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Subscribe What's trending on Access Water Water and Wastewater Systems Cybersecurity--2021 State of the Sector Author(s)Water Sector Coordinating CouncilDocument typeTechnical ReportPrint publication date Jun, 2021Volume / Issue First / last page(s)1 - 22Copyright2021Word count200Subject keywordsOperationsCybersecurityInformation TechnologyOperational TechnologySupply Chain IntegrityRisk ManagementIndustrial Water Reclamation and Reuse to Minimize Liquid Discharge Publisher Site This book serves as a comprehensive summary of water reclamation technologies and practices for minimizing liquid discharge for a broad range of industries. It is of use to practitioners, consultants, management, and research and development professionals who want a timely update on the technologies in use and on those technologies on the horizon to provide the highest rates of water recovery in industrial practice. The industrial sectors covered include oil and gas (unconventional oil and gas and produced and petroleum refining water), pharmaceutical, textile, automotive, manufacturing, energy, and food and beverage. The book covers a much broader perspective than North America, including technology development and sustainable applications within the water-scarce yet growing regions of Central and South America, Asia, and the Middle East.Author(s)Water Environment FederationSourceTechnical Practice CommitteeProject IDW110077CommitteePrepared by the Industrial Water Reclamation and Reuse to Minimize Liquid Discharge Task Force of the Water Environment Federation, under the Direction of the Industrial Wastewater Subcommittee of the Technical Practice CommitteeDocument typeDigital BookPublisherWater Environment FederationPrint publication date May, 2021Print ISBN 978-1-57278-360-7EISBN 9781572783607Volume / Issue1 / 1First / last page(s)i - 522Copyright2021Word count166,5082020 National Municipal Separate Storm Sewer System (MS4) Needs Assessment Survey ResultsBased on input from leading stormwater professionals, the Water Environment Federation (WEF) Stormwater Institute (SWI) developed Rainfall to Results: The Future of Stormwater. The report detailed the challenges, opportunities, and pathways to improving the nation’s stormwater systems to make them more efficient, effective, and sustainable. The report also developed a vision for the future of stormwater: Plus, the report identified six objectives that are central to supporting the future of stormwater vision. To begin working toward these objectives, the SWI conducted national assessment surveys of municipal separate storm sewer system (MS4) permittees in 2018 and again in 2020. This report details the results.Author(s)Water Environment FederationSourceWater Environment FederationCommitteeStormwater InstituteDocument typeTechnical ReportPublisherWater Environment FederationPrint publication date Feb, 2021Volume / Issue Content sourceStormwater InstituteFirst / last page(s)1 - 34Word count13Subject keywordsStormwaterMS4Municipal Separate Storm Sewer SystemUnderstanding Polymer For Thickening And Dewatering ProcessesPolymers are excellent flocculants and are critical for use as a solids conditioner prior to thickening and dewatering equipment. Applying polymer prior to a thickening or dewatering process, or “conditioning”, is often a requirement for the thickening or dewatering equipment to successfully operate. This operator fact sheet takes readers through the basics of polymers used in thickening and dewatering processes. You will learn about different types of polymer products, how to calculate polymer dose, appropriate handling and storage of polymer products, and equipment and processes relating to make-down and activation. This information can help operators make informed decisions to save money on polymer use in water resource recovery facilities (WRRFs).Author(s)Water Environment FederationContributing authorsHeidi BauerYong KimSourceWater Environment FederationDocument typeFact SheetPublisherWater Environment FederationPrint publication date Jun, 2020Volume / Issue Content sourceOperator Initiative Advisory PanelWord count8Subject keywordswastewatertrainingfundamentalspolymerthickeningdewateringflocculationflocculantsconditioningmathOperationOperator TrainingOperatorChapter 8 of Safety, Health and Security in Wastewater Systems, MOP 1, 6th EditionSince the Triangle Shirtwaist Factory fire in 1911, health and safety has been an upfront management tool spoken in the same context as productivity, quality, and cost. The fire showed that fatalities and injuries, if prevented, have a direct effect on the bottom line and the workforce.This Manual of Practice will serve as an injury-reduction tool to all those working in the wastewater field. There are guidelines for creating written programs and procedures as well as guidelines that describe how to perform a confined space entry, lockout/tagout, and chemical deliveries. From the laboratory to sewer system collection applications, this manual has recommendations that could help you reduce injuries and mishaps to ensure the ultimate safety of employees.Author(s)Water Environment FederationSourceMOP from Water Enviornment FederationCommitteeSafety, Health and Security in Wastewater Systems task force of WEFDocument typeDigital BookPublisherWater Environment FederationPrint publication date Sep, 2013Volume / Issue First / last page(s)1 - 385Copyright2013Word count132Subject keywordsWastewaterPPEvirusparasiteinfectionbiological hazardspathogenAerosolEvolution of Poly- and Perfluoroalkyl Substances (PFAS) Management: Holistic Approach to Understanding and Reducing PFAS DischargeWEFTEC, the largest event of its kind in North America, offers water quality professionals the best in water quality education and training. With almost 200 technical sessions, workshops, mobile sessions, local facility tours and 1,000+ exhibitors, it is the premier water conference! The WEFTEC technical program is selected through a rigorous, peer-review process, ensuring that attendees experience the highest-quality education. WEFTEC speakers are experts and innovators, leading the way in water quality. The following paper was presented at WEFTEC 2019.Author(s)J. EgliM.R. HicksSourceProceedings of the Water Environment FederationSubject212 Knowledge Development Forum: What are PFAS and What Do We Need to Know?Document typeConference PaperPublisherWater Environment FederationPrint publication date Sep, 2019ISSN1938-6478DOI10.2175/193864718825156943Volume / Issue Content sourceWEFTECCopyright2019Word count2,550Subject keywordsDisinfectionAssociated keywords:Industrial Issues, Including Mining and Petro-Chemical IndustriesInteractiveLaboratory PracticesFly, swim or crawl your way to safer work conditionsFor workers in the water sector, inherent workplace conditions expose them to daily potential for serious injury. Working in the confined spaces under city streets often comes with awkward postures, incessant vibrations, extreme temperatures, and hazardous gases that can injure. For workers dealing with chemicals or risking exposure to known viruses, bacteria, protozoa, and parasites, the risks become even more complicated. Physical inspection of tanks, pipes, and reservoirs — regardless of provided safety precautions — often require workers to step into environments that carry these risks as well as potential for catastrophic physical traumas.As a result, safety is a necessity. While strict adherence to departmental safety protocols and the proper deployment of personal protective equipment can reduce injuries, the only way to truly eliminate these types of injuries is to keep workers from entering those dangerous environments in the first place.However, such a simple proposition, proves more difficult in real-world application. How does a utility actually inspect and repair small-diameter pipes, investigate sediment buildup in holding tanks, or evaluate a collapsed pipe or sewer tunnel without deploying personnel into that very dangerous situation?Historically, these projects often called for entire system segments to be taken off-line, tanks to be drained, or heavy equipment to dig up entire city blocks. Now, the burgeoning drone industry is bringing numerous purpose-built solutions to the aid of water and wastewater agencies looking for safer, more efficient, and more affordable options.Author(s)Marc GandillonSourceArticle of WE&T MagazineSubjectAutomation;Collection Systems;SafetyDocument typeMagazine ArticlePublisherWater Environment FederationPrint publication date Feb, 2019Volume / Issue31 / 2Content sourceWater Environment and Technology MagazineFirst / last page(s)32 - 35Copyright2019Word count1,480Subject keywordsdronesclosed-circuit televisionhigh-definition videoinfraredsensors3D modelsremote operated vehiclesEmergency Planning, Response, and RecoveryEmergency Planning, Response, and Recovery will help your utility develop an emergency response plan to recover from events such as infrastructure failure, small- and large-scale natural disasters, and human-created incidents. Includes case studies from around the world.Author(s)Water Environment FederationDocument typeDigital BookPublisherWater Environment FederationPrint publication date Jul, 2013Volume / Issue2013 Word count85,641A Convenient Spreadsheet-Based Thermal Model for Heat Recovery and Effluent CoolingThe prime objective of this work was to identify the major sources of internal heat generation and locations within the water recovery facility that provide the most potential for heat dispersion to the atmosphere. A facility-wide thermal energy model applied to each unit process was developed, calibrated and validated at two water recovery facilities....Author(s)John BratbySourceProceedings of the Water Environment FederationSubject403 Process Modeling for Industrial Wastewater System Design and OptimizationDocument typeConference PaperPublisherWater Environment FederationPrint publication date Sep, 2018ISSN1938-6478SICI1938-6478(20180101)2018:13L.2465;1-DOI10.2175/193864718825136972Volume / Issue2018 / 13Content sourceWEFTECFirst / last page(s)2465 - 2483Copyright2018Word count208Subject keywordsTemperatureHeat recoveryHeat increaseCoolingCoversNitrification new to the platform Affordability of Wastewater ServiceAuthor(s)Water Environment FederationProject ID1-57278-185-8Document typeDigital BookPublisherWater Environment FederationPrint publication date Jan, 2007EISBN z1572781858Volume / Issue1 / 1First / last page(s)1 - 78Copyright2007Word count19,810Subject keywordsAffortabilityUtility ManagementOperationsAssociated keywords:BiosolidsDesignOperationsWastewater Biology: The Life Processes* DeceasedAuthor(s)Water Environment FederationProject ID1-881369-93-5Document typeDigital BookPublisherWater Environment FederationPrint publication date Jan, 1994EISBN 1-881369-93-5Volume / Issue1 / 1First / last page(s)1 - 210Copyright2002Word count58,293Subject keywordsWater and Wastewater TreatmentThird Century of Biochemical Oxygen DemandWater Environment FederationAuthor(s)Water Environment FederationProject ID1-57278-171-8Document typeDigital BookPublisherWater Environment FederationPrint publication date Jan, 2002EISBN 1572781718Volume / Issue1 / 1First / last page(s)1 - 408Copyright2002Word count168,791Subject keywordsWater and Wastewater TreatmentCombined Heat and Power MicroturbinesThis fact sheet provides a review of combined heat and power (CHP) technologies for use at water resource recovery facilities (WRRFs). CHP, also called “co-generation,” is defined as the concurrent production of electricity and thermal energy from a power-generating device. Individually, microturbines are on the smaller end of the spectrum of CHP units and, at 92 MW of total installed capacity, they only comprise 0.1% of the total CHP capacity in the United States (U.S. Department of Energy, 2015). Their small size and modular design allow for widespread applicability, and, in terms of number of CHP sites using microturbines as their chosen technology, microturbines comprise approximately 8% of the U.S. CHP market (U.S. Department of Energy, 2016). Microturbines make use of a Brayton cycle, where air is first drawn into the engine and compressed to high pressure by a radial compressor and is then mixed with fuel in the combustion chamber and continuously ignited. The compressed air is used to drive a turbine that provides torque to both the compressor drawing the air in and an electrical generator. Modern microturbines also make use of a recuperator stage, where hot exhaust air passes by the compressed air entering the combustion chamber, preheating the air before combustion and increasing thermal efficiency.Microturbines of 30 to 300 kW are an economical option, with the ability to parallel multiple modular units (U.S. Department of Energy, 2016). In December 2019, only 36 sites with a total capacity of 7.4 MW within the U.S. water resource recovery industry were demonstrating this technology and its economic benefits (U.S. Department of Energy, 2019). U.S. installations at WRRFs range in size from 30 kW to 1.6 MW (U.S. Department of Energy, 2019).Author(s)Water Environment FederationSourceResiduals and Biosolids CommitteeDocument typeFact SheetPublisherWater Environment FederationPrint publication date Jun, 2021Volume / Issue First / last page(s)1 - 11Copyright2021Word count6Subject keywordsWater and Wastewater TreatmentMicroturbinesCHPco-generationresiduals and biosolidsWastewater Biology: The HabitatsAuthor(s)Water Environment FederationProject ID1-57278-163-7Document typeDigital BookPublisherWater Environment FederationPrint publication date Jan, 2000EISBN 1572781637Volume / Issue1 / 1First / last page(s)1 - 127Copyright2000Word count42,326Subject keywordsWater and Wastewater TreatmentOccupational Health and Safety For Water Resource Recovery Facility DesignAuthor(s)Water Environment FederationDocument typeDigital BookPublisherWater Environment FederationPrint publication date Jan, 1998Volume / Issue1 / 1First / last page(s)1 - 34Copyright1998Word count10,666The Chlorination/Dechlorination HandbookThe Chlorination/Dechlorination HandbookAuthor(s)Water Environment FederationProject ID1-57278-174-2Document typeDigital BookPublisherWater Environment FederationPrint publication date Jan, 2002EISBN 1572781742Volume / Issue1 / 1First / last page(s)1 - 208Copyright2002Word count58,902Subject keywordsWater and Wastewater TreatmentGlosario de Replace with translation of English title below Engineering Water Resource Recovery Glossary Espafiol-IngiesPara obtener mayor información sobre cómo asociarse a la WEF, sus publicaciones y conferencias, sírvase contactara la:Author(s)Water Environment FederationProject ID1-57278-126-2Document typeDigital BookPublisherWater Environment FederationPrint publication date Jan, 1998EISBN 1572781262Volume / Issue1 / 1First / last page(s)1 - 207Copyright1998Word count85,051Subject keywordsBiosolids Resource RecoveryIndustrial Wastewater Management, Treatment, and Disposal (formerly Pretreatment of Industrial Wastes)Prepared by Industrial Wastewater Management, treatment, and disposal task Force of the Water environment FederationAuthor(s)Water Environment FederationSourcePrepared by Industrial Wastewater Management, Treatment, and Disposal Task Force of the Water Environment Federation Under the Direction of the Industrial and Hazardous Wastes Subcommittee of the Technical Practice CommitteeProject ID978-0-07-159238-3Document typeDigital BookPublisherWater Environment FederationPrint publication date Jan, 2008EISBN 9780071592383Volume / Issue1 / 1First / last page(s)1 - 568Copyright2008Word count164,473Subject keywordsIndustrial Water ResourcesWeak-In Worked OutA common problem for achieving biological phosphorus removal at small facilities is weak influent. Conventional BNR requires an ample source of readily degradable organic material in the wastewater to drive the biochemical reactions that convert nitrate to nitrogen gas and dissolved phosphorus to particulates. Unfortunately, many wastewaters do not have sufficient carbon for nutrient removal. Effective process control is one of the keys to overcoming this problem to make the proper adjustments to the wastewater treatment tanks to avoid noncompliance.Author(s)Jon van DommelenSubjectbilogical treatment; nutrient controlDocument typeArticlesPublisherWater Environment FederationPrint publication date Jun, 2021Volume / Issue33 / 6Content sourceWE&T magazineFirst / last page(s)48 - 52Copyright2021Word count2,456Subject keywordsdataloggingmonitoringdissolved oxygenBNR