MQXF Cold-mass Assembly and Cryostating H. Prin, D. Duarte Ramos, P. Ferracin, P. Fessia 4 th Joint HiLumi LHC-LARP Annual Meeting November 17-21, 2014.

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Presentation transcript:

MQXF Cold-mass Assembly and Cryostating H. Prin, D. Duarte Ramos, P. Ferracin, P. Fessia 4 th Joint HiLumi LHC-LARP Annual Meeting November 17-21, 2014 KEK, Tsukuba

Cold mass assembly steps Magnets reception (visual inspection, mechanical and electrical measurement…) Cold mass assembly 1.Magnets alignment on the dedicated bench 2.Alignment key installation and welding to the magnet yoke 3.Upper shell positioning 18/11/2014 H. Prin, D. Duarte Ramos, P. Ferracin, P. Fessia2 MQXFA or MQXFB MQXFA or MCBXFB

Cold mass assembly steps 4.Tack welding the alignment key and the shell to preserve alignment 5.Rotation by 180° around the longitudinal axis 18/11/2014 H. Prin, D. Duarte Ramos, P. Ferracin, P. Fessia3

Cold mass assembly steps 6.Transfer inside assembly cradles 7.Magnets alignment measurement (at the yoke level) 18/11/2014 H. Prin, D. Duarte Ramos, P. Ferracin, P. Fessia4 1.Individual geometrical measurements of straightness in horizontal and vertical planes, twist over full length 2.Pitch, yaw and roll angle between magnets

Cold mass assembly steps 8.Bus bars installation and connection 9.Instrumentation wires connection (V-Taps, Quench heaters, cryogenic instrumentation…) 10.Electrical tests (check instrumentation and general wiring) 18/11/2014 H. Prin, D. Duarte Ramos, P. Ferracin, P. Fessia5 Wires preparationWires routingWires connectionResistive heaterCryo Thermometer

Cold mass assembly steps 11.Cold bore tube installation 12.Heat exchanger tubes insertion 13.Upper shell installation 14.Electrical tests (final check before welding, very important!) 18/11/2014 H. Prin, D. Duarte Ramos, P. Ferracin, P. Fessia6

Cold mass assembly steps 15.Transfer in the welding press 16.Longitudinal welding 18/11/2014 H. Prin, D. Duarte Ramos, P. Ferracin, P. Fessia7

Cold mass assembly steps 17.Removal from the welding press 18.Welds examination (Visual + X rays) 19.Electrical tests 20.Transfer to finishing bench 21.Geo-magnetic measurements to determine the cold mass main axis 18/11/2014 H. Prin, D. Duarte Ramos, P. Ferracin, P. Fessia8 Cold mass transfer to the finishing benchTracker in position during measurements Existing QIMM and DIMM magnetic measurement rotating coil systems

Cold mass assembly steps 21.Welded cylinder cutting extremities and machining 22.Support bases alignment and welding 23.Equipped end covers (flanges and bellows) alignment and welding 24.Cold bore and heat exchangers alignment and welding to the end covers 25.(Pick-up support alignment and welding if any) 18/11/2014 H. Prin, D. Duarte Ramos, P. Ferracin, P. Fessia9

Cold mass assembly steps 26.Cold mass geometry measurement 27.Electrical tests 28.Warm magnetic measurements and polarity checks (if different from step 21.) 18/11/2014 H. Prin, D. Duarte Ramos, P. Ferracin, P. Fessia10 Cold mass finishing benches Geometric measurement mole Laser tracker

Cold mass assembly steps 29.Cold mass preparation for pressure/leak and cold tests: weld caps on covers apertures 30.Weld examination (Visual + X rays) 31.Transfer and connect the cold mass into the pressure test tank 32.Perform pressure and leak tests 33.QA documentation 18/11/2014 H. Prin, D. Duarte Ramos, P. Ferracin, P. Fessia11 Preparation for leak/pressure and cold tests Insertion in the pressure/leak test tank Leak detection diagram = f (pressure)

Cryostating steps Only the main steps are listed The list is for the most complex cryostat variant, i.e. with jumper and phase separator, thus including a so-called service module Intermediate leak checks and electrical tests will be done at critical steps (to be defined) A pressure test may be required at the end, before shipping to the cold test facility Assuming an LHC type cryostat with support posts and a bottom tray supported shield. The sequence may end up quite different if we need to implement an alternative cryostat design. 18/11/2014 H. Prin, D. Duarte Ramos, P. Ferracin, P. Fessia12

The examples of the IR quad and LHC main dipole 18/11/2014 H. Prin, D. Duarte Ramos, P. Ferracin, P. Fessia13

Cryostating steps (I) 1.Assembly of 1.9 K auxiliary lines, outside the cold mass 1.pumping line, aux. bus-bar lines, quench line, etc. 2.Preparation of instrumentation cables 1.present LHC choice is to connect all of them to instrumentation feed-box on top of the cryostat 3.Assembly the cold mass onto the bottom tray and cold supports subassembly 4.Wrapping multi-layer insulation (MLI) around the cold mass 5.Assembly of the thermal shield shells and auxiliary 70K lines, if any 6.Wrapping MLI around the thermal shields 7.Insertion into the vacuum vessel 1.in this phase only 2 lifting points at the extremities 8.Fastening the cold supports 18/11/2014 H. Prin, D. Duarte Ramos, P. Ferracin, P. Fessia14

Cryostating steps (II) 9.Welding of cryogenic piping and phase separators 10.Assembly of the instrumentation feed-through (IFS) 11.Splice brazing and welding of bus-bars bypass and temporary cryo circuits for cold testing (those that may not be done during cold mass assembly) 12.Closing of the service module thermal shield and vacuum vessel 13.Assembly of the jumper to the QRL and the IFS box 14.Final tests and preparation for transport to SM18 for cold testing 15.Cold test 16.Stripping 17.Interfaces preparation for tunnel installation 18.Shielding/beam screen insertion 18/11/2014 H. Prin, D. Duarte Ramos, P. Ferracin, P. Fessia15

Appendix 18/11/2014 H. Prin, D. Duarte Ramos, P. Ferracin, P. Fessia16

Computation of deflection Assumptions – Total length: 9.5 m – Mass/m: 1500 kg/m – OD: 630 mm – Vessel thickness: 8, 10 and 12 mm – Only the moment of inertia of the vessel is considered Minimum deflection – C = 2.12 m Maximum deflection – C = 0 m 18/11/2014 H. Prin, D. Duarte Ramos, P. Ferracin, P. Fessia17 TH8 mm10 mm12 mm Y min0.20 mm0.16 mm0.14 mm Y max9.83 mm7.94 mm6.68 mm

Computation of deflection 18/11/2014 H. Prin, D. Duarte Ramos, P. Ferracin, P. Fessia18

Cold mass and cryostat Open issues Welding on backing strip on aluminum shells Thickness of stainless steel shell (8 or 10 mm) Supports of the cold-mass – Considered scenario 2 (not at the extremities) or 3 supports while inserting the magnet (LHC main dipole scenario) 3 support of the cold-mass inside the cryostat 2 supports for the cryostat 18/11/2014 H. Prin, D. Duarte Ramos, P. Ferracin, P. Fessia19

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