NASA has been involved in the development of Closed Brayton Cycle (CBC) power conversion technology since the 1960's. CBC systems can be coupled to reactor, isotope, or solar heat sources and offer the potential for high efficiency, long life, and scalability to high power. In the 1960's and 1970's, NASA and industry developed the 10 kW Brayton Rotating Unit (BRU) and the 2 kW mini-BRU demonstrating technical feasibility and performance, In the 1980's, a 25 kW CBC Solar Dynamic (SD) power system option was developed for Space Station Freedom and the technology was demonstrated in the 1990's as part of the 2 kW SO Ground Test Demonstration (GTD). Since the early 2000's, NASA has been pursuing CBC technology for space reactor applications. Before it was cancelled, the Jupiter Icy Moons Orbiter (HMO) mission was considering a 100 kWclass CBC system coupled to a gas-cooled fission reactor. Currently, CBC technology is being explored for Fission Surface Power (FSP) systems to provide base power on the moon and Mars. These recent activities have resulted in several CBC-related technology development projects including a 50 kW Alternator Test Unit, a 20 kW Dual Brayton Test Loop, a 2 kW Direct Drive Gas Brayton Test Loop, and a 12 kW FSP Power Conversion Unit design

Mason, Lee S.

NASA Technical Reports Server

Oral Presentation/Viewgraphs Summary: 
NASA has been involved in the development of Closed Brayton Cycle (CBC) power conversion technology 
since the 1960's. CBC systems can be coupled to reactor, isotope, or solar heat sources and offer the 
potential for high efficiency, long life, and scalability to high power. In the 1960's and 1970's, NASA and 
industry developed the 10 kW Brayton Rotating Unit (BRU) and the 2 kW mini-BRU demonstrating technical 
feasibility and performance, In the 1980's, a 25 kW CBC Solar Dynamic (SO) power system option was 
developed for Space Station Freedom and the technology was demonstrated in the 1990's as part of the 2 
kW SO Ground Test Demonstration (GTD) . Since the early 2000's, NASA has been pursuing CBC technology for 
space reactor applications. Before it was cancelled, the Jupiter Icy Moons Orbiter (HMO) mission was 
considering a 100 kWclass CBC system coupled to a gas-cooled fission reactor. Currently, CBC technology is 
being explored for Fission Surface Power (FSP) systems to provide base power on the moon and Mars. These 
recent activities have resulted in several CBC-related technology development projects including a 50 kW 
Alternator Test Unit, a 20 kW Dual Brayton Test Loop, a 2 kW Direct Drive Gas Brayton Test Loop, and a 12 
kW FSP Power Conversion Unit design. 
https://ntrs.nasa.gov/search.jsp?R=20120016632 2019-08-30T23:15:19+00:00Z
National Aeronautics and Space Administration 
A Summary of Closed Brayton Cycle 
Development Activities at NASA 
Lee Mason 
NASA Glenn Research Center 
Supercritical CO2 Power Cycle Symposium 
April 29-30, 2009 
Pre-Decisional , For Discussion Purposes Only 
• 
www.nasa.gov 1 
Outline • 
National Aeronautics and Space Administration 
• Space Power Conversion Options 
• Closed Brayton Cycle Timeline 
• Brayton Development Projects 
- Brayton Rotating Unit & Mini-BRU 
- Solar Dynamic Brayton 
- Brayton Concepts & Studies 
- Jupiter Icy Moons Orbiter 
- 2 kW Brayton Testbed 
- Dual Capstone Brayton Loop 
- Fission Surface Power 
- Direct Drive Gas Brayton 
- Technology Demonstration Unit 
- Full-scale Power Conversion Unit 
Pre-Decisional , For Discussion Purposes Only www.nasa.gov 2 
National Aeronautics and Space Administration 
Space Power Conversion Options 
• Closed Brayton Cycle 
- Mature Technology with 
High Power Potential 
• Free-Piston Stirling 
- High Efficiency & Scales 
Well to Low Power 
• Organic or Liquid-Metal 
Rankine 
- Potential for Low Mass at 
High Power, but Material 
& Fluid Mgmt Issues 
• Thermoelectric 
- Flight Proven with Long 
Life , but Low Efficiency 
• Thermionic 
- Extensive Database, but 
Life Issues Remain 
Pre-Decisional , For Discussion Purposes Only 
30 
-
25 
~ 0 
~ 
• >-u 20 
I: 
.~ 
u 
:E 15 
W 
10 
5 
Ni-Based -,-__ Re~~?ct()ry ;-_---,-_Ceramics 
Superal/oys Composites 
<> Rankine 
SNAP-50 
<> Segmented 
High T TE 
LowT 
<> PbTe 
SiGe <> Thermo-
electric 
: Thermionic 
1000 1200 1400 1600 1800 2000 
Peak Temperature (K) 
www.nasa.gov 3 
National Aeronautics and Space Administration 
Closed Brayton Cycle 
• 
• 
• 
• 
• 
• 
Liquid 
coolant 
• 
• 
• • 
• • 
• • 
• • 
• • 
.. ,. 
Pump 
Pre-Decisional, For Discussion Purposes Only 
AC or DC 
Turboalternator-
Compressor 
Inert gas 
working 
fluid 
• 
www.nasa.gov 4 
National Aeronautics and Space Administration 
BRU esc Timeline • 
BIPS SP-100 Demo DIPS JIMO 
( I I I I I I I ) 
1970 1980 1990 2000 
Mini-BRU SP-100 Studies SSF SD FSP 
SDGTD 
Pre-Decisional , For Discussion Purposes Only www.nasa.gov 5 
National Aeronautics and Space Administration 
Brayton Rotating Unit 
• First-ever Closed Brayton Cycle (CBC) power 
conversion system for space (1968-76) 
- 4 BRUs Fabricated by AiResearch and Tested at 
Lewis Research Center 
- Included Brayton Heat Exchanger Unit (BHXU) 
combined Recuperator and Cooler 
• BRU Program Successfully Demonstrated: 
- Manufacturing & Assembly 
- Jacking Gas Startup 
- High Conversion Efficiency (>25%) 
Material Compatibility 
- Tilt-Pad Bearings 
- Extended Life: 38000 Hrs Operation on One 
Unit Without Degradation, Approx. 50000 Hrs 
Total on Four Units 
• Performance Parameters: 
- Alternator Output 2.25 to 15 kWe 
- Turbine Inlet Temp 1144 K (1600 F) 
- Compressor Inlet Temp 300 K (80 F) 
- Compressor Exit Pressure 310 kPa (45 psia) 
36000 RPM, 1200 Hz, 208 V 
- 65 kg BRU, 200 kg BHXU 
Pre-Decisional , For Discussion Purposes Only 
BRAYTON POWER SYSTEM 
Tu rboalternator 
BHXU 
BRU Life 
Test 
www.nasa.gov • 
National Aeronautics and Space Administration 
Mini-BRU 
• Mini-BRU and Recuperator developed for use 
with Modular Isotope Heat Source (1974-78) 
Built by AiResearch, Tested by Lewis 
Major Differences from BRU: Lower Power, 
Foil Bearings, Internal Stator Cooling 
- Interchangeable Superalloy and Refractory 
Turbine Plenums Fabricated 
• Led to 1.3 kW Brayton Isotope Power System 
(BIPS) development (DOE) 
- No Flight, but 1000 Hr Workhorse Loop Test 
• Mini-BRU Successfully Demonstrated: 
- High Efficiency (>25%) at Lower Power 
- Foil Bearings 
- Alternator Motoring Startup 
- Leak-Free Recuperator Designs 
• Performance Parameters: 
- Alternator Output 650 to 2100 watts 
- Turbine Inlet Temp 1144 K (1600 F) 
- Compressor Inlet Temp 300 K (80 F) 
- Compressor Exit Pressure 730 kPa (106 psia) 
- 52000 RPM, 1733 Hz, 67 V 
- 17 kg mini-BRU, 59 kg Recuperator 
Pre-Decisional , For Discussion Purposes Only 
Turboalternator 
• 
BIPS 
Workhorse 
Loop 
Mini-BRU 
Recuperator 
www.nasa.gov 7 
National Aeronautics and Space Administration 
Solar Dynamic Brayton - Space Station Freedom • 
• 25 kW Solar Dynamic Power Module for 
Space Station Freedom (1986-91) 
- Part of Hybrid PV/SD Power System 
- Reduced Life Cycle Costs Compared to 
Photovoltaic/Battery System 
- 15 year On-Orbit life 
- Man-Rated System 
• Phase C/O Design Completed 
- Higher Risk Components Built & Tested 
(e.g. Concentrator, Heat Receiver) 
- Power Conversion Unit Considered Low 
Risk due to BRU Heritage 
• Performance Parameters 
- Alternator Output 36 kWe 
- Cycle Efficiency 27% 
- Turbine Inlet Temp 1034 K (1400 F) 
Compressor InletTemp 338 K (148 F) 
Compressor Exit Pressure 560 kPa (81 
psia) 
- 32000 RPM, 120V 
104 kg Turboalternator-Compressor, 162 
kg Recuperator, 85 kg Gas Cooler 
Pre-Decisional , For Discussion Purposes Only 
-
--
Turboalternator 
,::.. 
......... 
-
SD Flight 
Configuration 
.. _-
Recuperatorl 
Cooler 
www.nasa.gov 8 
National Aeronautics and Space Administration 
Solar Dynamic Ground Test Demonstration • 
• 2 kW Solar Dynamic Ground Test 
Demonstration (1994-98) 
- Congressional Ear-Mark Following 
Cancellation of SO Option for SSF 
- Full End-to-End System Test in Solar-
Thermal-Vacuum (TRL6) 
- Government/Industry Team: NASA Lewis, 
Allied Signal, Harris, Loral-Vought, 
Rocketdyne 
• Extensive Test Program 
- 33 Separate Tests, 372 LEO Orbit Cycles 
- 800 Hours of Operational Experience 
- No Performance Degradation 
• Led to Joint US/Russian 2 kW Mir SO 
Flight Demo (1996-98) 
- Shuttle Delivery Mission Re-directed to 
Mir Re-supply 
• Multiple Brayton Unit Configurations 
- Mini-BRU with 120V Rice Alternator 
- SO Mir Development Unit with 28V 
Permanent Magnet (PM) Alternator 
- SO Mir Unit with Rewound 120V PM 
Alternator 
Pre-Decisional , For Discussion Purposes Only 
Heat Receiver & 
Power Conversion Unit 
View from 
Solar Sim. 
Window Port 
Rotor Components 
-
www.nasa.gov 9 
National Aeronautics and Space Administration 
Brayton Concepts & Studies • 
• 20 kW Brayton for Near-Term 
SP-100 Reactor Flight 
Demonstration Mission 
• 6 kW Dynamic Isotope Power 
System (DIPS) for Air Force 
Boost Satellite Tracking 
System (BSTS) 
• 500 watt to 2.5 kW DIPS for 
Space Exploration Initiative 
(SEI) 
- Science Rovers 
- Surface Utility Power 
• 100 to 550 kW SP-1 00 Brayton 
for Lunar and Mars Surface 
Missions 
• Bi-Modal Nuclear Thermal 
Rocket with 25 to 50 kW 
Brayton 
Pre-Decisional, For Discussion Purposes Only 
6 kW DIPS 
Bi-Modal NTR 
550 kW SP-100 Brayton 
For Lunar Surface 
www.nasa.gov 10 
National Aeronautics and Space Administration 
Jupiter Icy Moons Orbiter (JIMO) Brayton 
liquid-Metal Reactor with 
1+1 Brayton (100 kWe) 
Gas-Cooled Reactor with 
2+2 Brayton (200 kWe) 
Pre-Decisional , For Discussion Purposes Only 
liquid-Metal Reactor with 
2+2 Brayton (135 kWe) 
www.nasa.gov " 
National Aeronautics and Space Administration 
2 kW Brayton Testbed 
• 2 kW "Space-Like" Closed Brayton 
Unit for JIMO Risk Reduction 
- Brayton Converter from SD GTD; 
Formerly "Mini-BRU" 
- Electrical Shell & Tube Helium-
Xenon Gas Heater 
- Commercial Ethylene Glycol 
Chiller 
- 120 Vdc Electrical Controller & 
Parasitic Load Radiator 
- Alternative 1100 Vdc Controller for 
Electric Propulsion Testing 
• Recent Testing Completed: 
- Performance Mapping (Jun (02) 
- Ion Thruster Demo (Dec (03) 
- Mech. Dynamics Test (Nov (04) 
- Thermal Transients Test (Sep (05) 
Pre-Decisional , For Discussion Purposes Only 
Evaluate Transient Measure Mech. 
Thermal Response Vibrations 
& Validate Codes Demonstrate & Validate Codes 
HV Distribution 
& EP Thruster 
I nteg ration 
www.nasa.gov 12 
National Aeronautics and Space Administration 
Dual Capstone Brayton Loop 
• System Designed and Built by Barber 
Nichols, Arvada CO 
- Uses Two Commercial Capstone Micro-
Turbine Generators 
- Modified for Closed-Loop Operation 
- Common Nitrogen Gas Loop; No Isolation 
Valves 
- Shared (180 kW) Electrical Resistance 
Heater; Water Cooling 
• First-of-a-Kind Test System 
- Representative of Direct-Gas Reactor with 
redundant Brayton units 
- Permits evaluation of operational 
interactions 
• GRC Testing Completed May-DB 
- Operated up to 22 kW Total Power, 950K 
Turbine Inlet, 90000 rpm 
- Equal & Unequal Shaft Speeds 
- Single and Dual Unit Operation 
- Staggered & Simultaneous Startup 
- Analytical Model Validation 
Pre-Decisional , For Discussion Purposes Only www.nasa .gov 13 
National Aeronautics and Space Administration 
... 
Dual Capstone - Equal Shaft Speeds 
25.--------.--------,--------.--------,--------.--------. 
20 
I 
I 
I 
I 
I I 
________________ l ________ J ________ J __ _ 
I I 
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--------~--------+--------~--
I I 
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I I 
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Reference Condition 
1=..:..:.;.;=.;-'i - - - -- ---
~ 
o 10 Q. 
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--------,--------
I I 
-----------------r--------
I 
g 
o 
I-
5 --------- -----~--------~---------~--------
I 
O+--------T--------T--------T--------.--------.------~ 
40 50 60 70 80 90 100 
Shaft Speed (krpm) 
-{)- DBPCS 950 K HET 
__ CCSS 950 K HET 
-0- DBPCS 895 K HET 
....... CCSS 895 K HET 
-c- DBPCS 840 K HET 
-..... CCSS 840 K HET 
DBPCS=Dual Brayton Power Conversion System; CCSS=Closed Cycle System Simulation 
Pre-Decisional , For Discussion Purposes Only www.nasa.gov ,. 
National Aeronautics and Space Administration 
Dual Capstone - Unequal Shaft Speeds 
12 ,--------.---------.--------.--------.---------.--------. 
1
0 
-_ -_ -_ -_ -_ -_ -_ -_ -_:f-~-_-~- ~- -~-~-:-~-~'-~-~- ~- ~- -~-~-~-~-t'-~-;-;- ;- -~-~-~L: ::~~r: --------
I 8 1 -1----- ---~----------
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Retererce Condition 
1 
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1 2 - - - - - - - - - - r- - - - - - - - - - r- - - - - - - - - -1- - - - - - - - - -1- - - - - - - - - -1- - - - - - - - -
1 1 
1 1 
1 
o +---------1---------1---------~--------_r--------_+--------~ 
40 50 60 70 80 90 100 
Variable Speed PCU Shaft Speed (krpm) 
• 
.-fr- DBPCS 
Constant 
Speed PCU 
-.-CCSS 
Constant 
Speed PCU 
~DBPCS 
Variable 
Speed PCU 
...... CCSS 
Variable 
Speed PCU 
DBPCS=Dual Brayton Power Conversion System; CCSS=Closed Cycle System Simulation 
Pre-Decisional , For Discussion Purposes Only www.nasa .gov 15 
National Aeronautics and Space Administration 
Fission Surface Power Concept 
• Modular 40 kWe System with 8-Year Design Life suitable for (Global) 
Lunar and Mars Surface Applications 
• Emplaced Configuration with Regolith Shielding Augmentation Permits 
Near-Outpost Siting «5 rem/yr at 100 m Separation) 
• Low Temperature, Low Development Risk, Liquid-Metal (NaK) Cooled 
Reactor with U02 Fuel and Stainless Steel Construction 
Radiator P",.",n. 
-.-------------16m----------------
Main Radiators 
Cavity Radiators 
NaK Pumps !i:iQ~~~;';':., 
Shield 
Reactor 
r 
4m 
1 
Pre-Decisional, For Discussion Purposes Only www.nasa.gov '6 
National Aeronautics and Space Administration 
Direct Drive Gas Brayton 
• 2 kW Closed Brayton Power Conversion 
Unit from Solar Dynamic Ground Test 
- Modified for Prometheus-JIMO Power 
Conversion tests 
- Flight-like Brayton: 900K Turbine Inlet, 
300K Compressor Inlet, 52000 rpm, He-
Xe Working Fluid 
• Direct Drive Gas (DOG) Reactor 
Simulator from MSFC 
- Designed & tested during JIMO with non-
representative heat sink 
- Pin heater elements in core-like bundle 
- Stainless steel clad & vessel 
• Completed integration & initial checkout 
testing at GRC Dec-08 
• Full performance characterization and 
controls test completed in Feb-09 
- Temperature Control 
- Simulated Reactor Feedback 
Pre-Decisional , For Discussion Purposes Only www.nasa.gov " 
National Aeronautics and Space Administration 
DOG Brayton Reactivity Simulations • 
Response to Brayton Speed Decrease 
OOOO~-,~,-,---~~~~~~~~ I Heater Inout Power C'Ne) 
-
-- - -
600 I - Alternator OJtput PowerC'Ne) 
400 
200 
, , , 
:['---, -, ,-=-, ,"'~&-.,T=-{: 1 
0.010 ! j ~E~ t------.. ------, ~ L = Rw~'= 
-0.010 ,~: ,-
o 10 20 30 40 50 60 70 80 
Time (rnn) 
Pre-Decisional , For Discussion Purposes Only 
Response to Neg. Reactivity Insertion 
OOOOr-~-'--~--~~~~~--~~ I Heater Input Power C'Ne) 
6000 r 
4000 r 
400 
2OOt- -------------J 
o 20 
, I 
40 60 
Time (min) 
80 100 
www.nasa.gov I. 
Technology Demonstration Unit - Objectives 
National Aeronautics and Space Administration 
• • 
• Reduce FSP Development Risk • Benchmark Analytical Codes 
• Verify System-Level Performance in 
Realistic Environment 
• Gain System Operations Experience for 
the NASA/DOE Team 
• Characterize Component Performance 
in a System Context 
• Expand Industrial Infrastructure for 
Component Design and Fabrication 
• Obtain Operational Data under Steady-
State and Transient Conditions 
• Obtain As-Built Mass and Cost Data 
• Provide Tangible and Measurable 
Technology Milestone • Develop System Control Methods 
" 
-
" 
111111111111 III~III 111111111111 \ H2O - 12kWe ,-,\.6m (-375K) 
- I 
111111111111 111111111111 1111111111 11 
Olav. 1 ~ , II ~oK J .t-i " (-8S0K) W ( 
, ' I:. - J -48 kW, 
, 'Sim / 
,lbEMl1 B-b ©!© ~)C: ~ -~ 
-2.1 It 1.7 m ell . 
, '@} GRC Vacuum Facility #6 : ~ _ _ DIll Power 
, Acq. &: - - - Mpu 
~ - - - - - - - - Control &:DiII. 
Pre-Decisional , For Discussion Purposes Only 
Notional TDU Test 
Layout in GRC 
Vacuum Facility #6 
www.nasa.gov '9 
. 
Full-scale Power Conversion Unit Contracts 
e ' National Aeronautics and Space Adm inistration 
• Two Phase I Design & Analysis contracts awarded May-OB 
- Sunpower (Stirling) and Barber Nichols (Brayton) 
- Approach provides parallel and diverse design path for Full-scale (12 kWe) PCU for 
FSP Technology Demonstration Unit (TDU) 
- Both Final Design Reviews completed in Apr-09 at GRC 
- Only one contractor will be selected for Phase II Fabrication & Test (Summer 2009) 
Flil 
- ~ Station r------------ -- -- ----------- -- ----------- Console 
, , , 
data : , 
-375KH20 , 
toHRS fromHRS 
, 
Converter , 
Cold-Side HX I Controller A./VV' I Alternator Startup & Control I 
Engine-
rectlfiC8ti°1 
Voltage ~ Alternator 400V Regulation Disconnect 120V DC AC to DC Bus 
I I I 
Parasitic Load 
Hot-Side HX 
-a5OKNaK to Ht Source ~vacuum Facility from HI Source 
-----
--' -
Pre-Decisional , For Discussion Purposes Only www.nasa.gov 20 
National Aeronautics and Space Administration 
• Full-scale 12 kW PCU Designs 
Courtesy of Sunpower Courtesy of Barber Nichols 
Pre-Decisional , For Discussion Purposes Only www.nasa.gov 21 
• National Aeronautics and Space Administration 
Summary • 
• Long History of Closed Brayton Technology Development within 
NASA & DOE 
- Brayton Rotating Units 
- Solar Dynamic Brayton 
- SP-100 Brayton 
- Dynamic Isotope Power System 
- Jupiter Icy Moons Orbiter 
- Fission Surface Power 
• Primary Benefits of Brayton include: 
- High Efficiency 
- Scalable to High Power 
- Potential for Long Life and High Reliability 
- Readily Adaptable to Solar and Nuclear Heat Sources 
- Simple and Efficient Electrical Integration 
Pre-Decisional , For Discussion Purposes Only www.nasa.gov 22 


A Summary of Closed Brayton Cycle Development Activities at NASA

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