The role of heating from nuclear radiation in design of the NERVA engine is treated. Some components are subjected to very high gamma heating rates in excess of 0.5 Btu/cubic inch/sec in steel in the primary nozzle or 0.25 Btu/cubic inch/sec in aluminum in the pressure vessel. These components must be cooled by a fraction of the liquid hydrogen propellant before it is passed through the core, heated, and expanded out the nozzle as a gas. Other components that are subjected to lower heating rates such as the thrust structure and the disk shield are designed so that they would not require liquid hydrogen cooling. Typical gamma and neutron heating rates, resulting temperatures, and their design consequences are discussed. Calculational techniques used in the nuclear and thermal analyses of the NERVA engine are briefly treated

Courtney, J. C.

Hertelendy, N. A.

Lindsey, B. A.

English

NASA Technical Reports Server

Radiation Heating in Selected NERVA* Engine Components**
J. C. Courtney+, N. A. Hertelendy+, B. A. Lindsey+
AeroJet Nuclear Systems Company
Sacramento, California
The role of heating from nuclear radiation in design of the NERVA* engine
is treated. Generally, radiation heating is more restrictive in design than
material degradation considerations. Some components are subjected to very
high gamma heating rates in excess of 0.5 Btu_n3-sec in steel in the primary
nozzle or 0.25 Btu/in3-sec in aluminum in the pressure vessel. These com-
ponents must be cooled by a fraction of the liquid hydrogen propellant before
it is passed through the core, heated, and expanded out the nozzle as a gas.
Other con_ponents that are subjected to lower heating rates such as the thrust
structure and the disk shield are designed so that they would not require
liquid hydrogen cooling. Typical gamma and neutron heating rates, resulting
temperatures, and their design consequences are covered in this paper. The
calculational techniques used in the nuclear and thermal analyses of the NERVA
engine are briefly treated.
Most components in the NERVA engine (shown in
Figure l) must be designed to perform with high re-
liability in severe radiation environments. Radi-
ation heating in several key components will be con-
sidered in this paper.
Generally, radiation heating is more restric-
tive in design than material degradation, due to the
choice of material for each component. 1 The NERVA
engine uses a relatively small core with a very high
leakage fraction for both neutron and gamma radi-
ation. At full power operation (75,000 lbs thrust
and 1515 Mw reactor _ower_. ra_iatlo_-in_J_ h_t.
ing may exceed 0.5 BTU/in3-sec in parts of the
stainless steel nozzle, and may exceed 0.2 BTU/in 3-
_ sec in the aluminum pressure vessel. Heating rates
of this magnitude require that components be cooled
by the liquid hydrogen propellant before it is
passed through the core, heated, and expanded out
the nozzle as a gas.
As long as the component is part of the pro-
pellant feed system or the pressure vessel and
reactor assembly, liquid or gaseous hydrogen is
*The Nuclear Engine for Rocket Vehicle Application
(NERVA) program is administered by the Space Nu-
clear Systems Office, a joint office of the USAEC
and NASA. Aerojet Nuclear Systems Company is prime
contractor for the engine system and Westinghouse
Electric Corporation is principal subcontractor
responsible for the nuclear subsystem.
+Staff Members, Nuclear Scienc_ Section, Aerojet
Nuclear Systems Company.
**Public Release Approval: PRA/SA - SNPO-C, dated
2k November 1970.
available as a heat transfer agent. However, it is
desirable that some components be designed so that
they require no coolant, and thus do not influence
the dgsign of the propellant feed system. For
example, the thrust structure is to be designed as
an uncooled system. If a disk shield is required
for some manned missions, it should be designed to
operate without cooling. The thrust structure and
the disk shield are located forward of the pressure
vessel dome and are partially protected by a shadow
shield inside the pressure vessel. Many other com-
ponents forward of the dome, such as lines and
valves, are already part of the liquid hydrogen
propellant feed system and receive coolant during
normal operation.
UPPER THRUST STRUCTURE --
GIMBAL -- _
LOWER THRUST STRUCTURE --
DISK SHIELD _ _ TURBOPUMP ASSEMBLY
FIGURE 1
NERVA Flight Ensine ConflKuratlon
460
https://ntrs.nasa.gov/search.jsp?R=19720010009 2020-03-17T03:49:13+00:00Z
Gammaraysare far moreeffectivethanneutrons
in heatingmetalcomponentsfor theradiationleak-
agesfromNERVA.Typically,direct neutroninter-
actionscontributeabout4%of thetotal heatingin
the stainlesssteelnozzle. In thealtnninumpres-
surevessel,fast neutronscontributesome6%of
thetotal heatingoppositethecoremidplane.
Neutronsmustbeconsiderednot somuchfor their
direct heatingof metals,but becauseof their
importancein producingsecondarygammar diation.
Figure2 presentsthe fractionof gammaheatlngin
thenozzledueto secondarygammasproducedin the
nozzleassembly.Directneutronheatingis signif-
icant in onlytwocomponents,hegraphitenozzle
extensionandpartsof the diskshield.
Heatingratesin enginecomponentspresented
in this paperareappropriatefor the flight en-
vironment.Duringgroundtests, additionalradi-
ation heatingoccursin somecomponentsdueto
contributionsfromfacility-related sourcesand
facility scatter.2 Thecomponentsforwardof the
pressurevesselaredesignedto takeadvantageof
theprotectionaffordedby theinternal shieldin
the flight environment.Specialfacility shielding
is requiredto assurethat thesecomponentsarenot
overexposedin groundtests.
FIGURE 2
D STAINLE3 STEEL REGIC
| GRAPHITE !_qAMPOSITE R_ ]ION
iV'q
8 - eee
40 •
• •; •0
m •
i00 200 300 boo
DISTANCE FROM PRESSURE VESSEL-NOZZLE FLANGE (CM)
5OO
Flight environment heating rates are calculated
in detail throughout the engine system using a
variety of techniques. Coupled discrete ordinates-
Monte Carl_ techniques are used extensively. The
DASH coupling code 3 has been used to bridge DOT_._
with COHORT 5 for calculations of the nozzle radi-
ation environment and bridge DOT with DOT to calcu-
late heating within the disk shield. Extensive
point kernel calculations are used to check the
predictions of the more sophisticated methods.
Also, the point kernel codes, QAD°_ and GGG 7, are
used to predict the facility perturbation of the
ground test environment. Calculated volumetric
heating rates are input to thermal analyses. Pre-
dicted temperatures are necessary for subsequent
stress and reliability analyses of candidate com-
ponent designs.
A numerical differencing code, CINDA 8, is used
to predict temperatures throughout the components.
It is used to construct and analyze mathematical
models of any arbitrary one-, two-, or three-
dimensional representation of physical systems
governed by the Fourier equation with a source
term. The user constructs a thermal analog net-
work representing the system of interest. Non-
linear material properties and boundary conditions
may be simultaneously calculated as a function of
one or more independent variables. For cooled
components (e.g., the nozzle), CINDA is used to
calculate the steady-state temperatures using the
full power heating rates. For uneooled components
(e.g., the disk shield), a transient analysis is
conducted to yield the temperature as a function of
time.
Before the individual components are considered,
it should be emphasized that the NEEVA flight
engine design is in the preliminary design stage.
Both the engine layout and the design of individual
components, hence, the heating rates, have been
revised periodically. However, the techniques used
to calculate radiation heating and resulting tem-
peratures can be applied to any configuration and
every attempt is made to simplify the analyses re-
quired. The particular components and data pre-
sented in this paper were selected to illustrate
the analytical approach to radiation heating in the
NERVA engine.
461
Oneof themostimportantcomponentsin the
engineis thenozzleassembly.It consistsof a
metalprimarynozzlewith a graphiteextensionas
shownin Figure3. Currentlythe candidatepri-
marynozzlematerialsareCRES-347stainlesssteel,
HastelloyX, andA_C022-13-5.Thenozzleexten-
sion is to befabricatedfroma fibrousreinforced
graphitecompositematerial. Becauseof the intense
gammaheatingandconsequenttemperatureincreases,
the decreasein allowablestressat theconvergent
conesectionis a majordesignconstraint. There-
fore, theprimarynozzlemustbecooledwith a
portion of the LH 2 flow from the pump discharge
line. Sufficient coolant flow must be provided to
assure that the bulk steel temperature is maintained
below about 1050°F. Not only is gamma heating an
important internal volumetric source, but the hot
exhaust gases ( 4000°R) flow over the inside sur-
face of the nozzle hydrogen coolant tubes. Total
nuclear heating rates in the primary nozzle shown
vary from 0.6 BTU/in3-sec in the core support
barrel to O.01 BTU/in3-sec near the nozzle exten-
sion interface. The neutron contribution is only
about 4% of the total heating in the steel. For
these rates, the temperatures attained in the
nozzle vary from -300°F in the coolant passages to
a maximum of 900°F in the nozzle wall for the designs
_urrently under consideration.
ngu_ 3
Tm_ _ ASS_eLY
_R
MO_E CAR_ ANA_SlS
138,_5
&62
In the graphite nozzle extension, the total
heating rates range from 0.002 to 0.0002 BTU/In 3-
sec, with the fast neutron heating contributing
about 40% to the total. The graphite composite
nozzle extension is only radiatively cooled since
it can tolerate higher temperatures than metals
(above 3000°F) and is subjected to lower heating
rates. After 60 minutes of continuous full power
operation, the temperature of the graphite varies
between 1850°F and 2650°F. 9
The calculational technique used to generate
steady-state nuclear heating rates is shown in
Figure 4. A DOT two-dimensional discrete ordinates
transport code produces a leakage tape for the
lower part of the pressure vessel and reactor
assembly. The DASH single event Monte Carlo
coupling coae !s uses to transport this radiation
across the void between the DOT source tape and
the nozzle. The COHORT Monte Carlo code is used
to calculate the radiation environment throughout
lO
the nozzle assembly. Subsequently, CINDA is used
to calculate the temperatures in the nozzle and
nozzle extension.
Next consider the results for the pressure
vessel. This component consists of an AI-7075 bar-
rel and an A1-6061 dome. The dome is attached to
the barrel by a forward closure flange with 124 bolts
of A-286 alloy. Peak heating rates in aluminum
opposite core midplane range from about 0.26 BTU/in 3
-sec on the inside surface to 0.18 BTU/in3-sec on
the outside surface. In spite of these high volu-
metric heating rates, the coolant flow keeps the
peak wall temperature in the pressure vessel below
lO0°F. The temperatures attained are strongly in-
fluenced by the coolant flow allocated to the re-
flector region. Most of the pressure vessel steady-
state temperatures sre below O°F for the current
flow conditions. In the top closure flange, high
density A-286 bolts attain higher temperatures than
the surrounding aluminum. Typically the aluminum
in the flange is about -160°F, with the bolt 13°F
higher since the gamma heating rates in the bolt are
about a factor of three higher than in the aluminum.
To prevent fluid leakage at this closure, the bolts
are prestressed upon assembly of the pressure
vessel.
_ _ACTOR
pRESSUR_
VESSEL
AT pr-d:SSUI_E
VZSSEL SU_ACE
MODEL FOR CALCULATION OF _S RADIATION ENVIRON_IENT
NERVA NOZZLE ASSF._Ly
F_gure 4
The lower portion of the thrust structure is
an aluminum cylindrical annulus with an inside
radius of 19 inches and a thickness of 0.28 inches.
It is attached directly to the pressure vessel. Not
only does this structure transmit the thrust devel-
oped by the engine to the rest of the vehicle, but
it supports part of the propellant feed system. If
possible, the thrust structure should be designed
so that it requires no coolant to keep temperatures
below the allowable design limits. Currently two
materials are under consideration for this component.
The primary design uses aluminum which is limited
to a maximum temperature of 300°F because above
that temperature age hardening is gradually lost.
An alternate design uses titanium which is limited
to 700°F by the decrease in the yield stress with
increasing temperature. Both designs are protected
to a large extent by the shadow shield inside the
pressure vessel. Heating rates in aluminum range
from 3 x lO "3 BTU/in3-sec in the lower thrust struc-
ture near the pressure vessel dome to about 5 x l0-4
BTU/in3-sec in the upper thrust structure near the
propellant tank. Peak temperature rises in the
lower thrust structure are on the order of 200°F
or less for an engine without a disk shield.
Since the thrust structure is uncooled, the
temperature attained after a period of full power
firing is strongly influenced by the initial tem-
perature. Coatings such as A1203 can be used to
keep the initial temperature below lO0°F. If the
thrust structure must be cooled, it will impact
on the engine and introduce additional failure
modes. An uncooled thrust structure design is thus
favored to increase the reliability of the engine
design.
The disk shield shown in Figure 5 may be re-
quired for some manned missions with light payloads.
it is designed to operate as an uncooled component.
Such a design permits the use of a single NEEVA
engine for any manned or unmanned mission. If a
light payload requires additional personnel shield-
ing, a disk shield may be added to the engine with
ll
a minimum impact on the total engine design. The
largest shield design considered (shown in Figure 5)
is a lO,O00 lb disk with regions of stainless steel,
lead, borated graphite, and lithium hydride.
EXTERNAL ENGINE DiSK SHIELD
50 IN
AISI 347 CRES /
ALU MINU_
CL
I
25 iN 1
"1
I
I
20.5 IN
fmUItE s
463
Table1 presentsthe specificationextreme
heatingrates in variousregionsof the shield.
NeutronheatingfromthelUB(n,_)7A Li reactionis
themostimportantsourcein theboratedgraphite.
Onlygammaheatingis of significancein the lead.
In lithiumhydridethe 6Li(n,_)3Hreactionis the
mostimportantsourceof heating. Fastneutron
reactionsaresecondin importance,followedby
smallvaluesof gammaheating. Heatingis much
higherin theperipheryof the shieldsinceleakage
radiationfromthesidesof thePVARAcan"view"
thediskaroundtheinternal shield.
Table2 presentsthepeaktemperaturesfor
specificationextreme(worstcase)nuclearand
thermalanalysesin thedisk shieldfor continuous
firing timesof lO, 30,and60minutes.Thepeak
temperaturesoccurat thetip of theshieldand
decreasewith decreasingradius. If someconser-
vatismis removedbythe useof nominalinsteadof
"worstcase"valuesfor someparameters,thetem-
peraturesare loweredbyat least 150°F.For
instance,the leadat the outeredgeof the shield
remainsbelow600°F.Designoptionscanalso be
exercisedto circumventthermalproblems.For
example,if thetemperatureis excessivein the
lithium hydride,it canbe removedfromtheouter
lO inchesof theperipheryof theshield.
Theinitial temperatureof the disk is an
importantparameterin thesecalculations. It is
expectedthat coatingssuchasaluminumoxidewill
assurethat the initial temperaturewill not differ
significantly fromtheambienttemperatureat
launch,evenafter a longspacesoak. Notethat in
Table2 theinitial temperaturesdiffer in thecen-
tral andperipheralportionsof the shield. This
is becausethecentralportion is enclosedbythe
lowerthrust structureandis inhibited fromlosing
heatbyradiation.
Theheatingrates in uncooledcomponentsear
thebottomof thepropellanttank, suchasthe glm-
bal assemblyandthegimbalactuator,areabout
1.5x 10-3 BTU/in3-secin steel. Thealuminumupper
thrust structureis subjectedto heatingrateson
theorderof 5.5x l0-4 BTU/in3-secin aluminum.
Fortheselowratestheglmbaltemperaturemayin-
crease250°F,andthe upperthrust structuretem-
peraturemayincreaseby70°Fafter 60minutesof
full powerfiring. Thus,radiationheatingis not
a factor in thedesignof suchcomponents.
REFERENCES
1. WAr, AN, E. A., ROGERS, D. R., COURTNEY, J. C., DIXON, C. D., SMITH, J. R., and
....... , v. : .... _.. _ __ _ _T_±=_ _Enw _ine Com-
ponents," Aerojet Nuclear Systems Company Report RN-S-0557, April 1970.
2. WAI_AN, E. A., FORI_AN, D. L., and COURTNEY, J. C.,: "Comparison of Computed
and Measured Radiation Levels in NERVA Development Engine Tests," Trans. Am.
Nuc. Soc., 12, 416 (1969).
3. LINDSTROM, D.Go and PRICE, J. H.: "Coupled Discrete Ordinates - Monte Carlo
Technique and Applications to NERVA," Trans. Am. Nuc. Soc., 12, 952 (1969).
4. MYNATT I F. R., "A Users Manual for DOT, a Two-Dimensional Discrete Ordinates
Transport Code with Anisotropic Scattering," Union Carbide Corporation,
Nuclear Division, Report K-1694 (1967).
5. COLLINS, D. G. and WELLS, M. B._ "COHORT - A Monte Carlo Program for Calculating
Radiation Heating and Transport," Radiation Research Associates, Inc.,
Report RRA-T62 (1966).
6. MALENFANT, R. E., "QAD: A Series of Point-Kernel General-Purpose Shielding
Programs," Los Alamos Scientific Laboratory Report LA-3573 (1967).
7. MAL_FANT, R. E., RSIC Code Package CCC-75, Radiation Shielding Information
Center, Oak Ridge National Laboratory.
8. LEWIS, D. R., C_SKI, J. D._ and THOMPSON, L. R., "CINDA-3G-Chrysler Improved
Numerical Differencing Analyzer for 3rd Generation Computers," Chrysler
Corporation Space Division, Technical Note AP-67-287 (1968).
Thermal and Fluid Flow Analysis Report, NERVA Program, Data Item S-31, Aerojet
Nuclear Systems Company Report S-031-CPO90290-F1 (1970).
WARKENTIN, J. K. and COURTNEY, J. C., "Monte Carlo Radiation Transp0rtAnalyses
of the NERVA Nozzle Assembly," Trans. Am. Nuc. Soc., 13, 439 (1970).
WA_AN, E. A.i COURTNEY, J. C., and KOEBBERLING, K. 0._ W_inal Report of Shield
System Trade Study," Aerojet Nuclear Systems Company Report S05h-023,
July197o.
.
lO.
ll.
464
TABLEI
Disk Shield Heating Rates
Nuclear Heating Rate (BTU/sec)
Gammas Shield
(From Nuclear Subsystem) Secondaries
Neutron
Absorption Totals
Central Region
0 to 25 inch Radius
Lower Steel Plate 1.4 O. 1 0 1.5
Borated Graphite 2. i O. 1 2.0 4.2
Lead 4.3 0.3 O 4.6
Lithium Hydride 0 0 4.1 4.1
7.8 0.5 6.1 14.4
Peripheral Region
25 to 50 inch Radius
Lower Steel Plate 7.0 1.2
Borated Graphite 10.6 2.2
Lead 19.6 3.1
Lithium Hydride 0.2 0
0 8.2
15.5 28.3
0 22.7
14.2 14.4
Shield Totals
37.4 6.5 29.7 73.6
45.2 7.o 35.8 88.0
TABLE2
Disk Shield Peak Temperatures
Initial Specification Extreme Peak Temperatures (OF)
Temperature Time of Continuous Full Power Firing
Material Regions in OF l0 Minutes 30 Minutes 60 Minutes
Central Region
Lower Steel Plate lO0 160 252 330
Borated Graphite i00 156 248 325
Lead i00 154 245 320
Lithium Hydride i00 150 240 305
Peripheral Region
Lower Steel Plate 70 350 630 870
Borated Graphite 70 280 540 780
Lead 70 260 520 760
Lithium Hydride 70 170 390 630
465


Radiation heating in selected NERVA engine components

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