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This paper describes and analyzes the results of investigations of application of heavy alcohols as an ingredient of diesel fuel. Three different mi xtures of butanol (as heavy alcohol), rape oil (as vegetable oil) and conventional diesel fuel (this mixture was called the biomixdiesel-BMD) were tested using a Perkins engine on a test bed. Contrary to existing experiences both the maximum power output and the maximum torque of the engine were higher in the whole range of the speed of the engine crankshaft when the engine biomixdiesel (BMD) was reinforced. The addition of the component biomix to fuel influenced the specific fuel consumption. Generally, with the larger part of the biomix components the specific fuel consumption were higher. Also the engine power was higher and one should expect that in exploitation the specific fuel consumption should not increase. It is very important that this fuel could be used to reinforce old, already existing and the future diesel engines.

The influence of the ignition timing on the exhaust emissions of an old technology vehicle fuelled by various ethanol/petrol mixtures was investigated. All tests were carried out on a 1300cc Ford Escort equipped with a carburettor and without a catalytic converter. The reference petrol fuel E0 and the blends E10, E20 and E50 were used, at three different constant speeds of 30, 50 and 90 km/h, under full load with wide open throttle while the vehicle was on a chassis dynamometer. All measurements were taken at three different settings of the advance angle, at 0°, 4° and 12° BTDC. With the use of an exhaust gas analyser, the concentrations of CO, CO2, HC, O2 and NOX in the exhaust gases at the tailpipe were recorded. For the evaluation of the results the lambda value was calculated from the available recorded data. Changing the ignition timing, while using the blends E10, E20 and E50, had the same effects on the emissions as the reference fuel E0.

The scope of this work was to study the impact of the ignition timing on the engine’s performance on an old technology vehicle fuelled by ethanol/petrol blends. Many previous studies have been published on the subject, but most of them were carried on SI engines using bench dynamometers. In this work, a 1.3 L Ford Escort equipped with a carburettor and without a catalytic converter was tested on a chassis dynamometer. Blends with ethanol concentrations of 10%, 20% and 50% per volume were used and the results were compared with the reference LRP fuel. All tests were performed at three different constant speeds of 30, 50 and 90 km/h, under full load with wide open throttle. Torque and rpm of the engine were recorded by the chassis dynamometer’s software. The fuel consumption was measured by means of the gravimetric method. All measurements were taken at three different settings of the advance angle, at 0°, 4° and 12° BTDC.

Green fuels or alternative fuels are growing fast now days and can be used in every passenger car but also in many commercial vehicles. In various countries all around Europe such as Italy, Netherlands and Belgium LPG is a reasonable alternative fuel for small and medium cars. This study evaluated the performance of a Suzuki Liane fitted with a multipoint in-line gas fuel injection system. During the tests various exhaust gasses (CO, CO2, NOx, O2 and HC) and temperatures were measured in different load condition on a chassis dynamometer. All tests were conducted in the engines laboratory at Karel de Grode Hogeschool (KDG) in Antwerp, Belgium. The car was tested on a chassis dynamometer similar to the one described in [1], [2], [3] and various loads were applied at different gear settings. All measurements were taken under full load and four different gears (2nd gear, 3rd gear, 4th gear and 5th gear) were selected in the gear box.

In this study the influence of various blends biodiesel on steady state exhaust emissions was determined using, in terms of technology, two different cars. A first series of tests were conducted in Greece and a second series of tests were conducted in Belgium. An old technology Ford Escort 86 model, 1.6L, 4 cylinders with indirect injection system engine was used on a chassis dynamometer in Greece and a Volvo V70 2.5L was tested in Belgium. The Ford Escort test car was not equipped with an engine Electronic Control Unit (ECU) and run on the dynamometer with full load on three different gear settings (second gear, third gear and fourth gear). The Belgian car was a modern Volvo V70 2.5 L Turbo diesel. Seven fuels were used in both cases, a high sulfur diesel in Greece, and blends of 10%, 20%, 30%, 40% and 50% by weight biodiesel in neat diesel or (B10), (B20), (B30), (B40), (B50) and (B100) respectively.

The purpose of this study is to investigate the effects on the engine's efficiency and exhaust gas emissions by the use of ethanol/gasoline blends in conventional technology vehicles. The fuels E0, E10, E20 and E50 were tested in a 1300cc old technology vehicle without a catalytic converter. The measurements of the engine's brake torque, revolutions and fuel consumption were accomplished on a chassis dynamometer for different engine loads and with different gear ratios. Regarding the exhaust gas emissions, the concentrations of CO2 , CO, HC and NOx were recorded. The results have shown that increasing the ethanol percentage in the blend has decreased the CO and HC emissions but increased the NOx emissions. For fuels E10 and E20 an increase on the engine's brake torque and power along with a decrease in fuel consumption were observed. For E50, both brake torque and power were reduced. The CO2 emissions were increased as the ethanol concentration increased.

Regulated and non-regulated tailpipe exhaust emissions were measured under real world urban driving conditions using a set of in-vehicle FTIR emission measurement system, which is able to measure 65 emission components simultaneously at a rate of 0.5 Hz. A EURO3 emission compliant SI car was used as a probe vehicle. An urban driving cycle was used for the test and four repeated journeys were conducted. The results were compared to EU emissions legislation. The results show that the TWC needed approximately 200 seconds to reach full conversion efficiency. THC and NOx emissions exceeded the EURO 3 exhaust emission legislation. CO2 emissions were well above the type approval value of this type of the vehicle. Greenhouse gases (methane and nitrous oxide) and toxic hydrocarbons such as benzene were predominantly emitted during cold start period from 0 to 200 seconds of the engine start. The results had a reasonable repeatability for most of the emissions.

In this study the influence of various blends biodiesel on steady state exhaust emissions was determined using, in terms of technology, two different cars. A first series of tests were conducted in Greece and a second series of tests were conducted in Belgium. An old technology Ford Escort 1986 model, 1.6L, 4 cylinders with indirect injection system engine was used on a chassis dynamometer in Greece [1] and a Volvo V70 2.5L, 2003 model with a modern engine fitted on was tested in Belgium [2]. The Greek test car was not equipped with an engine Electronic Control Unit (ECU) and run on the dynamometer with full load on three different gear settings (second gear, third gear and fourth gear). The Belgian car was a modern Volvo V70 2.5L Turbo Diesel. Seven fuels were used in both cases, a high sulfur diesel, more than 300 ppm, in Greece, and blends of 10%, 20%, 30%, 40% and 50% by weight biodiesel in neat diesel or (B10), (B20), (B30), (B40), (B50) and (B100) respectively.

In this study the influence of various blends biodiesel on steady state exhaust emissions was determined. A series tests were conducted over a period of six months, including the summer when the ambient temperature is quite high in Greece. An old technology Ford Escort 1.6L, 4 cylinders with indirect injection system was used on a chassis dynamometer. The test car was not equipped with an engine Electronic Control Unit (ECU) and run on the dynamometer with full load on three different gear settings (second gear, third gear and fourth gear). Seven fuels were used, a high sulfur diesel, and blends of 10%, 20%, 30%, 40% and 50% by weight biodiesel in neat diesel (B10), (B20), (B30), (B40), (B50) and (B100) respectively. Fuel injection timings were held the same for the biodiesel blends and the baseline diesel fuel to eliminate the potential injection timing differences due to the different fuel heating values.

Two biofuels were converted chemically to biodiesels: cottonseed oil, which was produced in Macedonia, Greece, and used frying oil which was collected in the city of Antwerp, Belgium. The conversion to biodiesels was accomplished in the Department of Industrial Sciences and Technology of the Karel de Grote-Hogeschool, Hoboken, Belgium. Mixtures of the two biodiesels with diesel were prepared as B10, B20, B30, B40, B50 and B100 (B10 means a 10 % by weight of biodiesel). These mixtures were used as fuel on two cars in the Combustion Laboratory in the Department of Industrial Sciences and Technology of the Karel de Grote-Hogeschool, Hoboken, Belgium. The two cars were a VOLVO V70 2.5 L turbo diesel and a FORD TRANSIT 2.5 L diesel. The cars were run under full load at 30, 50, 90 and 120 km/h speeds on a chassis dynamometer.