CRANFIELD UNIVERSITY Rachel Louise Whitton Algae Reactors for Wastewater Treatment School of Energy, Environment and Agrifood EngD Academic Year: 2015 - 2016 Supervisors: Prof. Bruce Jefferson & Dr Raffaella Villa February 2016 CRANFIELD UNIVERSITY School of Energy, Environment and Agrifood EngD Academic Year 2015 - 2016 Rachel Louise Whitton Algae Reactors for Wastewater Treatment Supervisors: Prof. Bruce Jefferson & Dr Raffaella Villa February 2016 This thesis is submitted in partial fulfilment of the requirements for the degree of EngD © Cranfield University 2016. All rights reserved. No part of this publication may be reproduced without the written permission of the copyright owner. Abstract The onset of the Water Framework Directive (WFD) will challenge water utilities to further reduce their wastewater phosphorus discharges to < 0.5 mg.L-1. Whilst conventional treatments, such as chemical dosing, are able to meet these new discharge consents, the strategies are representative of a linear economy model where resources are unrecovered and disposed. An alternative solution which can contribute to the aspiration of a circular economy is microalgae. Microalgae are ubiquitous in wastewater environments and assimilate phosphorus during their growth, to residual concentrations complementary of the WFD. Furthermore, microalgal biomass can be anaerobically digested to produce biomethane offering the potential for an energy neutral approach. However, uptake of microalgal systems are lacking in the UK through limited knowledge of operation; and the belief that such solutions are synonymous to large, shallow open ponds with extensive treatment times. The development of alternative microalgal reactors are increasingly investigated to overcome these implementation challenges. Of these, immobilised microalgae has shown great potential; and whilst within its infancy demonstrates the greatest opportunity for development and optimisation. This thesis determines the critical operational parameters that influence the remediation efficacy of immobilised microalgae for tertiary nutrient removal; including species selection, biomass concentration, treatment period and lighting; with recommendations for optimal performance. These recommendations are then applied to the design and operation of an immobilised bioreactor (IBR) to understand the key design and operating components that influence the overall economic viability. In doing so, the potential for an IBR to be economically viable, within the next decade, in comparison to traditional approaches are discussed. Keywords: immobilisation, phosphate, nitrogen, circular economy i Acknowledgments My foremost thanks go to the members of the ‘algae team’. Headed, of course, by Prof. Bruce Jefferson who pushed me to my intellectual limits and challenged me to achieve my best. Not only have you supported me in achieving an EngD, but taught me to ‘man up’ and ‘just do it!’ I appreciate all your encouragement and enthusiasm and the time you committed to seeing me succeed (including your free time), I will be forever grateful. I would like to especially thank Dr Raffaella Villa for her endless support and positivity. You always managed to help me to step back from problems and issues, and realise that they weren’t really problems at all. This is one of the many reasons why I couldn’t leave you behind in Denmark! To Dr Francesco Ometto, who taught me everything I know about microalgae! I really enjoyed working with you and have many fond memories of our time together in the microbiology lab. Your endless enthusiasm and ability to always put a smile on my face contributed to ‘Whit-ton’ completing. I hope we always stay friends and wish you nothing but the best. I would like to thank Dr Marc Pidou for your friendship, support and technical assistance. Your arrival in the ‘algae team’ reinvigorated the research, and your ability to think outside the box allowed progress to be made at a point when I felt stuck in a rut. I’ll think of you each and every time I drink a can of Coca Cola…! Throughout the years, the ‘algae team’ have hosted a number of students whom I had the pleasure in supporting and whose contribution helped progress themes of the research. I thank Marie Chazaux, Amandine Le Mével, Vaiai Richmond, Marta San Juan Gomez and especially Martina Santinelli for all your hard work and enthusiasm. I enjoyed getting to know you all and learning about your home countries… which I am very much looking forward to being invited to in the future..! I express gratitude to David Inman and Adam Brookes of Anglian Water for making me feel part of the AW team and providing guidance and support throughout the project. In addition to Pete Vale of Severn Trent and Graeme Moore and Roi Otero of Scottish Water, for your enthusiasm during the project and at the progress review meetings. iii I am extremely grateful for the technical support I received from my technician friends, including Jane Hubble, Alan Nelson, Paul Barton, Rukshana Ormesher, Jan Bingham and Maria Biskupska. Thank you for always being approachable, even when busy, and for your guidance and the jokes we shared. I wonder if other students will find you can be bribed with chocolate? I am thankful to the STREAM administration; Paul Jeffrey, Ewan Mcadam and especially Tania Rice for her support right up until the minute of my submission! Also, my fellow Research Engineers in Cohort 2, in particular my Cranfield companions Catherine Rolph and James Keeley. We did it! To all my fellow PhD/EngD students in building 39/52a, especially Caroline Hepburn and Frankie Hassard for your support and camaraderie even during the gloomiest days in the ‘Room of Doom’ (with the help of the treat drawer!). And of course to my Mum, Dad and sister Marie. Thank you for all your support and encouragement through my entire studies. Thank you for always being there and your constant belief in me. I’m very much looking forward to graduation and another set of family air-brushed photos for us to display proudly within the family home. Finally, I thank Michael Green (Dr!). We shared this experience together, through the good and the bad, and I thank you for your support and understanding. I look forward to the future and for us finally being able to sleep through the night without waking up with the 3 am fear. And as I always promised throughout the four/five years, I end my acknowledgements with a quote from a boy band whom brightened up the gloomiest of writing up days… ‘All you people can't you see, can't you see? How your love's affecting our reality. Every time we're down, you can make it right, and that makes you larger than life’ Backstreet Boys (1999) iv Table of Contents Abstract ....................................................................................................................... i Acknowledgments .................................................................................................... iii List of Figures ......................................................................................................... viii List of Tables ............................................................................................................ xi List of Equations ..................................................................................................... xiii Abbreviations ......................................................................................................... xiv Introduction ........................................................................................1 1.1 Background .......................................................................................................1 1.1.1 Microalgae for wastewater nutrient remediation .......................................2 1.1.2 Understanding the route to implementation ..............................................3 1.2 Research Development .....................................................................................6 1.3 Aims and Objectives .........................................................................................7 1.4 Thesis Plan ........................................................................................................9 1.5 References ......................................................................................................13 Microalgae for Municipal Wastewater Nutrient Remediation: Mechanisms, Reactors and Outlook for Tertiary Treatment ....................................17 2.1 Introduction ....................................................................................................18 2.1.1 Overview of Microalgal Nutrient Remediation Mechanisms .................19 2.2 Microalgal Bioreactor Configurations for Wastewater Nutrient Remediation ..........................................................................................................28 2.2.1 High Rate Algal Pond (HRAP) ...............................................................32 2.2.2 Photobioreactor (PBR) ............................................................................32 2.2.3 Microalgal Biofilms .................................................................................33 2.2.4 Matrix-immobilisation .............................................................................33 2.3 Influence of Operational Parameters and Bioreactor Design on Remediation Performance ..........................................................................................................34 2.3.1 Influent Nutrient Concentration and Treatment Period ...........................34 2.3.2 Light, Temperature and Biomass Productivity ........................................38 2.4 Conclusions and Key Remaining Challenges .................................................41 2.5 Acknowledgements ........................................................................................42 2.6 References ......................................................................................................42 Influence of Microalgal N and P Composition on Wastewater Nutrient Remediation 53 3.1 Introduction ....................................................................................................54 3.2 Materials and Methods ...................................................................................57 3.2.1 Microalgal biomass culture and immobilisation .....................................57 3.2.2 Freshwater species characterisation - nutrient remediation and internal N and P composition ............................................................................................57 3.2.3 Wastewater nutrient remediation trials for S.obliquus and C.vulgaris ....58 v 3.2.4 Calculations for optimal biomass concentration for wastewater treatment by S.obliquus and C.vulgaris – suspended and immobilised cultures ..............59 3.3 Results ............................................................................................................60 3.3.1 Freshwater species characterisation - nutrient remediation and internal N and P composition ............................................................................................60 3.3.2 Wastewater nutrient remediation by S.obliquus and C.vulgaris .............64 3.3.3 Discussion: implications for an immobilised microalgal reactor for tertiary wastewater nutrient remediation .......................................................................67 3.4 Conclusions ....................................................................................................72 3.5 Acknowledgements ........................................................................................72 3.6 References ......................................................................................................72 Tertiary Nutrient Removal from Wastewater by Immobilised Microalgae: Impact of N:P Ratio and Hydraulic Retention Time (HRT) ................77 4.1 Introduction ....................................................................................................78 4.2 Materials and Methods ...................................................................................80 4.2.1 Wastewater ..............................................................................................80 4.2.2 Microalgae cultivation and immobilisation procedure ............................81 4.2.3 Experimental setup for continuous treatment ..........................................82 4.2.4 Sample analysis and biomass growth ......................................................84 4.3 Results and Discussion ...................................................................................85 4.3.1 Phosphate remediation .............................................................................85 4.3.2 Nitrogen remediation and pH ..................................................................88 4.3.3 Bead remediation characteristics .............................................................92 4.4 Conclusions ....................................................................................................94 4.5 Acknowledgements ........................................................................................94 4.6 References ......................................................................................................95 The Effect of Light on Wastewater Nutrient Remediation by Immobilised Microalgae ...........................................................................................99 5.1 Introduction ..................................................................................................100 5.2 Materials and Methods .................................................................................102 5.2.1 Microalgal cultivation and immobilisation procedure...........................102 5.2.2 Wastewater ............................................................................................103 5.2.3 Experimental set up and light regime ....................................................103 5.2.4 Batch nutrient remediation sample analysis and biomass growth and yield on light energy ................................................................................................105 5.2.5 Light transmittance ................................................................................106 5.3 Results ..........................................................................................................106 5.3.1 Impact of wavelength and PFD on nutrient remediation and growth ...106 5.3.2 Light attenuation ....................................................................................109 5.3.3 Light regimes .........................................................................................111 5.4 Discussion: Implications for lighting microalgae for wastewater nutrient remediation .........................................................................................................119 vi
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