IC Engine Design Strategies Vs Exhaust Emissions
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Transcript of IC Engine Design Strategies Vs Exhaust Emissions
IC Engine Design Strategies Vs Exhaust Emissions
P M V Subbarao
Professor
Mechanical Engineering Department
An Efficient Engine Design is not Obviously Eco-friendly Design…
Concentration of any chemical is pollution but not the quantity…..
Emission sources in a gasoline fuelled car
Emission sources in a diesel engine powered bus
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Adverse Health Effects of IC Engine Generated Air Pollutants
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Pollutants Short-term health effects Long-term health effectsCarbon
monoxideHeadache, shortness of
breath, dizziness, impaired judgment, lack of motor
coordination
Effects on brain and central nervous system, nausea, vomiting, cardiac and pulmonary functional
changes, loss of consciousness and death
Nitrogen dioxide Soreness, coughing, chest discomfort, eye irritation
Development of cyanosis especially at lips, fingers
and toes, adverse changes in cell structure of lung wall
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Oxidants Difficulty in breathing, chest tightness, eye
irritation
Impaired lung function, increased susceptibility to
respiratory functionOzone Similar to those of NO2 but
at a lower concentrationDevelopment of
emphysema, pulmonary edema
Sulfates Increased asthma attacks Reduced lung function when oxidants are present
TSP/Respirable suspended particulate
Increased susceptibility to other pollutants
Many constituents especially poly-organic
matter are toxic and carcinogenic, contribute to
silicosis, brown lung
Emissions Control
• Three basic methods used to control engine emissions:
• 1)Engineering of combustion process -advances in fuel injectors, oxygen sensors, and on-board computers.
• 2) Optimizing the choice of operating parameters -two Nox control measures that have been used in automobile engines are spark retard and EGR.
• 3) After treatment devices in the exhaust system -catalytic converter.
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Three chemical reactions form the Zeldovich reaction are:
Zelodvich reaction is the most significant mechanism of NO formation in IC engines.
Forward rate constants:
Tk
Tk
Tk
f
f
f
/450exp101.7
/4680exp108.1
/38370exp108.1
10,3
7,2
11,1
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Global Reaction Rate
• Using the chemical reactions given, one can write the following expression for the rate of change of nitric oxide concentration.
• Where the brackets denote concentrations in units of molecules/m3.• Approximations to solve above equation:
• The C-O-H system is in equilibrium and is not perturbed by N2 dissociation.
• This means that the pressure, temperature, equivalence ratio and residual fraction of fluid element only are required to calculate NO concentration.
• N atoms change concentration by a quasi-steady process.• This means that one can solve for the N atom concentration by
setting the rate of change of atoms to zero.
HNOkOHNkONOkONkNNOkNOkdt
NOdbfbfbf ,3,3,22,2,12,1
0,3,3,22,2,12,1 HNOkOHNkONOkONkNNOkNOkdt
Ndbfbfff
Using two approximations together:
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1
12
1
160
RRR
R
pdt
dxNO
Where xNO is mass fraction of NO and is the ratio of instantaneous NO mass fraction to equilibrium mass fraction of NO.
eNO
NO
x
x
,
eef
eef
eef
OHNkR
ONkR
NOkR
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2,22
2,11
Practical Aspects of NOx Reactions
• NO formation is kinetically controlled.
• The NOx reactions are quasi steady.
• The concentrations of [O2], [O], [OH], [H] & [N2] are in equilibrium.
• Formation of N is slow and hence [N] is always in steady state.
• The practical kinetics of formation of NO shows:
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Effect of Equivalence Ratio on NO Concentration
Effect of Various Parameters on NO Concentration
Increased spark advance and intake manifold pressure both result in higher cylinder temperatures and thus higher NO concentrations in the exhaust gas
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Exhaust NO Concentration Reduction
Since the formation of NO is highly dependent on cylinder gas temperatureany measures taken to reduce the AFT are effective:
• increased residual gas fraction• exhaust gas recirculation (EGR)• moisture in the inlet air
In CI engines the cylinder gas temperature is governed by the load and injection timing
EGR for Reduction of NO
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EGR System
The EGR flow is directed by a solenoid valve that is controlled by the Power train Control Module (PCM). The PCM uses inputs such as engine speed, intake-manifold pressure, and engine temperature to determine how much exhaust flow to meter back to the air-fuel mixture.
Closing Remarks on NO Control
• Unfortunately, EGR also reduces flame speed.
• Excessive EGR rates can slow burn rate so drastically as to cause surge, misfire, and other combustion problems.
• However, EGR can increase fuel economy.
• When used optimally, EGR can reduce NO and improve fuel economy while avoiding rough engine operation.
• This optimum varies with speed, load, and engine design.
• Nox also varies with spark timing.
• More spark advance means that parts of the mixture spend more time at high temperatures, so more NO is formed.
Hydrocarbon Emission Sources
Crevices – these are narrow regions in the combustion chamber into which the flame cannot propagate because it is smaller than the quenching distance.Crevices are located around the piston, head gasket, spark plug and valve seats and represent about 1 to 2% of the clearance volume.The crevice around the piston is by far the largest, during compression the fuel air mixture is forced into the crevice and released during expansion.
Hydrocarbon Emission Sources for SI Engines
There are six primary mechanisms believed to be responsible for hydrocarbon emissions:
% fuel escaping Source normal combustion % HC emissions
Crevices 5.2 38Oil layers 1.0 16Deposits 1.0 16Liquid fuel 1.2 20Flame quench 0.5 5Exhaust valve leakage 0.1 5
Total 9.0 100
RT
pxx
Tdt
HCdOHC 2
ˆˆ18735
exp107.6 15
HC emission control:
• Three basic types of emission control systems are used in modern vehicles; pre-combustion, post-combustion and evaporating control system.
• Pre-combustion control; (Positive Crankcase Ventilation (PCV).
• Engine Modification System; (Secondary air or air injector systems, and Catalytic converters).
• The evaporative control system; (traps the fuel vapors from fuel tank, maniolds and carburetor).
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Setting of Air/fuel Ration at Idling Conditions
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Selection of Idling RPM Vs HC Emissions
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Coolant Temperature Vs HC Emissions
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Ignition Timing Vs HC Emissions
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Effect of Misfiring on HC Emissions
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Bore to Stroke Ratio Vs HC Emissions
• There will be a direct consequence of lower heat losses at high S/B ratio and much greater than combustion higher combustion temperatures,.
• These are associated with increasing the stroke and making the chamber portions more lean.
• It could be speculated that the long-stroke (small-bore) engine would be advantageous in terms of unburned hydrocarbon emissions since crevice volumes, and hence trapped unburned charge in such volumes, much smaller in the small-bore engine.
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