基本信息

张伟荣，教授、博士生导师，国家海外高层次人才青年项目入选者。2012年于日本东京大学取得工学博士学位。2012年至2014年，受日本学术振兴会资助在日本东京大学任博士后研究员，2014年至2018年在东京工艺大学建筑系任副教授。2018年加入北京工业大学。

担任日本东京大学生产技术研究所客座教授，国际期刊International Journal of Ventilation 副主编，全国碳达峰碳中和计量技术委员会建筑碳计量分技术委员会委员等。围绕建筑节能和提高室内环境舒适度的重大需求，主持了国家自然科学基金2项、科技部国家重点研发计划项目子课题2项、日本国家能源产业机构重大项目1项、日本文部科学省重点合作研究1项，日本铁道集团重点项目1项，以及几十个个企事业委托项目。在上述研究方向发表各类论文70余篇，参与编著了3本专著，参编了10余项国内外行业标准，在建筑环境控制方面拥有多项专利。2014年获得日本暖通空调学会论文奖，2016年获得日本暖通空调学会颁发的功绩奖，2021年获得住房和城乡建设部华夏建设科学技术奖二等奖。

研究方向

建筑环境与能源应用工程

1.建筑微电网的构建和调度

2.建筑智能通风

3.区域低碳规划

4.基于人工智能的建成环境相关技术

主讲课程

本科生教学：通风工程，绿色建筑技术

研究生教学：建筑围护结构及室内环境模拟技术

代表性学术论文

1.A collaborative matching method for multi-energy supply systems in office buildings considering the random characteristics of electric vehicles[J]. Energy and Buildings, 2024, 303: 113809.

2.Enhancing indoor environmental quality: Personalized recommendation method for demand-oriented indoor ventilation strategy[J].Sustain Cities Soc,2024,101:105061.

3.Field study of meeting thermal needs of occupants in old residential buildings in low-temperature environments using personalized local heating[J].Building and Environment, 2024, 247: 111004.

4.Non-uniform state-based Markov chain model to improve the accuracy of transient contaminant transport prediction[J].Building and Environment, 2023,245.: 110977.

5.Prediction and influencing factors of photovoltaic system power generation of a single house based on continuously measured data[J].Indoor and Built Environment,2023.

6.Study on choosing mobile sensor location to improve the prediction accuracy of indoor temperature distribution[J]. Building and Environment, 2023, 240: 110424.

7.Optimizing multi-vent module-based adaptive ventilation using a novel parameter for improved indoor air quality and health protection, Building Simulation., 2024, 17(1): 113-130.

8.Effective improvement of a local thermal environment using multi-vent module-based adaptive ventilation, Building Simulation., 2023: 1-20.

9.Flexibility quantification and enhancement of flexible electric energy systems in buildings[J]. Journal of Building Engineering, 2023: 106114.

10.An enhanced principal component analysis method with Savitzky–Golay filter and clustering algorithm for sensor fault detection and diagnosis[J]. Applied Energy, 2023, 337: 120862.

11.Multi-vent module-based adaptive ventilation to reduce cross-contamination among indoor occupants[J]. Building and Environment, 2022, 212: 108836.

12.Comparative study of indoor thermal environment and human thermal comfort in residential buildings among cities, towns, and rural areas in arid regions of China[J]. Energy and Buildings, 2022, 273: 112373.

13.Effect of Open-Window Gaps on the Thermal Environment inside Vehicles Exposed to Solar Radiation[J]. Energies, 2022, 15(17): 6411.

14.A numerical study on changes in air temperature around buildings due to retrofits in existing residential districts[J]. Indoor and Built Environment, 2022: 1420326X211055818.

15.Review and Development of the Contribution Ratio of Indoor Climate (CRI)[J]. Energy and Built Environment, 2021(9).

16.Decision-making analysis of ventilation strategies under complex situations: A numerical study[J]. Building and Environment, 2021, 206: 108217.

17.The Framework of Technical Evaluation Indicators for Constructing Low-Carbon Communities in China[J]. Buildings, 2021, 11(10): 479.

18.Predicting indoor temperature distribution based on contribution ratio of indoor climate (CRI) and mobile sensors[J]. Buildings, 2021, 11(10): 458.