This paper describes the development of a water-cooled, lean burn, gaseous fueled engine designed for distributed power installations. Electric generators have become popular because they provide a portable supply of electrical power at consumer demand. They are used in critical need areas such as hospitals and airports, and have found their way into homes frequented with power outages or homes in remote locations. Gensets are available in a wide variety of sizes ranging from 1 kilowatt (kW) to thousands of kilowatts. In the midrange, the power sources are typically spark-ignition, automotive type internal combustion engines. Since engines designed for automotive use are subject to different emission regulations, and are optimized for operation at revolutions per minute (RPM) and brake mean effective pressures (BMEPs) above that of electric generator engines, modifications can be made to optimize them for gensets. This work describes modifications which can be made during remanufacturing an automotive engine to optimize it for use as a generator engine. While the work recognizes the potential for cost savings from the use of remanufactured automotive engines over that of using new automotive engines and the majority of the design constraints were adopted to reduce engine cost, the main focus of the work is quantifying the increase in fuel efficiency that can be achieved while meeting the required EPA emission requirements. This paper describes the seven combustion chamber designs that were developed and tested during this work. Friction reduction was obtained in both valve train and journal bearing design. The engine optimized for fuel efficiency produced a maximum brake thermal efficiency (BTE) of 37.5% with λ = 1.63. This yielded an EPA test cycle average brake specific fuel consumption (BSFC) of 325 g/kW hr. Modification of the spark advance and low load equivalence ratio to meet EPA Phase III emission standards resulted in an EPA test cycle average BSFC of 330 g/kW hr. When the engine used in this research was tested in its unmodified, automotive configuration under the EPA compliant test cycle, its EPA test cycle average BSFC was 443.4 g/kW hr. This is a 34% increase in fuel consumption compared to the modified engine.

References

1.
Park
,
C.
,
Oh
,
S.
,
Kim
,
T.
,
Oh
,
H.
, and
Bae
,
C.
,
2014
, “
Combustion Characteristics of Stratified Mixture in Lean-Burn LPG Direct-Injection Engine With Spray-Guided Combustion System
,”
ASME
Paper No. ICEF2014-5531.
2.
Quader
,
A. A.
,
1974
, “
Lean Combustion and the Misfire Limit in Spark Ignition Engines
,”
SAE
Paper No. 741055.
3.
Lancaster
,
D.
,
Krieger
,
R.
, and
Lienesch
,
J.
,
1975
, “
Measurement and Analysis of Engine Pressure Data
,”
SAE
Paper No. 750026.
4.
Quader
,
A. A.
,
1976
, “
What Limits Lean Operation in Spark Ignition Engines-Flame Initiation or Propagation?
,”
SAE
Paper No. 760760.
5.
Perry
,
G. C.
,
Ursu
,
B.
,
Filetti
,
T.
, and
Yip
,
D.
,
1996
, “
Injected Heavy-Duty Propane Engine
,”
SAE
Paper No. 961688.
6.
Alasfour
,
F. N.
,
2002
, “
LPG Fueled Engine Under Kuwait Summer Climate
,”
ASME
Paper No. ICES2002-444.
7.
Lee
,
D.
,
Shakai
,
J.
,
Goto
,
S.
,
Ishikawa
,
H.
,
Ueno
,
H.
, and
Harayama
,
N.
,
1999
, “
Observation of Flame Propagation in an LPG Lean Burn SI Engine
,”
SAE
Paper No. 1999-01-0570.
8.
Alger
,
T.
,
Mehta
,
D.
,
Chadwell
,
C.
, and
Roberts
,
C.
,
2005
, “
Laser Ignition in a Pre-Mixed Engine: The Effect of Focal Volume and Energy Density on Stability and the Lean Operating Limit
,”
SAE
Paper No. 2005-01-3752.
9.
Khan
,
M. A.
,
Watson
,
H.
,
Baker
,
P.
,
Liew
,
G.
, and
Johnston
,
D.
,
2006
, “
SI Engine Lean-Limit Extension Through LPG Thottle-Body Injection for Low CO2 and NOx
,”
SAE
Paper No. 2006-01-0495.
10.
Akram
,
M.
,
Saxena
,
P.
, and
Kumar
,
S.
,
2012
, “
Laminar Burning Velocity of LPG–Air Mixture at Elevated Temperatures
,”
ASME
Paper No. GTINDIA2012-9728.
11.
Ibrahim
,
A.
, and
Ahmed
,
S.
,
2015
, “
Measurements of Laminar Flame Speeds of Alternative Gaseous Fuel Mixtures
,”
ASME J. Energy Resour. Technol.
,
137
(
3
), p.
032209
.
12.
Akram
,
M.
,
Saxena
,
P.
, and
Kumar
,
S.
,
2013
, “
Experimental and Computational Determination of Laminar Burning Velocity of Liquefied Petroleum Gas–Air Mixtures at Elevated Temperatures
,”
ASME J. Eng. Gas Turbines Power
,
135
(
9
), p.
091501
.
13.
Badr
,
O. A.
,
Elsayed
,
N.
, and
Karim
,
G. A.
,
1996
, “
An Investigation of the Lean Operational Limits of Gas-Fueled Spark Ignition Engines
,”
ASME J. Energy Resour. Technol.
,
118
(
2
), pp.
159
163
14.
Gatowski
,
J. A.
, and
Heywood
,
J. B.
,
1985
, “
Effects of Valve-Shrouding and Squish on Combustion in a Spark-Ignition Engine
,”
SAE
Paper No. 852093.
15.
Matsushita
,
S.
,
Inoue
,
T.
,
Nakanishi
,
K.
,
Okumura
,
T.
, and
Isogai
,
K.
,
1985
, “
Effects of Helical Port With Swirl Control Valve on the Combustion and Performance of S. I. Engine
,”
SAE
Paper No. 850046.
16.
Patrie
,
M. P.
,
Martin
,
J. K.
, and
Engman
,
T. J.
,
1998
, “
Inlet Port Geometry and Flame Position, Flame Stability, and Emissions in an SI Homogeneous Charge Engine
,”
SAE
Paper No. 982056.
17.
Li
,
L.
,
Wang
,
Z.
,
Wang
,
H.
,
Deng
,
B.
, and
Xiao
,
Z.
,
2002
, “
A Study of LPG Lean Burn for a Small SI Engine
,”
SAE
Paper No. 2002-01-2844.
18.
Thring
,
R. H.
, and
Overington
,
M. T.
,
1982
, “
Gasoline Engine Combustion—The High Ratio Compact Chamber
,”
SAE
Paper No. 820166.
19.
Khn
,
M.
,
Abthoff
,
R.
,
Kemmler
,
R.
, and
Kaiser
,
T.
,
1996
, “
Influence of the Inlet Port and Combustion Chamber Configuration on the Lean-Burn Behavior of a Spark-Ignition Gasoline Engine
,”
SAE
Paper No. 960608.
20.
Stone
,
R.
,
2012
,
Introduction to Internal Combustion Engines
,
SAE International and MacMillan Press
, Warrendale, PA.
21.
Nagayama
,
I.
,
Araki
,
Y.
, and
Lioka
,
Y.
,
1977
, “
Effects of Swirl and Squish on S.I. Engine Combustion and Emission
,”
SAE
Paper No. 770217.
22.
Nakamura
,
N.
,
Baika
,
T.
, and
Shibata
,
Y.
,
1985
, “
Multipoint Spark Ignition for Lean Combustion
,”
SAE
Paper No. 852092.
23.
Lumsden
,
G.
,
Eddleston
,
D.
, and
Sykes
,
R.
,
1997
, “
Comparing Lean Burn and EGR
,”
SAE
Paper No. 970505.
24.
Pozniak
,
D. J.
, and
Rydzewski
,
J. S.
,
1985
, “
A Study of In-Cylinder Air Motion in the General Motors VORTEC 4.3L, V-6 Engine
,”
SAE
Paper No. 850510.
25.
Bhale
,
P. V.
,
Ardhapurkar
,
P. M.
, and
Deshpande
,
N. V.
,
2005
, “
Experimental Investigations to Study the Comparative Effect of LPG and Gasoline on Performance and Emissions of SI Engine
,”
ASME
Paper No. ICES2005-1065.
26.
Ferguson
,
C. R.
, and
Kirkpatrick
,
A. T.
,
2000
,
Internal Combustion Engines: Applied Thermosciences
,
Wiley
, New York, p.
436
.
27.
Obert
,
E. F.
,
1997
,
Internal Combustion Engines
,
International Textbook Company
,
Scranton, PA
, p.
510
.
28.
Pipitone
,
E.
, and
Genchi
,
G.
,
2014
, “
Experimental Determination of Liquefied Petroleum Gas–Gasoline Mixtures Knock Resistance
,”
ASME J. Eng. Gas Turbines Power
,
136
(
12
), p.
121502
.
29.
Cullen
,
B.
, and
McGovern
,
J.
,
2009
, “
The Quest for More Efficient Industrial Engines: A Review of Current Industrial Engine Development and Applications
,”
ASME J. Energy Resour. Technol.
,
131
(
2
), p.
021601
.
30.
Mizushima
,
N.
,
Sato
,
S.
,
Ogawa
,
Y.
,
Yamamoto
,
T.
,
Sawut
,
U.
,
Takigawa
,
B.
,
Kawayoko
,
K.
, and
Konagai
,
G.
,
2009
, “
Combustion Characteristics and Performance Increase of an LPG-SI Engine With Liquid Fuel Injection System
,”
SAE
Paper No. 2009-01-2785.
31.
Baker
,
P.
, and
Watson
,
H.
,
2005
, “
MPI Air/Fuel Mixing for Gaseous and Liquid LPG
,”
SAE
Paper No. 2005-01-0246.
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