转鼓真空过滤机英文文献和中文翻译(4)

where S is the intersectional area of the non-cylindrical pore, and L

is the circumference of the pore。 The ﬂow-rate of water through the ﬁlter medium can thus be governed by the Hagen–Poiseuille Equa-

The volumes of algae and water ﬁltrate are linked to the volume

fraction by Eq。 (10)

For better ﬁltration efﬁciency, a thin layer of pre-coat of ﬁne

particulates (e。g。 diatomaceous earth) may need to be deposited on the surface of the ﬁlter medium。 In such cases, an additional

resistance is included in Eq。 (15) by using a correction factor, a。

70 P。 Shao et al。 / Chemical Engineering Journal 268 (2015) 67–75

3。3。 Transport of ﬁltrate water through the algal cake-layer and the ﬁlter medium

The resistances of the algal cake-layer and the ﬁlter medium are in-series, therefore these two resistances are additive and the ﬂow- rate of the ﬁltrate water can ﬁnally be formulated as,

dV Dp

through direct image analysis of the algal cake-layer, the effect of clogging, if any, on pore size can thus be assessed by a simpliﬁed model as developed in this work。 Thus-achieved pore size is an equivalent pore size。

This equivalent pore size of the cake-layer is evaluated by assuming that the porous algal cake-layer is comprised of an ensemble of cylindrical pores (2r) that pose a same hydraulic resis-

tance for water transport as the network pathway does。 Therefore,

In practice, the driving force Dp is generally kept as a constant

during ﬁltration。 Integrating of Eq。 (16) under a constant pressure difference gives

where a in this case stands for the tortuosity of the network path- way。 Inserting Eq。 (7)into Eq。 (21)yields the equivalent pore radius, r

Based on Eq。 (17), for a given ﬁltration time, t, the volume of the ﬁltrate water can be evaluated。 The capacity of a ﬁlter for process- ing the algae feed is thus determined by Eq。 (18),

A requirement for algae-dewatering using vacuum pressure is that the applied pressure difference must be large enough to over- come resistance arising from the surface tension of water。 There- fore, the minimum pressure required for displacing the water out

ð23Þ

where T is the ﬁlter rotation cycle time, which is three times as long

as the ﬁltration time (i。e。 t = T/3) since only one-third of the ﬁlter as shown in Fig。 1 is working for the ﬁltration, while the rest of the time is for cake-layer-dewatering and cake-layer-discharging。

3。4。 Compressibility of the algal cake-layer and equivalent pore size of the cake-layer

Algae deform under the applied pressure in ﬁltration, giving rise to compression of the algal cake-layer。 Compression of the cake-

where r is the surface tension of water, and h is the contact angle of water on the surface of algae。

4。 Energy and capital costs, and process economics

Assuming the ﬂow-rate of the harvested algae to be dewatered is Ffeed, the number of ﬁlters required for processing the algae is thus

layer reduces the porosity, which can be expressed as,

where k is the compression index, B is a constant, and p is the com- pressive pressure。 An extensive literature survey showed that there had been no reported data on the compressibility of algal cake- layer。 Therefore, the compression properties of a bio-cake [30,31], consisting mostly of yeast cells, and expected to have similar com- pression properties to that of algae, were adopted to investigate the impacts of compression on water transport through an algal cake-layer。 The obtained pressure-dependent mean porosity of the bio-cake is shown in Eq。 (20), 转鼓真空过滤机英文文献和中文翻译(4):http://www.youerw.com/fanyi/lunwen_83220.html