The increasing use of unattended sensors by the Information, Surveillance, and Reconnaissance community requires the development of higher power and energy density sources to provide increased capabilities and operation time while minimizing size and weight. Among the emerging power sources, fuel cell (FC) systems potentially offer an improved alternative to existing solutions. The Communications and Electronics Research and Development and Engineering Center/Command, Power & Integration Directorate/Army Power Division's Power Sources branch has been evaluating fuel cells to meet tactical power military applications. Testing of methanol based FC systems indicates 50% weight savings over a secondary Li-ion rechargeable system at 200 W h, and 30% weight savings over a primary Li battery at 600 W h. However, significant technical barriers to fuel cell based power sources for sensor deployment exist, including requirements for additional size and weight reduction to meet portable sensor design requirements. Additionally, testing of FC systems demonstrate the importance of appropriate battery hybridization to maintain load following as well as increasing system power density. A comparison of a Reformed Methanol FC system and a Direct Methanol FC system was also completed, and results for the system size, weight, and fuel consumption are similar for both technologies. To examine the benefits of larger power fuel cells appropriate for stationary unattended sensor use, a comparison of power and weight available from a solar/battery hybrid system versus a solar/battery/RMFC hybrid system was also completed. Although the solar/battery hybrid system's size and weight are larger than the hybrid system with an FC unit, 14 kg versus 8 kg, respectively, there is significant logistic burden when utilizing a FC system due to its methanol refueling requirement.

References

1.
Walsh
,
D.
,
2012
, “
Ground Sensors Play Key Role in Battlefield Snooping
,” Defense Systems, August 2012, pp
36
38
.
2.
L-3 Communication Systems
, “
REMBASS-II/AN/GSR-8(V): Remotely Monitored Battlefield Sensor System—II
,” datasheet, http://www2.l-3com.com/cs-east/pdf/rembassii.pdf
3.
L-3 Communication Systems
, “
BAIS AN/PRS-9-Battlefield Anti-Intrusion System
,” data sheet.
4.
ARA Sensor Systems
, “
E-UGS Expendable Unattended Ground Sensors
,” data sheet.
5.
Tenney
,
S.
,
Mays
,
B.
,
Hillis
,
D.
,
Tran-Luu
,
D.
,
Houser
,
J.
, and
Reiff
,
C.
,
2004
, “
Acoustic Mortar Localization System Results From OIF
,” Defense Technical Information Center, Fort Belvoir, VA.
6.
Viveiros
,
E.
,
Wellman
,
R.
,
Clark
,
J.
,
Tahmoush
,
D.
,
Silvious
,
J.
,
Kurtz
,
J.
,
Wikner
,
D.
,
Adler
,
E.
,
2010
, “
An Unattended, Unmanned, and Man-Portable Tactical Doppler Radar
,” 2010 Tri-Service Radar Symposium, Orlando, FL, June 21–25.
7.
Textron Defense Systems
, “
MicroObserver®—Textron Defense Systems' Suite of Unattended Ground Sensors
,” data sheet.
8.
Pandya
,
N.
, “
The Power of Slew-to-Cue Surveillance Capability
,” FLIR Systems Inc., Technical Notes, http://gs.flir.com/surveillance-products/surveillance-technology/radar-technotes/slew-to-cue-surveillance
9.
Morse
,
J. D.
,
2007
, “
Micro-Fuel Cell Power Sources
,”
Int. J. Energy Res.
,
31
, pp.
576
602
.10.1002/er.1281
10.
Novoa
,
J.
,
Shah
,
S.
,
Jong
,
M.
de, Dominick
,
M.
, and
Kowal
,
J. J.
,
2009
, “
US Army CERDEC Field Evaluation and Testing of Soldier and Man-Portable Fuel Cell Power Sources
,”
2009 Fuel Cell Seminar & Expo
,
Palm Springs, CA
, November 16–19.
11.
Xie
,
C.
,
Bostaph
,
J.
, and
Pavio
,
J.
,
2004
, “
Development of a 2W Direct Methanol Fuel Cell Power Source
,”
J. Power Source
,
136
(
1
), pp.
55
65
.10.1016/j.jpowsour.2004.05.025
12.
Mench
,
M.
,
2008
,
Fuel Cell Engines
,
John Wiley & Sons
,
Hoboken, NJ
, pp.
343
350
.
13.
Park
,
J.-Y.
,
Seo
,
Y.
,
Kang
,
S.
,
You
,
D.
,
Cho
,
H.
, and
Na
,
Y.
,
2012
, “
Operational Characteristics of the Direct Methanol Fuel Cell Stack on Fuel and Energy Efficiency With Performance and Stability
,”
Int. J. Hydrogen Energy
,
37
(
7
), pp.
5946
5957
.10.1016/j.ijhydene.2011.12.066
14.
Carlstrom
,
C.
,
2011
, “
Commercialization of 1 Watt Consumer Electronics Power Pack
,” Project ID: H2RA001, DOE H2 & Fuel Cells Program Report 2011 Annual Merit Review, http://www.hydrogen.energy.gov/annual_review11_arra.html
15.
Pearson
,
K.
,
2011
, “
Forward Deployable Renewable Energy
,” Joint Service Power Expo 2011, Myrtle Beach, SC, May 2–5.
16.
Motyka
,
T.
,
2011
, “
Development of High Capacity Portable Power Systems
,” 2011 Fuel Cell Seminar Orlando, FL, October 31–November 3.
17.
Bender
,
G.
,
Angelo
,
M.
,
Bethune
,
K.
,
Dorn
,
S.
,
Thampan
,
T.
, and
Rocheleaua
,
R.
,
2009
, “
Method Using Gas Chromatography to Determine the Molar Flow Balance for Proton Exchange Membrane Fuel Cells Exposed to Impurities
,”
J. Power Source
,
193
(
2
), pp.
713
722
.10.1016/j.jpowsour.2009.04.028
18.
SAFT
, “
Primary Lithium Battery LS 17500, Document No 31029-2-0710
,” data sheet.
19.
NAL Research Corporation
,
2012
, “
General Description of Model A3LA-RS Version 1.0
,” Document No. TN2012-02-V1.0 2012.
20.
Palo
,
D.
,
Dagle
,
R.
, and
Holladay
,
J.
,
2007
, “
Methanol Steam Reforming for Hydrogen Production
,”
Chem. Rev.
,
107
, pp.
3992
4021
.10.1021/cr050198b
21.
Ratcliff
,
M.
,
Posey
,
F.
,
Johnson
,
D.
, and
Chum
,
H.
,
1985
, “
Operational Study of a Phosphoric Acid Fuel Cell With Hydrogen and Methanol/Steam
,”
J. Electrochem. Soc.
,
132
(
3
), pp.
577
582
.10.1149/1.2113909
You do not currently have access to this content.