惯性聚合 高效追踪和阅读你感兴趣的博客、新闻、科技资讯
阅读原文 在惯性聚合中打开

推荐订阅源

cs.AI updates on arXiv.org
cs.AI updates on arXiv.org
V
Visual Studio Blog
The GitHub Blog
The GitHub Blog
Apple Machine Learning Research
Apple Machine Learning Research
J
Java Code Geeks
T
Tailwind CSS Blog
大猫的无限游戏
大猫的无限游戏
Jina AI
Jina AI
OSCHINA 社区最新新闻
OSCHINA 社区最新新闻
Hugging Face - Blog
Hugging Face - Blog
WordPress大学
WordPress大学
宝玉的分享
宝玉的分享
freeCodeCamp Programming Tutorials: Python, JavaScript, Git & More
罗磊的独立博客
人人都是产品经理
人人都是产品经理
H
Heimdal Security Blog
Last Week in AI
Last Week in AI
博客园 - 【当耐特】
Cyberwarzone
Cyberwarzone
Google DeepMind News
Google DeepMind News
雷峰网
雷峰网
Hacker News: Ask HN
Hacker News: Ask HN
Webroot Blog
Webroot Blog
Microsoft Azure Blog
Microsoft Azure Blog
MyScale Blog
MyScale Blog
A
About on SuperTechFans
V2EX - 技术
V2EX - 技术
小众软件
小众软件
博客园 - Franky
博客园 - 司徒正美
P
Privacy International News Feed
爱范儿
爱范儿
U
Unit 42
博客园 - 叶小钗
The Hacker News
The Hacker News
C
Check Point Blog
奇客Solidot–传递最新科技情报
奇客Solidot–传递最新科技情报
Simon Willison's Weblog
Simon Willison's Weblog
N
News and Events Feed by Topic
D
Docker
T
Threatpost
MongoDB | Blog
MongoDB | Blog
让小产品的独立变现更简单 - ezindie.com
让小产品的独立变现更简单 - ezindie.com
H
Help Net Security
L
LINUX DO - 最新话题
Security Latest
Security Latest
T
The Exploit Database - CXSecurity.com
S
SegmentFault 最新的问题
A
Arctic Wolf
Spread Privacy
Spread Privacy

Knowledge Transfer - Accelerating Innovation @ CERN

CERN tech for Quantum Systems CERN tech for Quantum Systems CERN tech for Quantum Systems Radiotherapy | Knowledge Transfer Radiotherapy | Knowledge Transfer Nuclear Medicine | Knowledge Transfer Nuclear Medicine | Knowledge Transfer Medical Imaging | Knowledge Transfer Medical Imaging | Knowledge Transfer General Medical Applications | Knowledge Transfer General Medical Applications | Knowledge Transfer Dosimetry | Knowledge Transfer Dosimetry | Knowledge Transfer Dosimetry | Knowledge Transfer Computing for Medical Applications | Knowledge Transfer Computing for Medical Applications | Knowledge Transfer Computing for Medical Applications | Knowledge Transfer Radiotherapy | Knowledge Transfer Nuclear Medicine | Knowledge Transfer Medical Imaging | Knowledge Transfer General Medical Applications | Knowledge Transfer Health, Safety and Environment Management Superconducting Magnets | Knowledge Transfer Sensors | Knowledge Transfer Health, Safety and Environment Management Sensors | Knowledge Transfer Superconducting Magnets | Knowledge Transfer Health, Safety and Environment Management Sensors | Knowledge Transfer
Superconducting Magnets | Knowledge Transfer
Anonymous · 2020-07-14 · via Knowledge Transfer - Accelerating Innovation @ CERN

CERN’s knowhow and facilities for end-to-end design, assembly, testing and operation of superconductive magnet systems.

CERN´s Know-How

  • Knowhow on applied superconductivity (materials, wires, cables, current leads, transfer lines)
  • In-house design and modelling of superconductive devices and magnet systems
  • Providing a ‘one-stop-shop’ with access to a range of unique facilities for testing ideas and new innovative magnet / superconductivity concepts

Facts & Figures

  • 7600 km: length of superconductive niobium titanium cables used in LHC
  • 14.6 T: high field 100 mm aperture superconducting dipole test facility (Fresca2) operating at 1.9 K
  • 20 kA: record currents at 20 K with magnesium diboride for power transmission
  • 170: tonnes of liquid helium to reach the a temperature of - 271.3 °C
  • 9600: extreme numbers of SC magnet systems being operated for decades
  • 1232: number of 15 m long dipole magnets, each 28 t in weight
  • 392: number of quadrupole magnets to help focus the beam of particles
  • 14,6 T: high field 100 mm aperture superconducting dipole test facility (Fresca2) operating at 1.9 K

Value Proposition

Read more about Superconductivity and Magnets here. 

Key Competences

Superconducting materials

CERN uses a wide range of superconducting materials in the construction of its accelerators and experiments. Niobium titanium has been the workhorse for the LHC. Nb3Sn is required to produce the high-field magnets needed for the high luminosity upgrade. A wide range of materials are being explored to enable the cables, magnets and devices required for the future.

Magnet design & modelling

CERN has vast experience with magnet design and modelling, with more than 50 types of permanent and superconductive electromagnets to steer particles: dipole magnets, but also complex sextupole, octupole and decapole magnets, which are necessary to guarantee beam stability. On top of this, in the detectors many different magnet types are used. CERN is using an holistic approach to magnet design and uses in-house software tools for fast and accurate simulations.

Assembly and testing

CERN has unique infrastructure for assembly and testing of resistive and superconductive magnet systems. The laboratories provide all infrastructure for manufacturing, assembly and (cyclic) testing of large components at high mechanical stresses, currents, magnetic fields and at low temperatures.

Key Applications

Transporting currents >10kA

The powering of a superconducting system requires transport of high currents, from ambient to cryogenic temperatures, the latter of which is necessary to enable superconductivity. For designing these superconductive devices, CERN has unique design knowhow and prototyping experience, leveraging knowledge of material properties and in-house developed simulation and modelling software.

Protection of Superconductive Devices

Coupling-Loss Induced Quench (CLIQ) is an innovative quench protection method that heats large portions of a superconductor reliably and efficiently. CLIQ’s fast and homogeneous transfer of the coil to the normal state can enable safe magnet operation at energy densities presently not possible with other systems.