Performance analysis of a single cylinder diesel engine using cotton seed oil.
Basha, M. Shameer ; Reddy, B.G. Krishna ; Reddy, K. Vijaya Kumar 等
Introduction
With the rapid development of automobile engines and fast depletion
of fossil fuels, the discrepancy between demand foe and supply of energy
has become and increasingly acute problem. Among the many different
types of alternative fuels, vegetable oils and their esters come across
as good choices. They are renewable, as the carbon released by the
burning of vegetable oils is used when the oil crops undergo
photosynthesis.
China is rich in cotton seed and research using cotton seed oil as
diesel engine fuel has been intensively and widely studied here. From a
technological point of view the fuel property of cotton seed oil seems
to meet the fundamental requirements of diesel engine. It has been
observed that by using cotton seed oil as there is unnecessary change in
engine structure. There are differences between properties of the cotton
seed oil and diesel oil, for the smooth engine performance optimum oil
mixture.
An extended experimental study is conducted to evaluate and compare
the use of various diesel fuel supplements at blend ratio's varying
from 25/75v/v to 75/25v/v by C.D. Rakpoulus et al [1]. An extended
experimental study is conducted to evaluate and compare the use of
various diesel fuel supplements at blend ratio's varying from
10/90v/v to 20/80v/v by C.D. Rakpoulus et al [1]. The researchers mainly
concentrated on the emission characteristics. Georgios Fontaras et al
[3] studied the performance of a Euro3-compliant diesel passenger car
using 10/90v/v cotton seed oil and diesel blend which showed promising
results. The higher blends of the cotton seed oil/diesel and palm
oil/diesel are mostly considered not viable alternatives for diesel, in
the emission point of view.
Y.D. Wang et al [2] carried out a series of experiments on
different vegetable oil blends varying in 25%, 50% and 75% proportions
and at different load conditions varying between no load to full load
i.e. 0%, 25%, 50%, 75%, 100% loads. The effect of variation of injection
pressure on the performance of the C.I engine using different blends
i.e. 25/75v/v, 50/50v/v, 75/25v/v 100/0 v/v, of cotton seed oil/diesel
oil, palm oil/diesel oil are generally neglected in the literature. In
the present research work, the effect of variation of injection
pressure, using different blends of cotton seed oildiesel, with and
without preheating are studied.
Experimental Procedure
The engine is started by hand cranking and with the help of the
decompression lever. The rack in the fuel pump is adjusted to run the
engine at rated speed of 1500 rpm. (At no load). Cooling water supply
valve is opened, and the water flow is adjusted such that the outlet
temperature of water is around 50[degrees] to 60[degrees]C. When the
engine runs steadily without fluctuations in the speed, time taken for
25cc of fuel consumption is noted down.
The exhaust gas temperature is also measured. Load is applied on
the dynamometer by opening the water inlet valve. When load is applied,
the speed falls. The engine speed is brought back to the rated speed (of
1500 rpm) by adjusting the fuel supply. Once again, the time taken for
25cc of fuel consumption and exhaust gas temperatures are noted down.
Now the engine is loaded in steps from zero loads to rated load.
In all these cases, the engine speed is maintained constant at
rated speed by adjusting the fuel supply. Smoke density is also measured
at no load, half load and rated load conditions. Constant speed
performance is conducted at different injection pressure of diesel,
cotton seed oil and blends of cotton seed oil- diesel. At each of this
condition, energy balance heat converted into work and heat carried away
by exhaust gases are calculated.
Results and discussions
The analysis of the experimental data obtained to characterize the
fuel propertied of cotton seed oil and cotton seed oil-diesel blends.
The performance of the engine with these fuels is also analyzed.
Figure (a) shows that the SFC of Cotton seed oil is around 8 to 9%
greater than the corresponding SFC with diesel. This can be attributed
to the lower value of calorific value of cotton seed oil compared to
diesel.
Figure (b) shows the comparison of S.F.C. at three different
injection pressures of 200 kg/[cm.sup.2], 225 kg/[cm.sup.2] and 250
kg/[cm.sup.2]. S.F.C. is minimum at 225 kg/[cm.sup.2]. With increase in
the fuel injection pressure, the droplet size, no doubt decreases, but
the velocity is so high, that it goes and hits the cylinder walls
Figure (c) shows the comparison of SFC vs. BKW at three different
injection pressures of 200, 225, 250kg/[cm.sup.2]. From the figure it
can be observed that the SFC is minimum at 225 kg/[cm.sup.2]. This can
be explained that the increase in fuel injection pressures depends on
the droplet size. This is also supported by the higher exhaust gas
temperature and higher smoke levels as shown in Figures (d) and (e).
It can be seen from the figure (f) there is a 4-6% decrease in the
S.F.C with preheating. This is because of the improved spray
characteristics.
It is observed that for 50%-50% Cotton seed oil--diesel blend, the
brake thermal efficiency is almost identical with that of pure diesel
operating throughout the range of power output. However, for the 75%-25%
Cotton seed oil -diesel blend, the thermal efficiency is 4-5% less. This
can be attributed to the poor spray characteristics.
[FIGURE (a) OMITTED]
[FIGURE (b) OMITTED]
[FIGURE (c) OMITTED]
[FIGURE (d) OMITTED]
[FIGURE (e) OMITTED]
[FIGURE (f) OMITTED]
Conclusions
Test result shows 25% cotton seed oil and 75% diesel oil was
suitable for it to be used as diesel fuel. The main factor influencing
the specific fuel consumption or thermal efficiency is good at fuel
injection pressure at 225Kgf.Heat losses in the engine are reduced with
the usage of cotton seed oil because exhaust gas temperatures are lower
when compared to diesel. Hence brake thermal efficiency of cotton seed
oil is higher.
References
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(1) M. Shameer Basha, (2) B.G. Krishna Reddy, (3) K. Vijaya Kumar
Reddy, (4) P. Ravi Kumar and (5) B. Sudheer Prem Kumar
(1) 9-4-86/136, 1st Floor, Salarjung Colony, Mehdipatnam Hyderbad
500008, Andhra Pradesh
(2) 17-1-389/1/203, Prasanth Nagar, Saida Bad, Hyderabad 500058,
Andhrapradesh
(3) Professor In Mechanical Department, Jntuce, Jntu Kukutpally,
Hyderbad500085, Andhra Pradesh
(4) Associate Professor, Nit, Warangal 506004, Andhra Pradesh
(5)Assoc.Professor In Mechanical Department, Jntuce, Jntu
Hyderbad500085, Andhra Pradesh
