转鼓真空过滤机英文文献和中文翻译

a b s t r a c t Clean and energy-efﬁcient rotary drum vacuum ﬁltration was selected to conduct algae-dewatering。 The dynamic formation of an algal cake-layer on the ﬁlter surface was modeled by correlating the cake-layer permeability to the physical parameters of algae and cake-layer。 The compressibility of algal cake-layer was taken into consideration in the modeling, and its effect on the algae-dewatering is discussed。73071

The dewatering process was simulated to determine the process energy demand。 Process economics were assessed considering the dewatering cost, which includes capital investment and energy cost and also labor, installation, maintenance and infrastructure。 Optimal operating conditions and minimum dewatering cost were achieved by process optimization, and two cost-sensitive zones in operating the ﬁltration were identiﬁed。 The techno-economics showed that the dewatering cost can be further reduced by scaling up the process。

1。 Introduction Filtration is a mature technology for the removal of particulate matters from ﬂuids。 It has found wide industrial applications in water treatment (e。g。 turbidity removal) [1–3], food processing (e。g。 clariﬁcation of beer and liquors) [4–6], air cleaning (e。g。 dust and bacteria removal), etc。 [7]。 At present, various ﬁlter media

are available for the removal of these small particulates ranging from submicron to 100 lm [8–11]。 Filtration is based on size- exclusion, so it does not require large energy input。 A low pressure (e。g。 20–30 kPa) can generate a high ﬂux through these well-tuned and highly porous ﬁlter media [12]。

Microalgae, mostly in the range of 5–20 lm, are now playing a

key role in the ongoing endeavors to sustain energy and

environment [13]。 Cultivation of algae consumes large amounts of CO2, as a carbon source for algal biomass synthesis。 Because algae grow fast and possess high lipid contents, algae have been mass cultivated to provide renewable energy and at the same time mitigate CO2 emissions [14–16]。 The concentration of algae in a culture medium is usually 0。1 w/w%, and this concentration can be enhanced up to 20 w/w% through centrifugal harvesting。 The traditional method to dewater this 20 w/w% harvested algae is with thermal energy to evaporate most of the remaining 80% water content [17]。 Given the extremely high latent heat of water, algae- dewatering by evaporation requires a very large energy input。 Alternative approaches have good potential to improve the energy efﬁciency of algae-dewatering。

One major objective of our algal biofuel project is to maximize the energy return to help better address energy sustainability。 Each operating unit of this process can beneﬁt from use of energy-efﬁ- cient technology。 Energy-efﬁcient ﬁltration with the rotary drum

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

vacuum ﬁlter (RDVF) was selected to conduct algae-dewatering。 Continuous operation of ﬁltration is favored by industry for its ﬂex- ibility in process scale-up and for not needing extra storage space for intermediate product。 In addition, by using the vacuum opera- tion, the amount of ﬁltrate water contained in the porous algal cake-layer can be minimized。 Consequently, much of the heating burden can be removed from the subsequent process for algae-dry- ing, which has been identiﬁed as one of the bottlenecks limiting the overall energy efﬁciency of algal biofuel technology [18,19]。转鼓真空过滤机英文文献和中文翻译:http://www.youerw.com/fanyi/lunwen_83220.html