A single droplet auto-ignition of surrogate fuels, lubricant oil and their mixtures at elevated temperature and pressure

Maharjan, Sumit

07 1900

Pre-ignition is a type of irregular combustion that occurs in boosted direct injection gasoline engines when one or more auto-ignition events occur before to spark ignition. Due to the direct injection of fuel into the cylinder, some liquid fuel may splash off the walls, dragging along lubricating oil. The self-ignition of liquid fuel/lubricant droplets is one of the pre-ignition sources studied. To test this stochastic behavior in a controlled manner, we examined the auto-ignition of a single droplet of a hexadecane-fuel mixture, with hexadecane serving as a surrogate for the lub oil. This experiment involved suspending a single hexadecane-fuel mixture droplet on a thermocouple bead in preheated air at temperatures ranging from 150 to 300 ° C over a wide range of pressures (4-30 bar). Various fuels with RON values ranging from 0 to 120 were blended with hexadecane at varying volume percentages of fuel in hexadecane from 0% to 100% to determine the droplet's time to ignition, denoted by TI. TI was determined by concurrently recording the history of the droplet temperature and imaging it at high speed. The ignition of the droplet is triggered by the self-ignition of the combustible mixture created by the vapor of the hexadecane-fuel mixture reacting with the heated ambient air surrounding the droplet. The increase in RON increased the TI as high RON fuels are difficult to ignite. However, the TI of the mixture depended on the fuel mixture properties even when the RON of the mixture was relatively high. Furthermore, the metal additives were added to the oil surrogate to investigate their effect on getting a pre-ignition event. The lubricant oil additives were phosphate, magnesium, and calcium. These additives were mixed with hexadecane at different concentrations. The experiments were conducted in a constant volume combustion chamber at 300 ⁰C temperature and the pressure was varied from 5 to 15 bar. The resulting TI were then compared with the TI of pure hexadecane. The results showed that addition of phosphate reduces the chances of getting a pre-ignition event, magnesium showed neutral effect while calcium enhanced the chances of getting a pre-ignition event.

Preignition

droplet

lubricant oil

surrogate fuels

Studies of Preignition in Homogeneous Environments

Figueroa Labastida, Miguel

06 1900

Preignition is an ignition event that happens before it is expected to happen and, many times, where it is not expected to happen. Understanding this phenomenon is of great importance as it influences the design and operation of modern downsized boosted internal combustion engines. To gain a fundamental understanding of preignition, homogeneous reactors like shock tubes and rapid compression machines may be used to decipher the influence of fuel chemical structure, temperature, pressure, equivalence ratio and bath gas on preignition. In this thesis, a comprehensive study of the preignition tendency of various chemical systems is presented. Firstly, renewable fuels like ethanol, methanol and a surrogate of conventional fuels, n-hexane, are characterized by traditional shock tube techniques, such as the measurements of ignition delay times and pressure-time histories, to identify thermodynamic conditions which promote non-ideal ignition behavior. Preignition pressure rise and the expedition of measured ignition delay times are identified as the indicators of non-homogeneous combustion. It is shown that preignition effects are more likely to be observed in mixtures containing higher fuel concentration and that preignition energy release is more pronounced at lower temperatures. High-speed imaging was implemented to visualize the combustion process taking place inside the shock tube. End-wall imaging showed that low-temperature ignition may be initiated from an individual hot spot that grows gradually, while high-temperatures ignition starts from many spots simultaneously which consume the reactive mixture almost homogeneously. Simultaneous lateral and endwall imaging was implemented in both low- and high-pressure shock tube facilities. All tested fuels exhibited localized ignition at low temperatures, and methanol showed a higher propensity than ethanol to ignite far from the endwall. Imaging experiments were also performed in a rapid compression machine to understand preignition at lower temperatures. Herein, ethanol showed non-homogeneous ignition while iso-octane and diethyl ether exhibited homogeneous ignition at the low-temperature conditions. Various criteria for the onset of preignition were tested against experimental observations to propose an adequate predictor of non-ideal ignition phenomena in practical applications. A non-dimensional number, relating the ignition delay sensitivity and laminar flame speed of the mixtures, was found to be the best criterion to elucidate ignition regimes.

Shock tube

imaging

ethanol

Preignition

Non-idealities

Rapid Compression Machine

Advancing the Limits of Dual Fuel Combustion

Königsson, Fredrik

January 2012

There is a growing interest in alternative transport fuels. There are two underlying reasons for this interest; the desire to decrease the environmental impact of transports and the need to compensate for the declining availability of petroleum. In the light of both these factors the Diesel Dual Fuel, DDF, engine is an attractive concept. The primary fuel of the DDF engine is methane, which can be derived both from renewables and from fossil sources. Methane from organic waste; commonly referred to as biomethane, can provide a reduction in greenhouse gases unmatched by any other fuel. The DDF engine is from a combustion point of view a hybrid between the diesel and the otto engine and it shares characteristics with both. This work identifies the main challenges of DDF operation and suggests methods to overcome them. Injector tip temperature and pre-ignitions have been found to limit performance in addition to the restrictions known from literature such as knock and emissions of NOx and HC. HC emissions are especially challenging at light load where throttling is required to promote flame propagation. For this reason it is desired to increase the lean limit in the light load range in order to reduce pumping losses and increase efficiency. It is shown that the best results in this area are achieved by using early diesel injection to achieve HCCI/RCCI combustion where combustion phasing is controlled by the ratio between diesel and methane. However, even without committing to HCCI/RCCI combustion and the difficult control issues associated with it, substantial gains are accomplished by splitting the diesel injection into two and allocating most of the diesel fuel to the early injection. HCCI/RCCI and PPCI combustion can be used with great effect to reduce the emissions of unburned hydrocarbons at light load. At high load, the challenges that need to be overcome are mostly related to heat. Injector tip temperatures need to be observed since the cooling effect of diesel flow through the nozzle is largely removed. Through investigation and modeling it is shown that the cooling effect of the diesel fuel occurs as the fuel resides injector between injections and not during the actual injection event. For this reason; fuel residing close to the tip absorbs more heat and as a result the dependence of tip temperature on diesel substitution rate is highly non-linear. The problem can be reduced greatly by improved cooling around the diesel injector. Knock and preignitions are limiting the performance of the engine and the behavior of each and how they are affected by gas quality needs to be determined. Based on experiences from this project where pure methane has been used as fuel; preignitions impose a stricter limit on engine operation than knock. / QC 20120626 / Diesel Dual Fuel

Diesel Dual Fuel

Methane

CNG

Biogas

Injector

Coking

Knock

Pre-ignition

Preignition

HCCI

PPCI

PPC

RCCI

Vehicle Engineering

Farkostteknik