THEA
Overview
THEA performs stationary and non-stationary Thermal, Hydraulic and Electric Analysis of a generic superconducting cable, cooled by forced-flow. THEA is suited for the full spectrum of evolutions, from cooldown of a coil to the stability analysis of the conductor. At the time of its release, THEA is the only code that takes consistently into account all macroscopic phenomena with the following origins:- thermal: heat generation and diffusion along the cable;
- hydraulic: mass, momentum and energy transport along the coolant flow;
- electric: current diffusion and distribution along the cable;
Details
- A 1 and 1/2-D description of the cable.
An arbitrary number of thermal, hydraulic and electric components are
mutually coupled as specified by the user.
- Modular conductor. The user selects the components and materials
forming the cable, including superconductor and stabilizer, the
additional structural materials or insulating barriers. Each component
can have a fine, homogeneised structure that is defined by the user. The
number and size of the cooling channels is as well arbitrary.
- Flexible electrical model.
Electric components can be defined and coupled through inductive and
resistive current transfer. The electrical and thermal models are coupled
to model resistive transition effects on current transfer and Joule heating.
- Power-law dependence of the
longitudinal electric field in the superconductor and consistent
current sharing model, for the accurate description of operating conditions
around the current sharing regime (e.g. critical current measurements and
stability transients).
- Geometry variations along the cable length can be easily taken into
account. Both thermal components and cooling channels can have variable
cross sections, thermophysical and hydraulic properties along the cable
length (e.g. to model joints).
- The solver uses finite elements in space (up to fifth order
interpolation) and a multi-step finite difference integrator in time (up
to third order accurate). Automatic time step adaptivity is used to
control the integration errors and to cope with strong variations in the
solution. Mesh adaptivity is used to cope with large gradients in the solution.
- Extensive user's defined routines to allow easy-to-use interfacing to
user's specific applications.
- Graphic (Postscript) post-processor included in the package.
- Open structure, for evolutive simulation power. The code is largely parametric, and thus can cope with new geometries, new materials and new phenomena. THEA is the cable simulator of the present and of the future.
Examples
Some examples of code runs and results:
- a calculation of current diffusion in a two strand cable
Version
January 2021, version 2.4
Installations
- Mac OSX (native development platform)
- Linux (e.g. RedHat, Fedora, Ubuntu, and other distributions)
- UNIX (e.g. AIX on RISC-6000, Solaris on Sun-Spark, DEC Alpha,
HP UX, and other)
- CYGWIN (port available to run under Windows, not supported)
On-line documentation
Download the manual in Pdf format for the latest version of THEA