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E. Todesco HL LHC LAYOUT FROM Interaction POINT TO SEPARATION DIPOLE E. Todesco CERN, Geneva Switzerland Acknowledgements: B. Dalena, M. Giovannozzi, R.

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Presentation on theme: "E. Todesco HL LHC LAYOUT FROM Interaction POINT TO SEPARATION DIPOLE E. Todesco CERN, Geneva Switzerland Acknowledgements: B. Dalena, M. Giovannozzi, R."— Presentation transcript:

1 E. Todesco HL LHC LAYOUT FROM Interaction POINT TO SEPARATION DIPOLE E. Todesco CERN, Geneva Switzerland Acknowledgements: B. Dalena, M. Giovannozzi, R. De Maria, S. Fartoukh, B. Holzer, P. Fessia, M. Karppinen, A. Ballarino, J. P. Burnet, R. Ostojic, H. Prin, F. Toral, D. Ramos Revised version 12 April 2013 Napa Valley, 8 th April 2013 LARP – Hilumi collaboration meeting

2 E. Todesco Lay out for HL LHC from IP to D1 - 2 WHERE ARE WE January 2012 Preliminary exploration of 4 layouts (120/140 mm, Nb-Ti and Nb 3 Sn), both triplet and separation dipole July 2012 Aperture and technology selection, 150 mm Nb 3 Sn Summer 2012 Estimates of heat load, shielding and cooling Target of 40 MGy, 5 mW/cm 3 possibly reduced to 20 Mgy So same levels as in LHC – please remember Fall 2012 Conceptual design correctors Winter 2012-2013: Powering, interconnections, layout from IP to D1

3 E. Todesco Lay out for HL LHC from IP to D1 - 3 Layouts LHC Phase-I Layout of Phase I and LHC [R. Ostojic, S. Fartoukh, Chamonix 2010]

4 E. Todesco Lay out for HL LHC from IP to D1 - 4 layouts LHC HL LHC Phase I Thick boxes are magnetic lengths Thin boxes are cryostats

5 E. Todesco Lay out for HL LHC from IP to D1 - 5 QUADRUPOLES 150 mm aperture, 140 T/m, Q1 and Q3 split in two 0.5 m between split cold masses (Q1 and Q3) 0.5 m between end of magnetic length and end of the cryostat Substantial design work ongoing to [P. Ferracin, G. Ambrosio, H. Felice, F. Borgnolutti, S. Izquierdo, M. Juchno, H. Prin …] Cryostat choices: We keep symmetry and modularity (two types only) Alternative: reducing number of cryostats from 4 to 3

6 E. Todesco Lay out for HL LHC from IP to D1 - 6 ORBIT CORRECTORS Requirement is to have 2.5 T m around Q2, and 4.5 T m between Q3 and D1 Nested option to save space (4 m) 2.1 T given by 50% margin with Mikko 4.6 mm width cable, one layer So 1.2 m and 2.2 m respectively allocated Proposal for nested MCBX (M. Karppinen)

7 E. Todesco Lay out for HL LHC from IP to D1 - 7 ORBIT CORRECTORS Alternative options I would exclude design with two layers, 4 T, saving 2 m but having 4 times torque Canted dipole ? – Some preliminary work being done Proposal for canted dipole [J. V. Nutgeren, S. Caspi]

8 E. Todesco Lay out for HL LHC from IP to D1 - 8 NON LINEAR CORRECTORS Superferric option, no nested, max saturation of 20% TF We satisfy the ABP requirements including a safety factor 2 for order 2,3,4 and a factor 1.5 for 5 and 6 corrector strength [F. Toral] Typical length of 100 mm – short coil ends Longer: skew quadrupole (730 mm) and b 6 ( 350 mm) a 2, b 3, a 3, b 4, a 4, b 5, a 5, b 6, a 6 : nine objects Assume 100 mm distance coil to coil (80 mm magnet to magnet) – Total length is 2.5 m

9 E. Todesco Lay out for HL LHC from IP to D1 - 9 NONLINEAR CORRECTORS Requirements based on tracking studies [M. Giovannozzi et al] Problem of longitudinal cross-talk being studied [F. Toral, B. Auchmann]

10 E. Todesco Lay out for HL LHC from IP to D1 - 10 NON LINEAR CORRECTORS Advantages Not nested – easier operation Very short heads (20 mm) Very robust to radiation Alternative options LHC design – larger field so shorter magnet But longer heads

11 E. Todesco Lay out for HL LHC from IP to D1 - 11 SEPARATION DIPOLE D1 35 T m required Assuming one layer of MB dipole cable, 5.2 T at 70% on the loadline – less than 6.7 m long [Q. Xu, T. Nakamoto] One layer reduces fringe field Alternative options: two layers, or reduce margin (in both cases we gain 1-2 m) I would wait to know heat load – first results coming in the next weeks

12 E. Todesco Lay out for HL LHC from IP to D1 - 12 BPM position Grey lines: position to avoid for BPM Multiple of 3.74 m [J. P. Koutchouk, R. Jones, and S. Fartoukh] Allowable band width ~1.5 m around optimal position – to be assessed So they are all ok except the last one between CP and D1

13 E. Todesco Lay out for HL LHC from IP to D1 - 13 CURRENTS AND POWERING Currents Quadrupoles: 17 kA (four circuits or one plus two trims) Corrector dipole: 2.4 kA (two times three circuits) Nonlinear correctors: 100 A (nine cicuits) Separation dipole: 11 kA (outer dipole cable) Cooling [R. Van Weelderen] Triplet and orbit correctors: two HX, 80 mm, at 45 degrees Best option: a separate HX for D1 and corrector package

14 E. Todesco Lay out for HL LHC from IP to D1 - 14 CURRENTS AND POWERING Favourite option Phase-separator & Piping entries/exits Phase-separator & Piping entries/exits Possible QRL-jumper SM & QRL-jumper Phase- separator Piping entries/exits actively cooled Q1,Q2a,Q2b,Q3: actively cooled for about 41 m, double-HXs needed CP,D1 : actively cooled for about 16 m, double-HXs needed actively cooled

15 E. Todesco Lay out for HL LHC from IP to D1 - 15 CURRENTS AND POWERING Currents Quadrupoles: 17 kA (four circuits or one plus two trims) Corrector dipole: 2.4 kA (two times three circuits) Nonlinear correctors: 100 A (nine cicuits) Separation dipole: 11 kA (outer dipole cable) Cooling [R. Van Weelderen] Triplet and orbit correctors: two HX, 80 mm, at 45 degrees Best option: a separate HX for D1 and corrector package

16 E. Todesco Lay out for HL LHC from IP to D1 - 16 CURRENTS AND POWERING Currents Quadrupoles: 17 kA (four circuits or one plus two trims) Corrector dipole: 2.4 kA (two times three circuits) Nonlinear correctors: 100 A (nine cicuits) Separation dipole: 11 kA (outer dipole cable) Cooling [R. Van Weelderen] Triplet and orbit correctors: two HX, 80 mm, at 45 degrees Best option: a separate HX for D1 and corrector package

17 E. Todesco Lay out for HL LHC from IP to D1 - 17 CURRENTS AND POWERING Three possibilities for the triplet One power converter, four magnet in series plus trims Discarded because of complexity Four power converter, one per magnet Discarded because too many kA to bring around This leaves one option …

18 E. Todesco Lay out for HL LHC from IP to D1 - 18 CURRENTS AND POWERING

19 E. Todesco Lay out for HL LHC from IP to D1 - 19 WHO DOES WHAT (TENTATIVE)

20 E. Todesco Lay out for HL LHC from IP to D1 - 20 RISKS We have chosen the layout that maximizes performance This (obviously) does not minimize risk Main concerns Large fraction of coils rejected – not suitable for production Producing and testing coils reduces the risk The choice of a cored cable has never been validated HQ02 will have it, we should have also HQ03 If all resources switched on QXF we stay two years without data HQ started in 2009, in 5 years two magnet tested – too slow for QXF Acceleration on HQ needed – its results relevant for QXF design How to minimize risks Profit of synergies with 11 T HQ03 should be planned and done asap Manufacturing and test of long coils should be pursed (LHQ)

21 E. Todesco Lay out for HL LHC from IP to D1 - 21 CONCLUSION We have a baseline from IP up to D1 This is needed to estimate the heat load on correctors and D1 [June 2013] So dimensioning cryogenics, iron holes, and possibly feeding back on aperture Do we really need 160 mm D1 aperture ? Do we need larger aperture for correctors ? We will review the layout at the end of the year Feeding back more information on the heads and interconnections Layout up to Q4 needed by June Work on D2 started [P. Wanderer, R. Gupta] Work on Q4 ongoing – final choice coming soon [M. Segreti, J. M. Rifflet]

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