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ATLAS+ Design Concepts - FCC-hh detector magnet - Matthias Mentink Alexey Dudarev Helder Silva Leonardo Erik Gerritse Herman ten Kate FCC Detectors Workshop.

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Presentation on theme: "ATLAS+ Design Concepts - FCC-hh detector magnet - Matthias Mentink Alexey Dudarev Helder Silva Leonardo Erik Gerritse Herman ten Kate FCC Detectors Workshop."— Presentation transcript:

1 ATLAS+ Design Concepts - FCC-hh detector magnet - Matthias Mentink Alexey Dudarev Helder Silva Leonardo Erik Gerritse Herman ten Kate FCC Detectors Workshop @ CERN, 3 Feb 2015 1

2 Overview  Introduction  Scaled up ATLAS concept  Angled concept  Extended End Cap Toroid concept  Conclusion 2

3 Introduction PropertyValue Stored energy 1.5 GJ (1.1 GJ BT + 2x 220 MJ ECT) Conductor mass 120 t BT + 2x 20 t ECT Length BT [m]25 Inner radius BT [m]4.7 Outer radius BT [m]10 Length ECT [m]5 Inner radius ECT [m]1.65 Outer radius ECT [m]4.7 Field integral η = 0 [Tm] (between conductors) 4 Field integral η = 2.44 [Tm] (between conductors) 9 Atlas toroidal field for muon detection:  Barrel Toroid (BT): open structure  End Cap Toroids: 8 coils in single cryostat 3

4 ATLAS+, a Scaled up ATLAS Concept PropertyValue Stored energy 51 GJ (48 GJ BT + 2x 1.6 GJ ECT) Conductor mass 4.3 kt (10x 400 t BT modules + 2x 140 t ECT) Length BT [m]52 Inner radius BT [m]7 Outer radius BT [m]15 Length ECT [m]8 Inner radius ECT [m]2.5 Outer radius ECT [m]7 Field integral η = 0 [Tm] (between conductors) 16 Field integral η = 2.44 [Tm] (between conductors) 16 Same concept as ATLAS, but higher field and more volume  More stored energy. Individual cryostats for barrel toroids. Possibility of single cryostat for each end cap toroid. 4

5 ATLAS+ variant - Angled Concept PropertyValue Stored energy 52 GJ (48 GJ BT + 2x 2.1 GJ ECT) Conductor mass 4.3 kt (10x 400 t BT modules + 2x 170 t ECT) Length BT [m]52 Inner radius BT [m]7 Outer radius BT [m]15 ECT inclination angle ( o )20 Field integral η = 0 (between conductors) [Tm] 16 Field integral η = 2.44 (between conductors) [Tm] 16 Reduction in peak field on conductor. Less complicated muon chamber placement, but… Blind spots at inclination angle (20 o ) 5

6 ATLAS+ variant - Extended End Cap Toroid Concept Reduction in magnetic field at edges:  Reduction in stored energy and total mass  More homogeneous field integral as function of η Reduced mass and length of BT modules. PropertyValue Stored energy 40 GJ (34 GJ BT + 2x 3 GJ ECT) Conductor mass 3.3 kt (10x 280 t BT modules + 20x 25 t ECT modules) Length BT [m]36 Inner radius BT [m]7 Outer radius BT [m]15 Length ECT [m]8 Inner radius ECT [m]2.5 Outer radius ECT [m]15 Field integral η = 0 [Tm] (between conductors) 16 Field integral η = 2.44 [Tm] (between conductors) 16 6

7 Conclusion ATLAS+ concepts:  Scaled up ATLAS concept: a proven design, we know how to make it…..  Angled ATLAS concept: significant reduction in peak magnetic field in the conductor.  Extended End Cap Concept featuring: 7 Open coil structure for both the Barrel Toroid and End Cap Toroids enabling better positioning of muon chambers around the toroids. More homogeneous field integral  Reduced stored energy for the same field integral at η = 0. Reduction in Barrel Toroid coil length and mass, but larger ECT coils. Coil units smaller, easier assembly, smaller crane loads……

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