Equitable cost allocation for rainwater harvesting system : framework analysis : case of Austin,TX

Kim, Hyun Woo

25 July 2011

The limitation of urban water supplies is becoming worse each year. Several studies estimate that 2 billion of the world’s population will suffer from water scarcity by 2050; and urbanization rates is placing an even greater challenge in providing the infrastructure needed to serve growing populations. At this point, rainwater may be considered as the most critical, untapped water resource in a global aspect. Rainwater Harvesting Systems (RWHS) have tremendous potential, not only to provide sufficient water supply, but also to serve as a valuable stormwater management tool. Despite these benefits, RWHS is still not popular among ordinary people in urban situations, due mostly to high installation costs. This study aims to explore the equitable cost reallocation of residential rainwater harvesting systems between the urban utility, land developer and homebuilder, and individual homeowner sectors. It may be possible to redistribute the cost equitably among the parties based on potential benefits received,thereby making RWHS more affordable and more viable as a new water supply for urban areas. / text

RWHS

Rainwater harvesting systems

Water harvesting

Austin

Texas

United States

Water supply

Impacts of scaling up water recycling and rainwater harvesting technologies on hydraulic and hydrological flows

Bertrand, Nathalie Marie-Ange

January 2008

In recent years, the increasing awareness of scarcity of water resources, indications of likely climate variability, and the increasing pressure to use available fresh water resources more efficiently have together reinforced the need to look at infrastructure solutions with due regard to environmental considerations and social impacts, present and future. There is a vital need to apply an integrated approach to catchment management to implement sustainable solutions to resolve issues such as water supply and sewerage, drainage and river flooding. Many potentials solutions are available to control water demand and manage flood problems. Greywater recycling and rainwater harvesting are novel technologies. However, their catchment scale impacts on hydraulic and hydrological flows are poorly understood. The research aim is to identify the hydrologic and hydraulic impacts of scaling up such technologies at catchment scale. For this particular study, a computer simulation model will be used to evaluate how increasing urbanisation, climate change and the implementation of greywater recycling and rainwater harvesting may alter the water balance within a representative catchment. To achieve these aims data from the Carrickmines catchment in Ireland have been collected; a simulation model has been adapted to carry out the study, the model has been calibrated and validated, results have been analysed, and finally, a sensitivity analysis has been carried out. The results show that rainwater harvesting systems are comparatively more effective than greywater recycling techniques in reducing flood frequency and intensity. Under five year return period rainfall events, the implementation of rainwater harvesting at any scale and number of units is a useful technique to control river flow and floods. However, the study also shows that under extreme conditions the efficiency of rainwater harvesting systems decreases. The study concludes that implementing the two technologies within a single catchment is not a solution to several forms of hydrological problem. The study shows that implementing rainwater harvesting or re-use technologies are a very useful way to protect local freshwater reserves and therefore conserve our environment.

628.1

Modeling Climate Change Impacts on the Effectiveness of Stormwater Control Measures in Urban Watersheds

Alamdari, Nasrin

30 August 2018

Climate change (CC) science has made significant progress in development of predictive models. Despite these recent advances, the assessment of CC impacts in urban watersheds remains an area of active research, in part due to the small temporal and spatial scales needed to adequately characterize urban systems. Urban watersheds have been the focus of considerable efforts to restore hydrology and water quality, and the aquatic habitat of receiving waters, yet CC impacts threaten to reduce the effectiveness of these efforts. Thus, assessing the impacts of CC in urban watershed assessment are essential for assuring the success of water quality improvement programs and is an important research need. Simulations of CC for the 2041-2068 period were developed using downscaled Global Climate Models (GCMs) from the North American Regional CC Assessment Program (NARCCAP) and Coupled Model Intercomparison Project Phase 5 (CMIP5) to forecast precipitation and temperature time series. This data were then used to force a Storm Water Management Model (SWMM) of the Difficult Run watershed of Fairfax County, Virginia, a tributary of Potomac River, which flows into Chesapeake Bay. NARCCAP uses a scenario represents a medium-high greenhouse gas emissions assumption, A2; the latter, uses five GCMs, and two Representative Concentration Pathways (RCP 4.5 and 8.5) scenarios in an ensemble approach to better assess variability of model predictions in presenting precipitation, temperature, runoff quantity and quality. Then, the effects of CC on runoff peak, volume, and nutrient and sediment loads delivered to the Chesapeake Bay and on the treatment performance of a very common stormwater control measure (SCM), retention ponds, was assessed. Rainwater Harvesting (RWH) systems are an unusual SCM in that they recycle and reuse stormwater, normally from rooftops, and increase water supply and reduce runoff. The efficiency of RWH systems for projected CC for these dual purposes was assessed. NARCAAP data for selected locations across the U.S. were statistically downscaled using a modified version of the equiratio cumulative distribution function matching method to create a time series of projected precipitation and temperature. These data were used to force a simulation model, the Rainwater Analysis and Simulation Program (RASP) to assess the impacts of CC on RWH with respect to the reliability of water supply and runoff capture. To support CC modeling, an easy-to-use software tool, RSWMM-Cost, was developed. RSWMM-Cost automates the execution of SWMM, which is commonly used for simulating urban watersheds. Several features were incorporated into the RSWMM-Cost tool, including automated calibration, sensitivity analysis, and cost optimization modules; the latter can assist in identifying the most cost-effective combination of SCMs in an urban watershed. As an example, RSWMM-Cost was applied to a headwater subcatchment the Difficult Run watershed. / Ph. D. / Urban watersheds have been the focus of considerable efforts to restore water quantity and quality, and the aquatic habitat of receiving waters, yet climate change impacts threaten to reduce the effectiveness of these efforts. The assessment of climate change impacts in urban watersheds remains an area of active research, in part due to the small temporal and spatial scales needed to adequately characterize urban systems. Thus, assessing the impacts of climate change in urban watershed assessment are essential for assuring the success of water quality improvement programs and is an important research need. In this study, simulations of climate change for the 2041-2068 period were developed to forecast precipitation and temperature data. These data were then used to force a hydrologic model for the Difficult Run watershed of Fairfax County, Virginia, a tributary of Potomac River, which flows into Chesapeake Bay. Then, the effects of climate change on runoff, nutrient and sediment loads delivered to the Chesapeake Bay and on the treatment efficiency of a very common management practice called retention ponds, was assessed. Rainwater harvesting systems are an unusual management practice that recycle and reuse stormwater, normally from rooftops, and increase water supply and reduce runoff. The efficiency of rainwater harvesting systems for projected climate change with respect to the reliability of water supply and runoff capture was assessed for the 2041-2068 period. To support climate change modeling, an easy-to-use tool, was also developed to select the most cost-optimized combination of best management practices in urban watersheds considering site constraints, limitations, and size. As an example, the tool was applied to a headwater subcatchment of the Difficult Run watershed. The ability to assess the impact of climate change on both hydrologic and water quality treatment could assist in the selection of the most appropriate management practices to address water management goals and conserve limited financial resources.

climate change

cost-optimization

retention pond

rainwater harvesting systems

cost effectiveness

load reduction

Domestic water demand for consumers with rainwater harvesting systems

O Brien, Olivia

04 1900

Thesis (MEng)--Stellenbosch University, 2014. / ENGLISH ABSTRACT: The focus of the study is to theoretically assess tank-water demand and employ methods to establish the actual tank-water demand at selected houses in a case study area. This study also examines the influence of domestic rainwater harvesting systems when used in combination with a municipal water distribution system. The case study comprises of 410 low cost housing units in the Western Cape. The system demand patterns of low cost housing units are uncharacteristic, when compared with suburban system demand patterns, and cannot be defined by traditional models. Similarly, the use of rainwater harvesting systems in these areas follows an unconventional routine that is yet to be defined. A stochastic end-use model for water demand is developed which produces temporal profiles for water supplied from both sources, namely the water distribution system and the rainwater harvesting system. The model approximates a daily system and tank-water demand pattern for a single domestic household, using @RISK software. The demand estimation methodology is clarified through application on a particular case study site where harvested rainwater is frequently utilized. Estimates of the parameter values are based on consumer surveys and previous studies on the case study area, where the household size was defined in the form of a probability distribution. The results confirm the atypical system demand patterns in low cost housing units units. Although two clear peaks exist in the morning and in the evening, a relatively constant average flow is present throughout the day. A sensitivity analysis of all the model parameters verified that the household size has the most substantial influence on the tank-water demand pattern. The system and tank-water demand patterns were compared to published average daily water demand guidelines, which confirmed that increased water savings could be achieved when the rainwater source is accessible inside the household with minimal effort. The stochastic demand profiles derived as part of this research agree with the metered system demand in the same area. The results of this study could be incorporated into the future development of national standards. / AFRIKAANSE OPSOMMING: Die fokus van die studie is om die tenkwater-aanvraag teoreties te ontleed en metodes in werking te stel om die werklike tenkwater-aanvraag vas te stel by geselekteerde huise in ‘n gevallestudie area. Hierdie studie ondersoek ook die invloed van plaaslike reënwater-herwinningstelsels wanneer dit gebruik word in kombinasie met ‘n munisipale waterverspreidingstelsel. Die gevallestudie bestaan uit 410 laekoste behuisingseenhede in die Wes-Kaap. Die stelsel-aanvraagpatrone van laekoste behuisingseenhede is verskillend wanneer dit met voorstedelike stelsel-aanvraagpatrone vergelyk word en kan nie gedefinieer word deur tradisionele modelle nie. Soortgelyk volg die gebruik van reënwater-herwinningstelsels in hierdie areas ‘n onkonvensionele roetine. ‘n Stogastiese eindgebruikmodel vir water-aanvraag is ontwikkel, wat tydelike profiele genereer vir water wat van beide bronne verskaf word, naamlik die waterverspreidingstelsel en die reënwater-herwinningstelsel. Die model bepaal by benadering ‘n daaglikse stelsel- en tenkwater-aanvraagpatroon vir ‘n enkele plaaslike huishouding, deur @RISK sagteware. Die aanvraag-beramingstegnieke word verduidelik deur toepassing op ‘n spesifieke gevallestudie, waar herwinde reënwater gereeld gebruik word. Die parameter waardeberamings is gebaseer op verbruikers-opnames en vorige studies oor die gevallestudie-gebied, waar die grootte van die huishoudings bepaal was in die vorm van 'n waarskynlikheidsverspreiding. Die resultate bevestig die atipiese stesel aanvraagpatrone in laekoste behuisingseenhede eenhede. Alhoewel twee duidelike pieke in die oggend en die aand voorkom, is ‘n relatiewe konstante vloei dwarsdeur die dag teenwoordig. ‘n Sensitiwiteitsanalise van al die modelparameters bevestig dat die grootte van die huishouding die grootste beduidende invloed op tenkwater- aanvraagpatrone het. Die stelsel- en tenkwater-aanvraagpatrone was vergelyk met gepubliseerde gemiddelde daaglikse water-aanvraag riglyne wat bevestig dat meer waterbesparings bereik kan word waar die reënwaterbron binne die huishouding beskikbaar is met minimale moeite. Die stogastiese aanvraagprofiele, wat as deel van hierdie navorsing afgelei was, stem saam met die gemeterde stelsel-aanvraagpatroon van dieselfde area. Die resultate van hierdie studie kan in die toekomstige ontwikkeling van nasionale standaarde opgeneem word.

Domestic Water Demand

System and Tank-Water Demand

Domestic Rainwater Harvesting Systems

Dissertations -- Civil engineering

Cisterns

Water consumption -- Measurement

Water harvesting

UCTD

Theses -- Civil engineering

Exploring Urban Rainwater Harvesting in the city of Madrid applying GIS based MCDA expert tools / Utforska Urban Rainwater Harvesting i staden Madrid med hjälp av GIS-baserade MCDA expertverktyg

Börjesson Ballesteros, Silvia

January 2022

Due to climate change, water resources’ scarcity and distribution variability have generated a growing interest in sustainable water management in recent years. In addition, the growing interest in implementing nature-based solutions for urban resilience leads to the development of decentralized water supply systems such as rainwater harvesting systems (RWHS) as a complementary resource to conventional centralized water supply systems. The study is motivated by the climatic risks that the city of Madrid is subject to face in the upcoming years such as pronounced summer droughts and urban heat waves, leading to the reduction of water resources availability. This study aims to use Multi-criteria decision analysis and Geographic Information systems as tools for locating optimal space for the installation of pond harvesting systems (PHS) in Madrid for water recollection for non-potable purposes in the city. Attaining this aim, two objectives were set. Firstly, to evaluate and select the most relevant criteria for the installation of PHS and secondly, to generate a map of the most suitable locations for installation of PHS in the city of Madrid through a proposed GIS-MCDA methodology and a complimentary evaluation for each possible solution, to obtain a global vision of the applicability of PHS in Madrid. Through the first objective, several criteria were set for PHS installation, namely: distance to the river, rainfall, slope, soil characteristics, and land use. These criteria were applied to Madrid through a GIS-MCDA methodology, using these two tools’ synergy to obtain a suitability map for PHS installation. Two criteria weightings will be performed to evaluate the model’s robustness by modifying the criteria’ weights resulting in two different suitability scenarios. The discussion will analyze the results obtained considering the two scenarios and propose the most suitable location clusters identified. Finally, the conclusion will reflect the study’s most important findings and open the door to further research on the topic, such as the design, operation infrastructure, drainage logistics distribution, and other modifications in Madrid’s current water management system. / Som en konsekvens av den pågående klimatförändringen och dess inverkan i distributionen av vattenresurser har det skapats ett växande intresse för en hållbar vattenförvaltning de senaste åren. Detta växande intresse leder till implementationen av naturbaserade lösningar för urban resiliens och till en utveckling av decentraliserade vattenförsörjningssystem som regnvattenuppsamling (RWHS) som en komplementerande resurs till konventionella centraliserade vattenförsörjningssystem. Huvudsyftetmed denna studie är att täcka forskningsklyftan och att genom användning av verktyg som multikriterieanalys och geografiskt informationssystem (GIS) lokalisera en optimal plats för installation av dammar för regnvattenupptagning som del av stadsplanering för att skapa en hållbar vattenförvaltning i staden. För att uppnå detta, sattes två mål. Det ena var att utvärdera och välja de mest relevanta kriterierna för installation av dammuppsamlingssystem (PHS), det andra målet var att generera en karta över de lämpligaste platserna för installation av PHS i Madrid (Spanien) genom en föreslagen GIS-MCDA-metod och en kompletterande utvärdering för varje möjligt resultat i syfte att få en global vision av tillämpligheten av PHS i Madrid. De främsta kriterierna som utsågs för att göra utvärderingen av uppsamlingssystems installationen var: avstånd till f loden, nederbörd, sluttning, markegenskaper och markanvändning. Dessa kriterier tillämpades genom en GIS-MCDA-metodik, och med hjälp av dessa verktygs synergi erhölls en lämplighetskarta för PHS-installationer. Två kriterie viktningar kommer att utföras för att utvärdera modellens robusthet och vilket även kommer att resultera i två olika lämplighetsscenarier. Diskussionen kommer bestå av en analys av resultaten med hänsyn till de två scenarierna, och föreslå de två lämpligaste lokaliseringsklustren som identifierats. Slutligen kommer slutsatsen att återspegla studiens viktigaste resultat och öppna dörren för ytterligare forskning i ämnet, såsom design, driftinfrastruktur, dräneringslogistikdistribution och andra modifieringar i Madrids nuvarande vattenledningssystem.

Rainwater Harvesting Systems

Pond Harvesting Systems

Nature-based facilities

Climate Change Adaptation

MCDA

ArcGIS

Madrid

Spain

Sustainable water management solutions

Regnvattenuppsamlingssystem

naturbaserade anläggningar

klimatanpassning

urban resiliens

MCDA

ArcGIS

Madrid

Spanien

lösningar för hållbar vattenhantering

Geotechnical Engineering

Geoteknik