Hystory (brief), Assumptions and General Approach An iron yoke with a window frame + asymmetric coils was our starting point. We did not look at different lay-outs First attempts were done for trying to have same angles for left and rigth branch of each coil but different number of turns (missing turns). Roxie + ANSYS large sistematic. Hypothesis soon abandoned in favour of asymmetry in angles (both and in the Roxie language). Five block configuration, one layer coil analysed. Partly this is a heritage of DISCORAP project; partly comes from the need to have as many degrees of freedom as possible We shall aim at designing feasible coils and magnet We should like to have soon an idea of mechanics
D2 CONFIGURATIONS P.Fabbricatore & S.Farinon INFN Genova
Starting from previous studies done at CERN, BNL and BLNL, possile
cross sections of D2 dipole were preliminary investigated. Among
many analysed lay-outs, three configurations looked promising and
we should like to have an opinion from colleagues before continuing
and focussing on one configuration. The main features of these
configurations are here described. The magnetic analyses were
mainly done with Roxie, with complementary studies performed with
ANSYS and COMSOL This activity related to D2 is done in the
framework o f a collaboration agreement (under definition) R&D
ACTIVITIES RELATING TO HIGH LUMINOSITY LHC (HL-LHC) SUPERCONDUCTING
MAGNETS between CERN and INFN (The INFN coordinator is G.Volpini).
D2 is being developed by INFN Genova and the activities are
organised in a Work Package: WP2 PADS Progetto Avanzato per i
Dipoli di Separazione (Advanced design of the separation dipoles).
Framework Hystory (brief), Assumptions and General Approach An iron
yoke with a window frame + asymmetric coils was our starting point.
We did not look at different lay-outs First attempts were done for
trying to have same angles for left and rigth branch of each coil
but different number of turns (missing turns). Roxie + ANSYS large
sistematic. Hypothesis soon abandoned in favour of asymmetry in
angles (both and in the Roxie language). Five block configuration,
one layer coil analysed. Partly this is a heritage of DISCORAP
project; partly comes from the need to have as many degrees of
freedom as possible We shall aim at designing feasible coils and
magnet We should like to have soon an idea of mechanics Integral
field 35 Tm Magnetic field from (3.5) 4T to 1.9K Beam separation
188 mm Coil aperture 105 mm GFR radius 35 mm Target variations of
b2 b3 b4 due to saturation< 10 units Change of b2 b3 b4 between
6.5 and 7 TeV< 1 unit Working point on load line max 70% (or
rather lower?) LHC outer layer conductor Focus on geometrical
harmonics and iron saturation effects Hystory (brief), Assumptions
and General Approach (cont) Missing turns ( Abandoned.. but we got
sensitivity to the parameters affecting the field quality.
Configurations with 58 to 64 turns were studied)) The studies with
missing turns showed that in order to better control the field
quality we need to have different angles and for right and left
branches of same coil. We started from the configurations
identified with missing turn approach and optimized the angles and
for both branches of the coil with Roxie. Only three configurations
appeared to be promising with 58, 59 and 63 turns. No acceptable
configurations with 60,61,62 and 64 turns were found (however our
systematic could miss some good lay-out). The study is indeed not
yet complete, missing the analysis of stability of the
configuration (how much small geometrical deviations are affecting
the field quality). Optimizing asymetrically the angles
Configuration INFN_0_1 29 turns both branches 5 asymmetric blocks
with turns: 11,8,4,4,2 right 12,8,4,4,1 left Iron window X =190 mm
x Y= 117 mm Shimming: R=40 mm, Dx 35 mm, Dy=10 mm, hole R h =20 mm
Iron ext 310 mm x 250mm B bore = A B peak = A B peak /B bore =
Inductance at T 2.9 mH/m Margin to load line at 4.00 T 60.4% Margin
to load line at T 70.2% Main Characteristics Dx Dy R RhRh Input
data for Roxie Configuration INFN_0_1 Load lines Configuration
INFN_0_1 Field Harmonics Configuration INFN_0_1 Mag. Field Map
Configuration INFN_0_1 Fringe 1 m midplane 18.6 mT Fringe Field
Configuration INFN_0_1 Fringe 1 m midplane with 10 mm cryostat wall
15.0 mT Configuration INFN_0_1 Mechanical analysis just started.
Presently the model is ready. Configuration INFN_1_1 32 turns left
branch 31 turns right 10+7,5,4,3,2 right 19,5,4,2,2 left Iron
window X =180 mm x Y=95 mm Shimming: R=40 mm, hole R h =20 mm Iron
ext 310 mm x 250mm B bore A B peak A B peak /B bore = Inductance at
B= 4.52 T 3.52 mH/m Margin to load line at 4.00 T 51.0 % Margin to
load line at 4.52 T 59.2% Margin to load line at 5.00 T 67.4 % R
RhRh Main Characteristics Configuration INFN_1_1 Detail of the coil
cross section Input data for Roxie Configuration INFN_1_1 Load
lines Configuration INFN_1_1 Field Harmonics Configuration INFN_1_1
Complex!..Not impossible Courtesy of Susana Izquierdo Bermudez Many
block to block jumps Configuration INFN_2 Main Characteristics 30
turns left branch 29 turns right 16,8,3,2 right 17,8,3,2 left Iron
window X =186 mm x Y=107 mm Shimming: R=40 mm, Dx 30 mm, Dy=10 mm
Iron ext 310 mm x 250mm B bore A B peak A B peak /B bore =
Inductance at B= 4.57 T mH/m Margin to load line at 4.00 T 57.8 %
Margin to load line at 4.52 T 67.6 % Dx Dy R Input data for Roxie
Configuration INFN_2 Load lines Configuration INFN_2 Field
Harmonics Configuration INFN_2 INFN_0_1INFN_1_1INFN_2 Mag. Field
bore (T) From 4 to 4.5From 4 to 5From 4 to 4.5 Blocks554 B bore /B
peak Margin on load line From 60 4T to T From 51 4T to T to 67 5T
From 57 4T to T Turns58= = =30+29 Comments1)4T option 2)4.5 T
option 3)Lay-out 4)Coil ends 5)Connections 1)4.5 T option 2)5.0 T
option 3)Lay-out 4)Coil ends 5)Connections 1)4T option 2)4.5 T
option 3)Lay-out 4)Coil ends 5)Connections 6)Very good b2 to b7
7)High b8 (6 units) and b9 (9 units) Summarizing Table All
Configurations
