Energy and phosphorus recovery from black water

Graaff, M.S. de; Temmink, Hardy; Zeeman, G.; Buisman, Cees J.N.

doi:10.2166/wst.2011.558

Cited by 47 publications

(60 citation statements)

References 21 publications

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“…By replacing the urine transport with a microbial fuel cell, the total primary energy consumption can be decreased by 19% in Concept 2 and 17%-23% in Concept 4, indicating a promising new direction for urine treatment. According to the current Dutch guidelines for sewage sludge reuse in agriculture (BOOM), reuse of black water sludge is prohibited, due to elevated concentrations of copper and zinc [41]. However, as black water is predominantly human originated (urine, feces and tap water), the applicability of sewage sludge reuse guidelines on the reuse of black water sludge can be argued.…”

Section: Nutrient Recoverymentioning

confidence: 99%

“…where m N aOH is the mass of NaOH (g/L), M is the molecular mass (g/mol), pH a is the influent pH of 7.7 [33] and pH b is the operational pH of 9 [35]. Consumption of 33% NaOH was further determined from the mass of NaOH.…”

Section: A2 Calculations For Chemical Usementioning

confidence: 99%

“…The storage time was 1 d for the UASB buffer tank (assumed), 0.3 d for the SBR, A-trap and MBR buffer tanks (assumed) and six months for the urine collection tank [7]. The HRT was 15 d for the digester [22], 0.08 d for the struvite reactor [35], 1.9 h for the MBR [12], 4 min and 54 min for the aerated grit chamber and settling tank, respectively [57], and 1.9 h for the A-trap reactor [34]. The HRT of the UASB reactor was calculated according to Zeeman and Lettinga [56] [Equation (A8)]:…”

Section: A3 Calculations For Reactor Dimensions and Land Area Requimentioning

confidence: 99%

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Prospects of Source-Separation-Based Sanitation Concepts: A Model-Based Study

Tervahauta

Hoang

Hernández³

et al. 2013

Water

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Separation of different domestic wastewater streams and targeted on-site treatment for resource recovery has been recognized as one of the most promising sanitation concepts to re-establish the balance in carbon, nutrient and water cycles. In this study a model was developed based on literature data to compare energy and water balance, nutrient recovery, chemical use, effluent quality and land area requirement in four different sanitation concepts: (1) centralized; (2) centralized with source-separation of urine; (3) source-separation of black water, kitchen refuse and grey water; and (4) source-separation of urine, feces, kitchen refuse and grey water.The highest primary energy consumption of 914 MJ/capita(cap)/year was attained within the centralized sanitation concept, and the lowest primary energy consumption of 437 MJ/cap/year was attained within source-separation of urine, feces, kitchen refuse and grey water. Grey water bio-flocculation and subsequent grey water sludge co-digestion decreased the primary energy consumption, but was not energetically favorable to couple with grey water effluent reuse. Source-separation of urine improved the energy balance, nutrient recovery and effluent quality, but required larger land area and higher chemical use in the centralized concept.

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Section: Nutrient Recoverymentioning

confidence: 99%

Section: A2 Calculations For Chemical Usementioning

confidence: 99%

Section: A3 Calculations For Reactor Dimensions and Land Area Requimentioning

confidence: 99%

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Prospects of Source-Separation-Based Sanitation Concepts: A Model-Based Study

Tervahauta

Hoang

Hernández³

et al. 2013

Water

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“…In this pH range struvite (MgNH4PO4.6H2O) precipitation may also be responsible for ammonium removal (De Graaff et al, 2011). However no further measurements were conducted to explain which mechanism was dominant for ammonium removal.…”

Section: Ammonium Removalmentioning

confidence: 98%

“…The very different removal from synthetic solution and the liquid fraction of digestate for the H2SO4 treatment may be attributed to the difference in pH between the two solutions. All liquid digestates had a final pH (at the end of the sorption experiment) of between 7.42 and 8.87 (Table 3.3), which would be within a suitable pH range for hydroxyapatite and struvite precipitation (De Graaff et al, 2011). Moreover, cation bridging of divalent and trivalent cations (which were not likely to be present in acid-treated biochar, but would be present in the digestate) with orthophosphate may explain the differences in orthophosphate removal between the synthetic solution and the liquid fraction of digestate (Lin et al, 2012;Qian et al, 2013).…”

Section: Orthophosphate Removalmentioning

confidence: 99%

Recovery of nutrients from biogas digestate with biochar and clinoptilolite

Kocaturk

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Taking the water out of “wastewater”: An ineluctable oxymoron for urban water cycle sustainability

Capodaglio

2020

Water Environment Research

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Water, energy, and food are key resources that could easily limit sustainability of human society development. Water supply requires considerable amounts of energy, and "usedwater" carries considerable amounts of embedded energy and recoverable materials within. Usedwater is increasingly considered as a potential resource, rather than as a waste. Among process technology options that may allow efficient recovery of that energy, anaerobic digestion could be considered the most mature, already sporting countless applications worldwide. However, the present inefficient dilutionbase collection systems paradigm produces rather dilute sewage, preventing to a large degree a more efficient application of this technology. A new collection system paradigm, based on liquid sources segregation and minimal organics dilution, could result in significant energy savings for conveyance and treatment. This could also enhance recovery of nutrients and reclamation of potentially reusable water, with the associated benefit of reduced production of process residuals requiring further disposal. Implications of this model are discussed. © 2020 Water Environment Federation • Practitioner points • The nexus between water, energy, and food is an impending challenge on water cycle sustainability • Current paradigms of urban water management are based on disadvantageous paradigms: high dilution and gravity flow • Taking the water out of wastewater may improve energy and recovery efficiency of urban water systems and water reuse options • Technologies exist (high-rate anaerobic, vacuum sewers) and are mature for more widespread application of new urban sanitation paradigms

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Energy and phosphorus recovery from black water

Cited by 47 publications

References 21 publications

Prospects of Source-Separation-Based Sanitation Concepts: A Model-Based Study

Prospects of Source-Separation-Based Sanitation Concepts: A Model-Based Study

Recovery of nutrients from biogas digestate with biochar and clinoptilolite

Taking the water out of “wastewater”: An ineluctable oxymoron for urban water cycle sustainability

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