Fabrication of superconducting material for application as wire or ribbon replacement

Ahmad, Anis

January 1989

No description available.

Engineering, Mechanical

Fabrication

Superconducting Material

Wire Replacement

Ribbon Replacement

Heat Transfer Correlations Between a Heated Surface and Liquid & Superfluid Helium : For Better Understanding of the Thermal Stability of the Superconducting Dipole Magnets in the LHC at CERN

Lantz, Jonas

January 2007

<p>This thesis is a study of the heat transfer correlations between a wire and liquid helium cooled to either 1.9 or 4.3 K. The wire resembles a part of a superconducting magnet used in the Large Hadron Collider (LHC) particle accelerator currently being built at CERN. The magnets are cooled to 1.9 K and using helium as a coolant is very efficient, especially at extremely low temperatures since it then becomes a superfluid with an apparent infinite thermal conductivity. The cooling of the magnet is very important, since the superconducting wires need to be thermally stable.</p><p>Thermal stability means that a superconductive magnet can remain superconducting, even if a part of the magnet becomes normal conductive due to a temperature increase. This means that if heat is generated in a wire, it must be transferred to the helium by some sort of heat transfer mechanism, or along the wire or to the neighbouring wires by conduction. Since the magnets need to be superconductive for the operation of the particle accelerator, it is crucial to keep the wires cold. Therefore, it is necessary to understand the heat transfer mechanisms from the wires to the liquid helium.</p><p>The scope of this thesis was to describe the heat transfer mechanisms from a heater immersed in liquid and superfluid helium. By performing both experiments and simulations, it was possible to determine properties like heat transfer correlations, critical heat flux limits, and the differences between transient and steady-state heat flow. The measured values were in good agreement with values found in literature with a few exceptions. These differences could be due to measurement errors. A numerical program was written in Matlab and it was able to simulate the experimental temperature and heat flux response with good accuracy for a given heat generation.</p>

Heat transfer

superfluid helium

low temperature

superconducting material

Mechanical and thermal engineering

Mekanisk och termisk energiteknik

Heat Transfer Correlations Between a Heated Surface and Liquid &amp; Superfluid Helium : For Better Understanding of the Thermal Stability of the Superconducting Dipole Magnets in the LHC at CERN

Lantz, Jonas

January 2007

This thesis is a study of the heat transfer correlations between a wire and liquid helium cooled to either 1.9 or 4.3 K. The wire resembles a part of a superconducting magnet used in the Large Hadron Collider (LHC) particle accelerator currently being built at CERN. The magnets are cooled to 1.9 K and using helium as a coolant is very efficient, especially at extremely low temperatures since it then becomes a superfluid with an apparent infinite thermal conductivity. The cooling of the magnet is very important, since the superconducting wires need to be thermally stable. Thermal stability means that a superconductive magnet can remain superconducting, even if a part of the magnet becomes normal conductive due to a temperature increase. This means that if heat is generated in a wire, it must be transferred to the helium by some sort of heat transfer mechanism, or along the wire or to the neighbouring wires by conduction. Since the magnets need to be superconductive for the operation of the particle accelerator, it is crucial to keep the wires cold. Therefore, it is necessary to understand the heat transfer mechanisms from the wires to the liquid helium. The scope of this thesis was to describe the heat transfer mechanisms from a heater immersed in liquid and superfluid helium. By performing both experiments and simulations, it was possible to determine properties like heat transfer correlations, critical heat flux limits, and the differences between transient and steady-state heat flow. The measured values were in good agreement with values found in literature with a few exceptions. These differences could be due to measurement errors. A numerical program was written in Matlab and it was able to simulate the experimental temperature and heat flux response with good accuracy for a given heat generation.

Heat transfer

superfluid helium

low temperature

superconducting material

Mechanical and thermal engineering

Mekanisk och termisk energiteknik

Estudo das propriedades supercondutoras da fase T2 no sistema Nb-Si-B / Study of superconducting properties of the T2 phase in the system Nb-Si-B.

Brauner, André

13 August 2010

Este trabalho tem como objetivo o estudo da influência do boro na fase &#945;Nb5Si3 (Fase T2) a baixas temperaturas analisando suas propriedades elétricas e magnéticas. Para o estudo deste tema as amostras foram preparadas, seguindo a estequiometria Nb5Si3-xBx, via metalurgia do pó e também por fusão a arco, com x dentro do intervalo limitado por 0 &#61603; X &#61603; 1,0. Estas amostras foram analisadas através de difratometria de raios x, microscopia eletrônica de varredura, magnetização, transporte elétrico e medidas calorimétricas em baixa temperatura. As medidas das propriedades elétricas e magnéticas destas fases mostram que a substituição de boro por silício induz supercondutividade na fase T2. O caráter volumétrico da transição supercondutora é confirmado pela medida de capacidade calorífica. Assim, este trabalho é o primeiro a mostrar uma nova família de materiais supercondutores que cristalizam na estrutura protótipo Cr5B3. / This work to study the influence of boron during low temperature &#945;Nb5Si3 (T2 phase) analyzing their electrical and magnetic properties. For the study of this subject the samples were prepared, following the stoichiometry Nb5Si3-xBx via powder metallurgy and also by arc melting process, with x within the range limited by 0&#61603;X&#61603;1.0. These samples were analyzed by X-ray diffraction, scanning electron microscopy, magnetization, electrical transport and calorimetric measurements of low temperature. Measurements of electrical and magnetic properties of these phases show that the substitution of boron by silicon induces superconductivity at the T2 phase. The bulk nature of superconducting transition is confirmed by heat capacity measurement. This study is the first to show a new family of superconducting materials that crystallize in the Cr5B3 prototype structure.

Estrutura lamelar

Fase T2 no sistema Nb-Si-B

Intersticial

Lamellar structure

new superconducting material

Superconductivity

Supercondutividade

Estudo das propriedades supercondutoras da fase T2 no sistema Nb-Si-B / Study of superconducting properties of the T2 phase in the system Nb-Si-B.

André Brauner

13 August 2010

Este trabalho tem como objetivo o estudo da influência do boro na fase &#945;Nb5Si3 (Fase T2) a baixas temperaturas analisando suas propriedades elétricas e magnéticas. Para o estudo deste tema as amostras foram preparadas, seguindo a estequiometria Nb5Si3-xBx, via metalurgia do pó e também por fusão a arco, com x dentro do intervalo limitado por 0 &#61603; X &#61603; 1,0. Estas amostras foram analisadas através de difratometria de raios x, microscopia eletrônica de varredura, magnetização, transporte elétrico e medidas calorimétricas em baixa temperatura. As medidas das propriedades elétricas e magnéticas destas fases mostram que a substituição de boro por silício induz supercondutividade na fase T2. O caráter volumétrico da transição supercondutora é confirmado pela medida de capacidade calorífica. Assim, este trabalho é o primeiro a mostrar uma nova família de materiais supercondutores que cristalizam na estrutura protótipo Cr5B3. / This work to study the influence of boron during low temperature &#945;Nb5Si3 (T2 phase) analyzing their electrical and magnetic properties. For the study of this subject the samples were prepared, following the stoichiometry Nb5Si3-xBx via powder metallurgy and also by arc melting process, with x within the range limited by 0&#61603;X&#61603;1.0. These samples were analyzed by X-ray diffraction, scanning electron microscopy, magnetization, electrical transport and calorimetric measurements of low temperature. Measurements of electrical and magnetic properties of these phases show that the substitution of boron by silicon induces superconductivity at the T2 phase. The bulk nature of superconducting transition is confirmed by heat capacity measurement. This study is the first to show a new family of superconducting materials that crystallize in the Cr5B3 prototype structure.

Estrutura lamelar

Fase T2 no sistema Nb-Si-B

Intersticial

Supercondutividade

Lamellar structure

new superconducting material

Superconductivity