Under contract to the Department of Energy (DOE), Lockheed Martin Space Systems Company (LMSSC) has been developing the Advanced Stirling Radioisotope Generator (ASRG). The use of Stirling technology introduces a four-fold increase in conversion efficiency over Radioisotope Thermoelectric Generators (RTGs), and thus the ASRG in an attractive power system option for future science missions. In August of 2008, the ASRG engineering unit (EU) was delivered to NASA Glenn Research Center (GRC). The engineering unit design resembles that of a flight unit, with the exception of electrical heating in place of a radioisotope source. Prior to delivery, GRC personnel prepared a test station continuous, unattended operation of the engineering unit. This test station is capable of autonomously monitoring the unit's safe operation and recording. , .. , .... performance data. Generator parameters recorded include temperatures, electrical power output, and thelmal power input. Convertor specific parameters are also recorded such as alternator voltage, current, piston amplitude, and frequency. Since November 2008, the ASRG EU has accumulated over 4,000 hours of operation. Initial operation was conducted using the AC bus control method in lieu of the LMSSC active power factor connecting controller. Operation on the LMSSC controller began in February 2009. This paper discusses the entirety of ASRG EU operation thus far, as well as baseline performance data at GRC and LMSSC, and comparison of performance using each control method

Oriti, Salvatore

Schifer, Nicholas

NASA Technical Reports Server

Oral Presentation/Viewgraph Summary: 
Under contract to the Department of Energy (DOE), Lockheed Martin Space Systems Company (LMSSC) 
has been developing the Advanced Stirling Radioisotope Generator (ASRG). The use of Stirling 
technology introduces a four-fold increase in conversion efficiency over Radioisotope Thermoelectric 
Generators (RTGs), and thus the ASRG in an attractive power system option for future science missions. 
In August of 2008, the ASRG engineering unit (EU) was delivered to NASA Glenn Research Center (GRC). 
The engineering unit design resembles that of a flight unit, with the exception of electrical heating in 
place of a radioisotope source. Prior to delivery, GRC personnel prepared a test station continuous, 
unattended operation of the engineering unit. This test station is capable of autonomously monitoring 
the unit's safe operation and recording. , .. , .... performance data. Generator parameters recorded 
include temperatures, electrical power output, and thelmal power input. Convertor specific parameters 
are also recorded such as alternator voltage, current, piston amplitude, and frequency. Since November 
2008, the ASRG EU has accumulated over 4,000 hours of operation. Initial operation was conducted 
using the AC bus control method in lieu of the LMSSC active power factor conecting controller. 
Operation on the LMSSC controller began in February 2009. This paper discusses the entirety of ASRG 
EU operation thus far, as well as baseline performance data at GRC and LMSSC, and comparison of 
performance using each control method. 
https://ntrs.nasa.gov/search.jsp?R=20120016779 2019-08-30T23:11:23+00:00Z
Recent Stirling Conversion Technology 
Developments and Operational 
Measurements 
7th International Energy Conversion 
Engineering Conference 
August 4, 2009 
Salvatore Oriti & Nicholas Schifer 
NASA Glenn Research Center 
RPT - Thermal Energy Conversion Branch 
Glenn Research Center 
at Lewis Field • 
Topics 
Advanced Stirling Radioisotope Generator (ASRG) support 
1 . Convertor acoustic characterization 
• Develop performance metric for extended operation 
2. Electromagnetic interference (EM I) mitigation via bucking coil and 
permalloy vessel 
• Experimental measurements on a pair of convertors 
New Stirling conversion techniques: 
3. Multiple-cylinder alpha: Higher power density 
• One of first demonstrations of free-piston in alpha arrangement 
4. Thermoacoustic: Eliminates displacer 
• No hot-end moving components, gas shuttled by high amplitude 
traveling wave 
Glenn Research Center 
• at Lewis Field 
Acoustic Emission Characterization 
• GAC is operating up to 16 convertors in continuous unattended 
mode: 
Performance parameters: Temperatures, power output, 
efficiency 
All external measurements: provides little information 
about internal components 
• Acoustic sensors can be used to monitor vibrations through 
convertor surfaces: 
Used to detect changes in gas bearing performance, 
displacer spring 
Methodology : develop first baseline signature, collect 
data every 1,000 hours 
Acoustic sensors capable of high frequency (100-600 
kHz) for sound waves through metal 
Accelerometers typically used to monitor bulk test article 
motion (-100 Hz) 
• Sensors: Physical Acoustics Corp. Micro30S 
100 to 600 kHz operating range 
Loaded onto convertor altemator housing with custom-
fabricated clamp for precise preload control 
Acoustic sensor and piston position signals routed to 
Yokogawa DL750 oscilloscope 
Sampled at 1 MHz for periods of 100 ms (10 convertor 
cycles) , capable of storing 100 s of sampled data 
Glenn Research Center 
at Lewis Field 
Convertor Alternator 
• 
Acoustic Emission Characterization 
• Majority of measurements taken on Advanced Stirling Convertors (ASC) 
• Common pattern found 
- Two pulses : midpoint of piston stroke in each direction 
- At least one secondary pulse 
• Some convertor acoustic signatures remained constant , others exhibited variances in some 
features: 
- Some secondary pulses varied in intensity and phase position 
- Some convertors exhibited multiple secondary pulses 
ASC -1 HI'1 
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Glenn Research Center 
• at Lewis Field 
Acoustic Emission Characterization 
• Observed acoustic emissions during deliberately disrupted convertor operation: 
Inoperable gas bearings 
Piston to displacer and planar spring contact 
Loose planar spring fasteners 
• Conclusions: 
1. Gas bearing operability did not change acoustic signature 
2. Contact between piston and displacer or planar spring resulted in sensor saturation 
3. Loose planar spring fasteners also resulted in sensor saturation 
4. Severe convertor disruptions can be detected 
5. For extended operation : baseline signatures can be compared to data collected at regular intervals (1,000 hours) 
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Glenn Research Center 
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AE (nohill 
at Lewis Field • 
• 
• 
Electromagnetic Interference (EMI) Mitigation 
ASRG system spec. for dc and ac magnetic field strength 
Specified at 1.0 m distance from center of convertor pair 
dc measured in nanoTesla, ac in dBpT 
Initial single convertor EMI measurements - August 2006 
Single convertor: ASC-1 #2 at Rocketdyne, Canoga Park, CA 
dBpT = 2010g( M J 
IpT 
Four configurations: unshielded, mu-metal shield, permalloy shield , double shield 
Up to 15 dBpT (83 %) reduction in ac magnetic field strength with double shield 
Conclusion: Commercially available magnetic-shielding materials were effective and attenuating ac magnetic field 
• Dual-opposed convertor EMI measurements - June 2007 
ASC-1 #3 and #4 at Glenn Research Center (GRC) 
Baseline unshielded EMI measurements on a pair of convertors in configuration similar to ASRG 
ac magnetic field strength at 1.0 m was 11 dBpT higher than ASRG system specification 
Conclusion : Explore mitigation techniques 
Glenn Research Center 
at Lewis Field • 
Electromagnetic Interference (EMI) Mitigation 
• GRC developed bucking coil investigation - December 2007 
Coil of magnet wire situated around outer diameter of alternator housing 
Wired electrically in series with alternator output 
With optimum number of turns, produced magnetic field that nullifies alternator emission 
Installed on ASC-1 #3 and #4, tested at GRC 
Up to 18 dBpT (87 %) reduction in ac magnetic field strength at 1.0 m : well below ASRG system spec. 
Conclusion : A simple coil around the alternator housing was capable of attenuating ac magnetic field emissions 
below the system specification 
• ASRG-EU EMI testing - March 2008 
EMI test of engineering unit generator at Lockheed Martin 
dc magnetic field lower than GPHS-RTG 
ac magnetic field comparable to dual-opposed ASC-1 #3 and #4 measurements 
• Magnetic-shielding alternator housings - June 2009 
Housings fabricated of Carpenter Technology 
Perm-49 (permalloy) 
Integrates shield into convertor construction : 
avoids extra mass of retrofitted shield 
Installed and tested on ASC-1 #3 and #4 
Results to be published in near future 
Glenn Research Center 
Hot·end 
insulation 
containment 
Alternator 
housing 
Bucking coil 
at Lewis Field 
Thermoacoustic Stirling Power Conversion 
• Traditional free-piston machine uses displacer to shuttle gas between hot and cold temperatures 
• Thermoacoustic eliminates displacer 
Working gas shuttled by high-amplitude acoustic wave 
Gas goes through same pressure and volume cycle 
No hot-end moving components 
Flat Plate Hot Heat Exchanger 
Thermal 
Buffer 
Tube 
Memator 
Interface 
Flange 
. ,. . 
/~:":--:i ,..-;-" . .0;- / "";'j"';-, "7 
Regenerator 
Reject HX 
Jet Pump 
Compliance 
Inertance Line 
Thermoacoustic configuration 
Image courtesy of North rop Grumman 
Glenn Research Center 
HeatorHoad 
OI.placor 
Heat Exchangers 
Displacer-based Stirling convertor 
Image courtesy of Sunpower 
at Lewis Field 
Planar Olsplaeer Spring 
Gas Bearing Cavity 
FloxRod 
Gas Bearing Pad. 
BOLrlCe Space 
• 
• 
• 
• 
• 
Thermoacoustic Stirling Power Conversion 
Research hardware produced by two thermoacoustic Stirling technology development contracts 
funded by NASA 
Northrup Grumman - 2003 
One heat engine with two dual-opposed pistons 
sharing working space 
Demonstrated 57 We at 17.9 % thermal-to-electric 
efficiency 
Underwent checkout testing at GRC 
• 
• 
• 
Sunpower - 2008 
Single coaxial thermoacoustic engine with single 
piston/altemator 
Demonstrated 50 We at 17.9 % thermal-to-electric 
efficiency 
Thermoacoustic Stirling being investigated for Venus lander power 
May offer attractive option at up to 200 °C hot-end operation temperature 
Facility being prepared at GRC for research and operation of both prototypes 
Glenn Research Center 
at Lewis Field • 
Multiple-cylinder Alpha Stirling 
• Most recent free-piston Stirling technology development 
focused on beta configuration 
Two moving components 
Coaxial piston and displacer 
Displacer only moves gas, doesn't seal pressure 
Piston seals working gas pressure wave from bounce 
space 
Piston sees little to no temperature gradient 
• Multiple-cylinder alpha configuration 
One moving component per cylinder 
Expansion space of one cylinder connected to 
compression space of next cylinder 
Each piston motion phase difference determined by 
number of cylinders - 90 0 for 4 cylinder 
arrangement 
Pistons move working gas and produce power 
Double acting pistons offer higher power density 
Piston seals working gas pressure wave across 
temperature gradient 
Piston sees little to no temperature gradient 
Long history in kinematic version 
For long life (free-piston) syncronization is not trivial 
Glenn Research Center 
Stlrtlng Workng Space 
Heater Head 
Ol. pl_ 
Heat Exc:hang .... 
Beta configuration Stirling convertor 
Image courtesy of Sunpower 
• 
Multiple-cylinder alpha configuration 
at Lewis Field 
Planar Displacer Spring 
Gas Bearing Cavity 
Flex Rod 
Gal Bearing Pads 
BOl.l'1CeSpace 
Multiple-cylinder Alpha Stirling 
Small Business Innovative Research (SBIR) contract awarded to Sunpower and Global Cooling to 
investigate multiple-cylinder alpha designs 
• Phase I - 2005 
- Evaluated high power design space (5 to 25 kWe -lunar fission surface power) 
- Single cylinder beta and multiple-cylinder alpha 
- Novel three-cylinder arrangement showed potential for significant improvement over previous high 
power design from SP-100 project : 40% higher specific power, 34% higher efficiency 
• Phase II - Completed 2008 
- Goals: 
1. Design 15 kWe three-cylinder alpha convertor (30 kWe in dual-opposed configuration) 
2. Produce 100 We-class four-cylinder alpha demonstration convertor for research and code 
validation 
- Investigate effects specific to alpha configuration - temperature gradient seal loss, cylinder 
interconect dead volumes, off-resonance pistons 
- Converted existing four-cylinder cooler to convertor 
- Changed hot-end material 
- Installed electric heat source 
Glenn Research Center 
• at Lewis Field 
Multiple-cylinder Alpha Stirling 
• Phase II results: 
Demonstration convertor produced over 135 W at 290 °C hot-end, 50 °C cold-end (TR=1.74) 
Experimental results agreed well with thermodynamic code prediction 
• Delivered to GRC - June 2008 
Alternators 
Completed low-temperature checkout (180 °C hot-end) and performance mapping 
Performance mapping: 180 °C to 300 °C hot-end and 75% to full piston amplitude 
20 W at low-temperature condition and 115 We at full-temperature 
Demonstrated stable operation - pistons maintained 90 ° phasing with only electrical connectivity 
-- 180 ·C 
.... 220 ·( 
Performance Mapping - Power vs. Amplitude 260 ·C 
- 300 · ( 
120 ~--------
100 
~80 ~---~~~~~---~~~-­
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.3 
" • ~ 40 
~ 
20 ~----------------
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2.5 3 3.5 4 4.5 5 
Piston Amplitude, mm 
Four-cylinder free piston demonstration convertor at GRC. GRC performance mapping results at different hot-end temperatures 
and piston amplitudes 
Glenn Research Center 
at Lewis Field • 
. -
. . 
Conclusion 
Operational measurements: 
1. Acoustic emission characterization 
• Baseline acoustic emissions characterized for several convertors undergoing extended operation 
• Methodology developed to monitor convertor operation by comparing periodic acoustic emission 
data to baseline 
2. EMI mitigation 
• Baseline magnetic field measurements taken on pair of dual-opposed convertors 
• Bucking coil situated around alternator housing proven capable of reducing ac magnetic field to 
below ASRG system specification 
• Alternator housings fabricated of permalloy were installed and tested on a pair of convertors 
Technology developments: 
3. Thermoacoustic Stirling conversion 
• NASA contracts produced two operational 100 W-class thermoacoustic research convertors, 
demonstrating Stirling conversion with no hot-end moving components 
• Facility being built at GRC for further testing 
4. Multiple-cylinder alpha Stirling conversion 
• NASA SBI R produced operational 100 W-class four-cylinder free-piston demonstration convertor 
• Performance mapping completed 
Acknowledgment 
Some work described in this paper was performed for the Science Mission Directorate (SMD) and the Radioisotope Power 
System (RPS) Program, which provided funding for these projects. The opinions expressed in this paper are those of the 
author and do not necessarily reflect the views of the RPS Program 
Glenn Research Center 
• at Lewis Field 


Recent Stirling Conversion Technology Developments and Operational Measurements

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