Browsing by Author "Kamranvand, Farhad"
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Item Open Access Impact of fouling, cleaning and faecal contamination on the separation of water from urine using thermally driven membrane separation(Taylor & Francis, 2018-02-12) Kamranvand, Farhad; Davey, Christopher; Sakah, H.; Autin, Olivier; Mercer, E.; Collins, Matt; Williams, Leon; Kolios, Athanasios; Parker, Alison; Tyrrel, Sean; Cartmell, Elise; McAdam, EwanIn this study, membrane distillation is evaluated as a technology for non-sewered sanitation, using waste heat to enable separation of clean water from urine. Whilst membrane fouling was observed for urine, wetting was not evident and product water quality met the proposed discharge standard, despite concentration of the feed. Fouling was reversible using physical cleaning, which is similar to previous membrane studies operating without pressure as the driving force. High chemical oxygen demand reduction was achieved following faecal contamination, but mass transfer was impeded and wetting occurred which compromised permeate quality, suggesting upstream intervention is demanded to limit the extent of faecal contamination.Item Open Access Membrane distillation for concentrated blackwater: Influence of configuration (air gap, direct contact, vacuum) on selectivity and water productivity(Elsevier, 2021-01-30) Davey, Christopher J.; Kamranvand, Farhad; Williams, Leon; Jiang, Ying; Parker, Alison; Tyrrel, Sean; McAdam, Ewan J.Water recovery from concentrated blackwater has been studied using air gap (AGMD), direct contact (DCMD) and vacuum membrane distillation (VMD) to deliver decentralised sanitation. Whilst good water quality was achieved with each configuration, differences in the rejection of volatile compounds was observed. VMD exhibited the highest rejection of volatiles, specifically ammoniacal nitrogen, of all the configurations but fouling inhibited total flux. DCMD exhibited a temperature dependent volatile rejection which resulted in poor rejection at lower feed temperatures (≤40 °C). AGMD was identified as the most promising configuration for application within decentralised sanitation, since the rejection of volatiles was consistent over a range of operating temperatures with ammonia rejection directly related to solution pH. An increase in organic colloids and particles due to faecal contamination reduced COD removal due to the induction of wetting, but was shown to be offset by adoption of a smaller pore size (0.1 μm), and when complemented with upstream solid-liquid separation within a fully integrated system, will provide a robust sanitation solution. Importantly, this work has shown that AGMD can recover water from concentrated blackwater close to international discharge and reuse regulations in a single stage process; this is significant as blackwater consists of only urine and faeces, and is thus 40 times more concentrated than municipal sewage. It is proposed that the water quality produced reflects a step change to delivering safe sanitation, and is complemented by a simple method for heat recovery integration this is similarly advantageous for resource constrained environments common to decentralised sanitation solutions.Item Open Access Membrane distillation of concentrated blackwater: effect of temperature, solids concentration and membrane pore size(Wiley, 2020-11-06) Kamranvand, Farhad; Davey, Chris J.; Williams, Leon; Parker, Alison; Jiang, Ying; Tyrrel, Sean; McAdam, Ewan J.This study has elucidated the mechanisms governing water recovery from blackwater using membrane distillation, and has clarified the role of the organic particle fraction on membrane performance. Whilst fecal pathogen growth was initially observed at lower temperatures, pathogen inactivation was demonstrated over time, due to urea hydrolysis which liberated ammonia in excess of its toxic threshold. During the growth phase, membrane pore size <0.45 µm was sufficient to achieve high log reduction values for Escherichia coli, due to size exclusion complimented by the liquid–vapor interface which enhances selective transport for water. Higher feed temperatures benefitted rejection by promoting thermal inactivation and suppressing urea hydrolysis. Whilst the mechanism is not yet clear, suppression of hydrolysis reduced bicarbonate formation kinetics stabilizing the ammonia‐ammonium equilibrium which improved ammonium rejection. Blackwater particle concentration was studied by increasing fecal content. Particle fouling improved selectivity for coarse pore membranes but increased mass transfer resistance which reduced flux. Particle fouling induced wetting as noted by an eventual breakthrough of feed into the permeate. We propose that by incorporating upstream solid–liquid separation for particle separation to limit wetting and mass transfer resistance, membrane distillation can be a reliable solution for the recovery of high‐quality permeate from blackwater.Item Open Access The Nanomembrane Toilet: Membranes for water recovery in decentralised sanitation systems(Cranfield University, 2018-10-22 10:34) Kamranvand, FarhadPoster presented at the Cranfield Doctoral Network Annual Event 2018.In this research, the Nanomembrane Toilet is introduced as a single household sanitation system independent of grid produced power. To address paucity of information on super-concentrated wastewater characterisation, chemical oxygen demand (COD), ammoniacal nitrogen, and E.Coli bacteria are analysed in the wastewater storage tank. A small-scale combustor is developed (Onabanjo et al., 2016) to operate on the faecal sludge phase, producing low-grade heat that is used to provide the vapour pressure gradient for thermally-driven membrane separation of water from faecally contaminated urine (FCU). Subsequently, a membrane technology is developed that can provide a single-stage treatment process, separating clean water from FCU. In this study, the impact of temperature on water recovery from FCU (urine:faece 56:1) by membranes (PTFE, nominal pore size 0.1 µm) is investigated. Out of 40, 50, and 60 ⁰C operational temperature values, operation at 60 c is shown to enable the process for the removal of organics, inorganics, and pathogens, sufficient to meet the ISO/PC 305 standard for sustainable non-sewered sanitation systems (American National Standards Institute, 2016). Furthermore, influence of faecal concentration in the FCU (at optimised temperature of 60 ⁰C) on the produced water quality is studied. The results show that high faecal concentration leads to high ammonium formation in the feed, hence faster ammonia breakthrough is observed. Lastly, the membrane pore size was optimised for the treatment of FCU at constant faecal concentration and temperature. It is concluded that only 0.1 µm membrane pore size is capable of removing ammonia, COD, and E.Coli to the proposed ISO standard at both 40 and 60 ⁰C. Importantly, this study has demonstrated that through integration of this modularised componentry into the Nanomembrane Toilet, single household sanitation can be delivered, independent of external power sources and infrastructure.Item Open Access Tube-side mass transfer for hollow fibre membrane contactors operated in the low Graetz range(Elsevier, 2016-09-28) Wang, C. Y.; Mercer, E.; Kamranvand, Farhad; Williams, Leon; Kolios, Athanasios; Parker, Alison; Tyrrel, Sean; Cartmell, Elise; McAdam, Ewan J.Transformation of the tube-side mass transfer coefficient derived in hollow fibre membrane contactors (HFMC) of different characteristic length scales (equivalent diameter and fibre length) has been studied when operated in the low Graetz range (Gz < 10). Within the low Gz range, mass transfer is generally described by the Graetz problem (Sh=3.67) which assumes that the concentration profile comprises a constant shape over the fibre radius. In this study, it is experimentally evidenced that this assumption over predicts mass transfer within the low Graetz range. Furthermore, within the low Gz range (below 2), a proportional relationship between the experimentally determined mass transfer coefficient (Kov) and the Graetz number has been identified. For Gz numbers below 2, the experimental Sh number approached unity, which suggests that mass transfer is strongly dependent upon diffusion. However, within this diffusion controlled region of mass transfer, tube-side fluid velocity remained important. For Gz numbers above 2, Sh could be satisfactorily described by extension to the Lévêque solution, which can be ascribed to the constrained growth of the concentration boundary layer adjacent to the fibre wall. Importantly this study demonstrates that whilst mass transfer in the low Graetz range does not explicitly conform to either the Graetz problem or classical Lévêque solution, it is possible to transform the experimentally derived overall mass transfer coefficient (Kov) between characteristic length scales (dh and L). This was corroborated by comparison of the empirical relationship determined in this study (Sh=0.36Gz) with previously published studies operated in the low Gz range. This analysis provides important insight for process design when slow tube-side flows, or low Schmidt numbers (coincident with gases) constrain operation of hollow fibre membrane contactors to the low Gz range.Item Open Access Ultrafiltration pretreatment enhances membrane distillation flux, resilience and permeate quality during water recovery from concentrated blackwater (urine/faeces)(Elsevier, 2020-08-08) Kamranvand, Farhad; Davey, Christopher John; Williams, Leon; Parker, Alison; Jiang, Y.; Tyrrel, Sean; McAdam, Ewan J.In this study, the pretreatment of concentrated blackwater using ultrafiltration (UF) was shown to improve the permeability, selectivity and robustness of membrane distillation (MD) for application to wastewater treatment. Concentrated blackwater comprises urine and faeces, with minimal flushwater added. The faecal contribution increased the soluble organic fraction and introduced coarse and colloidal particles into the urine, which increased resistance to filtration during dead-end UF. Ultrafiltration removed the particulate and colloidal fractions (MW > 500 kDa) from the blackwater, which permitted similar permeability and robustness for MD to that observed with urine (29.9 vs 25.9 kg m−2 h−1), which comprises a lower colloidal organic concentration. Without UF pretreatment, a higher density organic layer formed on the MD surface (197 vs 70 gCOD m−2) which reduced mass transfer, and transformed the contact angle from hydrophobic to hydrophilic (144.9° to 49.8°), leading to pore wetting and a dissipation in product water quality due to breakthrough. In comparison, with UF pretreatment, MD delivered permeate water quality to standards satisfactory for discharge or reuse. This is particularly timely as the ISO standard for non-sewered sanitation has been adopted by several countries at a national level, and to date there are relatively few technologies to achieve the treatment standard. Membrane distillation provides a robust means for concentrated blackwater treatment, and since the energy required for separation is primarily heat, this advanced treatment can be delivered into areas with more fragile power networks.