Abstract:
Rice hulls, the largest milling byproduct of
rice, constitute one fifth of the paddy by weight. The hulls
which can be obtained at relatively low cost, are in abundant
supply in most developing countries, particularly in the
Asian region. Hull contains approximately 20% silica by
weight and, on combustion, yields a porous ash having a
silica content of approximately 90 percent. This thesis
investigates the following two possible applications of rice
hull ash in water treatment processes:
(i) the use of rice hull ash as a filter medium;
(ii) the use of rice hull ash as a coagulant aid.
Rice hull ash comprising amorphous silica was
produced from locally available rice hulls, using a specially
constructed incinerator. Scanning electron microscopic
studies were conducted to evaluate the microstructure of
this ash as well as diatomaceous earth and filter sand. The
laboratory filtration experiments were conducted at slow to
semi-rapid filtration rates in order to investigate the
effectiveness of rice hull ash medium in removing turbidity,
bacteria and colour from water, and to compare its performance
with a conventional sand filter. Synthetic water was made by
adding suitable amounts of kaolin clay, Escherichia coli
suspension, coffee/leaf extract, to laboratory tap water.
Filtrate quality and head loss were considered as the major
parameters in assessing the performance of these filters. A
number of thin layer filter experiments were conducted to
obtain the variation of turbidity with depth in rice hull
ash filters, under selected operating conditions. Solubility
studies of rice hull ash at various strengths of sodium
hydroxide and for various steeping periods were made to
evaluate the optimum conditions for silica solubilisation.
A dilution procedure including partial neutralization and
Subsequent aging prior to further dilution was adopted to
convert alkali soluble rice hull ash into activated silica.
Coagulation of dilute clay suspensions (£ 40 m g / L ) , using
alum, activated silica and selected polyelectrolytes were
conducted with the aid of a jar test apparatus.
The filtrate turbidity for approximately 750 mm
depth of rice hull ash medium was equal to or less than that
of a sand medium, at rates of filtration 0.25 to 2.0 m 3 / m 2h
and a turbidity range of 20 to 60 FTU. The rate of head
loss in the sand medium was 1.5 to 5 times more than in an
ash filter. The optimum rate of filtration for the ash filter
occurred at 1.0 m 3 / m 2 h , with a rate of head loss of 52 mm/d.
At filtration rates of 0.5 and 1.0 m 3 / m 2 h , for an influent
Escherichia coli concentration of 100 - 2000 no/mL, approximately
70% to 90% reductions in bacterial numbers were
achieved by 750 mm depths of rice hull ash media. Colour
removal of at least 30% was achieved by shallow depths
(< 320 mm) of ash media, at slow rates of filtration
(< 0.25 m 3 / m 2 h ).
The results obtained from thin layer filtration
experiments were analysed using a statistical filtration
model known as the chi-square distribution analogy. This
technique was successful in predicting the performance of
rice hull ash filters at specific operating conditions.
The optimum removal of silica from rice hull ash
occurred when ash was steeped in 5% NaOH solution for a
period of 24 h. A procedure for the preparation of
activated silica from rice hull ash was developed. The
addition of 5 mg/L of activated silica as a coagulant aid
during the coagulation of turbid water (4 0 mg/L of kaolin
clay) with 50 mg/L of alum at pH value of 6, was sufficient
to achieve a residual turbidity of 1.2 FTU. The coagulation
of the same water with alum or alum-polyelectrolyte at
similar conditions led to higher residual turbidity.
Citation:
Mampitiyaarachchi, T.R. (1980). Use of rice hull ash in water treatment [Doctoral dissertation, University of Moratuwa]. Institutional Repository University of Moratuwa. http://dl.lib.mrt.ac.lk/handle/123/9865