Search Results

This work compares the accuracy of in-cylinder pressure and apparent heat release rate (AHRR) diagrams to the experimental data and the use of different chemical kinetics models applied to the GT-Power® software. The engine computational model is based on a naturally aspirated diesel engine with three cylinders, one of them modified to operate with hydrous ethanol with port fuel injection and HCCI combustion achieved with hot exhaust gas recirculation (EGR) of the Diesel cylinders. Operating points chosen to perform the comparison to experimental tests were 1800 rpm, 300 kPa of indicated mean effective pressure and fuels with 10% and 20% of water-in-ethanol by volume. The kinetic mechanisms for ethanol oxidation evaluated were the detailed NUI Galway and a Skeletal model based on it. With either model, cylinder pressure diagrams were not very different from the experimental values. The detailed mechanism was, on average, 9 times slower to process each case than the Skeletal mechanism.

Concerns about global warming, pollutant emissions and energy security have driven research towards cleaner and more environmentally friendly fuels. In the same way as ethanol, butanol is a promising biofuel but with different characteristics such as higher calorific value and lower latent heat of vaporization. It has similar properties to those of gasoline, which makes it a potential surrogate for this fossil fuel. Therefore, the present study proposes a comparison among four different fuels i.e. n-butanol, n-butanol and ethanol blend (B73E27), gasoline and ethanol blend (G73E27), and hydrous ethanol. A single cylinder naturally aspirated research engine with port fuel injection was employed. Engine performance was experimentally evaluated and combustion parameters were determined through reverse calculation based on acquired intake, exhaust and in-cylinder pressure on GT-Power.

The forecast scenarios regarding the environmental pollution raises a question whether the current vehicle emission certification is reliable enough to assure fleet agreement with the legal limits. Type approval tests have been performed on chassis dynamometer in order to evaluate the emission factors and fuel consumption for passenger cars. Standardized procedures such as the FTP-75 proposed in the United States (currently incorporated in the Brazilian legislation) and the Worldwide harmonized Light vehicles Test Cycle (WLTC), a transient driving cycle model designed by the European Union to overcome the shortcomings of the New European Driving Cycle (NEDC), are discussed in this paper. Both cycles were performed in a chassis dynamometer with a flex-fuel passenger car running on ethanol blend (E92W08). The driver, vehicle and fuel were kept constant so the comparison between the cycles would not be compromised.

Among the gases usually emitted by internal combustion engines, NOx chemical species appear as some of the causes of great environmental impact and damage to human health, which shows the relevance of its study and quantification, as well as the constant search for the reduction of these emissions. The use of biofuels such as hydrous ethanol and n-butanol has the goal of reducing CO2 emissions in comparison to fossil fuels. However, it has to be accomplished without increasing NOx emissions. Analyzing combustion of these two fuels through a two-zone model for an Otto cycle engine, this work compared quantitatively the NOx emissions with the Zeldovich reaction mechanism, which can predict the formation and consumption of these chemical species during the engine's combustion cycle, being thus known as thermal NO.

The ethanol fuel sold in Brazil, which is seen as an option that represents less polluting gases emitted into the atmosphere, goes through a period where its economic viability does not compensate its use against the alternative coming from nonrenewable sources. It is known that part of the cost associated with commercial ethanol is due to its purification through distillation, which decreases the water percentage in the final composition. Aiming to evaluate alternatives to reduce the final cost of the fuel, a comparison was made between the burning results of hydrous ethanol, with up to 5% of water by volume, and the wet ethanol, with 30% water by volume, in an Otto cycle engine, operating with a fixed speed of 1800 RPM and seeking the maximum brake torque in each test.

Hydrous ethanol is pointed out as one of the major alternative fuel for internal combustion engines, because it is environmental friendly (almost zero CO2 emission) and has excellent combustion properties. Recent studies have shown that ethanol-water fuel blends with higher water content (so-called wet ethanol) can reduce the overall costs of ethanol production. The use of wet ethanol results in lower nitrogen oxides emissions at the cost of reduced lower heating value per mass of fuel blend, which may result in less thermal efficiency. On the other hand, the increase in water content improves knock resistance. Thus, this study aims to investigate the effects of mechanical compression ratio variation on a spark ignition engine using ethanol-water fuel blends containing 4, 10, 20 and 30% v/v of water in ethanol. The research was carried out in a SI single cylinder engine, port fuel injected, 0.668 dm3 with the compression ratio modified by spacer rings.

The current quest for clean and renewable fuels has prompted the appearance of several bio-mass fuel alternatives. Ethanol is a renewable biofuel obtained from different agricultural crops. The main production process to obtain anhydrous ethanol consists of crop production, mashing and cooking, fermentation, distillation and chemical dehydration. Some attractive characteristics of ethanol as a clean energy source is the CO2 absorption through photosynthesis during the crop plantation phase and positive ethanol life cycle energy balance. Even though, ethanol production cost is still relatively high when compared to fossil fuels. Knowing that a large energy amount is spent in the distillation phase, the use of hydrous ethanol as fuel, with high water content, can be economically attractive. This paper compares the use of high water-in-ethanol volumetric content fuel, varying from 5% to 40%, in a naturally aspirated 0.668-L single-cylinder port-fuel injected spark-ignited engine.

Vegetable oils have been seen as promising surrogates to petroleum diesel in compression ignition internal combustion engines, showing similar performance and combustion characteristics of the fossil fuel. Nevertheless, the use of straight (crude) vegetable oil (SVO) is unfavorable due to its high viscosity, which affects the Sauter Mean Diameter of fuel spray and, consequently, fuel-air mixing process, resulting in incomplete combustion. The SVO heating, as well as transesterification and blending with diesel or additives, are some of the techniques to reduce its viscosity and enable its use. Of these the most simple and direct is the heating and was used in this paper to evaluate the performance and emissions of a diesel engine fueled with preheated soybean oil (PSO) by electrical resistances. The experiments were carried out in a single cylinder four-stroke compression ignition engine with mechanical fuel injection.

Global warming and pollutant emission concerns have been driving research towards cleaner and environmentally friendly fuels. Like ethanol, butanol is a promising biofuel with characteristics such as higher calorific value and lower latent heat of vaporization. Due to its similar properties to those of gasoline, butanol stands as a potential gasoline surrogate. Butanol can be produced from through the ABE (acetone–butanol–ethanol) fermentation process, which uses bacterial fermentation to produce acetone, n-Butanol, and ethanol from carbohydrates such as starch and glucose. This work presents the experimental results of a single-cylinder spark ignition research engine equipped with port fuel injection. Several compression ratios were compared via spacer rings. Fuels as n-butanol, hydrous ethanol (E95W05) and their blends were evaluated in comparison to primary reverence fuel (isooctane).