This document summarizes research adapting a VW Golf automobile to run on pure rapeseed oil as fuel. Key points:
- A VW Golf with a 1.9L diesel engine was modified using an Elsbett one-tank conversion kit, allowing it to use pure rapeseed oil as fuel.
- Initial tests were conducted in winter conditions down to -7°C. The modified engine started and drove without issues, showing rapeseed oil fuel consumption was slightly higher than diesel but better than biodiesel.
- Component temperature measurements showed the electric fuel heater brought oil temperatures over 60°C within 1.5-1.7 minutes, allowing warm engine operation on rapeseed oil even below
The International Journal of Engineering and Science (The IJES)theijes
The International Journal of Engineering & Science is aimed at providing a platform for researchers, engineers, scientists, or educators to publish their original research results, to exchange new ideas, to disseminate information in innovative designs, engineering experiences and technological skills. It is also the Journal's objective to promote engineering and technology education. All papers submitted to the Journal will be blind peer-reviewed. Only original articles will be published.
The papers for publication in The International Journal of Engineering& Science are selected through rigorous peer reviews to ensure originality, timeliness, relevance, and readability
Comparative Study Of Synthetic Oil And Mineral Oil On The Basis Of Physical C...ijifr
Petroleum oils are insufficient in lubricating our engines since they are
made of refined substance, since some of the chemicals present in
conventional petroleum oil break down at temperatures within the normal
range usually around 325 to 250 degree Fahrenheit. Synthetic Oil
outperforms all brands of petroleum oil in every aspect, but the best benefit
we can derived from continuous use of synthetic oil is the extended life of
your vehicle. Synthetic oil will make your engine last longer that petroleum
oil through its continuous use. Throughout its history, the diesel has been the
subject of a great deal of research and development. This work has focused
on comparative study of physical properties Synthetic Oil and Mineral Oil.
take this privilege to welcome all of you to the continuous 36th edition of International Journal Of Informative & Futuristic Research (IJIFR) - Volume 3, Issue 12, August 2016.
The International Journal of Engineering and Science (The IJES)theijes
The International Journal of Engineering & Science is aimed at providing a platform for researchers, engineers, scientists, or educators to publish their original research results, to exchange new ideas, to disseminate information in innovative designs, engineering experiences and technological skills. It is also the Journal's objective to promote engineering and technology education. All papers submitted to the Journal will be blind peer-reviewed. Only original articles will be published.
The papers for publication in The International Journal of Engineering& Science are selected through rigorous peer reviews to ensure originality, timeliness, relevance, and readability
Comparative Study Of Synthetic Oil And Mineral Oil On The Basis Of Physical C...ijifr
Petroleum oils are insufficient in lubricating our engines since they are
made of refined substance, since some of the chemicals present in
conventional petroleum oil break down at temperatures within the normal
range usually around 325 to 250 degree Fahrenheit. Synthetic Oil
outperforms all brands of petroleum oil in every aspect, but the best benefit
we can derived from continuous use of synthetic oil is the extended life of
your vehicle. Synthetic oil will make your engine last longer that petroleum
oil through its continuous use. Throughout its history, the diesel has been the
subject of a great deal of research and development. This work has focused
on comparative study of physical properties Synthetic Oil and Mineral Oil.
take this privilege to welcome all of you to the continuous 36th edition of International Journal Of Informative & Futuristic Research (IJIFR) - Volume 3, Issue 12, August 2016.
Experimental Investigation on Use of Honge(Pongamia) Biodiesel on Multi-cylin...ijsrd.com
Biodiesel is a fatty acid alkyl ester which is renewable, biodegradable and non toxic fuel which can be derived from any vegetable oil by transesterifiaction process. Biodiesel has become a key source as a substitution fuel and is making its place as a key future renewable energy source. Biodiesel derived from vegetable oils are quite promising alternative fuels for diesel engines. Use of vegetable oils in diesel engines leads to slightly inferior performance and higher smoke emissions due to their high viscosity. The performance of vegetable oils can be improved by modifying them through the Transesterification process. In the present work, the performance of single cylinder direct injection diesel engine using honge as fuel was evaluated for its performance, emission and combustion characteristics. The properties of honge thus obtained are comparable with ASTM biodiesel standards. The produced honge biodiesel was tested for their use as a substitute fuel for diesel engine. Tests have been conducted at different varying load of biodiesel, at 60% throttle. The performance parameters elucidated includes brake thermal efficiency, specific fuel consumption, torque, also emission characteristics against varying Brake Power (BP) and combustion characteristics against crank angle.
Experimental Investigation on Performance, Emission and Combustion Character...IJMER
Diesel is a fossil fuel that is getting depleted at a fast rate. So an alternative fuel is necessary
and a need of the hour. Rice bran oil, which is cultivated in India at large scales, has a high potential
to become an alternative fuel to replace diesel fuel. Direct use of mahua oil cannot be done, as its
viscosity is more than the diesel fuel, and hence affects the combustion characteristics. The mahua oil is
esterified to reduce the viscosity and it is blended with diesel on volume basis in different proportions.
The use of thermal barrier coatings (TBCs) to increase the combustion temperature in diesel engines
has been pursued for over 20 years. Increased combustion temperature can increase the efficiency of
the engine. However, TBCs have not yet met with wide success in diesel engine applications because of
various problems associated with the thermo-mechanical properties of the coating materials. Although,
the in-cylinder temperatures that can be achieved by the application of ceramic coatings can be as high
as 850-9000C compared to current temperatures of 650-7000C. The increase in the in-cylinder
temperatures helped in better release of energy in the case of biodiesel fuels thereby reducing emissions
at, almost the same performance as the diesel fuel. Here the effort has been made to determine the
performance, emission and combustion characteristics of MOME blend with diesel in conventional
engine and LHR engine.
Effect of Diesel Engine Fuelled with Biofuel Blendsijtsrd
The present work was conducted on a 1-cylinder, 4S, DI CI engine, on which neat diesel, neem biodiesel and polanga biodiesel and ethanol fuel were tested by varying the load on the engine setup at various blend ratios such as - diesel fuel 100 D100 , biodiesel neem 100 N100 , biodiesel polanga 50 blended with diesel 50 P50 , and ethanol 5 blended with diesel 95 E5 .The research carried was to compare the performance-emission characteristics of various blend samples w.r.t neat diesel fuel. The performance results show that, the BTE of N100, P50 fuel blends was less than E5 blend, as compared to neat diesel, whereas, the BSFC of D100, E5 blend had a decreasing nature than N100 and P50 blend. The CO emissions among the biofuel blends was maximum for N100 and then P50 blend but the least was for E5 blend w.r.t neat diesel. Also, the UHC emission for N100, P50 and E5 blends had a decreasing trend than neat diesel fuel. The D100 fuel had a maximum NOx emission in comparison to others and the least was by E5 blend. The CO2 emission of N100 and D100 was the highest than P50 and E5 blends during the operation. The unused O2for N100 fuel was the least than other fuel samples and the maximum was for E5 blend. The biofuel blends being used here had an effective outcome which can be utilised as an substitute for neat diesel. Akash Paul | Amiya Bhaumik | Kushal Burman "Effect of Diesel Engine Fuelled with Biofuel Blends" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-2 | Issue-6 , October 2018, URL: http://www.ijtsrd.com/papers/ijtsrd18915.pdf
The search for alternative fuels in last few decades is intensive due to the rapid
depletion of petroleum fuels and their ever increasing costs. There is a great need to
reduce the consumption of conventional fuels in both developed and developing countries.
The consumption and demand of the petroleum based fuels is increasing every year due
to the increased industrialization and innovation in the world. The aim of the present
experimental work is to evaluate the impact of various compression ratio using blends of
diesel fuel with 20% concentration of Methyl Ester of Jatropha biodiesel blended with bio
additive and the blends of diesel fuel with 20% concentration of methyl ester of mahua
biodiesel blended with bio additive as an alternate fuel. The experiment is carried out
with three different compression ratios in DI diesel engine. Biodiesel is extracted from
Jatropha oil and mahua oil, 20% (B20) concentration with 3ml bio additive is found to
be the best blend ratio from the earlier experimental study. 3ml of biodiesel B20MEOJBA
and 3ml of B20MEOMBA is tested with compression ratio of 17.5. The purpose of the
experimental study is to obtain better efficiency, minimum specific fuel consumption, and
lower smoke and lesser emission. This is done by increasing cetane number using
combustion additives of 3ml bio additive blends with biodiesel when compared with the
baseline diesel.
Experimental Investigation on Use of Honge(Pongamia) Biodiesel on Multi-cylin...ijsrd.com
Biodiesel is a fatty acid alkyl ester which is renewable, biodegradable and non toxic fuel which can be derived from any vegetable oil by transesterifiaction process. Biodiesel has become a key source as a substitution fuel and is making its place as a key future renewable energy source. Biodiesel derived from vegetable oils are quite promising alternative fuels for diesel engines. Use of vegetable oils in diesel engines leads to slightly inferior performance and higher smoke emissions due to their high viscosity. The performance of vegetable oils can be improved by modifying them through the Transesterification process. In the present work, the performance of single cylinder direct injection diesel engine using honge as fuel was evaluated for its performance, emission and combustion characteristics. The properties of honge thus obtained are comparable with ASTM biodiesel standards. The produced honge biodiesel was tested for their use as a substitute fuel for diesel engine. Tests have been conducted at different varying load of biodiesel, at 60% throttle. The performance parameters elucidated includes brake thermal efficiency, specific fuel consumption, torque, also emission characteristics against varying Brake Power (BP) and combustion characteristics against crank angle.
Experimental Investigation on Performance, Emission and Combustion Character...IJMER
Diesel is a fossil fuel that is getting depleted at a fast rate. So an alternative fuel is necessary
and a need of the hour. Rice bran oil, which is cultivated in India at large scales, has a high potential
to become an alternative fuel to replace diesel fuel. Direct use of mahua oil cannot be done, as its
viscosity is more than the diesel fuel, and hence affects the combustion characteristics. The mahua oil is
esterified to reduce the viscosity and it is blended with diesel on volume basis in different proportions.
The use of thermal barrier coatings (TBCs) to increase the combustion temperature in diesel engines
has been pursued for over 20 years. Increased combustion temperature can increase the efficiency of
the engine. However, TBCs have not yet met with wide success in diesel engine applications because of
various problems associated with the thermo-mechanical properties of the coating materials. Although,
the in-cylinder temperatures that can be achieved by the application of ceramic coatings can be as high
as 850-9000C compared to current temperatures of 650-7000C. The increase in the in-cylinder
temperatures helped in better release of energy in the case of biodiesel fuels thereby reducing emissions
at, almost the same performance as the diesel fuel. Here the effort has been made to determine the
performance, emission and combustion characteristics of MOME blend with diesel in conventional
engine and LHR engine.
Effect of Diesel Engine Fuelled with Biofuel Blendsijtsrd
The present work was conducted on a 1-cylinder, 4S, DI CI engine, on which neat diesel, neem biodiesel and polanga biodiesel and ethanol fuel were tested by varying the load on the engine setup at various blend ratios such as - diesel fuel 100 D100 , biodiesel neem 100 N100 , biodiesel polanga 50 blended with diesel 50 P50 , and ethanol 5 blended with diesel 95 E5 .The research carried was to compare the performance-emission characteristics of various blend samples w.r.t neat diesel fuel. The performance results show that, the BTE of N100, P50 fuel blends was less than E5 blend, as compared to neat diesel, whereas, the BSFC of D100, E5 blend had a decreasing nature than N100 and P50 blend. The CO emissions among the biofuel blends was maximum for N100 and then P50 blend but the least was for E5 blend w.r.t neat diesel. Also, the UHC emission for N100, P50 and E5 blends had a decreasing trend than neat diesel fuel. The D100 fuel had a maximum NOx emission in comparison to others and the least was by E5 blend. The CO2 emission of N100 and D100 was the highest than P50 and E5 blends during the operation. The unused O2for N100 fuel was the least than other fuel samples and the maximum was for E5 blend. The biofuel blends being used here had an effective outcome which can be utilised as an substitute for neat diesel. Akash Paul | Amiya Bhaumik | Kushal Burman "Effect of Diesel Engine Fuelled with Biofuel Blends" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-2 | Issue-6 , October 2018, URL: http://www.ijtsrd.com/papers/ijtsrd18915.pdf
The search for alternative fuels in last few decades is intensive due to the rapid
depletion of petroleum fuels and their ever increasing costs. There is a great need to
reduce the consumption of conventional fuels in both developed and developing countries.
The consumption and demand of the petroleum based fuels is increasing every year due
to the increased industrialization and innovation in the world. The aim of the present
experimental work is to evaluate the impact of various compression ratio using blends of
diesel fuel with 20% concentration of Methyl Ester of Jatropha biodiesel blended with bio
additive and the blends of diesel fuel with 20% concentration of methyl ester of mahua
biodiesel blended with bio additive as an alternate fuel. The experiment is carried out
with three different compression ratios in DI diesel engine. Biodiesel is extracted from
Jatropha oil and mahua oil, 20% (B20) concentration with 3ml bio additive is found to
be the best blend ratio from the earlier experimental study. 3ml of biodiesel B20MEOJBA
and 3ml of B20MEOMBA is tested with compression ratio of 17.5. The purpose of the
experimental study is to obtain better efficiency, minimum specific fuel consumption, and
lower smoke and lesser emission. This is done by increasing cetane number using
combustion additives of 3ml bio additive blends with biodiesel when compared with the
baseline diesel.
A Technical Review of Biodiesel Fuel Emissions and Performance on Industrial ...IJMER
Biofuels play an important role in many developing countries as a clean liquid fuel which helps
to address the energy, costs and global warming as compared to petroleum fuels. Biodiesel can be
blended to any level to any petroleum diesel to create a biodiesel blend. Blending of biodiesel with small
amount of petroleum product gives control to air pollution. Additives plays and important role in
minimizing the NOx Emission which result in sigh of relief who are opting biodiesel as an alternative fuel.
In the future the biodiesel play an important role in reduce the greenhouse gases In this review article the
reports on regulated and non-regulated emission, durability, economy and performance on biodiesel by
various researchers have seen cited since 2000
Generally the fuels which are sourced from plants or waste products and are known as alternative or bio-fuels.
Pure Plant Oil (PPO) is also known as SVO – straight vegetable oil. It is not a bio diesel.
Bio methanol is the product of the trans esterification of vegetable/waste oil or animal fats.
Bio ethanol is mainly used in petrol engines to deliver higher performance and reduced emissions.
Natural gas, a fossil fuel comprised mostly of methane, is one of the cleanest burning alternative fuels.
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Adapting A VW Golf Car For Using Pure Rapeseed Oil As Fuel
1. ENGINEERING FOR RURAL DEVELOPMENT Jelgava, 28.-29.05.2009.
ADAPTING OF AUTOMOBILE VW GOLF FOR USING PURE RAPESEED OIL AS FUEL
Ilmars Dukulis, Aivars Birkavs, Gints Birzietis, Vilnis Pirs
Latvia University of Agriculture
Ilmars.Dukulis@llu.lv, Aivars.Birkavs@llu.lv, Gints.Birzietis@llu.lv, Vilnis.Pirs@llu.lv
Abstract. The use of straight vegetable oil in diesel engines is one of the available alternatives nowadays how to
introduce in practice the EU biofuel Directive with a target of 5.75 % biofuels in 2010, but it usually requires
modification of the engine or fuel system components. This article presents adapting of automobile VW GOLF
for using pure rapeseed oil as a fuel. The car was modified using the ELSBETT one-tank conversion kit, and the
first exploitation tests were carried out in winter time when the air temperature reached -7 °C. Starting the engine
and driving in such weather conditions did not cause any problems. Fuel consumption was estimated in two
different routes – in intensive traffic conditions in Jelgava city and outside the urban area. The first test results
show that pure rapeseed oil fuel consumption is slightly behind fossil diesel, but quite significantly overtakes
biodiesel. The modified diesel engine was successfully operated not only with rapeseed oil, but also with fossil
diesel and biodiesel, and with various mixtures of these fuels. Analyses of rapeseed oil manufactured in Latvia
were performed in Latvia and Germany. They showed that in order to avoid problems of using this oil as a fuel is
substantially to control the quality of seeds and pressing process regimes.
Keywords: biofuels, straight vegetable oil (SVO), rapeseed oil, fuel consumption, one-tank system
Introduction
Rapidly growing interest in biofuels is being spurred by the realization that they represent only a
large near-term substitute for the petroleum fuels that provide more than 95 % of the world’s
transportation energy. Today, the question is not whether renewable biofuels will play a significant
role in providing energy for transportation, but rather what the implementations of their use will be –
for economy, for the environment, for global security, and for the health of societies.
The liquid biofuels most widely used for transport today are ethanol and biodiesel, which can both
be used in existing vehicles where ethanol is blended with gasoline and biodiesel is blended with
conventional diesel fuel. The use of straight vegetable oil (SVO) and pure biodiesel in diesel engines
as well as neat bioethanol in spark-ignition engines are other available alternatives nowadays, but they
may require modification of the engine or fuel system components.
Due to SVO relatively high viscosity (approximately 12 times higher than ordinary diesel), using
SVO in unmodified engines can result in poor atomization of the fuel in the combustion chamber,
incomplete combustion, cooking of the injectors, and accumulation of soot deposits in the piston
crown, rings and lubricating oil [1]. In order to run on SVO, these engines must either be refitted
(often by attaching a mechanism for pre-heating oil), or they must be dedicated engines, such as the
Elsbett engine [2]. Vehicle manufacturers generally will not warranty their engines for operation with
SVO. Moreover, development of modern engines has led in the direction of increased electronic
engine and combustion control systems, which are generally not compatible with operation using
SVO. If SVO is to be used in conjunction with diesel in a dual-fuel mode, necessary modifications
include an additional fuel tank for SVO, a system to allow for switching between the two fuels, and a
heating system for the SVO tank and lines if the vehicle operates in low temperatures. Under this
configuration, the engine started on diesel and switched over to SVO as soon as it is warmed up. It is
then switched back to diesel shortly before being turned off to ensure that it contains no SVO when it
is restarted. Another alternative is to use SVO exclusively. Modifications would include an electric
pre-heating system for the fuel (including lines and filters), an upgraded injection system, and the
addition of glow plugs in the combustion chamber since vegetable oil is not highly flammable. The
modification can be expensive, reaching a cost of € 2 000 or more [1].
The EU biofuels market, under the biofuels Directive with an extrapolated target of 20 % biofuels
in 2030 [3], has been modelled with the BIOTRANS model with the aim to conduct quantitative
analyses on the production and costs of biofuels, and on the resulting market structure and supply
chains. According to the BIOTRANS analysis, of the conventional biofuels PVO proves to be the
lowest cost option compared to biodiesel and bioethanol, even with the necessary cost of vehicle
adaptation (Table 1) [4].
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2. ENGINEERING FOR RURAL DEVELOPMENT Jelgava, 28.-29.05.2009.
Table 1
Lowest cost biofuel mix up to 2030
Biofuel 2005 2010 2015 2020 2025 2030
PVO 90 % 80 % 70 % 50 % 41 % 20 %
Biodiesel 10 % 3% 4% 4% 4% 4%
Bio-DME 1% 2% 20 % 30 % 53 %
Biomethanol 6% 14 % 15 % 15 % 14 %
CSNG 10 % 10 % 11 % 10 % 9%
The key message is that in order to reach the 5.75 % target in 2010 a 100 % use of PVO and
biodiesel exclusively for the diesel fleet of vehicles would be more cost-efficient than the use of E-05
bioethanol for the petrol fleet. The BIOTRANS model predicts that after 2010 the fraction of PVO –
and in practise also biodiesel – in the biofuel mix decreases in favour of that of advanced biofuels. The
reason for this is that in order to achieve increasing biofuel targets less attractive potentials (less
suitable land for crop production) for PVO and biodiesel would have to be used, which leads to higher
costs for these fuels. If PVO and biodiesel become more expensive, the use of advanced biofuels may
become economically attractive, when they are available.
Rapeseed oil as fuel in Latvia by the law was approved in May 2006, and it can be used in diesel
engines considering certain emission requirements. The rapeseed oil quality requirements are set down
by the Cabinet of Ministers regulations No. 515, which were enforced in July 2007. These norms are
based on the German Quality Standard for Rapeseed Oil as a Fuel (RK-Qualitätsstandard) [5]. The
main properties defined by the standard are the density, flash point, kinematic viscosity, carbon
residue, iodine number, and the sulphur content, but limiting values are determined for the
contamination, acid value, oxidation stability, and the content of phosphorus, ash, and water.
The most experienced country in the use of biofuels is Germany where over 50 companies offer
adaptation technique for rapeseed oil fuel. Adaptation costs vary from € 1 000 to € 7 000. Adapted
engines are used in cars, busses, trucks, tractors, agricultural and construction machinery, stationary
engines, boats, trains, etc. Far more than 12 000 adapted engines are operated with rapeseed oil.
Emission tests with rapeseed fuelled tractor Deutz-Fahr (162 PS) on the test bench show that limiting
values of CO, HC and particulate matter of EURO norms for rapeseed oil and diesel fuel are met, but
emission of NOx with rapeseed oil fuel is up to 14 % higher than the limiting value [6].
Considering, that at the Scientific Laboratory of Biofuels (Latvia University of Agriculture) very
qualitative laboratory equipment, for example, the laboratory chassis dynamometer MD-1750, fuel
consumption meter AVL KMA Mobile, and the SESAM FTIR system for measuring emissions in
exhaust gases, is available, as well as the fact that in cooperation with the limited company
IECAVNIEKS studies of the MAN TGA 18.410 exploitation, using the pure rapeseed oil and a two-
tank system recently were carried out, it was decided to modify a passenger car to run on pure
rapeseed oil, but using a one-tank system. The one-tank choice was based on the fact that in the
passenger car facilities to install a second tank without taking up much room at the baggage
compartment are limited. In addition, the excess weight carriage would lead to increased fuel
consumption and reduction of dynamic performance. Moreover, in many countries (including Latvia)
the second fuel tank is classified as a modification, which requires a special certification for the car to
successfully pass the roadworthiness test. Exploring possibilities for starting the car in winter
conditions and ascertainment whether the oil produced in Latvia meets the standard requirements were
set as the subordinate objectives of this investigation.
Materials and methods
Dealing with the problem to rebuild the car, the proposed conversion components of companies
ATG [7], ELSBETT [8], GREENBULL [9], and RMG RAPSOL [10] were investigated. The choice
was made for the benefit of the firm ELSBETT that in the one-tank use area they have the longest
experience, and the fact that the company offers a specially developed nozzle design. The fuel using
the ELSBETT nozzles is injected locally and tangentially inside the central combustion area within the
chamber. This process prevents the fuel and its residue from making contact with the walls, thus
142
3. ENGINEERING FOR RURAL DEVELOPMENT Jelgava, 28.-29.05.2009.
minimizing the loss of heat. For this reason the injection nozzles have one aperture with a self-
cleaning needle, and are arranged in a specific position and at a specific angle.
The typical one-tank conversion kit would contain the following parts (Fig. 1):
• injector components;
• glow-plugs;
• additional fuel filter;
• sometimes additional fuel pump;
• coolant-water heat exchanger;
• electrical fuel heater/filter;
• temperature switch;
• cut-off valve;
• relays and sockets;
• fuel and water pipes;
• fuel hand pump;
• cabling.
Fig. 1. The typical 1-tank conversion kit components
The cars that can be modified to run on rapeseed oil using ELSBETT one-tank sets are
summarized in Table 2.
Table 2
The most popular cars, which can be modified using a one-tank system
Car Diesel engine volume Production years Fuel system
Land-rover cars
BMW X 5 3.0 2000 – 2003 BOSCH
CHRYSLER JEEP CHEROKEE 2.0 – 2.5 1984 – 2001 BOSCH
CHRYSLER JEEP GRAND 2.5 – 3.0 1997 – 2005 BOSCH
CHEROKEE
FORD MAVERICK 2.7 1993 – 1998 BOSCH
MITSUBISHI PAJERO 2.5 1991 – 2005 DIESEL KIKI
NISSAN PATROL 2.8 – 4.2 1987 – 2000 BOSCH KIKI
TOYOTA LANDCRUISER 2.4 – 4.2 1980 – 2002 DENSO
Passenger cars
AUDI 80 1.6 – 1.9 1982 – 1996 BOSCH
AUDI 100 2.4 – 2.5 1982 – 1997 BOSCH
BMW 1.8 – 2.5 1983 – 2000 BOSCH
CITROEN 1.9 1998 – 2002 BOSCH
FIAT 1.7 – 1.9 1987 – 1995 BOSCH
FORD 1.6 – 1.8 1993 – 1998 BOSCH
LADA NIVA 1.9 1994 – 2000 BOSCH
MERCEDES BENZ 1961 – 2001 BOSCH
MITSUBISHI 1.8 – 2.3 1988 – 2003 NIPPON DENSO
WOLKSWAGEN 1.9 1985 – 2006 BOSCH
VW Golf 1.9TD was chosen for reconstruction. As a basis for selecting this car served the fact
that it is, though not very new, but still quite widespread in Latvia (also called peoples’ car). Besides
that, the same engine is used in cars AUDI 80, SEAT CORDOBA, SEAT IBIZA, SEAT TOLEDO,
VW PASSAT and VW VENTO, that raises the representativeness of the selected engine.
The car adapting starts with the fuel hose test. The internal diameter has to be not less than 8 mm
for the unrestricted free flow of rapeseed oil. Other adaptation actions are carried out in the engine
compartment of the car, where the place of the heat exchanger and the heated fuel filter has to be
selected. It is preferable to designate these places so that the potential heat losses would be smaller. So
the heat exchanger should be closer to the cabin heater hoses. In turn, the heated fuel filter has to be as
near as possible to the heat exchanger, in order that the warmed rapeseed oil does not get cool when it
143
4. ENGINEERING FOR RURAL DEVELOPMENT Jelgava, 28.-29.05.2009.
reached the filter. Balanced and efficient operation of the heat exchanger and fuel filter allows faster
interrupting electrical heating of the fuel filter. The manual fuel pump is installed in the fuel line
before the heat exchanger. With this pump the fuel system is bleeded after the filter replacement. The
original fuel filter is included into the backup line and, using the valve, it can be engaged in the case,
when the first filter blocks, as well as for making easier the flow through the filters after the engine
warm-up (Fig. 2). Finally, the nozzles and glow plugs have to be replaced.
2 3 4 5
6
1
Fig. 2. Displacement of one-tank system components in engine compartment: 1 – valve;
2 – original fuel filter; 3 – fuel hand pump; 4 – heat exchanger; 5 – fuel heater/filter; 6 – relays
When the fuel system conversion was finished, the fuel tank of the car was filled by rapeseed oil
(Fig. 3). The first experiments were carried out in winter conditions (Fig. 4).
Fig. 3. Filling the car with pure rapeseed oil Fig. 4. Car before the first experiments
Starting the engine the smell of baked potato was felt, but the exhaust gases were colorless. The
surprise was also the fact, that changing the cold engine revolutions, the soot emissions on the snow
were not visible. The engine was started at different temperatures below zero, and using infrared
thermometer SMART SENSOR AR 300 temperature measurements of the various fuel system
components were performed during the engine warm-up. The results are summarized in Table 3.
The driving tests 3 to 8 minutes after the engine starts were also performed with increments of
1 minute. Significant differences in comparison to operation with fossil diesel fuel were not observed,
because the electric heater, new nozzles and glow plugs provided the oil heating and smooth operation
even when the engine was not yet warmed up.
144
5. ENGINEERING FOR RURAL DEVELOPMENT Jelgava, 28.-29.05.2009.
Table 3
Fuel system component temperature measurements after 25 minutes engine idling operation
Measured parameter Test No. 1 Test No. 2 Test No. 3
Air temperature, °C -1.4 -5.2 -7.1
Cold engine temperature, °C -1.6 -5.3 -7.0
Electric heater heating time up to 60 °C, min 1.5 1.7 1.7
Coolant temperature, when the electric heater turns off, °C 69.1 69.8 70.1
Fuel heat exchanger temperature, °C 59.0 57.2 56.2
Fuel filter temperature, °C 54.8 56.2 52.3
Temperature at the high pressure pump, °C 54.1 55.9 50.5
Driving the car in an urban area, as well as outside the city, the horsepower reduction was not
noticed, but further experiments require more precise measurements on the laboratory chassis
dynamometer. To obtain the first comparative results of the fuel consumption, the car was equipped
with a fuel consumption meter at the baggage compartment (Fig. 5).
Fig. 5. Fuel consumption meter AVL KMA Mobile
Results and discussion
Since this car before conversion was tested in
real road experiments using fossil diesel and
biodiesel, the same parameters were determined
also using rapeseed oil as a fuel.
The fuel consumption was estimated in two
different routes – in intensive traffic conditions in
Jelgava city and outside the urban area. In the first
selected route (Fig. 6) 15 drive repetitions using
each fuel were made. Three trips with the highest
speed curves correlations were selected for
comparison. Driving tests were only conducted
during normal working days’ peak hours (8:00 –
9:30 and 11:30 – 13:30), excluding the public
holidays. The second route (Jelgava – Tukums –
Engure – Rindzele – Engure – Tukums – Jelgava)
included driving in the cities (Jelgava and
Tukums), non-urban area, as well as driving
through small villages. As the total route distance
was large (approximately 176 km), then 3 drive
Fig. 6. Driving route in Jelgava
repetitions with each fuel type were conducted.
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6. ENGINEERING FOR RURAL DEVELOPMENT Jelgava, 28.-29.05.2009.
The results of the tests are given in Table 4.
Table 4
Fuel consumption test results
Parameters Fossil diesel Biodiesel Pure rapeseed oil
City driving route
Average distance, km 2.36 2.35 2.36
Average speed, km h-1 23.36 23.16 23.26
Average fuel consumption per 100 km, l 9.67 10.65 9.72
Combined driving route
Average distance, km 175.50 176.12 176.23
-1
Average speed, km h 72.04 72.26 72.19
Average fuel consumption per 100 km, l 6.55 6.76 6.57
The first results show that pure rapeseed oil fuel consumption is slightly behind fossil diesel, but
quite significantly overtakes biodiesel. However, objectively only the first two types of fuel could be
compared, because using rapeseed oil, the car was modified, i.e., different nozzles and glow plugs
were used. Therefore, a behavior of a modified engine with fossil diesel and biodiesel has to be
established in future experiments. Of course, performing real road tests, there is appreciable scattering
in the results between repetitions, that is why it is necessary to carry out experiments on the laboratory
chassis dynamometer, simulating real driving conditions in the different modes. It should be noted that
even after rebuilding the car could run without problems with fossil diesel and biodiesel, but then the
electric heating filter and the heat exchanger were switched off.
The home pages of the above mentioned conversion kit manufacturing companies contain
information on cars that are operated with pure rapeseed oil – the driven kilometers, the number of
refusals, their reasons, etc. The analyses of these refusals show that a great attention should be paid to
the used oil quality, which is highly dependent on the seed quality and the compliance of oil pressing
process regimes. Therefore, in cooperation with the limited company LOGINS & CO independent
analyses of oil samples were carried out in Latvia (Ventspils) and Germany. The tested oil was pressed
from the seeds, which were purchased in two different firms, which here are named as “Company X”
and “Company Y”. Oil extraction was done using the FARMET presses, but the same pressing process
regimes were provided using an automatic control system, which was managed from the computer.
The results of the received analyses are summarized in Table 5. For comparison, the standard limiting
values are also shown.
Table 5
Results of oil sample laboratory analyses
Testing results Limiting values
Oil pressed Oil pressed
Determined index from the seeds from the seeds
min max
purchased in purchased in
“Company X” “Company Y”
Water content, % m m-1 0.08 0.08 N/A 0.075
-1
Total contamination, mg kg 46 18 N/A 24
Phosphorus content, mg kg-1 11.7 42.6 N/A 12 (20*)
Sulphur content, mg kg-1 1.9 2.0 N/A 20
Iodine value, g J2 per 100 g 111 114 95 125
Kinematic viscosity, mm2 s-1 at 40 °C 33.63 36.57 N/A 36 (38*)
Density at 15 oC, g m-3 920.3 920.4 900 930
*
– Permitted in Latvia until January 2010
As it can be seen from the Table 5, in oil samples from the seeds purchased in “Company X”
nonconformity is observed in total contamination quantity, but from the seeds purchased in
“Company Y” the phosphorus content does not meet the requirements. This can cause blocking of the
fuel filter (swelling of phosphorus lipids), deposits on valves and pistons, contamination of catalysts,
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7. ENGINEERING FOR RURAL DEVELOPMENT Jelgava, 28.-29.05.2009.
and ash deposits in the particle filter. These analyses show that regardless that the oil by the law is
approved as a fuel in Latvia, its commercial realization in fuel filling stations can not be started until
all quality requirements are guaranteed. Similarly, the oil production companies and farmers that
already use oil as a fuel for their motor vehicles, have to be very careful, because the poor seed
quality, non-compliance of optimal harvesting, seed processing or pressing regimes can led to engine
damage, which require large expenditures. As the German experience shows, these problems can be
solved by after treatment of the extracted oil.
Conclusions
1. Performing the modifying of the car for running on rapeseed oil as a fuel, it was found that a user
with the engineering experience can easily obtain the necessary fuel system components and make
conversion under one’s own steam.
2. The first studies of the passenger car running on rapeseed oil as a fuel in winter conditions show
that exploitation even when the air temperature reached -7 °C did not cause any problems. If the
temperature becomes lower, it is advisable to add the winter biodiesel to the oil so much that
rapeseed oil has to free flow out from the fuel tank.
3. Modified diesel engines can be operated not only with rapeseed oil, but also with fossil diesel and
biodiesel, or with various mixtures of these fuels. So just which of these fuels can be cheaper to
buy, it can be used to run diesel engines.
4. First test results show that pure rapeseed oil fuel consumption is slightly behind fossil diesel, but
quite significantly overtakes biodiesel. However, objectively only the fossil diesel and biodiesel
fuel consumption results could be compared, because using rapeseed oil, the car was modified.
Therefore, the behavior of a modified engine with fossil diesel and biodiesel has to be established
in future experiments.
5. Analyses of rapeseed oil manufactured in Latvia showed that, in order to avoid the problems of
using this oil as a fuel from both a technical and legislative point of view, it is substantially to
control the quality of seeds and pressing process regimes.
References
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