A Quench Detection and Monitoring System for Superconducting Magnets at Fermilab

TL;DR

This paper presents a multi-tier quench detection and monitoring system designed for superconducting magnets at Fermilab, emphasizing dependability, redundancy, and long-term operation, with successful implementation in test environments.

Contribution

It introduces a novel three-tier quench detection system with independent, redundant components, and demonstrates its successful deployment in Fermilab's magnet testing.

Findings

Successful quench protection during HL-LHC magnet test

Reliable detection and characterization of quenches

System's dependability for long-term operation

Abstract

A quench detection system was developed for protecting and monitoring the superconducting solenoids for the Muon-to-Electron Conversion Experiment (Mu2e) at Fermilab. The quench system was designed for a high level of dependability and long-term continuous operation. It is based on three tiers: Tier-I, FPGA-based Digital Quench Detection (DQD); Tier-II, Analog Quench Detection (AQD); and Tier-3, the quench controls and data management system. The Tier-I and Tier-II are completely independent and fully redundant systems. The Tier-3 system is based on National Instruments (NI) C-RIO and provides the user interface for quench controls and data management. It is independent from Tiers I & II. The DQD provides both quench detection and quench characterization (monitoring) capability. Both DQD and AQD have built-in high voltage isolation and user programmable gains and attenuations. The DQD and AQD also includes user configured current dependent thresholding and validation times. A 1st article of the three-tier system was fully implemented on the new Fermilab magnet test stand for the HL-LHC Accelerator Up-grade Project (AUP). It successfully provided quench protection and monitoring (QPM) for a cold superconducting bus test in November 2020. The Mu2e quench detection design has since been implemented for production testing of the AUP magnets. A detailed description of the system along with results from the AUP superconducting bus test will be presented.