A small intro:
Alcohol is a bio-based renewable and oxygenated fuel, thereby providing potential to increase performance, reduce
the PM emission in diesel engines and to provide reduction in life cycle
CO2.The objective of this investigation is to first create a stable
alcohol-diesel blended fuel, and then to generate transient performance, and
emissions data for evaluation of different alcohol content on a diesel engine.
Isopropyl alcohol a new oxygenate is investigated in this study. A
single-cylinder, air-cooled, direct injection diesel engine developing a power
output of 5.2 kW at 1500 rev/min was used. Base data was generated with
standard diesel fuel. Subsequently four fuel blends, namely 90D: 10IPAa,
85D: 15IPA, 75D: 25IPA and 70D: 30IPA percentage by volume were prepared and
tested. Engine performance and emission data were used to optimize the blends
for reducing emission and improving performance. Results show improved
performance with blends compared to neat fuel for all conditions of the engine.
However, 75D: 25IPA blends recorded a maximum brake thermal efficiency of
36.86%. Drastic reduction in NOx was observed with slight increase in HC
emissions for the blends as compared to neat diesel.
What
guys just confused ok , I explain it in a simple way :)
- Its just mixing of Isopropyl alcohol (which
is nothing but rubbing alcohol like CD cleaner liquid) with ordinary
diesel fuel of different proportions like 10%,20%,25%,30%..
- Then its performance and emission are tested
in ordinary diesel engines...
Hereby I gave my work
completely guys :
EXPERIMENTAL SETUP
Diesel with
Isopropyl alcohol blends are used in single cylinder diesel engine. The diesel
engine is operated on different blend ratios 90D: 10IPA, 85D: 15IPA, 75D:
25IPA and 70D: 30IPA respectively.
Experiments were
conducted on a, single-cylinder, water-cooled, direct injection diesel engine
developing a power output of 5.2 kW at 1500 rev/min connected with a water
cooled eddy current dynamometer. The engine was operated at a constant speed of
1500 rpm and standard injection pressure of 220 Kgf/cm2. The specification of
the engine is given in Table1. The fuel flow rate was measured on volume basis
using a burette and a stop watch. K-type thermocouple and a digital display
were employed to note the exhaust gas temperature.
NOx emission is measured
with help of an exhaust gas analyzer. AVL smoke meter is used to measure the
smoke density. AVL five-gas analyzer is used to measure the rest of the
pollutants. A burette is used to measure the fuel consumption for a specified
time interval. During this interval of time, how much fuel the engine consumes
is measured, with the help of the stopwatch.
Type
|
Vertical,
Water Cooled, Four Stroke
|
|
Number
of Cylinder
|
One
|
|
Bore
|
87.5
mm
|
|
Stroke
|
110
mm
|
|
Compression
Ratio
|
17.5:1
|
|
Maximum
Power
|
5.2
kW
|
|
Speed
|
1500
Rev/min
|
|
Dynamometer
|
Eddy
Current
|
|
Injection
Timing
|
23o Before
TDC
|
|
Injection
Pressure
|
220
kgf/cm2 , Direct Injection
|
|
Specifications
of the Test Engine
EXPERIMENTAL PROCEDURE
The engine was allowed to run with neat diesel at a various load
for nearly 10 minutes to attain the steady state constant speed conditions.
Then the following observations were made.
1 The water flow is
started and maintained constant throughout the experiment.
2 The load, speed and
temperature indicators were switched on.
3 The engine was started
by cranking after ensuring that there is no load.
4 The engine is allowed
to run at the rated speed of 1500 rev/min for a period of 10 minutes to reach
the steady state.
5 The fuel consumption is
measured by a stop watch.
6 Smoke readings were
measured using the Smoke meter at the exhaust outlet.
7 The NOx emission was
measured using exhaust gas analyzer.
8 The exhaust temperature
was measured at the indicated by using a sensor.
9 Then the load is
applied by adjusting the knob, which is connected to the eddy current
dynamometer.
10 Experiments were conducted using neat diesel –
ethanol, diesel, and Isopropyl alcohol the above procedure is adopted.
Experimental setup
RESULTS AND DISCUSSION
The figure 1 shows the Specific fuel consumption for different concentration of Isopropyl alcohol. The specific fuel consumption increases with increase in brake power of the engine. Among the blends 70D:30 IPA concentration of Isopropyl alcohol shows lower specific fuel consumption than other concentrations.
Figure 1.Variation of SFC for Diesel: IPA blends at peak load.
Figure 2 shows the brake thermal efficiency for different ratio of fuel Isopropyl alcohol. The brake thermal efficiency increases with increase in brake power of the engine. Among the blend ratio 75D: 25 IPA concentration of Isopropyl alcohol shows higher than that of other blend ratio.
Figure 2.Variation of BTE for Diesel: IPA blends at peak load
The presence of oxygen due to the addition of Isopropyl alcohol in the diesel fuel, improve the combustion, especially diffusion combustion and hence increase the brake thermal efficiency.
Fig. 3 shows the exhaust smoke (soot) density for the neat diesel fuel and the various percentages of the IPA in its blends with diesel fuel. One can observe that the soot emitted by the 70D:30IPA fuel blends is significantly lower than that for the corresponding neat diesel fuel case, with the reduction being higher the higher the percentage of in the blend. The results reveal that the tendency to generate soot from the fuel-rich regions inside diesel diffusion flame is decreased by Isopropyl alcohol in the blends.
Figure 4.Variation of EGT for Diesel: IPA blends at peak load
Figure 4 gives the exhaust gas temperature with different concentration of blend ratio. The result is shown that exhaust gas increases linear with increase of brake power of the engine. It can be concluded that all the blend ratio of Isopropyl alcohol lower the exhaust gases than sole fuel.
Figure5.Variation of NOx for Diesel: IPA blends at peak load
Figure 5 shows NOx emission of Isopropyl alcohol concentration. It can be seen that NOx emission decreases with bled ratio than sole fuel shows max reduction of NOx emissions. Among the blend ratio 70D:30IPA concentration of Isopropyl alcohol shows lower than that of other blend ratio at peak load.
Figure6.Variation of HC for Diesel: IPA blends at peak load
Figure 6 shows that hydrocarbon emission of blend ratio concentration. It can be seen that hydrocarbon emission increases with all the concentration of blend ratio than sole fuel.
