Complex/dynamic systems and technologies are gaining traction in architecture, but accurate analysis and simulation of conflicting dynamic systems within a building model has yet to be achieved. Most ideas of analysis and simulation revolve around a set process: model one instance of a building (i.e. without changing parameters) and analyze in a separate program. The use of a parametric base for analysis/simulation plugins, as well as an easily manipulatable and responsive model would not only further the accuracy of testing the effects of multiple dynamic systems, but become a new tool that merges model, behavior, analysis and simulation to strive for efficient implementation of these technologies and act as a platform for testing systems’ compensation for introduced variables (bio-responsiveness, enviro-responsiveness, manipulability, system responsiveness). My method for testing this system utilizes Grasshopper, which excels at: providing a base for parametric plugins linking ‘static’ software, using data trees for complex behavioral modeling, and easing the manipulability of a parametric model. This method for analysis and optimization would facilitate the efficient implementation of dynamic/advanced/sustainable technologies in any number of building typologies

Rogler, Kurt

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Syracuse University Research Facility and Collaborative Environment

Syracuse University SURFACE Architecture Senior Theses School of Architecture Dissertations and Theses 5-2015 Energy Modeling and Implementation of Complex Building Systems, Pt. 2 Kurt Rogler Follow this and additional works at: https://surface.syr.edu/architecture_theses  Part of the Architecture Commons Recommended Citation Rogler, Kurt, "Energy Modeling and Implementation of Complex Building Systems, Pt. 2" (2015). Architecture Senior Theses. 306. https://surface.syr.edu/architecture_theses/306 This Thesis is brought to you for free and open access by the School of Architecture Dissertations and Theses at SURFACE. It has been accepted for inclusion in Architecture Senior Theses by an authorized administrator of SURFACE. For more information, please contact surface@syr.edu. 61603. Zoomed-in Scale: Analyzed with E+Seagram Building floor without context or EDDS.Analyzing People/Systems:The internal heat gains in each zone resulting from people (kWh).People GainsThe electric equipment energy needed for each zone in kWh.The electric lighting energy needed for each zone in kWh.Electric Equip. Energy Usage Electric Lighting Energy Usage63623. Zoomed-in Scale: Analyzed with E+Seagram Building floor without context or EDDS.1meter by 1meter grid of sensor points each provide a result post-analysis to be merged into an indoor radiant temperature map. Note the corridor penetrating the center of the building (with the least amount of area-to-glazing ratio). The cooler sensory points at the north corner of the building may be an anomaly, or an accurate representation of the cooler north-side zones. Indoor Radiant Temperature Map65643. Preliminary Results - No EDDSLooking at the results of a section of the Seagram BuildingLevel 1Level 2Level 3 Level 4Level 5Levels: 15 zones eachEnergyPlus provides results on a zone-by-zone basis, with data for each zone representable for every hour of the year (in this case, an averaged total hourly thermal energy required per zone per m2 per month per year).Diagram of results mapped out over timeJanuaryMaySeptemberFebruaryJuneOctoberMarchJulyNovemberAprilAugustDecember67664. Building & Zoomed-in ScaleSeagram Building and building section analyzed with a static instance of EDDS implemented.Seagram Building typical direct/diffuse daylighting levels analyzed without contextual influence. One instance of a non-moving EDDS facade is analyzed.Building Scale AnalysisTest of daylighting analysis in a space with two EDDS-like partitions. Context and building are not taken into account. This study represents an instance of light diffusing around temporary or potentially moving EDDS obstructions. Zoomed-in Analysis6968Behavioral Modeling - My ProposalPart 5 looks at applying a dynamic system to a building and building section, and analyze each’s impact on the space. 71705. Building Scale & Zoomed-in AnalysisSeagram Building Test building and zoomed-in model analyzed with a dynamic instance of EDDS implemented.Composite analysis of 5 facade iterations, meant to simulate EDDS movement. Building Scale AnalysisBehavior: Person walking in front of responsive EDDS facade. 7 points along the way compiled into a composite analysis.Zoomed-in Analysis7372What could a dynamic system, such as EDDS compensate for in a space/building?• Heat/Cooling/Lighting gains due to:• Increase of Occupants• Changing weather patterns• An influx of machines in a space (computers etc)• Changing thermal properties on nearby floors/in nearby zones• More…Systematic Compensation Example 1Building ScaleAnalysis with no EDDSResults: Of the 54990 m2 floor area, 7142 m2 day-litAverage 13.0% of floor is directly lit by sunDaylight Plugins for Grasshopper Honeybee, Ladybug, DIVA, Archsim, UrbanDaylightingResults*Analysis SoftwareEnergyPlus, Radiance, Daysim, EvalGlareEDDS responding to areas of too much direct lightingResultant simulationAfter the first simulation, the results are read and the new model rebuilds itself to accommodate the results: to lessen direct daylighting loads.Results: Of the 54990 m2 floor area, 4351 m2 day-lit areaAverage 7.9% of floor is directly lit by sun2792m/60% direct daylighting decrease from  non-EDDS analysisBehavioral Cues Environmental variables,Dynamic Systems,OccupantsDynamic SystemsTechnologies which respond to the analysis dataBehavioral Model Data trees, which contain each ‘frame’ of an action of a changing elementDaylight Plugins for Grasshopper Honeybee, Ladybug, DIVA, Archsim, UrbanDaylightingAnalysis SoftwareEnergyPlus, Radiance, Daysim, EvalGlareResults*Parametric Model Accumulation of inputs, flexible in accordance with destination software7574Systematic Compensation Example 2Zoomed-in ScaleEDDS non-responsive patternBehavioral Cues Environmental variables,Dynamic Systems,OccupantsDynamic SystemsTechnologies which respond to the analysis dataBehavioral Model Data trees, which contain each ‘frame’ of an action of a changing elementParametric Model Accumulation of inputs, flexible in accordance with destination softwareEDDS responding to an occupant EDDS compensating for the previous responseBehavioral Cues Environmental variables,Dynamic Systems,OccupantsDynamic SystemsTechnologies which respond to the analysis dataBehavioral Model Data trees, which contain each ‘frame’ of an action of a changing elementDaylight Plugins for Grasshopper Honeybee, Ladybug, DIVA, Archsim, UrbanDaylightingDaylight Plugins for Grasshopper Honeybee, Ladybug, DIVA, Archsim, UrbanDaylightingAnalysis SoftwareEnergyPlus, Radiance, Daysim, EvalGlareAnalysis SoftwareEnergyPlus, Radiance, Daysim, EvalGlareResults* Results*Parametric Model Accumulation of inputs, flexible in accordance with destination softwareWhat could a dynamic system, such as EDDS compensate for in a space/building?• Heat/Cooling/Lighting gains due to:• Increase of Occupants• Changing weather patterns• An influx of machines in a space (computers etc)• Changing thermal properties on nearby floors/in nearby zones• More…7776Analysis Speculation:Example: Mean Radiant Temp AnalysisZones of Analysis (75)Time (in Months)A representation of the average radiant temperature in all zones over the span of a year (monthly values are determined from hourly results). Clearly the simulation shows that there is a rise in temperature during the summer months as is expected.The mean radiant temperature of each zone (degrees Celsius).Result diagram key:  Color key:No EDDS/Shaders - Actual AnalysisZones of Analysis (75)Zones of Analysis (75)Implementing any shading device, including a static instance of EDDS, would result in a decrease of average radiant temperatures during the summer months. Moving beyond static shading devices, however, we get into the territory of responsive systems. I speculate an improvement in average temperature during summer months with the implementation of a fully dynamic EDDS system. In this case, EDDS would respond to occupant movement, other systems, environmental cues etc.Static Instance of EDDS - Speculation Dynamic/Responsive EDDS - Speculation7978I hope to further develop a method for analyzing and simulating complex building systems in architecture. This method for analysis and optimization would facilitate the efficient implementation of dynamic/advanced/sustainable technologies in all building typologies.Moving Forward8180Daylight Plugins for Grasshopper Honeybee, Ladybug, DIVA, Archsim, UrbanDaylightingThermal/Systems Plugins for Grasshopper Honeybee, Ladybug, Archsim, GecoAnalysis SoftwareEnergyPlus, Radiance, Daysim, EvalGlareAnalysis SoftwareEnergyPlus, OpenStudio, EcotectResults*Parametric Model Accumulation of inputs, flexible in accordance with destination softwareSCENEGeometryLandscapeReflectance levelsMaterialsArtificial LightingShadingArea of InterestViewpointGrid of lighting/thermal sensor pointsSpace UsageProgramLighting requirementsThermal comfort req’sSchedulesSky ModelDateTimeLocationSky conditionWeather dataSolar RadiationHypothesis: Moving ForwardBehavioral Cues Environmental variables,Dynamic Systems,OccupantsDynamic SystemsTechnologies which respond to the analysis dataBehavioral Model Data trees, which contain each ‘frame’ of an action of a changing elementProposal: A New Grasshopper ComponentThe main potential of this research, I feel, is to create a method for implementing and analyzing dynamic systems in design. The proposal for bringing behavioral modeling into the parametric design realm might best be captured by creating a new grasshopper component which facilitates this idea.This component would separate dynamic input into data sets readable by EnergyPlus & Radiance.Bibliography:Dogan, T., Reinhart, C., & Michalatos, P. (2012). Urban Daylight Simulation: Calculating   the Daylit Area of Urban Designs. Fifth National Conference of IBPSA-USA.Hensel, Michael, Achim Menges, and Michael Weinstock. 2010. Emergent Technologies   and Design: Towards a Biological Paradigm for Architecture. 1 edition. Oxon,   U.K. ; New York, NY: Routledge.Herkel, S., & Reinhart, C. (2000). The Simulation of Annual Daylight Illuminance    Distributions. Energy and Buildings, 167-187.Jakubiec, J. A., & Reinhart, C. F. (2011). Integraing Daylight and Thermal Simulations   Using Rhionceros 3D, Daysim and Energyplus. 12th Conference of    International Building Performance Simulation Association.Jong, Kenneth A. de De, and Kenneth A. De Jong. 2002. Evolutionary Computation. 1st   edition. Cambridge, Mass: A Bradford Book.Loukissas, Yanni. 2012. Co-Designers: Cultures of Computer Simulation in Architecture.   1 edition. Abingdon, Oxon England ; New York, NY: Routledge.Malkawi, Ali, and Godfried Augenbroe, eds. 2004. Advanced Building Simulation. New   York: Routledge.Peters, Terri, and Brady Peters. 2013. Inside Smartgeometry: Expanding the Architectural  Possibilities of Computational Design. 1 edition. Chichester, West Sussex,   United Kingdom: Wiley.Probst, Maria Cristina Munari, and Christian Roecker. 2011. Architectural Integration   and Design of Solar Thermal Systems. Pap/Chrt edition. New York: EPFL Press.Rawn, Evan.“Emerging Voices: David Benjamin of The Living” 05 Oct 2014. ArchDaily.   Accessed 05 Nov 2014. <http://www.archdaily.com/?p=553776>Reas, Casey, and Chandler McWilliams. 2010. Form+Code in Design, Art, and    Architecture. 1st edition. New York: Princeton Architectural Press.Reinhart, C. (2012). Daylighting Lecture. MIT, Caimbridge, Massachusetts, USA.SuperJury PresentationSpring 2015Kurt RoglerAdvisor Bess KrietemeyerReal-Time Whole Building Performance Impacts of Occupant Interaction with Dynamic Façade SystemsModeling and Analyzing Unpredictable Building SystemsContention• IntroductionContention• Dynamic Facade Systems• Analysis Inputs• e Method• Soware Used• e Building Testbed• Single Zone Analysis• Multiple Zone Analysis• Building Visualizations• ConclusionsFloor Normalized ermal EnergyDaylighting % throughout the day500 kwh/m2/yr Heating30%0 kwh/m2/yr Heating0%By developing a new workow that links energy analysis tools to parametric modeling tools which can represent human behavior, we can better design and implement new building façade technologies that deal with a broader range of architectural performance criteria.Current tools don’t support analyzing unpredictable systems’ eects on buildings.Building performance analyses are usually centered around static resultant data and they don’t necessarily account for unpredictable human behavior. Problems:I contend:Part 1:Project BackgroundDynamic Glazing Systems• Introduction• Dynamic Facade SystemsExamples• Analysis Inputs• e Method• Soware Used• e Building Testbed• Single Zone Analysis• Multiple Zone Analysis• Building Visualizations• ConclusionsDynamic Glazing SystemsExample 1The Arab World Instituteby Jean Nouvel• Introduction• Dynamic Facade SystemsArab World Institute• Analysis Inputs• e Method• Soware Used• e Building Testbed• Single Zone Analysis• Multiple Zone Analysis• Building Visualizations• ConclusionsDynamic Glazing SystemsExample 2Syracuse Center of Excellenceby Toshiko Mori • Introduction• Dynamic Facade SystemsCenter of Excellence• Analysis Inputs• e Method• Soware Used• e Building Testbed• Single Zone Analysis• Multiple Zone Analysis• Building Visualizations• ConclusionsDynamic Glazing SystemsExample 3Homeostatic Facade Systemby Decker Yeadon LLC• Introduction• Dynamic Facade SystemsHomeostatic Facade System• Analysis Inputs• e Method• Soware Used• e Building Testbed• Single Zone Analysis• Multiple Zone Analysis• Building Visualizations• ConclusionsDynamic Glazing SystemsExample 4Electroactive Dynamic Display System (EDDS)by the Center for Architecture Science and Ecology• Introduction• Dynamic Facade SystemsEDDS• Analysis Inputs• e Method• Soware Used• e Building Testbed• Single Zone Analysis• Multiple Zone Analysis• Building Visualizations• ConclusionsDynamic Glazing SystemsExample 4 ContinuedEDDS detailsPatent #: US 8,134,112 B2• Introduction• Dynamic Facade SystemsEDDS• Analysis Inputs• e Method• Soware Used• e Building Testbed• Single Zone Analysis• Multiple Zone Analysis• Building Visualizations• ConclusionsGlass SubstrateTransparent Fixed ElectrodesTransparent Dielectric LayerAdhesive GlueAnchor LinesMovable Electrode Rolled Metalized Polymer-possibility for multiple layers• Contained within an IGU• Switches (rolls) easily• Default position is up• Low cost to fabricate/operate•  ~$10-$80 per 2 (electrochromic glass is $100+ per 2)• High voltage, low current systemAccommodates:• Solar tracking• Glare/Daylighing control• Design variability • Occupant interaction• Much more...Dynamic Glazing SystemsExample 4 ContinuedEDDS visualization• Introduction• Dynamic Facade SystemsEDDS• Analysis Inputs• e Method• Soware Used• e Building Testbed• Single Zone Analysis• Multiple Zone Analysis• Building Visualizations• ConclusionsDynamic Glazing SystemsExample 4 ContinuedOccupant Viewing & Privacy Screens• Introduction• Dynamic Facade SystemsEDDS• Analysis Inputs• e Method• Soware Used• e Building Testbed• Single Zone Analysis• Multiple Zone Analysis• Building Visualizations• ConclusionsDynamic Glazing SystemsExample 4 ContinuedOccupant Interaction• Introduction• Dynamic Facade SystemsEDDS• Analysis Inputs• e Method• Soware Used• e Building Testbed• Single Zone Analysis• Multiple Zone Analysis• Building Visualizations• ConclusionsDynamic Glazing SystemsExample 4 ContinuedSystem Compensation• Introduction• Dynamic Facade SystemsEDDS• Analysis Inputs• e Method• Soware Used• e Building Testbed• Single Zone Analysis• Multiple Zone Analysis• Building Visualizations• ConclusionsEDDS default state EDDS responding to an occupant EDDS compensating for the previous responseThe Traditional Building AnalysisC. Reinhart’s Daylighting Analysis Example• Introduction• Dynamic Facade Systems• Traditional AnalysisCurrent Method Used• e Method• Soware Used• e Building Testbed• Single Zone Analysis• Multiple Zone Analysis• Building Visualizations• ConclusionsSCENEGeometryLandscapeReflectance levelsMaterialsArtificial LightingShadingInputsArea of InterestViewpointGrid of sensor pointsSpace UsageProgramLighting requirementsSchedulesSky ModelDateTimeLocationSky conditionWeather dataModel Analysis & SimulationDaylight Simulation EngineRaytracing RadiositySimulation Outcome Performance metricsVisualizationsIntermediate ResultsIlluminances LuminancesResults ProcessorFixed Model 

Energy Modeling and Implementation of Complex Building Systems, Pt. 2

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Energy Modeling and Implementation of Complex Building Systems, Pt. 2

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