0 * * NASA CONTRACTOR REPORT cv d 0 d W I d u .0 NASA CR - 61012 p65 10627 z 0 E IPAGES) 2 L. (NASA CR OR THX OR AD NUMBER) APOLLO LOGISTICS SUPPORT SYSTEMS MOLAB STUDIES TASK ORDER N-34 POWER SYSTEM CONCEPTUAL DESIGN 2 Prepared under Contract No. NAS8-I1096 by W. L. Breazeale and C. 0. DeLong NORTHROP SPACE LABORATORIES Space Systems Section 6025 Technology Drive Huntsville, Alabama OTS PRICE XEROX $ MICROFILM $ d m /??I For NASA - GEORGE C. MARSHALL SPACE FLIGHT CENTER Huntsville, Alabama October 1964 https://ntrs.nasa.gov/search.jsp?R=19650001026 2020-07-10T12:30:00+00:00Z
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N A S A C O N T R A C T O R R E P O R T
cv d 0 d W I
d u
. 0
NASA CR - 61012
p65 1 0 6 2 7 z 0
E IPAGES) 2 L.
(NASA C R OR THX O R AD NUMBER)
APOLLO LOGISTICS SUPPORT SYSTEMS MOLAB STUDIES
TASK ORDER N-34
POWER SYSTEM CONCEPTUAL DESIGN
2
Prepared under Contract No. NAS8-I1096 by
W. L. Breazeale and C. 0. DeLong
NORTHROP SPACE LABORATORIES Space Systems Section 6025 Technology Drive Huntsville, Alabama OTS PRICE
This report is reproduced photographically f rom copy supplied by the contractor.
NASA-GEORGE C. MARSHALL SPACE FLIGHT CENTER
NOTICE
This report was prepared as an account of Government sponsored work. Neither the United States, nor the National Aeronoutics and Space Administration (NASA), norany person acting on behalf of NASA:
A Makes any warranty of representation, expressed or impiied, with respect to the accuracy, completeness, o r usefulness of the infor- mation contained in this report, o r that the use of any information, apparatus, method, or process disclosed in this report may not infringe privately owned rights; o r
B Assumes any liabilities with respect to the use of, o r for damages resulting from the use of any information, apparatus, method o r process disclosed in this report.
As used above, "persons acting on behalf of NASA" includes any employee o r contractor of NASA, or employee of such contractor, to the extent that such employee orcontractor of NASA, o r employee of such contractor prepares, disseminates, o r provides access to, any information pursuant to his employment or contract with NASA, or his employment with such contractor.
APOLLO LOGISTICS SUPPORT SYSTEMS MOLAB STUDIES
TASK ORDER N-34
POWER SYSTEM CONCEPTUAL DESIGN
for a
LUNAR MOBILE LABORATORY
W. L. Breazeale C. 0. DeLong
0
ABSTRACT
A conceptual design of the electric power system is evolved for the Lunar Mobile Laboratory. Functional block diagrams of appropriate subsystems a r e developed and pertinent design data is presented. system components on the MOLAB VI1 vehicle a r e investigated.
Packaging concepts of the electric power
PREFACE
This document by Northrop Space Laboratories, Huntsville Department, is a report to Marshall Space Flight Center on work performed under Task Order N-34, Contract Number NAS8-11096.
The NASA Technical Liaison Representative for this Task Order was Mr. E. E. Dungan of Advanced Studies (R-ASTR-A).
A 30-man week effort beginning on July 1 and ending on September 30 was expended on this task.
The information contained in this document represents a conceptual design of the electric power system for a Lunar Mobile Lab o r a tory .
.
~~
TABLE O F CONTENTS
1 .0 SUMMARY
2.0 INTRODUCTION
3.0 REACTANT CONTROL SYSTEM
3. 1 General
3. 2 Demand Regulator System
3.3 Measurement
4.0 ELECTRIC POWER SYSTEM THERMAL MANAGEMENT
4.1 General
4.2 Heat Sources and Problem Areas
4.3 Thermal Management Subsystem
4. 3; 1 General
4. 3. 2 System Description
4. 3.3 System Operation
5 .0 ELECTRICAL POWER SOURCES INTERFACE WITH SYSTEMS LOADS
5.1 General
5.2 Distribution Bussing and Grounding
5.3 Power Control
6.0 AUXILIARY POWER SOURCE
PAGE
1
2
4
4
7
7
8
8
8
10
13
13
13
15
16
iV
6. 1 G e n e r a l
6 . 2 Power R e q u i r e m e n t s
6. 3 Analysis
6 .4 Conclusions
6. 5 Recommenda t ions
c OiViP ONEX T PA c KA GING
7. 1 G e n e r a l
7 . 2 Mod1
7. 3 Mod 11
7 . 4 Mod 111
7. 0
8 . 0 REFERENCES
P A G E
16
16
16
19
19
20
20
20
20
29
40
V
c
V-
LIST O F ILLUSTRATIONS
t
FIGURE
1
2
3
4
5
6
7
8
9
10
11
12
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TITLE
FUEL CELL ASSEMBLY
REACTANT CONTROL SYSTEM
ELECTRIC POWER SYSTEM THERMAL MANAGEMENT SUBSYSTEM
POWER DISTRIBUTION SYSTEM BUSS SCHEMATIC
SNAP-19 TMRTY WATT GENERATOR
TOTAL GENERATOR WEIGHT AS A FUNCTION OF POWER LEVEL - PU-238
TOTAL GENERATOR WEIGHT AS A FUNCTION O F POWER LEVEL - PO-210
TOTAL GENERATOR WEIGHT AS A FUNCTION O F POWER LEVEL - PM-147
TOTAL GENERATOR WEIGHT AS A FUNCTION OF POWER LEVEL - CE-144
POWER CORRECTION FACTOR AS A FUNCTION O F GENERATOR LIFE
ELECTRIC POWER SYSTEM MOD I, MOLAB - VII
ELECTRIC POWER SYSTEM MOD 11, MOLAB- VI1
ELECTRIC POWER SYSTEM MOD III, MOLAB - VI1
PAGE
3
5
9
14
21
22
23
24
25
26
27
28
30
vi
LIST O F TABLES
TITLE PAGE
12 OPERATIONAL "TRUTH" TABLE FOR THEMS
IS0 TOPE PROPERTIES 18
31 WEIGHT AND BALANCE CHART, MOD I
34 WEIGHT AND BALANCE CHART, MOD I1
37 WEIGHT AND BALANCE CHART, MOD 111
r
Y
vii
THEMS
RECS
" RTG
SNAP
VT
V P
vv
vs
ABBREVIATIONS AND DEFINITIONS
ABBREVIATIONS
Thermal Management Subsystem
Reactant control Sy s t em
Radio - is otope Thermoelectric Generator
Systems for Nuclear Auxiliary Power
Thermostatic Valve
P r e s s u r e Operated Ball-Check Valve
Vent Valve
Solenoidal Valve
DEFINITIONS
Gamma An energetic electro-magnetic wave of nuclear origin.
Alpha Par t ic le A helium nucleus.
Beta Par t ic le An electron
Half - Life Time required for a given number of active nuclei to decay to half its initial value.
Radio-Isotope Short for radioactive isotope, that is one which undergoes spontaneous decay by the emission of an alpha particle or a beta particle.
... V l l l
SECTION 1.0
SUMMARY
The conceptual design of the electric power system for the MOLAB consists of functional block diagrams for the reactant control subsystem, the thermal management subsystem, 'power source inter- faces with system loads, and packaging arrangements of power system components on the MOLAB-VI1 vehicle. Pertinent design data is also included.
An analysis is performed on several radio-isotope thermo- electr ic generators to determine shield weights, isotope weights, and generator weights. Under the conditions investigated, a SNAP- 19 type generator fueled with Pu-238 is considered the "best" choice for the auxiliary power source.
SECTION 2. 0
INTRODUCTION
This document describes the evolution of the conceptual design of the electric power system for the MOLAB. functional block diagrams and design data for the major electric power subsystems. A previous task order report (Reference 1) describes the fuel cells under consideration. Figure 1. solely to that subsystem.
The design consists of
A sketch of the fuel cell i s shown in Each major subsystem has a section of the report devoted
u I4 W 5 61 4
W d 5
61 9
3
,
SECTION 3 . 0
REACTANT CONTROL SYSTEM (REGS)
3 . 1 GENERAL
The Reactant Control System (RECS) is a system to control, monitor, and regulate the flow of reactants to the MOLAB fuel cell assemblies. A brief , simplified schematic is present in Figure 2 .
The system, a s presented, i s redundant in all tanks and l ines and is a reliable, flexible means of connecting reactant supplies to fuel cell assembly loads.
3 . 2 DEMAND REGULATOR SYSTEM
During the lunar storage phase the liquid hydrogen and oxygen tank pressures a r e maintained below a predetermined pressure by vent valves VVI, VV2, VV3, and VV4 as indicated in the referenced schematic. The boiloff ra te through these vent valves is determined by the ra te of influx of heat into the cryogenic tankage from exterior sources . During the active lunar phase, when electric power is being produced, heat f rom exterior sources is inadequate to maintain tank pressures a t a level to sustain g a s flow at the ra tes required. simple means of introducing heat electrically i s described in reference 2 . Indicated heater power requirements a r e 119 watts average at a 6 KW generation level.
A
A "bang-bang" servo regulator is indicated in the referenced schematic to maintain line pressure , a t regulator inputs, at the r e - quired level. The regulator consists of a p re s su re operated switch ( H P ) , an activation relay (Kl), and a heater load in the LH #1 tank 2 section. tem. demand and the heater dissipation.
Each additional tank section contains a s imilar control sys - The ratio of heater "on" to "off" t ime is determined by the flow
Tank separator domes located in both LHZ and LOX tanks per - mi t thermodynamic feed-through such that failure of either tank sec- tion heater servo does not degrade system performance. not shown i n the schematic, overpressure cutout switches may be provided as backup in case of heating circuit lock-up.
Although
3 . 3 MEASUREMENTS
Transducers, not shown, a r e provided to supply electrical signals corresponding to flow rates f rom each tank section as well as to each fuel cell solenoid valve. ing to total LH
An electrical signal correspond- and LOX flow ra te into each fuel cell is provided. 2
4
;E >
J1 >
Q U' U'
B
R 5
Tank, regulator, and line pressure signals a r e available f rom each of four line sections.
Transducers a r e provided to supply electrical signals co r re s - ponding to remaining reactant in each tank section. for monitoring heater current for each tank section.
Provision i s made
A signal corresponding to total integrated flow-rate, either from a transducer o r from adjacent equipment operating f m m flow- ra te transducers i s provided for each fuel cell reactant input.
A signal, which is independent of any voltage that might cause valve actuation, i s provided to indicate the position of each valve.
6
a
SECTION 4. 0
ELECTRIC POWER SYSTEM THERMAL MANAGEMENT
4 .1 GENERAL
A large by-product fraction of MOLAB Electric Power System The kilowatt-hour requirement is sig- energy conversion is thermal.
nificant for thermal control of electronic components and associated devices during the long six month dormant phase. Too, requirement exists for fuel cell temperature conditioning pr ior to utilization. odic telemetry, checkout, and locomotion requirements for e lectr ic power during dormancy demands readiness capability. ezing or jelling of coolant necessitates heating of coolant lines pr ior to utilization. and dormant requirements bears careful consideration.
P e r i -
Possible f r e -
Judicious allotment of energy to meet these operational
4 .2 HEAT SOURCES AND PROBLEM AREAS
In the process of generating a particular level of electricpower, each fuel cell assembly produces heat a s a by-product at a given rate. The rate of heat production depends upon the level of power produced and the operating efficiency associated with the particular power level. Utilization of electric power from this source, for heating, involves a weight penalty. As an illustration, assume a modest 500 watt thermal control requirement for one-half of the 14 day operational sequence. This increase in additional power creates an increase in tankage, r e - actants, cell capacity and radiator a rea . The weight penalty incurred is approximately 150 pounds. It is, therefore, easy to see that de- pendence upon electrical heating, during the operational mission, is undesirable. Heating by this means, for the six months dormant period, is a l so undesirable since the weight penalty is too excessive. Since an increase in fuel cell operating level decreases cell mean- time-to-failure, system reliability is a l so impaired.
The Radioisotope Thermoelectric Generator (RTG), as con- t ras ted with fuel cells, produces heat continuously at a rate which decays exponentially with time from date of manufacture. Since the efficiency of conversion of heat to e lectr ic power i s small, of order less than lo%, the effect of changes in electrical load on the RTG ther - mal output is second order. The weight penalty associated with
7
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utilization of this source of heat i s negligible. Availability of heat is excellent in that heat is rejected in the range between 350 and 450OF. The RTG, therefore, becomes a prime candidate fo r selection of a heat generation source for MOLAB during the dormant and operational phase s . 4 . 3 THERMAL MANAGEMENT SUBSYSTEM (THEMS) - A CON-
CEPTUAL DESIGN
4. 3. 1 General
The Thermal Management Subsystem (THEM)(see Figure 3) , is synthesized a s a means of supplying thermal management and tem- perature control for the MOLAB Electric Power System. The system, as presented in the referenced schematic, has the following attributes:
Full 8. 8 kilowatt electric power is immediately available upon demand and i s full9 operational at. any time during the six month dormant phase or the 14 day operational phase.
All fuel cell assemblies, pumps, piping, valves, radiator, attendant electronic devices, and cabin temperature a r e auto- matically kept above a minimum lower temperature a s r e - quired.
" -
Total system heat requirements a r e furnished by the RTG units.
A completely redundant system as su res high reliability during all mission phases.
Fully autornatic system operation relieves the astronauts of manual functions.
Sv stem De s c ripti on
THEMS, a s generally described in the referenced schematic, contains four RTG units, each capable of an electrisal output of ap- proximately 40 watts and a by-product thermal output of approximately 800 watts. ducts heat directly f rom the cold junction operating in the range of 350 to 450' F at no heat load. Fluid cirkulation through this exchanger affords heat transfer, by forced convection, to additional system elements. In the event that circulation fails, heat exchanger tempera- ture approaches no-load values and heat i s rejected by radiative
Each RTG is fitted with a fluid heat exchanger which con-
8
F
t ransfer f rom attached fins.
Pumps, piping, solenoidal and thermostatic valves a r e pro- vided for the circulation, control, and regulation of the heat transfer fluid, Lines a r e filled with Monsanto Chemical Company MCS-198, a silicate ester based fluid, which has a pour point of -175OF and a vapor pressure of only 960 mm Hg a t 475OF.
4. 3. 3 System Operation
All symbolism herein contained is related to the previously referenced schematic. Since the system i s completely redundant, for ease of explanation only the upper half of the schematic i s discussed. During the dormant phase pump P1 is active, pumps P2 and P3 a r e inactive. Pump P1 is a completely sealed weldment utilizing a n im- mersed rotor and hydrostatic bearings. cycle induction motor with field winding electrically accessible through glass -to-metal seals.
The pump i s driven by a 400
Circulation is out of Plinto VS5, an open bistable solenoidal valve: VS6 is closed. A thermostatic valve, VT1, controls the flow into the radiator. Solenoidal valve VS1 is closed. shuts off vent t o the radiator and flow is bypassed by VP1 a pressure operated ball-check valve. VT1 which maintains radiator temperature a t a preset value during the night cycle. Fuel cell assemblies No. 1 and No. 2 a r e tempera- ture controlled, in a similar manner as the radiator, by VT2, VT3, VS2, VS3, V P z and VP3. VS4 i s a lso open and conducting during dormant operation. The finned temperature control plate, whereupon electronic equipment is mounted and cabin a i r i s exchanged, is con- trolled by VT4 and V P 6 in a manner similar to that described for the radiator. During the 14 day active phase VS4 and VS5 a r e turned off and VS6 is turned on. redundant standby. Ball-check valves VP1, VP2 and VP3 a r e inactive due to reversed circulation. VS1, VS2 and VS3.
Closing of VT1
Radiator temperature i s monitored by
Pump P 2 i s turned on with pump P3 off as
VT1, VT2 and VT3 a r e bypassed by
A small solid-state 400 cycle inverter (IT) powers the low power sealed pump (Pl). relay K1 f r o m RTG-2. K1 automatically switches the inverter to the alternate source (RTG-1).
Power for the inverter is conducted through In event of failure of RTG-2 electrical output,
Attention is drawn to the redundancy of the system. In the
10
event of failure of any of the aforementioned items, a duplicate se t is capable of performing the function of cabin heating. units provides heat at the maximum level of 1600 watts.
Each pair of RTG
The system, a s presented, is tentative and is not intended for design application. The electrical circuits associated with valves, pumps and transducers and the lbgic involved is presently beyond the level of detail of this report. for the half-system previously described (see Table 1).
An operational "truth" Table is enclosed
P
11
TABLE 1
OPERATIONAL “TRUTH TABLE FOR THEMS
PHASE ITEM SYMBOL DORMANT ACTIVE
Bistabie Soienoidai Valve OFF
Bistable Solenoidal Valve vs2 OFF ON
Bistable Solenoidal Valve v s 3 OFF ON
Bistable Solenoidal Valve v s 4 ON O F F
Bistable Solenoidal Valve v s 5 ON O F F
Bistable Solenoidal Valve VS6 O F F ON . Pump P 1 ON ON
Pump P 2 OFF ON
Pump P 3 OFF STANDBY
12
SECTION 5.0
ELECTRICAL POWER SOURCES INTERFACE WITH SYSTEM LOADS
5.1 GENERAL
The interconnection of sources of MOLAB electrical power with subsystem loads is provided by the power distribution system. The general philosophy of this arrangement i s given in a previous report ( see reference 1). a system of busses , circuit breakers , and shunts to distribute, control and monitor all sources of electrical power. is provided in Figure 4.
Specifically the power distribution system provides
A generalized schematic
5.2 DISTRIBUTION BUSSING AND GROUNDING
The MOLAB distribution bus system consists of the following pr imary busses: 1) Essential Buss 2) Locomotion Buss 3) Telemetry Buss
Under all conditions of source and load, the voltage, as deliver- ed to these busses is (positive) 28 t 2 volts. provided with a separate ground reFurn, which is not the MOLAB structure o r supportive sheet metal. All ground returns a r e connect- ed to the MOLAB structure a t a common grounding point. cel l and RTG negative output terminals a r e directly connected through conductors to the said common grounding point.
Each buss as named is
All fuel
All ground and feed lines consist of non-braid, low-inductance conductors. Resistance and inductance of named conductors, under expected loads and in the absence of convective heat t ransfer , a r e sufficiently minimized to maintain equipment voltages within allow - able tolerances and minimize inductive transients and heating effects. Secondary distribution busses also meet the above named requirements. Insulation of pr imary and secondary busses is adequate to provide isolation under any possible transient fault conditions. Insulation materials do not produce smoke, noxious odors o r toxic gases under sustained fault conditions in a pure oxygen atmosphere and are capable of maintaining integrity and initial properties under all conditions and combinations of environment.
A secondary buss is provided for each individual subsystem as required. provided as desired. Each secondary buss which terminates within . o r upon an individual electrical load is provided \irth a female connector, adquately keyed and coded to prevent undesired connection, and whose inter -terminal insulation and terminal conductivity meet the previously
Further "fanning" of busses within the subsystem i s to be
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t -- A
14
named requirements.
5.3 POWER CONTROL
Control of electrical power is exerted in three general a r eas a s follows:
2) 3) Between each pr imary buss.
L 1) Between each power source and each pr imary buss. Between each pr imary buss and each secondary buss.
A maximum of flexibility and protection i s assured by providing means to individually connect all sources and loads. failure of any source o r a fault o r failure in any secondary buss o r subsystem does not degrade the remaining system performance as related through the electrical power system grid.
That i s ,
15
SECTION 6.0
AUXILIARY POWER SOURCE
6.1 GENERAL
During the dormant phase of the mission, the pr imary electr i - cal power for the MOLAB is provided by four radio-isotope thermo- electric generator (RTG) units. power supply during the manned phase of the mission. In addition to the electrical power supplied by these units, a considerable amount of thermal energy is available for use in the thermal control of the MOLAB cabin and the power system. cal and thermal power.
6 . 2 POWER REQUIREMENTS
These units also serve as an auxiliary
Thus the RTG units provide both electr i -
Since the primary purpose of the RTG units is to supply elec- r ical power, the "size" of the RTG units is dictated by the electrical power requirements. Those subsystems normally requiring electr i - cal power during the dormant phase a r e the telemetry subsystem, the thermal management system and the R . F. communicztions subsystem. There a r e periods during the dormant phase when large amounts of power a r e required such as the unloading of the MOLAB from the LEM truck, complete system chechout, etc. At these t imes, a sufficient number of fuel cells to meet the power demands a r e activated. ever , these periods a r e infrequent and relatively short in duration.
How-
Thetelemetry subsystem requires a maximum of 150 watts. Approximately 100 watts of this amount is required on a continuous basis while the other 50 watts may be required every hour for a dur- ation of 1 to 2 seconds. The R. E'. communications subsystem r e - quires 50 watts every six hours for a period of about 12 minutes. During the operation of the R. F. communications subsystem, the telemetry power requirements a r e 100 watts o r l e s s . Hence, these two subsystems have a combined power requirement of 150 watts.
An allotment of ten wa t t s electrical is made to the thermal management system for the operation of pumps, etc. electrical power required i s 160 watts. assumed, then the maximum available thermal output of the RTG units is 3.2 kilowatts. output is usable and available to the thermal management system, which maintains the temperatures oi the electrical power system and the MOLAB cabin.
Thus, the total If an RTG efficiency of 5% is
The assumption is made that 1. 5 kilowatts of this
6.3 ANALYSIS
In order to perform an analysis of possible RTG units, a number
16
of assumptions a r e made. consistent results, a r e as follows:
These assumptions, necessary to insure
1. 2.
3 .
4.
The RTG has an efficiency of 570. Sufficient shielding i s provided to reduce the dose r a t e to 10 mrem/hr or less a t 1 meter . Generator weights and dimensions a r e based on SNAP-19 type characteristics (See Figure 5). The useful generator life is one year o r longer.
The list of iso2ope candidates for use as heat sources in the RTG units is rather small. Polonium-210, Promethium-147, and Cerium-144. Table 2 l is ts the properties of these isotopes.
The possible candiates a r e Plujonium-238,
Three shielding materials a r e considered for gamma shielding, The gamma while lithium hydride (LiH) i s used as the neutron shield.
shields under consideration a r e lead, iron, and depleted uranium. Less frequently used materials, such as Mallory-1000 (a tungsten alloy) are not included in this study, but may warrant investigation in la te r studies. and a r e easy to form into the required shield configuration.
All the materials under study a r e readily available,
Shielding weights are generated in the following manner. electrical power level is mqtiplied by twenty to determine the thermal power level. F rom curves different isotopes and for different thicknesses of shi elding materials, the required shield thickness is determined. the shield weights a r e calculated. ed by dividing the thermal power by watts per gram for a particular isotope. Plutonium generator weights for various power levels a r e obtained by multiplying the ratio of the desired power level-to-30 watts t imes the generator weight for SNAP-19, which is a 30 watt generator. Generator weights for other isotopes at a given power level a r e cal- culated by obtaining the ratio of the specific power density (watt/cc) of plutonium to the specific power density of the isotope in question, and then multiplying this ratio time the plutonium generator weight. Figures 6 through 9 i l lustrate the results of these calculations. Several comments are in order regarding these figures. level indicated on the graphs i s the initial power level of the generator and no allowance is made for the decay of the isotope with time. Order to account for this effect, the initial power is multiplied by the appropriate correction factor. For example, suppose a Pm-147 fuel- ed RTG is desired which will furnish 150 watts-electrical for a period of one year. factor of 1.47 is found to be necessary, i. e . , an initial power of 150 t imes 1.47 o r 220.5 watts is required to insure an output of 150 watts a t the end of one year.
The
of dose rates versus thermal power for
F r o m these thicknesses The isotope weights a r e determin-
The power
In
By looking at the Pm-147 curve on Figure 10, a correction
17
TABLE 2
ISOTOPE FROFERTIES
ISOTOPE H A L F - LIFE MODE O F DECAY POWER DENSITY ~~~~
PU -238 89.8 Y r . Alpha': Po -210 0.38 Alpha*::<
Pm -147 2 . 6 Beta
Ce -144 0.78 Beta
9 . 3 Wattslcc 1320
1.0
13.8
aPu-238 also has a spontaneous fission half-life which gives r i s e to a neutron flux and a soft gamma flux. fission, neutrons a r e generated by .7 , reactions on light elements present.
In addition to spontaneous
.Ir .b although Po -210 i s primarily an alpha emitter, the gamma activity is high enough to require shielding. diluted in an iner t metal matrix to achieve a specific power density of 75 wattslcc.
Also, Po-210 is usually
18
r
6.4 CONCLUSIONS
Based on total weight, shielding requirements, isotope avail- ability, biological hazards, and power flatning, the Pu-238 fueled RTG is determined to be the most suitable for the MOLAB mission. Also the Pu-238 RTG i s the only long-lived space power unit which is presently in use, being utilized-in transit 4A and Transit 4B. other units undoubtedly will have been space tested before the launch period for the MOLAB mission. Although the present study i s based on thermoelectric generators , the possibility of using more efficient thermionic generators cannot be eleminated as development programs on this type generator may produce tangible results before the schedul- ed launch period.
However,
6 .5 RECOMMENDATIONS
The shielding analysis in this study does not account for the location of the RTG on the MOLAB o r for the inherent shielding provid- ed by the MOLAB structure or apurtenances. investigation in a more detailed design of the power system layout. Also the shielding weights calculated a r e based on 4 r sh ie ld ing . restricting the amount of time an astronaut spends near an unshielded side of an RTG, shadow shielding can be effectively employed.
These effects need
By
It is assumed in this study that the RTG units remain on the MOLAB during the entire manned phase of the mission. if the units a r e removed f rom the MOLAB by the astronauts upon their arr ival , then the sheilding requirements can be relaxed since the astronauts spend very little time in the vicinity of the RTG units. The weight savings and feasibility of this plan mer i t further attention.
However,
The total expected dose from celestial sources such a s solar f la res , etc. needs to be estimated for the entire mission. In light of this dose and the mission operational plan, the relaxing of the allow- able dose ra te of 10 m r e m / h r at one meter f rom the RTG is possible.
One a r e a that deserves considerable attention i s the disposition of the RTG units at the end of the MOLAB mission. Since the Pu-238 has such a long half-life (89 years) and the generator life is also lengthy, the RTG units provide 160 w (e ) for a minimum of five years on the lunar surface. ways. One such possibility i s the use of these RTG units as a subse- quent power supply for a navigational homing beacon. Another possi- bility is to use the RTG units to power a scientific package that auto- matically collects, analyzes, and transmits data to the earth for ex- tended time periods. Therefore, modular design should be employed with flexibility in u s e a s a guideline in subsequent RTG studies.
This amount of power is useful in numerous
19
SECTION 7 .0
COMPONENT PACKAGING
7 . 1 GENERAL
Three packaging arrangements of reactant tanks, RTG units, afid fuel cells on MOLAB VI1 are evolved for the purpose of deter- mining desirable power equipment configurations. configuration developed has de si rable features, these configurations have not been completely analyzed to determine if they a r e the layouts. and the reactant tanks in order that coolant lines f rom the RTG units to the fuel cells a r e as short as possible. energy from the RTG units incident on the reactant tanks may greatly complicate the tankage insulation problems. offs is acknowledged, but complete studies of such problems a r e not par t of this task.
Although each
As a n example, the RTG units a r e kept close to the fuel cells
However, radiated thermal
Existence of such t rade -
7 . 2 MOD I
This concept (Figure l l ) . a n d the other two concepts have the hydrogen tank mounted above the oxygen tank. In all three concepts, these tanks a r e mounted contiguous to the cabin. This arrangement moves the cg's of these tanks as close as possible to the cg of the vehicle. The four fuel cells a r e mounted as two horizontal pairs on opposite sides of the reactant tanks. An RTG is mounted above and below each fuel cell pair. f rom the RTG units for heating of the fuel cells. The RTG fuel cell combinations are mounted as far forward as possible without inter- ferring with the airlock door operation. balances for this configuration.
This arrangement utilizes the radiant heat
Table 3 lists weights and
7.3 MOD I1
In this configuration (see Figure 12) the fuel cell pairs a r e mounted below the RTG units. a r e parallel t o the fore-aft axis of the MOLAB. lowers the vehicle cg since the heavier fuel cells are placed below the RTG units. of the RTG units.
The longitudinal axes of the fuel cells This configuration
This arrangement a l so allows fo r easier handling Table 4 contains weight and balance data.
20
L
FIGURE 5. SNAP-19 THIRTY WATT GENERATOR
21
1,000
900
800
h
cfj 700
z 3
n
0 pc , 600 Y
0 b 400
300
200
0
~-
F LUTONII'M-238 ($hielding -Lithium ilydride) - ,
0 140 160 180 2 00 220 240 260
POWER LEVEL - (WATTS-ELECTRICAL)
.
FIGURE 6. TOTAL GENERATOR WEIGHT AS A FUNCTION OF POWER LEVEL - P U - 2 3 8
22
1,000
900
800
700
600
500
400
300
200
0
4
POLONI
4 U-Shi
M-210 I
f z 1 lding
0 140 160 180 200 220 240 260
POWER LEVEL - (WATTS-ELECTRICAL)
FIGURE 7. TOTAL GENERATOR WEIGHT AS A FUNCTION O F POWER LEVEL - PO-210
23
4,400
4,000
h
u3 3, 600 z
5 0 pc Y
I 3,200
E-c
3 j 2, 800 4 E-c 0 E-c
2,400
2,000
1,600
140 160 180 200 220 240 260 0
POWER LEVEL - (WATTS-ELECTRICAL)
FIGURE 8. TOTAL GENERATOR WEIGHT AS A FUNCTION O F POWER LEVEL - PM-147
20,000
18,000
16,000
14,000
12,000
10,000
8,000
6,000
4,000
2,000
1
0
POWER LEVEL (WATTS-ELECTRICAL)
FIGURE 9. TOTAL GENERATOR WEIGHT AS A FUNCTION OF POWER LEVEL - CE-144
.
FIGURE 10. POWER CORRECTION FACTOR AS A FUNCTION O F GENERATOR LIFE
26
- - .
P IJ-
n \ F
3 E! Q
28
7 . 4 MOD UI
F o r this configuration mounted with their longitudinal mounted above the RTG units.
(see Figure 13) the fuel cell pairs axes vertical. The fuel c e l l s a r e The RTG-fuel cell assemblies a r e
a r e
placed next to the MOLAB cabin. a i r lock door is changed f rom its present location. rangement places the cg's of the fuel cells and RTG units as far for - ward as possible. given i n Table 5.
This configuration assumes that the This particular ar-
Balance and weight information for this layout a r e
29
-..
U s I
2 I4 0 2. .. H U H
R 0 z z w I3 VI * VI
d
0 a u I3 u w i4 w
z 2
Vl 4
w d 5 r3 i;I
30
f
31
ttt +
,I
I- ' 4 2
d d d rn
6 Iz
U
c
32
8
..
t
33
8
34
.
f f
..
37
38
4
39
SECTION 8.0
REFERENCES
1.
2.
DeLong, C. O. , "Power System Studies fo r a Lunar Mobile Laboratory", Task Order Report N-20, to be published.
Merrifield, D. V. , "MOLAB Power System Consideration'', Future Studies Branch, John F. Kennedy Space Center, May 25, 1964.
3. Davis, H. L . , "Isotope Costs and Availability", Nucleonics, 21 (No. 3), pp 61-65 (March 1963).
4. Arnold, E. D., Handbook of Shielding Requirements and Radiation Characteristics of Isotopic .Power Sources for Terrestr ia l , Marine, and Space Applications, ORNL-3576, April 1964.
.-
I
40
DISTRIBUTION
INTERNAL
DIR DEP-T R-AERO-DIR
-S -SP (23)
-A (13)
-A -AB ( 5 ) -AL (5)
R-ASTR-DIR
R-P&VE-DIR
R-RP-DIR -J ( 5 )
R-FP-DIR R-FP (2) R-QUAL-DIR
-J (3) R-COMP-DIR R-ME-DJR
-X R-TEST-DIR I-DIR :kls-IP MS-IPL ( 8)
EXTERNAL
NASA €Ladquarters MTF coi. -r. E V ~ S
MTF Naj. E. Andrews (2) MTF Mr. D. Beattie R-I Dr. James B. Edson
Kennedy Space Center K-DF Mr. von Tiesenhausen
Northrop Space Laboratories Huntsville Department Space Systems Section (5)
Scientific and Technical Information Facility P.O. Box 5700 Bethesda, Maryland
Attn: NASA Representative (S-AK/RKT) ( 2 j
Manned Spacecraft Center Houston, Texas
Mr. Gillespi, MTG Miss M. A. Sullivan, RNR John M. Eggleston