Experimental analysis of fouling rates in two small-scale domestic boilers

• Published in: Applied thermal engineering Vol. 100; pp. 849 - 860
• Main Authors: Patiño, David, Crespo, Bárbara, Porteiro, Jacobo, Míguez, Jose L.
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 05.05.2016
• Subjects: Biomass deposition; Boiler; Boilers; Combustion; Domestic; Experimental; Fouling; Fouling rate; Particulate emissions; Particulate matter; Pellets; Thermal engineering; Wood; CFD; Boiler; Biomass deposition; Experimental; Particulate matter; PM; SP; Fouling rate
• ISSN: 1359-4311
• DOI: 10.1016/j.applthermaleng.2016.02.112

•The fouling rates of 24 kW water-tube and 60 kW fire-tube boilers were experimentally obtained.•Sampling probes were placed at different locations of the heat exchangers during the tests.•Commercial wood pellets were used as fuel.•The particulate matter (PM) and flue gas composition were studied. [Display omitted] Fouling is a topic of interest in almost all heat production systems. A noticeable fall in thermal efficiency can be caused by accumulated fouled matter, especially in those surfaces where heat exchange takes place. In this research, two domestic-scale commercial pellet boilers were studied (a 24 kW water-tube boiler-stove and a 60 kW fire-tube boiler). Sampling probes were placed in both heat exchangers to measure the deposition rate. Commercial wood pellets were used as fuel. A series of tests were carried out under the same operating conditions. Average fouling rates (FR) of 7–12 g/m2h in the water-tube boiler-stove and 3–5 g/m2h in the fire-tube boiler were measured. The variation of these fouling rates with the position in the boiler side was also analyzed. In addition, measurements of the particulate matter (PM) concentration and flue gas composition were made during the tests. A correlation between the CO emissions and the collected solid particulate (SP) matter was obtained for each case of study. PM values of 110–280 mg/Nm3 were measured for the water-tube boiler and 13–135 mg/Nm3 for the fire-tube boiler. An SP size distribution study provided evidence for the large amount of ultrafine particles in domestic biomass combustion systems.