%0 Journal Article %J Science of The Total Environment %D 2019 %T Assessment of occupant-behavior-based indoor air quality and its impacts on human exposure risk: A case study based on the wildfires in Northern California %A Luo, Na %A Weng, Wenguo %A Xu, Xiaoyu %A Tianzhen Hong %A Fu, Ming %A Sun, Kaiyu %K computational fluid dynamics siumlation %K human exposure risk %K indoor air quality %K NAPA wildfire %K occupant behavior %K respiratory injury %X

The recent wildfires in California, U.S., have caused not only significant losses to human life and property, but also serious environmental and health issues. Ambient air pollution from combustion during the fires could increase indoor exposure risks to toxic gases and particles, further exacerbating respiratory conditions. This work aims at addressing existing knowledge gaps in understanding how indoor air quality is affected by outdoor air pollutants during wildfires—by taking into account occupant behaviors (e.g., movement, operation of windows and air-conditioning) which strongly influence building performance and occupant comfort. A novel modeling framework was developed to simulate the indoor exposure risks considering the impact of occupant behaviours by integrating building energy and occupant behaviour modeling with computational fluid dynamics simulation. Occupant behaviors were found to exert significant impacts on indoor air flow patterns and pollutant concentrations, based on which, certain behaviors are recommended during wildfires. Further, the actual respiratory injury level under such outdoor conditions was predicted. The modeling framework and the findings enable a deeper understanding of the actual health impacts of wildfires, as well as informing strategies for mitigating occupant health risk during wildfires

%B Science of The Total Environment %V 686 %P 1251 - 1261 %8 Jan-10-2019 %G eng %! Science of The Total Environment %R 10.1016/j.scitotenv.2019.05.467 %0 Journal Article %J Applied Energy %D 2018 %T Bidirectional low temperature district energy systems with agent-based control: Performance comparison and operation optimization %A Felix Bunning %A Michael Wetter %A Marcus Fuchs %A Dirk Muller %B Applied Energy %V 209 %G eng %2 2001090 %R 10.1016/j.apenergy.2017.10.072 %0 Journal Article %J Sustainability %D 2018 %T Performance-Based Evaluation of Courtyard Design in China’s Cold-Winter Hot-Summer Climate Regions %A Xiaodong Xu %A Fenlan Luo %A Wei Wang %A Tianzhen Hong %A Xiuzhang Fu %K aspect ratio %K courtyard design %K ecological buffer area %K ecological effect %K layout %X

Evaluates the performance of the traditional courtyard design of the Jiangnan Museum, located in Jiangsu Province. In the evaluation, the spatial layout of courtyards is adjusted, the aspect ratio is changed, and an ecological buffer space is created. To model and evaluate the performance of the courtyard design, this study applied the Computational fluid dynamics (CFD) software, Parabolic Hyperbolic Or Elliptic Numerical Integration Code Series (PHOENICS), for wind environment simulation, and the EnergyPlus-based software, DesignBuilder, for energy simulation. Results show that a good combination of courtyard layout and aspect ratio can improve the use of natural ventilation by increasing free cooling during hot summers and reducing cold wind in winters. The results also show that ecological buffer areas of a courtyard can reduce cooling loads in summer by approximately 19.6% and heating loads in winter by approximately 22.3%. The study provides insights into the optimal design of a courtyard to maximize its benefit in regulating the microclimate during both winter and summer.

%B Sustainability %V 10 %P 3950 %8 10/2018 %G eng %U http://www.mdpi.com/2071-1050/10/11/3950http://www.mdpi.com/2071-1050/10/11/3950/pdf %N 11 %! Sustainability %R 10.3390/su10113950 %0 Journal Article %J Energy Conversion and Management %D 2017 %T Dynamic equation-based thermo-hydraulic pipe model for district heating and cooling systems %A Brahm van der Heijde %A Marcus Fuchs %A Carles Ribas Tugores %A Gerald Schweiger %A Kevin Sartor %A Daniele Basciotti %A Dirk Muller %A Christoph Nytsch-Geusen %A Michael Wetter %A Lieve Helsen %X

Simulation and optimisation of district heating and cooling networks requires efficient and realistic models of the individual network elements in order to correctly represent heat losses or gains, temperature propagation and pressure drops. Due to more recent thermal networks incorporating meshing decentralised heat and cold sources, the system often has to deal with variable temperatures and mass flow rates, with flow reversal occurring more frequently. This paper presents the mathematical derivation and software implementation in Modelica of a thermo-hydraulic model for thermal networks that meets the above requirements and compares it to both experimental data and a commonly used model. Good correspondence between experimental data from a controlled test set-up and simulations using the presented model was found. Compared to measurement data from a real district heating network, the simulation results led to a larger error than in the controlled test set-up, but the general trend is still approximated closely and the model yields results similar to a pipe model from the Modelica Standard Library. However, the presented model simulates 1.7 (for low number of volumes) to 68 (for highly discretized pipes) times faster than a conventional model for a realistic test case. A working implementation of the presented model is made openly available within the IBPSA Modelica Library. The model is robust in the sense that grid size and time step do not need to be adapted to the flow rate, as is the case in finite volume models.

%B Energy Conversion and Management %V 151 %G eng %2 2001049 %R 10.1016/j.enconman.2017.08.072 %0 Journal Article %J Energy and Building %D 2017 %T IEA EBC Annex 66: Definition and simulation of occupant behavior in buildings %A Da Yan %A Tianzhen Hong %A Bing Dong %A Ardeshir Mahdavi %A Simona D'Oca %A Isabella Gaetani %A Xiaohang Feng %K building performance %K energy modeling %K energy use %K IEA EBC Annex 66 %K Interdisciplinary approach %K occupant behavior %X

More than 30% of the total primary energy in the world is consumed in buildings. It is crucial to reduce building energy consumption in order to preserve energy resources and mitigate global climate change. Building performance simulations have been widely used for the estimation and optimization of building performance, providing reference values for the assessment of building energy consumption and the effects of energy-saving technologies. Among the various factors influencing building energy consumption, occupant behavior has drawn increasing attention. Occupant behavior includes occupant presence, movement, and interaction with building energy devices and systems. However, there are gaps in occupant behavior modeling as different energy modelers have employed varied data and tools to simulate occupant behavior, therefore producing different and incomparable results. Aiming to address these gaps, the International Energy Agency (IEA) Energy in Buildings and Community (EBC) Programme Annex 66 has established a scientific methodological framework for occupant behavior research, including data collection, behavior model representation, modeling and evaluation approaches, and the integration of behavior modeling tools with building performance simulation programs. Annex 66 also includes case studies and application guidelines to assist in building design, operation, and policymaking, using interdisciplinary approaches to reduce energy use in buildings and improve occupant comfort and productivity. This paper highlights the key research issues, methods, and outcomes pertaining to Annex 66, and offers perspectives on future research needs to integrate occupant behavior with the building life cycle.

%B Energy and Building %V 156 %G eng %R 10.1016/j.enbuild.2017.09.084 %0 Report %D 2017 %T Small and Medium Building Efficiency Toolkit and Community Demonstration Program %A Mary Ann Piette %A Tianzhen Hong %A William J. Fisk %A Norman Bourassa %A Wanyu R. Chan %A Yixing Chen %A H.Y. Iris Cheung %A Toshifumi Hotchi %A Margarita Kloss %A Sang Hoon Lee %A Phillip N. Price %A Oren Schetrit %A Kaiyu Sun %A Sarah C. Taylor-Lange %A Rongpeng Zhang %K CBES %K commercial buildings %K energy efficiency %K energy modeling %K energy savings %K indoor air quality %K indoor environmental quality %K outdoor air measurement technology %K outdoor airflow intake rate %K retrofit %K ventilation rate %X

Small commercial buildings in the United States consume 47 percent of all primary energy consumed in the building sector. Retrofitting small and medium commercial buildings may pose a steep challenge for owners, as many lack the expertise and resources to identify and evaluate cost-effective energy retrofit strategies. To address this problem, this project developed the Commercial Building Energy Saver (CBES), an energy retrofit analysis toolkit that calculates the energy use of a building, identifies and evaluates retrofit measures based on energy savings, energy cost savings, and payback. The CBES Toolkit includes a web app for end users and the CBES Application Programming Interface for integrating CBES with other energy software tools. The toolkit provides a rich feature set, including the following:

  1. Energy Benchmarking providing an Energy Star score
  2. Load Shape Analysis to identify potential building operation improvements
  3. Preliminary Retrofit Analysis which uses a custom developed pre-simulated database
  4. Detailed Retrofit Analysis which utilizes real time EnergyPlus simulations

In a parallel effort the project team developed technologies to measure outdoor airflow rate; commercialization and use would avoid both excess energy use from over ventilation and poor indoor air quality resulting from under ventilation.

If CBES is adopted by California’s statewide small office and retail buildings, by 2030 the state can anticipate 1,587 gigawatt hours of electricity savings, 356 megawatts of non-coincident peak demand savings, 30.2 megatherms of natural gas savings, $227 million of energy-related cost savings, and reduction of emissions by 757,866 metric tons of carbon dioxide equivalent. In addition, consultant costs will be reduced in the retrofit analysis process.

CBES contributes to the energy savings retrofit field by enabling a straightforward and uncomplicated decision-making process for small and medium business owners and leveraging different levels of assessment to match user background, preference, and data availability.

%8 03/2017 %G eng %2 LBNL-2001054 %R 10.7941/S93P70 %0 Journal Article %J Energy and Buildings %D 2016 %T The Impact of Evaporation Process on Thermal Performance of Roofs - Model Development and Numerical Analysis %A Lei Zhang %A Rongpeng Zhang %A Yu Zhang %A Tianzhen Hong %A Qinglin Meng %A Yanshan Feng %K Evaporative Cooling %K model development %K Net zero energy building %K Numerical analysis %K Passive techniques %K Porous building material %K Roof thermal performance %B Energy and Buildings %G eng %0 Journal Article %D 2015 %T Design choices for thermofluid flow components and systems that are exported as Functional Mockup Units %A Michael Wetter %A Marcus Fuchs %A Thierry Stephane Nouidui %X

This paper discusses design decisions for exporting Modelica thermofluid flow components as Functional Mockup Units. The purpose is to provide guidelines that will allow building energy simulation programs and HVAC equipment manufacturers to effectively use FMUs for modeling of HVAC components and systems. We provide an analysis for direct input-output dependencies of such components and discuss how these dependencies can lead to algebraic loops that are formed when connecting thermofluid flow components. Based on this analysis, we provide recommendations that increase the computing efficiency of such components and systems that are formed by connecting multiple components. We explain what code optimizations are lost when providing thermofluid flow components as FMUs rather than Modelica code. We present an implementation of a package for FMU export of such components, explain the rationale for selecting the connector variables of the FMUs and finally provide computing benchmarks for different design choices. It turns out that selecting temperature rather than specific enthalpy as input and output signals does not lead to a measurable increase in computing time, but selecting nine small FMUs rather than a large FMU increases computing time by 70%

%2 LBNL-1002826 %0 Journal Article %J Energy and Buildings %D 2015 %T Occupant Behavior Modeling for Building Performance Simulation: Current State and Future Challenges %A Da Yan %A William O'Brien %A Tianzhen Hong %A Xiaohang Feng %A H. Burak Gunay %A Farhang Tahmasebi %A Ardeshir Mahdavi %K building simulation %K energy efficiency %K energy modeling %K energy use %K occupant behavior %X

Occupant behavior is now widely recognized as a major contributing factor to uncertainty of building performance. While a surge of research on the topic has occurred over the past four decades, and particularly the past few years, there are many gaps in knowledge and limitations to current methodologies. This paper outlines the state-of-the-art research, current obstacles and future needs and directions for the following four-step iterative process: (1) occupant monitoring and data collection, (2) model development, (3) model evaluation, and (4) model implementation into building simulation tools. Major themes include the need for greater rigor in experimental methodologies; detailed, honest, and candid reporting of methods and results; and development of an efficient means to implement occupant behavior models and integrate them into building energy modeling programs.

%B Energy and Buildings %V 107 %P 264-278 %8 11/2015 %2 LBNL-1004504 %R 10.1016/j.enbuild.2015.08.032 %0 Journal Article %J Energy and Buildings %D 2015 %T Simulation of Occupancy in Buildings %A Xiaohang Feng %A Da Yan %A Tianzhen Hong %K building simulation %K co-simulation %K occupancy %K occupant behavior %K software module %K stochastic modeling %X

Occupants are involved in a variety of activities in buildings, which drive them to move among rooms, enter or leave a building. In this study, occupancy is defined at four levels and varies with time: (1) the number of occupants in a building, (2) occupancy status of a space, (3) the number of occupants in a space, and (4) the space location of an occupant. Occupancy has a great influence on internal loads and ventilation requirement, thus building energy consumption. Based on a comprehensive review and comparison of literature on occupancy modeling, three representative occupancy models, corresponding to the levels 2–4, are selected and implemented in a software module. Main contributions of our study include: (1) new methods to classify occupancy models, (2) the review and selection of various levels of occupancy models, and (3) new methods to integrate these model into a tool that can be used in different ways for different applications and by different audiences. The software can simulate more detailed occupancy in buildings to improve the simulation of energy use, and better evaluate building technologies in buildings. The occupancy of an office building is simulated as an example to demonstrate the use of the software module.

%B Energy and Buildings %V 87 %P 348-359 %8 01/2015 %2 LBNL-180424 %R 10.1016/j.enbuild.2014.11.067 %0 Journal Article %J Energy and Buildings %D 2014 %T Comparison of Building Energy Use Data Between the United States and China %A Jianjun Xia %A Tianzhen Hong %A Qi Shen %A Wei Feng %A Le Yang %A Piljae Im %A Alison Lu %A Mahabir Bhandari %K buildings %K comparison %K data analysis %K data model %K Energy benchmarking %K energy monitoring system %K energy use %K retrofit %X

Buildings in the United States and China consumed 41% and 28% of the total primary energy in 2011, respectively. Good energy data are the cornerstone to understanding building energy performance and supporting research, design, operation, and policy making for low energy buildings. This paper presents initial outcomes from a joint research project under the U.S.–China Clean Energy Research Center for Building Energy Efficiency. The goal is to decode the driving forces behind the discrepancy of building energy use between the two countries; identify gaps and deficiencies of current building energy monitoring, data collection, and analysis; and create knowledge and tools to collect and analyze good building energy data to provide valuable and actionable information for key stakeholders. This paper first reviews and compares several popular existing building energy monitoring systems in both countries. Next a standard energy data model is presented. A detailed, measured building energy data comparison was conducted for a few office buildings in both countries. Finally issues of data collection, quality, sharing, and analysis methods are discussed. It was found that buildings in both countries performed very differently, had potential for deep energy retrofit, but that different efficiency measures should apply.

%B Energy and Buildings %V 78 %P 165-175 %8 08/2014 %2 LBNL-6669E %R 10.1016/j.enbuild.2014.04.031 %0 Journal Article %J Applied Energy %D 2014 %T Data and Analytics to Inform Energy Retrofit of High Performance Buildings %A Tianzhen Hong %A Le Yang %A David Hill %A Wei Feng %K Analytics %K data model %K Energy benchmarking %K energy use %K High performance buildings %K retrofit %X

Buildings consume more than one-third of the world’s primary energy. Reducing energy use in buildings with energy efficient technologies is feasible and also driven by energy policies such as energy benchmarking, disclosure, rating, and labeling in both the developed and developing countries. Current energy retrofits focus on the existing building stocks, especially older buildings, but the growing number of new high performance buildings built around the world raises a question that how these buildings perform and whether there are retrofit opportunities to further reduce their energy use. This is a new and unique problem for the building industry. Traditional energy audit or analysis methods are inadequate to look deep into the energy use of the high performance buildings. This study aims to tackle this problem with a new holistic approach powered by building performance data and analytics. First, three types of measured data are introduced, including the time series energy use, building systems operating conditions, and indoor and outdoor environmental parameters. An energy data model based on the ISO Standard 12655 is used to represent the energy use in buildings in a three-level hierarchy. Secondly, a suite of analytics were proposed to analyze energy use and to identify retrofit measures for high performance buildings. The data-driven analytics are based on monitored data at short time intervals, and cover three levels of analysis – energy profiling, benchmarking and diagnostics. Thirdly, the analytics were applied to a high performance building in California to analyze its energy use and identify retrofit opportunities, including: (1) analyzing patterns of major energy end-use categories at various time scales, (2) benchmarking the whole building total energy use as well as major end-uses against its peers, (3) benchmarking the power usage effectiveness for the data center, which is the largest electricity consumer in this building, and (4) diagnosing HVAC equipment using detailed time-series operating data. Finally, a few energy efficiency measures were identified for retrofit, and their energy savings were estimated to be 20% of the whole-building electricity consumption. Based on the analyses, the building manager took a few steps to improve the operation of fans, chillers, and data centers, which will lead to actual energy savings. This study demonstrated that there are energy retrofit opportunities for high performance buildings and detailed measured building performance data and analytics can help identify and estimate energy savings and to inform the decision making during the retrofit process. Challenges of data collection and analytics were also discussed to shape best practice of retrofitting high performance buildings.

%B Applied Energy %I Elsevier %V 126 %P 90-106 %8 08/2014 %R 10.1016/j.apenergy.2014.03.052 %0 Report %D 2014 %T Development of Diagnostic and Measurement and Verification Tools for Commercial Buildings %A Philip Haves %A Craig P. Wray %A David A. Jump %A Daniel Veronica %A Christopher Farley %K application programming interface %K fault detection and diagnosis %K M&V %K Measurement and verification %K Universal Translator %X

This research developed new measurement and verification tools and new automated fault detection and diagnosis tools, and deployed them in the Universal Translator. The Universal Translator is a tool, developed by Pacific Gas and Electric, that manages large sets of measured data from building control systems and enables off‐line analysis of building performance. There were four technical projects following the program administration tasks identified as Project 1:

  1. Program Administration
  2. Methods and Tools to Reduce the Cost of Measurement and Verification.
  3. Fault Detection and Diagnostics for Commercial Heating, Ventilating, and Air‐ Conditioning Systems.
  4. Test Procedures and Tools to Characterize Fan and Duct System Performance in Large Commercial Buildings.
  5. Universal Translator Development: Integration of Application Programming Interface.

Project 1 consisted of administrative tasks related to the project.

Project 2 addressed the need for less expensive measurement and verification tools to determine the costs and benefits of retrofits and retro‐commissioning at both the individual building level and the utility program level.

Project 3 extended previous work on fault detection and diagnosis to additional systems and subsystems, including dual duct heating, ventilating and air‐conditioning systems and fan‐coil terminal units.

Project 4 combined previous work on duct leakage and fan modeling to develop a performance assessment method for existing fan/duct systems that could also be used in the analysis of retrofit measures identified by the tools in Projects 2 and 3 using the EnergyPlus simulation program to help select the most cost‐effective package of improvements.

Some of the diagnostic methods and tools developed in projects 2 through 4 were incorporated in the Universal Translator via a new application programming interface that was specified, developed and tested in Project 5. Combined, these tools support analyses of energy savings produced by new construction commissioning, retro‐commissioning, improved routine operations and code compliance. The new application programming interface could also facilitate future development, testing and deployment of new diagnostic tools.

%I California Energy Commission %8 09/2014 %2 LBNL-188324 %0 Report %D 2013 %T Building Energy Monitoring and Analysis %A Tianzhen Hong %A Wei Feng %A Alison Lu %A Jianjun Xia %A Le Yang %A Qi Shen %A Piljae Im %A Mahabir Bhandari %X

U.S. and China are the world's top two economics. Together they consumed one-third of the world's primary energy. It is an unprecedented opportunity and challenge for governments, researchers and industries in both countries to join together to address energy issues and global climate change. Such joint collaboration has huge potential in creating new jobs in energy technologies and services.

Buildings in the US and China consumed about 40% and 25% of the primary energy in both countries in 2010 respectively. Worldwide, the building sector is the largest contributor to the greenhouse gas emission. Better understanding and improving the energy performance of buildings is a critical step towards sustainable development and mitigation of global climate change.

This project aimed to develop a standard methodology for building energy data definition, collection, presentation, and analysis; apply the developed methods to a standardized energy monitoring platform, including hardware and software, to collect and analyze building energy use data; and compile offline statistical data and online real-time data in both countries for fully understanding the current status of building energy use. This helps decode the driving forces behind the discrepancy of building energy use between the two countries; identify gaps and deficiencies of current building energy monitoring, data collection, and analysis; and create knowledge and tools to collect and analyze good building energy data to provide valuable and actionable information for key stakeholders.

Key research findings were summarized as follows:

The research outputs from the project can help better understand energy performance of buildings, improve building operations to reduce energy waste and increase efficiency, identify retrofit opportunities for existing buildings, and provide guideline to improve the design of new buildings. The standardized energy monitoring and analysis platform as well as the collected real building data can also be used for other CERC projects that need building energy measurements, and be further linked to building energy benchmarking and rating/labeling systems.

%8 06/2013 %2 LBNL-6640E %0 Report %D 2012 %T Monitoring-based HVAC Commissioning of an Existing Office Building for Energy Efficiency %A Shankar Earni %A Spencer Woodworth %A Xiufeng Pang %A Jorge Hernandez-Maldonado %A Rongxin Yin %A Liping Wang %A Steve E. Greenberg %A John Fiegel %A Alma Rubalcava %K benchmarking %K commissioning %K energyplus %K fault detection and diagnostics %K functional testing %K trend data %X

The performance of Heating, Ventilation and Air Conditioning (HVAC) systems may fail to satisfy design expectations due to improper equipment installation, equipment degradation, sensor failures, or incorrect control sequences. Commissioning identifies and implements cost-effective operational and maintenance measures in buildings to bring them up to the design intent or optimum operation. An existing office building is used as a case study to demonstrate the process of commissioning. Building energy benchmarking tools are applied to evaluate the energy performance for screening opportunities at the whole building level. A large natural gas saving potential was indicated by the building benchmarking results. Faulty operations in the HVAC systems, such as improper operations of air-side economizers, simultaneous heating and cooling, and ineffective optimal start, were identified through trend data analyses and functional testing. The energy saving potential for each commissioning measure is quantified with a calibrated building simulation model. An actual energy saving of 10% was realized after the implementations of cost-effective measures.

%8 10/2012 %2 LBNL-5940E %0 Conference Paper %B ACEEE 2012 Summer Study %D 2012 %T A Retrofit Tool for Improving Energy Efficiency of Commercial Buildings %A Mark D. Levine %A Wei Feng %A Jing Ke %A Tianzhen Hong %A Nan Zhou %K building simulation %K buildings %K China %K commercial building %K energy efficiency measures %K retrofit tool %K simulation research group %X

Existing buildings will dominate energy use in commercial buildings in the United States for three decades or longer and even in China for the about two decades. Retrofitting these buildings to improve energy efficiency and reduce energy use is thus critical to achieving the target of reducing energy use in the buildings sector. However there are few evaluation tools that can quickly identify and evaluate energy savings and cost effectiveness of energy conservation measures (ECMs) for retrofits, especially for buildings in China. This paper discusses methods used to develop such a tool and demonstrates an application of the tool for a retrofit analysis. The tool builds on a building performance database with pre-calculated energy consumption of ECMs for selected commercial prototype buildings using the EnergyPlus program. The tool allows users to evaluate individual ECMs or a package of ECMs. It covers building envelope, lighting and daylighting, HVAC, plug loads, service hot water, and renewable energy. The prototype building can be customized to represent an actual building with some limitations. Energy consumption from utility bills can be entered into the tool to compare and calibrate the energy use of the prototype building. The tool currently can evaluate energy savings and payback of ECMs for shopping malls in China. We have used the tool to assess energy and cost savings for retrofit of the prototype shopping mall in Shanghai. Future work on the tool will simplify its use and expand it to cover other commercial building types and other countries. 

%B ACEEE 2012 Summer Study %C Asilomar, CA %8 08/2012 %G eng %U http://aceee.org/files/proceedings/2012/data/papers/0193-000098.pdf#page=1 %2 LBNL-6553E %0 Journal Article %J Building Simulation %D 2010 %T Assessment of Energy Savings Potential from the Use of Demand Control Ventilation Systems in General Office Spaces in California %A Tianzhen Hong %A William J. Fisk %K building simulation %K california building energy standard %K Commercial Building Ventilation and Indoor Environmental Quality Group %K demand controlled ventilation %K energy savings %K indoor environment department %K other %X

Demand controlled ventilation (DCV) was evaluated for general office spaces in California. A medium size office building meeting the prescriptive requirements of the 2008 California building energy efficiency standards (CEC 2008) was assumed in the building energy simulations performed with the EnergyPlus program to calculate the DCV energy savings potential in five typical California climates. Three design occupancy densities and two minimum ventilation rates were used as model inputs to cover a broader range of design variations. The assumed values of minimum ventilation rates in offices without DCV, based on two different measurement methods, were 81 and 28 cfm per occupant. These rates are based on the co‐author's unpublished analyses of data from EPA's survey of 100 U.S. office buildings. These minimum ventilation rates exceed the 15 to 20 cfm per person required in most ventilation standards for offices. The cost effectiveness of applying DCV in general office spaces was estimated via a life cycle cost analyses that considered system costs and energy cost reductions.

The results of the energy modeling indicate that the energy savings potential of DCV is largest in the desert area of California (climate zone 14), followed by Mountains (climate zone 16), Central Valley (climate zone 12), North Coast (climate zone 3), and South Coast (climate zone 6).

The results of the life cycle cost analysis show DCV is cost effective for office spaces if the typical minimum ventilation rates without DCV is 81 cfm per person, except at the low design occupancy of 10 people per 1000 ft2 in climate zones 3 and 6. At the low design occupancy of 10 people per 1000 ft2, the greatest DCV life cycle cost savings is a net present value (NPV) of $0.52/ft2 in climate zone 14, followed by $0.32/ft2 in climate zone 16 and $0.19/ft2 in climate zone 12. At the medium design occupancy of 15 people per 1000 ft2, the DCV savings are higher with a NPV $0.93/ft2 in climate zone 14, followed by $0.55/ft2 in climate zone 16, $0.46/ft2 in climate zone 12, $0.30/ft2 in climate zone 3, $0.16/ft2 in climate zone 3. At the high design occupancy of 20 people per 1000 ft2, the DCV savings are even higher with a NPV $1.37/ft2 in climate zone 14, followed by $0.86/ft2 in climate zone 16, $0.84/ft2 in climate zone 3, $0.82/ft2 in climate zone 12, and $0.65/ft2 in climate zone 6.

DCV was not found to be cost effective if the typical minimum ventilation rate without DCV is 28 cfm per occupant, except at high design occupancy of 20 people per 1000 ft2 in climate zones 14 and 16.

Until the large uncertainties about the base case ventilation rates in offices without DCV are reduced, the case for requiring DCV in general office spaces will be a weak case.

%B Building Simulation %I Lawrence Berkeley National Laboratory %C Berkeley %V 3 %P 117-124 %8 06/2010 %G eng %N 2 %9 Research Article %2 LBNL-3523E %R 10.1007/s12273-010-0001-8 %0 Journal Article %J ASHRAE Transactions %D 2010 %T Impacts of Static Pressure Reset on VAV System Air Leakage, Fan Power, and Thermal Energy %A Mingsheng Liu %A Jingjuan Feng %A Zhan Wang %A Keke Zheng %A Xiufeng Pang %B ASHRAE Transactions %V 116 %P 428-436 %G eng %N 1 %0 Journal Article %J Flow, Turbulence and Combustion %D 2009 %T Anisotropy invariant Reynolds stress model of turbulence (AIRSM) and its application on attached and separated wall-bounded flows %A V. Kumar %A Bettina Frohnapfel %A Jovan Jovanović %A Michael Breuer %A Wangda Zuo %A Ibrahim Hadzić %A Richard Lechner %K Anisotrpoy %K Invariant map %K Reynolds stress model %K Reynolds-averaged Navier-Stokes %K Separated wall-bounded flow %K Turbulence %K Turbulence modeling %X

Numerical predictions with a differential Reynolds stress closure, which in its original formulation explicitly takes into account possible states of turbulence on the anisotropy-invariant map, are presented. Thus the influence of anisotropy of turbulence on the modeled terms in the governing equations for the Reynolds stresses is accounted for directly. The anisotropy invariant Reynolds stress model (AIRSM) is implemented and validated in different finite-volume codes. The standard wall-function approach is employed as initial step in order to predict simple and complex wall-bounded flows undergoing large separation. Despite the use of simple wall functions, the model performed satisfactory in predicting these flows. The predictions of the AIRSM were also compared with existing Reynolds stress models and it was found that the present model results in improved convergence compared with other models. Numerical issues involved in the implementation and application of the model are also addressed.

%B Flow, Turbulence and Combustion %V 83 %P 81-103 %8 07/2009 %G eng %N 1 %& 81 %R 10.1007/s10494-008-9190-y %0 Conference Proceedings %B Proc. of the 7th International Modelica Conference %D 2009 %T Standardization of thermo-fluid modeling in Modelica.Fluid 1.0 %A Rüdiger Franke %A Francesco Casella %A Martin Otter %A Katrin Proelss %A Michael Sielemann %A Michael Wetter %K modelica %X

This article discusses the Modelica.Fluid library that has been included in the Modelica Standard Library 3.1. Modelica.Fluid provides interfaces and basic components for the device-oriented modeling of one dimensional thermo-fluid flow in networks containing vessels; pipes; fluid machines; valves and fittings.

A unique feature of Modelica.Fluid is that the component equations and the media models as well as pressure loss and heat transfer correlations are decoupled from each other. All components are implemented such that they can be used for media from the Modelica.Media library. This means that an incompressible or compressible medium; a single or a multiple substance medium with one or more phases might be used with one and the same model as long as the modeling assumptions made hold. Furthermore;

trace substances are supported. Modeling assumptions can be configured globally in an outer System object. This covers in particular the initialization; uni- or bi-directional flow; and dynamic or steady-state formulation of mass; energy; and momentum balance. All assumptions can be locally refined for every component.

While Modelica.Fluid contains a reasonable set of component models; the goal of the library is not to provide a comprehensive set of models; but rather to provide interfaces and best practices for the treatment of issues such as connector design and implementation of energy; mass and momentum balances. Applications from various domains are presented.

%B Proc. of the 7th International Modelica Conference %7 13 %I Linköping University Electronic Press %C Como, Italy %V 43 %8 09/2009 %@ 978-91-7393-513-5 %G eng %U http://www.ep.liu.se/ecp_article/index.en.aspx?issue=043;article=13 %R 10.3384/ecp0943 %0 Conference Paper %B the 7th International Conference of Enhanced Building Operations %D 2007 %T Economizer Control Using Mixed Air Enthalpy %A Jingjuan Feng %A Mingsheng Liu %A Xiufeng Pang %B the 7th International Conference of Enhanced Building Operations %S 7th %C San Francisco, CA %8 2007 %G eng %0 Conference Paper %B Proc. Building Simulation 2007 %D 2007 %T Use of Simulation Tools for Managing Buildings Energy Demand %A Alberto Hernandez %A Flávio Neto %A Augusto Sanzovo Fiorelli %B Proc. Building Simulation 2007 %C Beijing, China %8 09/2007 %G eng %0 Conference Proceedings %B IEEE CPMT International Symposium and Exhibition on Advanced Packaging Materials %D 2006 %T Carbon Nanotube (CNT)-Centric Thermal Management of Future High Power Microprocessors %A Prajesh Bhattacharya %A Wei, X. %A Andrei G. Fedorov %A Yogendra K. Joshi %A Navdeep Bajwa %A Anyuan Cao %A Pulickel Ajayan %B IEEE CPMT International Symposium and Exhibition on Advanced Packaging Materials %C Atlanta, GA %8 03/2006 %G eng %0 Conference Paper %B IBPSA Building Simulation 2005 %D 2005 %T Modeling Ground Source Heat Pump Systems in a Building Energy Simulation Program (EnergyPlus) %A Daniel E. Fisher %A Simon J. Rees %B IBPSA Building Simulation 2005 %C Montreal, canada %8 08/2005 %G eng %0 Conference Proceedings %B SimBuild 2004, Building Sustainability and Performance Through Simulation %D 2004 %T Comparative Analysis of One-Dimensional Slat-Type Blind Models %A Chanvit Chantrasrisalai %A Daniel E. Fisher %B SimBuild 2004, Building Sustainability and Performance Through Simulation %C Boulder, Colorado, USA %8 08/2004 %G eng %0 Conference Proceedings %B SimBuild 2004, Building Sustainability and Performance Through Simulation %D 2004 %T EnergyPlus: An Update %A Drury B. Crawley %A Linda K. Lawrie %A Curtis O. Pedersen %A Frederick C. Winkelmann %A Michael J. Witte %A Richard K. Strand %A Richard J. Liesen %A Walter F. Buhl %A Yu Joe Huang %A Robert H. Henninger %A Jason Glazer %A Daniel E. Fisher %A Don B. Shirley %A Brent T. Griffith %A Peter G. Ellis %A Lixing Gu %B SimBuild 2004, Building Sustainability and Performance Through Simulation %C Boulder, Colorado, USA %8 08/2004 %G eng %0 Journal Article %J Journal of Central South University, Technology %D 2003 %T Research of ANN Internal Model Self-tuning Control Applied in Combustion Process Control of Heating Furnace in Oil Field %A Yongcheng Jiang %A Xiufeng Pang %A Fu,Shaobo %B Journal of Central South University, Technology %V 34 %P 108-112 %G eng %N 2 %0 Conference Proceedings %B System Simulation in Buildings ’02 %D 2002 %T HVAC Component Data Modeling Using Industry Foundation Classes %A Vladimir Bazjanac %A James Forester %A Philip Haves %A Darko Sucic %A Peng Xu %X

The Industry Foundation Classes (IFC) object data model of buildings is being developed by the International Alliance for Interoperability (IAI). The aim is to support data sharing and exchange in the building and construction industry across the life-cycle of a building.

This paper describes a number of aspects of a major extension of the HVAC part of the IFC data model. First is the introduction of a more generic approach for handling HVAC components. This includes type information, which corresponds to catalog data, occurrence information, which defines item-specific attributes such as location and connectivity, and performance history information, which documents the actual performance of the component instance over time. Other IFC model enhancements include an extension of the connectivity model used to specify how components forming a system can be traversed and the introduction of time-based data streams.

This paper includes examples of models of particular types of HVAC components, such as boilers and actuators, with all attributes included in the definitions. The paper concludes by describing the on-going process of model testing, implementation and integration into the complete IFC model and how the model can be used by software developers to support interoperability between HVAC-oriented design and analysis tools.

%B System Simulation in Buildings ’02 %C Liège, Belgium %8 12/2002 %G eng %2 LBNL-51365 %0 Conference Proceedings %B BEP'94 %D 1994 %T Fault Detection in Air-Conditioning Systems Using A.I. Techniques %A Arthur L. Dexter %A Richard S. Fargus %A Philip Haves %B BEP'94 %C York, England %G eng %0 Conference Proceedings %B System Simulation in Buildings '94 %D 1994 %T Model-Based Approaches to Fault Detection and Diagnosis in Air-Conditioning System %A Mourad Benouarets %A Arthur L. Dexter %A Richard S. Fargus %A Philip Haves %A Tim I. Salsbury %A Jonathan A. Wright %B System Simulation in Buildings '94 %C Liège, Belgium %8 12/1994 %G eng