Requirements exist for an extremely stable, high performance, all-weather tethered aerostat system. This requirement has been satisfied by a 250,000 cubic foot captive buoyant vehicle as demonstrated by over a year of successful field operations. This achievement required significant advancements in several technology areas including composite materials design, aerostatics and aerodynamics, structural design, electro-mechanical design, vehicle fabrication and mooring operations. This paper specifically addresses the materials and structural design aspects of pressurized buoyant vehicles as related to the general class of Lighter Than Air vehicles

Witherow, R. G.

English

NASA Technical Reports Server

I 068 ¢
TECHNOLOGY UPDATE TETHERED AEROSTAT
STRUCTURAL DESIGN AND MATERIAL DEVELOPMENTS
i_ Robert G. Witherow*
I .
" ABSTRACT: Requirements exist for an extremely stable,
high performance, all-weather tethered aerostat system.
This requirement has been satisfied by a 250,000 cubic
foot captive buoyant vehicle as demonstrated by over a
year of successful field operations. This achievement
_i required significant advancements in several technology
areas including composite materials design, aerostatics
and aerodynamics, structural design, electro-mechanical
design, vehicle fabrication and mooring operations. This
"_: paper specif cally addresses the material_ ant structural
design aspects of pressurized buoyant vehicles as related
to the general class of Lighter Than Air vehicles--the
subject of this Workshop.
L-
_ INTRODUCTION
_'_.
_, In the late 60's, Sheldahl, under sponsorship of ARPA {Advanced Research
Projects Agency), undertook a project to design, develop and fabricate
_ three 200,000 cubic foot tethered aerostats under the direction of the ;Air Force Range bleasurement Laboratory (RML). Starting with the
limited balloon and non-rigid airship technology that existed at the
::, time, considerable effort was devoted to extend the applicable ad-
vanced design and analytical techniques already used by aerospace
engineers to the design of aerodynamically shaped, buoyant, pressur-
ized vehicles. Despite the fact that the 250,000 cubic foot Captive
Buoyant Vehicle, which eventually evolved and is _-mplc, yed commerically
today by 'room (Tethered COMmunications, a division of Westinghouse -'
Electric Company), is to some extent a marvel of art, it represents a ,,
_' significant technological improvement over previous H'A vehicles in
;; terms of performance, reliability and ruggedness. The structures and
materials technology advancements played a dominant role in the suc-
cess of the aerostats being deployed worldwide today for communica-
: tions, monitoring, and surveillance applications.
} * Manager, Structures and Naterials Engineering, Sheldahl, Inc
Northfield, Minnesota, U.S.A.
'* f
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Figure A
250,000 CU. FT. AEROSTAT IN-FLIGHT/MOORED
I
OPERATIONAL/PERFCRbtANCE HISTORY
The CBV-250 is shown in flight aad moored in Figure A. Each aerc_tat
is completely rigged a-d checked out (including a proof pressure test)
at a hangar facility in Elizabeth City, North Carolina and _hen sent
to its operational site. The first CBV-250 was operationally de-
_loyed in the Bahamas in the summer of 1973 and has provided valuable
system design feedback since that time. The aerostat was flown in
all types of wbather typical of that climate including severe elec-
trical storms and a hurricane. In October of 1973, during Hurricane
t;ilda, winds exceeding 82 knots were sustained by the aerostat flying
at 3,000 feet with no apparent damage. Other experiences t'me and
again demonstrated the structural ruggedness, stability, and opera-
tional advantages of this vehicle. The CBV-25G and the CBV-350 with
payload capabilities of 4,1190 pounds and 6,000 pounds respectively
are compared in si:e in Figure BI.
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1976007927-615
Figure B1
AEROSTAT SIZE COMPARISON
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Figure B2
SAFE OPt_RATIONAL ZONE
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1976007927-616
m,i
" ! Figure Ct
MAJOR AEROSTAT SUBSYSTEMS
ENVIRONMENTAL REQUIREMENTS
The aerostats are being deployed in the Far East, the Mideast and
other parts of the world--requiring design to climatic extremes.
MIL-STD-210B has served as a valuable guide in establishing environ-
mental requirements. The aerostats are designed to sustain winds of
85 knots at i0,000 feet with a minimum structural safety factor of
2. Winds alofE at various worldwide locations are also depicted in
_ Figure B2indicating the safe operational envelope of these vehicles.
Temperature design criteria include the extremes from +120°F down
i to -40°F. A ten year life with minimal maintenance is required of
the major structural envelcpes, the hull and empennage. Other
design criteria include requirements for blowing sand, hail and
, lightning to enab.e around-the-clock operational capability.
PRIMARY SUBSYSTEMS
The major subsystems of the CBV-250 aerostat are depicted in Figure
C. Note the overall dimensions and general performance data. The
payload is accessibly housed in the windscreen.
AEROSTAT MATERIALS
The fabrics of construction are pictorially described in Figure D.
Most of the materials are composite adhesive bonded laminates of
TEDLAR PVF film, for weathering and UV stability, MYI.AR polyester
film for helium impermeability and shear s_rength, and Dacron poly-
ester plain weave cloth for the strength member. Urethane coatings
are used where excessive material flexing occurs such as the wind-
screen and ballonet.
PRESSURE CONTROL SYSTEM
Pressure sensors, compartmental valves, and blowers compris." the
pressure control system maintaining each main compartment _. _ome
level above freestream dynan, ic pressure, q, as shown in Figure li.
The power is supplied by two on-board 18 hp Sachs-Wankel rotary
c .robust ion engines coupled to a _t;_tic brushless generator with a
static voltage regulator.
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Figure F
AEROSTAT EMPENNAGE
EMPENNAGE
The aerostat Empennage* as i||ustrated in Figure F is the product of
a long-term development effo,t. The entire pressurized assembly is
quite larg_ and well aft on the hull--dictated by aerodyl,amic stability
considerations. Fin ribs run spanwise for maximum flexural and shear
stiffness and are quite unique--borrowing from the concept of" a uni-
_. form load distributing parabolic shape, and are laced with Dacron
cord. The aft hull is pressurized slightly above the empennage to
_ allow for natural curvature. The fins are guyed one to another to i
• prevent large rigid body rotations°
NOSE STRUCTURE
The nose strt_cture i11ustrated in Figure G is the primary load trans-
fer structure for the moored aerostat. A high stre:gth, light
weight tubular aluminum nose cone, and _6 a£uminum nose beams, which
are laced to the hull, react mooring load equivalent to 90 knot
surface winds based on a mooring dynamic analysis. The nose beams
transfer the load into the hull fabric as a shear load.
PAYLOAD ATTACHMENT
The gimbaled payload is suspended from a welded aluminum truss
structure laced to the underside of the hull. Tbe hull is at a
higher pressure than the windscreen to prevent the interface from
wrinkling and going fiat.
SUSPENSION LOAD PATCH
The primary load carrying suspension patches also utilize the para-
bolic scallop design approach to uniformly distribute the 2,500
Found maximum suspension line load into the hull fabric. The suspen-
sion lines are sized ba3ed on stiffness in addition to stre_gtk to
optimize distribution of the main tether load.
Patent pending.
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q976007927-6q9
F,gure G
LOAD ATTACHMENT HARDWARE,
,_ blATERl,xi.S FABRICATION
:. The Dacron cloth is supplied by speciality weavers and is "s_.t" by
: running the woven cloth through at: adhesive bath. This permits the
woven cloth rolls to bt shipped to Sheldahl, wherein they are combined
.; with the 'rEDLAR x MYI.AR x MYLAR tri-laminate USillg special purpose
; polyester adhesive.,:. A'I laminating variables are preci.-ely contrail ,d
resulting in a consistent product. Figures }l arid I show a laminator,
; the flying thread loom tused to manufacture structural tape), and
the weaving loom.
! AI!ROSTAT FABRICATION
The flexible material sheet goods are then accurately cut into
various shaped pat_els using full scale patterns, l'he panels are then
bonded together using specially designed thermal tt, pul:,e sealing
eqaipment, l'he ];allel-,o-p;nlel botld_ ;Ire constructtd ;J,_ butt .lOlllt',
'_ using a t_'o tape system--a struct' ,el taipe ,.',_ ti,v _n. ide ,llld ;l
'; weather protection fEZ)fAR cover t,J0e on the out._i,le.
/
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1976007927-620
Figure I
/_ROSTAT FABRICATION
•; REPRODUCIBILrI_OP TH_
6ao ORIGINALPAGE ISPOOR
1976007927-621
STRUCTURAL DESIGN CRITERIA
The aerostat is designed to operate in winds to 70 knots MSL and at a
constant q of 3.2 in. H20 aloft. At 70 knots, there is a minimam
;-. factor of safety of two on fabric stresses (both direct and shear) and
a factor of 1.5 on hull or fin buckling. Based on wind tunnel tests
the angle of attach,_(, was predicted to be_6 degrees and this has
%. been verified in flight tests. Additionally, the aerostat is designed _
to sustain 90 knot MSL winds with no structural safety factor; however,
; this requirement is less critical than the former. A dynamic mooring
loads analysis established the nose structure load criteria of 25,000 i
pounds axial and 13,000 pounds side loads. A minimum factor of 1.5 _-
is required on all metallic members. Tear propagation data for this _ '_particular material has bee,, experimentally derived and is summarized *
zn Figure J. During the checkout phase, each aerostat is thoroughly _ i
inspected for defects in the cloth such as burn marks; and, all suchdefects effecting more than 2-3 yarns are reinforced. Each aerostat _ :
_- is then proof pressure tested to equivalent 90 knot levels to insure _
that no design or fabrication defects remain. In-flight loads at 70 _ :
: knots are predicted to be less critical than prGof pressure loads--
:' hence a successful proof pressure test is evidence of a reliable
! vehicle. 1
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_Lt_ bE_T | _ No. OF ,_
; _ 1000 I_r_ _ 4
Figure J
CRITICAL _FECT LENGTH FOR TEAR PROPAGATION
OF SHELDAHL CBV-350A AEROSTAT
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1976007927-622
If J',
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STRUCTURAL ANALYSIS
The principal analytical tool used in the stress and deformation
'_ - analysis of fabric portions of the aerostat was the large scale finite
"" element computer program designated LDIDX, Large Deformation Analysis
of Three-Dimensional Structures Extended. The program accommodates
non-linear geometry behavior and orthotropic materials Additionally
,| • p
." the program is designed such that external loads (buoyancy, aero-
dynamic pressure, skin friction drag, tether lo_d, etc.) can be applied
, sequentially as they occur in service. Figure _ illustrates the gross
:_, finite element computer plot of a horizontal fin and the aerodynamic
'. pressure distribution on the fin as established by wind tunnel tests
!.
MATERIALS QUALIFICATION ,e
Every material used in Sheldahl's CBV-250 aerostat, from the hull and
_...._ ballonet composites to the seal tapes and T-tapes, is tailored to its f
specific task. Despite the fact that each material is designed to
different requirements, the design approach is the same: 1) define
_' the requirements, and 2) perform qualification tests on the condi-
tioned candidate materials. Figure L delineates the test equipment
necessary to condition and qualify these materials and also illus-
trates the specially designed biaxial cylinder test machine which is
used to determine the stress-strain characteristics of the composite
_ laminate used as input to the structural analysis.
,_
_e_mATr, D)
Figure X
AEROSTAT EMPENNAGE
AERODYNAMIC LOADS AND STRUCTURAL MODEL
632
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1976007927-623
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:_ t ......................................... "'_ _i_
,_ TECHNOLOGY ADVANCEHENT
_, , Figure M summarizes the more significant technological advances
_:,., relating to the design and fabricationof pressurizedbuoyant
I vehiclesas developedduring this program.
: Figure M _'
/ i SORRY OF TECHNOLOGY ADVANCES IN STRUCTURES AND MATERIALS
_I FOR LTA {lgEO'S TO 19741 "
IN lg60*S IN Ig74 IMPROVEMENT I,_
.BAS]C MATERIALS _Y
_ • NEATHERING LAYER HYPALON TEDLAR MAINTENANCE FREE ZO YEARLIFE AS OPPOSED TO ANNUAL 7
_ MAINTENANCE '_"
r
• GAS IMPERMEABLE LAYER URETMANE OR MYLAR FROM l,O TO 0.$ 1/m2/24 HR 4_
_p,_" NEOPRENE REDUCTION IN PERMEABILITY
_ COATING
STRUCTURAL CLOTH HIGH COUNT LOW COUNT GREATER TEAR STRENGTH, _
: NYLON OR DACRON DACRON SETTER DIMENSIONAL _
STABILITY
BIAS _RENGTH/ B_ASED NYLON/ MYLAR MEIGH_ REDUCTION OF 1-5
STIFFNESS LAYER DACRON CLOTH OZ/YD*
.Q
_" _TERIAL COMPOSITE
COMPOSITE NEIGHT I2.g OZ/YD 2 7.| OZ/YD 2 4or DECREASE
COMPOSITE STRENGTH 19S LRS/IN 225 LRS/IN 3OI INCREASE
_ . ADHESIVE IMPROVEMENTS PRIMARILY Fi._/FILM, GREATER PEEL, INTERPL_
ii COATINGS CLOTH/FILM SHEAR STRENGTH
STRESS-STRAIN UNIAXIAL BIAXIAL DETERMINE SIX CONSTITUTIVE
CHA_CTERIZATION INSTRON CYLINDER COEFFICIENTS OF COMPOSITE J_
".b
_ • MATERIALS CONDITIONING/ BASICALLY MANY SPECIAL RELATIVE COMPARISON OF
QUALIFICATION ASTM TESTS PURPOSE TESTS 14AT_RIAL CHARACTERISTICS
VEHICLE DESIGN
VEHICLE ENVIRONMENTAL LIMITED MIL-STD-21OB ENVIRONMENTAL REQUIREMENTS
REQUIREMENTS STANDARDS NASA-TMX-64S89 FOR WORLDWIDE OPERATIONS
THRU ALTITUDES OF INTEREST
COMPUTERIZED FINITE NONE LDSDX COMPI'-_R ALLONS GROSS AND FINE
ELEMENT STRUCTURAL AVAILABLE PRGGRA_ ELEMENT MODELING USING
ANALYSIS ORTItOTROFIC MATERIALS AND
AkqlTRARY LOADS.
LARGE, SHAPED, EITi:_n RIGID AERODYNAMICALLY INFLA_ED FIN SIMULATES A
STRUCTURALLY SOUND PANLLS OR SHAPED FINS NACA FIN PROFILE NITH
EMPENNAGE LIGHT kIND CHORDWISE AND SPAN_ISE
I NFI.AT/BLI. TAPLR
DESIGN'_
VEH|CLI. DYNAMICS LIMITEL _ COMPUII R PRO- PRFDIC1 IONS OF INFLIGItT
ANALY'fI'AL GRAMS PREUICT STABILITY. AND INFLIGHT
TI.CItNIQIIS DYNAMIC RFSPONSL AND MOORED DYNAH1C LOADS
VLtlICLL FABRICATION
SEALING MFTHODS IIAND lOOt MACIIINI IMPULSE, RF, AND TRAVELING
SIALID CONTROILLU NIILLL HEAT SLALLRS
SEALING
QUALITY CONTROL I. IMIILD lOOt Q.C. IN- PR_)F PRFSSURE FESTS
CIIELKS ON SPECTION AND VERIFY RELIABILITY OF
SFALS PRFSSURL TEST EVERY VLIIICLE
LOAD ATTACHML_TS U_RELIABLI ALL LOAD ATTACtl- VIRTUALLY ALL LOAD ATTACH-
PI_FORMANCI. MENTS REDLSIGNLD MENT METHODS ARE DESIGNED
OT EXISTING AND PROOF TESTED TO SPRLAD LOADS UNIFORMLY
AI FACIIMI NTS _N[O lllJl I
634 iLI,_['itL)I -, _ ]_ pOON
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1976007927-625
, /
AREAS FOR FURTHER MATERIALS RESEARCH
In terms of improving the material composites for aerostat_ and for
LTA vehicles in general, several areas require further research to
improve performance and provide a more reliable product. Included
are:
• Optimization of composite design in terms of strength and /
stiffness--tailored to a particular application at minimum
weight.
• Evaluation of KEVLAR as a potential replacement for Dacron
as the primary load carrying member.
te
• Develop fracture mechanics techniques applicable to
pressurized fabric structures, and evaluate weight tradeoffs
versus increased tear propagation strength.
¢
Also, improvements in puncture resistance, sand abrasion, flexing,
and thermal control would be beneficial for greater potential
utility of these vehicles.
SUMMARY
While it is quite evident that much of the technology described
herein is applicable to the design and development of airships, it Ls
not quite so obvious as to what form the initial vehicle shoult take.
If a minimum risk approach is contemplated, the following criteria
are suggested:
• A semi-buoyant hybrid airship using helicopters for lift-off
and in-flight control--interconnected by a rigid truss
structure supported a non-rigid aerodynamically shaped
pressurized hull.
• Attached to the hull for stability would be inflatable fins--
designed to buckle under extreme gust loads prior to
structural failure of the hull.
• Utilize the material composites and sealing techniques
described herein. Employ tear stop features.
• Use a ballonet/s--which has been proven, and results in
minimum hull pressure stresses.
• dtilize a pressure control system to regulate compartmental
pressures.
• Plan to proof pressure test every vehicle.
• Moor at bow--allowing the vehicle to weather vane.
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1976007927-626


Technology update: Tethered aerostat structural design and material developments

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