamic and static loads, and finally lower the temperature rise along the warm inner conductor. In addition, to get stronger coupling, better power handling and less multipacting probability, one new cold part design was proposed using a 60 mm coaxial line; the corresponding multipacting simulation studies have also been investigated.

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RF thermal and new cold part design studies on a TTF-Ⅲ input coupler for Project-X

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通讯作者: 陈斌, bchen63@163.com

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