Water Conservation for the County of San Luis Obispo

Antoniou, Dimitri Theodore

01 June 2010

This study is an academic research project completed to satisfy the California Polytechnic Master Thesis Requirement for the Master Degree of City and Regional Planning in the College of Architecture and Environmental Design. The County of San Luis Obispo Planning and Building Department is the client for this professional project. The project was requested by the County of San Luis Obispo to assist in its water conservation efforts and to help achieve a 20 percent per capita reduction of water use by the year 2020. The project consists of two documents: A Handbook of Water Conservation Technologies and Practices (Handbook) and the Background Report for the Water Conservation Handbook (Background Report). The Handbook is intended to provide a quick guide to various water conserving fixtures and appliances that developers and residents throughout the County of San Luis Obispo can reference for personal use. The Handbook includes information on the type of technology, the benefits in terms of water saving potential, and the cost of implementation. The Handbook is organized based on Indoor and Outdoor water uses. The Background Report is a supplemental document for the Handbook which provides more in depth descriptions and examples on each technology. The Background Report also provides history on water conservation issues in California and San Luis Obispo. It looks at two case studies: one, on the water conservation efforts in Phoenix, Arizona, and two, on a plumbing retrofit project on the Cal Poly Campus that was awarded LEED certification for its water savings. Furthermore, the Background Report explores case studies in the use of community participatory planning to produce water conservation plans. The studies focused on a Community Plan development in Arroyo Grande, California, and on an Integrated Regional Water Management Plan in the Greater Los Angeles Region. The Background Report concludes by providing some cautionary advice on water conservation technologies and provides future recommendations for the county of San Luis Obispo to improve its water conservation efforts.

Water Conservation

Technologies

County of San Luis Obispo

Handbook

Environmental Design

Natural Resources and Conservation

Urban, Community and Regional Planning

Optimal energy-water nexus management in residential buildings incorporating renewable energy, efficient devices and water recycling

Wanjiru, Evan

January 2017

Developing nations face insurmountable challenges to reliably and sustainably provide energy and water to the population. These resources are intricately entwined such that decisions on the use of one affects the other (energy-water nexus). Inadequate and ageing infrastructure, increased population and connectivity, urbanization, improved standards of living and spatially uneven rainfall are some of the reasons causing this insecurity. Expanding and developing new supply infrastructure is not sustainable due to sky high costs and negative environmental impact such as increased greenhouse gas emissions and over extraction of surface water. The exponentially increasing demand, way above the capacity of supply infrastructure in most developing countries, requires urgent mitigation strategies through demand side management (DSM). The DSM strategies seek to increase efficiency of use of available resources and reducing demand from utilities in the short, medium and long term. Renewable energy, rooftop rain water harvesting, pump-storage scheme and grey water recycling are some alternatives being used to curb the insecurity. However, renewable energy and rooftop water harvesting are spasmodic in nature hampering their adoption as the sole supply options for energy and water respectively. The built environment is one of the largest energy and water consuming sectors in the world presenting a huge potential towards conserving and increasing efficiency of these resources. For this reason, coupled with the 1970s energy challenges, the concept of green buildings seeking to, among other factors, reduce the consumption of energy and water sprung up. Conventionally, policy makers, industry players and researchers have made decisions on either resource independently, with little knowledge on the effect it would have on the other. It is therefore imperative that optimal integration of alternative sources and resource efficient technologies are implemented and analysed jointly in order to achieve maximum benefits. This is a step closer to achieving green buildings while also improving energy and water security. A multifaceted approach to save energy and water should integrate appropriate resource efficient technology, alternative source and an advanced and reliable control system to coordinate their operation. In a typical South African urban residential house, water heating is one of the most energy and water intensive end uses while lawn irrigation is the highest water intensive end use occasioned by low rainfall and high evaporation. Therefore, seamless integration of these alternative supply and most resource intensive end uses provides the highest potential towards resource conservation. This thesis introduces the first practical and economical attempt to integrate various alternative energy and water supply options with efficient devices. The multifaceted approach used in this research has proven that optimal control strategy can significantly reduce the cost of these resources, bring in revenue through renewable energy sales, reuse waste water and reduce the demand for grid energy, water and waste water services. This thesis is generally divided into cold and hot water categories; both of which energy-water nexus DSM is carried out. Open-loop optimal and closed-loop model predictive (MPC) control strategies that minimize the objective while meeting present technical and operational constraints are designed. In cold water systems, open-loop optimal and MPC strategies are designed to improve water reliability through a pump storage system. Energy efficiency (EE) of the pump is achieved through optimally shifting the load to off-peak period of the time-of-use (TOU) tariff in South Africa. Thereafter, an open-loop optimal control strategy is developed for rooftop rain water harvesting for lawn irrigation. The controller ensures water is conserved by using the stored rain water and ensuring only the required amount of water is used for irrigation. Further, EE is achieved through load shifting of the pump subject to the TOU tariff. The two control strategies are then developed to operate a grey water recycling system that is useful in meeting non-potable water demand such as toilet flushing and lawn irrigation and EE is achieved through shifting of pump's load. Finally, the two control strategies are designed for an integrated rain and grey water recycling for a residential house, whose life cycle cost (LCC) analysis is carried out. The hot water category is more energy intensive, and therefore, the open-loop optimal control strategy is developed to control a heat pump water heater (HPWH) and an instantaneous shower, both powered by grid-tied renewable energy systems. Solar and wind energy are used due to their abundance in South Africa. Thereafter, the MPC strategy is developed to power same devices with renewable energy systems. In both strategies, energy is saved through the use of renewable energy sources, that also bring in revenue through sale of excess power back to the grid. In addition, water is conserved through heating the cold water in the pipes using the instantaneous shower rather than running it down the drain while waiting for hot water to arrive. LCC analysis is also carried out for this strategy. Each of the two control strategies has its strengths. The open loop optimal control is easier and cheaper to implement but is only suitable in cases where uncertainties and disturbances affecting the system do not alter the demand pattern for water in a major way. Conversely, the closed-loop MPC strategy is more complicated and costly to implement due to additional components like sensors, but comes with great robustness against uncertainties and disturbances. Both strategies are beneficial in ensuring security and reliability of energy and water is achieved. Importantly, technology alone cannot have sustainable DSM impact. Public education and awareness on importance of energy and water savings, improved efficiency and effect on supply infrastructure and greenhouse gas emissions are essential. Awareness is also important in enabling the acceptance of these technological advancements by the society. / Thesis (PhD)--University of Pretoria, 2017. / National Hub for Energy Efficiency and Demand Side Management (EEDSM) / University of Pretoria / Electrical, Electronic and Computer Engineering / PhD / Unrestricted

UCTD

Demand side management

Energy efficiency

Grey water recycling

Heat pump water heater

Water conservation

Energy-water nexus

The Water-Energy Nexus: a bottom-up approach for basin-wide management

Escrivà Bou, Àlvar

21 December 2016

Tesis por compendio / [EN] First chapter uses California's drought to identify the economic threats of water scarcity on food, energy and environmental systems as a way to introduce the multiple interactions between these resources. The second part of this first chapter introduces the focus of the dissertation, the water-energy nexus, presents a literature review identifying gaps, states the main and specific research objectives and the research questions, explains the research approach, and describes the organization of the dissertation. Second chapter develops an end-use model for water use and related energy and carbon footprint using probability distributions for parameters affecting water consumption in 10 local water utilities in California. Statewide single-family water-related CO2 emissions are 2% of overall per capita emissions, and locally variability is presented. The impact of several common conservation strategies on household water and energy use are assessed simulating different scenarios. Based on the this model, Chapter 3 introduces a probabilistic two-stage optimization model considering technical and behavioral decision variables to obtain the most eco-nomical strategies to minimize household water and water-related energy bills and costs given both water and energy price shocks. Results can provide an upper bound of household savings for customers with well-behaved preferences, and show greater adoption rates to reduce energy intensive appliances when energy is accounted, result-ing in an overall 24% reduction in indoor water use that represents a 30 percent reduc-tion in water-related energy use and a 53 percent reduction in household water-related CO2 emissions. To complete the urban water cycle, Chapter 4 develops first an hourly model of urban water uses by customer category including water-related energy consumption and next I calibrate a model of the energy used in water supply, treatment, pumping and wastewater treatment by the utility, using real data from East Bay Municipal Utility District in California. Hourly costs of energy for the water and energy utilities are assessed and GHG emissions for the entire water cycle estimated. Results show that water end-uses account for almost 95% of all water-related energy use, but the 5% managed by the utility is still worth over $12 million annually. Several simulations analyze the potential benefits for water demand management actions. The total carbon footprint per capita of the urban water cycle is 405 kg CO2/year representing 4.4% of the total GHG emissions per capita in California. Accounting for the results obtained in Chapters 2 to 4, Chapter 5 describes a simple but powerful decision support system for water management that includes water-related energy use and GHG emissions not solely from the water operations, but also from final water end uses, including demands from cities, agriculture, environment and the energy sector. The DSS combines a surface water management model with a simple groundwater model, accounting for their interrelationships, and also includes explicitly economic data to optimize water use across sectors during shortages and calculate return flows from different uses. Capabilities of the DSS are demonstrated on a case study over California's intertied water system over the historic period and some simulations are run to highlight water and energy tradeoffs. Results show that urban end uses account for most GHG emissions of the entire water cycle, but large water conveyance produces significant peaks over the summer season. The carbon footprint of the entire water cycle during this period, according to the model, was 21.43 millions of tons of CO2/year, what was roughly 5% of California's total GHG emissions. The last two chapters discus and summarize the thematic and methodological contribu-tions and looks for further research presenting and discussing the research gaps and research questions that this dissertation left open. / [ES] El primer capítulo utiliza la sequía de California para identificar las amenazas económicas de la escasez de agua en los sistemas de producción de alimentos, energético y medioambiental para presentar las múltiples interacciones entre estos recursos. La segunda parte del primer capítulo centra el objetivo de la tesis, la relación entre el agua y la energía, presenta la revisión de la literatura identificando los vacíos, describe los objetivos y las cuestiones que busca responder esta investigación, explica la metodología seguida, y describe la organización de la tesis. En el segundo capítulo se desarrolla un modelo de usos finales de agua, contando con la energía y las emisiones de GEI asociados utilizando distribuciones de probabilidad para los parámetros que afectan al uso del agua en 10 ciudades en California. Como resultados principales se obtiene que las emisiones de GEI asociadas al consumo residencial de agua representan el 2% del total de emisiones per cápita, y se presenta la variabilidad debida a las condiciones locales. Los impactos de algunas prácticas comunes de ahorro de agua y energía son calculadas simulando diferente escenarios. Basado en ese modelo, el Capítulo 3 se presenta un modelo de optimización probabilísticos en dos periodos considerando variables de decisión de modificaciones técnicas y de comportamiento en relación al consumo de agua para obtener las estrategias más económicas para minimizar las facturas de agua y energía. Los resultados proporcionan un límite superior para el ahorro doméstico, y muestran mayores tasas de adopción para reducir usos de agua que son más intensivos en consumo energético cuando la energía se incluye, resultando en una reducción del 24% de uso de agua adentro de las casas, que representa un 30% en reducción de energía y un 53% de emisiones de GEI, ambos relacionados con el consumo de agua. Para completar el ciclo urbano del agua, el Capítulo 4 desarrolla primero un modelo horario de usos de agua incluyendo la energía asociada y después se calibra un modelo de agua y energía en el abastecimiento, tratamiento y bombeo de agua, y el tratamiento de agua residual, utilizando datos reales de East Bay Municipal Utility District en California. Los costes horarios de energía para las compañías de agua y energía, así como las emisiones de GEI son estimadas. Los resultados muestran que los usos finales son responsables del 95% de la energía relacionada con el uso del agua, pero que el 5% restante tiene un coste de 12 millones de dólares anualmente. Teniendo en cuenta los resultados obtenidos en los capítulos 2, 3 y 4, el Capítulo 5 describe un sistema de apoyo de decisión (SSD) para gestión de recursos hídricos incluyente energía y emisiones de GEI no sólo de la gestión del agua, sino también de usos finales del agua, incluyendo demandas urbanas, agrícolas, ambientales y del sector energético. El SSD combina un modelo de agua superficial con uno de agua subterráneo, incluyendo sus interacciones, y también incluye explícitamente datos económicos para optimizar el uso del agua durante periodos de sequía. Las posibilidades del SSD son demostradas en un caso de estudio aplicado a un modelo simplificado del sistema de recursos hídricos de California. Los resultados muestran que los usos finales del agua en zonas urbanas son responsables de la mayoría de las emisiones de GEH, pero que las grandes infrastructures de transporte de agua producen importante picos en verano. De acuerdo con el modelo, la huella de carbón del ciclo del agua en California es de 21.43 millones de toneladas de CO2/año, lo que significa aproximadamente el 5% del total de emisiones de GEI del estado. Los últimos dos capítulos resumen y discuten las contribuciones temáticas y metodológicas de esta tesis, presentando nuevas líneas de investigación que se derivan de este trabajo. / [CA] El primer capítol utilitza la sequera de Califòrnia per a identificar les amenaces econòmiques de l'escassesa d'aigua en els sistemes de producció d'aliments, energètic i mediambiental per a presentar les múltiples interaccions entre estos recursos. La segona part del primer capítol centra l'objectiu de la tesi, la relació entre l'aigua i l'energia, presenta la revisió de la literatura identificant els buits, descriu els objectius i les qüestions que busca respondre esta recerca, explica la metodologia seguida, i descriu la organització de la tesi. Al segon capítol es desenvolupa un model d'usos finals d'aigua, comptant amb l'energia i les emissions de GEH associats utilitzant distribucions de probabilitat per als paràmetres que afecten a l'ús de l'aigua en 10 ciutats en Califòrnia. Com a resultats principals s'obté que les emissions de GEH associades al consum residencial d'aigua representen el 2% del total d'emissions per càpita, i es presenta la variabilitat deguda a les condicions locals. Els impactes d'algunes pràctiques comunes d'estalvi d'aigua i energia són calculades simulant diferent escenaris. Basat en eixe model, al Capítol 3 es presenta un model d'optimització probabilístics en dos períodes considerant variables de decisió de modificacions tècniques i de comportament en relació al consum d'aigua per a obtindre les estratègies més econòmiques per a minimitzar les factures d'aigua i energia. Els resultats proporcionen un límit superior per a l'estalvi domèstic, i mostren majors taxes d'adopció per a reduir usos d'aigua que són més intensius en consum energètic quan l'energia es incluïda, resultant en una reducció del 24% d'ús d'aigua a dins de les cases, que representa un 30% en reducció d'energia i un 53% d'emissions de GEH, ambdós relacionats amb el consum d'aigua. Per a completar el cicle urbà de l'aigua, el Capítol 4 desenvolupa primer un model horari d'usos d'aigua incloent l'energia associada i després es calibra un model d'aigua i energia en l'abastiment, tractament i bombeig d'aigua i al tractament d'aigua residual, utilitzant dades reals de East Bay Municipal Utility District en Califòrnia. Els costs horaris d'energia per a les companyies d'aigua i energia, així com les emissions de GEH són estimades. Els resultats mostren que els usos finals són responsables del 95% de l'energia relacionada amb l'ús de l'aigua, però que el 5% restant té un cost de 12 milions de dolars anualment. Algunes simulacions analitzen els beneficis econòmics potencials de mesures de gestió de demanda d'aigua. La petjada de carbó total del cicle urbà de l'aigua s'estima en 405 kg CO2/any representant el 4.4% de les emissions per càpita en Califòrnia. Tenint en compte els resultats obtesos en els capítols 2, 3 i 4, el Capítol 5 descriu un sistema de suport de decisió (SSD) per a gestió de recursos hídrics incloent energia i emissions de GEH no sols de la gestió de l'aigua, sinó també del úsos finals de l'aigua, incloent demandes urbanes, agrícoles, ambientals i del sector energètic. El SSD combina un model d'aigua superficial amb un d'aigua subterrànea, incloent les seues interrelacions, i també inclou explícitament dades econòmiques per a optimitzar l'ús de l'aigua durant períodes de sequera. Les possibilitats del SSD són demostrades en un cas d'estudi aplicat a un model simplificat del sistema de recursos hídrics de Califòrnia. Els resultats mostren que els usos finals de l'aigua en zones urbanes són responsables de la majoria de les emissions de GEH, però que les grans infrastructures de transport d'aigua produïxen important pics a l'estiu. D'acord amb el model, la petjada de carbó del cicle de l'aigua a Califòrnia és de 21.43 milions de tones de CO2/any, el que significa aproximadament el 5% del total d'emissions de GEH a l'estat. Els últims dos capítols resumeixen i discuteixen les contribucions temàtiques i metodològiques d'esta tesi, presentan / Escrivà Bou, À. (2015). The Water-Energy Nexus: a bottom-up approach for basin-wide management [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/59451 / TESIS / Premios Extraordinarios de tesis doctorales / Compendio

Water-energy nexus

Water management

Water resources system

Residential water conservation

Urban water

GHG emissions

Climate change

INGENIERIA HIDRAULICA

Understanding consumers' ornamental plant preferences for disease-free and water conservation labels

Hartter, David L.

27 August 2012

Product labeling is increasingly used as a tool to differentiate products with public and private benefits that cannot be readily evaluated by a consumer at the time of purchase. Our research investigates how a labeling program may be applied in the sale of ornamental plants to address two key issues; plant disease and irrigation water use. A choice modeling survey was utilized to estimate consumers' willingness to pay a premium for six ornamental plants with disease-free and/or water conservation certification labels. The results of the mixed logit models show consumers are willing to pay a premium for plants certified as disease-free and/or produced with water conservation practices. The results strongly suggest producers can recoup some of the costs of implementing water conservation measures such as water recycling and disease control measures amid regulatory and drought concerns. Our research also investigated consumers' preferences for multiple third party certifying authorities and whether preferences for the labels varied among consumers. The results showed ornamental plant consumers did not reveal a preference for a particular certifying authority. The results are mixed as to whether willingness to pay for the labels varies among respondents. We show willingness to pay does vary among respondents for three of the plant models indicating preference heterogeneity. / Master of Science

Willingness to pay

mixed logit

ornamental plants

third-party certification

water conservation

product labeling

water-borne disease

Vattenbesparing inom hushåll : Fallstudie av Sandön och Oaxen med tillhörande kommuner Värmdö och Södertälje / Water Conservation in Households : Case Study of Sandön and Oaxen, Including Associated Municipalities Värmdö and Södertälje

Andersson, Emilie, Hambraeus, Ellinor

January 2021

Vatten är avgörande för allt liv på jorden och utgör FN:s sjätte globala hållbarhetsmål ”rent vatten och sanitet”. Denna rapport syftar på att undersöka vattenbesparing inom hushåll genom en fallstudie av Oaxen och Sandön med tillhörande kommuner Södertälje och Värmdö. Genom litteraturstudier kartlades befintliga vattenbesparingsåtgärder och kommunernas vattenarbete undersöktes både genom litteraturstudier samt intervjuer. En enkätstudie genomfördes även för att kartlägga individers beteende, kunskap och inställning till vattenbesparingsåtgärder. Det erhållna resultatet från enkätstudien visade på en positiv inställning till vattenbesparingsåtgärder och många individer har en stor medvetenhet kring sitt beteende relaterat till vattenanvändning. Litteraturstudien och intervjuerna visade vidare att det i dagsläget finns få riktlinjer relaterat till vattenbesparing och befintliga riktlinjer fokuserar framförallt på ramar för vattenanvändning snarare än att införa rekommendationer kring olika vattenbesparingsåtgärder. Slutligen rekommenderas snålspolande munstycken (sparstrålsamlare) och snålspolande toaletter som de bästa åtgärderna baserat på vattenbesparing, installationskostnad, kostnadsbesparing och individers inställning. / Water is crucial for all life on earth and constitutes UN’s sixth sustainable development goal ”Clean Water and Sanitation”. This report aims to study water conservation in households through a case study of the two islands Oaxen and Sandön with their associated municipalities Södertälje and Värmdö. Existing water conservation measures were identified through literature studies and the municipalities efforts in water management were studied through both literature studies and interviews. A survey was also conducted to study individuals’ behaviour, knowledge and view on water conservation measures.  The result obtained from the survey study showed a positive view to water conservation measures and many respondents showed great awareness regarding their behaviour related to water usage. Furthermore, the literature study and the interviews convey that there currently are few guidelines related to water conservation. Existing guidelines mainly focuses on limitations for water usage rather than introducing recommendations on different technical water conservation measures. In conclusion, low-flush nozzles and toilets are recommended since they are considered to be the best water conservation measures based on installation cost, cost savings, water conservation and individuals’ views. Recirculating shower and usage of rainwater are to be considered for those having the possibility to make a bigger investment due to the water conservation being great.

Water conservation

water usage

household

Oaxen

Sandön

Vattenbesparing

vattenanvändning

hushåll

Oaxen

Sandön

Other Environmental Engineering

Annan naturresursteknik

Addressing the future of water in Oregon : a look at the human and institutional factors shaping Oregon water management

Wolters, Erika Allen

26 April 2012

Oregon is a state with great social and ecological diversity. Unfortunately however, Oregon's water-rich reputation is more rumor than reality. As with many Western states, Oregon struggles with water scarcity, especially during dry summer months. Recent efforts by the state to develop an integrated water resource strategy (IWRS) to manage present and future water demand in Oregon signifies the very real concern that water is no longer as abundant and available as it once was. With the predicted impacts of climate change and population growth, the already-strained water supply will unlikely sustain current water needs. Using a statewide mail survey of 1,537 Oregon residents (2010), a second survey of 390 water stakeholders (2011), and 12 semi-structured interviews conducted in 2010 and 2011 of stakeholders and elected officials this dissertation examined the role of sociodemographic attributes and environmental values pertaining to concern about Oregon’s water supply, climate change, water conservation behaviors, and prioritization of water use. Data analysis (regression analysis) revealed that to varying degrees gender, age, education, income, concern about water scarcity and belief in the New Ecological Paradigm (NEP) proved reliable predicators of concern about that water quantity is a problem, that Oregonians will be personally affected by water scarcity, and personal water conservation behaviors. The dissertation further applies the Institutional and Analysis Development (IAD) framework to the current efforts by the state to create and IWRS. Recommendations for successful application of the IWRS are discussed, specifically use of adaptive governance in basin and sub-basin planning efforts. / Graduation date: 2012

Integrated Water Resource Strategy

Oregon water

New Ecological Paradigm

Attitude-Behavior

Water Conservation

Water-supply -- Oregon

Water-supply -- Oregon -- Public opinion

Water conservation -- Oregon

A critical evaluation of urban water management: comparative case studies of Meadowlands Township, Soweto and Florida suburb, Roodepoort

Msimango, Langalibalele Innocent

02 1900

Water is a vital component for human survival but unsustainable patterns of water consumption are still evident internationally. In South Africa, water conservation has traditionally been limited to the responsibility of the state, with little effort being made by the consumers. However, as water scarcity increasingly becomes a problem, government and residents need to find out how urban South Africans can access water and implement water conservation methods in their homes without the support of government supervision programmes. This study explores the relationship between urban residences in two different parts of Johannesburg (Meadowlands in Soweto and Florida in Roodepoort) and their consumption, perception and usage of water and its conservation. Based on interviews with residents from different backgrounds, the results of this research show that residents have varied but generally limited concern for water issues. Findings from this study indicate that for a resident to conserve water, the type of abode in which he/she lives is irrelevant. Whether the resident lives in suburban home or small government funded housing, the attitudes of the interviewees and the perceptions which they expressed regarding solutions to the water dilemma proved to be similar: people in these urban areas are aware of the importance of water conservation, however, there is limited practice thereof. / Geography / M. Sc. (Geography)

Water conservation

Households

Perceptions

Meadowlands

Florida

Access

Residents

Sustainability

Income

Community

Climate change

Comparison

333.7316096822

Soweto (South Africa)

Roodepoort (South Africa)

水環境保護中政府治理與公眾參與的關係研究 : 以滇池治理為例

楊清卿

January 2012

University of Macau / Faculty of Social Sciences and Humanities / Department of Government and Public Administration

Integrated water demand management for local water governance

Du Plessis, J. A.

12 1900

Thesis (PhD (Public Management and Planning))--University of Stellenbosch, 2010. / Please refer to full text for abstract

Municipal water supply

Water supply -- Government policy

Water conservation -- Management

Water efficiency

Theses -- Public management and planning

School of Public Leadership

Avaliação de um sistema de tratamento de águas cinzas em edificação de campus universitário / Evaluation of a greywater treatment system in a building of university campus

Chrispim, Mariana Cardoso

01 September 2014

O reúso de água é um instrumento importante que contribui para a redução da pressão sobre os mananciais e para redução do consumo de água potável para fins que não requeiram água de padrão potável. Neste contexto, o presente estudo teve como objetivo principal analisar um sistema de coleta e tratamento de águas cinzas provenientes de pias de banheiro, chuveiros e máquina de lavar roupas tendo em vista o reúso não-potável em edificações. Os objetivos específicos foram: caracterizar qualitativamente e quantitativamente as frações de águas cinzas; operar e monitorar um sistema de tratamento de águas cinzas sintéticas em escala piloto e analisar o efluente após tratamento. A partir de uma edificação existente no campus da EACH/USP, adaptou-se a estrutura hidráulica de forma a permitir a segregação e coleta desta fração de águas residuárias para caracterização e tratamento. A instalação de hidrômetros nas tubulações de alimentação dos pontos de uso (máquina de lavar, chuveiros e lavatórios) possibilitou analisar a produção de águas cinzas individualizada. Para o tratamento em escala piloto, adotou-se um biorreator de leito móvel com biofilme (MBBR) seguido por decantador. A avaliação do sistema de tratamento foi realizada com base no monitoramento periódico dos parâmetros físico-químicos durante o período de operação do sistema. Com base nos resultados obtidos, dentre as três frações de águas cinzas, a do chuveiro foi a que apresentou maior concentração de E.coli, enquanto que a maior concentração de coliformes totais foi na água cinza de lavatórios. As eficiências de remoção de DBO e DQO foram de 59 por cento e 70 por cento respectivamente. Houve baixa remoção de fósforo e não houve remoção de Nitrogênio Total durante o tratamento. / Water reuse is an important tool that can contribute to the reduction of the pressures from human activities on water resources and to reduce the demand for potable water for purposes that do not require high quality water. Therefore, the main objective of this study was to evaluate a greywater collection and treatment system from lavatories, showers and washing machine aiming the non-potable reuse in buildings. The specific objectives were: to characterize in terms of quality and quantity the greywater from each source, to monitor a pilot system for synthetic greywater treatment and to analyze the quality of the effluent after treatment. In an existing building in the University of Sao Paulo campus, the wastewater collection drains were modified to allow the segregated wastewater collection and the greywater characterization and treatment. To evaluate the greywater generation three water flow meters were installed in water inlet of each greywater source (washing machine, showers and lavatories). The greywater treatment included a moving bed biofilm reactor (MBBR) and a settling tank at pilot scale. The evaluation of greywater treatment was conducted based on the periodic monitoring of several physicochemical water quality parameters during the operation of the experimental system. Based on the results, amongst the three greywater sources, the greywater from showers had the highest E. coli count while the lavatories greywater had the highest total coliforms count. The removal efficiencies of BOD and COD were 59 per cent e 70 per cent respectively. In addition there was low removal of phosphorus and there was not Total Nitrogen Removal during the treatment.

Água Cinza

Biological Reactor

Conservação da Água

Greywater

Reator Biológico

Reúso de Água

Saneamento Ambiental

Sustainability

Sustainable Sanitation

Sustentabilidade

Water Conservation

Water Reuse