More beam (muons) from the AGS
description
Transcript of More beam (muons) from the AGS
More beam (muons) from the AGS
AGS RHIC Users Group MeetingEDM Workshop
Brookhaven National Laboratory7 June 2006
Phil Pile
Outline
• AGS Issues• V1 Beam Line – present limitations• V1 Beam Line – possible improvements• To Do
More beam from the AGS
The expertsBNL• Hugh Brown – V1 / Beam Line Design
University of Illinois • Peter Kammel• Paul Debevec• Sara Knaack
They began studies over two years ago on how to improve Hugh Brown’s V1 beam line design.
g-2 short history• E821 (as run)
Year Weeks Hours Integrated Protons Remarks1996 8 196 - pulse-on-demand1997 8 pulse-on-demand
4 546 0.13 x 1020 1st physics run1998 2 pulse-on-demand
4 254 0.08 x 1020
1999 2 pulse-on-demand9 924 0.4 x 1020
2000 12 1312 0.5 x 1020
2001 12 793 0.6 x 1020
TOTALS 63 40251.7 x 1020
• E969 (my estimate)2010 10 960 - Commissioning
2011 21 1920 1.3 x 102 15 weeks with RHIC on
• AGS Total integrated protons (SEB+FEB), 1993-2002 = 6.5 x 1020
PROTON BEAM FY96 FY97 FY98/99 FY2000 FY2001 FY2002SEB SEB FEB (g-2) SEB FEB (g-2) FEB (g-2) FEB (g-2) SEB
Beam Energy 24 GeV 24 GeV 24 GeV 24 GeV 24 GeV 24 GeV 24 GeV* 22 GeV* Peak Beam Intensity 62 x 1012 ppp 62 x 1012 ppp 46 x 1012 ppp 72 x 1012 ppp 58 x 1012 ppp 61 x 1012 ppp 63 x 1012 ppp 76 x 1012 ppp Total protons accelerated 0.9 x 1020 0.4 x 1020 0.1 x 1020 0.9 x 1020 0.4 x 1020 0.5 x 1020 0.6 x 1020 0.7 x 1020
Spill Length/Cycle Time 1.6 sec/3.6 sec 1.6 sec/3.6 sec 2.8 sec/5.1 sec 2.4 sec/5.4 sec -> Duty Cycle 44% 44% 55% 44%
Spill Structure Modulation(peak-average) /average 20% 20% 20% 20%
Average Availability/Best Week 76% / 92% 71% / 79% 58 % / 67 % 71% / 88% 55 % / 83 % 74 % / 87 % 83 % / 88 % 85 % / 97 %
HEAVY ION BEAM Au Au Fe (NASA) Au Fe (NASA) Fe (NASA) Fe (NASA) Fe (NASA)
Beam Energy /nucleon 11 / 4 / 2 GeV 11 / 8 / 6 GeV 1.0 / 0.6 GeV 11 GeV 1.0 / 0.6 GeV 1.0 GeV 1.0 GeV 1.0 GeVPeak Beam Intensity 4 x 108 Au/p 17 x 108 Au/p 20 x 108 Fe/p 9 x 108 Au/bunch 36 x 108 Fe/p 17 x 108 Fe/p 80 x 108 Fe/p 49 x 108 Fe/p
Spill Length/Cycle Time 1.4 sec/3.6 sec 1.5 sec/4.0 sec 1.2 sec/3.0 sec 0.9 sec/3.3 sec 0.9 sec/3.3 sec 0.9 sec/3.3 sec -> Duty Cycle 39% 38% 40 % 27% 27% 27%
Spill Structure Modulation(peak-average) /average <20% <20% <20% <20% <20% <20%
Average Availability 80% 82 % 96 % 81 % 90 % 90 % 97 % 84 %
* Westinghouse Motor Generator
AGS performance T. Roser
12:00 o’clock
2:00 o’clock
4:00 o’clock6:00 o’clock
8:00 o’clock
PHOBOS10:00 o’clock
BRAHMS
STAR (p)
PHENIX (p)RHIC
AGS
LINAC
BOOSTER
TANDEMS
NSRL (NASA) g-2U-line
Pol. Proton Source
High Intensity Source
Slow extraction
Fast extraction AGS:•Intensity: 7 1013 protons/pulse•Injector to RHIC:< 1 hour about every 4 hours
AGS/RHIC Accelerator Complexp gas jet target
AGS Complex
Booster
AGS
V1 / Beam Line
g-2 experiment
to RHIC
Linac
TTBC-AD Admin
NSRL
AGS and Booster need a re-hab before returning to high intensity
3.094 GeV/c muon channel, 8 quads
3.15 GeV/c pion front end
Inflector
E821 beam line and muon storage ring
Beam Studies Summary March 16 ‘06
Condition N NP2Fig of Merit
for 1x 1.000 1.000 1
for 2x 2.503 2.492 2.338
for 4x 3.721 3.698 3.180
for 4x pi+3% 3.529 3.265 2.435
for 4x pi+5% 3.244 2.650 1.622
back 1x 0.661 0.666 0.818
back 2x 1.924 1.793 1.606
back 4x 2.703 2.460 1.747
back 4x qs 3.010 2.694 1.787Forward: + 3% looks promising. Factor 2.4 over E821. Main uncertainties: model/reality difference in P scaling (factor 2), pion flash prediction, phase space effect.
Can largely be verified in beam test run. Investigate K1/K2 improvement.
Backward: Factor 1.75 over E821 with effort. Gets hit twice by 2nd order effects (intensity and phase space losses). Needs to overcome those to remain competitive.Main uncertainties: New injection beam line and 2nd order effects. Higher cost and effort.Can only be partially verified in beam test run.
differences Petersightly different tunesfit of XX’ sigma (Dave)optimized injection mag in q tuneforward -8% due to finite target
(Peter Kammel Slide)
What I’ll discuss today
See http://www.npl.uiuc.edu:8081/ for more
decay channel (3 GeV/c ’s)Add 30 new 4Q24’s
New Inflector
E969 beam line and muon storage ring
IMPROVED E821 Beam Line
New VQ12
So how do we get more muons?
The basic approach - Reduce beta function in decay channel (add quads) and get more muons into storage ring with no increase in pions.
Some Issues:• Pion flash• First order beam blow-up due to extended target• 2nd order beam blow-up• Inflector/Ring admittance• Muon Polarization
Q1Q2D1
D2Q3
Q5
D3
D4D4Q7Q8
Q9a
Q10
Q11
P1Q12
Q13
Q14
Q15
Q16
Q17
Q18
Q19
P2Q20
D5Q21
Q22
Q23a
Q24
Q25
D6
Q26
Q27
Q28
Q29
D4SX
Q9SX
K1K2
W409
MTCH
W430
W450
W470
SWP
W608
K3K4
W646
W678
W712
FBAK
HOLE
CNTR
TAR
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m o
r cm
/%
x (cm)
y (cm)
dy/dp (cm/%)
dx/dp (cm/%)
10 20 30 40 50 60 70 80 90 100 meters
The E821 beam line (1 % dp/p), 3.15 GeV/c pion beamFIRST ORDER CALCULATION and target 0 cm d/s
1. 0.2616 17.0 0.1880 60.0 8.776 1.0 3.1523 /pion/ ;
P1P2
Q1Q2D1
D2Q3
Q5
D3
D4D4Q7
Q8
P1Q9Q10
Q10a
Q10b
Q11
Q11a
Q11b
Q11c
Q12
Q12a
Q12b
Q12c
Q13
Q13a
Q13b
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Q14
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Q15
Q15a
Q15b
Q15c
Q16
Q16a
Q16b
Q16c
Q17
Q17a
Q17b
Q17c
Q18
Q18a
Q18b
Q18c
Q19
Q19b
P2
D5Q21
Q22
Q23a
Q24
Q25
D6
Q26
Q27
Q28
Q29
D4SX
K1K2
K3K4
FBAK
ENTR
CNTR
EXIT
TAR
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1
2
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4
0
4
8
12
c
m o
r cm
/%
x (cm)
y (cm)
dy/dp (cm/%)
dx/dp (cm/%)
10 20 30 40 50 60 70 80 90 100 meters
The E821 w/4X FODO beam line (1 % dp/p), 3.15 GeV/c pion beamFIRST ORDER CALCULATION and target 0 cm d/s
1. 0.2616 15.0 0.1880 80.0 8.776 1.0 3.1513 /pion/ ;
P1 P2
Q1Q2D1
D2Q3
Q5
D3
D4D4Q7Q8
Q9a
Q10
Q11
P1Q12
Q13
Q14
Q15
Q16
Q17
Q18
Q19
P2Q20
D5Q21
Q22
Q23a
Q24
Q25
D6
Q26
Q27
Q28
Q29
D4SX
Q9SX
K1K2
W409
MTCH
W430
W450
W470
SWP
W608
K3K4
W646
W678
W712
FBAK
HOLE
CNTR
TAR
16
1
2
8
4
0
4
8
12
c
m o
r cm
/%
x (cm)
y (cm)
dy/dp (cm/%)
dx/dp (cm/%)
10 20 30 40 50 60 70 80 90 100 meters
The E821 beam line (1 % dp/p), 3.15 GeV/c pion beam SECOND ORDER CALCULATION and target 0 cm d/s
1. 0.2616 17.0 0.1880 60.0 8.776 1.0 3.1523 /pion/ ;
P1P2
Q1Q2D1
D2Q3
Q5
D3
D4D4Q7
Q8
P1Q9Q10
Q10a
Q10b
Q11
Q11a
Q11b
Q11c
Q12
Q12a
Q12b
Q12c
Q13
Q13a
Q13b
Q13c
Q14
Q14a
Q14b
Q14c
Q15
Q15a
Q15b
Q15c
Q16
Q16a
Q16b
Q16c
Q17
Q17a
Q17b
Q17c
Q18
Q18a
Q18b
Q18c
Q19
Q19b
P2
D5Q21
Q22
Q23a
Q24
Q25
D6
Q26
Q27
Q28
Q29
D4SX
K1K2
K3K4
FBAK
ENTR
CNTR
EXIT
TAR
16
1
2
8
4
0
4
8
12
c
m o
r cm
/%
x (cm)
y (cm)
dy/dp (cm/%)
dx/dp (cm/%)
10 20 30 40 50 60 70 80 90 100 meters
The E821 w/4X FODO beam line (1 % dp/p), 3.15 GeV/c pion beamSECOND ORDER CALCULATION and target 0 cm d/s
1. 0.2616 15.0 0.1880 80.0 8.776 1.0 3.1513 /pion/ ;
Q1Q2D1
D2Q3
Q5
D3
D4D4Q7Q8
Q9a
Q10
Q11
P1Q12
Q13
Q14
Q15
Q16
Q17
Q18
Q19
P2Q20
D5Q21
Q22
Q23a
Q24
Q25
D6
Q26
Q27
Q28
Q29
D4SX
Q9SX
K1K2
W409
MTCH
W430
W450
W470
SWP
W608
K3K4
W646
W678
W712
FBAK
HOLE
CNTR
TAR
16
1
2
8
4
0
4
8
12
c
m o
r cm
/%
x (cm)
y (cm)
dy/dp (cm/%)
dx/dp (cm/%)
10 20 30 40 50 60 70 80 90 100 meters
The E821 beam line (1 % dp/p), 3.15 GeV/c pion beamFIRST ORDER CALCULATION and target 9 cm d/s
1. 0.2616 17.0 0.1880 60.0 8.776 1.0 3.1523 /pion/ ;
Q1Q2D1
D2Q3
Q5
D3
D4D4Q7
Q8
P1Q9Q10
Q10a
Q10b
Q11
Q11a
Q11b
Q11c
Q12
Q12a
Q12b
Q12c
Q13
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Q13b
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Q14
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Q14b
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Q15
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Q15b
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Q17
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Q18
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Q19
Q19b
P2
D5Q21
Q22
Q23a
Q24
Q25
D6
Q26
Q27
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Q29
D4SX
K1K2
K3K4
FBAK
ENTR
CNTR
EXIT
TAR
16
1
2
8
4
0
4
8
12
c
m o
r cm
/%
x (cm)
y (cm)
dy/dp (cm/%)
dx/dp (cm/%)
10 20 30 40 50 60 70 80 90 100 meters
The E821 w/4X FODO beam line (1 % dp/p), 3.15 GeV/c pion beamFIRST ORDER CALCULATION and target 9 cm d/s
1. 0.2616 15.0 0.1880 80.0 8.776 1.0 3.1513 /pion/ ;
Q1Q2D1
D2Q3
Q5
D3
D4D4Q7Q8
Q9a
Q10
Q11
P1Q12
Q13
Q14
Q15
Q16
Q17
Q18
Q19
P2Q20
D5Q21
Q22
Q23a
Q24
Q25
D6
Q26
Q27
Q28
Q29
D4SX
Q9SX
K1K2
W409
MTCH
W430
W450
W470
SWP
W608
K3K4
W646
W678
W712
FBAK
HOLE
CNTR
TAR
16
1
2
8
4
0
4
8
12
c
m o
r cm
/%
x (cm)
y (cm)
dy/dp (cm/%)
dx/dp (cm/%)
10 20 30 40 50 60 70 80 90 100 meters
The E821 beam line (1 % dp/p), 3.15 GeV/c pion beamSECOND ORDER CALCULATION and target 9 cm d/s
1. 0.2616 17.0 0.1880 60.0 8.776 1.0 3.1523 /pion/ ;
Q1Q2D1
D2Q3
Q5
D3
D4D4Q7
Q8
P1Q9Q10
Q10a
Q10b
Q11
Q11a
Q11b
Q11c
Q12
Q12a
Q12b
Q12c
Q13
Q13a
Q13b
Q13c
Q14
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Q14b
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Q15
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Q16
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Q16b
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Q17
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Q17b
Q17c
Q18
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Q18b
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Q19
Q19b
P2
D5Q21
Q22
Q23a
Q24
Q25
D6
Q26
Q27
Q28
Q29
D4SX
K1K2
K3K4
FBAK
ENTR
CNTR
EXIT
TAR
16
1
2
8
4
0
4
8
12
c
m o
r cm
/%
x (cm)
y (cm)
dy/dp (cm/%)
dx/dp (cm/%)
10 20 30 40 50 60 70 80 90 100 meters
The E821 w/4X FODO beam line (1 % dp/p), 3.15 GeV/c pion beamSECOND ORDER CALCULATION and target 9 cm d/s
1. 0.2616 15.0 0.1880 80.0 8.776 1.0 3.1513 /pion/ ;
Q1Q2D1
D2Q3
Q5
D3
D4D4Q7Q8
Q9a
Q10
Q11
P1Q12
Q13
Q14
Q15
Q16
Q17
Q18
Q19
P2Q20
D5Q21
Q22
Q23a
Q24
Q25
D6
Q26
Q27
Q28
Q29
D4SX
Q9SX
K1K2
W409
MTCH
W430
W450
W470
SWP
W608
K3K4
W646
W678
W712
FBAK
HOLE
CNTR
TAR
16
1
2
8
4
0
4
8
12
c
m o
r cm
/%
x (cm)
y (cm)
dy/dp (cm/%)
dx/dp (cm/%)
10 20 30 40 50 60 70 80 90 100 meters
The E821 beam line (1 % dp/p), 3.15 GeV/c pion beamSECOND ORDER CALCULATION and target 9 cm u/s
1. 0.2616 17.0 0.1880 60.0 8.776 1.0 3.1523 /pion/ ;
Q1Q2D1
D2Q3
Q5
D3
D4D4Q7
Q8
P1Q9Q10
Q10a
Q10b
Q11
Q11a
Q11b
Q11c
Q12
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Q12b
Q12c
Q13
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Q13b
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Q14
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Q15
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Q16
Q16a
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Q17
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Q19
Q19b
P2
D5Q21
Q22
Q23a
Q24
Q25
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Q26
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Q29
D4SX
K1K2
K3K4
FBAK
ENTR
CNTR
EXIT
TAR
16
1
2
8
4
0
4
8
12
c
m o
r cm
/%
x (cm)
y (cm)
dy/dp (cm/%)
dx/dp (cm/%)
10 20 30 40 50 60 70 80 90 100 meters
The E821 w/4X FODO beam line (1 % dp/p), 3.15 GeV/c pion beamSECOND ORDER CALCULATION and target 9 cm u/s
1. 0.2616 15.0 0.1880 80.0 8.776 1.0 3.1513 /pion/ ;
E821 1X FODO beam line tgt position study
0.00
0.20
0.40
0.60
0.80
1.00
1.20
-10 -5 0 5 10
Z tgt (cm)
pi/
mu
to
P2
pi to P2
1X mu to P2
The target length issue
E696 4X FODO beam line tgt position study
0.00
0.20
0.40
0.60
0.80
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1.20
-10 -5 0 5 10
Z tgt (cm)
pi/
mu
to
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pi to P2
mu to p2
4X/1X FODO beam line tgt position studypolarization and admittance accounted for
0.00
0.50
1.00
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2.00
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-10 -5 0 5 10
Z tgt (cm)
Rat
io 4
X m
u's
/1X
mu
's s
tore
d
4X/1X N*Pol**2
Linear (4X/1X N*Pol**2)
Muon momentum (GeV/c)
Muon
Polarization
Pion Flash and polarization issues – study with 3.15 GeV/c ± 90% pion momentum
4X FODO to u/s of P2(end of decay channel) Primodial muons
3.094 GeV/c ± 0.25%
1x vs 4X FODO Fwd Decay Beampion dp/p = 3.15 +/- 90%
0
500
1000
1500
2000
2500
2.6 2.7 2.8 2.9 3 3.1 3.2 3.3
Muon Momentum (GeV/c)
Co
un
ts p
er
0.0
1 G
eV
/c
3.094 GeV/c ± 0.25%
The Pion Flash Issue
4X
1X
Note rapid loss vs gradual loss of muons
4X/1X FODO Ratio Fwd Decay Beampion dp/p = 3.15 +/- 90%
0.00
1.00
2.00
3.00
4.00
5.00
6.00
7.00
8.00
2.7 2.8 2.9 3 3.1 3.2
Muon Momentum (GeV/c)
4X
/1X
Ra
tio
3.094 GeV/c ± 0.25%
The Pion Flash Issue
The pion flash issue together with polarization loss and admittance issues
4X FODO beam line muon momentum study, polarization and acceptance loss -- xx',yy' is % accepted into storage ring
0.0%
20.0%
40.0%
60.0%
80.0%
100.0%
120.0%
-7.00% -6.00% -5.00% -4.00% -3.00% -2.00% -1.00% 0.00%
muon pion momentum difference
Pol (%)
XX' %
YY' %
Linear (XX' %)
Linear (YY' %)
Linear (Pol (%))
3.094 GeV/c ± 0.25%
The pion flash issue together with polarization loss and admittance issues
E696 4X FODO beam line muon momentum study
0.00
0.20
0.40
0.60
0.80
1.00
1.20
1.40
1.60
-7.00% -6.00% -5.00% -4.00% -3.00% -2.00% -1.00% 0.00%
muon pion momentum difference
mu
to
P2 4X N*Pol**2
4X mu to p2
# Stored
Linear (4X mu to p2)
Poly. (# Stored)
Poly. (4X N*Pol**2)
E821 muon momentum range
Takes into account admittance
Takes into account admittanceand polarization
Comparing Present (1X) to Proposed (4X) Beam Lineincludes muon admittance and p2 factor for polarization
Bottom Line - EXPECTED IMPROVEMENT
4X/1X FODO Fwd Decay beam line muon momentum study(1x baseline at -1.8% muon momentum)
0.00
0.50
1.00
1.50
2.00
2.50
3.00
3.50
4.00
-7.00% -6.00% -5.00% -4.00% -3.00% -2.00% -1.00% 0.00%
muon pion momentum difference
Rat
io 4
X m
u's
/1X
mu
's s
tore
d
4X/1X N*Pol**2
Poly. (4X/1X N*Pol**2)
E821 muon momentum range
Better rejection more stored
Summary of Beam Line Changes
V Primary Transport• New VQ12 – to reduce primary beam losses
V1 pion production target• Unchanged
V1 / Beam Line• Reposition V1P1 upstream (more ’s collected)• Add 30 New 4Q24 magnets in decay channel• Add earth shielding over V1 transport tunnel• Improve shielding between beam line and storage ring• New Inflector (open end)
H
H10
H
G
H11
21
F
21
H12
101 -104
H13
E
U P
22
H14
D
116.685"
FLAG
UF1
4x6.75D2 4-1139.609"
UTV1
169.609"
UTH2
4x6.75D2 4-5195.495"
BPM
TRA
VE
L LIMIT
TRA
VE
L LIMIT
UBH/V1
H15
40 TON
CR
AN
E
40 TON
CR
AN
E
230.435"
UQ1
N3Q36-9
U P
DR 16DR 16
20
N3Q36-8
UQ2
287.436"
C
23
H16
V
399.079"
RO
OM
RO
OM
ME
N`S
ME
N`S
(REF : rd57080013a1.dwg)
H 17
B
C1
133.737"
24
88 .33"4Q26.5-9
H 18
BPM
UBH/V2
126.785"
U P
A
H 19
19
U P
C
B
11-B
H 20
10-D
(REF : rd57010175a1.dwg)
CAD0110
1534
H I
6-8-01
7-7-98
I1
E N G . A P P .E C N N O .Z O N ER E V . B YD A TE C K R S U P V . A P P .
21
R. BO W M AN
UN
ITU
NIT
R. BO W M AN
A/C
A/C
A/C
A/C
C. PEARSO N
I2
C. PEARSO N
732.081"
I3
UBV3
18
779.851"
A. PENDZICK
VBPM
U G E 1
(REF : rd57010118c1.dwg)
BEAM DI RECTIO N
907.567"
I4
965.957"UBH4
HBPM
I5
20
M.E
. BU
ILDIN
G
M.E
. BU
ILDIN
G
I6
(REF : rd57010249b1.dwg)
17
I7
( FEB G ATE 2 )
UG I1
1438.078"
FLAG
UF2
I8
1497.933"
19
COLL.
UC1
I9
4x6.75D2 4-11(REF : rd57080001a1.dwg)
1675.553"
I10
UTH3
1705.553"
4x6.75D2 4-4
UTV4
SU
B S
TAT IO
N "F" &
"P"
1760.561"
U P
I
16
I11
1898.721"
VD3
I12
12C100-2
18
-1 .5053°3."GAP
(REF : rd57010230c1.dwg)
I13
2P41-1
VD412C100-1
121-124
SN AKE
P.S .605
SN AKE
800A
-1.5053°3."GAP
I14
2P42-1
VF232
U P
FLAG
A-T
RA
ILER
SN AKE
FM7 8
P.S .606
SN AKE
125-128
800A
I15
15
1F44-1
30-5VQ 9
P.S .919
VD 1-2
129-132
10-41
HO
US
E
A-P
OW
ER
SU
PP
LY
VP290
2476.840"
EL.BO X
UN
IT
xxx
17
I16
xxx
AIR
CO
ND
IT ION
ING
P.S
. 6 0 0-31
UQ
8P.S
. 6 0 0-30
10-42
UQ
11
VD 314
UQ
7
P.S
. 2 5 -5
P.S
. 2 5 -8U
Q13
P.S
. 2 5 -4U
Q6
P.S
. 2 5 -9
UQ
4
P.S
. 2 5 -3
P.S .156
P.S
. 2 5 -2
VQ 10-11
2P44-1
UQ
5P .S . S 5 0 -1 0
UTH
3
UQ
9
UTV
4
P .S . S5 0 -1 1
P.S
. 1 6 -1 0
U Q1 2
P.S
. 2 5 -6
133-136
UQ
10
P.S
. 1 2 -1
I17
P.S
. 2 5 -7
A-1
UD
3,4 ,5 ,6P
.S. 5 0 5
P.S .502
VQ 12
VW 264
2668.506"
EPM
UTV
7
VB266
BPM
P.S
. 1 6 -3
A-13
2F41-1
UTH
6P
.S. 1 6 -4
UTV
5
P.S .467
V1Q 1
P.S
. 1 6 -7
I18
VQ9
4Q26.5-6
(REF : rd57080011b1.dwg)
137-140
BUILD ING
EL.BO X
EQU IPTMENT
(REF : 5b010001a1.dwg)
168.022"
V1Q 2
P.S .I225 -1
2F42-1
I19
V1D 4
P.S .923
141-144
14
P.S .920
V1D 1
I20
4x6D24-4
VP290
V1D 3
P.S .901
16
P.S .902
V1D 2
VQ10
192.022"
5Q36-02
5Q36-07
VQ11
1F44-2
IJ
V1Q 3,6
P .S .62-1 ,2
V1Q 4,5
145-148
VB302
(REF : 57080012b1.dwg)
J1
168.021"
P.S .251
V1Q 7
2F42-2
V1Q 8
N3Q36-21
VQ12
J2
149-152
VD3144x6D24-2
(SH IELD ING REF: neg CN 4-311 -94)
EL.BO X
VTG E1
VX315CUR.X .FO RM .
UC2
J3
153.072"
VE324
TGT.SWICVW325
SEC
VF326
2P41-2
FLAG
UQ10
VTG
E2
BLD G 921
153-156
13
J4
290.993"
"V" TARGET
V1Q1N8Q48-2
15
4D24-9
UTV5
BU
OY
AN
CH
OR
S 3 H
IGH
N8Q32-15
V1Q2
V1P1
SU MP
P.S .N 50-6
RE F . D W G D 14 -1619-C6
J5
2P44-2
P .S .5-2V1Q 9
P.S .5-1
M 73 7
V 1D 1
V1Q 1
157-160
-16 .13 19°
3 .5 "G A P
(REF : 57083001 .dwg )
P.S .16-5
(SH IELD ING REF: neg CN 4-313 -94)
V1Q 11,13 ,15
P .S . R AC KS
V1D 214C 72-2
SEC U R ITY C ABIN ETS
J6
2P42-2
P .S . 16-8
-14.8608 °
P .S . 2.4 -1
V1Q 12,14 ,16,18
3"G AP
P.S . 2.4 -2P .S . 2.4 -3P .S . 2.4 -4P .S . 2.4 -5
161-164
V1Q 3
V1P399VD 411
4Q 16-21
V IP424V1D 452VIP464
V1Q 4
J7
4Q 16-23
V1C 1
SEC U R ITY C ABIN ETS
V1Q 5
673.633"
4Q 16-22
V1Q 6
UB6
4Q 16-24
V 1D 3
E L E C TR O N IC S
UC3
R O O M
749.969"
J8
-14 .86 09°
M 73 4
SLAC730-10
A .B .R AC K S
UQ11
3 .5 " G A P
SUMP
V 1D 4
804.570"
12
14
4D24-7
-16 .13 19°
UTH6
J9
M 73 83 .5 "G A P
V1Q7
M 116
V1Q8
(REF : 57010122b1.dwg)
J10
M 121
V1P399
4D16-1
J
V1Q9
J11
4Q24-4
4Q24-22V1Q10 V1W 409
SW IC
TAR GET AREA
ION
PU M P R OO M
(SH
IELD
ING
RE
F:D
14-1
594
-C-6
)
V1D411
J12
4D16-2
CO
ND
UIT
U P
J13
V1P424
4D16-3
V1Q11
4Q24-5
SH IELDING REF: D14-1613-C -5
V1W 430
SW IC
13
V1D440
11
g -2 BE AM L IN E / BU ILD ING 949
4D16-4
V1P1
5D32-1
V1Q12
4Q24-6
V1G E1
V1W 450
SW IC V1D452
4D16-4
FAN
V1P464
4D16-5
V1W 470
V1Q13
4Q24-7
SW IC
ION
V1D484
SW EEPER
V1Q14
4Q24-8
12
10
V1Q15
4Q24-9
UP
V1Q16
4Q24-10
V1P546
UP
4D16-6
V1Q17
4Q24-11
FAN
11
V1D566
4 D1 6 -7
V1Q18
9
4Q24-12
V1P587
4D16-8
V1Q19
4Q24-13
V1P2
5D32-2
V1W 608V1Q20
SW IC
V1D5
4Q24-14
3.5"G AP
M 712
10
U P
21.0479°
V1Q 21
4Q 24-15
V 1 G E 2
8
V1Q 22
4Q 24-16
V1C 2 V1Q 23
4Q 24-17
F A N
V1W 646
H 1 A N D H 2 S U B S TA TIO N
V1P648
SW ICIO N
4D 16-9
V1Q 24
4Q 24-16
9
V1Q 25
(S H IE LD IN G R E F : D 1 4 -1 61 8 -C -5 )
4Q 24-19
P S 18 -4V 1 IN F L E C T O R
V1D 6
M 707
V 1Q 2 0P S 10 -3 9
3.5"G AP
UP
7
V 1Q 2 8P S 2 2 5- 2I
V 1D 6 TP S 10 -4 0
21.0479°
P S 10 -5
V 1Q 2 9P S 2 2 5- 3I
V 1Q 2 1, Q 2 5
G A S S H E D
P S 25 -1 A
V 1P 2
V1W 678
P S N 5 0 -7
P S 10 -4 4
SW IC
V 1Q 2 6
V 1Q 2 3
P S 5- 3V 1Q 2 7
P S 42 7V 1D 5 , D 6
P S 16 -1 2V 1Q 2 2, Q 2 4
V 1 G E 3
4Q 24-20
V1Q 26
P S 2. 4 -1 0
P S 2. 4 -6V 1P 4 5 46
P S 2. 4 -1 1
P S 2. 4 -8V 1P 5 8 7
V 1D 6 84
P S 2. 4 -1 2
V 1D 6 84
V 1D 7 10
R E C T IF IE RR O O M
P S 2. 4 -7V 1D 5 66
PS R
ACK S
P S 2. 4 -9V 1P 6 4 8
A /BR A C K S
V1Q 27
4Q 24-21
C O N F. R O O M
V1P694
4D 16-11
E L E C TR O N IC S A R E A
CR AN E L IM IT
V1Q 28
8
10
M 113
C O N TR O L R O O M
11
H V A C S Y S T E M
V1Q 29
M 122
9
V1D 710
4D 16-12
12
16
17
15
V1W 712
/IO NSW IC
18
14
TURBOPUMP
CR AN E L IM IT
TURBOPUMP
13
19
CRYO
6
PUMP
M G E 1
20
12
L U N C H R O O M
8
1
G RID R OTAT ION P IV OT PO INT
21
N 19 40 0.0 00 00 0 00
11
E -500 0 .0 00 0 00 00
CONTROLSKICKER
POW ER SUP PLYPULSAR
"
BOTTOM ELEC TR OD ES
SCRAPING +"B
"
"C /D "
U P
CONTROLSKICKER
ELEC TR OD ESTOP
STANDARD +"A
AND LEDLASER
SIDEELEC TR OD ES
STANDARD -
RACK
ELEC TR OD ESS IDE
"C /D "SCRAPING -
10
22
9
23
7
2
QUENCH
8
ELECT
24
CRYOPUMP
TURBOPUMP
UP
QU
EN
CH
7
1
PR
OT
EC
T
M P .S .
UP
6
2
A N DM O T O R C O N TR O L C E N TE R
5
3
S H O P A R E A
4
6
3
7
M E D 1 ,2
5
4
TURBOPUMP
TURBOPUMP
FLOOR EL 64'-2"
D UM PR ESIST OR
CR AN E L IM IT
U PSPS
H E A TE XC H AN G E R
5
PU
MP
RO
OM
L ND E W A R
2
M E D 3
P U M PA R E A
C O M P R E S S O R R O O M
L HD E W A R
e
P LA N "A " R E FR IG E R A TO R
6
C O O L IN GT O W E R
R AM P( DO W N )
C R Y O G E N ICC O N TR O L R M .
C O L DB O X
2L N D E W A R
CO
MP
RE
SS
OR
H E LIU MA R E A
4
P LA N "B " R EF RIG E RA TO R
C O M P .
B L D G 9 1 9-C
L NH E A T
E X C H A N G E R
2
UP
CO
MP
RE
SS
OR
H 3 S U B S T A T IO N
PAN EL
5
H e T A N K
3
4
R H ICC O M P R E S S O R R M
O V E RH E AD T R AY 20 ' C LEA R AN CE
2
3
E X P /O RB E A M LIN E
A P P R O V A LE N G IN E E R
A P P R O V A LS U P V R .
B Y
A P P R O V A LDIV HE A D
B Y
R A D S A F E TYA P P R O V A L
P H YS IC IS TA P P R O V A L
CHE CK E D
DRA W N
DA TEQ.A. CATEGORY A-1
R. BOW MAN 3/20/97
D. PH ILLIPS 4/30/97
D . PH ILLIPS 4/30/97
W . M EN G 5/5/97
R . K . R E E C E 5/21/97
A . PENDZICK 4/30/97
P . P ILE 6/3/97
1
E X P /O RB E A M LIN E
A P P R O V A LE N G IN E E R
A P P R O V A LS U P V R .
B Y
A P P R O V A LDIV HE A D
B Y
R A D S A F E TYA P P R O V A L
P H YS IC IS TA P P R O V A L
CHE CK E D
DRA W N
DA TEQ.A. CATEGORY A-1
R. BOW MAN 3/20/97
D. PH ILLIPS 4/30/97
D . PH ILLIPS 4/30/97
W . M EN G 5/5/97
R . K . R E E C E 5/21/97
A . PENDZICK 4/30/97
P . P ILE 6/3/97
2
H
G
F
BROOKHAVEN NATIONAL LABORATORY
UPTON, N.Y. 11973A S S OCIA TE D UNIV E RS ITIE S , INC.
AG SB E A M LIN EE X P /O R
DRA W N
CHE CK E D
A P P R O V A LP H YS IC IS T
A P P R O V A LR A D S A F E TY
B Y
DIV HE A DA P P R O V A L
B Y
S U P V R .A P P R O V A L
E N G IN E E RA P P R O V A L
S CA LE :
DRA W ING NUM B E R
S HE E T
-6RE V .
-6
U S E D O N D W G . N O .
AG S N O R TH EXP. AR EA H -10
F.E .B .TR AN SPO R T, g-2 BM , EXP. #821
G EN ER AL LAYO U TD 14-1598-AD 14-1598-A
DA TE
C
EXP. #821EXP. #821
Q.A. CATEGORY A-1
M ARASCIA / BOW M AN 11/8/94
J. SCADUTO 5/1/97
J. SCADUTO 5/1/97
G . BUNCE 5/2/97
R . K . R E E C E 5/21/97
A . PENDZICK 4/30/97
P . P ILE 6/3/97 1/8"=1 '-0" 1 OF 1
E
D
C
1
B
*AU T O C AD
A
VQ12 replaced with 4” dia quad
g-2 / beam line front end
H
H 10
H
G
H 11
21
F
21
H 12
10 1-104
H 13
E
U P
22
H 14
D
116.685"
FLAG
U F1
4 x6 .75 D 24 -1139.609"
U TV1
169.609"
U TH 2
4 x6 .75 D 24 -5195.495"
BPM
TRA
VE
L L IMIT
TRA
VE
L L IMIT
U BH/V1
H 15
40 TO
N C
RA
NE
40 TO
N C
RA
NE
230.435"
U Q1
N 3Q 3 6-9
U P
DR 16DR 16
20
N 3Q 3 6-8
U Q2
287.436"
C
23
H 16
V
399.079"
RO
OM
RO
OM
ME
N`S
ME
N`S
(R EF : rd57080013a1 .dw g)
H 17
B
C1
133.737"
24
88.33"4 Q26.5 -9
H 18
BPM
UBH/V2
126.785"
U P
A
H 19
19
U P
C
B
11-B
H 20
10-D
(R EF : rd57010175a1 .dw g)
C AD 0110
1534
HI
6-8-01
7-7 -98
I1
ENG. APP.ECN NO.ZONEREV. BYDATE CKR SUPV. APP.
21
R . B O W M A N
UN
ITU
NIT
R . B O W M A N
A/C
A/C
A/C
A/C
C . P E A R S O N
I2
C . P E A R S O N
732.081"
I3
UBV3
18
779.851"
A . P E N D Z IC K
VBPM
UG E1
(R EF : rd57010118c1 .dw g)
BEAM DI RECT IO
N
907.567"
I4
965.957"UBH4
HBPM
I5
20
M.E
. BU
ILDIN
G
M.E
. BU
ILDIN
G
I6
(R EF : rd57010249b1 .dw g)
17
I7
( FEB GATE 2 )
UG I1
1438.078"
FLAG
UF2
I8
1497.933"
19
C OL L .
U C 1
I9
4 x6 .75D 24 -1 1(R EF : rd57080001a1 .dw g)
1675.553"
I10
U TH 3
1705.553"
4 x6 .75D 24 -4
U TV4
SU
B S
TATIO
N "F
" & "P
"
1760.561"
U P
I
16
I11
1898.721"
VD 3
I12
1 2C 100 -2
18
-1.50 5 3°3 ."G AP
(R EF : rd57010230c1 .dw g)
I13
2 P 41 -1
VD 41 2C 1 00 -1
1 21 -1 24
S N A K E
P .S .60 5
S N A K E
8 00 A
-1.50 5 3°3 ."G AP
I14
2 P 42 -1
VF2 3 2
U P
FL AG
A-TR
AILER
S N A K E
FM78
P .S .60 6
S N A K E
1 25 -1 28
8 00 A
I15
15
1 F44 -1
3 0-5V Q 9
P .S .91 9
V D 1-2
1 29 -1 32
1 0-41
HO
US
E
A-PO
WER
SU
PPLY
V P 2 90
2476.840"
E L .B O X
UN
IT
xxx
17
I16
xxx
AIR
CO
ND
ITION
ING
P.S
. 600-31
UQ
8P.S
. 600-30
1 0-42
UQ
11
V D 31 4
UQ
7
P.S
. 25-5
P.S
. 25-8U
Q13
P.S
. 25-4U
Q6
P.S
. 25-9
UQ
4
P.S
. 25-3
P .S .15 6
P.S
. 25-2
V Q 10 -1 1
2 P 44 -1
UQ
5P.S. S50-10
UT
H3
UQ
9
UT
V4
P .S. S50 -11
P.S
. 16-10
UQ12
P.S
. 25-6
1 33 -1 36
UQ
10
P.S
. 12-1
I17
P.S
. 25-7
A-1
UD
3,4,5
,6P
.S. 505
P .S .50 2
V Q 12
VW 26 4
2668.506"
EPM
UT
V7
VB2 66
BPM
P.S
. 16-3
A-1
3
2 F41 -1
UT
H6
P.S
. 16-4U
TV
5
P .S .46 7
V 1 Q1
P.S
. 16-7
I18
VQ 9
4 Q2 6.5 -6
(R EF : rd57080011b1 .dw g)
1 37 -1 40
BU ILD ING
E L .B O X
EQ U IP TM EN T
(R EF : 5b010001a1 .dwg )
168.022"
V 1 Q2
P .S .I2 2 5-1
2 F42 -1
I19
V 1 D4
P .S .92 3
1 41 -1 44
14
P .S .92 0
V 1 D1
I20
4 x6 D 24 -4
VP2 90
V 1 D3
P .S .90 1
16
P .S .90 2
V 1 D2
VQ 10
192.022"
5 Q3 6-02
5 Q3 6-07
VQ 11
1 F44 -2
IJ
V 1 Q3 ,6
P .S .62 -1 ,2
V 1 Q4 ,5
1 45 -1 48
VB3 02
(R EF : 57080012b1 .dwg)
J1
168.021"
P .S .25 1
V 1 Q7
2 F42 -2
V 1 Q8
N 3Q 3 6-21
VQ 12
J2
1 49 -1 52
VD 31 44 x6 D 24 -2
(S HIELDING REF : neg C N 4 -311 -94 )
E L .B O X
VTGE1
VX3 15C U R.X .FO R M .
U C 2
J3
153.072"
V E32 4
T G T .SW ICV W 3 25
S EC
V F 326
2 P 41 -2
F LA G
U Q10
VTG
E2
B LD G 921
1 53 -1 56
13
J4
290.993"
"V " TA R G ET
V1 Q1N 8Q 4 8-2
15
4D24 -9
U TV5
BU
OY
AN
CH
OR
S 3 H
IGH
N 8Q 3 2-15
V1 Q2
V 1 P 1
SUMP
P .S .N5 0 -6
REF. DW G D14-1619-C6
J5
2 P 44 -2
P .S .5-2V 1 Q9
P .S .5-1
M737
V1D1
V 1 Q1
1 57 -1 60
-16.1319°
3.5"GAP
(R EF : 57083001 .dw g)
P .S .16 -5
(S HIELDING REF : neg C N 4 -313 -94 )
V 1 Q1 1,1 3,1 5
P .S . R A C K S
V 1 D21 4C 7 2-2
S E C U R IT Y C A B IN E TS
J6
2 P 42 -2
P .S . 1 6 -8
-14 .8 6 08 °
P .S . 2 .4-1
V 1 Q1 2,1 4,1 6,18
3 "G A P
P .S . 2 .4-2P .S . 2 .4-3P .S . 2 .4-4P .S . 2 .4-5
1 61 -1 64
V 1 Q3
V 1 P 39 9V D 41 1
4 Q1 6-21
V IP 42 4V 1 D4 5 2V IP 46 4
V 1 Q4
J7
4 Q1 6-23
V 1 C1
S E C U R IT Y C A B IN E TS
V 1 Q5
673.633"
4 Q1 6-22
V 1 Q6
U B6
4 Q1 6-24
V1D3
ELECTRO NICS
U C 3
RO OM
749.969"
J8
-14.8609°
M734
SLAC 73 0-10
A .B .RA CK S
U Q11
3.5"GAP
SUMP
V1D4
804.570"
12
14
4D2 4 -7
-16.1319°
UTH 6
J9
M7383.5"GAP
V1 Q7
M 1 16
V1 Q8
(R EF : 57010122b1 .dwg )
J1 0
M 1 21
V1 P39 9
4 D1 6 -1
J
V1 Q9
J1 1
4 Q2 4-4
4 Q2 4-22V1 Q1 0 V1 W4 0 9
SW IC
TARGET AREA
ION
PUMP ROOM
(SH
IELD
ING
RE
F:D
14-1
594
-C-6
)
V1 D4 1 1
J1 2
4 D1 6 -2
CO
ND
UIT
U P
J1 3
V1 P42 4
4 D1 6 -3
V1 Q1 1
4 Q2 4-5
S H IE LD IN G R EF : D14-16 13-C -5
V1 W4 3 0
SW IC
13
V1 D4 4 0
11
g-2 BEAM LINE / BUILDING 949
4 D1 6 -4
V1 P1
5 D3 2 -1
V1 Q1 2
4 Q2 4-6
V1GE1
V1 W4 5 0
SW IC V1 D4 5 2
4 D1 6 -4
FAN
V1 P46 4
4 D1 6 -5
V1 W4 7 0
V1 Q1 3
4 Q2 4-7
SW IC
ION
V1 D4 8 4
SW EEPER
V1 Q1 4
4 Q2 4-8
12
10
V1 Q1 5
4 Q2 4-9
U P
V1 Q1 6
4 Q2 4-10
V1 P54 6
U P
4 D1 6 -6
V1 Q1 7
4 Q2 4-11
FAN
11
V1 D5 6 6
4D 16-7
V1 Q1 8
9
4 Q2 4-12
V1 P58 7
4 D1 6 -8
V1 Q1 9
4 Q2 4-13
V1 P2
5 D3 2 -2
V1 W6 0 8V1 Q2 0
SW IC
V 1 D5
4 Q2 4-14
3 .5 "GA P
M 7 12
10
U P
2 1.04 7 9°
V 1 Q2 1
4 Q2 4-15
V1GE 2
8
V 1 Q2 2
4 Q2 4-16
V 1 C2 V 1 Q2 3
4 Q2 4-17
FA N
V 1 W 6 4 6
H1 AND H2 SUBSTATION
V 1 P 64 8
S W ICION
4 D1 6 -9
V 1 Q2 4
4 Q2 4-16
9
V 1 Q2 5
(SHIE LDING REF: D14-1618-C-5)
4 Q2 4-19
PS 1 8-4V1 INFL ECTOR
V 1 D6
M 7 07
V1Q20PS 1 0-39
3 .5 "GA P
UP
7
V1Q28PS 2 25-2I
V1D6TPS 1 0-40
2 1.04 7 9°
PS 1 0-5
V1Q29PS 2 25-3I
V1Q21, Q2 5
G AS SHED
PS 2 5-1A
V1P2
V 1 W 6 7 8
PS N5 0-7
PS 1 0-44
S W IC
V1Q26
V1Q23
PS 5 -3V1Q27
PS 4 27V1D5, D6
PS 1 6-12V1Q22, Q2 4
V1GE 3
4 Q2 4-20
V 1 Q2 6
PS 2 .4-10
PS 2 .4-6V1P4 546
PS 2 .4-11
PS 2 .4-8V1P5 87
V1D68 4
PS 2 .4-12
V1D68 4
V1D71 0
RECTIFIERRO OM
PS 2 .4-7V1D56 6
PS R
ACKS
PS 2 .4-9V1P6 48
A /BRACKS
V 1 Q2 7
4 Q2 4-21
CO NF. RO O M
V 1 P 69 4
4 D1 6 -1 1
ELECTRO NICS AREA
C R A N E LIM IT
V 1 Q2 8
8
10
M 1 13
CO NTROL ROO M
11
HVAC SYSTEM
V 1 Q2 9
M 1 22
9
V 1 D7 1 0
4 D1 6 -1 2
12
16
17
15
V 1 W 7 1 2
/IONS W IC
18
14
T UR BOPU MP
C R A N E LIM IT
T UR BOPU MP
13
19
C RYO
6
PU MP
MG E1
20
12
LUNCH RO OM
8
1
GRID R OTATION P IVOT POINT
21
N 19400.00000000
11
E -5000 .00000000
C ONT ROLSKICKER
P OWE R SUP PLYPU LSAR
"
BOT TOM E LE CTRODE S
SC RAPING +"B
"
"C /D "
UP
C ONT ROLSKICKER
E LE CTRODE ST OP
ST AND ARD +
"A
AN D LEDLASER
SIDEE LE CTRODE S
ST AND ARD -
R ACK
E LE CTRODE SSIDE
"C /D "SC RAPING -
10
22
9
23
7
2
QUENCH
8
ELECT
24
C RYOPU MP
T UR BOPU MP
UP
QU
EN
CH
7
1
PR
OT
EC
T
M P.S.
UP
6
2
ANDMO TOR CONTROL CENTER
5
3
SHO P AREA
4
6
3
7
ME D 1,2
5
4
T UR BOPU MP
T UR BOPU MP
F L O O R E L 64 '-2 "
D U M PR E SIS T O R
C R A N E LIM IT
U P SP S
HEATE XC HA NG E R
5
PU
MP
RO
OM
LNDEW AR
2
ME D3
PUMPAREA
CO MPRESSO R ROO M
LHDEW AR
e
P LAN "A " RE FRIGE RA TOR
6
CO OLINGTO W ER
R A M P( D O W N )
CRYO GENICCO NTROL RM.
CO LDB OX
2LN DEW AR
CO
MP
RE
SS
OR
HELIUMAREA
4
P LA N "B " R E F R IG E R A T O R
CO MP.
BLDG 919-C
LNHEAT
E XCHA NGE R
2
UP
CO
MP
RE
SS
OR
H3 SUBS TATIO N
P A N E L
5
H e TA NK
3
4
RHICCO MPRESSO R RM
O V E R H E A D T R A Y 20 ' C LE A R A N C E
2
3
EXP/O RBEAMLINE
A P P R O V A LE N G IN E E R
A P P R O V A LS U P V R .
BY
A P P R O V A LDIV HEAD
BY
RAD SAFETYA P P R O V A L
P H YS IC IS TA P P R O V A L
CHECKED
DRAW N
DATEQ.A. CATEGORY A-1
R. B O W M A N 3/20/97
D. PHILLIPS 4/30/97
D. PHILLIPS 4/30/97
W . M ENG 5/5/97
R . K . R EEC E 5/21/97
A. PENDZICK 4/30/97
P. PILE 6/3/97
1
EXP/O RBEAMLINE
A P P R O V A LE N G IN E E R
A P P R O V A LS U P V R .
BY
A P P R O V A LDIV HEAD
BY
RAD SAFETYA P P R O V A L
P H YS IC IS TA P P R O V A L
CHECKED
DRAW N
DATEQ.A. CATEGORY A-1
R. B O W M A N 3/20/97
D. PHILLIPS 4/30/97
D. PHILLIPS 4/30/97
W . M ENG 5/5/97
R . K . R EEC E 5/21/97
A. PENDZICK 4/30/97
P. PILE 6/3/97
2
H
G
F
BRO O KHAVEN NATIO NAL LABO RATO RY
UPTON, N.Y. 11973ASSOCIATED UNIVERSITIES, INC.
A G SBEAMLINEEXP/O R
DRAW N
CHECKED
A P P R O V A LP H YS IC IS T
A P P R O V A LRAD SAFETY
BY
DIV HEADA P P R O V A L
BY
S U P V R .A P P R O V A L
E N G IN E E RA P P R O V A L
SCALE:
DRAW ING NUMBER
SHEET
-6REV.
-6
USED ON DW G. NO.
AG S N O R TH EXP. AR EA H -10 F .E .B .TR AN SPO R T, g-2 BM , EXP. #821
G ENERAL LAYO UTD 14-1598-AD 14-1598-A
DATE
C
EXP. #821EXP. #821
Q.A. CATEGORY A-1
M ARASCIA / BO W M AN 11/8/94
J. SCADUTO 5/1 /97
J. SCADUTO 5/1 /97
G . BUNCE 5/2 /97
R . K . R EEC E 5/21/97
A. PENDZICK 4/30/97
P. PILE 6/3/97 1/8"=1 '-0 " 1 O F 1
E
D
C
1
B
*AUTO CAD
A
No Changes
H
H10
H
G
H11
21
F
21
H12
1 01 -1 04
H13
E
UP
22
H14
D
1 16 .68 5"
FLAG
UF1
4 x 6 .7 5D 24 -11 39 .60 9"
U TV 1
1 69 .60 9"
U TH 2
4x 6 .7 5D 24 -51 95 .49 5"
BPM
TR
AV
EL L IM
IT
TR
AV
EL L IM
IT
UBH /V1
H15
40 TO
N C
RA
NE
40 TO
N C
RA
NE
2 30 .43 5"
U Q 1
N 3Q 36 -9
UP
D R 1 6D R 1 6
20
N 3Q 36 -8
U Q 2
2 87 .43 6"
C
23
H16
V
3 99 .07 9"
RO
OM
RO
OM
ME
N`S
ME
N`S
(REF: rd57080013a1.dw g)
H17
B
C1
1 33 .73 7"
24
8 8.3 3"4Q 26 . 5 -9
H18
BPM
UBH /V2
1 26 .78 5"
UP
A
H19
19
UP
C
B
11-B
H20
10-D
(REF: rd57010175a1.dw g)
C AD 0110
1534
H I
6-8-01
7-7-98
I1
E NG. A P P .E CN NO.ZONERE V . B YDA TE CK R S UP V . A P P .
21
R. B OW M A N
UN
ITU
NIT
R. B OW M A N
A/C
A/C
A/C
A/C
C. P E A RS ON
I2
C. P E A RS ON
7 32 .08 1"
I3
UBV3
18
7 79 .85 1"
A . P E NDZICK
VBPM
U G E 1
(REF: rd57010118c1.dwg)
BEA
M DIR
ECTI O
N
9 07 .56 7"
I4
9 65 .95 7"UBH 4
HBPM
I5
20
M.E
. BU
ILDIN
G
M.E
. BU
ILDIN
G
I6
(REF: rd57010249b1.dw g)
17
I7
( F EB G ATE 2 )
UG I1
1 43 8.0 78 "
FLAG
UF2
I8
1 49 7.9 33 "
19
C O LL .
U C1
I9
4x 6 .75D 24 -1 1(REF: rd57080001a1.dw g)
1 67 5.5 53 "
I10
U TH 3
1 70 5.5 53 "
4x 6 .75D 24 -4
U TV 4
SU
B S
TAT IO
N "F" &
"P"
1 76 0.5 61 "
UP
I
16
I11
1 89 8.7 21 "
V D 3
I12
12C 100 -2
18
-1 . 5 053 °3 . "G A P
(REF: rd57010230c1.dwg)
I13
2 P 4 1 -1
V D 412C 100 -1
1 2 1 -1 2 4
S N A K E
P . S .6 0 5
S N A K E
8 0 0 A
-1 . 5053 °3 . "G A P
I14
2 P 4 2 -1
V F 232
UP
F LA G
A-T
RA
ILER
S N A K E
FM
78
P . S .6 0 6
S NA K E
1 2 5 -1 2 8
8 0 0 A
I15
15
1 F 4 4 -1
3 0 -5V Q 9
P . S .9 1 9
V D 1 -2
1 2 9 -1 3 2
1 0 -4 1
HO
US
E
A-P
OW
ER
SU
PP
LY
V P 2 9 0
2 47 6.8 40 "
E L . B O X
UN
IT
xx x
17
I16
xx x
AIR
CO
ND
ITION
ING
P.S
. 6 00 -3 1
UQ
8P.S
. 6 00 -3 0
1 0 -4 2
UQ
1 1
V D 3 1 4
UQ
7
P.S
. 2 5- 5
P.S
. 2 5- 8U
Q1 3
P.S
. 2 5- 4U
Q6
P.S
. 2 5- 9
UQ
4
P.S
. 2 5- 3
P . S .1 5 6
P.S
. 2 5- 2
V Q 1 0 -1 1
2 P 4 4 -1
UQ
5P .S . S50-10
UTH
3
UQ
9
UTV
4
P .S . S5 0 -1 1
P.S
. 1 6- 10
U Q 1 2
P.S
. 2 5- 6
1 3 3 -1 3 6
UQ
1 0
P.S
. 1 2- 1
I17
P.S
. 2 5- 7
A-1
UD
3 ,4,5 ,6P
.S. 5 05
P . S .5 0 2
V Q 1 2
V W 264
2 66 8.5 06 "
E P M
UTV
7
V B 266
B P M
P.S
. 1 6- 3
A-1 3
2 F 4 1 -1
UTH
6P
.S. 1 6- 4
UTV
5
P . S .4 6 7
V 1 Q 1
P.S
. 1 6- 7
I18
V Q 9
4Q 26 . 5 -6
(REF: rd57080011b1.dw g)
1 3 7 -1 4 0
BUILD ING
E L . B O X
EQUIPTM ENT
(REF: 5b010001a1.dwg )
1 68 .02 2"
V 1 Q 2
P . S .I 2 2 5 -1
2 F 4 2 -1
I19
V 1 D 4
P . S .9 2 3
1 4 1 -1 4 4
14
P . S .9 2 0
V 1 D 1
I20
4x 6D24 -4
V P 290
V 1 D 3
P . S .9 0 1
16
P . S .9 0 2
V 1 D 2
V Q 10
1 92 .02 2"
5Q 36 -02
5Q 36 -07
V Q 11
1 F 4 4 -2
IJ
V 1 Q 3 , 6
P . S .6 2 -1 , 2
V 1 Q 4 , 5
1 4 5 -1 4 8
V B 302
(REF: 57080012b1.dwg )
J1
1 68 .02 1"
P . S .2 5 1
V 1 Q 7
2 F 4 2 -2
V 1 Q 8
N 3Q 36 -21
V Q 12
J2
1 4 9 -1 5 2
V D 3144x 6D24 -2
(SHIELDING
REF: neg CN 4 -311-94)
E L . B O X
V T G E 1
V X 315C UR .X .FO R M .
U C2
J3
1 53 .07 2"
V E 324
T G T.S W ICV W 325
S E C
V F 326
2 P 4 1 -2
F LA G
U Q 10
VTG
E2
B LD G 921
1 5 3 -1 5 6
13
J4
2 90 .99 3"
"V" TAR GE T
V 1Q 1N 8Q 48 -2
15
4D 24 -9
U TV 5
BUO
Y ANC
HO
RS 3 H
IGH
N 8Q 32 -15
V 1Q 2
V 1 P 1
S U MP
P . S .N 5 0 -6
R E F. D W G D 1 4-16 1 9-C 6
J5
2 P 4 4 -2
P . S .5 -2V 1 Q 9
P . S .5 -1
M737
V1D1
V 1 Q 1
1 5 7 -1 6 0
-16.1319 °
3.5 "GAP
(REF: 57083001.dwg)
P . S .1 6 -5
(SHIELDING
REF: neg CN 4 -313-94)
V 1 Q 1 1 , 1 3 ,1 5
P . S . RA C K S
V 1 D 21 4 C 7 2 -2
S E C UR IT Y C A B I NE T S
J6
2 P 4 2 -2
P . S . 1 6 -8
-1 4 . 8 6 0 8 °
P . S . 2 .4 -1
V 1 Q 1 2 , 1 4 ,1 6 ,1 8
3 "G A P
P . S . 2 .4 -2P . S . 2 .4 -3P . S . 2 .4 -4P . S . 2 .4 -5
1 6 1 -1 6 4
V 1 Q 3
V 1 P 3 9 9V D 4 1 1
4 Q 1 6 -2 1
V I P 4 2 4V 1 D 4 5 2V I P 4 6 4
V 1 Q 4
J7
4 Q 1 6 -2 3
V 1 C 1
S E C UR IT Y C A B I NE T S
V 1 Q 5
6 73 .63 3"
4 Q 1 6 -2 2
V 1 Q 6
U B 6
4 Q 1 6 -2 4
V1D3
E L E C T R O N IC S
U C3
R O O M
7 49 .96 9"
J8
-14.8609 °
M7 34
S LAC 730 -10
A . B .R A CK S
U Q 11
3.5 "GAP
S U MP
V1D4
8 04 .57 0"
12
14
4D 24 -7
-16.1319 °
U TH 6
J9
M7383.5 "GAP
V 1 Q 7
M 116
V 1 Q 8
(REF: 57010122b1.dwg )
J10
M 121
V 1 P 399
4D 16 -1
J
V 1 Q 9
J11
4Q 24 -4
4Q 24 -22V 1 Q 10 V 1 W 409
S W IC
T A R G E T A R E A
IO N
P U M P R O O M
(SH
IEL
DIN
G R
EF
:D1
4-1
59
4-C
-6)
V 1 D 41 1
J12
4D 16 -2
CO
ND
UIT
UP
J13
V 1 P 424
4D 16 -3
V 1 Q 11
4Q 24 -5
S HIE LDING RE F: D14 -1613 -C-5
V 1 W 430
S W IC
13
V 1 D 44 0
11
g -2 B E A M LIN E / B U ILD IN G 9 49
4D 16 -4
V 1 P 1
5D 32 -1
V 1 Q 12
4Q 24 -6
V 1 G E 1
V 1 W 450
S W IC V 1 D 45 2
4D 16 -4
F A N
V 1 P 464
4D 16 -5
V 1 W 470
V 1 Q 13
4Q 24 -7
S W IC
IO N
V 1 D 48 4
S W E E P E R
V 1 Q 14
4Q 24 -8
12
10
V 1 Q 15
4Q 24 -9
UP
V 1 Q 16
4Q 24 -10
V 1 P 546
UP
4D 16 -6
V 1 Q 17
4Q 24 -11
F A N
11
V 1 D 56 6
4 D 16 -7
V 1 Q 18
9
4Q 24 -12
V 1 P 587
4D 16 -8
V 1 Q 19
4Q 24 -13
V 1 P 2
5D 32 -2
V 1 W 608V 1 Q 20
S W IC
V 1 D 5
4Q 24 -14
3 . 5 "G A P
M 7 1 2
10
UP
2 1 . 0 4 7 9 °
V 1 Q 2 1
4 Q 2 4 -1 5
V 1 G E 2
8
V 1 Q 2 2
4 Q 2 4 -1 6
V 1 C 2 V 1 Q 2 3
4 Q 2 4 -1 7
F A N
V 1 W 6 4 6
H 1 A N D H 2 S U B S T A T IO N
V 1 P 6 4 8
S W IC
I O N
4 D 1 6 -9
V 1 Q 2 4
4 Q 2 4 -1 6
9
V 1 Q 2 5
(S H IE LD IN G R E F: D 1 4 -1 6 18 -C -5 )
4 Q 2 4 -1 9
PS 18-4V1 IN FLEC TOR
V 1 D 6
M 7 0 7
V1Q20PS 10-39
3 . 5 "G A P
UP
7
V1Q28PS 225-2I
V1D 6TPS 10-40
2 1 . 0 4 7 9 °
PS 10-5
V1Q29PS 225-3I
V1Q21, Q25
G A S S H E D
PS 25-1A
V1P2
V 1 W 6 7 8
PS N50-7
PS 10-44
S W IC
V1Q26
V1Q23
PS 5-3V1Q27
PS 427V1D 5, D6
PS 16-12V1Q22, Q24
V 1 G E 3
4 Q 2 4 -2 0
V 1 Q 2 6
PS 2.4-10
PS 2.4-6V1P4546
PS 2.4-11
PS 2.4-8V1P587
V1D 684
PS 2.4-12
V1D 684
V1D 710
R E C T IF IE RR O O M
PS 2.4-7V1D 566
PS
RA
CK
S
PS 2.4-9V1P648
A/BR ACKS
V 1 Q 2 7
4 Q 2 4 -2 1
C O N F . R O O M
V 1 P 6 9 4
4 D 1 6 -1 1
E L E C T R O N IC S A R E A
C RAN E LIMIT
V 1 Q 2 8
8
10
M 1 1 3
C O N T R O L R O O M
11
H V A C S Y S T E M
V 1 Q 2 9
M 1 2 2
9
V 1 D 7 1 0
4 D 1 6 -1 2
12
16
17
15
V 1 W 7 1 2
/ IO NS W IC
18
14
T U R B OP U M P
C RAN E LIMIT
T U R B OP U M P
13
19
C R YO
6
P U M P
M G E 1
20
12
L U N C H R O O M
8
1
G R ID R O T A T IO N P IV O T P O IN T
21
N 1 94 0 0 .0 0 0 00 0 0 0
11
E - 50 0 0 .00 0 0 00 0 0
CO NT RO LSKIC KER
PO WER SU PPLYPUL SAR
"
BO TT O M EL ECTROD ES
SCR APING +"B
"
"C /D "
UP
CO NT RO LSKIC KER
EL ECTROD EST OP
STANDAR D +"A
AND LEDL ASER
SID EEL ECTROD ES
STANDAR D -
RAC K
EL ECTROD ESSID E
"C /D "SCR APING -
10
22
9
23
7
2
Q U E N C H
8
E L E C T
24
C R YOP U M P
T U R B OP U M P
UP
QU
EN
CH
7
1
PR
OT
EC
T
M P.S .
UP
6
2
A N DM O TO R C O N T R O L C E N TE R
5
3
S H O P A R E A
4
6
3
7
M E D 1,2
5
4
T U R B OP U M P
T U R B OP U M P
F LO O R E L 6 4'-2"
DU MPRESI STO R
C RAN E LIMIT
UP SP S
H E A TE XC H AN G E R
5
PU
MP
RO
OM
L ND E W A R
2
M E D 3
P U M PA R E A
C O M P R E S S O R R O O M
L HD E W A R
e
P LA N "A " R E F R IG E R A T O R
6
C O O LIN GT O W E R
R AM P( D O W N )
C R Y O G E N ICC O N T R O L R M .
C O L DB O X
2L N D E W A R
CO
MP
RE
SS
OR
H E LIU MA R E A
4
P LAN "B" R EF R IG E R A T OR
C O M P .
B L D G 9 19 -C
L NH E A T
E X C H A N G E R
2
UP
CO
MP
RE
SS
OR
H 3 S U B S T A T IO N
P AN EL
5
H e T A N K
3
4
R H ICC O M P R E S S O R R M
O VER H EAD TR AY 20 ' C LEAR AN C E
2
3
E X P /O RB E A M LINE
A P P ROV A LE NGINE E R
A P P ROV A LS UP V R.
BY
A P P ROV A LDIV HEAD
BY
RA D S A FE TYA P P ROV A L
P HY S ICIS TA P P ROV A L
CHECKED
DRAWN
DATEQ.A. CATEGORY A-1
R . B O W M A N 3/20/97
D. PHILLIPS 4/30/97
D . PHILLIPS 4/30/97
W . M E NG 5/5/97
R . K . R E E C E 5/21/97
A . PENDZICK 4/30/97
P . P ILE 6/3/97
1
E X P /O RB E A M LINE
A P P ROV A LE NGINE E R
A P P ROV A LS UP V R.
BY
A P P ROV A LDIV HEAD
BY
RA D S A FE TYA P P ROV A L
P HY S ICIS TA P P ROV A L
CHECKED
DRAWN
DATEQ.A. CATEGORY A-1
R . B O W M A N 3/20/97
D. PHILLIPS 4/30/97
D . PHILLIPS 4/30/97
W . M E NG 5/5/97
R . K . R E E C E 5/21/97
A . PENDZICK 4/30/97
P . P ILE 6/3/97
2
H
G
F
BROOKHAVEN NATIONAL LABORATORY
UPTO N, N.Y . 11973ASSOCIATED UNIVERSITIES, INC.
AGSB E A M LINEE X P /O R
DRAWN
CHECKED
A P P ROV A LP HY S ICIS T
A P P ROV A LRA D S A FE TY
BY
DIV HEADA P P ROV A L
BY
S UP V R.A P P ROV A L
E NGINE E RA P P ROV A L
SCALE:
DRAWING NUMBER
SHEET
-6REV.
-6
US E D ON DW G. NO.
A G S N O R T H E X P . A R E A H -10
F .E .B .T R A N S P O R T , g -2 B M , E X P . #821
GENERAL LAYOUTD14-1598-AD14-1598-A
DATE
C
E X P . #821E X P . #821
Q.A. CATEGORY A-1
M A R A S C IA / B O W M A N 11/8/94
J. SCADUTO 5/1/97
J. SCADUTO 5/1/97
G . B U N C E 5/2/97
R . K . R E E C E 5/21/97
A . PENDZICK 4/30/97
P . P ILE 6/3/97 1 /8 "= 1 '-0 " 1 OF 1
E
D
C
1
B
*A U TO C A D
A
Move V1P1 upstream (longer decay channel)
Shielding mods
H
H1 0
H
G
H1 1
21
F
2 1
H1 2
1 01 -1 04
H1 3
E
UP
2 2
H1 4
D
11 6.6 85"
FL AG
U F14x6 .7 5D2 4- 113 9.6 09"
U TV 1
16 9.6 09"
U TH 2
4x6 .7 5D2 4- 519 5.4 95"
B PM
TR
AV
EL
LI MI T
TR
AV
EL
LI MI T
U BH /V 1
H1 5
40 T
ON
CR
AN
E
40 T
ON
CR
AN
E
23 0.4 35"
U Q1
N 3Q 36- 9
UP
D R 1 6D R 1 6
20
N 3Q 36- 8
U Q2
28 7.4 36"
C
2 3
H1 6
V
39 9.0 79"
RO
OM
RO
OM
MEN
`SM
EN`S
( RE F: rd 5708 0013 a1. dw g)
H1 7
B
C1
13 3.7 37"
2 4
88 .33 "4Q 26 .5- 9
H1 8
B PM
U BH /V 2
12 6.7 85"
UP
A
H1 9
19
UP
C
B
1 1 - B
H2 0
1 0 - D
( RE F: rd 5701 0175 a1. dw g)
C AD 0 1 1 0
1 5 3 4
H I
6 - 8 - 0 1
7 - 7 - 9 8
I1
E N G . A P P .E C N N O .ZO N ER E V . B YD A TE C K R S U P V . A P P .
21
R . BO W M AN
UN
ITU
NIT
R . BO W M AN
A/C
A/C
A/C
A/C
C . PEAR SO N
I2
C . PEAR SO N
73 2.0 81"
I3
U BV 3
18
77 9.8 51"
A. PEN D Z IC K
V BP M
U G E 1
( RE F: rd 5701 0118 c1. dwg )
90 7.5 67"
I4
96 5.9 57"U BH 4
H BP M
I5
20
M.E. BU
IL DIN
G
M.E . BU
IL DIN
G
I6
( RE F: rd 5701 0249 b1. dw g)
17
I7
( F E B G AT E 2 )
U G I1
14 38. 078"
FL AG
U F2
I8
14 97. 933"
19
C OL L.
U C1
I9
4x6 .7 5D2 4- 11( RE F: rd 5708 0001 a1. dw g)
16 75. 553"
I1 0
U TH 317 05. 553"
4x6 .7 5D2 4- 4
U TV 4
SU
B STAT IO
N " F " & "P
"
17 60. 561"
UP
I
16
I1 1
18 98. 721"
V D3
I1 2
12C10
0- 2
18
- 1. 5053°3. "GA
P
( RE F: rd 5701 0230 c1. dwg )
I1 3
2P 41- 1
V D4
12 C10 0- 1
12 1- 124
S NA KE
P .S .6 05
S NA KE
80 0A
- 1. 5053°
3. "GA P
I1 4
2P 42- 1
V F232
UP
FL AG
A-T
R AIL
E R
S NA KE
F M7
8
P .S .6 06
SN AK E
12 5- 128
80 0A
I1 5
15
1F 44- 1
30 -5
V Q9
P .S .9 19
V D1- 2
12 9- 132
10 -4 1
HO U
SE
A-P
OW
E R S
UP P
L Y
V P29 0
24 76. 840"
E L.B O X
UN I T
xxx
17
I1 6
xxx
AIR
CO
N DI T I O N
I N G
P.S
. 600-3
1U
Q8P.S
. 600-3
0
10 -4 2
UQ1
1
V D31 4
UQ7
P.S
. 25- 5
P.S
. 25- 8U
Q13
P.S
. 25- 4U
Q6
P.S
. 25- 9
UQ4
P.S
. 25- 3
P .S .1 56
P.S
. 25- 2
V Q1 0- 11
2P 44- 1
UQ5
P.S
. S 50 - 1 0
UTH
3
UQ9
UTV
4
P .S . S5 0- 11
P.S
. 16- 10
U Q1 2
P.S
. 25- 6
13 3- 136
UQ1
0
P.S
. 12- 1
I1 7
P.S
. 25- 7
A-1
UD3
,4, 5, 6P
.S. 505
P .S .5 02
V Q1 2
V W264
26 68. 506"
E PM
UTV
7
V B26 6
B PM
P.S
. 16- 3
A-1
3
2F 41- 1
UTH
6P
.S. 16- 4
UTV
5
P .S .4 67
V 1Q 1
P.S
. 16- 7
I1 8
V Q9
4Q 26 .5- 6
(REF: rd
5708 0011b1. dw
g)
13 7- 140
BUI LDI NG
E L.B O X
EQ UIPTMENT
( REF: 5b01
0001a1. dw
g)
16 8.0 22"
V 1Q 2
P .S .I 225 -1
2F 42- 1
I1 9
V 1D4
P .S .9 23
14 1- 144
14
P .S .9 20
V 1D1
I2 0
4x6 D2 4- 4
V P29 0
V 1D3
P .S .9 01
16
P .S .9 02
V 1D2
V Q1 0
192.0
22"
5Q 36 -0 2
5Q 36 -0 7
V Q1 1
1F 44- 2
I J
V 1Q 3,6
P .S .6 2- 1,2
V 1Q 4,5
14 5- 148
V B30 2
( REF: 5708
0012b1. dw
g)
J1
168.0
21"
P .S .2 51
V 1Q 7
2F 42- 2
V 1Q 8
N 3Q 36- 21
V Q1 2
J2
14 9- 152
V D31 44x6 D2 4- 2
(SHI ELD
I NG RE
F: neg CN
4- 311- 94)
E L.B O X
V T G E 1
V X31 5C UR . X. FO RM.
UC2
J3
153.0
72"
V E32 4
TG T .S WICV W325
S EC
V F326
2P 41- 2
FL AG
UQ1
0
VT
GE
2
B L D G 9 2 1
15 3- 156
13
J4
290.9
93"
"V" TAR GET
V 1Q 1N 8Q 48- 2
15
4D24-9
UTV
5
BUOY ANC
HORS 3 HIG
H
N 8Q 32- 15
V 1Q 2
V 1P1
SUM
P
P .S .N 50- 6
R E F . D W G D 1 4- 16 1 9 -C 6
J5
2P 44- 2
P .S .5 -2
V 1Q 9
P .S .5 -1
M 7 3 7
V 1 D 1
V 1Q 1
15 7- 160
- 1 6 . 1 3 1 9 °
3 . 5 " G A P
( REF: 5708
3001.dw
g)
P .S .1 6- 5
(SHI ELD
I NG RE
F: neg CN
4- 313- 94)
V 1Q 11, 13, 15
P .S . R AC KS
V 1D214 C72 -2
S EC UR I TY C AB IN ET S
J6
2P 42- 2
P .S . 16- 8
- 14. 860 8°
P .S . 2. 4- 1
V 1Q 12, 14, 16, 18
3"G AP
P .S . 2. 4- 2P .S . 2. 4- 3P .S . 2. 4- 4
P .S . 2. 4- 5
16 1- 164
V 1Q 3
V 1P3 99
V D41 1
4Q 16 -2 1
V IP 424V 1D4 52
V IP 464
V 1Q 4
J7
4Q 16 -2 3
V 1C1
S EC UR I TY C AB IN ET S
V 1Q 5
673.6
33"
4Q 16 -2 2
V 1Q 6
UB6
4Q 16 -2 4
V 1 D 3
E LE C T R O N IC S
UC3
R O O M
749.9
69"
J8
- 1 4 . 8 6 0 9 °
M 7 3 4
SLAC
730-1
0
A .B .R AC K S
UQ1
1
3 . 5 " G A P
SUM
P
V 1 D 4
804.5
70"
12
14
4D24-7
- 1 6 . 1 3 1 9 °
UTH
6
J9
M 7 3 83 . 5 " G A P
V 1Q 7
M 116
V 1Q 8
( REF: 5701
0122b1. dw
g)
J1 0
M 121
V 1P3 99
4D 16- 1
J
V 1Q 9
J1 1
4Q 24 -4
4Q 24 -2 2V 1Q 10 V 1W409
S WIC
T A R G E T AR E A
I ON
P U M P R O O M
(SH
I EL
DIN
G R
EF
: D14
-159
4-C
-6)
V 1D4 11
J1 2
4D 16- 2
CO
ND
UIT
UP
J1 3
V 1P4 24
4D 16- 3
V 1Q 11
4Q 24 -5
SHI ELDI NG REF : D1 4- 16 13 -C
-5
V 1W430
S WIC
13
V 1D4 40
11
g -2 BE AM L INE / B U IL DIN G 9 4 9
4D 16- 4
V 1P1
5D 32- 1
V 1Q 12
4Q 24 -6
V 1G E1
V 1W450
S WIC V 1D4 52
4D 16- 4
F A N
V 1P4 64
4D 16- 5
V 1W470
V 1Q 13
4Q 24 -7
S WIC
I ON
V 1D4 84
S WEE PE R
V 1Q 14
4Q 24 -8
12
10
V 1Q 15
4Q 24 -9
UP
V 1Q 16
4Q 24 -1 0
V 1P5 46
UP
4D 16- 6
V 1Q 17
4Q 24 -1 1
F A N
11
V 1D5 66
4D 16- 7
V 1Q 18
9
4Q 24 -1 2
V 1P5 87
4D 16- 8
V 1Q 19
4Q 24 -1 3
V 1P2
5D 32- 2
V 1W608
V 1Q 20
S WIC
V 1D5
4Q 24 -1 4
3. 5"G AP
M 712
10
UP
21 .04 79°
V 1Q 21
4Q 24 -1 5
V 1G E2
8
V 1Q 22
4Q 24 -1 6
V 1C2V 1Q 23
4Q 24 -1 7
F A N
V 1W646
H1 AND H2 SUBST AT IO N
V 1P6 48
S WIC
I ON
4D 16- 9
V 1Q 24
4Q 24 -1 6
9
V 1Q 25
(S H IEL D IN G R EF : D 1 4 -1 61 8 -C -5 )
4Q 24 -1 9
P S 1 8 - 4V 1 I N F L E C T O R
V 1D6
M 707
V 1 Q 2 0P S 1 0 - 3 9
3. 5" G AP
UP
7
V 1 Q 2 8P S 2 2 5 - 2I
V 1 D 6 TP S 1 0 - 4 0
21 .04 79°
P S 1 0 - 5
V 1 Q 2 9
P S 2 2 5 - 3I
V 1 Q 2 1 , Q 2 5
G A S S H ED
P S 2 5 - 1 A
V 1 P 2
V 1W678
P S N 5 0 - 7
P S 1 0 - 4 4
S WIC
V 1 Q 2 6
V 1 Q 2 3
P S 5 - 3V 1 Q 2 7
P S 4 2 7V 1 D 5 , D 6
P S 1 6 - 1 2V 1 Q 2 2 , Q 2 4
V 1G E3
4Q 24 -2 0
V 1Q 26
P S 2 . 4 - 1 0
P S 2 . 4 - 6V 1 P 4 5 4 6
P S 2 . 4 - 1 1
P S 2 . 4 - 8V 1 P 5 8 7
V 1 D 6 8 4
P S 2 . 4 - 1 2
V 1 D 6 8 4
V 1 D 7 1 0
R E CT IF IE RR O O M
P S 2 . 4 - 7V 1 D 5 6 6
PS
RACK
S
P S 2 . 4 - 9V 1 P 6 4 8
A /BR A C K S
V 1Q 27
4Q 24 -2 1
C O N F . R O O M
V 1P6 94
4D 16- 11
E LE C T R O N IC S A R EA
C RA NE LIM I T
V 1Q 28
8
10
M 113
C O N T R O L R O O M
11
H V AC SY S T EM
V 1Q 29
M 122
9
V 1D7 10
4D 16- 12
12
1 6
1 7
1 5
V 1W712
/ IO N
S WIC
1 8
1 4
TU R BOP UM P
C RA NE LIM I T
TU R BOP UM P
1 3
1 9
C RY O
6
P UM P
M G E 1
2 0
1 2
L U N C H R O O M
8
1
2 1
1 1
C ON TR O LSK IC KE R
P OWE R S UP PL YP ULS AR
"
B OT TO M E LEC TR O DE S
S CR AP IN G +" B
"
" C/ D "
UP
C ON TR O LSK IC KE R
E LEC TR O DE STO P
S TAN D AR D +" A
A ND L EDLA SE R
S ID EE LEC TR O DE S
S TAN D AR D -
R AC K
E LEC TR O DE SS ID E
" C/ D "S CR AP IN G -
1 0
2 2
9
2 3
7
2
Q UENCH
8
ELECT
2 4
C RY OP UM P
TU R BOP UM P
UP
QUE
NCH
7
1
PRO
TECT
M P . S .
UP
6
2
AN DM O T O R C O NT R O L C E N T E R
5
3
S H O P A R EA
4
6
3
7
M ED 1 ,2
5
4
TU R BOP UM P
TU R BOP UM P
F LO OR EL 64 '- 2"
C RA NE LIM I T
UPSPS
H E ATE XC HA NG E R
5
PU
MP
RO
OM
L ND E W A R
2
M ED 3
P U M PA R EA
C O M P RE S SO R R O O M
L HD E W A R
e
P L A N " A " R E F R IG E R A T O R
6
C O O LIN GT O W ER
RAM P( DO WN )
C R YO G E N ICC O N T R O L R M .
C O L DB O X
2
L N D E W A R
CO
MP
RE
SS
OR
H E LIU MA R EA
4
P LAN "B " R EF RI G ER AT O R
C O M P .
B LD G 9 1 9 -C
L NH E AT
E X C H A N G E R
2
UP
CO
MP
RE
SS
OR
H 3 SU B ST A T IO N
PANEL
5
He T A N K
3
4
R H ICC O M P RE S SO R R M
O VERHEAD TR AY 20 ' CLEAR ANCE
2
3
EXP/O RBEAM LINE
A P P R O V A L
E N G IN E E R
A P P R O V A L
S U P V R .
B Y
A P P R O V A L
D IV H E A D
B Y
R A D S A FE TYA P P R O V A L
P H Y S IC IS TA P P R O V A L
C H E C K E D
D R A W N
D A TEQ .A. C AT EG O R Y A- 1
R . B O W M A N 3/20/97
D. PHILLIPS 4/30/97
D. PHILLIPS 4/30/97
W . M E NG 5/5/97
R. K . REECE 5/21/97
A . PENDZ ICK 4/30/97
P . P IL E 6/3/97
1
EXP/O RBEAM LINE
A P P R O V A L
E N G IN E E R
A P P R O V A L
S U P V R .
B Y
A P P R O V A L
D IV H E A D
B Y
R A D S A FE TYA P P R O V A L
P H Y S IC IS TA P P R O V A L
C H E C K E D
D R A W N
D A TEQ .A. C AT EG O R Y A- 1
R . B O W M A N 3/20/97
D. PHILLIPS 4/30/97
D. PHILLIPS 4/30/97
W . M E NG 5/5/97
R. K . REECE 5/21/97
A . PENDZ ICK 4/30/97
P . P IL E 6/3/97
2
H
G
F
BROOKHAVEN NATIONAL LABORATORY
UP TO N, N .Y . 1 1 9 7 3A S S O C IA TE D U N IV E R S ITIE S , IN C .
AGSBEAM LINEEXP/O R
D R A W N
C H E C K E D
A P P R O V A LP H Y S IC IS T
A P P R O V A LR A D S A FE TY
B Y
D IV H E A D
A P P R O V A L
B Y
S U P V R .
A P P R O V A L
E N G IN E E R
A P P R O V A L
S C A LE :
D R A W IN G N U M B E R
S H E E T
-6R E V .
-6
U S E D O N D W G . N O .
A GS NORT H E X P . A RE A H-10 F.E .B .T RA NS P ORT , g-2 B M, E X P . #821
GENERAL LAYOUTD14-1598-AD14-1598-A
D A TE
C
E X P . # 8 2 1E X P . # 8 2 1
Q .A. C AT EG O R Y A- 1
M A R A S C I A / B O W M A N 11/8 /94
J. SCADUT O 5/1/97
J. SCADUT O 5/1/97
G . B UN CE 5/2/97
R. K . REECE 5/21/97
A . PENDZ ICK 4/30/97
P . P IL E 6/3/97 1/8"= 1'-0" 1 O F 1
E
D
C
1
B
*AUTOCAD
A
Add 30 quads to pion decay channel, collect more muons
H
H1 0
H
G
H1 1
21
F
2 1
H1 2
1 01 -1 04
H1 3
E
UP
2 2
H1 4
D
11 6.6 85"
FL AG
U F14x6 .7 5D2 4- 113 9.6 09"
U TV 1
16 9.6 09"
U TH 2
4x6 .7 5D2 4- 519 5.4 95"
B PM
TR
AV
EL
LI MI T
TR
AV
EL
LI MI T
U BH /V 1
H1 5
40 T
ON
CR
AN
E
40 T
ON
CR
AN
E
23 0.4 35"
U Q1
N 3Q 36- 9
UP
D R 1 6D R 1 6
20
N 3Q 36- 8
U Q2
28 7.4 36"
C
2 3
H1 6
V
39 9.0 79"
RO
OM
RO
OM
MEN
`SM
EN`S
( REF: rd
57080013
a1. dwg)
H1 7
B
C1
13 3.7 37"
2 4
88 .33 "4Q26
.5- 9
H1 8
B PM
U BH/V
2
12 6.7 85"
UP
A
H1 9
19
UP
C
B
1 1 - B
H2 0
1 0 - D
( REF: rd
57010175
a1. dwg)
C AD 0 1 1 0
1 5 3 4
H I
6 - 8 - 0 1
7 - 7 - 9 8
I1
E N G . A P P .E C N N O .ZO N ER E V . B YD A TE C K R S U P V . A P P .
21
R . BO W M AN
UN
ITU
NIT
R . BO W M AN
A/C
A/C
A/C
A/C
C . PEAR SO N
I2
C . PEAR SO N
73 2.0 81"
I3
U BV3
18
77 9.8 51"
A. PEN D Z IC K
V BPM
U G E 1
( REF: rd
57010118
c1. dwg)
90 7.5 67"
I4
96 5.9 57"U BH
4
H BPM
I5
20
M.E. BU
IL DIN
G
M.E . BU
IL DIN
G
I6
( REF: rd
57010249
b1. dwg)
17
I7
( F E B G AT E 2 )
U G I1
14 38. 078"
FL AG
U F2
I8
14 97. 933"
19
COL
L.
UC1
I9
4x6.7
5D24- 11
( REF: rd
57080001
a1. dwg)
16 75. 553"
I1 0
UTH
3
17 05. 553"
4x6.7
5D24- 4
UTV
4
SU
B STAT IO
N " F " & "P
"
17 60. 561"
UP
I
16
I1 1
18 98. 721"
VD3
I1 2
12C10
0-2
18
- 1. 5053°3. "GA
P
( REF: rd
57010230
c1. dwg)
I1 3
2P 41- 1
VD4
12C10
0- 1
12 1- 124
S NA KE
P .S .6 05
S NA KE
80 0A
- 1. 5053°
3. "GAP
I1 4
2P 42- 1
V F232
UP
FL AG
A-T
R AIL
E R
S NA KE
F M7
8
P .S .6 06
SN AK E
12 5- 128
80 0A
I1 5
15
1F 44- 1
30 -5
V Q9
P .S .9 19
V D1- 2
12 9- 132
10 -4 1
HO U
SE
A-P
OW
E R S
UP P
L Y
V P29 0
24 76. 840"
E L.B O X
UN I T
xxx
17
I1 6
xxx
AIR
CO
N DI T I O N
I N G
P.S
. 600-3
1U
Q8P.S
. 600-3
0
10 -4 2
UQ1
1
V D31 4
UQ7
P.S
. 25- 5
P.S
. 25- 8U
Q13
P.S
. 25- 4U
Q6
P.S
. 25- 9
UQ4
P.S
. 25- 3
P .S .1 56
P.S
. 25- 2
V Q1 0- 11
2P 44- 1
UQ5
P.S
. S 50 - 1 0
UTH
3
UQ9
UTV
4
P .S . S5 0- 11
P.S
. 16- 10
U Q1 2
P.S
. 25- 6
13 3- 136
UQ1
0
P.S
. 12- 1
I1 7
P.S
. 25- 7
A-1
UD3
,4, 5, 6P
.S. 505
P .S .5 02
V Q1 2
V W264
2668. 506"
E PM
UTV
7
V B26 6
B PM
P.S
. 16- 3
A-1
3
2F 41- 1
UTH
6P
.S. 16- 4
UTV
5
P .S .4 67
V 1Q 1
P.S
. 16- 7
I1 8
V Q9
4Q 26 .5- 6
( REF: rd
57080011
b1. dwg)
13 7- 140
BUI LDI NG
E L.B O X
EQ UIPTMENT
( REF: 5b01
0001a1. dw
g)
168.0
22"
V 1Q 2
P .S .I 225 -1
2F 42- 1
I1 9
V 1D4
P .S .9 23
14 1- 144
14
P .S .9 20
V 1D1
I2 0
4x6 D2 4- 4
V P29 0
V 1D3
P .S .9 01
16
P .S .9 02
V 1D2
V Q1 0
192.0
22"
5Q 36 -02
5Q 36 -07
V Q1 1
1F 44- 2
I J
V 1Q 3,6
P .S .6 2- 1,2
V 1Q 4,5
14 5- 148
V B30 2
( REF: 5708
0012b1. dw
g)
J1
168.0
21"
P .S .2 51
V 1Q 7
2F 42- 2
V 1Q 8
N 3Q 36- 21
V Q1 2
J2
14 9- 152
V D31 44x6 D2 4- 2
( SHI ELD
I NG RE
F: neg CN
4- 311- 94)
E L.B O X
V T G E 1
V X31 5C UR . X. FORM .
UC2
J3
153.0
72"
V E32 4
TGT .S
WICV W
325
S EC
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FLAG
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0
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2
B L D G 9 2 1
15 3- 156
13
J4
290.9
93"
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V 1Q 1N 8Q 48- 2
15
4D24-9
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5
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H
N 8Q 32- 15
V 1Q 2
V 1P1
SUM
P
P .S .N 50- 6
R E F . D W G D 1 4- 16 1 9 -C 6
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V 1Q 1
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( REF: 5708
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g)
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V 1Q 12, 14, 16, 18
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P .S . 2. 4- 2P .S . 2. 4- 3P .S . 2. 4- 4
P .S . 2. 4- 5
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V 1Q 3
V 1P3 99
V D41 1
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V IP 424V 1D4 52
V IP 464
V 1Q 4
J7
4Q 16 -2 3
V 1C1
S EC UR I TY C AB IN ET S
V 1Q 5
673.6
33"
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V 1Q 6
UB6
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V 1 D 3
E LE C T R O N IC S
UC3
R O O M
749.9
69"
J8
- 1 4 . 8 6 0 9 °
M 7 3 4
SLAC
730-1
0
A .B .R AC K S
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1
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SUM
P
V 1 D 4
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70"
12
14
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6
J9
M 7 3 83 . 5 " G A P
V 1Q 7
M 116
V 1Q 8
( REF: 5701
0122b1. dw
g)
J1 0
M 121
V 1P3 99
4D 16- 1
J
V 1Q 9
J1 1
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4Q 24 -2 2V 1Q 10 V 1W409
S WIC
T A R G E T AR E A
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(SH
IEL
DIN
G R
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4-C
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ND
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SHI ELDI NG REF : D1 4- 16 13 -C
-5
V 1W430
S WIC
13
V 1D4 40
11
g -2 BE AM L INE / B U IL DIN G 9 4 9
4D 16- 4
V 1P1
5D 32- 1
V 1Q 12
4Q 24 -6
V 1G E1
V 1W450
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4D 16- 4
F A N
V 1P4 64
4D 16- 5
V 1W470
V 1Q 13
4Q 24 -7
S WIC
I ON
V 1D4 84
S WEE PE R
V 1Q 14
4Q 24 -8
12
10
V 1Q 15
4Q 24 -9
UP
V 1Q 16
4Q 24 -1 0
V 1P5 46
UP
4D 16- 6
V 1Q 17
4Q 24 -1 1
F A N
11
V 1D5 66
4D 16- 7
V 1Q 18
9
4Q 24 -1 2
V 1P5 87
4D 16- 8
V 1Q 19
4Q 24 -1 3
V 1P2
5D 32- 2
V 1W608
V 1Q 20
S WIC
V 1D5
4Q 24 -1 4
3. 5"G AP
M 712
10
UP
21 .04 79°
V 1Q 21
4Q 24 -1 5
V 1G E2
8
V 1Q 22
4Q 24 -1 6
V 1C2V 1Q 23
4Q 24 -1 7
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H1 AND H2 SUBST AT IO N
V 1P6 48
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V 1Q 24
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V 1Q 25
(S H IEL D IN G R EF : D 1 4 -1 61 8 -C -5 )
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P S 1 8 - 4V 1 I N F L E C T O R
V 1D6
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V 1 Q 2 0P S 1 0 - 3 9
3. 5" G AP
UP
7
V 1 Q 2 8P S 2 2 5 - 2I
V 1 D 6 TP S 1 0 - 4 0
21 .04 79°
P S 1 0 - 5
V 1 Q 2 9P S 2 2 5 - 3I
V 1 Q 2 1 , Q 2 5
G A S S H ED
P S 2 5 - 1 A
V 1 P 2
V 1W678
P S N 5 0 - 7
P S 1 0 - 4 4
S WIC
V 1 Q 2 6
V 1 Q 2 3
P S 5 - 3V 1 Q 2 7
P S 4 2 7V 1 D 5 , D 6
P S 1 6 - 1 2V 1 Q 2 2 , Q 2 4
V 1G E3
4Q 24 -2 0
V 1Q 26
P S 2 . 4 - 1 0
P S 2 . 4 - 6V 1 P 4 5 4 6
P S 2 . 4 - 1 1
P S 2 . 4 - 8V 1 P 5 8 7
V 1 D 6 8 4
P S 2 . 4 - 1 2
V 1 D 6 8 4
V 1 D 7 1 0
R E CT IF IE RR O O M
P S 2 . 4 - 7V 1 D 5 6 6
PS
RAC K
S
P S 2 . 4 - 9V 1 P 6 4 8
A /BR A C K S
V 1Q 27
4Q 24 -2 1
C O N F . R O O M
V 1P6 94
4D 16- 11
E LE C T R O N IC S A R EA
C RA NE LIM I T
V 1Q 28
8
10
M 113
C O N T R O L R O O M
11
H V AC SY S T EM
V 1Q 29
M 122
9
V 1D7 10
4D 16- 12
12
1 6
1 7
1 5
V 1W712
/ IO N
S WIC
1 8
1 4
TU R BOP UM P
C RA NE LIM I T
TU R BOP UM P
1 3
1 9
C RY O
6
P UM P
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2 0
1 2
L U N C H R O O M
8
1
2 1
1 1
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"
B OT TO M E LEC TR O DE S
S CR AP IN G +" B
"
" C/ D "
UP
C ON TR O LSK IC KE R
E LEC TR O DE STO P
S TAN D AR D +" A
A ND L EDLA SE R
S ID EE LEC TR O DE S
S TAN D AR D -
R AC K
E LEC TR O DE SS ID E
" C/ D "S CR AP IN G -
1 0
2 2
9
2 3
7
2
Q UENCH
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NC H
7
1
PRO
T ECT
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UP
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2
AN DM O T O R C O NT R O L C E N T E R
5
3
S H O P A R EA
4
6
3
7
M ED 1 ,2
5
4
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TU R BOP UM P
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C RA NE LIM I T
UPSPS
H E ATE XC HA NG E R
5
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MP
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OM
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2
M ED 3
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e
P L A N " A " R E F R IG E R A T O R
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2
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MP
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4
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2
UP
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MP
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SS
OR
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PANEL
5
He T A N K
3
4
R H ICC O M P RE S SO R R M
O VERHEAD TR AY 20 ' CLEAR ANCE
2
3
EXP/O RBEAM LINE
A P P R O V A L
E N G IN E E R
A P P R O V A L
S U P V R .
B Y
A P P R O V A L
D IV H E A D
B Y
R A D S A FE TYA P P R O V A L
P H Y S IC IS TA P P R O V A L
C H E C K E D
D R A W N
D A TEQ .A. C AT EG O R Y A- 1
R . B O W M A N 3/20/97
D. PHILLIPS 4/30/97
D. PHILLIPS 4/30/97
W . M E NG 5/5/97
R. K . REECE 5/21/97
A . PENDZ ICK 4/30/97
P . P IL E 6/3/97
1
EXP/O RBEAM LINE
A P P R O V A L
E N G IN E E R
A P P R O V A L
S U P V R .
B Y
A P P R O V A L
D IV H E A D
B Y
R A D S A FE TYA P P R O V A L
P H Y S IC IS TA P P R O V A L
C H E C K E D
D R A W N
D A TEQ .A. C AT EG O R Y A- 1
R . B O W M A N 3/20/97
D. PHILLIPS 4/30/97
D. PHILLIPS 4/30/97
W . M E NG 5/5/97
R. K . REECE 5/21/97
A . PENDZ ICK 4/30/97
P . P IL E 6/3/97
2
H
G
F
BROOKHAVEN NATIONAL LABORATORY
UP TO N, N.Y . 1 1 9 7 3A S S O C IA TE D U N IV E R S ITIE S , IN C .
AGSBEAM LINEEXP/O R
D R A W N
C H E C K E D
A P P R O V A LP H Y S IC IS T
A P P R O V A LR A D S A FE TY
B Y
D IV H E A D
A P P R O V A L
B Y
S U P V R .
A P P R O V A L
E N G IN E E R
A P P R O V A L
S C A LE :
D R A W IN G N U M B E R
S H E E T
-6R E V .
-6
U S E D O N D W G . N O .
A GS NORT H E X P . A RE A H-10 F.E .B .T RA NS P ORT , g-2 B M, E X P . #821
GENERAL LAYOUTD14-1598-AD14-1598-A
D A TE
C
E X P . # 8 2 1E X P . # 8 2 1
Q .A. C AT EG O R Y A- 1
M A R A S C I A / B O W M A N 11 /8 /94
J. SCADUT O 5/1/97
J. SCADUT O 5/1/97
G . B UNCE 5/2/97
R. K . REECE 5/21/97
A . PENDZ ICK 4/30/97
P . P IL E 6/3/97 1/8"= 1'-0" 1 O F 1
E
D
C
1
B
*AUTOCAD
A
Improve shieldingNew open-end inflectorLess multiple scattering, more muons stored
To Do List
• Complete simulations to include transport to K3K4 and inflector for both the present beam line and the proposed beam line, done but with little thought and is not optimized.– Include 19 cm length in simulation
• Can we reconcile differences between beam line measurements and simulations
• Are 30 quads (4X) in decay channel optimum? There’s room for more but pole tip field becomes a problem…
Supplementary Information
H
H 10
H
G
H 11
2 1
F
21
H 12
101- 104
H 13
E
U P
22
H 14
D
TRA
VEL L
IMI T
TRA
VEL L
IMI T
H 15
40 T
ON CR
ANE
40 T
ON CR
ANE
U P
D R 16D R 16
2 0
C
23
H 16
V
ROO
MR
OOM
MEN
`S
MEN
`S
H 17
B
C1
24
H 18
U P
A
H 19
1 9
U P
C
B
1 1 - B
H 20
1 0 - D
C A D 0 1 1 0
1 5 3 4
H I
6 - 8 - 0 1
7 - 7 - 9 8
I 1
ENG . APP.ECN NO .ZO NEREV. BYDATE CKR SUPV. APP.
2 1
R . B O W M A N
UNI T
UNI T
R . B O W M A N
A/C
A/C
A/C
A/C
C . P E A R S O N
I 2
C . P E A R S O N
I 3
1 8
A . P E N D Z I C K
U GE 1
I 4
I 5
2 0
M. E. B
UI LDI NG
M. E. B
UI LDI NG
I 6
1 7
I 7
( FEB
GA
TE 2 )
UGI 1
I 8
1 9
I 9 I 10
SUB
STA
TI ON "F
" & "P
"
U P
I
1 6
I 11 I 12
1 8
I 13 I 14
U P
A-T
RAIL
ER
FM7
8
I 15
1 5
HOU
SE
A-P
OW
ER S
UPP
LY
UNI T
1 7
I 16
AIR
CO
NDI TI ON
I NG
P. S. S50- 10
I 17
I 18
BUI LD
ING
EQU
I PTME
NT
I 19
1 4
I 20
1 6
I J
J1
J2
V TG E1
J3
VTG
E2
B L D G 92 1
1 3
J4
"V" TA RG E T
1 5
BUO
Y ANC
HOR
S 3 HI GH
R EF . DWG D 14- 161 9-C6
J5
M 737
V 1D1- 16. 131 9°
3. 5"G AP
J6
J7
V 1D3
E LEC TR O NI C S
R OO M
J8
- 14. 860 9°
M 734 3. 5" G AP
V 1D4
1 2
1 4
- 16. 131 9°
J9
M 7383. 5"G AP
J10
J
J11
TA R GE T AR EA
P UM P R O OM
(SH
IELD
I NG
RE
F:D1
4-15
94-C
-6)
J12
CON
DUI
T
U P
J13
S HI EL DI NG RE F: D14 -1 613- C - 5
1 3
1 1
g- 2 BE AM LI NE / B UI LD IN G 9 49
V 1G E1
FA N
1 2
1 0
U P
U P
FA N
1 1
9
1 0
U P
V 1 G E 2
8
FA N
H 1 A N D H 2 S U B S T A T I O N
9
( SH I ELD I NG RE F: D 14- 16 18- C -5 )
PS 18- 4V1 IN FLECTO R
V1Q 20PS 10- 39
UP
7
V1Q 28PS 225- 2I
V1D 6TPS 10- 40
PS 10- 5
V1Q 29PS 225- 3I
V1Q 21, Q25
G AS S H ED
PS 25- 1A
V1P2PS N50- 7
PS 10- 44
V1Q 26
V1Q 23
PS 5- 3V1Q 27
PS 427V1D 5, D6
PS 16- 12V1Q 22, Q24
V 1 G E 3
PS 2.4- 10
PS 2.4- 6V1P4546
PS 2.4- 11
PS 2.4- 8V1P587
V1D 684
PS 2.4- 12
V1D 684
V1D 710
R EC TI FI ER
R OO M
PS 2.4- 7V1D 566
PS R
ACKS
PS 2.4- 9V1P648
A/ BRA CKS
C ON F. RO O M
E LEC TR O NI C S AR EA
8
C ON TR O L RO O M
H VA C SY ST EM
16
17
15
18
14
13
19
6
M G E 1
20
12
LU N CH R O O M
21
11
U P
10
22
9
23
8
24
UP
QUE
NCH
7
1
PRO
TECTM P. S.
UP
6
2
AN D
M O TO R C ON TR O L CE NT ER
5
3
S HO P A RE A
4
7
M E D 1 , 2
FL OO R E L 64' -2 "
U PSP S
H EA T
E XC HA NG E R
5
PUM
P R
OOM
LN
D EWA R
2
M E D 3
P UM P
A RE A
C OM P RE SS O R R OO M
LH
D EWA Re
P LAN "A " R EF RI G ER AT O R
6
C OO LI N G
TO WE R
R AM P
( D O WN )
C RY O GE NI C
C ON TR O L RM .
C OL D
B OX
2LN D EWA R
COM
PRE
SSO
R
H ELI U M
A RE A
4
P LAN "B " R EF RI G ER AT O R
C OM P .
B LDG 919 -C
LN
H EA TE XC HA NG E R
2
UP
COM
PRE
SSO
R
H 3 SU BS TA TI ON
P AN EL
5
H e TA N K
3
4
R HI C
C OM P RE SS O R R M
O VE RH E AD T RA Y 2 0' CL EA RA NC E
2
3
E X P / O R
B E A M L I N E
APPRO VALENG I NEER
APPRO VALSUPVR.
BY
APPRO VALDI V HEAD
BY
RAD SAFETYAPPRO VAL
PHYSI CI STAPPRO VAL
CHECKED
DRAWN
DATEQ . A. CATEG O RY A- 1
R . B O W M A N 3 / 2 0 / 9 7
D . P H I L L I P S 4 / 3 0 / 9 7
D . P H I L L I P S 4 / 3 0 / 9 7
W . M E N G 5 / 5 / 9 7
R . K . R E E C E 5 / 2 1 / 9 7
A . P E N D Z I C K 4 / 3 0 / 9 7
P . P I L E 6 / 3 / 9 7
1
E X P / O R
B E A M L I N E
APPRO VALENG I NEER
APPRO VALSUPVR.
BY
APPRO VALDI V HEAD
BY
RAD SAFETYAPPRO VAL
PHYSI CI STAPPRO VAL
CHECKED
DRAWN
DATEQ . A. CATEG O RY A- 1
R . B O W M A N 3 / 2 0 / 9 7
D . P H I L L I P S 4 / 3 0 / 9 7
D . P H I L L I P S 4 / 3 0 / 9 7
W . M E N G 5 / 5 / 9 7
R . K . R E E C E 5 / 2 1 / 9 7
A . P E N D Z I C K 4 / 3 0 / 9 7
P . P I L E 6 / 3 / 9 7
2
H
G
F
B R O O K H A V E N N A TIO N A L LA B O R A TO R YU P T O N , N . Y . 1 1 9 7 3
ASSO CI ATED UNI VERSI TI ES, I NC.
AGSB E A M L I N E
E X P / O R
DRAWN
CHECKED
APPRO VALPHYSI CI ST
APPRO VALRAD SAFETY
BY
DI V HEADAPPRO VAL
BY
SUPVR.APPRO VAL
ENG I NEERAPPRO VAL
SCALE:
DRAWI NG NUM BER
SHEET
-6 REV.
-6
USED O N DWG . NO .
A G S N O R T H E X P . A R E A H - 1 0 F . E . B . T R A N S P O R T , g - 2 B M , E X P . # 8 2 1
GENERAL LAYOUT
D14-1598-AD14-1598-A
DATE
C
E X P . # 8 2 1E X P . # 8 2 1
Q . A. CATEG O RY A- 1
M A R A S C I A / B O W M A N1 1 / 8 / 9 4
J . S C A D U T O 5 / 1 / 9 7
J . S C A D U T O 5 / 1 / 9 7
G . B U N C E5 / 2 / 9 7
R . K . R E E C E 5 / 2 1 / 9 7
A . P E N D Z I C K 4 / 3 0 / 9 7
P . P I L E 6 / 3 / 9 7 1 / 8 " = 1 ' - 0 " 1 O F 1
E
D
C
1
B
*AU T O C AD
A
What is needed to baseline the costs (not included in construction cost estimate)
• 1.0 g-2 Ring/Building maintenance– 1 man month to engineer an air conditioning
system for bldg 919• 1.1 V/V1 Beam Lines
– 1 man-months engineering– 1 man-months physicist
• 1.2 Inflector (see Meng talk)– A quote from the Furukawa Company for
superconductor• 1.3 E Quads
– Nothing new, defendable• 1.8 Kicker
– Nothing new, defendable• 1.11 Cryogenics (to determine scope)
– 2 man-months engineering– 1 man-month tech
• 1.12 Vacuum System– 1 man-month engineering
• 1.14 Booster/AGS– 0.5 man month engineering– 0.5 man month physicist
• ES&H – review operation within present guidelines
– 1 man-month physicist– 1 man month engineer
• Preparation of Cost Books, Resource Loaded Schedules, CD0-1 documents etc
– 4 man-months engineering– 4 man--months physicist
• Summary
– 11 man-month engineering– 7 man-month physicist– 1 man-month tech
• Required Budget ~ $360K
• Calendar Time Required ~ 6-8 months
Muon g-2 Experiment Construction, Cost Summary
• Experiment Construction, Direct Costs M$ Contingency
– G-2 Ring and building $ 0.56 21%– V/V1 Beam Line modifications $ 2.59 18%– Inflector (open ends) $ 0.64 19%– E-Quad rebuild $ 0.13 15%– Additional muon Kicker $ 0.41 15%– Cryogenic plant rehab $ 0.74 233%– Ring Vacuum System $ 0.16 29%– Equipment Testing $ 0.63 20%– Project Office $ 0.37 20%
• Sub-Total, direct costs $ 6.2• Indirects (reduced) $ 2.2• Contingency (44%) $ 3.7
• Sub-Total, with indirects $ 12.1
• University (Detectors/DAQ) $ 1.4
• Total (DOE) $ 13.6
• University (Detectors/DAQ - NSF) $ 1.0
FY 2006 $’s
AGS/Booster Restoration to High Intensity, Cost Summary
• AGS/Booster, Direct Costs M$ Contingency
– ES&H (CAPS) $ 2.63 28%– Electrical Modifications $ 2.11 22%– Mechanical Modifications $ 1.25 20%– RF System Modifications $ 0.67 22%– Instrumentation $ 0.34 20%– Project Support $ 0.33 34%– Controls $ 0.16 24%
• Sub-Total, direct costs $ 7.5
• Indirects (reduced) $ 1.9
• Contingency (24%) $ 2.3
• Total $ 11.7
FY 2006 $’s
g-2 Experiment Operations, Cost Summary
• Base Plan (0.25 ppm experiment)
Year Wks w/RHIC Wks Stand-Alone Physics Wks Cost (M$)
1st 12 0 3 $ 5.8
2nd 20 0 15 $ 7.8
Total 34 0 18 $ 13.6
Additional 10-15 week year of running with RHIC adds ~$6-7M
FY 2006 $’s
g-2 Experiment Operations, Cost Summary
DOE Costs
• Baseline Costs (C-AD pre-construction) $ 0.4
• Experiment Construction (mostly C-AD) $ 12.1
• Universities $ 1.4
• AGS/Booster restoration to high intensity $ 11.7
• Operations $ 13.6
• Total $ 39.2
NSF Costs
• Universities $ 1.0
FY 2006 $’s
g-2 Experiment Operations Plan
Example Total g-2 Ops Cost w/o RHIC w/RHIC HI w/RHIC pp(Stand-by cost not included)Accelerator Weeks 20 4,320,157$ 2,441,170$ 1,611,790$
-$ -$ -$ g-2 Weeks (includes fixed cost) 20 5,203,998$ 3,120,798$ 2,717,598$ Personnel FTE's 11 2,508,126$ 2,508,126$ 2,508,126$ Total g-2 Cost 12,032,281$ 8,070,094$ 6,837,515$
Example g-2 Operations PlanAssumptions(1) AGS not available for g-2 during 1st 2 weeks of RHIC operations (Cryo cool-down) due to AGS development/tune-up for RHIC(2) AGS not available for g-2 during next 3 weeks due to AGS injection for RHIC ramp/collision development 1st 5 weeks of RHIC operations and for 3 weeks/additional beam during a given year(3) AGS not available for g-2 during an additional 3 week period for each different ion used by RHIC in a given year(4) Last 0.5 week of RHIC operations is considered running outside RHIC operations since this is cryo warm-up week (injectors not running)(5) Assume 2 ion species per year and AGS is available for g-2 the balance of the time after reserving 15 weeks for shutdown work(6) Assumes during g-2 data taking an average of 40 TP available in 1st year, 55 TP second year any 60 TP therafter(7) 80 full intensity hours/week are available for g-2 experiment during RHIC Operations, assumes 60 hrs per week data taking at full intensity(8) 120 full intensity hours/week are available for g-2 experiment outside RHIC Operations, assumes 100 hrs per week data taking at full intensity(9) RHIC Cryo Operations based on 30 weeks per year (consistent with RHIC Mid-Term Plan - 14 Feb 06)
g-2 Experiment Operations (0.5 ppm)FY 2006 $’s
g-2 Protons/spill (average) 4.00E+13 5.50E+13 6.00E+13 0.00E+00 0.00E+00Sec/spill 2.7 2.7 2.7 2.7 2.7
Protons per yearTotal Weeks 14.0 0.0 0.0 0.0setup weeks 9 0 0 0
protons 2.03E+19 0.00E+00 0.00E+00 0.00E+00Integrated Protons
g-2 (0.2E20 Goal for 0.5 ppm) 2.03E+19 2.03E+19 2.03E+19Fixed Costs on/off 1 0 0
Cost Summary (FY 2006 $'s) 1st year# 2nd year* 3rd year** Total0.5 ppm experimentPersonnel 1,286,895$ -$ -$ -$ 1,286,895$ Shift Differential 16,086$ -$ -$ -$ 16,086$ Power 1,780,800$ -$ -$ -$ 1,780,800$ DTS 172,968$ -$ -$ -$ 172,968$ SP 545,965$ -$ -$ -$ 545,965$ MSTC 771,494$ -$ -$ -$ 771,494$ g-2 Startup Costs 117,890$ -$ -$ -$ 117,890$ Additional fixed costs, Stand-by mode 115,569$ -$ -$ Indirect 1,778,599$ -$ -$ -$ 1,778,599$ University (DAQ etc) 175,000$ 150,000$
Total 6,761,266$ 150,000$ -$ -$ 6,911,266$
* Assumes first 5 weeks setup mode while running with RHIC - not counted toward integrated proton totals** Assumes first 3 weeks setup mode while running with RHIC - not counted toward integrated proton totals# Engineering Run
g-2 Experiment Operations (0.25 ppm)FY 2006 $’s
g-2 Protons/spill (average) 4.00E+13 5.50E+13 6.00E+13 0.00E+00 0.00E+00Sec/spill 2.7 2.7 2.7 2.7 2.7
Protons per yearTotal Weeks 12.0 19.5 0.0 0.0setup weeks 9 5 0 0
protons 9.60E+18 6.38E+19 0.00E+00 0.00E+00Integrated Protons
g-2 (0.7E20 Goal for 0.25 ppm) 9.60E+18 7.34E+19 7.34E+19Fixed Costs on/off 1 1 0
Cost Summary (FY 2006 $'s) 1st year# 2nd year* 3rd year** Total0.25 ppm experimentPersonnel 1,286,895$ 1,286,895$ -$ -$ 2,573,791$ Shift Differential -$ -$ -$ -$ -$ Power 1,330,560$ 2,167,200$ -$ -$ 3,497,760$ DTS 119,923$ 195,640$ -$ -$ 315,563$ SP 422,815$ 693,361$ -$ -$ 1,116,176$ MSTC 608,157$ 989,560$ -$ -$ 1,597,718$ g-2 Startup Costs 117,890$ 117,890$ -$ -$ 235,780$ Additional fixed costs, Stand-by mode 115,569$ 115,569$ -$ Indirect 1,644,223$ 1,904,270$ -$ -$ 3,548,493$ University (DAQ etc) 175,000$ 150,000$
Total 5,821,033$ 7,620,385$ -$ -$ 13,441,418$
* Assumes first 5 weeks setup mode while running with RHIC - not counted toward integrated proton totals** Assumes first 3 weeks setup mode while running with RHIC - not counted toward integrated proton totals# Engineering Run
g-2 Experiment Operations (0.2 ppm)FY 2006 $’s
g-2 Protons/spill (average) 4.00E+13 5.50E+13 6.00E+13 0.00E+00 0.00E+00Sec/spill 2.7 2.7 2.7 2.7 2.7
Protons per yearTotal Weeks 12.0 28.5 0.0 0.0setup weeks 9 5 0 0
protons 9.60E+18 1.24E+20 0.00E+00 0.00E+00Integrated Protons
g-2 (1.3E20 Goal for 0.2 ppm) 9.60E+18 1.34E+20 1.34E+20Fixed Costs on/off 1 1 0
Cost Summary (FY 2006 $'s) 1st year# 2nd year* 3rd year** Total0.2 ppm experimentPersonnel 1,286,895$ 1,286,895$ -$ -$ 2,573,791$ Shift Differential -$ 56,300$ -$ -$ 56,300$ Power 1,330,560$ 3,984,960$ -$ -$ 5,315,520$ DTS 119,923$ 404,338$ -$ -$ 524,262$ SP 422,815$ 1,219,996$ -$ -$ 1,642,811$ MSTC 608,157$ 1,667,819$ -$ -$ 2,275,976$ g-2 Startup Costs 117,890$ 117,890$ -$ -$ 235,780$ Additional fixed costs, Stand-by mode 115,569$ 115,569$ -$ Indirect 1,644,223$ 2,451,447$ -$ -$ 4,095,670$ University (DAQ etc) 175,000$ 150,000$
Total 5,821,033$ 11,455,214$ -$ -$ 17,276,247$
* Assumes first 5 weeks setup mode while running with RHIC - not counted toward integrated proton totals** Assumes first 3 weeks setup mode while running with RHIC - not counted toward integrated proton totals# Engineering Run
LEP Quads
http://www-ap.fnal.gov/~bcbrown/Sources/LEP_Quad_Info.html