Abstract

This paper addresses the need for efficiency gains in the modern industrial engine as utilized in combined heat and power (CHP) generation and other distributed generation situations. Power generation is discussed in terms of reciprocating-engine-based plant operating on Otto type thermodynamic cycles. The current state of the technology and the research being conducted is examined. Internal combustion engine performance improvement in the industrial engine sector focuses on improvements in the combustion characteristics of the plant, with emphasis on areas such as piston design, valve timing, and supercharging. Maximum brake-thermal efficiencies, in percentage terms, are currently in the 40s. In CHP generation, most of the energy not utilized for mechanical power is recovered as heat from various engine systems, such as jacket water and exhaust, and utilized for space or process heating. In other distributed generation situations, this energy is not utilized in this manner and is lost to the surroundings. While second law analysis would provide a more meaningful interpretation of the efficiency defect, this approach is still not the norm. Distributed generation benefits directly from efficiency improvements; the more efficient use of primary energy leads to reduced fuel costs. Combined heat and power generation is, however, more sensitive to the matching between the plant and its energy sinks, as its successful implementation is dictated by the ability of a site to fully utilize the heat and electrical power produced by the plant. At present, the energy balance of such engines typically dictates that heat is produced in greater quantity than electrical power, the ratio being of the order of 1.1–1.5:1. Due to this production imbalance, it is accepted that in order to be economically feasible, thermal and electrical demand should be coincident and also all heat and power should be utilized. This has traditionally led to certain sectors being deemed unsuitable for CHP use. Some current research is aimed at tipping the production balance of these engines in favor of electrical power production; however, performance gains in this regard are slow. This paper concludes with some brief commentary on current industrial engine developments and applications.

1.
Stone
,
R.
, 1999,
Introduction to Internal Combustion Engines
,
Macmillan
,
London
.
2.
Heywood
,
J. B.
, 1998,
Internal Combustion Engine Fundamentals
,
McGraw Hill
,
New York
.
3.
Van Basshuysen
,
R.
, and
Schafer
,
F.
, 2004,
Internal Combustion Engine Handbook
,
SAE International
,
Warrendale, PA
.
4.
Badami
M. C. A.
,
Campanile
,
P.
, and
Anzioso
,
F.
, 2007, “
Performance of an Innovative 120 kWe Natural Gas Cogeneration System
,”
Energy
0360-5442,
32
, pp.
823
833
.
5.
Fleten
,
S. E.
,
Maribu
,
K. M.
, and
Wangensteen
,
I.
, 2007, “
Optimal Investment Strategies in Decentralized Renewable Power Generation Under Uncertainty
,”
Energy
0360-5442,
32
, pp.
803
815
.
6.
Fraser
,
P.
, 2002, “
Distributed Generation in Liberalised Electricity Markets
,” OECD/IEA.
7.
Themelis
,
N. J.
, and
Ulloa
,
P. A.
, 2007, “
Methane Generation in Landfills
,”
Renewable Energy
0960-1481,
32
, pp.
1243
1257
.
8.
2004, Deutz Power Systems (DPS) Technical Circular No. 0199-99-3017.
9.
Mayhew
,
Y.
, and
Rogers
,
G.
, 1992,
Engineering Thermodynamics
, 4th ed.,
Longman Scientific & Technical
,
Essex
.
10.
Roubaud
,
A.
, and
D.
Favrat
, 2005, “
Improving Performances of a Lean Burn Cogeneration Biogas Engine Equipped With Combustion Prechambers
,”
Fuel
0016-2361,
84
, pp.
2001
2007
.
11.
Oh
,
S. -D.
,
Oh
,
H. -S.
, and
Kwak
,
H. -Y.
, 2007, “
Economic Evaluation for Adoption of Cogeneration System
,”
Appl. Energy
0306-2619,
84
, pp.
266
278
.
12.
2004, Directive 2004/8/EC of the European Parliament and of the Council of 11 February 2004, on the promotion of cogeneration based on a useful heat demand in the internal energy market, amending Directive 92/42/EEC.
13.
DIT Energy Bureau
, 2008, available from http://bms.dit.ie/http://bms.dit.ie/.
14.
Panno
,
D.
,
Messineo
,
A.
, and
Dispenza
,
A.
, 2007, “
Cogeneration Plant in a Pasta Factory: Energy Saving and Environmental Benefit
,”
Energy
0360-5442,
32
, pp.
746
754
.
16.
Medrano
,
M.
,
Brouwer
,
J.
,
McDonell
,
V.
,
Mauzey
,
J.
, and
Samuelsen
,
S.
, 2008, “
Integration of Distributed Generation Systems Into Generic Types of Commercial Buildings in California
,”
Energy Build.
0378-7788,
40
, pp.
537
548
.
17.
Schneider
,
E. W.
, and
Blossfeld
,
D. H.
, 2003, “
Radiotracer Method for Measuring Real Time Piston Ring and Cylinder Bore Wear in Spark Ignition Engines
,”
Nucl. Instrum. Methods Phys. Res.
0167-5087,
505
, pp.
559
563
.
18.
Hannah
,
J.
, and
Hillier
,
M.
, 1995,
Applied Mechanics
,
Longman Scientific & Technical
,
Essex
.
19.
Silva
,
F. S.
, 2006, “
Fatigue on Engine Pistons—A Compendium of Case Studies
,”
Eng. Failure Anal.
1350-6307,
13
, pp.
480
492
.
20.
Kajiwara
,
H.
,
Fujioka
,
Y
,
Susuki
,
T.
, and
Negishi
,
H.
, 2002, “
An Analytical Approach for Prediction of Piston Temperature Distribution in Diesel Engines
,”
JSAE Rev.
0389-4304,
23
, pp.
429
434
.
21.
Al-Sarkhi
,
A.
,
Jaber
,
J. O.
, and
Probert
,
S. D.
, 2006, “
Efficiency of a Miller Engine
,”
Appl. Energy
0306-2619,
83
, pp.
343
351
.
22.
Zhao
,
Y.
, and
Chen
,
J.
, 2006, “
Performance Analysis of an Irreversible Miller Heat Engine and Its Optimum Criteria
,”
Appl. Therm. Eng.
1359-4311,
27
, pp.
2051
2058
.
23.
Wu
,
C.
,
Puzinauskas
,
P. V.
, and
Tsai
,
J. S.
, 2003, “
Performance Analysis and Optimisation of a Supercharged Miller Cycle Otto Engine
,
Appl. Therm. Eng.
1359-4311,
23
, pp.
511
521
.
24.
Wang
,
Y.
,
Lin
,
L.
,
Roskilly
,
A. P.
,
Zeng
,
S.
,
Huang
,
J.
,
He
,
Y.
,
Huang
,
X.
,
Huang
,
H.
,
Wei
,
H.
,
Li
,
S.
, and
Yang
,
J.
, 2005, “
Experimental Investigation of Applying Miller Cycle to Reduce NOx Emission From Diesel Engine
,”
Proc. Inst. Mech. Eng., Part A
0957-6509,
219
, pp.
631
638
.
25.
Wang
,
Y.
,
Lin
,
L.
,
Roskilly
,
A. P.
,
Zeng
,
S.
,
Huang
,
J.
,
He
,
Y.
,
Huang
,
X.
,
Huang
,
H.
,
Wei
,
H.
,
Li
,
S.
, and
Yang
,
J.
, 2007, “
An Analytic Study of Applying Miller Cycle to Reduce NOx Emission From Petrol Engine
,”
Appl. Therm. Eng.
1359-4311,
27
, pp.
1779
1789
.
26.
Kesgin
,
D.
, 2005, “
Effect of Turbocharging System on the Performance of a Natural Gas Engine
,”
Energy Convers. Manage.
0196-8904,
46
, pp.
11
32
.
27.
Katrasnik
,
T.
,
Medica
,
V.
, and
Trenc
,
F.
, 2005, “
Analysis of the Dynamic Response Improvement of a Turbocharged Diesel Engine Driven Alternating Current Generating Set
,”
Energy Convers. Manage.
0196-8904,
46
, pp.
2838
2855
.
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