Download - MSI-V J. Borburgh, B. Balhan, E. Carlier, J.M. Cravero, B. Goddard, D. Nisbet, P. Van Trappen, F. Velotti

MSI-V

J. Borburgh, B. Balhan, E. Carlier, J.M. Cravero, B. Goddard, D. Nisbet, P. Van Trappen, F. Velotti

outline

1. Septum requirements2. Retained septum concept3. Mechanical concept and integration4. Magnet control electronics5. Power supply6. Planning and resource requirements

Injection trajectory

MSI-V blade

Courtesy: F. Velotti

TIDVG

MSI

Septum requirementsBeam p [GeV/c] B.Rho [T.m] Angle [mrad] B.dl [T.m]

LHC/FT ions 17.1 60.0 13.0 0.78

LHC p+ 26.0 89.7 10 0.90

CNGS p+ 14.0 49.7 8.0 0.40

Values indicated assume: 3.0 m magnetic length 60 mm full vertical gap 5 mm septum width

• Flat-top: tentatively 1-2. 10-3 over at least 100 µs (depending on timing accuracy?)• Requested margin on magnet strength: being able to deflect protons 13 mrad at 26 GeV

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Basic magnet characteristics

• Under vacuum pulsed magnet• Assuming half sine with third harmonic:

100 μs at 10-3 precision → pulse width >~800 μs• Layout proposed: 2 magnet blocks under vacuum• 5 mm thick copper/stainless steel septum blade• 1 single vacuum vessel

Magnet parametersMagnetic length 996 + 996 mm

Physical length 1060 + 1060 mm

Gap height 60.4 mm

Horizontal aperture 102 mm

Magnetic field 0.541 T

∫B.dl 0.583 + 0.583 T.m

Deflection angle 6.5 + 6.5 mrad

Ipeak 28.2 kA

Pulse width ~3 ms

Septum thickness 4.5 + 0.5 (copper + s.steel) mm

Vacuum tank length ~ 2500 mm

Expected lifetime 60.106 # pulses

Radial septum position 1/2

FT beam at entrance of septum Ion beam at exit of septum

Septum blade position at grazing incidence with orbiting FT beam

• Lphysical = 3000 mm, downstream in the ‘shade’ of MSI (~ 40 mm septum thickness).

• Radial position blade when @grazing incidence with orbiting FT beam : – 48 mm upstream, 43 mm downstream (i.e. @1.66 mrad)

• Radial position blade when @grazing incidence with orbiting ion beam (since closer to orbiting beam than FT): – 72 mm upstream, 51 mm downstream (i.e. @7.33 mrad)

• Proposed positioning range (septum downstream):Radial: 42 – 52 mmAngular: 0 – 8 mrad

• No retracting foreseen

Radial septum position 2/2

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Mechanical Concept 2 magnets, 1 common vacuum vessel 1 feedthrough per magnet Outside vacuum remote displacement system Impedance screen 2 VPI’s (tbc.) 2 transformers close to tank.

Design and integrationDownstream Cross-Section Upstream Cross-Section

Top Cross-Section

Possible integration

Cooling

• Magnet needs water cooling:• ΔP = 12 bar• Pin max. = 15 bar• Flow: Q ≈ 10 l/min.

Auxiliary pump may be required in tunnel to keep pressure within range magnet operating range.

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Controls needs

• Dead beat control system by switching on/off 48V AC motors• Local control with Touch Panel, remote control through FESA• Siemens S7-300 F-CPU system with SIMOCODE modules for

motor management• Fail-safe modules for human and machine protection

• Position measurement by potentiometers, precision 100 µm• Voltage measurement by analogue input cards; this limits

cable length to 200 m when shielded

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Powering• Proposal is to use MegaDiscaP type converter that

is a high power / fast pulsed current source.• MegaDiscaP converters are used in AD since 2012

and will be used for BI.SMV (PSB injection) • One power supply per coil is required to cope

with total load resistance. • Matching transformers with n=16 to be installed

in the tunnel (1m3 per transformer) close to the magnet. (estimated stripline length = 2m)

Maximum operating current 30kA

Flat-top duration (with current stabilization) 500µs

Current precision < 1000 p.p.m.

Primary voltage 2kV

Transformer ratio 16

Septum resistance (total) 0.200mΩ

Resistance @ converter output 0.150Ω

Inductance @ converter output 820uH

Estimated cable length 250m

Estimated stripline length 2m

Converter Parameters

Septum magnet current

Septum Magnet CurrentMegaDiscaP Converter

Still to be studied in detail:oDCCT current measurement installation oMatching transformer design

Outstanding

Leak field validationVacuum equipment requirementsCooling system in the tunnel Detailed integration study Impact of radiation on system

0 10 20 30 40 50 60 700.0

1.0

2.0

3.0

4.0

5.0

6.0

7.0

8.0

9.0

10.0

tank 2

tank 1

tank 4

tank 3

distance from septum (mm)

1/1

00

0 o

f g

ap

fie

ld

Integrated leak field

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Proposed strategy and planning• For LIU-PSB BT.SMV magnets will be removed from the

vacuum tanks for newly constructed septa.• As from 2018, at least 3 magnets will be available, with 6

more after LS2.• These magnets could be re-used to construct 1 MSI-V for

installation in LS2 and spares to be build after LS2.• 1 magnet installed + 1 operational spare

Resource requirementsMaterial budget kCHF

Mechanical design, drawing office 60Vacuum equipment, incl. bake out system, ion pump, gauges

2 x 80

Vacuum vessel 2 x 100Mechanical support 30Remote displacement system mechanics 2 x 50

Electrical connection, incl. feedthrough, stripline, under vacuum connection

2 x 50

Hydraulics, under vacuum, connections in tunnel

50

Remote displacement electronics plus bake-out electronics, incl. cabling and FSU support

120

Power supply, including cabling to tunnel and transformer

500

TOTAL 1320

Manpower MYSeptum hardware 0.8

Septum electronics 0.5

Power supply 1.0

Download - MSI-V J. Borburgh, B. Balhan, E. Carlier, J.M. Cravero, B. Goddard, D. Nisbet, P. Van Trappen, F. Velotti

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