Abstract
The Future Circular Collider (FCC-hh) project is a conceptual study whose goal is to design the successor of the Large Hadron Collider, increasing the collision energy from 14 to 100 TeV. The energy stored in the 16-T superconducting dipole magnets and the length of the sectors composing the 100-km FCC tunnel are considerably larger than those in present accelerators. This means that the energy stored in the FCC-hh dipole circuit is likely to be much higher than that in existing superconducting circuits. In the case of magnet quenches or faults, the circuit needs to be protected, i.e., its energy needs to be rapidly dissipated without inducing excessive voltages in the magnet chain. This article proposes a conceptual design for the FCC-hh dipole circuit, which satisfies the constraint of the maximum allowable voltage-to-ground and fulfills additional requirements related to the FCC-hh operation and tunnel layout. A compromise among the considered requirements leads to a relatively simple circuit layout and a large number of circuits for the entire machine. The behavior of the proposed circuit during the critical fast power abort phase is simulated through a numerical model, which covers the electrical circuit domain and the electrothermal magnet domain. Each FCC-hh dipole magnet is protected by means of the coupling-loss-induced quench (CLIQ) protection system, which also acts at the circuit level. The simulations predict severe voltage oscillations in the FCC-hh dipole circuits that may pose a problem for the quench detection system. The simulations also show that the severity of the oscillations is not due to the presence of CLIQ. This protection system can be integrated into the proposed circuit layout and represents an effective protection system for the entire string of FCC-hh dipole magnets.
Highlights
T HE quench protection of superconducting dipole magnets of the Future Circular Collider (FCC-hh) was integrated into the 16-T development program [1]
The minimum number of circuits per powering sector (PS) that leads to a discharge time constant in the order of 100 s is numbers of circuit in the 4-km PS (Ncir/PS) = 5
The highest differential voltage was obtained for position n = 43, i.e., for the quench detection system (QDS) of the magnet close to the power converter (PC) and energy extraction (EE) systems, which are the origin of the voltage transients in the circuit
Summary
T HE quench protection of superconducting dipole magnets of the Future Circular Collider (FCC-hh) was integrated into the 16-T development program [1]. A CLIQ unit consists of a charged capacitor bank that generates oscillations in the magnet transport current that deposit ac losses in the conductor It acts both at the magnet level (spreading the normal zone after a quench and developing resistance and voltage in the magnet coils) and the circuit level (being electrically connected to the circuit). A numerical circuit model based on netlists is developed in Cadence PSpice, and a finite-element electrothermal model of an FCC-hh dipole magnet protected by CLIQ is developed in COMSOL [7] These models are coupled by means of the STEAM cosimulation framework recently developed at CERN [8] that allows performing a consistent simulation through the cooperation of different models.
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