MARC Record from marc_columbia

LEADER: 09787cam a2200373 a 4500
001 8067416
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008 100407t20102010njuab b 001 0 eng
010 $a 2010013928
019 $a632081736
020 $a9780470453612 (hbk.)
020 $a0470453613 (hbk.)
024 $a99939487436
035 $a(OCoLC)548651510$z(OCoLC)632081736
035 $a(OCoLC)ocn548651510
035 $a(NNC)8067416
035 $a8067416
040 $aDLC$cDLC$dYDX$dBTCTA$dYDXCP$dUKM$dCDX$dOrLoB-B
042 $apcc
050 00 $aTA170$b.S24 2010
082 00 $a710$222
100 1 $aSarté, S. Bry,$d1972-$0http://id.loc.gov/authorities/names/n2010021105
245 10 $aSustainable infrastructure :$bthe guide to green engineering and design /$cS. Bry Sarté.
260 $aHoboken, N.J. :$bWiley,$c[2010], ©2010.
300 $axix, 363 pages :$billustrations, maps ;$c24 cm
336 $atext$btxt$2rdacontent
337 $aunmediated$bn$2rdamedia
504 $aIncludes bibliographical references and index.
505 00 $tForeword /$rCliff Garten -- $gPART I.$tTHE PROCESS AND SYSTEMS OF SUSTAINABLE DESIGN -- $gChapter 1.$tThe Process of Sustainable Engineering Design -- $tCreating a New Paradigm for Design -- $tIntegrating Disciplines: Architects and Engineers -- $tThe Sustainable Design Team: An Engineer's Perspective -- $tDesign Drivers for Sustainable Infrastructure Systems -- $tProject Drivers -- $tEstablishing Project Values and Setting Goals -- $tDefining Desired Outcomes and Metrics -- $tCreating Frameworks and Action Plans -- $tDesign Strategies -- $tImplementing the Process -- $tApplying Integrative Design to Old Mint Plaza -- $tGoal Setting at Aquatera, Florida -- $gChapter 2.$tSustainable Infrastructure Frameworks -- $tEstablishing a Framework -- $tGreen Building Rating Systems: Helping or Hurting? An Architect's Perspective -- $tUsing Sustainable Infrastructure Frameworks -- $tUsing Frameworks for Different Types of Development -- $gFramework #1.$tPillars of Sustainability -- $tPillars of Sustainability at the Great Wall Eco-Villages -- $tPlaNYC: Pillars of Sustainability in Action -- $gFramework #2.$tThe Scale-Density Framework -- $tApplying the Scale-Density Framework to New Development -- $gFramework #3.$tThe Transect -- $tUsing the Transect to Redevelop Tehachapi -- $tAIA/COTE Ten Measures of Sustainable Design -- $gFramework #4.$tThe Built Form-Ecology Framework -- $tBalancing Human and Ecological Development on the Santa Lucia Preserve -- $tEcosystem Services -- $tSynergy and Sustainable Community Design -- $tOne Planet Living Framework: Sonoma Mountain Village -- $tNotes -- $gPART II.$tSUSTAINABLE RESOURCE SYSTEMS -- $gChapter 3.$tWater Conservation and Supply -- $tThe Aspen Institute: Energy and Environment Program -- $tWater Management Plans -- $tAchieving Water Balance -- $tLooking at a Water Balance for a Retreat Center -- $tWater Balance on the "Ahwahnee" Project -- $tThe Living Building Challenge: Water -- $tAnalyzing Water Sources -- $tGroundwater -- $tSurface Water -- $tRainwater -- $tBrackish Water -- $tSeawater -- $tStormwater -- $tWater Supply Strategies -- $tReduce Demand/Conserve Water -- $tImprovements to Infrastructure -- $tExpansion of Existing Water Resources -- $tResidential Rainwater Harvesting in Sausalito -- $tNotes -- $gChapter 4.$tIntegrated Water Management -- $tWater as Resource, Not Waste Product -- $tImpacts of Modern Wastewater Practice -- $tRedefining Wastewater -- $tIntegrated Stormwater Management -- $tEffects of Development on Stormwater Runoff -- $tLow-Impact Development Design Principles -- $tBenefits of LID Stormwater Management -- $tOrder of Design Operations -- $tUrban Stormwater Treatment Strategies in San Mateo County -- $tUrban Stormwater Treatment Strategies -- $tExtensive Stormwater Treatment Systems -- $tAddressing Constraints and Barriers to Implementation -- $tInadequate Local Resources -- $tCost -- $tPhysical Site Constraints -- $tUtility Conflicts -- $tMaintenance Burden -- $tOld Mint Plaza -- $tSan Francisco's Urban Watershed Planning Charrette -- $tGraywater Treatment and Reuse -- $tGraywater Quality Characterization -- $tPotential as an Alternative Water Source -- $tGraywater Reuse Systems -- $tKeys to the Long-Term Success of a Graywater System -- $tBerkeley EcoHouse -- $tHillside Residence -- $tIntegrating Graywater into a Water Resources Master Plan -- $tSystem Process and Components -- $tBlackwater Management Approaches -- $tBlackwater Treatment Levels -- $tTreatment Technologies -- $tBlackwater Reuse Potential -- $tShifting the Water Treatment Paradigm -- $tNotes -- $gChapter 5.$tEnergy and Greenhouse Gases -- $tReducing Demand through Design -- $tReducing Energy Use in Buildings -- $tPassive Design Strategies -- $tUsing Energy Efficiently -- $tEnergy-Efficient Systems for Communities -- $tAccounting for Water as an Energy Use -- $tReducing Demand through Transportation Changes -- $tDesigning Sustainable Power Supplies -- $tSolar Power -- $tPhotovoltaics -- $tSolar Thermal -- $tWind Power -- $tGeothermal Systems -- $tBiomass -- $tBiogas -- $tWater Power -- $tAddressing Climate Change and Reducing Carbon Footprint -- $tMeasuring a Project's Carbon Footprint -- $tReducing a Project's Carbon Impact -- $tDeveloping Carbon-Neutrality Management Plans -- $tPolicy Measures for Increasing Energy Security and Efficiency -- $tSetting Caps -- $tNet Metering -- $tRenewable Energy Certificates -- $tGreen Power Programs -- $tIncentive Programs -- $tRegional Power Purchasing Agreements -- $tBuilding-Scale Financing Options -- $tUtility Profit Decoupling Strategies -- $tEfficiency Incentives and Requirements -- $tDesign Guidelines and Performance Standards -- $tEfficiency Programs and Standards -- $tPerformance Standards -- $tNotes -- $gChapter 6.$tSustainable Site Planning, Built Systems, and Material Flows -- $tSustainable Site Planning -- $tUnderstanding a Site as a Living System -- $tUnderstanding Natural Patterns -- $tAnalysis: Performing Contextual Background Studies -- $tSynthesis: Interpretation and Response -- $tGreen Streets and Transportation Networks -- $tComplete Streets -- $tTypical Street Types and Uses -- $tImplementing a Woonerf: Santa Monica Borderline -- $tImplementing Smart-Growth Streets -- $tGreen Streets -- $tChicago Green Alleys Program -- $tCity of Portland, Oregon, Green Streets Program -- $tWorking with the Land -- $tSensitive Streetscape Design -- $tSanta Lucia Preserve Street Design Process -- $tSensitive Site Design -- $tBalancing Earthwork Using Grading Analysis -- $tMaterial and Waste Flows -- $tEvaluating the Environmental Impact of Infrastructure Materials -- $tMaterials Red List -- $tChoosing Environmentally Appropriate Materials -- $tPost-Tensioning in Concrete Structures -- $tConstruction Methods and Management -- $tSolid Waste Management -- $tNotes -- $gPART III.$tDESIGN APPLICATIONS -- $gChapter 7.$tCity-Scale Approaches -- $tGuangzhou: City-Scale Transformation in China -- $tTianjin Eco-City Master Plan -- $tPlaNYC: An Integrated Stormwater Approach -- $tSan Francisco City Greening Initiatives -- $g1.$tSan Francisco Better Streets Plan -- $g2.$tUrban Forest Master Plan -- $g3.$tStormwater Design Guidelines -- $g4.$tSewer System Master Plan -- $g5.$tMission Streetscape Plan -- $g6.$tCesar Chavez Green Street Corridor -- $g7.$tOld Mint Plaza -- $g8.$tPavement to Parks Initiative -- $tThe Expressive Potential of Infrastructure -- $tNotes -- $gChapter 8.$tApplications for Sustainable Communities -- $tAchieving a Perfect Balance: Pearl Island, Panama -- $tGoing Beyond Engineering: Sharing Standards for Sustainability -- $tIntegrating Stormwater Strategies into the Transect at the Community Scale: Cattle Creek, Colorado -- $tStitching Together Lost Connections with Green Infrastructure -- $gChapter 9.$tBuilding-Scale Sustainable Infrastructure -- $tThe California Academy of Sciences, San Francisco, California -- $tCreating the New Academy -- $tChartwell School: Design Teaches Children to Celebrate Water and Energy -- $tPearl Island, Panama: Designing Buildings for Energy Savings -- $tSustainable Sites Initiative -- $tBrisbane City Hall: Green Site Design -- $tStanford University Green Dorm: A Living Laboratory -- $tPearl River Tower, Guangzhou, China -- $tNotes.
520 $a"As more factors, perspectives, and metrics are incorporated into the planning and building process, the roles of engineers and designers are increasingly being fused together. The Art of Eco-Engineering explores this tend with in-depth look at sustainable engineering practices in an urban design as it involves watershed master-planning, green building, optimizing water reuse, reclaiming urban spaces, green streets initiatives, and sustainable master-planning. This complete guide provides guidance on the role creative thinking and collaborative team-building play in meeting solutions needed to affect a sustainable transformation of the built environment"--$cProvided by publisher.
520 $a"In-depth look at sustainable engineering practices in an urban design context, this book offers guidance on developing strategies for implementing the complex solutions needed to affect a sustainable transformation of the built environment. With coverage of watershed master-planning, green building, optimizing water reuse, reclaiming urban spaces, green streets initiatives, and sustainable master-planning, the book supplements the core reference material with international examples and case studies"--$cProvided by publisher.
650 0 $aSustainable engineering.$0http://id.loc.gov/authorities/subjects/sh2006001869
650 0 $aSustainable design.$0http://id.loc.gov/authorities/subjects/sh2007001468
852 00 $boff,ave$hTA170$i.S24 2010g