转鼓真空过滤机英文文献和中文翻译(6)

items detailed in Eqs。 (32), (38) and (39)

Cdewatering ¼ Cenergy þ Cdepreciation þ Clabor ð40Þ

It is anticipated that this overall cost as deﬁned in Eq。 (36)can be minimized by identifying the optimal operating conditions

including the ﬁltration vacuum pressure, p, and the ﬁlter rotation

where k is the ratio of heat capacities of air at constant pressure and constant volume。 The energy required to maintain the rotation of the ﬁlter drum is assessed by Eq。 (30) [28],

5。 Results and discussion

5。1。 Algal cake-layer thickness

The sized ﬁlter has a drum diameter of 0。9 m and a drum length

of 0。6 m, and it provides a working area of 1。69 m2。 The thickness

where x is the angular velocity of the rotating drum ﬁlter, k is the ratio of radius of the drum ﬁlter to that of the feed tank, the ﬁrst term is the drag force experienced by the rotating ﬁlter in the feed tank, and the second term is the torque resistance。

Therefore, the total energy of the RDVF dewatering system is

Wtotal ¼ Wwater pump þ Wvacuum þ Wrotation ð31Þ

Assuming the price of industrial electricity is 0。05 US$/kWh, the energy cost is thus

Cenergy ¼ 0:05 · Wtotal ð32Þ

Supposing the unit price of the rotary ﬁlter is Pc, the capital cost for purchase of the ﬁlters is

C1 ¼ n · Pc ð33Þ

As a rule of thumb, the installation of the dewatering system can be considered to be 60% of the major capital cost [35,36] of the process。

C2 ¼ 0:6 · n · Pc ð34Þ

The room temperature operation of the process also requires the dewatering facility and the accompanying system to be installed indoors。 Infrastructure cost is assessed by assuming the space required by the whole system and the open space needed for process maintenance and operation, which is estimated at 50% of the capital cost。

C3 ¼ 0:5 · n · Pc ð35Þ

Empirically, it has been shown that the maintenance cost is usually 10% [35,36] of the sum of the above three items,

C4 ¼ 0:21 · n · Pc ð36Þ

Therefore, the total capital investment is

Ccapital ¼ 2:31 · n · Pc ð37Þ

Assuming the life span of the ﬁlter with maintenance is 20 years [35], the hourly depreciation of the investment is estimated as

Cdepreciation ¼ 2:31 · n · Pc=20=365=24 ð38Þ

of algal cake-layer as shown in Fig。 3 was investigated over a wide range of operating conditions: vacuum pressure ranging from 5 to 60 kPa, and ﬁlter rotation cycle time varying from 10 to 120 s。 Nat- urally, for a speciﬁc operating pressure, a thicker algal cake-layer corresponds to a longer cycle time。 As shown in Fig。 3, the impact of the working pressure on the cake-layer thickness is more com- plicated。 Roughly speaking, algae-dewatering beneﬁted from using a higher ﬁltration pressure under 10 kPa, as indicated by the increased algal cake-layer thickness。 Negative impact was observed instead when the ﬁltration pressure was higher than 20 kPa。 It was seen that the buildup rate of algal cake-layer was remarkably slowed by the increased working pressure。 This resulted from the compressibility of algae。 For a compressible algal cake-layer, the ﬁltration pressure plays two roles, one is the driving force for the ﬁltration, and the other is the driver for cake-layer compression, and the other occurs when the working pressure is raised higher than the critical pressure (17 kPa) of algae compres- sion。 Any pressure surpassing this critical pressure densiﬁes the algal cake-layer, and causes a higher transport resistance for ﬁl- trate water, resulting in a reduced throughput for water and a cor- responding lesser algal cake-layer thickness。 It is shown in Table 1 that the porosity of the algal cake-layer is strongly dependent upon the working pressure。 There is almost 45% cake-layer porosity loss 转鼓真空过滤机英文文献和中文翻译(6):http://www.youerw.com/fanyi/lunwen_83220.html