Design and operating parameters of a fluidized bed for the combustion of municipal solid waste using standpipes air distributors
Hydrodynamic studies and combustion of simulated and actual municipal solid waste were carried out in a fluidized bed system. A wide range of parameters was investigated in hydrodynamic study after which the optimum parameters were implemented in the combustion studies. A newly fabricated standpi...
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| Format: | Thesis |
| Language: | English |
| Published: |
2009
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| Subjects: | |
| Online Access: | http://eprints.utm.my/id/eprint/48114/1/AnwarJohariPFKM2009.pdf http://eprints.utm.my/id/eprint/48114/ http://dms.library.utm.my:8080/vital/access/manager/Repository/vital:77639?queryType=vitalDismax&query=Design+and+operating+parameters+of+a+fluidized+bed+for+the+combustion+of+municipal+solid+waste+using+standpipes+air+distributors&public=true |
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| Institution: | Universiti Teknologi Malaysia |
| Language: | English |
| Summary: | Hydrodynamic studies and combustion of simulated and actual municipal
solid waste were carried out in a fluidized bed system. A wide range of parameters
was investigated in hydrodynamic study after which the optimum parameters were
implemented in the combustion studies. A newly fabricated standpipes air distributor
(primary air inlet) was designed based on findings of the optimum orifice diameter,
orifice distance and distance between pipes. Orifice diameter, orifice distance and
distance between pipes of 3 mm, 10 mm and 70 mm were used in the hydrodynamic
studies of circular and rectangular columns (CHS and RHS). The operating
parameters investigated in the CHS and RHS included the effect of sand sizes and
aspect ratios on the fluidization profile. Standpipes air distributors having the same
orifice diameter and distance but with a wider pipe distance of 200 mm were used in
the hydrodynamic studies of a bigger rectangular (big scale) column. Different air
flow strategies were implemented to ensure good mixing between sand and samples
and to investigate the penetration of the incombustibles into the sand bed. Parameters
studied in the combustion of municipal solid waste included the effect of fluidizing
velocity and air factor on the combustion profile in the bed as well as the freeboard
region with standpipe air distributor design and dimension established from the
hydrodynamic studies of a bigger scale rectangular column. Findings from the CHS
and RHS showed that sand particles with mean size of 0.34 mm performed good
fluidization profile compared to other coarser sand sizes. The ratio of the bed height
over diameter of column (Dc) for good fluidization was determined at H = Dc for the
circular column whereas the ratio of the bed height (H) over the length (L) of column
was observed at H<L for the rectangular columns. A two side air flow was seen as
the best air flow strategy for good mixing in a bigger rectangular column. The range
of fluidization number and air factor for the combustion of simulated municipal solid
waste in a rectangular fluidized bed combustor was 5 - 7 Umf in which 5 Umf was
found to be the optimum with air factor of 0.8 (primary air). Air factor of 0.4
(secondary air) was observed to show good temperature profile in the freeboard
region for the combustion of municipal solid waste. The optimum total combined air
factor for the combustion of municipal solid waste was 1.2 in which inlet primary air
factor and inlet secondary air factor were 0.8 and 0.4, respectively. |
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