The Fermilab CMTF Cryogenic Distribution Remote Control System

被引：3

作者：

Pei, L. ^{[1
]}

Theilacker, J. ^{[1
]}

Klebaner, A. ^{[1
]}

Martinez, A. ^{[1
]}

Bossert, R. ^{[1
]}

机构：

[1] Fermilab Natl Accelerator Lab, Batavia, IL 60510 USA

来源：

ADVANCES IN CRYOGENIC ENGINEERING | 2014年 / 1573卷

关键词：

Cryomodule test facility; Distribution; real-time remote control;

D O I：

10.1063/1.4860914

中图分类号：

O414.1 [热力学];

学科分类号：

摘要：

The Cryomodule Test Facility (CMTF) is able to provide the necessary test bed for measuring the performance of Superconducting Radio Frequency (SRF) cavities in a cryomodule (CM). The CMTF have seven 300 KW screw compressors, two liquid helium refrigerators, and two Cryomodule Test Stands (CMTS). CMTS1 is designed for 1.3 GHz cryomodule operating in a pulsed mode (PM) and CMTS2 is for cryomodule operating in Half-Wave (HW) and Continuous Wave (CW) mode. Based on the design requirement, each subsystem has to be far away from each other and be placed in distant locations. Therefore choosing Siemens Process Control System 7-400, DL205 PLC, Synoptic and Fermilab ACNET are the ideal choices for CMTF cryogenic distribution real-time remote control system. This paper presents a method which has been successfully used by many Fermilab distribution cryogenic real-time remote control systems.

引用

页码：1713 / 1719

页数：7

共 50 条

[41] CONTROL-SYSTEM FOR THE FERMILAB TROMBONE NOTCH FILTER
CALVO, OA
MARTIN, MI
IEEE TRANSACTIONS ON NUCLEAR SCIENCE, 1989, 36 (01) : 794 - 797
[42] Conceptual design of cryogenic distribution control system for CFETR Central Solenoid Model Coil
Lu, Xiaofei
Zhang, Qiyong
Cheng, Anyi
Hu, Liangbing
Zhou, Zhiwei
Liu, Xiaogang
PROCEEDINGS OF THE 36TH CHINESE CONTROL CONFERENCE (CCC 2017), 2017, : 4402 - 4406
[43] Intelligent System for Remote Control of Liquid Nitrogen Pressure and Flow in the Cryogenic System of Superconducting Magnets: Hardware and Software Platform
Butenko, A. V.
Zrelov, P. V.
Korenkov, V. V.
Kostromin, S. A.
Nikiforov, D. N.
Reshetnikov, A. G.
Semashko, S. V.
Trubnikov, G. V.
Ulyanov, S. V.
PHYSICS OF PARTICLES AND NUCLEI LETTERS, 2023, 20 (02) : 172 - 182
[44] Intelligent System for Remote Control of Liquid Nitrogen Pressure and Flow in the Cryogenic System of Superconducting Magnets: Hardware and Software Platform
A. V. Butenko
P. V. Zrelov
V. V. Korenkov
S. A. Kostromin
D. N. Nikiforov
A. G. Reshetnikov
S. V. Semashko
G. V. Trubnikov
S. V. Ulyanov
Physics of Particles and Nuclei Letters, 2023, 20 : 172 - 182
[45] Nitrogen precooling heat exchanger replacement and control system upgrade in superfluid cryoplant at CMTF
Subedi, J.
Hansen, B.
White, M.
Patel, V
Makara, J.
Atassi, O.
Johnson, G.
ADVANCES IN CRYOGENIC ENGINEERING: PROCEEDINGS OF THE CRYOGENIC ENGINEERING CONFERENCE, CEC 2023, 2024, 1301
[46] REMOTE CONTROL SYSTEM
HINKLEY, JE
MITCHUSS.GA
INDUSTRIAL PHOTOGRAPHY, 1969, 18 (03): : 71 - &
[47] A CONTROL-SYSTEM FOR CRYOGENIC INSTALLATIONS
AUGUERES, JL
BENICHOU, J
KADIR, B
KIRCHER, F
SELLIER, JC
JOURNAL DE PHYSIQUE, 1984, 45 (NC-1): : 649 - 652
[48] The Reliability Analysis and FMECA Analysis of Cryogenic Distribution System for Cryogenic System of HL-3
Zhong, Yunke
Chen, Xin
Li, Qiang
Lin, Tao
Zhu, Genliang
Chen, Jinlong
Li, Sijia
IEEE TRANSACTIONS ON APPLIED SUPERCONDUCTIVITY, 2024, 34 (08)
[49] A diagnostic tool for console applications of the Fermilab accelerator control system
Wang, JY
Hendricks, B
ACCELERATOR AND LARGE EXPERIMENTAL PHYSICS CONTROL SYSTEMS, 1997, : 82 - 84
[50] Remote monitoring system for the cryogenic system of superconducting magnets in the SuperKEKB interaction region
Aoki, K.
Ohuchi, N.
Zong, Z.
Arimoto, Y.
Wang, X.
Yamaoka, H.
Kawai, M.
Kondou, Y.
Makida, Y.
Hirose, M.
Endou, T.
Iwasaki, M.
Nakamura, T.
ADVANCES IN CRYOGENIC ENGINEERING, 2017, 278

← 1 2 3 4 5 →