Your search keyword '"Hong, Tianzhen"' showing total 12 results

1. Evaluating energy retrofits of historic buildings in a university campus using an urban building energy model that considers uncertainties.

Author

Lin, Ziqi, Hong, Tianzhen, Xu, Xiaodong, Chen, Jiayu, and Wang, Wei

Subjects

HISTORIC buildings, RETROFITTING of buildings, SUSTAINABLE architecture, COLLEGE buildings, ENGINEERING standards, ENERGY consumption

Abstract

• Uncertainties are the key consideration in the urban building energy model. • This study proposed to energy retrofitting of historical urban block considering uncertainties. • For building energy retrofitting packages with passive and active measures were proposed. • Real energy data was applied to calibrate the energy model with an accuracy of larger than 80%. • This study can be a significant reference for energy retrofitting of historical urban block. Urban building energy model (UBEM) is a powerful tool to simulate performance and evaluate efficiency of upgrades for a group of buildings under the urban context. However, the larger the scale/number of buildings, more parameters must be collected to create energy models that cover each individual building, causing more uncertainties. To reveal this, this study created a UBEM for the mixed modern and historic buildings at a campus in China. The calibrated set of UBEMs with the modeled results meeting the 20% error range, were then used to evaluate uncertainties of energy-savings of four building energy retrofit (BER) measures. The first measure, BER 1, was to preserve the historic values of buildings; BER 2 to meet green building design standard; BER 3 to achieve 20% more savings than BER 2; and BER 4 to utilize renewable photovoltaic energy. For BER 1, BER 2, and BER 3, the energy savings of buildings of different ages varied within 10%–44%. For BER 4, the energy savings of buildings varied within 49%–505%, respectively, where the reason for higher than 100% is energy production is much higher than energy demand. Similar results can be concluded for building functions, for BER 1, BER 2, and BER 3, the energy-saving potentials varied within 6%– 45%, while 97%–492% to BER 4. This study can provide an important and significant reference to apply UBEM in evaluating energy-efficient retrofits as well as other energy-related studies that consider uncertainties. [ABSTRACT FROM AUTHOR]

Published

2023

2. A thorough assessment of China’s standard for energy consumption of buildings.

Author

Yan, Da, Hong, Tianzhen, Li, Cheng, Zhang, Qi, An, Jingjing, and Hu, Shan

Subjects

*ENERGY consumption of buildings, *HEATING & ventilation industry, *ENERGY policy, *ESTIMATION theory

Abstract

China’s Design Standard for Energy Efficiency of Public Buildings (the Design Standard) is widely used in the design phase to regulate the energy efficiency of physical assets (envelope, lighting, HVAC) in buildings. However, the standard does not consider many important factors that influence the actual energy use in buildings, and this can lead to gaps between the design estimates and actual energy consumption. To achieve the national energy savings targets defined in the strategic 12th Five-Year Plan, China developed the first standard for energy consumption of buildings GB/T51161-2016 (the Consumption Standard). This study provides an overview of the Consumption Standard, identifies its strengths and weaknesses, and recommends future improvements. The analysis and discussion of the constraint value and the leading value, two key indicators of the energy use intensity, provide insight into the intent and effectiveness of the Consumption Standard. The results indicated that consistency between China’s Design Standard GB 50189-2015 and the Consumption Standard GB/T51161-2016 could be achieved if the Design Standard used the actual building operations and occupant behavior in calculating the energy use in Chinese buildings. The development of an outcome-based code in the U.S. was discussed in comparison with China’s Consumption Standard, and this revealed the strengths and challenges associated with implementing a new compliance method based on actual energy use in buildings in the U.S. Overall, this study provides important insights into the latest developments of actual consumption-based building energy standards, and this information should be valuable to building designers and energy policy makers in China and the U.S. [ABSTRACT FROM AUTHOR]

Published

2017

3. Comparison of building energy use data between the United States and China.

Author

Xia, Jianjun, Hong, Tianzhen, Shen, Qi, Feng, Wei, Yang, Le, Im, Piljae, Lu, Alison, and Bhandari, Mahabir

Subjects

*ENERGY consumption of buildings, *DATA modeling, *BENCHMARKING (Management)

Abstract

Highlights: [•] Existing energy monitoring platforms lack standards of data model and collection. [•] Good data at various time intervals are key to energy profiling and diagnostics. [•] An energy data model based on the ISO Standard 12655 is key for energy benchmarking. [•] Buildings in the U.S. and China performed differently due to design and operations. [•] Different retrofit measures should apply to buildings in the U.S. and China. [ABSTRACT FROM AUTHOR]

Published

2014

4. A close look at the China Design Standard for Energy Efficiency of Public Buildings

Author

Hong, Tianzhen

Subjects

*ENERGY consumption, *PUBLIC buildings, *POWER resources

Abstract

Abstract: This paper takes a close look at the China national standard GB50189-2005, Design Standard for Energy Efficiency of Public Buildings, which was enforced on July 1, 2005. The paper first reviews the standard, then compares the standard with ASHRAE Standard 90.1-2004 to identify discrepancies in code coverage and stringency, and recommends some energy conservation measures that can be evaluated in the design of public buildings to achieve energy savings beyond the standard. The paper also highlights several important features of 90.1-2004 that may be considered as additions to the GB50189-2005 standard during the next revision. At the end the paper summarizes the latest developments in building energy standards and rating systems in China and the US. [Copyright &y& Elsevier]

Published

2009

5. A novel approach for selecting typical hot-year (THY) weather data.

Author

Guo, Siyue, Yan, Da, Hong, Tianzhen, Xiao, Chan, and Cui, Ying

Subjects

*HEAT waves (Meteorology), *CLIMATE change, *HOT weather conditions, *EXTREME environments, *WEATHER, *HEAT

Abstract

• The impacts of heat wave on outdoor and indoor environment are different. • The heat wave impacts are not sensitive to the envelope performance in this study. • A novel approach was developed to determine typical hot year weather data. • The derived heat waves data are different from the outdoor-based results. The global climate change has resulted in not only warmer climate conditions but also more frequent extreme weather events, such as heat waves. However, the impact of heat waves on the indoor environment has been investigated in a limited manner. In this research, the indoor thermal environment is analyzed using a building performance simulation tool for a typical residential building in multiple cities in China, over a time period of 60 years using actual measured weather data, in order to gain a better understanding of the effect of heat wave events. The simulation results were used to analyze the indoor environment during hot summers. A new kind of weather data referred to as the typical hot year was defined and selected based on the simulated indoor environment during heat waves. The typical hot-year weather data can be used to simulate the indoor environment during extreme heat events and for the evaluation of effective technologies and strategies to mitigate against the impact of heat waves on the energy demand of buildings and human health. The limitations of the current study and future work are also discussed. [ABSTRACT FROM AUTHOR]

Published

2019

6. Comparison of typical year and multiyear building simulations using a 55-year actual weather data set from China.

Author

Cui, Ying, Yan, Da, Hong, Tianzhen, Xiao, Chan, Luo, Xuan, and Zhang, Qi

Subjects

*COMPARATIVE studies, *SIMULATION methods & models, *WEATHER, *ENERGY consumption, *ENERGY consumption of buildings

Abstract

Weather has significant impacts on the thermal environment and energy use in buildings. Thus, accurate weather data are crucial for building performance evaluations. Traditionally, typical year data inputs are used to represent long-term weather data. However, there is no guarantee that a single year represents the changing climate well. In this study, the long-term representation of a typical year was assessed by comparing it to a 55-year actual weather data set. To investigate the weather impact on building energy use, 559 simulation runs of a prototype office building were performed for 10 large cities covering all climate zones in China. The analysis results demonstrated that the weather data varied significantly from year to year. Hence, a typical year cannot reflect the variation range of weather fluctuations. Typical year simulations overestimated or underestimated the energy use and peak load in many cases. With the increase in computational power of personal computers, it is feasible and essential to adopt multiyear simulations for full assessments of long-term building performance, as this will improve decision-making by allowing for the full consideration of variations in building energy use. [ABSTRACT FROM AUTHOR]

Published

2017

7. Data analysis and stochastic modeling of lighting energy use in large office buildings in China.

Author

Zhou, Xin, Yan, Da, Hong, Tianzhen, and Ren, Xiaoxin

Subjects

*OFFICE building energy consumption, *ENERGY consumption, *STOCHASTIC processes, *INTERIOR lighting, *DATA analysis

Abstract

Lighting consumes about 20% to 40% of the total electricity use in large office buildings in China. Commonly in building simulations, static time schedules for typical weekdays, weekends and holidays are assumed to represent the dynamics of lighting energy use in buildings. This approach does not address the stochastic nature of lighting energy use, which can be influenced by occupant behavior in buildings. This study analyzes the main characteristics of lighting energy use over various timescales, based on the statistical analysis of measured lighting energy use data from 15 large office buildings in Beijing and Hong Kong. It was found that in these large office buildings, the 24-hourly variation in lighting energy use was mainly driven by the schedules of the building occupants. Outdoor illuminance levels had little impact on lighting energy use due to the lack of automatic daylighting controls (an effective retrofit measure to reduce lighting energy use) and the relatively small perimeter area exposed to natural daylight. A stochastic lighting energy use model for large office buildings was further developed to represent diverse occupant activities, at six different time periods throughout a day, and also the annual distribution of lighting power across these periods. The model was verified using measured lighting energy use from the 15 buildings. The developed stochastic lighting model can generate more accurate lighting schedules for use in building energy simulations, improving the simulation accuracy of lighting energy use in real buildings. [ABSTRACT FROM AUTHOR]

Published

2015

8. Vertical meteorological patterns and their impact on the energy demand of tall buildings.

Author

Gui, Chenxi, Yan, Da, Hong, Tianzhen, Xiao, Chan, Guo, Siyue, and Tao, Yifan

Subjects

*TALL building design & construction, *TALL buildings, *HUMIDITY, *WIND speed, *BUILDING performance, *COOLING loads (Mechanical engineering), *HEATING load, *BUILDING-integrated photovoltaic systems

Abstract

In accordance with the developing economy and growing population, an increasing number of tall buildings have been constructed over the last 20 years. In 2017, there were 144 new buildings worldwide that were 200 m or greater in height; 50% of these buildings were in China. Due to the vertical gradient impact of meteorological parameters, the energy performance of tall buildings differs from that of general buildings. Few studies exist on vertical meteorological changes using measured data at different heights. Most studies on dynamic energy simulation simulate meteorological parameters using models. This study explores vertical meteorological patterns using hourly dry-bulb temperature, relative humidity, and wind speed data from 2007 to 2017 for a 325 m meteorological tower in Beijing. The temperature decreased significantly with increasing altitude (~0.9 °C per 100 m), while the daily temperature difference decreased with increasing altitude. The absolute humidity did not change significantly with height. The wind speed increased with altitude at approximately 2 m/s per 100 m. The building simulation showed that the annual heating load at a height of 320 m increased by 85% from that at 8 m; the annual cooling load decreased by 20%. Such significant differences in thermal loads for 300-m-tall buildings confirm the need to consider vertical meteorological differences in building performance simulations for tall buildings. A greater number of measurement points at different heights improve the simulation accuracy. Guidance on selecting the heights for vertical metrological measurements is provided based on the influences of building thermal loads. [ABSTRACT FROM AUTHOR]

Published

2021

9. Operation and performance of VRF systems: Mining a large-scale dataset.

Author

Qian, Mingyang, Yan, Da, Hong, Tianzhen, and Liu, Hua

Subjects

*ENERGY consumption, *OFFICE buildings, *CLUSTER analysis (Statistics), *DISTRIBUTION (Probability theory), COLD regions

Abstract

• New key performance indicators were proposed to benchmark actual application of 287,000 VRF systems in all five climate zones in China. • Data mining on a large-scale dataset is a powerful tool to obtain statistical distributions of VRF systems for different types of buildings and climate zones. • Cluster was applied to analyze typical operating load patterns of VRF systems for residential and office buildings, where partial load operations are common. •. • Findings inform the design, operation, industry standard development, and performance optimization of VRF systems. The energy consumption of air-conditioning systems has gained increasing attention as it contributes significantly to the global building energy use. The variable refrigerant flow (VRF) system is a common air-conditioning system applied widely in residential and office buildings in China. Understanding the actual operation and performance of VRF systems is fundamental for the energy-efficient design and operation of VRF systems. Previous research on VRF system operation used either limited field data covering certain building types and climate zones or used a questionnaire to obtain a larger dataset. However, they did not capture the wide applications of VRF systems quantitatively across all building types, climate zones, and operating conditions. To fill this gap, statistical and clustering analysis was conducted on the newly proposed key performance indicators of approximately 287,000 VRF systems for residential and commercial buildings in all five climate zones in China. The main findings are: (1) VRF systems are mainly used for cooling in all climate zones in China; (2) among all building types, the duration of use is lowest in residential buildings and highest in hotels and medical buildings; (3) the distribution of the ideal VRF cooling coefficient of performance (COP) is similar across all climate zones and building types; whereas the COPs of ideal VRF heating in the Severe Cold region and Cold regions are lower than those in other climate zones; and (4) partial load operations for VRF systems are common in residential buildings and office buildings due to the part-time-part-space operation mode. These findings can inform the actual application of VRF systems in China, supporting the design, operation, industry standard development, and performance optimization of VRF systems. [ABSTRACT FROM AUTHOR]

Published

2021

10. Comparative study of air-conditioning energy use of four office buildings in China and USA.

Author

Zhou, Xin, Yan, Da, An, Jingjing, Hong, Tianzhen, Shi, Xing, and Jin, Xing

Subjects

*AIR conditioning, *OFFICE building energy consumption, *OFFICE buildings, *ENERGY policy

Abstract

Energy use in buildings has great variability. In order to design and operate low energy buildings as well as to establish building energy codes and standards and effective energy policy, it is crucial to understand and quantify key factors influencing building energy performance. This study investigates air-conditioning (AC) energy use of four office buildings in four locations: Beijing, Taiwan, Hong Kong, and Berkeley. Building simulation was employed to quantify the influences of key factors, including climate, building envelope and occupant behavior. Through simulation of various combinations of the three influencing elements, it is found that climate can lead to AC cooling consumption differences by almost two times, while occupant behavior resulted in the greatest differences (of up to three times) in AC cooling consumption. The influence of occupant behavior on AC energy consumption is not homogeneous. Under similar climates, when the occupant behavior in the building differed, the optimized building envelope design also differed. Overall, the optimal building envelope should be determined according to the climate as well as the occupants who use the building. [ABSTRACT FROM AUTHOR]

Published

2018

11. Comparative study of the cooling energy performance of variable refrigerant flow systems and variable air volume systems in office buildings.

Author

Yu, Xinqiao, Yan, Da, Sun, Kaiyu, Hong, Tianzhen, and Zhu, Dandan

Subjects

*OFFICE building air conditioning, *OFFICE buildings & the environment, *VARIABLE air volume systems (Air conditioning), *COOLING, *REFRIGERANTS, *OFFICE buildings

Abstract

Variable air volume (VAV) and variable refrigerant flow (VRF) systems are widely used in office buildings. This study investigated VAV and VRF systems in five typical office buildings in China, and compared their cooling energy use. Site survey and field measurements were conducted to collect the data of building characteristics and operation. Measured cooling electricity use was collected from sub-metering in the five buildings. The sub-metering data normalized by climate and operating hours indicated that the cooling energy consumed by VRF systems was up to 70% lower than that consumed by VAV systems. This was mainly because of the different operation modes of both system types that led to significantly fewer operating hours for the VRF systems. Building simulations were used to quantify the impact of operation modes of VRF and VAV systems on cooling loads. A prototype office building in China was used as the model. The simulation results showed that the VRF operation mode required much lower cooling load when compared to the VAV operation mode. For example, the cooling loads decreased by 42% in Hong Kong and 53% in Qingdao. The key findings include the following: the VRF systems operated in the part-time-part-space mode enabling occupants to turn on the air-conditioning only when needed and when the spaces were occupied. However, the VAV systems operated in the full-time-full-space mode limiting occupants’ control of operation. These findings provide insights into VRF systems operation and controls as well as their energy performance, which could help guide HVAC designers on system selection and building operators or facility managers on system operations to achieve low- or zero-net energy buildings. [ABSTRACT FROM AUTHOR]

Published

2016

12. An improved method for direct incident solar radiation calculation from hourly solar insolation data in building energy simulation.

Author

An, Jingjing, Yan, Da, Guo, Siyue, Gao, Yan, Peng, Jinqing, and Hong, Tianzhen

Subjects

*SOLAR spectra, *SOLAR radiation, *SPECTRAL irradiance, *ENERGY consumption of buildings, *BUILDING performance

Abstract

• Incident solar radiation calculations in DOE-2, EnergyPlus, and DeST were analyzed. • An improved calculation method for direct incident solar radiation calculation was proposed. • The proposed method was demonstrated and evaluated in eight cities of China. • It contributes to BEMPs to improve the accuracy of simulated building loads. Solar radiation considerably influences the energy consumption of buildings and the power production of building integrated photovoltaic (BIPV) systems. Hourly solar insolation (Wh/m2), represented as the amount of solar irradiance collected on the ground during a 1-h period, is the most common solar radiation data available and widely used in weather files applied in building energy modeling programs (BEMPs). Because the solar beam and position vary over time, the use of hourly insolation data as the input might result in errors in the estimation of the direct incident solar radiation on a particular surface. In this study, methods used in BEMPs for direct incident solar radiation calculations are first analyzed, and an improved method adopting a new algorithm for estimating the solar irradiance is proposed. The algorithm assumes that the solar irradiance changes linearly within a 1-h period and can be estimated based on the solar irradiance at the half clock and slope. The collected direct normal solar irradiance data of 2016 from eight solar radiation stations in China were used to demonstrate the proposed method and evaluate its performance by comparing the results with those from three conventional methods used in BEMPs along with the ground truth measurements. In addition, in this study, factors affecting the accuracy of the calculation results are explored. The results of the estimated direct incident solar radiation show that the proposed method achieves the best accuracy, followed by the methods used in DOE-2, EnergyPlus, and DeST. The proposed method guarantees that the hourly direct solar insolation will remain the same and reflects the variation in the direct solar irradiance across a 1-h time frame. The proposed method can be adopted in BEMPs to improve the accuracy of the solar radiation calculation, thereby improving the accuracy of the simulated building performance and the BIPV production. [ABSTRACT FROM AUTHOR]

Published

2020