Feedstock-Dependent Phosphate Recovery in a Pilot-Scale Hydrothermal Liquefaction Bio-Crude Production

Microalgae ( Spirulina ) and primary sewage sludge are considerable feedstocks for future fuel-producing biorefinery. These feedstocks have either a high fuel production potential (algae) or a particularly high appearance as waste (sludge). Both feedstocks bring high loads of nutrients (P, N) that must be addressed in sound biorefinery concepts that primarily target specific hydrocarbons, such as liquid fuels. Hydrothermal liquefaction (HTL), which produces bio-crude oil that is ready for catalytic upgrading (e.g., for jet fuel), is a useful starting point for such an approach. As technology advances from small-scale batches to pilot-scale continuous operations, the aspect of nutrient recovery must be reconsidered. This research presents a full analysis of relevant nutrient flows between the product phases of HTL for the two aforementioned feedstocks on the basis of pilot-scale data. From a partial experimentally derived mass balance, initial strategies for recovering the most relevant nutrients (P, N) were developed and proofed in laboratory-scale. The experimental and theoretical data from the pilot and laboratory scales are combined to present the proof of concept and provide the first mass balances of an HTL-based biorefinery modular operation for producing fertilizer (struvite) as a value-added product.

[1]  S. Fairweather-Tait,et al.  Iron , 2020, Reactions Weekly.

[2]  A. Kruse,et al.  Experimental and thermodynamic studies of phosphate behavior during the hydrothermal carbonization of sewage sludge. , 2019, The Science of the total environment.

[3]  B. Young,et al.  Phosphorus recovery through struvite crystallisation: Recent developments in the understanding of operational factors. , 2019, Journal of environmental management.

[4]  P. Savage,et al.  Using Solvents To Reduce the Metal Content in Crude Bio-oil from Hydrothermal Liquefaction of Microalgae , 2019, Industrial & Engineering Chemistry Research.

[5]  M. Glasius,et al.  How Do Hydrothermal Liquefaction Conditions and Feedstock Type Influence Product Distribution and Elemental Composition? , 2019, Industrial & Engineering Chemistry Research.

[6]  S. Stagg-Williams,et al.  Simultaneous solid and biocrude product transformations from the hydrothermal treatment of high pH-induced flocculated algae at varying Ca concentrations , 2019, Algal Research.

[7]  A. Kruse,et al.  Hydrothermal carbonization of Spirulina platensis and Chlorella vulgaris combined with protein isolation and struvite production , 2019, Bioresource Technology Reports.

[8]  A. Kruse,et al.  Novel approach of phosphate-reclamation as struvite from sewage sludge by utilising hydrothermal carbonization. , 2019, Journal of environmental management.

[9]  L. Rosendahl,et al.  Catalytic upgrading of hydrothermal liquefaction biocrudes: Different challenges for different feedstocks , 2019, Renewable Energy.

[10]  B. Deal,et al.  Biological systems for treatment and valorization of wastewater generated from hydrothermal liquefaction of biomass and systems thinking: A review. , 2019, Bioresource technology.

[11]  G. Robertson,et al.  Strategies for recovery and recycling of nutrients from municipal sewage treatment effluent and hydrothermal liquefaction wastewaters for the growth of the microalga Scenedesmus sp. AMDD , 2019, Algal Research.

[12]  Lisa M. Colosi,et al.  Evaluating the Impacts of ACP Management on the Energy Performance of Hydrothermal Liquefaction via Nutrient Recovery , 2019, Energies.

[13]  B. Young,et al.  Phosphorous recovery through struvite crystallization: Challenges for future design. , 2019, The Science of the total environment.

[14]  Daniel C W Tsang,et al.  Phosphorus recovered from digestate by hydrothermal processes with struvite crystallization and its potential as a fertilizer. , 2019, The Science of the total environment.

[15]  Lasse Rosendahl,et al.  Continuous Hydrothermal Liquefaction of Biomass: A Critical Review , 2018, Energies.

[16]  Fei Yang,et al.  Migration and transformation of phosphorus in municipal sludge by the hydrothermal treatment and its directional adjustment. , 2018, Waste management.

[17]  Lasse Rosendahl,et al.  Catalytic Hydrotreatment of Microalgae Biocrude from Continuous Hydrothermal Liquefaction: Heteroatom Removal and Their Distribution in Distillation Cuts , 2018, Energies.

[18]  Patrick Biller,et al.  Continuous Hydrothermal Liquefaction of Biomass in a Novel Pilot Plant with Heat Recovery and Hydraulic Oscillation , 2018, Energies.

[19]  E. Meers,et al.  Stripping and scrubbing of ammonium using common fractionating columns to prove ammonium inhibition during anaerobic digestion , 2018, International Journal of Energy and Environmental Engineering.

[20]  Sandeep Kumar,et al.  Nutrients recovery and recycling in algae processing for biofuels production , 2018, Renewable and Sustainable Energy Reviews.

[21]  Dezhen Chen,et al.  Phosphorus Transformation in Hydrothermal Pretreatment and Steam Gasification of Sewage Sludge , 2018, Energy & Fuels.

[22]  A. Kruse,et al.  Fertilizer and activated carbon production by hydrothermal carbonization of digestate , 2018 .

[23]  Z. Wen,et al.  Use of microalgae to recycle nutrients in aqueous phase derived from hydrothermal liquefaction process. , 2018, Bioresource technology.

[24]  P. Savage,et al.  Metals and Other Elements in Biocrude from Fast and Isothermal Hydrothermal Liquefaction of Microalgae , 2018 .

[25]  P. A. Marrone,et al.  Bench‐Scale Evaluation of Hydrothermal Processing Technology for Conversion of Wastewater Solids to Fuels , 2018, Water environment research : a research publication of the Water Environment Federation.

[26]  Lihong Peng,et al.  A comprehensive review of phosphorus recovery from wastewater by crystallization processes. , 2018, Chemosphere.

[27]  P. Biller,et al.  Primary sewage sludge filtration using biomass filter aids and subsequent hydrothermal co-liquefaction. , 2018, Water research.

[28]  Yuanzhi Tang,et al.  Transformations of Phosphorus Speciation during (Hydro)thermal Treatments of Animal Manures. , 2018, Environmental science & technology.

[29]  P. Biller,et al.  Hydrothermal liquefaction: A promising pathway towards renewable jet fuel , 2018 .

[30]  Claus Uhrenholt Jensen,et al.  PIUS - Hydrofaction(TM) Platform with Integrated Upgrading Step , 2018 .

[31]  Chuanping Feng,et al.  Simultaneous phosphorus and nitrogen recovery from anaerobically digested sludge using a hybrid system coupling hydrothermal pretreatment with MAP precipitation. , 2017, Bioresource technology.

[32]  R. Jiang,et al.  Transformation of Phosphorus during (Hydro)thermal Treatments of Solid Biowastes: Reaction Mechanisms and Implications for P Reclamation and Recycling. , 2017, Environmental science & technology.

[33]  Daniel B. Anderson,et al.  Phosphorus and nitrogen recycle following algal bio-crude production via continuous hydrothermal liquefaction , 2017 .

[34]  P. Savage,et al.  Influence of process conditions and interventions on metals content in biocrude from hydrothermal liquefaction of microalgae , 2017 .

[35]  G. Olofsson,et al.  Impact of nitrogenous alkaline agent on continuous HTL of lignocellulosic biomass and biocrude upgrading , 2017 .

[36]  S. Adhikari,et al.  Nutrient removal and energy production from aqueous phase of bio-oil generated via hydrothermal liquefaction of algae. , 2017, Bioresource technology.

[37]  Daniel B. Anderson,et al.  Impact of iron porphyrin complexes when hydroprocessing algal HTL biocrude , 2016 .

[38]  A. Kruse,et al.  Fate of Nitrogen during Hydrothermal Carbonization , 2016 .

[39]  X. Ye,et al.  Effects of organic substances on struvite crystallization and recovery , 2016 .

[40]  S. Dyhrman Nutrients and Their Acquisition: Phosphorus Physiology in Microalgae , 2016 .

[41]  Douglas C. Elliott,et al.  Review of recent reports on process technology for thermochemical conversion of whole algae to liquid fuels , 2016 .

[42]  M. A. Camargo-Valero,et al.  A comparison of product yields and inorganic content in process streams following thermal hydrolysis and hydrothermal processing of microalgae, manure and digestate. , 2016, Bioresource technology.

[43]  Xingzhong Yuan,et al.  The migration and transformation behaviors of heavy metals during the hydrothermal treatment of sewage sludge. , 2016, Bioresource technology.

[44]  Yuanzhi Tang,et al.  Speciation Dynamics of Phosphorus during (Hydro)Thermal Treatments of Sewage Sludge. , 2015, Environmental science & technology.

[45]  G. Zeng,et al.  The comparison of the migration and transformation behavior of heavy metals during pyrolysis and liquefaction of municipal sewage sludge, paper mill sludge, and slaughterhouse sludge. , 2015, Bioresource technology.

[46]  A. Faaij,et al.  The feasibility of short‐term production strategies for renewable jet fuels – a comprehensive techno‐economic comparison , 2015 .

[47]  Paul Westerhoff,et al.  We Should Expect More out of Our Sewage Sludge. , 2015, Environmental science & technology.

[48]  Clemens Posten,et al.  Cultivation of microalgae with recovered nutrients after hydrothermal liquefaction , 2015 .

[49]  M. Detamore,et al.  Promoting catalysis and high-value product streams by in situ hydroxyapatite crystallization during hydrothermal liquefaction of microalgae cultivated with reclaimed nutrients , 2015 .

[50]  C. Ludwig,et al.  First developments towards closing the nutrient cycle in a biofuel production process , 2015 .

[51]  Susanne B. Jones,et al.  Hydrothermal liquefaction of biomass: developments from batch to continuous process. , 2015, Bioresource technology.

[52]  Vladimir Strezov,et al.  Hydrothermal processing of biomass , 2015 .

[53]  B. Iversen,et al.  Hydrothermal Liquefaction of the Microalgae Phaeodactylum tricornutum: Impact of Reaction Conditions on Product and Elemental Distribution , 2014 .

[54]  Kurt A Spokas,et al.  Phosphorus reclamation through hydrothermal carbonization of animal manures. , 2014, Environmental science & technology.

[55]  Onursal Yakaboylu,et al.  Supercritical water gasification of manure: A thermodynamic equilibrium modeling approach , 2013 .

[56]  Andrew J. Schmidt,et al.  Process development for hydrothermal liquefaction of algae feedstocks in a continuous-flow reactor , 2013 .

[57]  Ganti S. Murthy,et al.  Effects of Environmental Factors and Nutrient Availability on the Biochemical Composition of Algae for Biofuels Production: A Review , 2013 .

[58]  J. Lavoie,et al.  Alternative fuel production by catalytic hydroliquefaction of solid municipal wastes, primary sludges and microalgae. , 2013, Bioresource technology.

[59]  Sascha R.A. Kersten,et al.  Microalgae growth on the aqueous phase from Hydrothermal Liquefaction of the same microalgae , 2013 .

[60]  Frederik Ronsse,et al.  Hydrothermal liquefaction (HTL) of microalgae for biofuel production: State of the art review and future prospects , 2013 .

[61]  YingHao Liu,et al.  Magnesium ammonium phosphate formation, recovery and its application as valuable resources: a review , 2013 .

[62]  Phillip E. Savage,et al.  Hydrothermal liquefaction of Nannochloropsis sp.: Systematic study of process variables and analysis of the product fractions , 2012 .

[63]  Peter Cornel,et al.  On wet chemical phosphorus recovery from sewage sludge ash by acidic or alkaline leaching and an optimized combination of both. , 2012, Water research.

[64]  Amanda Lea-Langton,et al.  Nutrient recycling of aqueous phase for microalgae cultivation from the hydrothermal liquefaction process , 2012 .

[65]  John W. Scott,et al.  Chemical properties of biocrude oil from the hydrothermal liquefaction of Spirulina algae, swine manure, and digested anaerobic sludge. , 2011, Bioresource technology.

[66]  K. Das,et al.  Effect of operating conditions of thermochemical liquefaction on biocrude production from Spirulina platensis. , 2011, Bioresource technology.

[67]  A. Ross,et al.  Hydrothermal liquefaction of the brown macro-alga Laminaria saccharina: effect of reaction conditions on product distribution and composition. , 2011, Bioresource technology.

[68]  David Kubička,et al.  Deactivation of HDS catalysts in deoxygenation of vegetable oils , 2011 .

[69]  Senthil Chinnasamy,et al.  Evaluation of microalgae cultivation using recovered aqueous co-product from thermochemical liquefaction of algal biomass. , 2011, Bioresource technology.

[70]  P. Biller,et al.  Potential yields and properties of oil from the hydrothermal liquefaction of microalgae with different biochemical content. , 2011, Bioresource technology.

[71]  C. Cheeseman,et al.  Production of technical grade phosphoric acid from incinerator sewage sludge ash (ISSA). , 2010, Waste management.

[72]  G. Versteeg,et al.  The solubilities of phosphate and sulfate salts in supercritical water , 2010 .

[73]  S. A. Parsons,et al.  Phosphorus Recovery from Wastewater by Struvite Crystallization: A Review , 2009 .

[74]  A Seco,et al.  A pilot-scale study of struvite precipitation in a stirred tank reactor: conditions influencing the process. , 2008, Bioresource technology.

[75]  Morgan Fröling,et al.  Thermochemical biofuel production in hydrothermal media: A review of sub- and supercritical water technologies , 2008 .

[76]  M Franz,et al.  Phosphate fertilizer from sewage sludge ash (SSA). , 2008, Waste management.

[77]  J. Medeiros,et al.  Analytical phosphorus fractionation in sewage sludge and sediment samples , 2005 .

[78]  B. Pérez Cid,et al.  Analytical phosphorus fractionation in sewage sludge and sediment samples , 2005, Analytical and bioanalytical chemistry.

[79]  K. Byrappa,et al.  Solution synthesis of hydroxyapatite designer particulates , 2002 .

[80]  P Pearce,et al.  Potential phosphorus recovery by struvite formation. , 2002, Water research.

[81]  J. Lester,et al.  Conditions influencing the precipitation of magnesium ammonium phosphate. , 2001, Water research.

[82]  V. Ruban,et al.  Harmonized protocol and certified reference material for the determination of extractable contents of phosphorus in freshwater sediments – A synthesis of recent works , 2001, Fresenius' journal of analytical chemistry.

[83]  S. Besler,et al.  Inorganic Compounds in Biomass Feedstocks. 1. Effect on the Quality of Fast Pyrolysis Oils , 1996 .

[84]  Shin-ya Yokoyama,et al.  Conversion of sewage sludge to heavy oil by direct thermochemical liquefaction , 1988 .

[85]  W. Frankenberger,et al.  Chemical composition of sewage sludges in Iowa , 1979 .

[86]  J. J. Morgan,et al.  Aquatic Chemistry: Chemical Equilibria and Rates in Natural Waters , 1970 .

[87]  H. Schüller Die CAL-Methode, eine neue Methode zur Bestimmung des pflanzenverfügbaren Phosphates in Böden , 1969 .