On the Distribution of Residual Carbon Particles by Heavy Fuel Oil Spray Combustion, in a Pilot Furnace

Two older boilers were burning low grade heavy fuel oil (number 6) and emitting large amounts of unburned carbon particles. Owing to the short life remaining of the units and economic constrains, it was not possible to change to a better fuel or install new burners. To contribute to the solution of this problem, an experimental program was carried out by emulsifying water in the fuel oil. Tests were performed in a scale furnace (0.35MWth) and the emulsions that produced the best results were assessed in the two boilers, 28 and 34 MWe capacity with Y-jet atomizer type. The system to prepare the emulsion was very simple: water was added into the oil before the fuel oil pump, no chemical products were added and a static mixed was used to improve the water size distribution, which 90% ranged from 1 to 9 micron. In the pilot furnace the emulsions were prepared with 5 and 10% water and atomized with compressed air. Particle reductions of 43 and 67% were obtained compared with the net heavy fuel oil. In the boilers, the emulsions were prepared with the same amount of water, and were atomized with saturated steam. In the 28 MWe boiler, a similar particle reduction was obtained to that of the scale furnace. However, in the 34 MWe boiler there was no particle abatement. By using a commercial fluid dynamic computer code, it was found that the combustion air transferred heat to the steam raising its temperature. Thus, in the mixing chamber of the Y-jet atomizers, the steam was superheated and destroyed the water droplets of the emulsion. Compressed air and saturated steam as atomizing medium of the emulsions had similar effect on the unburned particle reduction. However, the effectiveness of the emulsions may be affected by the steam. Care should be taken to avoid the use of steam with a temperature higher than the saturated water temperature.

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Experimental Study in a 350 MWe Utility Boiler of Oil Droplet and Coke Size Analysis

ASME 2007 Power Conference ◽

10.1115/power2007-22105 ◽

2007 ◽

Author(s):

Antonio Diego-Marin ◽

Carlos Melendez-Cervantes ◽

Armando Giles-Alarcon

Keyword(s):

Size Distribution ◽

Droplet Size Distribution ◽

High Viscosity ◽

Fuel Oil ◽

Unburned Carbon ◽

Size Analysis ◽

Heavy Fuel Oil ◽

Oil Droplet ◽

Carbon Particles ◽

Micron Size

A study was carried out to find out the cause of premature plugging of air heaters of a 350 MWe oil fired boiler. The unit burnt a heavy fuel oil number 6, with both high levels of sulfur (3.75%) and asphaltenes (16.2%), as well as high viscosity (555 SSF at 50°C) and API gravity of 11.2. Particle concentration at the furnace exit and at the stack were measured, also flue gas analyses were performed at the same sites. In the furnace were employed water cooled probes of six meters in length which allowed traversing 70% of its width. In addition, the oil droplet size distribution from an atomizer was measured with a Malver Particle Sizer. Cold condition using simulating fluids were taken in this analysis. Also, the unburned carbon particles size distribution, both from the furnace exit and from the stack, was performed with a particle Malver Sizer. The atomizer produced large oil drops, 5.7% by volume larger than 300 micron size, which were considered as promoters of unburned carbon. The concentration of carbon particles in the stack was 60% of that of the furnace exit. Furthermore, the particles from the stack were of smaller size (95% <150 μm) than those of the furnace (89% <150 μm). Deposition of carbon particles in the internal component of the boiler, mainly in the air heaters, was the cause of this finding. To solve the premature plugging of the air heaters of this oil fired boiler, the atomizers should be modified to reduce at a minimum level the oil drops larger than 200 micron size.

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The Esso Energy Award Lecture, 1988 - Improvements in the combustion of heavy fuel oils

Proceedings of the Royal Society of London Series A - Mathematical and Physical Sciences ◽

10.1098/rspa.1989.0053 ◽

1989 ◽

Vol 423 (1865) ◽

pp. 233-265 ◽

Cited By ~ 6

Keyword(s):

Coke Formation ◽

Fuel Oil ◽

Particulate Emissions ◽

Heavy Fuel Oil ◽

Carbon Particles ◽

Burn Out ◽

Heavy Fuel Oils ◽

Droplet Sizes ◽

Oil Emulsions ◽

The Individual

The changing pattern of demand for oil products has required that refining practices be adjusted to maximize yields of premium products from crudes. There has been a concomitant deterioration in the quality of the ‘residual’ or ‘heavy’ fuel oil used in power generation. A major constraint on the burning of such heavy fuel is a restriction on particulate emissions. These emissions largely comprise carbon particles (coke), which form from the individual oil spray droplets and remain unburnt. Poorer quality oils have an increased propensity to form coke, and can give rise to unacceptable emissions. One way of countering these increases is to make the fuel spray finer and hence improve burn-out. Research has been aimed firstly at quantifying the effects of those oil properties that directly influence coke formation and combustion and then at developing improved atomizers and water-in-oil emulsions to reduce droplet sizes.

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3D-CFD Lagrangian Spray Simulations for Large Two Stroke Marine Diesel Engines Compared With Experimental Data of a Spray Combustion Chamber

ASME 2012 Internal Combustion Engine Division Spring Technical Conference ◽

10.1115/ices2012-81016 ◽

2012 ◽

Cited By ~ 4

Author(s):

M. Bolla ◽

M. A. Cattin ◽

Y. M. Wright ◽

K. Boulouchos ◽

R. Schulz

Keyword(s):

Experimental Data ◽

Combustion Chamber ◽

Numerical Data ◽

Swirl Flow ◽

Fuel Oil ◽

Spray Combustion ◽

Fuel Quality ◽

Heavy Fuel Oil ◽

Marine Engines ◽

Simulation Results

The behavior of lagrangian spray models for the application in large two stroke marine engines is investigated. 3D-CFD simulations of a Spray Combustion Chamber (SCC) with a single hole (0.875 mm diameter) injector are presented and compared with experimental results. Shadow images of the spray under evaporating and non-evaporating conditions, with and without swirl flow and for different chamber pressures are available by means of which the simulation results are validated. A novel post processing methodology for 3D CFD spray simulations is introduced, which converts the numerical data into images which allows for a more rigorous quantitative comparison with the experimental data. Good agreement of the simulation results with the experiment is reported both in terms of spray penetration as well as concerning the evaporation of the fuel. Since the appropriate discretization of the large volumes typical of 2-stroke marine engines presents a substantial challenge, the influence of the grid resolution is investigated. In addition, the influence of fuel quality on the evolution of the spray morphology is assessed. For this purpose, simulations with heavy fuel oil (HFO) are compared with experiment.

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