Preliminary Airworthiness

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Preliminary Airworthiness

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1. Preliminary Airworthiness. Design Review for FIFI LS ... Engineers: H. Dohnalek (Design engineer, cryo/mechanics) G. Kettenring (Support engineer, FE modeling) ... – PowerPoint PPT presentation

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Title: Preliminary Airworthiness

1

Preliminary Airworthiness
Design Review for FIFI LS
(Field-Imaging Far-Infrared Line Spectrometer)
MPE
15 December 1998

Overview
Albrecht Poglitsch
MPE
15 December 1998

3
The FIFI LS Team

MPE Garching
PI Albrecht Poglitsch
CoIs Norbert Geis (Instrument Scientist)
Reinhard Genzel (MPE director)
Leslie Looney (Project Scientist)
Dieter Lutz
Linda Tacconi
Engineers H. Dohnalek (Design engineer,
cryo/mechanics)
G. Kettenring (Support engineer, FE
modeling)
J. Niekerke (Electrical Engineer, control
electronics)
G. Pfaller (Head of MPE machine shop)
M. Rumitz (Electrical engineer, readout
electronics)
H. Wang (Electrical engineer, control SW/HW)
Students Dirk Rosenthal (Detector development)
Walfried Raab (Cryostat definition, grating,
optics)
Alexander Urban (Detector readout testing)

4
The FIFI LS Team (cont.)

Univ. of Jena
CoI Thomas Henning
Student Randolf Klein (Software user
interface, data analysis)

5
FIFI LS Overview

PI Instrument for SOFIA
Wavelength ranges 42-110 mm 110-210 mm
Resolution 0.03-0.1 mm ( 175 km/s)
Instantaneous spectral coverage 1300 - 3000 km/s
Two 2516 GeGa photoconductor arrays
55 (spatial pixels) 16 (spectral channels)
Built by MPE Garching / Univ. Jena, Germany

6
System Overview
7
FIFI LS Instrument
8
FIFI LS Instrument
9
Instrument
10
Instrument

Cryostats and vacuum vessel built from Aluminum
5083 (AlMg4.5Mn) (TBD for vacuum vessel)
Indium sealed stainless steel necks
Work surfaces attached to bottom of cryostats
Work surfaces are not part of cryostats
Work surfaces connected via fiberglass tabs
Optic components mounted on work surface and
surrounded by sheet aluminum cryogenic shields

Schedule
Norbert Geis
MPE
15 December 1998

12
FIFI LS Schedule
13

Functional Hazard Analysis I
Alexander Urban
MPE
15 December 1998

14
Analysis Overview

I.Cryogenic Issues
1.Quiescent cryogen boil-off
Cabin oxygen goes from 21 to 20.7
2.Rapid cryogen boil-off, worst case
Cabin oxygen goes from 21 to 19.5
3.Vacuum vessel overpressure
Use room temperature pressure relief devices
4.Cryogen can overpressure
Use double neck design with warm pressure relief
devices

15
Analysis Overview

II.Structural Issues
5.Estimated Masses
Total weight including cart 595 kg
Total weight w/o cart 490 kg
6.g-loading
7.Containment analysis
8.Structural analysis
Finite Element analysis will be performed
9. Lasers and Gases
Possible use of class IIIb or less alignment
laser
No noxious gases used in FIFI LS

16
Cryogen Boil-off

1.Quiescent Cryogenic Boil-Off
Assumptions
Cabin volume 866 m3 (30000 ft3)
Must have O2 ³ 19.5 of cabin air
8 hours flight
Gas generation rate
1l LHe produces 0.7 m3 gaseous He at room T, P
1l LN2 produces 0.65 m3 gaseous N2 at room T, P
36l LHe (main LHe cryostat) estimated hold time
75 h gt 0.48 l/h
2.8l LHeII (HeII cryostat) pumping time 18 h gt
0.15 l/h
30l LN2 estimated hold time 29 h gt
1.03 l/h

17
Cryogen Boil-off

For 8 hour flight, total boil-off is
(0.48 l/h)(8h) 3.8l LHe gt 2.7 m3 gaseous He
(0.15 l/h)(8h) 1.2l LHeII gt 0.8 m3 gaseous He
(1.03 l/h)(8h) 8.2l LN2 gt 5.3 m3 gaseous N2
Corrected for reduced pressure in cabin (4/3 V0)
4.7 m3 He and 7.0 m3 N2
Impact on cabin oxygen is
21 (1 - 11.7/866) 20.7
This is above the minimum of 19.5 and assumes no
ongoing recirculation

18
Cryogen Boil-off

2.Rapid Cryogen Boil-Off After Loss of Vacuum
Assumption
39l LHe and 30l LN2 boil-off instantly
Gas generation rate
39l LHe produces 27.3 m3 gaseous He at room T, P
30l LN2 produces 19.5 m3 gaseous N2 at room T, P
Corrected for reduced pressure in cabin (4/3 V0)
36.4 m3 He and 26 m3 N2
Effect on cabin O2
21 (1 - 62.4/866) 19.5
This fulfills the requirement of 19.5 and
assumes no ongoing recirculation

19
Vacuum Vessel Overpressure

3.Vacuum Vessel Overpressure
Vacuum vessel is not strong enough to contain all
cryogen at room temperature
Warm pressure relief devices on vacuum vessel
Commercial spring-loaded relief device
Opens at 0.1 bar (TBD) differential
pressure

20
Cryogen Vessel Overpressure

4.Cryogen Vessel Overpressure
None of the cryogen vessels are strong enough to
contain all cryogen at room temperature
LN2 Vessel
Two independent necks
Bleed valve at one neck
Two warm pressure relief devices at other neck
opens at 0.1 bar (TBD) and 0.5 (TBD) differential
pressure
No need for cold pressure relief device or double
neck insert
Main LHe Vessel and Auxiliary LHe Vessel
Use of double neck inserts

21
Double Neck Inserts

Two independent tubes to LHe cryostats
Total diameter of tubes
Main LHe Cryostat 2.6 cm
Auxiliary LHe Cryostat 1.6 cm
One way valves are at room temperature
Insert removed during LHe transfer (on ground)
Red tag procedure guarantees installation of
double neck inserts before flight
During pumping on LHe
Additional warm pressure relief device in pump
line if necessary

22
Double Neck Inserts
23
Double Neck Insert

He Boil-Off
Maximum boil-off in case of vacuum failure
Assume
Heat input of 1W per cm2 of cryostat wetted by
LHe ()
Total surface of LHe (LHeII) cryostat is 7500 cm2
(1300 cm2)
gt total heat input is 7500W (1300 W)
Temperature of outflowing gas 6 K
Density of He gas at 6 K is 8 kg/m3
1W heat input generates 6.210-3 l/s of He gas
gt total generated volume of He gas is 47 l/s (8
l/s)
() W. Lehmann, G.Zahn, Safety Aspects for LHe
Cryostats and LHeTransport containers, ICEC 7
Procs., 1978,569-579

24
Double Neck Insert

Characterization of Flow
Assumption Neck is dominant impediment to flow
Maximum velocity of flow is speed of sound
Sound speed in He gas at 6 K is 145 m/s
Assume
Cross section of neck is 5.3 cm2 (2 cm2)
Mean velocity of flow is (generated gas)/(cross
section of neck)
(0.047 m3/s)/(5.310-4 m2) 89 m/s (40
m/s)
gt velocity of flow is 60 (28) of sound speed
Viscosity of He gas at 6 K is 210-6 Pas
Reynolds number in tube is 9106 (2.6106)
gt Flow in neck is turbulent

25
Double Neck Insert

Pressure Rise
Pressure in LHe cryostat is p1 a (a2
p22)1/2 ()
p2 ambient pressure 105 Pa
a (llrv)/(2d)
Tube drag number l 7.2310-3 (8.610-3)
Length of neck l 0.23 m
Mean velocity of flow v 89 m/s (40 m/s)
Diameter of neck d 2.6 cm (1.6 cm)
Pressure in LHe cryostat is 1.017105 Pa
(1.007105 Pa) giving a differential pressure of
0.017 bar (0.007 bar)
() According to Willi Bohl,Technische
Strömungslehre, Vogel-Verlag, 1978

Functional Hazard Analysis II
Walfried Raab
MPE
15 December 1998

27
Mass Budget

5. Estimated Masses
Vacuum vessel 259 kg
Cryostat mount 50 kg
Electronic boxes 30 kg
Cart 105 kg
Optics 20 kg
Cryogen vessels N2 84 kg
(including Cryogens) LHe (4K) 45 kg
LHe (2K) 1.4 kg
Total weight 595 kg
Total weight w/o cart 490 kg

28
Center of Gravity

550 mm from TA flange
along beam
400 mm above beam axis

29
g-Loading

6. g-Loading
Mass of mounted Instrument (m) 490 kg
Thickness of FIFI LS-flange (t) 20 mm
Number of bolts (n) 13
Bolt circle diameter (Bc) 990 mm
Bolt diameter (Dbolt) 12 mm
Number of shear pins 2(4)
Shear pin diameter (Dpin) 25.4 mm
Shear pin circle diameter (Dpi) 990 mm
According to MIL-HDBK5G using the A-Basis for
Aluminum 5083
Ultimate shear strength (FSu) 11500 N/cm2
Ultimate tensile strength (Ftu) 18390 N/cm2
Bearing yield stress allowable (Fbru) 27560
N/cm2

30
Nasmyth Flange
31
Nasmyth Flange
32
Flange Failure at Pin Inserts

Flange failure modes at pin inserts are
a) bearing failure and
b) flange failure in tension
Assumptions for both scenarios
Entire shear load is reacted on two pins
Highest tension is reacted on 3 and 9 oclock
pins
Relevant emergency loads are 5g upward and 6g
downward
Maximum load is 490 kg (6g) gt 29400 N
Tension load per pin is 14700 N

33
Bearing Failure

a) Bearing Failure
Failure mode is yielding of the contact area
between the pin and the flange with deformation
of the flange material
Calculation of bearing failure
Abr bearing area 2.2 cm x 1.7 cm 3.74 cm2
fbr tensile stress 14700 N/3.74 cm2 3930
N/cm2
M.S. (Fbru/fbr) - 1 (27560/3930) - 1 6

34
Flange Failure in Tension
SI flange
dowel pin
35
Flange Failure in Tension

b) Flange Failure in Tension
Failure mode is rending of the flange material at
the smallest cross section
Calculation of Flange Failure
ft tensile stress P/A
P tension load 14700 N
A area in tension (13.5)(2) cm2 27 cm2
ft 14700/27 544 N/cm2
M.S. (Ftu/ft) - 1 (18390/544) - 1 33

36
Bolt Hole Shear Tear-Out

Two basic types of bolts
Instrument bolts (2)
barrel nuts in instrument ribs
Cradle bolts (11)
use of caged nuts provided
by observatory

37
Bolt Hole Shear Tear-Out

Flange material needs to react to the forward
loading and the moments created by vertical and
lateral loads
Forward load
Equally divided over all 13 bolts assuming
9 g-loading
Pf forward shear load per bolt
490 kg (9g)/13 3390 N
Moments created by vertical load
Highest at topmost bolts
Reacted equally on 2 instrument bolts
Pv moment due to vertical load per bolt
Pv 490 kg (6g)(55/40)/2 20200 N
gt Vertical loading yields much higher bolt load

38
Bolt Hole Shear Tear-Out

Instrument Bolts
Barrel nut shear tear-out
Pv shear load 490 kg (6g)(55/40)/2 20200 N
Abr shear area Dpinl 3cm5cm 15 cm2
fbr tensile stress Pv/Abr 20200 N/15 cm2
1350 N/cm2
M.S. (Fbru/fbr) - 1 (27560/1350) - 1 19.5

39
Bolt Hole Shear Tear-Out

Instrument Bolts
Rib failure in tension
Pv tension load 20200 N
As tension area (5cm - 3cm) 5cm 10 cm2
fs tensile stress Pv/As 20200N/10cm2 2020
N/cm2
M.S. (Fsu/fs) - 1 (11500/2020) - 1 4.7

40
Bolt Failure

Cradle bolts 1/2, provided by observatory
Instrument bolts M12, provided by team
steel alloy 10.9 57400 N ultimate strength
Highest load on single instrument bolt is 20200 N
M.S. (57400/20200) - 1 1.8

41
Bolt Hole Shear Tear-Out

Cradle bolts
Forward load
Equally divided over all 11 bolts assuming 9
g-loading
Pf forward shear load per bolt 490 kg (9g)/11
4000 N
Moments created by vertical load
Highest at topmost bolts
Reacted equally on 2 bolts
Pv moment due to vertical load per bolt
Pv 490 kg (6g)(55/60)/2 13500 N
gt Vertical loading yields much higher bolt load

42
Bolt Hole Shear Tear-Out

Cradle bolts
fs tensile stress Pv/As
Pv shear load 13500 N
As shear area Dboltpt 1.2 cmp2 cm
7.54 cm2
Dbolt bolt diameter, t flange thickness
fs 13500/7.54 1790 N/cm2
M.S. (Fsu/fs) - 1 (11500/1790) - 1 5.4

43
Containment Analysis

7. Containment Analysis
Loose Objects inside the vacuum vessel cannot
attain the gate valve
Most parts are too big to fit through cryostat
window
Vacuum tight polyethylene window
All screws inside boresight box secured by wires
or equivalent

44
Structural Analysis

8. Structural Analysis
Not completed as of 15 December 1998
Finite element analysis will be made for critical
items

45
Lasers and Gases

9. Lasers and Gases
No noxious Gases used in FIFI LS
Possible use of class IIIb or less alignment laser

Electrical Hazard Analysis
Leslie Looney
MPE
15 December 1998

47
Electronic System Overview

Instrument mounted electronics will be packaged
within aluminum enclosures
Cables to/from cryostat will be internal to
enclosure
All high speed signals will be on fiber
All copper cables will be shielded with overall
braid
All external connectors will be military style
when appropriate
All systems will be properly shielded, fused, and
grounded

48
Electronic System Overview

Teflon or Tefzel insulated wire will be used in
custom electronics and interconnects
Battery system will be used to insure proper
shutdown of read-out electronics

49
Electronics Overview
50
Warm Read-Out Electronics

Two aluminum enclosures mounted on instrument
(one for each detector array)
Contains amplifiers, multiplexers, and A/Ds
All electronics are custom
No high speed signals on copper cables between SI
rack and PI rack 4 MHz output signal on fiber
Clock (2 MHz on coax from SI rack to SI 10 kHz)
and Sync ( 0.6 kHz) signals from SI rack
End of scan (EOS) signal ( 0.6 kHz) to SI rack
DC power on Tefzel cable (24 V _at_ 3A 12 V _at_ 3A)
with a battery backup to insure proper shutdown

51
Grating Encoder

Two aluminum enclosures mounted on instrument
(one for each detector array)
Contains grating position electronics and medium
voltage power to control PZTs
All custom electronics
Power supplied on Tefzel insulated cable

52
Guiding Camera and Driver

COTS CCD camera (and COTS camera driver, TBD) in
aluminum enclosure mounted on instrument
Fiber optic link to dedicated COTS PC computer at
PI rack
BNC coax link to monitor in PI rack/video
distribution system
PC computer will control guiding camera and
receive data output
PC computer linked to VX real-time computer in PI
rack

53
Master Clock

A programmable ( 2 MHz) frequency standard that
is used to derive other clock standards in
instrument
Sends clock signals ( 16 kHz) to the Controller,
Grating Driver, Chopper Driver, and K Mirror
Driver
Sends clock ( 10 kHz) and sync signals ( 0.6
kHz) to both detectors
Mounted in SI rack
All connections are Teflon insulated shielded
copper cables

54
Mechanism Drivers

Custom electronic drivers for Chopper, K Mirror,
and two Gratings
Commanded by the controller
Aluminum enclosures in the SI rack
Teflon insulated, shielded cable used for signal

55
Hardware Controller

Hardware controller in an aluminum enclosure in
SI rack
Commanded by the VX real-time computer
Controls the Master Clock frequency and sync
signals
Controls the Grating, Chopper, and K Mirror
Drivers

56
Computers

COTS VX Real Time computer in VME crate at PI
rack
Primary control computer
Data from both detectors received via fiber cable
Performs some data processing
Commands Controller via shielded copper cables
Communicates to Windows NT workstation via
Ethernet bus
COTS Windows NT computer in VME crate at PI rack
Used at SI rack by personnel to monitor SI
Update of instrument status
Detector data inquires
Data from camera guider through the PC
Sends request to the TA control through the MCCS

57
Batteries

Batteries used to ensure proper shutdown of
sensitive read-out electronics.
Battery size and type TBD
Batteries will be mounted in SI rack in
containment enclosure

Stress Analysis
Norbert Geis
MPE
15 December 1998

59
Stress Analysis Cryostat

Four components need to be analyzed
Vacuum container
Nitrogen vessel
Main Helium vessel
Auxiliary Helium vessel
Preliminary Analysis with Structural formula
First article testing on above components is
planned
No certification of welding
Witnessed burst-pressure test
Finite Element Analysis using Pro/Mechanica will
be performed on components which are impractical
to test

60
Vessel Design/Analysis

Avoid sophisticated analysis and certification of
electron beam welding shop by witnessed burst
test of all vessels to 3 times the maximum
operating (differential) pressure
Maximum operating pressure defined by relief
valves, including margin for tolerance in relief
pressure
Verify design with analytical calculation / FEM
analysis to withstand burst test without
permanent deformation
Operating differential pressure ( margin) for
vacuum vessel 0.1 (0.05) bar
nitrogen vessel 1.1 (0.05) bar
main helium vessel 1.1 (0.05) bar
auxiliary helium vessel 1.1 (0.05) bar

61
Vacuum Container

Material (TBD) certified 5083 Aluminum (Al Mg
4.5 Mn)
Light weight construction
Consists of 3 main parts
Top shell
Middle part
Base shell
Each main part milled
O-ring seals between main parts

62
Vacuum Container
top shell
middle part
base shell
63
Vacuum Container Analysis
1bar

Top shell Dimensions
length l 860 mm
loaded area
A 1376 cm2
pressure 1 bar

64
Vacuum Container Analysis

Highest stress occurs at top shell
Stress analysis on cross bar
f tensile stress M/W
M bending moment ql2/8
q Ap/l 16 kp/cm
M (16)(86)2/8 kpcm 147920 Ncm
W moment of resistivity I/c 26 cm3
I Moment of inertia c distance from neutral
axis
f 147920/26 5690 N/cm2
M.S. (17430/5690) - 1 2
All formulas from Formeln der Technik, Heinrich
Netz, G. Westermann, 1960

65
Nitrogen Vessel

Material 5083 Aluminum (AlMg4.5Mn)
Eccentric cylindrical shape
Main body milled
Top plates electron beam welded to main body
Dimensions
Outer diameter 830 mm
Inner diameter 348 mm
Height 109 mm
Volume 30 l

66
Nitrogen Cryostat
67
Nitrogen Vessel

Structural analysis is applied to weakest cross
bar
Dimensions
length l 210 mm
width b 140 mm
assumed pressure p 3.5 bar

68
Nitrogen Vessel

f tensile stress M/W
M bending moment ql2/8
q Ap/l 49 kp/cm
M (49)(21)2/8 kpcm 27000 Ncm
W moment of resistivity 3.6 cm3
f 27000/3.6 7500 N/cm2
M.S. (18390/7500) - 1 1.5

69
Main Helium Vessel

Material 5083 Aluminum (AlMg4.5Mn)
Dome shaped to enhance pressure stability
made on lathe from single block
Base plate electron beam welded to dome
Dimensions
Diameter 560 mm
Max. Height 227 mm
Volume 36 l

70
Main Helium Vessel
71
Main Helium Vessel

Dome Shape
Wall thickness t 0.5 mm
Constructed with two overlapping radii
Structural Analysis applied to three critical
Points
A Point at base plate
B Intersection of the
radii R1 and R2
C Point on radius R1

p 3.5 bar
72
Main Helium Vessel

Two independent directions of stress on surface
meridian stress
horizontal stress
For each of the points A,B,C the higher stress is
considered
Point A fm gt fh
Point B fm lt fh
Point C fm fh

73
Main Helium Vessel

Stress at point A
fA meridian tensile stress pR0/2t
fA (3.5)(28)/2(0.5) kp/cm2 980 N/cm2
M.S. ( Ftu/fA) - 1 (18390/980) - 1 17.8
Stress at point B
fB horizontal tensile stress pR1(2-R1/R2)/2t
fB (3.5)(86)(2-86/16) /2(0.5) kp/cm2
10150 N/cm2
M.S. ( Ftu/fB) - 1 (18390/ 10150) - 1 0.8
Stress at point C
fC meridian tensile stress pR1/2t
fC (3.5)(86)/2(0.5) kp/cm2 3010 N/cm2
M.S. ( Ftu/fC) - 1 (18390 /3010) - 1 5.1

74
Main Helium Vessel

Circular Base Plate
Dimensions
Radius R0 280 mm
Height h 30 mm
fbp tensile stress 1.24 pR02/h2
fbp 1.24(3.5)(28)2/(3)2 kp/cm2 3780 N/cm2
M.S. (Ftu/ftp) - 1 (18390/3780) - 1 3.9

75
Auxiliary Helium Vessel

Material 5083 Aluminum (AlMg4.5Mn)
Closed cylinder
Top and base plate electron beam welded to
cylindrical walls
Dimensions
Vessel radius R 146 mm
Vessel height H 213 mm
Volume 1.8 l

76
Auxiliary Helium Vessel
p 3.5 bar
77
Auxiliary Helium Vessel

Circular Top Plate
Top plate thickness ttp 12 mm
ftp tensile stress of top plate 1.24 pR2/ttp2
ftp 1.24(3.5)(7.3)2/(1.2)2 kp/cm2 1606 N/cm2
M.S. (Ftu/ftp)-1 (18390/1606) - 1 10.5
Circular Base Plate
Base plate thickness tbp 20 mm
fbp tensile stress of base plate 1.24
pR2/tbp2
fbp 1.24(3.5)(7.3)2/(2)2 kp/cm2 578 N/cm2
M.S. (Ftu/ftp) - 1 (18390 /578) - 1 30.8

78
Auxiliary Helium Vessel

Cylindrical Walls
Cylinder wall thickness tcyl 2 mm
fcyl tensile stress in vessel wall pR/tcyl
fcyl (3.5)(7.3)/0.2 1278 N/cm2
M.S. (Ftu/fcyl) - 1 (18390 /1278) - 1 13.4

79
Composite Material Tabs

Made from GFRP/CFRP (TBD)
Provide thermal isolation and precise positioning
for cryogen vessels
Three types of tabs
LN2-tabs between Vacuum Vessel and LN2 plate
LHe-tabs between LN2 plate and LHe plate
LHeII- tabs between LHe plate and LHeII plate
Number of tabs 4 of each type
Failure of tabs would impair instrument
performance and lead to increased cryogen
boil-off
Load is highest on LN2-tabs
Structural Formula Analysis shown here as an
example

80
Example LN2-Tabs

LN2-Tab Dimensions

LN2 tab
LHe tab
LHe II tab
81
Example LN2-Tabs

Tab shear failure
Failure mode is shear of the tab along width
9g forward load is applied on two tabs
Dimensions
Width w 9.5 cm
Effective height or distance between bolt holes h
4.2 cm
Thickness t 0.2 cm
fs shear stress per tab ½(M/W)
M bending moment 150 kg (9g)4.2 cm 56700
Ncm
W moment of resistivity tw2/6
(0.2)(9.5)2/6 3 cm3
fs (1/2)(56700/3) 9450 N/cm2
M.S. (Fsu/fs) -1 (27560/9450) - 1 1.9

82
Example LN2-Tabs

Tab buckling
Failure mode is buckling of the tab
6g downward load is applied on four tabs
Ultimate buckling stress allowable
Fbu ultimate buckling stress kE(t/l)2
k buckling factor 8.9 (According to DIN
4114)
E elastic modulus of fiberglass at 4 K
7.5105 N/cm2
Fbu (8.9)(7.5105)(0.2/9.5)2 2950 N/cm2

83
Example LN2-Tabs

Buckling stress
Tab cross section A 1.9 cm2
F force per tab 150 kg (6g)/4 2250 N
f buckling stress F/A 1180 N/cm2
M.S. (Fbu/fb) - 1 (2950/1180) -1 1.5

84
Hard Stops

Fiber tabs from non-certified material
Hard stops at each fiber tab
Made from 5083 Aluminum (AlMg4.5Mn)
Hard stops treated as nominal support system
Failure of tabs under limit loads considered
non-critical
Stops are recessed into work surfaces to take up
shear forces
Finite Element Analysis of hard stops will be
performed
Analysis with structural formulas shown here
Failure modes considered
Shear tear under 9g forward load
Failure in tension under 9g forward load
Shear tear under 6g downward load
Failure in tension under 6g downward load

85
Hard Stops
LN2 plate

hardstop

tab
LHe plate
86
Hard Stops Analysis

Analysis for 9g forward load
Assume
Main LHe container and auxiliary LHe container
accelerating at 9g for a distance of Lr 0.5 mm
Mass of object mobj 56 kg
v speed at hard stop (29gLr)1/2 0.3 m/s
T kinetic energy ½mobjv2 260 Ncm

87
Hard Stops Analysis

Shear Analysis (9g forward)
Dimensions of hard stop
bstop width 2.4 cm
wstop thickness 3.5 cm gt Shear area Astop
8.4 cm2
hstop height 1 cm
Assume
Shear load is equally divided on two hard stops
GAl Shear modulus of Aluminum 0.385E
2,772,000 N/cm2
Fstop force on stops (1/nstop)(2TobjAstopGA
l/hstop)1/2 55000 N
fshear shear stress Fstop/Astop 6550 N/cm2
M.S. (Fsu/fshear) - 1 (11500/6550) - 1 0.7

88
Hard Stops Analysis

Failure in Tension (9g forward)
fbend bending stress Mstop/Wstop
Mstop bending moment Fstophstop 55000 Ncm
Wstop moment of resistivity bw2/6
Wstop (2.4)(3.5)2/6 4.9 cm3
fbend 55000/4.9 11220 N/cm2
M.S. (Ftu/fbending) - 1 (18390/11220) - 1
0.5

89
Hard Stops Analysis

Analysis for 6g downward load
Assume
Main LHe container and auxiliary LHe container
accelerating at 6g for a distance of Lr 1 mm
Mass of object mobj 56 kg
v speed at hard stop (26gLr)1/2 0.35 m/s
T kinetic energy ½mobjv2 343 Ncm

90
Hard Stops Analysis

Shear Analysis (6g downward)
Dimensions of hard stop
bstop width 2 cm
wstop thickness 1.5 cm gt Shear area
Astop 3 cm2
hstop height 0.4 cm
Assume
Shear load is equally divided on eight hard stops
GAl Shear modulus of Aluminum 0.385E
2,772,000 N/cm2
Fstop force on Stops (1/nstop)(2TobjAstopGA
l/hstop)1/2 15000 N
fshear shear stress Fstop/Astop 4975 N/cm2
M.S. (Fsu/fshear) - 1 (11500/4975) - 1 1.3

91
Hard Stops Analysis

Failure in Tension (6g downward)
fbend bending stress Mstop/Wstop
Mstop bending moment Fstophstop 6000 Ncm
Wstop moment of resistivity bw2/6
Wstop (2)(1.5)2/6 0.75 cm3
fbend 6000/0.75 8000 N/cm2
M.S. (Ftu/fbending) - 1 (18390/8000) - 1 1.3

Miscellaneous Items
Dirk Rosenthal
MPE
15 December 1998

93
Cryostat mount

Light weight construction made of 5083 Aluminum
(AlMg4.5Mn)
No welding
All components joined by rivets, bolts and pins
Just mechanical support
Pressure seal provided by stainless steel bellows
Finite Element Analysis will be performed

94
Cryostat mount
95
Cryostat mount
96
Pressure Coupling Device

Provides pressure seal between FIFI LS and gate
valve
Double O-ring sealed snout
Stainless steel bellows
Aluminum tube to protect bellows from mechanical
damage

97
Pressure Coupling Device
98
Boresight box

Splits off visible from IR light
Optically aligns FIFI LS to Telescope axis
Contains
Dichroic filter
Optical mirror
Adjustment mechanisms
Optical lens ( pressure window)
Pressure inside is stratospheric pressure
Pump port required
Sealed off before take-off

99
Boresight box
polyethylene window
pressure coupling device
mirror
dichroic filter
lens
O-rings
O-rings
100
Electronic Enclosures

Six electronic enclosures mounted to instrument
Working on appropriate mounting techniques
Will use certified materials
Finite element analysis of stresses at critical
areas for g-loading will be performed

101
Electronic Enclosures
102
Electronic Enclosures (cont.)
103
SI Cart

Used to transport FIFI LS into airplane and to
lift onto (already installed) cryostat mount
(cradle)
Four rotatable and securable wheels with brakes
Hand-operated lifting mechanism
Four lever arms
Threaded control rods
In transport configuration FIFI LS bolted to cart
Low center of gravity gt stable configuration
Technical data
Mass 105 kg
Wheel track 750 mm
Overall center of gravity above ground 970 mm

104
SI Cart
105
SI Cart
106

FIFI LS Operations
Dirk Rosenthal
MPE
15 December 1998

107
FIFI LS Operations

Document will be produced to govern instrument
set-up and maintenance
Steps for routine, ongoing inspections
Precool safety check-list
Installation and removal procedures
On-board cryogen refill procedures
In-flight operations
Procedure for access to SI/SI-Rack during flight
Warm-up process

108
Operations Preparation

Arrival at destination
Check shipping crates for coarse damage
Open-up cryostat
Visual inspection of entire system
Inspect cryostat window
Check for frayed cables, loose hardware, etc.
Check for missing system components
Check GFRP/CFRP supports
Inspect batteries
Re-assemble cryostat

109
Operations Cool down

Check for water in cryogen cans
Remove if necessary
Pump out vacuum space
Use roughing pump to reach coarse vacuum
Use turbo pumps to reach end vacuum
Leak check vacuum vessel and cryogen cans on 1st
cool-down of each flight series
Transfer LN2 into LN2 cryostat
Transfer LN2 into LHe cryostat
Refill both cans when empty
Remove N2 from LHe cryostat
Transfer LHe in LHe cryostat
Refill LHe and LN2 cans as needed

110
Operations System checks

Check out electronics
Verify detector health
Verify functionality of mechanisms
Perform laboratory calibration measurements

111
Operations SIL

Attach system to simulator
Use SI cart to bring cryostat to mounting plate
Installation procedure as on airplane
PI rack and SI rack needed (SI rack close to
flange)
Perform alignment and functionality tests on
simulator
Remove system from simulator
Disconnect cables, fiber links, pump lines
Transfer cryostat to SI cart

112
Operations TA

Install cradle to Nasmyth flange
Cradle can be lifted/positioned manually
Fasten nuts bolts
Install FIFI LS on cradle and flange
Use installation SI cart to lift and position
instrument on cradle
Push into docking position and insert tighten
screws
Connect all cables and fiber optics links
Perform verification tests with MCCS
Transfer LN2 and LHe as necessary
Bring LN2 and LHe storage dewars on plane
Fill cans to capacity
Perform daily inspection of system for anything
unusual or noteworthy

113
Operations In-flight

Access to instrument during routine operations
Turn filter wheel
Done by turning knobs
Reaching over safety rail probably OK
Caged telescope probably OK, but not desired
Troubleshooting (diagnostics)
Sometimes requires access inside safety rail
Examples
Swapping electronic boards (inside)
Reseating components (inside)
Cycling power (outside)
Probing voltages (some of both)
Need to establish guidelines for whats allowed

114
Operations End of flight series

Disconnect all cables and fiber optic links at
end of observing run
Remove system from telescope
Remove FIFI LS from cradle and flange with cart
Remove cradle from Nasmyth flange
Return system back to lab
Perform any post run checks if necessary
Allow system to warm up
Place one way valves on both fill ports to
prevent water condensation into cryogen cans
Place into shipment crates

115