1 qxf heater proposal m. marchevsky, h. felice, t. salmi, d. cheng, g. sabbi, lbnl

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  • Slide 1
  • 1 QXF heater proposal M. Marchevsky, H. Felice, T. Salmi, D. Cheng, G. Sabbi, LBNL
  • Slide 2
  • 2 General considerations Active quench protection: to create the largest normal zone in the shortest possible time; distribute stored magnet energy dissipation as uniformly as possible. Heater: layered geometry means that heat from comes from the surface to generate a bulk transition in the coil inherently not very efficient method. Furthermore, the insulation barrier and the heat capacity associated with heater material slow down the heat transfer to the cable. Bulk heating could be a better idea (eddy currents, etc) QXF heaters should be: -Powerful enough to meet the quench protection challenges -Similarly designed for inner and outer layer -Redundant -Scalable : same pattern for long and short QXF Surface power density of > 100 W/cm 2 is desirable, based on HQ / LQ experience
  • Slide 3
  • 3 LARP magnet heater options a ) HQ-style heater a single strip meandering along the coil inner and outer surfaces b) LQ/LHQ style a meandering strip with varying cross-section heating station concept c) Straight strips separately covering the high field and low filed zones and separately powered d) A modification of c) with sections lengths optimized according to the superconducting margin of each section
  • Slide 4
  • 4 Choosing the layout The only layout that was successfully tested in long magnets if the LQ-style one (b). It allows extension over large distances by spacing the heating stations further apart Its first alternative is the pattern c that is planned to be checked against the pattern b in the upcoming test of the LHQ. The trace containing both patterns is being fabricated :
  • Slide 5
  • 5 Optimizing period of the LHQ-style heater R1R1 R2R2 R3R3 R4R4 R3R3 R2R2 period r2r2 U1U1 U2U2 hot spot at the inner side of the curved segment! r1r1 W1W1 L1L1 W2W2 L2L2 r1r1 r2r2 L3L3 Dimensionmm L2L2 5 r1r1 2.5 W2W2 8.98 d0.000025 L4000 Optimize power per unit area of the heating station for L 1, W 1 LHQ Coil 1 heater pattern(LQ-style)
  • Slide 6
  • 6 Possible design parameters (QXF) N=17 W 1 = 44 mm, L 1 = 210 mm p HS =127 W/cm 2 Assuming =5 10 -7 (SS304 at 100 K), U 0 =350 V and L= 4 m: R heater = 4.81 For W 1 = 44 mm we can then have the heating station coverage from the second turn from the pole to the third turn from the outer turn same as in HQ.
  • Slide 7
  • 7 Same design parameters for SQXF For the SQXF length of 1.3 m and same heater design parameters we have a large reserve in heater power: p HS =1500 W/cm 2 R heater = 1.42 SQXF heaters can be then powered in series with a resistor to simulate the QXF heater behavior.
  • Slide 8
  • 8 Further steps on optimizing heater performance Reducing heat capacity of the heater and increasing heat diffusivity of the insulation is the most straightforward path Heater powering is done by discharging a capacitor through it - technically simple, but not optimal for the achieving the fastest heat transfer. Making heater hot in a shortest possible time is needed Heater geometry should be further adjusted based on the quench propagation velocity, as the timescale for the active protection is the sum of time needed for the heat to reach the cable edge plus the timescale for the quench propagation between heating stations.
  • Slide 9
  • 9 Heat transfer basics is thermal conductivity (W/(mK)) is density (kg/m) is specific heat capacity (J/(kgK)) - thermal diffusivity Materials with high thermal diffusivity: Pyrolytic graphite, parallel to layers 1.22 10 -3 m 2 /s Silver, pure (99.9%) 1.65 10 -4 m 2 /s Silicon 8.8 10 5 m 2 /s Helium (300 K, 1 atm) 1.910 4 m 2 /s Can we introduce voids in the heater insulation layer to benefit from high thermal diffusivity of the helium gas???
  • Slide 10
  • 10 Thermal diffusivity of the coil materials SS304 Kapton Cu G10
  • Slide 11
  • 11 Transverse heat diffusion H. S. Carslaw and J. C. Jaeger, Conduction of Heat in Solids (Oxford University Press, New York, 1959), 2nd ed., p. 101. If the initial temperature distribution within a thermally insulated solid of uniform thickness L is T(x,0), the temperature distribution at any later time t is given by: x L 0 surroundings heater insulation cable Can be solved recursively for = (T(x,t)), using small time increments QQ The amount of heat introduced in the heater zone at each step is calculated based on the heater resistance R(T(x,t)), heat capacity c(T(x,t)) and current I(t)
  • Slide 12
  • 12 Heater simulation tool
  • Slide 13
  • 13 Simulation of heater operation U 0 =100 V C=50 mF Heater (SS304) thickness = 120 micron Heater length = 1 m Heater width = 10 mm Insulation 140 micron of Kapton 59 ms to reach 18.6 K at ~0.8 mm depth into the cable
  • Slide 14
  • 14 Heater delay studies % of Iss T. Salmi, H. Felice HQ01e Experimental verification of heater performance in and calibration of delay versus heater power, magnet current and ambient temperature was conducted for HQ01 and is in progress for HQ02. These data are of great value for calibrating numerical tools and optimizing heater geometry based on variation of the quench delay values for different sections of the winding.
  • Slide 15
  • 15 Heater temperature evolution in HQ01d 5 % Heater temperature rises to 90 K This is still a low temperature for preserving the integrity of heater material 5 % Heater temperature reaches a maximum 35 ms after HFU firing. This is a long time for protection! Resistance of the four-heater circuit after HFU firing
  • Slide 16
  • 16 Conclusions Heater design work is in progress at LBL, involving -development of the simulation tools -verification with current and future magnet tests (HQ, LHQ) -search for the better heater material and doing evaluative studies -new ideas about optimizing heater powering scheme LQ/LHQ style heater pattern is proposed as basis for the QXF heaters; its further optimization will be done using existing and newly developing tools. It is also pending experimental verification of performance in the upcoming LHQ mirror test.