8 Oct 2011

AUTOMOTIVE POLLUTION AND CONTROL

AT1353 AUTOMOTIVE POLLUTION AND CONTROL 3 0 0 100

OBJECTIVES

To make the students to realize the impact of automobile emissions on the environment and expose student to factors affecting the formation and control of automobile pollutants.

UNIT – I INTRODUCTION 9

Vehicle population assessment in metropolitan cities and contribution to pollution, effects on human health and environment, global warming, types of emission, transient operational effects on pollution.

UNIT – II POLLUTANT FORMATION IN SI ENGINES 9

Pollutant formation in SI Engines, mechanism of HC and CO formation in four stroke and two stroke SI engines, NOx formation in SI engines, effects of design and operating variables on emission formation, control of evaporative emission. Two stroke engine pollution.

UNIT – III POLLUTANT FORMATION IN CI ENGINES 9

Pollutant formation in CI engines, smoke and particulate emissions in CI engines, effects of design and operating variables on CI engine emissions. Nox formation and control. Noise pollution from automobiles, measurement and standards.

UNIT – IV CONTROL OF EMISSIONS FROM SI AND CI ENGINES 9

Design of engine, optimum selection of operating variables for control of emissions, EGR, Thermal reactors, secondary air injection, catalytic converters, catalysts, fuel modifications, fuel cells, Two stroke engine pollution control.

UNIT – V MEASUREMENT TECHNIQUES EMISSION STANDARDS AND TEST PROCEDURE 9

NDIR, FID, Chemiluminescent analyzers, Gas Chromatograph, smoke meters, emission standards, driving cycles – USA, Japan, Euro and India. Test procedures – ECE, FTP Tests. SHED Test – chassis dynamometers, dilution tunnels.

TOTAL : 45

TEXT BOOKS

1. Paul Degobert – Automobiles and Pollution – SAE International ISBN-1-56091-563-3, 1991.

2. Ganesan, V- “Internal Combustion Engines”- Tata McGraw-Hill Co.- 2003.

REFERENCES

1. SAE Transactions- “Vehicle Emission”- 1982 (3 volumes).

2. Obert.E.F.- “Internal Combustion Engines”- 1988

3. Marco Nute- “ Emissions from two stroke engines, SAE Publication – 1998

UNIT – I INTRODUCTION

POLLUTION:

The mixing of unwanted and undesirable substances into our surroundings that cause undesirable effects on both living and non living things is known as pollution.

AIR POLLUTION:

Air pollution is defined as the addition of unwanted and undesirable things to our atmosphere that have harmful effect upon our planned life.

Major sources of Air pollution:

1. Automotive Engines

2. Electrical power generating stations

3. Industrial and domestic fuel consumption

4. Refuse burning of industrial processing, wastes etc.,

Sources of Pollutants from Gasoline Engine:

There are four possible sources of atmospheric pollution from a petrol engine powered vehicle. They are

1. Fuel Tank

2. Carburettor

3. Crank case

4. Engine

The amount of pollutants contributed by the above mentioned sources are as follows.

a.. Fuel tank evaporative loss 5 to 10 % of HC

b. Carburettor evaporative loss 5 % of HC

c. Crank case blow by 20 to 35 % of HC

d. Tail Pipe exhaust 50 to 60 % of HC and

almost all Co and NOx

Emittant as a Pollutant:

An emittant is said to be a pollutant when it has some harmful effect upon our surroundings.

The primary source of energy for our automotive vehicles is crude oil from underground which typically contains varying amounts of sulphur. Much of the sulphur is removed during refining of automotive fuels. Thus the final fuel is hydrocarbon with only a small amount of sulphur. If we neglect sulphur and consider complete combustion, only water and carbon dioxide would appear in the exhaust.

Water is not generally considered undesirable and therefore it is not considered as a pollutant. Likewise carbon dioxide is also not considered as pollutant in earlier days. But due to increase in global warming due to CO₂ which is a green house gas, now a days CO₂ is also considered as unwanted one.

Then apart from this we get sulphur dioxide a pollutant which is a product of complete combustion. Apart from this all the compounds currently considered as pollutants are the result of imperfect or incomplete combustion.

Pollutants Pollutant Effects

Unburned Hydro Carbons (UBHC) Photochemical Smog

Nitric Oxide Toxic , Photochemical Smog

Carbon monoxide Toxic

Lead compounds Toxic

Smoke combines with fog and forms a dense invisible layer in the atmosphere which is known as Smog. The effect of Smog is that it reduces visibility.

Effect of Pollutants on Environment:

a. Unburned Hydro Carbons ( UBHC ):

The major sources of UBHC in an automobile are the engine exhaust, evaporative losses from fuel system, blow by loss and scavenging in case of 2-stroke petrol engines.

Unburned or partially burned hydrocarbons in gaseous form combine with oxides of nitrogen in the presence of sunlight to form photochemical smog.

UBHC + NOx à Photochemical smog

The products of photochemical smog cause watering and burning of the eyes and affect the respiratory system, especially when the respiratory system is marginal for other reasons.

Some of the high molecular weight aromatic hydrocarbons have been shown to be carcinogenic in animals. Some of the unburned hydrocarbons also serve as particulate matter in atmosphere.

b. Carbon monoxide:

Carbon monoxide is formed during combustion in engine only when there is insufficient supply of air. The main source is the engine exhaust.

The toxicity of carbon monoxide is well known. The hemoglobin the human blood which carries oxygen to various parts of the body has great affinity towards carbon monoxide than for oxygen. When a human is exposed to an atmosphere containing carbon monoxide, the oxygen carrying capacity of the blood is reduced and results in the formation of carboxy hemoglobin. Due to this the human is subjected to various ill effects and ultimately leads to death.

The toxic effects of carbon monoxide are dependent both on time and concentration as shown in the diagram.

c. Oxides of Nitrogen ( NOx ) :

Oxides of nitrogen ( NO, NO₂ , N₂O₂ etc) are formed at higher combustion temperature present in engines and the engine exhaust is the major source.

Like carbon monoxide, oxides of nitrogen also tend to settle on the hemoglobin in blood. Their most undesirable effect is their tendency to join with moisture in the lungs to form dilute nitric acid. Because the amounts formed are minute and dilute, their effect is very small but over a long period of time cam be cumulatively undesirable, especially when the respiratory problems for other reasons are found.

Another effect is that, the oxides of nitrogen are also one of the essential component for the formation of photochemical smog.

d. Sulphur dioxide:

Sulphur dioxide from automotive vehicle is very less when compared to that emitted by burning coal. Sulphur dioxide combines with moisture in atmosphere and forms sulphuric acid at higher temperatures. This comes to the earth as acid rain.

Much of the sulphur dioxide combines with other materials in the atmosphere and forms sulphates which ultimately form particulate matter.

e. Particulates:

Particulate matter comes from hydrocarbons, lead additives and sulphur dioxide. Particulates when inhaled or taken along with food leads to respiratory problems and other infections.

Particulates when settle on the ground they spoil the nature of the object on which they are settling. Lead, a particulate is a slow poison and ultimately leads to death.

UNIT - II POLLUTANT FORMATION IN SI ENGINES

CHEMISTRY OF SI ENGINE COMBUSTION:

In a Spark ignition engine a perfectly mixed air fuel mixture enters the engine during suction stroke. The charge is compressed well and at the end of end of compression stroke, the charge is ignited by means of spark from spark plug. The air fuel mixture is delivered to engine by means of carburettor.

The quantity and quality of charge entering the engine is controlled according to the engine speed and load conditions.

GASOLINE ENGINE EMISSIONS

The emissions form gasoline powered automobiles are mainly

1. Unburned Hydro Carbons

2. Carbon monoxide

3. Oxides of nitrogen

4. Oxides of sulphur and

5. Particulates including smoke

Pollutant formation in Gasoline engine:

1. Hydrocarbons:

Hydrocarbon exhaust emission may arise from three sources as

a. Wall quenching

b. Incomplete combustion of charge

c. Exhaust scavenging in 2-stroke engines

In an automotive type 4-stroke cycle engine, wall quenching is the predominant source of exhaust hydrocarbon under most operating conditions.

a. Wall quenching:

The quenching of flame near the combustion chamber walls is known as wall quenching. This is a combustion phenomenon which arises when the flame tries to propagate in the vicinity of a wall. Normally the effect of the wall is a slowing down or stopping of the reaction.

Because of the cooling, there is a cold zone next to the cooled combustion chamber walls. This region is called the quench zone. Because of the low temperature, the fuel-air mixture fails to burn and remains unburned.

Due to this, the exhaust gas shows a marked variation in HC emission. The first gas that exits is from near the valve and is relatively cool. Due to this it is rich in HC. The next part of gas that comes is from the hot combustion chamber and hence a low HC concentration. The last part of the gas that exits is scrapped off the cool cylinder wall and is relatively cool. Therefore it is also rich in HC emission.

b. Incomplete combustion:

Under operating conditions, where mixtures are extremely rich or lean, or exhaust gas dilution is excessive, incomplete flame propagation occurs during combustion and results in incomplete combustion of the charge.

Normally, the carburettor supplies air fuel mixture in the combustible range. Thus incomplete combustion usually results from high exhaust gas dilution arising from high vacuum operation such as idle or deceleration.

However during transient operation, especially during warm up and deceleration it is possible that some times too rich or too lean mixture enters the combustion chamber resulting in very high HC emission.

Factors which promote incomplete flame propagation and misfire include:

a. Poor condition of the ignition system, including spark plug

b. Low charge temperature

c. Poor charge homogeneity

d. Too rich or lean mixture in the cylinder

e. Large exhaust residual quantity

f. Poor distribution of residuals with cylinder

Carburetion and mixture preparation, evaporation and mixing in the intake manifold, atomization at the intake valve and swirl and turbulence in the combustion chamber are some factors which influence gaseous mixture ration and degree of charge homogeneity including residual mixing.

The engine and intake system temperature resulting from prior operation of the engine affect charge temperature and can also affect fuel distribution.

Valve overlap, engine speed, spark timing, compression ratio, intake and exhaust system back pressure affect the amount and composition of exhaust residual. Fuel volatility of the fuel is also one of the main reasons.

c. Scavenging:

In 2-stroke engine a third source of HC emission results from scavenging of the cylinder with fuel air mixture. Due to scavenging part of the air fuel mixture blows through the cylinder directly into exhaust port and escapes combustion process completely. HC emission from a 2-Stroke petrol engine is comparatively higher than 4-Stroke petrol engine.

2. Carbon monoxide:

Carbon monoxide remains in the exhaust if the oxidation of CO to CO₂ is not complete. This is because carbon monoxide is an intermediate product in the combustion process. Generally this is due to lack of sufficient oxygen. The emission levels of CO from gasoline engine are highly dependent on A/F ratio.

The amount of CO released reduces as the mixture is made leaner. The reason that the CO concentration does not drop to zero when the mixture is chemically correct and leaner arises from a combination of cycle to cycle and cylinder to cylinder mal distribution and slow CO reaction kinetics. Better carburetion and fuel distribution are key to low CO emission in addition to operating the engine at increased air-fuel ratio.

3. Oxides of Nitrogen:

Nitric oxide is formed within the combustion chamber at the peak combustion temperature and persists during expansion and exhaust in non-equilibrium amount. Upon exposure to additional oxygen in the atmosphere, nitrogen dioxide ( NO₂) and other oxides may be formed.

It should be noted that although many oxides of nitrogen may be also formed in low concentrations like, Nitrogen trioxide (N₂O₃ ), Nitrogen pent oxide (N₂O₅ ) etc., they are unstable compounds and may decompose spontaneously at ambient condition to nitrogen dioxide.

A study of the equilibrium formation of the different nitrogen oxides showed that No is the only compound having appreciable importance with respect to engine combustion. In engine terminology an unknown mixture or nitrogen oxides usually NO and NO₂ is known as NOx. It is expected that higher temperature and availability of oxygen would promote the formation of oxides of nitrogen.

Mechanism of NO formation:

The nitric oxide formation during the combustion process is the result of group of elementary reaction involving the nitrogen and oxygen molecules. Different mechanism proposed are discussed below.

a. Simple reaction between N₂ and O₂

N₂ + O₂à 2 NO

This mechanism proposed by Eyzat and Guibet predicts NO concentrations much lower that those measured in I.C engines. According to this mechanism, the formation process is too slow for NO to reach equilibrium at peak temperatures and pressures in the cylinders.

b. Zeldovich Chai Reaction mechanism:

O₂à 2 O ------------- ( 1)

O + N₂à NO + N ------( 2 )

N + O₂ àNO + O ------( 3 )

The chain reactions are initiated by the equation ( 2 ) by the atomic oxygen, formed in equation ( 1 ) from the dissociation of oxygen molecules at the high temperatures reached in the combustion process. Oxygen atoms react with nitrogen molecules and produces NO and nitrogen atoms. In the equation ( 3 ) the nitrogen atoms react with oxygen molecule to form nitric oxide and atomic oxygen.

According to this mechanism nitrogen atoms do not start the chain reaction because their equilibrium concentration during the combustion process is relatively low compared to that of atomic oxygen. Experiments have shown that equilibrium concentrations of both oxygen atoms and nitric oxide molecules increase with temperature and with leaning of mixtures. It has also been observed that NO formed at the maximum cycle temperature does not decompose even during the expansion stroke when the gas temperature decreases.

In general it can be expected that higher temperature would promote the formation of NO by speeding the formation reactions. Ample O₂ supplies would also increase the formation of NO. The NO levels would be low in fuel rich operations, i.e. A/F 15, since there is little O₂ left to react with N₂ after the hydrocarbons had reacted.

The maximum NO levels are formed with AFR about 10 percent above stoichiometric. More air than this reduces the peak temperature, since excess air must be heated from energy released during combustion and the NO concentration fall off even with additional oxygen.

Measurements taken on NO concentrations at the exhaust valve indicate that the concentration rises to a peak and then fall as the combustion gases exhaust from the cylinder. This is consistent with the idea that NO is formed in the bulk gases. The first gas exhausted is that near the exhaust valve followed by the bulk gases. The last gases out should be those from near the cylinder wall and should exhibit lower temperatures and lower NO concentration.

4. Particulate matter and Partial Oxidation Products:

Organic and inorganic compounds of higher molecular weights and lead compounds resulting from the use of TEL are exhausted in the form of very small size particles of the order of 0.02 to 0.06 microns. About 75% of the lead burned in the engine is exhausted into the atmosphere in this form and rest is deposited on engine parts.

Some traces of products of partial oxidation are also present in the exhaust gas of which formaldehyde and acetaldehyde are important. Other constituents are phenolic acids, ketones, ethers etc., These are essentially products of incomplete combustion of the fuel.

Flame Quenching:

The phenomenon of flame quenching at the engine walls and the resulting unburned layer of combustible mixture play a significant role in the overall problem of air pollution.

It has long been understood that a flame will not propagate through a narrow passage. It has been found that the walls comprising the narrow passage quench the flame by acting as a sink for energy. The minimum distance between two plates through which a flame will propagate is defined as the quenching distance.

The quenching distance is found to be a function of pressure, temperature and reactant composition.

When a flame is quenched by a single wall as would be the case in the combustion chamber of a S.I engine, the distance of the closest approach of the flame to the wall is smaller than the quenching distance. This distance is called the dead space. In general, the dead space has been assumed to range from 0.33 to1.0 of the quenching distance.

Friedman and Johnson, Green and Agnes, Gottenbery and others have made significant work on this area. The following points are drawn from their experiments.

1. Essentially the expression for quenching distance is of the form

q_d = -------

P^αT^β

Where the values of α and β depends on the stoichiometry of the combustible mixture.

2. Lean mixtures have significantly large quenching distance than stoichiometry or rich mixture at any given pressure.

3. There exist a direct linear relationship between the total exhausted hydrocarbon and surface to volume ratio, a direct linear relationship between the representatives measured quench distance and the quantity of unburned hydrocarbons in the combustion products.

4. The quenching distance of copper, mica, glass and platinum surfaces were the same and hence they concluded that the quenching effect was independent of the surface material.

5. As the temperature of the wall increases, the flame can propagate closer to it. If high temperature materials could be used to make the cylinder walls in an engine capable of withstanding 800 °C to 1200 °C temperature, the quench layer thickness can be reduced to bring down the concentration of hydrocarbons.

Danial proposed that the unburned hydrocarbons that are exhausted during the cruise and acceleration modes are due to the quenching of flames by the walls of the combustion chamber piston.

He measured the thickness of the dark zone between the flame and the combustion chamber wall in a single cylinder engine that was fitted with a single quartz head. The dark zone or dead space was measured by taking stroboscopic picture of successive cycle through the quartz cylinder head, and he showed that the quantity of fuel trapped in the dead space was sufficient to account for the unburned hydrocarbons emitted from the engine. He also reported that the thickness of the dark zone was a function of temperature and pressure as referred by Friedman and Johnson.

Tabaczynski proposed that there are four separate quench regions in the cylinder of a S.I engine. As shown in fig 3.1, these four quench layers may be expected to be exhausted from the cylinder at different times during the exhaust stroke. Regions 1 and 2 shown in the figure are the head and side wall quench layers respectively. Region 3 represents the piston face quench layer and region 4 corresponds to the quench volume between the cylinder wall, piston crown and first compression ring.

It has been proposed that the head quench layer and part of the side wall quench layer nearest the exhaust valve leave the cylinder when the exhaust valve opens. Due to the low flow velocities near the piston face, the piston face quench layer will probably not leave the cylinder at any time during the stroke. During the expansion stroke, the hydrocarbons from the crevice between the piston crown and the first compression ring are laid along the cylinder wall.

As the piston begins its upward stroke, it has been shown that a vortex is formed which scraps up the hydrocarbons along the wall and forces them to be exhausted near the end of the exhaust stroke.

EFFECT OF DESIGN AND OPERATING VARIABLES ON GASOLINE ENGINE EXHAUST EMISSIONS

The exhaust emission of hydrocarbons, carbon monoxide and nitric oxide can be minimized by the control of several inter related engine design and operating parameter. Fuel preparation, distribution and composition are also factors. In this section the effects on emissions of factors which the engineer has under his control when designing and tailoring his engine for minimum exhaust emissions are discussed.

The factors include:

· Air fuel ratio

· Load or power level

· Speed

· Spark timing

· Exhaust back pressure

· Valve overlap

· Intake manifold pressure

· Combustion chamber deposit build up

· Surface temperature

· Surface to volume ratio

· Combustion chamber design

· Displacement per cylinder

· Compression ratio

· Stroke to bore ratio

In the following discussions, the hydrocarbons and CO emissions are treated together; because once they are formed they both can be reduced by chemical oxidation process in either the cylinder or the exhaust system. On the other hand nitric oxide, once formed must be reduced by a chemical reduction process.

In the first case for HC and CO reduction, excess O₂is required where as in the second case for NO reduction a deficiency of O₂is desirable.

EFFECTS ON UNBURNED HYDROCARBONS AND CARBON MONOXIDE

1. AIR – FUEL RATIO:

a. Hydrocarbon emission:

Hydrocarbon emissions are high at rich air fuel ratios and decrease as the mixture is leaned up to about 17:1. When operation leaner than 17 or 18:1 is attempted, emissions increases because of incomplete flame propagation and the engine begin to misfire.

The basic factor contributing to the shape of the curve for HC emissions are the effect of mixture ratio on quench layer thickness and on fuel concentration within that quench layer, and the effect of mixture ratio on the availability of excess oxygen in the exhaust to complete the combustion and on the exhaust system temperature. When the temperature is over 650 °C and with oxygen available appreciable exhaust after reaction does occur.

b. CO emission:

CO emissions are high at rich air fuel ratios and decreases as the mixture is leaned. On the richer side, a change of only 1/3 air fuel ratio leads to a change of 1.0% in exhaust CO. The reason that the CO concentration does not drop to zero when the mixture is chemically correct and leaner arises from a combination of cycle to cycle and cylinder to cylinder mal distribution and slow CO kinetics.

2. POWER OUTPUT:

a. Hydrocarbon emission:

Hydrocarbon concentration does not change as load is increased while speed and mixture ratio are held constant and spark is adjusted to MBT. This result is to be viewed as arising from effects of several factors some of which tend to reduce HC while others tend to increase them, apparently counter balancing one another.

A factor which increases the HC formation as load increases is the reduced time within the exhaust system. The residence time of the exhaust gas in the very hot section of the exhaust system is very important for increased exhaust after-reaction.

Factors tending to reduce HC concentration include decreased quench thickness and increased exhaust temperature. Quench layer thickness decreases inversely as pressure increases and the mean cylinder pressure increases linearly with increase in load. Increased temperature with increasing load tends to increase exhaust after-reaction.

However, an almost linear increase in HC mass emissions is observed as load is increased. A light car with low power is better than a large car on mass emission basis.

b. CO emission:

At a fixed air-fuel ratio there is no effect of power output on CO emission concentration. However, as in the case of HC emissions, CO emission on mass basis will increase directly with increasing output, giving advantage for a small light and efficient car.

3. ENGINE SPEED:

a. Hydrocarbon emission:

HC emission is considerably reduced at higher engine speeds. This is because with increase in engine speed, the combustion process within the cylinder is increased by increasing turbulent mixing and eddy diffusion. In addition, increased exhaust port turbulences at higher speeds promotes exhaust system oxidation reactions through better mixing.

b. CO emission:

Speed has no effect on CO concentration. This is because oxidation of CO in the exhaust is kinetically limited rather than mixing limited at normal exhaust temperatures.

4. SPARK TIMING:

a. HC emission:

HC emission has huge impact on spark timing. As the timing is retarded, the HC emissions are reduced. This is because, the exhaust gas temperature increases which promotes CO and HC oxidation. This advantage is gained by compromising the fuel economy.

b. CO emission:

Spark timing has very little effect on CO concentration. But at very high retarded timing, the CO emission increases. This is due to lack of time, to complete oxidation of CO.

5. EXHAUST BACK PRESSURE:

a. HC emission:

Increasing exhaust back pressure increases the amount of residual exhaust gas left in the cylinder at the end of the exhaust. If this increase in dilution does not affect the combustion process adversely, the HC emissions would be marginally reduced. The reduction arises from leaving the tail end of the exhaust, which is rich in HC, in the cylinder. This tail will be subsequently burned in the next cycle. If the back pressure is increased more and more, HC emission would rise sharply because of the effect of excessive dilution on combustion.

On the other hand, increased dilution at idle increases HC emission concentration. At idle, dilution is already quirt high and combustion is marginal and the engine cannot tolerate much more exhaust dilution.

6. VALVE OVERLAP:

a. HC emission:

Increasing valve overlap has an effect similar to increasing the back pressure. The charge is further diluted with residual gases. A slight 2 overlap provided minimizes emission due to re burning of exhaust tail gas which is rich in HC.

Combustion deteriorates with lean mixture as residual is increased. If the mixture ratio is richened to provide stable idle and off-idle performance, then HC advantage will be lost and CO will be increased.

In general, minimum HC emissions are obtained with moderate or low back pressure with minimum overlap.

b. CO emission:

There is no effect of overlap on CO concentration at a constant mixture ratio. However any increase in richness of the mixture for smooth idle or off idle will increase the CO directly. This is due to lack of insufficient supply of oxygen for complete oxidation of CO.

7. INTAKE MANIFOLD PRESSURE:

a. HC emission:

The intake manifold pressure variation reflects the variation in power output of an engine. Between 22cm and 60cm of Hg manifold pressure, the A/F ratio is lean which minimizes HC and CO emissions. Above 60cm of Hg, the engine power increases and the carburettor switch to rich mode. The rich mixture increases HC and CO emissions. This holds good only in case of carbureted engine.

8. COMBUSTION CHAMBER DEPOSITS:

a. HC emission:

It is well known that in a normal engine the major source of combustion chamber deposit is TEL, a fuel additive used to suppress combustion knock. The deposits act to increase the surface area of the chamber because of their irregular porous nature.

As a result, the mass of quenched HC increases. Deposits act as a sponge to trap raw fuel which remains unburned and adds to exhaust. All these tend to increase the HC emission.

Tests have indicated that removal of deposits, depending on the extent of deposit build up, would reduce about 15% in HC emissions. Addition of fuel additives to reduce deposit build up may be helpful. Ethylene dibromide is commonly added to motor fuel to reduce lead deposits from TEL. Any modification to both fuels and lubricants can indirectly reduce HC emissions through deposit modification.

b. CO emission:

There is no effect of deposit build up on CO emission.

9. SURFACE TEMPERATURE:

a. HC emission:

Combustion chamber surface temperature affects the unburned HC emissions by changing the thickness of combustion chamber quench layer and degree of after burning. Higher the combustion chamber surface temperature, the lower are the HC emissions.

In addition to changing quench distance and after-reaction, changing engine temperature increases fuel evaporation and distribution, and result in a faster reaction and hence reduced HC emission.

b. CO emission:

An increase in surface temperature of chamber increases the rate of oxidation of CO and hence reduces CO emission. Further exhaust after reaction also increases resulting in decrease in CO emission.

10. SURFACE TO VOLUME RATIO:

a. HC emission:

Because hydrocarbon emissions arise primarily from quenching at the combustion chamber wall surface, it is desirable to minimize the surface area of the chamber. The ratio of surface area to volume of the combustion chamber (S / V) is useful for interpreting the effects of many designs and operating variables on HC concentration. Lowering the S / V ratio reduces HC emission concentration.

b. CO emission:

CO concentration has no effect on surface to volume ratio.

11. COMBUSTION CHAMBER DESIGN:

One of the most important factors that the emission engineer has under his control is the combustion chamber design. For a given clearance volume, reducing the surface area is an important way of reducing HC emission. Designing a combustion chamber to create better turbulence will reduce both HC and CO emission.

12. STROKE / BORE RATIO:

Another design factor is stroke to bore ratio. Engines with small bore and long stroke have lower S / V ratio. Engines with low surface to volume ratio provide a good emission reduction compared to the engine with higher surface to volume ratio.

Unfortunately this requirement is opposed to modern design practice of short stroke for reduced friction, increased power and economy. Long stroke engines tend to be large, heavy and more expensive and they have poor fuel economy and reduced peak power.

13. DISPLACEMENT PER CYLINDER:

For a given displacement, engines with larger cylinders have smaller surface to volume ratio. This result suggests that for an engine of given displacement, hydrocarbon emissions can be reduced by decreasing the number of cylinders and increasing the displacement per cylinder.

14. COMPRESSION RATIO:

A decrease in compression ratio decreases surface to volume ratio. Decrease in compression ratio increases the clearance volume greatly with little increase in surface area. Due to this decrease in surface to volume ratio the HC emission is reduced.

A decrease in compression ratio decreases the HC emission on a second way also. With reduced compression ratio, thermal efficiency is lowered and as a result exhaust gas temperature is increased. This improves exhaust system after-recirculation and lowers the HC emission even more.

On the other hand, as engine efficiency is lowered, mass flow is increased for a given horse power level which increases mass emissions.

On the other hand with large reduction in compression ratio, the temperature in chamber decreases and it increases both HC and CO emission.

EFFECT OF NITRIC OXIDE:

The concentration of NO in the exhaust gases depends upon the difference between the rate of its formation at the highest temperature in the cycle and the rate of its decomposition as the temperature decreases during the expansion stroke. A study of the decomposition rate of NO indicates that the amount decomposed is negligible because of the short time available during the expansion stroke.

1. EQUIVALENCE RATIO:

The equivalence ratio affects both the gas temperature and the available oxygen during combustion. Theoretically an increase in the equivalence ratio form 1.0 to 1.1 results in an increase of maximum cycle temperature by about 55C while oxygen concentration is reduced by 50%. At equivalence ratio of 1.1, NO in the exhaust is very low. Maximum NO concentration occurs at an equivalence ratio of 0.8. The maximum cycle temperature with this lean mixture is lower than with a rich mixture but available oxygen concentration is much higher.

With very rich mixtures, low peak combustion temperatures and low oxygen concentration lead to low NO. For mixtures leaner than 15.5:1 there is enough oxygen but the temperature is very less and hence lower the NO formation. Thus NO concentration is very low for very lean as well as very rich mixtures.

2. SPARK TIMING:

An advance in spark timing increases the maximum cycle temperature and therefore results in increased NO concentration.

3. MANIFOLD PRESSURE:

An increase in manifold vacuum decreases load and temperature. As a result the ignition delay is increased and the flame speed is reduced. Both these factors increase the time of combustion. This reduces the maximum cycle temperature and thus reducing NO concentration in the exhaust.

4. ENGINE SPEED:

An increase in engine speed has little effect on ignition delay. Increase in engine speed results in an increase in flame speed due to turbulence and reduces heat losses per cycle which tends to raise compression and combustion temperature and pressure. If spark timing is held constant, a greater portion of this combustion tends to occur during expansion where temperature and pressure are relatively low.

This is most pronounced for the slowest burning mixture ratio of 19:1. For richer mixtures which burn faster, the effect of reduced heat losses at higher speeds predominates.

These are two opposing influences – an increase in the rate of NO formation due to reduced heat losses opposed by a reduction in the rate of NO formation due to late burning. For rich mixtures where combustion and NO formation are rapid, the former predominates. For lean mixtures where combustion and NO formation are slow, the later effect predominates.

5. COOLANT TEMPERATURE AND DESPOSIT:

An increase in the coolant temperature results in a reduction of heat losses to the cylinder walls and an increase in the maximum gas temperature. This results in an increase in NO concentration.

An increase in deposit thickness causes an increase in compression ratio, reduction in heat losses to the coolant and an increase in NO concentration.

6. HUMIDITY:

The reduction in NO formation caused by an increase in mixture humidity is mainly due to the drop in maximum flame temperature. Test on hydrogen-air, and ethylene-air mixture indicates that 1% of water vapour reduces the flame temperature by 20C. This reduces the initial rate of NO production by about 25%.

7. EXHAUST GAS RECIRCULATION:

Recycling of a portion of exhaust gas to inlet charge increases dilution. This reduces peak combustion temperature, since the inert exhaust gas re circulated will act as a heat sink. This also reduces the oxygen availability.

About 15% recycle will reduce NOx emission by about 80%. The maximum percentage which can be re circulated is limited by rough engine operation and loss of power.

8. SURFACE TO VOLUME RATIO:

Engine changes which decrease surface to volume ratio reduce heat loss to the coolant. As a result NO concentration may increase.

EFFECT OF DESIGN AND OPERATING VARIABLES ON EXHAUST EMISSIONS

SL.NO.	VARIABLE INCREASED	HC	CO	NO
1	Load	_	_	Increase
2	Speed	Decrease	-	Increase/Decrease
3	Spark retard	Decrease	-	Decrease
4	Exhaust back pressure	Decrease	-	Decrease
5	Valve overlap	Decrease	-	Decrease
6	Intake manifold pressure	-	-	Increase
7	Combustion chamber deposit	Increases	-	Increases
8	S/V ratio	Increase	-	-
9	Combustion chamber area	Increase	-	-
10	Stroke to bore ratio	Decrease	-	-
11	Displacement per cyl.	Decrease	-	-
12	Compression ratio	Increase	-	Increase
13	Air Injection	Decrease	Decrease	Increase
14	Fuel injection	Decrease	Decrease	Increase
15	Coolant temperature	Decrease	Decrease	Increase

UNIT- III POLLUTANT FORMATION IN CI ENGINES

DIESEL ENGIEN EXHAUST EMISSIONS:

The pollutants from diesel engines can be categorized into two types:

1. Visible and 2. Invisible. The first one consists of smoke and metallic particulates. Smoke being so conspicuous and odorous is objected to public and also reduces visibility and has smudging character but is not harmful to health.

The second type consists of CO, un burnt hydrocarbons including poly nuclear aromatics, oxides of N2, SO2 and partially oxidized organics (aldehydes, ketones etc.,)

Among these pollutants smoke, CO, UBHC and oxides of nitrogen are of most immediate concern.

FORMATION OF POLLUTANTS IN DIESEL ENGINES:

Unlike a gasoline engine, where fuel and air are premixed into a homogenous form before entering the cylinder, in the diesel engine fuel is injected into the compressed air charge inside the cylinder. As the mixing of air and fuel has to take place entirely in the combustion chamber, complete mixing is virtually impossible and infinite variations in air-fuel mixture ratio takes place within the same cylinder. Also as the load requirement is met through variation in the quantity of fuel injected, the overall air fuel ratio varies within wide limits, about 20:1 to 60:1.

A normally rated and well maintained engine emits negligible amount of CO and unburnt hydrocarbons, through considerable amount of oxides of nitrogen and smoke are emitted.

Carbon monoxide:

It is formed during combustion when there is insufficient oxygen to oxidize the fuel fully. Compression ignition engines have long been known to produce low levels of CO because of excess amount of air available for combustion. Theoretically it should not emit any CO as it always operated with large amount of excess air. Nevertheless CO is present in small quantities ( 0.1 to 0.75%) in the exhausts.

This is possible because of the fact that fuel injected in later part of the injection does not find enough oxygen due to local depletion in certain parts of the combustion chamber.

Unburnt Hydrocarbons:

The concentrations of hydrocarbons in diesel exhaust varies for a few parts per million to several thousand parts per millions depending on engine speed and load. Hydrocarbons in engine exhaust are composed of many individual hydrocarbons in the fuel supplied to the engine as well as number of hydrocarbons partially unburnt produced during the combustion process. In addition some unburnt hydrocarbons may be from lubricating oils. Tests on engine with single component fuels shows that these engines contained hydrocarbons of higher and lower molecular weights, than original fuel as well as molecules with different structures. Aromatic compounds have been observed in exhaust of engines operated on pure paraffins. Poly nuclear aromatics found in exhaust are products of this synthesis.

During the normal operation the relatively cold walls “quench” the fuel air mixture and inhibit combustion leaving a thick skin of unburnt air fuel mixture over the entire envelope of the combustion chamber. The amount of unburnt fuel depends on the thickness of quench zone and the effective combustion chamber area. The thickness of quench zone depends on many variables as combustion temperature, pressure, mixture ratio, turbulence and residual gas dilution. Higher surface to volume ratio of combustion chamber leads to greater fraction of unburnt hydrocarbon from the quench zone.

Partially oxidized hydrocarbons (aldehydes) have been associated with diesel exhaust. They produce objectionable odor and are high when engine idles and under cold starting indicating poor combustion.

OXIDES OF NITROGEN:

This is more significant. The formation of Nitric oxide, the major component of oxides of nitrogen depends on number of operating conditions of diesel engine. The main factors that control this formation are amounts of oxygen available and the peak temperature in the zones with sufficient oxygen and residence times at temperatures above 2000K.

Both open and pre-combustion chamber produce small amount of oxides of nitrogen when air fuel ratio is about 0.01 to maximum near air fuel ratio of about 0.035 ratios. Additional fuel tends to lower air fuel ratio; the charge temperature also reduces which consequently reduces oxides of nitrogen.

Formation of oxides of nitrogen:

Since nitrogen is a high temperature species its formation is influenced by combustion temperature and time available for combustion. Hence NO tends to increase with advanced injection timing. Also NO produced increase with fuel supply. Notable exception is prechamber. In direct injection engines NO reaches maximum value at stoichiometric air fuel ratio, as lean and rich mixtures tend to reduce combustion temperatures. Increase in compression ratio leads to increase in combustion temperature and hence higher NO formation.

Valve overlap has significant effect on NO formation. Higher valve overlap dilutes the incoming air more and more leading to increasing in fuel/air ratio. This in turn reduces combustion temperatures and hence lowers NO formation.

Earlier inlet valve opening before TDC leads to increased dilution of incoming air and hence lower NO.

Extended inlet valve opening up to 20 has no effect on NO formation as it does not vary manifold pressure.

Extended exhaust valve opening before bottom dead centre results in marginal increase in NO due to better scavenging, conversely later exhaust valve opening leads to delayed scavenging and higher dilution.

Exhaust valve closing determine effect of scavenging and pronounced effect on dilution and hence Nitrogen formation.

DIESEL ENGINE SMOKE EMISSION:

Engine exhaust smoke is a visible indicator of the combustion process in the engine. Smoke is due to incomplete combustion. Smoke in diesel engine can be divided into three categories: blue, white and black.

Blue smoke:

It results from the burning of engine lubricating oil that reaches combustion chamber due to worn piston rings, cylinder liners and valve guides.

White or cold smoke:

It is made up of droplets of unburnt or partially burnt fuel droplets and is usually associated with the engine running at less than normal operating temperature after starting, long period of idling, operating under very light load, operating with leaking injectors and water leakage in combustion chamber. This smoke normally fades away as engine is warmed up and brought to normal stage.

Black or hot smoke:

It consists of unburnt carbon particles ( 0.5 – 1 microns in diameter) and other solid products of combustion. This smoke appears after engine is warmed up and is accelerating or pulling under load.

Formation of smoke in Diesel engines:

The main cause of smoke formation is known to be inadequate mixing of fuel and air. Smoke is formed when the local temperature is high enough to decompose fuel in a region where there is insufficient oxygen to burn the carbon that is formed. The formation of over-rich fuel air mixtures either generally or in localized regions will result in smoke. Large amounts of carbons will be formed during the early stage of combustion. This carbon appears as smoke if there is insufficient air, if there is insufficient mixing or if local temperatures fall below the carbon reaction temperatures (approximately 1000C) before the mixing occurs.

Acceptable performance of diesel engine is critically influenced by exhaust some emissions. Failure of engine to meet smoke legislation requirement prevents sale and particularly for military use, possible visibility by smoke is useful to enemy force. Diesel emissions gives information on effectiveness of combustion, general performance and condition of engine.

FACTORS AFFECTING SMOKE FORMATION:

The smoke intensity in the diesel exhaust is generally affected by many parameters. By controlling them, smoke intensity may be reduced.

1. Injection timing:

Advancing the injection timing in diesel engines with all other parameters kept constant results in longer delay periods, more fuel injected before ignition, higher temperatures in the cycle and earlier ending of the combustion process.

The residence time is therefore increased. All these factors have been fond to reduce the smoke intensity in the exhaust. However earlier injection results in more combustion noise, higher mechanical and thermal stresses, and high NO concentration.

In a recent study, khan reported that a very late injection reduces the smoke. The timing after which this reduction occurs is that at which the minimum ignition delay occurs. He suggested that one of the factor that contributes to the reduction in smoke at the retarded timing is the reduced rat of formation due to decrease in the temperature of the diffusion flames as most of these flames occur during the expansion stroke.

2. Rate of Injection:

Higher initial rates of injection have been found to be effective in reducing the exhaust smoke.

3. Injection nozzle:

The size of the nozzle holes and the ratio of the hole length to its diameter have an effect on smoke concentration. A larger hole diameter results in less atomization and increased smoke. An increase in the length/diameter ratio beyond a certain limit also results in increased smoke.

4. Maintenance:

The engine condition plays a very important role in deciding the smoke levels. The maintenance affects the injection characteristics and the quantity of lubricating oil which passes across the piston rings and thus a profound effect on smoke generation tendency of the engine. Good maintenance is a must for lower smoke levels.

5. Fuel:

Higher cetane number fuels have a tendency to produce more smoke. It is believed to be due to lower stability of these fuels. For a given cetane number less smoke is produced with more volatile fuels.

6. Load:

A rich fuel-air mixture results in higher smoke because the amount of oxygen available is less. Hence any over loading of the engine will result in a very black smoke. The smoke level rises from no load to full load. During the first part, the smoke level is more or less constant as there is always excess air present. However in the higher load range there is an abrupt rise in smoke level due to less available oxygen.

7. Engine type and speed:

Naturally aspirated engines have higher smoke levels at higher loads than turbo charged engines, because the later have sufficient oxygen even at full loads. The smoke is worse at low as well as at high speeds. This follows the volumetric efficiency curve of the engine in some measure as it drops at the extremes of speed.

8. Fuel air ratio:

The smoke increases with richening the mixture. The increase in smoke occurs even with as much as 25% excess air in cylinder, cleanly indicating that the diesel engine has a mixing problem.

CONTROL OF DIESEL ENGINE SMOKE:

Smoke can be reduced by some of the following methods:

1. Derating:

Derating is nothing but making the engine to run at lower loads. At lower loads more excess air is present in the combustion chamber and hence the smoke developed is less as already discussed. However this means a loss of output.

2. Proper maintenance of the engine:

Maintaining the engine properly, especially the injection system, will not only result in reducing smoke but also keep the performance of the engine at its best.

3. Proper choice of combustion chamber design and operating conditions:

A proper choice of combustion chamber design results in better mixing of fuel and air in the chamber and hence reduces the smoke level to a considerable level.

4. Use of smoke suppression additives:

Some barium compounds if used in fuel reduce the temperature of combustion, thus avoiding the soot formation. Even if formed they break it into fine particles, thus appreciably reducing smoke. However, the use of barium salts increases the deposit formation tendencies of engine and reduces the fuel filter life.

5. Adopting fumigation technique:

This method consists of introducing a small amount of fuel into the intake manifold. This starts precombustion reactions before and during the compression stroke resulting in reduced chemical delay, because the intermediate products such as peroxides and aldehydes react more rapidly with oxygen than original hydrocarbons. The shortening of delay period curbs thermal cracking which is responsible for soot formation.

Fumigation rate of about 15% gives best smoke improvement. However this improvement varies greatly with engine speed. At low engine speeds 50 to 80% smoke reduction is obtained. This decrease as speed increases until a speed at which there is no effect of fumigation.

DIESEL ODOUR:

Ever since the first diesel engine was developed, the odor from its exhaust has been recognized as undesirable. Determination of the cause of this odor has been difficult because of the complexity of the heterogeneous combustion process and the lack of chemical instruments available. In practice the human nose plays a significant role in odor measurement.

The members of the aldehydes family are supposed to be responsible for the pungent odors of diesel exhaust. Though the amount of aldehydes is small being less than 30ppm, the concentration as low as 1ppm are irritating the human eyes and nose.

Mechanism of odour production:

Some experimental results indicate that the products of partial oxidation are the main cause of odor in diesel exhaust. This partial oxidation may be because of either very lean mixture or due to quenching effect.

In diesel combustion there are most probably regions in which the fuel/oxygen/inert mixture is outside the flammability limits.

The fuel in these regions which are too lean to burn might only partially oxidize resulting in odors. This is most likely to occur during idling and or part load operation of the engine. Also the fact that chemical reactions take place during the second stage of diesel combustion suggest that if the reactions are quenched during this period, partial oxidation products will result in odour in the diesel exhaust.

Barns concluded in his research that diesel odor resulted from partial oxidation reaction in the fuel lean regions which are almost inevitably formed in heterogeneous combustion. Graph shows the relative odor producing capabilities of different air fuel regions. The data shown in graph were obtained using CFR engine and varying air-fuel ratios and the inlet air temperatures.

Odor relevant compounds:

Until recently very little was known about the compound or compounds that contribute to the odorous qualities of diesel exhaust. Rounds and Pearsall correlate odor with the aldehydes in diesel exhaust gas. However Vogh says that aldehydes are not significant contributors to the overall odor problem. Vogh also says that neither SO2 nor particulate contribute significantly to diesel odor emissions.

Research work at the Illinois Institute of Technology, Research Institute ( IITRI ) has contributed significantly to the development of a better understanding of the chemical nature of the odor contributors in diesel exhaust. Based on the IITRI work, various high molecular weight cyclic and aromatic hydrocarbons including naphthalene, tetra ling and cyclo paraffins some with olefinic and or paraffinic side changing were reported as major contributors to the burnt odor note of the exhaust.

Various non aromatic hydrocarbons with more than one double or triple bond were also reported to contribute to the burnt odor note. Furan aldehydes, aromatic benzene and paraffinic aldehydes from ethanol to n-octanol were found be important odor contributors and have individual odors that varied from pleasant to pungent. Some heterocyclic sulfur compounds, thiophene and benzothiophene derivatives were also reported to be odor contributors.

FACTORS AFFECTING ODOR PRODUCTION:

1. Fuel air ratio:

The fact that very lean mixtures result in odorous diesel exhaust has already been discussed.

2. Engine operation mode:

It has been found that the mode of operation of the engine significantly affects the exhaust odor. Maximum odor occurs while accelerating from idle and minimum odor results when the engine is running at medium sped and or at part loads.

Effect of engine operating mode on odor production ( 4-stroke normally aspirated medium speed diesel engine)

Engine operation mode	Odor intensity ( Turk number)
Idle	3.6
Acceleration	4.1
Part load	3.0
Full load	3.5

3. Engine type:

The odor intensity does not vary with the engine type as can be seen from the table. The odor intensity from all the engines is more or less the same.

Engine type	Odor intensity ( Turk number)
Two stroke	3.5
Four stroke normally aspirated ( medium speed)	3.3
Four stroke normally aspirated ( high speed)	3.5
Four stroke – Turbo charged	3.4

4. Fuel composition:

It is really surprising to find that the composition of the fuel has no effect on exhaust odor intensity. The changes in fuel composition result in different second stage combustion time in diesel combustion and it is expected that this will affect the degree of oxidation if quenching is taking place. However the results contradict this expectation.

5. Odor suppressant additives:

It has been claimed from time to time, by different manufactures of odor suppressant additive compounds that they reduce the odor. However small and rather insignificant effects upon the odor has been found in comparison of exhausts from treated and untreated fuels. No predictable and reliable correspondence between the additives and odor is found.

Odor Measurement Techniques:

Effective chemical or physical methods for the measurement of odor have not been developed, and therefore the human nose plays a significant role in all odor studies. In practice odor is measured by a specially selected, specially trained human panel.

When the nose is subjected to an odor, the physiological response to the odor can be classified by either intensity or intensity and quality. The Turk kit contains a number of different standard odors that are classified as a) burnt/smoky b) oily

c) pungent/acid and d) aldehydic/aromatic. It has been generally accepted as a standard for rating the intensity and quality of an unknown odorous sample.

Odor-detection methods that have been developed todate may be placed in two general categories. The first category includes methods that only rate the over all odor intensity, while the second group is employed to classify odors by quality and intensity. The threshold dilution technique and natural dilution technique that are described below fall into the first category.

The threshold dilution technique consists of presenting raw diesel exhaust synthetically diluted with variable quantities of odor free air to a panel of “Sniffers” person who smells. A series of diluted samples, both above and below the threshold dilution ratio, are presented to members of the panel and the individual panel members are asked to determine whether or not any odor is detectable. The odor intensity is assumed to be proportional to the dilution ratio at which the odor is just detectable to the panel.

The natural dilution technique was developed in order to determine whether diesel powered vehicles could meet the motor vehicle exhaust odor on standards set by the state of California. During the course of these tests, a panel is seated at varying distance from a vehicle.

Both the vehicle and the panel are located inside a large municipal hanger, in order to minimize the effects due to winds and the panelists are asked to determine whether or not they can detect any odor from the vehicle. Their responses are utilized to evaluate threshold response distances.

Variations of the direct method have been used to rate the quality and intensity of diesel odor and hence thy fall into the second category of odor detection methods. When applying this method, the exhaust from the diesel engine is usually diluted with odor free air at the engine exhaust pipe and the resulting mixture of gases which consists of raw diesel exhaust mixed with odor free air in ratios ranging from 1 to 200 flows dynamically through a presentation system to the panelists. The panelists who have been previously trained to evaluate both quality and intensity as determined by the Turk kit are asked to record their response to test gases as a function of dilution ratio and experimental parameters.

UNIT - IV CONTROL OF EMISSIONS FROM SI AND CI ENGINES

Design changes:

The effects of engine design and operating variables on exhaust emission were discussed in a detailed manner already. Based on the discussions made already the engine design modifications approaches to control the pollutants are discussed below.

1. NOx is decreased by

A. Decreasing the combustion chamber temperature

The combustion chamber temperature can be decreased by

1. Decreasing compression ratio

2. Retarding spark timing

3. Decreasing charge temperature

4. Decreasing engine speed

5. Decreasing inlet charge pressure

6. Exhaust gas recirculation

7. Increasing humidity

8. Water injection

9. Operating the engine with very lean or very rich air fuel ratio

10. Decreasing the coolant temperature

11. Decreasing the deposits

12. Increasing S/V ratio

B. By decreasing oxygen available in the flame front

The amount of oxygen available in the chamber can be controlled by

1. Rich mixture

2. Stratified charge engine

3. Divided combustion chamber

2. Hydrocarbon emission can be decreased by

1. Decreasing the compression ratio

2. Retarding the spark

3. Increasing charge temperature

4. Increasing coolant temperature

5. Insulating exhaust manifold

6. Increasing engine speed

7. Lean mixture

8. Adding oxygen in the exhaust

9. Decreasing S/V ratio

10. Increasing turbulence

11. Decreasing the deposits

12. Increasing exhaust manifold volume

13. Increasing exhaust back pressure

3. CO can be decreased by

1. Lean air fuel ratio

2. Adding oxygen in the exhaust

3. Increasing coolant temperature.

EXHAUST GAS RECIRCULATION:

In exhaust gas recirculation a portion of the exhaust gas is recirculated to the cylinder intake charge. This reduces the peak combustion temperature, since the inert gas serves as a heat sink. This also reduces the quantity of oxygen available for combustion.

The exhaust gas for recirculation is passed through the control valve for regulation of the rate and inducted down to the intake p[ort, The recycle rate control valve is connected to the throttle shaft by means of appropriated linkage and the amount of valve opening is regulated by throttle position. The link is designed so that recycled exhaust is normally shut off during idle to prevent rough engine operation. This is also shut off during full throttle, acceleration to prevent loss of power when maximum performance is needed.

The NOx concentration will vary with the amount of recycling of gas at various air fuel ratios. About 15% recycle will reduce NOx emission by about 80%. The maximum percentage which can be circulated is limited by rough engine operation and loss of power.

The above figure shows a vacuum controlled EGR valve used to control the recycle rate. A special passage connects the exhaust manifold with the intake manifold. This passage is opened or closed by a vacuum controlled EGR valve. The upper part of the valve is sealed. It is connected by a vacuum line to a vacuum port in the carburettor. When there is no vacuum the port, there is no vacuum applied to the diaphragm in the EGR valve. Therefore, the spring holds the valve closed. No exhaust gas recirculates. This is the situation during engine idling when little NOx is formed.

As the throttle valve opens it passes the vacuum port in the carburettor. This allows intake manifold vacuum to operate the EGR valve. Then vacuum raises the diaphragm, which lifts the attached valve off its seat. Now exhaust gas flows into the intake manifold. There the exhaust gas mixes with the air fuel mixture and enter the engine cylinders.

At wide open throttle, there is little vacuum in the intake manifold. This produces a denser mixture which burns cooler during the combustion process. Therefore at wide open throttle there is less need for exhaust gas recirculation. Due to low vacuum, the EGR valve is nearly closed.

A thermal vacuum switch on many cars prevents exhaust gas recirculation until the engine temperature reaches about 100 F 0r 37.8C. The thermal vacuum switch is also called a coolant temperature override switch (CTO switch). It is mounted in a cooling system water jacket, so it senses coolant temperature. If this temperature is below 100F, the switch remains closed. This prevents the vacuum from reaching the EGR valve, so the exhaust gas does not recirculate. Cold engine performance immediately after starting is improved. After the engine warms up it can tolerate exhaust gas recirculation. Then the CTO valve opens. Now vacuum can get to the EGR valve, so that exhaust gas can recirculate.

EGR invariably results in drop in power, increased fuel consumption and rough combustion. In addition excessive intake system deposit buildup and increased oil sludging occur.

Fumigation technique:

CRANKCASE EMISSION AND CONTROL

During the compression and combustion strokes, highly corrosive blowby gases are forced past the piston rings into the crankcase. The amount of blowby entering the crankcase generally increases with engine speed. The amount of blowby also depends on other conditions including piston, ring and cylinder wear. The actual amount of wear may be small, perhaps only a few thousands of an inch. But almost any wear is enough to weaker the sealing effect of the rings and permit blowby to increase. Blowby gases contain burned and unburned fuel, carbon and water vapour from the combustion chamber. When the engine is cold, some of the water vapour of the blowby condenses on the cylinder walls and crankcase. It forms into droplets and runs down into the oil pan. Gasoline vapour also condenses on cold engine parts and drips down into the oil pan. This gasoline dilutes and thins the oil, reducing its lubricating ability.

The churning action of the rotating crank shaft can whip the water and engine oil into thick, gummy substance called sludge. The acid compounds from the blowby can get into the sludge and cause corrosion and faster wear of engine parts. Sludge can also clog oil passages and prevent normal engine lubrication, thereby leading to early engine failure.

Blowby causes pressure in the crankcase. If this pressure is allowed to build up, engine oil is forced past the oil seals and gaskets and out of the engine. To help to control the effect of blowby, there must be a way to relieve the crankcase pressure caused by blow by gases.

CRANKCASE VENTILATION

To avoid the above said problems, the unburned and partly burned gasoline and the combustion gases and water vapour must be cleared out of the crankcase by providing crankcase ventilation systems.

In early engines, the crankcase ventilation system was very simple. It provided crankcase breathing by passing fresh oil through the crankcase. On almost all American made automobile engines built prior to 1961, the fresh air entered through an air inlet at the top front of the engine. The fresh air is mixed with the blowby fumes and other vapours in the crankcase. These vapours were routed out of the crankcase through a large hollow tube called the road draft tube, which discharged under the car into the atmosphere.

The fresh air inlet was usually the crankcase breather cap. On most engines it also served as the cap for the crankcase oil filler tube. The cap was open, or vented with holes on both sides to let fresh air to pass through. The cap was filled with oil soaked steel wool or similar material to serve as an air filter. The filter prevented dust particle in the air from getting into the crankcase oil and causing engine wear.

ROAD DRAFT TUBE EMISSIONS:

The road draft tube system worked well to keep the crankcase free of fumes and pressure build up. However it discharged all the crankcase pollutants into the atmosphere. This discharge through the road draft tube represented about 20% of the total HC emissions from an automobile. Therefore controlling blow by was the first step in eliminating atmospheric pollution from the automobile.

OPEN PCV SYSTEM:

An early system that partially controlled crankcase emission was installed on cars built for sale in California beginning in 1961. The system was called open positive crankcase ventilation system.

In this system a tube is connected between a crank case vent and the intake manifold. While the engine is running, intake manifold vacuum is used to pull vapour from the crankcase through the tube into the intake manifold. Fresh ventilating air is drawn into the crankcase through an open oil filler cap. In the intake manifold, the crankcase vapours are mixed with the incoming air-fuel mixture and sent to the cylinders for burning.

For the engine to operate properly under all conditions of speed and load, a flow control valve is required. Without a flow control valve, excessive ventilation air passes from the crankcase into the intake manifold during idling and low speed. This upsets the engine air fuel ratio and results in poor idling with frequent stalling.

The PCV valve is installed in a tube from the crankcase vent to the intake manifold. The PCV valve is a variable orifice valve. A variable orifice is a hole that acts as a valve by changing the size to vary the flow rate through it. This valve is also called a metering valve, a modulator valve and a regulator valve.

A typical PCV valve consists of a coil spring, a valve and a two piece outer body which is usually crimped together. At idle or low speed, high intake manifold vacuum tends to pull the valve closed or into its minimum flow condition. As the valve tries to close it compresses the valve spring. The smaller opening now allows a much smaller volume of blow by gas to pass through. At high engine speeds, the compressed spring overcomes the pull of the vacuum on the valve. The spring begins to force the valve open towards the maximum flow condition. As the valve moves open, the flow capacity increases. This is to handle the greater volume of blowby that results from an increase in engine load and speed.

CLOSED PCV:

The crankcase emission control system described above is not completely effective in controlling crankcase emissions. In open type system, blowby in excess of the PCV valve flow rate escapes to the atmosphere through the open oil filler cap. To overcome this problem, a closed positive crankcase ventilation system was developed. All cars manufactured in California in 1963 and later used a closed type of positive crankcase ventilation system.

The blowby gases are turned to the engine cylinder through the intake manifold and under appropriate conditions, through the carburettor air cleaner. The PCV valve described earlier is generally used as the flow control valve. A closed oil filler cap is used. Other possible outlets for blow by gases, such as dipstick tube are sealed.

All cars are now being equipped with such closed PCV system wherever there are air pollution regulations. These systems have completely eliminated the crankcase as a source of atmospheric contamination and no additional control in future is required in this direction.

EVAPORATIVE EMISSIONS AND CONTROL

Hydrocarbon evaporative emissions from a vehicle arise from two sources as evaporation of fuel in the carburettor float bowl ( 5-10 percent ) of fuel in the fuel tank ( about 5 percent ).

CARBURETTOR EVAPORATIVE LOSSES:

Carburettor hydrocarbon vapour losses arise from distillation of fuel from the float bowl. Carburettor fuel temperature often reaches 55°C during warm weather engine operation and may rise up to 80°C during a hot soak. Hot soak is a condition when a running car is stopped and its engine turned off. During the soak a significant fraction of the fuel will boil off and a large portion of the loss finds its way into the atmosphere. There is a considerable rise in fuel system temperature following shut down after a hard run.

The basic factors governing the mass of fuel distilled from carburettor during a hot soak period are

· maximum fuel bowl temperature

· amount of fuel in the bowl

· amount of after-fill and

· distillation curve of the fuel

Tests have indicated that a less volatile fuel would reduce the evaporative losses considerably. A fuel with 20% distilled at 72 °C would give 22% less losses as compared to a fuel which distilled 25% at 72 °C .

The carburettor bowl volume has a significant effect on evaporative losses. Increase in the volume of the bowl increases the losses linearly. If an insulated spacer is placed between the carburettor and the inlet manifold, almost 50% reduction can be observed.

Filling of the carburettor (after-fill) to the original liquid level is similar to an increase in the bowl volume and the distillation losses would increase by about 15%.

FUEL TANK EVAPORATIVE LOSSES:

Fuel tank losses occur by displacement of vapour during filling of petrol tank, or by vaporization of fuel in the tank, forcing the vapour through a breather vent to the atmosphere. When the temperature is low, the fuel tank breathes in air. When the temperature goes high it breathes out air, loaded with petrol vapours. Fuel tank losses occur because the tank temperature is increased during the vehicle operation which causes an increase in the vapour pressure and thermal expansion of tank vapour.

The mechanism of tank loss is as follows: When a partially filled fuel tank is open to atmosphere, the partial pressure of vapour phase hydrocarbons and vapour pressure of the liquid phase are equal and they are in equilibrium. If the temperature of the liquid is increased, say by engine operation, the vapour pressure of the liquid will increase and it will vaporize in an attempt to restore equilibrium. As additional liquid vaporize the total pressure of the tank increases and since the tank is open to atmosphere, the vapour will flow out of the tank. This outflow to the vapour will increase if in addition to liquid temperature rise, the vapour temperature is also increased.

The evaporation from the tank is affected by a large number of variables of which the ambient and fuel tank temperature, the mode of vehicle operation, the amount of fuel in the tank and the capacity, design and location of the fuel tank with reference to exhaust system and the flow pattern of the heated air underneath the vehicle.

Less the tank fill, greater is the evaporative loss. The effect of the tank fill and the temperature are shown in the table. This reflects the difference in the tank vapour space. Also when a car is parked in a hot location, the evaporation of gasoline in the tank accelerates and so the evaporation loss is greater.

EFFECT OF FUEL TANK FILL ON EVAPORATIVE LOSS:

Tank fill	Ambient temperature C	Temp. rise during test in °C	Loss during operations %
¼	19	7	5.7
½	16	4	1.2
¾	18	2	0.1
Full	22	3	0.0

The operational modes substantially affect the evaporation loss. When the tank temperature rises, the loss increases. The fuel composition also affects the tank losses. About 75% of the HC losses from the tank are C4 and C5 hydrocarbons.

Design factors that affect the evaporative losses include the peak tank temperature, the area of the liquid vapour surface, and the amount of agitation. It is obvious that nay design change which reduces the peak tank temperature will reduce the tank loss.

Such modifications include tank insulation, lower surface to volume ratio of tank, better tank orientation or location for reduced heat pick up from solar radiation or other heat sources such as the exhaust system.

The surface area for evaporation and tank agitation are factor which influence the speed with which equilibrium is achieved. Baffles in the tank can reduce losses by maintaining concentration gradients.

EVAPORATIVE EMISSION CONTROL DEVICES:

Evaporative emission control devices are designed to virtually eliminate the hydrocarbon vapours emitted by the carburettor and fuel tank during both running and hot soak. During running, fuel tank vapours are inducted and burned in the engine. Carburettor losses are vented to intake system. Vehicles without evaporative controls are estimated to 10se 30 g/day of HC from fuel tank filling and breathing. Another 40 g/day is lost by evaporation from the carburettor ( hot soak loss ) when the vehicle is parked after being operated. ON this basis, evaporative losses are estimated to be 23% of total HC emissions.

The device as shown in the figure consists of an absorbent chamber, the pressure balance valve and the purge control valve. The absorbent chamber which consists of a charcoal bed or foamed poly-urethane holds the hydrocarbon vapour before they can escape to atmosphere. The carburettor bowl and the fuel tank are directly connected to the absorbent chamber.

During hot soaks, vapours from the fuel tank are routed to a storage device. Carburettor vapours may be vented to the storage system or retained internally in the carburettor or induction system volume. A schematic diagram of this arrangement is shown in the figure.

Upon restart, filtered air is drawn through the stored vapours and the mixture is metered into the intake system and burned in the engine. In this manner the storage device is purged (removed off the retained vapour). The operations of the purge control valve are controlled by the exhaust back pressure.

The storage system consists of a canister containing activated charcoal located in the engine compartment. Activated charcoal has an affinity for HC and on a recycle basis can store 30-35 grams of fuel per 100 grams of charcoal without breakthrough. Typically 700-800 grams of charcoal are used in a vehicle system.

One problem with any storage system is the possibility of liquid fuel entering the storage device. Ball check valves or vapour liquid separators assure than only fuel vapours reach the storage device. In addition, a dead volume in the tank allow for thermal expansions of a full fuel tank. About 10% of the tank volume is partially walled off from the remainder of the tank. When the tank is filled, this volume remains nearly empty. After a period of time, the fuel fills the additional volume thereby leaving room for expansion in the rest of the tank. Otherwise expansion could force the liquid fuel into the charcoal canister or the crankcase.

THERMAL REACTORS:

Thermal reactor is a chamber in the exhaust system designed to provide sufficient residence time to allow appreciable homogeneous oxidation of HC and CO to occur. In order to improve CO conversion efficiency, the exhaust temperature is increased by retarding spark timing. This however results in fuel economy loss.

The air is supplied from an engine driven pump through a tube to a place very near to the exhaust valve. To achieve a high degree of exhaust system oxidation of HC and CO, a high exhaust temperature coupled with sufficient oxygen and residence time to complete the combustion is needed. Oxides of nitrogen are not reduced. In fact, they may be increased if sufficiently high exhaust temperature results from the combustion of CO and HC with the added air or if the injected air enters the cylinder during the overlap period, thereby leaning the mixture in the cylinder.

Warren has derived the following equation for the concentration of hydrocarbons leaving the exhaust system.

C_o= C_i* exp K_rO₂P²V

K₃T²W

Where,

C_o= Concentration of HC leaving the thermal reactor

Ci = Concentration of HC leaving cylinders and entering the thermal reactor

Kr = Specific reaction rate ft³/lbm – mole/sec

K3 = constant

O2 = oxygen concentration in exhaust gases. Volume percent

P = exhaust pressure ( Psi)

V = thermal reactor volume available for reaction Cu.ft

T = Absolute temperature C

W = Mass flow rate of air ( lb/sec)

Note the importance of pressure term. Increasing exhaust system back pressure promote after reaction. However commercially, the possible back pressure increase is small.

The graph shows the effect of temperature on specific reaction rate Kr, calculated from the above equation by warren from his experimental data. The nearness of his curve to a straight line suggests the equation is a good approximation for the overall reactions occurring. Note that a decrease in exhaust temperatures from 1100C to 1000F decrease the reaction rate by a factor of 10.

The graph shows the effect of temperature and reactor volume on exhaust hydrocarbon concentration at an oxygen input concentration of 3%. Reactor volume may be viewed as the volume of the exhaust system which is insulated and ant the high temperature needed for reaction.

Note that if the exhaust temperature were 1400F, only twice the convention system volume is required for virtually complete elimination of the hydrocarbons. On the other hand, if the temperature were only 1200F, eight times the volume would achieve only a 76% reduction. A pair of conventional exhaust manifolds has about 0.09 ft3 of volume.

Increasing the exhaust system volume increases the residence time during which reactions can occur. This is a benefit, providing the added surface area does not result in excessive cooling. Thus when large volume exhaust manifolds are to be used, they must be well insulated.

Brownson and stebar have studied thermal reactor performance for a reactor coupled to a single cylinder CFR engine. In their work an insulated exhaust mixing tank of 150 cubic inch was used for some tests. They determined that the basic factors governing the combustion of CO and hydrocarbons in the exhaust system are composition of the reacting mixture, temperature and pressure of the mixture, and residence time of the mixture or time available for reaction.

The graph shows the hydrocarbon and CO emissions as a function of air-fuel ratio and injected air flow rate. The emission concentration results were corrected for the added air. Injected air flow rate is indicated as a percentage of the engine air volume flow rate. An insulated 150 cubic inch exhaust mixing tank was used.

The minimum HC concentrations occurred at rich mixtures. When too much air was injected, especially at lean mixtures, excessive cooling of the exhaust increased HC concentrations above those with no air. Thus the normal oxidation process was apparently inhibited by this cooling. A small increase in CO occurred slightly richer than stoichiometric. At stoichiometric mixtures and leaner, CO was very low. Best results occurred for rich mixtures with air injection at 20-30% of inlet air flow. The air-fuel ratio for best emission reduction was 13.5:1. Normally engine operation at such a rich mixture would reduce fuel economy by 10%.

At each air-fuel ratio there exists one minimum air injection rate that provides maximum emission reduction. Minimum air flow is desired in order to reduce pump power requirement, size and cost. Graph shows the optimum air injection rate for both HC and CO emissions.

CATALYTIC CONVERTERS:

Catalytic converters provide another way to treat the exhaust gas. These devices located in the exhaust system, convert the harmful pollutants into harmless gases.

In contrast to thermal reactors efficient catalytic oxidation catalysts can control CO and HC emissions almost completely at temperature equivalent to normal exhaust gas temperatures. Thus the fuel economy loss necessary to increase the exhaust temperature is avoided.

Inside the catalytic converter the exhaust gases pass over a large surface area coated with a catalyst. A catalyst is a material that causes a chemical reaction without actually becoming a part of the reaction process.

Catalytic reaction of NO can be represented as follows:

NO + CO à CO₂+ ½ N₂

NO + H₂ à H₂O + ½ N₂

10 NO + 4HC à 2H₂O + 4CO₂ + 5 N₂

HC / CO oxidation is represented by

CO + ½ O₂à CO₂

4HC + 5 O₂ à 2H₂O + 4CO₂

The figure shows a single bed catalytic converter. The exhaust gas and air are passed through a bed of platinum coated pellets or honeycomb core. HC and CO react with the oxygen in the air. Harmless ware and carbon dioxide are formed.

The catalyst platinum act on the exhaust gas in two ways, converting HC and CO to carbon dioxide and water. So it is called a two way catalyst.

Figure show a dual bed catalytic converter. The exhaust gas first passes through the upper bed. The upper bed contains a reducing catalyst ( example rhodium). NOx is reduced to nitrogen and oxygen in the upper bed. Then secondary air is mixed with the exhaust gas. The mixture of exhaust gas and secondary air flows to the lower bed. The lower bed contains an oxidizing catalyst ( example platinum). HC and CO are oxidized to water vapour and carbon dioxide in the lower bed. Here the catalyst rhodium is a one way catalyst since it acts o NOx only. Platinum is a two way catalyst since it acts on HC and CO.

A three way catalyst is a mixture of platinum and rhodium. It acts on all three of the regulated pollutants ( HC, CO and NOx) but only when the air-fuel ratio is precisely controlled. If the engine is operated with the ideal or stoichiometric air-fuel ratio of 14.7:1. The three way catalyst is very effective. It strips oxygen away from the NOx to form harmless water, carbon dioxide and nitrogen. However the air-fuel ratio must be precisely controlled, otherwise the three way catalyst does not work.

Figure shows a three way catalytic converter. The front section( in the direction of gas flow) handles NOx and partly handles HC and CO. The partly treated exhaust gas is mixed with secondary air. The mixture of partly treated exhaust gas and secondary air flows into the rear section of the chamber. The two way catalyst present in the rear section takes care of HC and CO.

Generally catalysts are classified as:

1. Supported catalysts based on

a. Noble metals b. Transition metals

Unsupported metallic alloys

NO-Reduction Catalysts:

From the literature, it is seen that the following materials have been tried successfully as reduction catalysts in the vehicle emission control

1. Copper oxide-chromia

2. Copper oxide – Vanadia

3. Iron oxide – Chromia

4. Nickel oxide pelleted on monolithic ceramic and metallic supports

5. Monel metal

6. Rare earth oxides

HC/CO oxidation catalysts:

1. Noble metal catalysts such as activated carbon, palladium or platinum

2. Transition metal oxide catalysts such as copper, cobalt, nickel and iron chromate as well as vanadium or manganese promoted versions of these metals.

3. Copper chromite-alumina and platinum oxide –alumina catalysts were developed with sufficient activity, stability and mechanical strength.

The catalysts chosen for vehicle emission control should satisfy the following:

1. High conversion efficiency under transient conditions

2. Effective for wide range of temperature ( for ambient to 1600 F)

3. Must withstand the poisoning action of additives in the gasoline that are emitted in the exhaust

4. Must be able to withstand thermal shock

5. Be attrition resistant to highly turbulent flows through the converter

6. Vehicle operation for 50,000 miles

7. Convert into harmless products

8. Cheap and readily available.

Converter Design:

Converter volume is fixed, based on the space velocity and exhaust flow rate

Space velocity = gas flow rate in cm^3 /hr / converter volume in cm^3

The reciprocal of this expression is the residence time. As the exhaust flow rate varies under different modes of vehicle operation, an average gas flow rate of 0.85m^3/min and a space velocity of 15000/hr are normally selected for the preliminary design of the converter. This will give a converter volume of 3,540 cm^3 in each stage.

Draw backs of the catalytic converter system:

1. Generally catalysts are active only at relatively high temperature. Emissions during warm-up cannot be catalysed and this period has particularly heavy emissions.

2. Catalysts operate over a wide but not unlimited temperature range. A temperature control is required to avoid burnout temperature at high speeds and loads.

3. Catalysts are poisoned by exhaust constituents in particular lead compounds. Hence conversion efficiency decreases with use.

4. The catalytic bed offers considerable back pressure which increases with use.

5. Catalytic converters are expensive.

Importance of unleaded Petrol:

Vehicles equipped with catalytic converters must use only un-leaded gasoline. If the gasoline contains lead, the lead will coat the catalyst and the converter will stop working.

OTHER EMISSIN CONTROL DEVICES:

1. Water injection:

In this a small amount of water is injected into the combustion chamber. Due to this the peak combustion temperature is reduced and thus NOx emission is reduced.

Graph shows nitric oxide reduction as a function of water rate. The spark advance was kept constant and the power loss was balanced by leaning the A/F ratio of the mixture. The specific fuel consumption as clear from the graph, decreases a few percent at medium water injection ratio. So for no attempts have been done to use water as a deice for controlling the NOx, perhaps because of complexity varying the amount of injection rate in relation to engine requirements.

2. Direct air Injection:

In this compressed air is introduced into the combustion chamber in addition to air fuel charge from the carburettor. This gives better combustion and hence reduced hydrocarbon and CO emission. This will also give tremendous power boost with some saving in fuel. But extra equipment in the form of air compressor and air valves will raise the cost very much. Also, exhaust gas recirculation will still be needed to curb NOx emissions.

3. Ammonia Injection:

In this ammonia is injected into the exhaust gas. Ammonia reacts with NOx in exhaust and forms nitrogen and water. Thus NOx emission is reduced.

As a fuel, ammonia does not hold much promise, but if used as an exhaust additive it can give excellent control for NOx emission. Ammonia and nitric oxide interact to form nitrogen and water. Ford motor company has been doing investigations with injecting Ammonia-water in the exhaust manifold, downstream from the port.

For an effective utilization of Ammonia injection, the exhaust gas temperature has to be kept within strict limits and the injecting device has to be put sufficiently down to bring the gas temperature to 165C. This also demands a very close tolerance in air-fuel ratio supplied by the carburettor. The present carburettors are incapable of this and it might be necessary to adopt electronic injection system to keep it.

4. Electronic Injection:

It is possible to develop an electronic injection system with sensors for air temperature, manifold pressure and speed which will precisely regulate the fuel supply giving only such air fuel ratio that will give no hydrocarbon or CO emissions.

Since the injection can be affected in individual intake ports, the problem of fuel distribution among various cylinders will automatically be avoided.

The emissions on deceleration can be completely removed by shutting off the fuel supply when the throttle is closed. But this system will still not be able to control the HC emission. Combination of electronic injection and ammonia as an exhaust additive has an attractive future.

UNIT – V

MEASUREMENT TECHNIQUES EMISSION STANDARDS AND TEST PROCEDURE

VEHICLE EMISSION STANDARDS:

Federal exhaust emission test procedures for light duty vehicles under 6000 lb GVW covering the period 1972 to 1975 assess hydrocarbon, carbon monoxide and nitric oxide emissions in terms of mass of emission emitted over a 7.5 mile chassis dynamometer driving cycle. Results are expressed as grams of pollutant emitted per mile.

There are two procedures in using the same test equipment which assess vehicle emissions. One, which is termed as CVS-1 (constant volume sampling), employs a single bag to collect a representative portion of the exhaust for subsequent analysis. This single bag system applied to testing of 1972, 1973 and 1974 vehicles. Based on this test, emission standards for vehicles have been set at

Hydrocarbons 3.4 g/mile (1972 to 1974)

Carbon monoxide 3.9 g/mile (1972 to 1974)

Oxide of nitrogen 3.0 g/mile (1973 to 1974)

The second test procedure, termed CVS-3 uses three sampling bags and is designed to give a reduced and more realistic weighing to cold start portion of the test. This three bag system applies to testing of 1975 to 1976 vehicles. Exhaust emission standards based on this test are

Hydrocarbons 0.41 g/mile (1975 to 1976)

Carbon monoxide 3.4 g/mile (1975 to 1976)

Oxide of nitrogen 3.0 g/mile (1975)

One of the latest U.S standards (1982) for passenger cars and equivalents are

Hydrocarbons 0.41 g/mile

Carbon monoxide 3.4 g/mile

Oxide of nitrogen 1.5 g/mile

These are measured by following a prescribed test procedure.

Driving Cycle:

The driving cycle for both CVS-1 and CVS-3 cycles is identical. It involves various accelerations, decelerations and cruise modes of operation. The car is started after soaking for 12 hours in a 60-80 F ambient. A trace of the driving cycle is shown in figure. Miles per hour versus time in seconds are plotted on the scale. Top speed is 56.7 mph. Shown for comparison is the FTP or California test cycle. For many advanced fast warm-up emission control systems, the end of the cold portion on the CVS test is the second idle at 125 seconds. This occurs at 0.68 miles. In the CVS tests, emissions are measured during cranking, start-up and for five seconds after ignition is turned off following the last deceleration. Consequently high emissions from excessive cranking are included. Details of operation for manual transmission vehicles as well as restart procedures and permissible test tolerance are included in the Federal Registers.

CVS-1 system:

The CVS-1 system, sometimes termed variable dilution sampling, is designed to measure the true mass of emissions. The system is shown in figure. A large positive displacement pump draws a constant volume flow of gas through the system. The exhaust of the vehicle is mixed with filtered room air and the mixture is then drawn through the pump. Sufficient air is used to dilute the exhaust in order to avoid vapour condensation, which could dissolve some pollutants and reduce measured values. Excessive dilution on the other hand, results in very low concentration with attendant measurement problems. A pump with capacity of 30-350 cfm provides sufficient dilution for most vehicles.

Before the exhaust-air mixture enters the pump, its temperature is controlled to within +or – 10F by the heat exchanger. Thus constant density is maintained in the sampling system and pump. A fraction of the diluted exhaust stream is drawn off by a pump P2 and ejected into an initially evacuated plastic bag. Preferably, the bag should be opaque and manufactured of Teflon or Teldar. A single bag is used for the entire test sample in the CVS-1 system.

Because of high dilution, ambient traces of HC, CO or NOx can significantly increase concentrations in the sample bag. A charcoal filter is employed for leveling ambient HC measurement. To correct for ambient contamination a bag of dilution air is taken simultaneously with the filling of the exhaust bag.

HC, CO and NOx measurements are made on a wet basis using FID, NDIR and chemiluminescent detectors respectively. Instruments must be constructed to accurately measure the relatively low concentrations of diluted exhaust.

Bags should be analyzed as quickly as possible preferably within ten minutes after the test because reactions such as those between NO, NO2 and HC can occur within the bag quite quickly and change the test results.

CVS-3 SYSTEM:

The CVS-3 system is identical to the CVS-1 system except that three exhaust sample bags are used. The normal test is run from a cold start just like the CVS-1 test. After deceleration ends at 505 seconds, the diluted exhaust flow is switched from the transient bag to the stabilized bag and revolution counter number 1 is switched off and number 2 is activated. The transient bag is analyzed immediately. The rest of the test is completed in the normal fashion and the stabilized bag analyzed. However in the CVS-3 test ten minutes after the test ends the cycle is begun and again run until the end of deceleration at 505 seconds. This second run is termed the hot start run. A fresh bag collects what is termed the hot transient sample. It is assumed that the second half of the hot start run is the same as the second half of the cold start run and is not repeated. In all, three exhaust sample bags are filled. An ambient air sample bag is also filled simultaneously.

STANDARDS IN INDIA:

The Bureau of Indian Standards ( BIS ) is one of the pioneering organizations to initiate work on air pollution control in

India

. At present only the standards for the emission of carbon monoxide are being suggested by BIS given in IS:9057-1986. These are based on the size of the vehicle and to be measured under idling conditions. The CO emission values are 5.5 percent for 2 or 3 wheeler vehicles with engine displacement of 75cc or less, 4.5 percent for higher sizes and 3.5 percent for four wheeled vehicles.

IS: 8118-1976 Smoke Emission Levels for Diesel vehicles prescribes the smoke limit for diesel engine as 75 Hatridge units or 5.2 Bosch units at full load and 60-70 percent rated speed or 65 Hatridge units under free acceleration conditions.

EMISSION MEASURING INSTRUMENTS:

Terms of expressions:

In emission measurement, volume concentrations of the several components are characteristically expressed in the following terms

1. Carbon dioxide and carbon monoxide are expressed as percent of the sample volume.

2. Nitric oxide and nitrogen dioxide are expressed as volume parts of NO or NO2 per million parts of the sample ( ppm). The total of NO and NO2 is designated as NOx.

3. Hydrocarbon is expressed as i. Parts of hydrocarbon per million parts of the sample or ii. Parts of carbon per million parts of the sample ( ppmc). The latter term is defined as the volume concentration of hydrocarbon in the sample multiplied by the average number of carbon atoms per molecule of that hydrocarbon. Thus 1ppm propane ( C3H8) is the equivalent of 3ppm C hydrocarbon. In the early days of emission measurement hydrocarbon emissions were measured in terms of the carbon equivalent of hexane or ppm hexane. Thus in early usage ppm values were often assumed to be ppm hexane even though not designated as hexane, this usage is ambiguous and should be avoided.

Flame Ionisation Detector ( FID ):

The unburned hydrocarbons in the exhaust consist of about 200 different compounds, each with different composition and different number of carbon and hydrogen atoms. It is impossible to detect each of these hydrocarbons separately. The over all concentration of the unburned hydrocarbons may be found by measuring the equivalent concentration of n-hexane ( C6H14). An accurate method of measuring the unburned hydrocarbon emissions is to use the Flame Ionisation Detector ( FID ).

The working principle of FID is as follows: A hydrogen-air flame contains a negligible amount of ions but if few hydrocarbon molecules are introduced into the flame a larger number of ions are produced. The ion yield is proportional to the amount of hydrocarbon introduced into the flame.

The basic elements of a Flame Ionisation Detector are as shown in the figure, a burner and ion collector assembly. In practice, a sample of gas is mixed with hydrogen in the burner assembly and the mixture burned in a diffusion flame. Ions that are produced in the flame move to the negatively polarized collector under the influence of an electrical potential applied between the collector plates. At the negative collector, the ions receive, via a current network, electrons that are collected from the flame zone at the positive collector. Thus a small current proportional to the amount of hydrocarbon entering the flame flows between the collector plates. This small current is amplified using a high impedance direct current amplifier, the output of which becomes an indication of hydrocarbon present.

The detector responds to carbon that is linked with hydrogen as in equation 1 and the response is largely independent of the molecular configuration, i.e hydrocarbon species. Thus the detector is essentially a carbon atom counter.

The output of the FID depends on the number of carbon atoms passing through the flame in a unit time. Doubling the flow velocity would also double the output. Hexane ( C6H14) would give double the output of propane ( C3H8). Therefore FID output is usually referred to a standard hydrocarbon usually as PPM of normal hexane.

Characteristics of the FID are improved with most burned designs if instead of using pure hydrogen fuel, the hydrogen is mixed with inert gas to decrease flame temperature. This mixture of hydrogen and inert gas is referred to as fuel gas or fuel.

The FID responds directly to the amount of hydrocarbon entering the flame. Therefore close control of sample flow is required. In general, the sample flow rate is specified at the minimum amount that will give the required sensitivity in any given instrument. Fuel and air flow rates also influence the response characteristics of the detector. Response typically first rises and then fall with increased fuel rate, as shown in the figure. Typical volume rates of instrument gases are sample 3-5 ml/min and fuel gas mixture 75ml/min and air 200ml/min.

Presence of CO, CO2, NOx, water and nitrogen in the exhaust have no effect on the FID reading.

FID analyzer is rapid, continuous and accurate method of measuring HC in the exhaust gas concentrations as low as 1ppb can be measured.