Your search keyword '"Fangliang Zhong"' showing total 10 results

1. Numerical Investigation of the Influence of Vegetation on the Aero-Thermal Performance of Buildings with Courtyards in Hot Climates

Author

Hao Sun, Carlos Jimenez-Bescos, Murtaza Mohammadi, Fangliang Zhong, and John Kaiser Calautit

Subjects

courtyard, vegetation, CFD Fluent, thermal performance, nature ventilation, Technology

Abstract

Natural ventilation is an energy-efficient way to provide fresh air and enhance indoor comfort levels. The wind-driven natural ventilation in courtyards has been investigated by many researchers, particularly the influence of the spatial configuration and environmental parameters on the ventilation and thermal comfort performance. However, previous research has mainly focused on the courtyard region instead of the indoor spaces surrounding it. Additionally, as a microclimate regulator, courtyards are rarely assessed in terms of the impact of vegetation, including its impact on energy consumption and thermal comfort. Evapotranspiration from vegetation can help lower air temperature in the surrounding environment and, therefore, its influence on the ventilation and thermal comfort in buildings with courtyards should be evaluated. The present study investigates the impact of vegetation on the aero-thermal comfort conditions in a courtyard and surrounding buildings in hot climates. Computational fluid dynamics was employed to evaluate the aero-thermal comfort conditions of the courtyard and surrounding buildings with different configurations of vegetation. The modeling was validated using previous works’ experimental data, and good agreement was observed. Thermal comfort indices were used to assess thermal performance. The study also evaluated the cover, height and planting area of vegetation in the courtyard. The results of this study can help develop tools that can assist the addition of vegetation in courtyards to maximize their effects. Future works will focus on looking at the influence of the strategies on different designs and layouts of courtyards.

Published

2021

2. Effect of Roof Cooling and Air Curtain Gates on Thermal and Wind Conditions in Stadiums for Hot Climates

Author

Fangliang Zhong, Hassam Nasarullah Chaudhry, and John Kaiser Calautit

Subjects

computational fluid dynamics, stadium cooling, air curtain, building energy simulation, thermal comfort, hot climates, Technology

Abstract

To host the 2022 FIFA World Cup, Qatar is facing the greatest challenge in balancing the energy consumptions for cooling the stadiums and the thermal comfort for both players and spectators. Previous studies have not considered using a combined configuration of air curtain and roof cooling supply slot in stadiums to prevent the infiltration of outside hot air and reduce the cooling system’s energy consumption. This paper presents a Computational Fluid Dynamics (CFD) study of thermal and wind modeling around a baseline stadium and simulates the cooling scenarios of air curtains and roof cooling along with the energy consumption estimations for the World Cup matches using Building Energy Simulation (BES). Sensitivity analysis of different supply speeds and supply temperatures of air curtain gates and roof cooling was carried out, and the results showed that scenario six, which provides supply air of 25 m/s and 20 m/s at the roof and air curtain gates with a supply temperature of 10 °C, demonstrates optimal thermal performances on both the spectator tiers and the pitch. Compared with the baseline stadium performance, the average reductions in temperature on the pitch and spectator tiers under scenario six could reach 15 °C and 14.6 °C. The reductions in the Predicted Percentage of Dissatisfied values for the upper and lower tiers as well as the pitch were 63%, 74%, and 78%. In terms of the estimated energy consumptions, scenario six would consume electric energy per match at a rate of 25.5 MWh compared with 22.8 MWh for one of the stadiums in the 2010 South Africa World Cup and 42.0 MWh for the 2006 Germany World Cup. Future research is recommended to explore the influence of supply angle on air curtain gates and roof cooling supply slots’ performances.

Published

2021

3. Design of a Passive Downdraught Evaporative Cooling Windcatcher (PDEC-WC) System for Greenhouses in Hot Climates

Author

Marouen Ghoulem, Khaled El Moueddeb, Ezzedine Nehdi, Fangliang Zhong, and John Calautit

Subjects

CFD, natural ventilation, evaporative cooling, water spray, Technology

Abstract

A windcatcher is a wind-driven natural ventilation system that catches the prevailing wind to bring fresh airflow into the building and remove existing stale air. This technology recently regained attention and is increasingly being employed in buildings for passive ventilation and cooling. The combination of windcatchers and evaporative cooling has the potential to reduce the amount of energy required to ventilate and cool a greenhouse in warm and hot climates. This study examined a greenhouse incorporated with a passive downdraught evaporative cooling windcatcher (PDEC-WC) system using Computational Fluid Dynamics (CFD), validated with experimental data. Different hot ambient conditions of temperature (30–45 °C) and relative humidity (15–45%) were considered. The study explored the influence of different spray heights, layouts, cone angles and mass flow rates on indoor temperature and humidity. The average error between measurements and simulated results was 5.4% for the greenhouse model and 4.6% for the evaporative spray model. Based on the results and set conditions, the system was able to reduce the air temperature by up to 13.3 °C and to increase relative humidity by 54%. The study also assessed the influence of neighbouring structures or other greenhouses that influence the flow distribution at the ventilation openings. The study showed that the windcatcher ventilation system provided higher airflow rates as compared to cross-flow ventilation when other structures surrounded the greenhouse.

Published

2020

4. An Integrated Cooling Jet and Air Curtain System for Stadiums in Hot Climates

Author

Fangliang Zhong and John Calautit

Subjects

atmospheric boundary layer (ABL), built environment, computational fluid dynamics (CFD), stadium, cooling, thermal comfort, Meteorology. Climatology, QC851-999

Abstract

The 2022 FIFA World Cup brings Qatar great challenges in terms of minimizing the cooling energy consumption and providing thermal comfort for both spectators and players. This paper presents comparisons among the results of thermal and wind environment modelling of a semi-outdoor stadium under three different cooling configurations and a baseline configuration without cooling using the Computational Fluid Dynamics (CFD) tool ANSYS Fluent 18.2. The three cooling configurations are: (1) vertical jets only above upper tiers, (2) vertical jets above upper tiers and horizontal jets at the back of lower tiers and around the pitch, (3) integrated vertical jets above upper tiers, horizontal jets at the back of lower tiers and air curtains at gates. De-coupled solar radiation simulations are implemented using the solar irradiance data in Doha under fair weather conditions method in Fluent in order to capture realistic thermal boundary conditions for the ground, stadium and surrounding buildings. On the basis of the set conditions, the results show that air curtains, employed in configuration 3 are effective in preventing the penetration of hot outside air through the gates of the stadium, which is an existing issue for stadiums in hot climates, and also contribute to lower energy consumption per match than the other configurations of cooling jets. The results presented in this study are useful not only for future design and retrofits of stadiums in hot climates but also for stadiums that incorporate mechanical cooling.

Published

2020

5. Analysis of passive downdraught evaporative cooling windcatcher for greenhouses in hot climatic conditions: Parametric study and impact of neighbouring structures

Author

John Kaiser Calautit, E. Nehdi, Fangliang Zhong, Khaled El Moueddeb, and Marouen Ghoulem

Subjects

Airflow, Environmental engineering, Soil Science, Greenhouse, Natural ventilation, Wind speed, law.invention, Control and Systems Engineering, law, Ventilation (architecture), Environmental science, Windcatcher, Relative humidity, Agronomy and Crop Science, Food Science, Evaporative cooler

Abstract

In hot climates, greenhouse cooling is essential to provide crops with suitable growth conditions. The combination of natural ventilation strategy such as windcatchers and evaporative cooling has the capability to decrease the energy requirement of greenhouses and provide improved conditions for the cultivation of crops. Although the windcatcher is a traditional architectural feature which originated in the Middle East, it has recently gained more attention and is increasingly being employed in buildings as a wind-driven cooling technique. This study aims to investigate the potential of a passive windcatcher and evaporative cooling system integrated into a greenhouse using computational fluid dynamics (CFD), validated with experimental data. Different wind speeds (1.96, 3.03, 4.87 and 6.07 m s−1) and ambient temperatures (30, 35, 40, 45 °C) and relative humidity (15, 25, 35 and 45%) were considered. The average error between measured and simulated results was 5.43% for the cross-flow ventilated greenhouse model and 4.55% for the evaporative cooling spray model. The results showed that the system could reduce the average indoor air temperature by up to 17.13 °C. The study explored the influence of different windcatcher heights and also the potential of fins installed in the windward openings to improve the uniformity of the ventilation airflow. The study also assessed the influence of neighbouring structures or other greenhouses on the ventilation performance. The results showed that the windcatcher provided higher airflow rates as compared to side openings when other structures surrounded the greenhouse.

Published

2020

6. Deep Learning-based Occupancy Behaviour Approach Towards the Improvement of the Indoor Air Quality Within Building Spaces

Author

Paige Paige, Paige Tien, Murtaza Mohammadi, Fangliang Zhong, John Calautit, Jo Darkwa, and Christopher Wood

Published

2021

7. Assessment of HVAC system operational fault impacts and multiple faults interactions under climate change

Author

Fangliang Zhong, John Kaiser Calautit, and Yupeng Wu

Subjects

General Energy, Mechanical Engineering, Building and Construction, Electrical and Electronic Engineering, Pollution, Industrial and Manufacturing Engineering, Civil and Structural Engineering

Published

2022

8. Numerical Investigation of the Influence of Vegetation on the Aero-Thermal Performance of Buildings with Courtyards in Hot Climates

Author

John Kaiser Calautit, Hao Sun, Carlos Jimenez-Bescos, Fangliang Zhong, and Murtaza Mohammadi

Subjects

nature ventilation, Technology, Control and Optimization, Renewable Energy, Sustainability and the Environment, Microclimate, Energy Engineering and Power Technology, Thermal comfort, Natural ventilation, Energy consumption, Vegetation, Civil engineering, law.invention, law, vegetation, Evapotranspiration, courtyard, Thermal, Ventilation (architecture), Environmental science, CFD Fluent, Electrical and Electronic Engineering, thermal performance, Engineering (miscellaneous), Energy (miscellaneous)

Abstract

Natural ventilation is an energy-efficient way to provide fresh air and enhance indoor comfort levels. The wind-driven natural ventilation in courtyards has been investigated by many researchers, particularly the influence of the spatial configuration and environmental parameters on the ventilation and thermal comfort performance. However, previous research has mainly focused on the courtyard region instead of the indoor spaces surrounding it. Additionally, as a microclimate regulator, courtyards are rarely assessed in terms of the impact of vegetation, including its impact on energy consumption and thermal comfort. Evapotranspiration from vegetation can help lower air temperature in the surrounding environment and, therefore, its influence on the ventilation and thermal comfort in buildings with courtyards should be evaluated. The present study investigates the impact of vegetation on the aero-thermal comfort conditions in a courtyard and surrounding buildings in hot climates. Computational fluid dynamics was employed to evaluate the aero-thermal comfort conditions of the courtyard and surrounding buildings with different configurations of vegetation. The modeling was validated using previous works’ experimental data, and good agreement was observed. Thermal comfort indices were used to assess thermal performance. The study also evaluated the cover, height and planting area of vegetation in the courtyard. The results of this study can help develop tools that can assist the addition of vegetation in courtyards to maximize their effects. Future works will focus on looking at the influence of the strategies on different designs and layouts of courtyards.

Published

2021

9. Effect of Roof Cooling and Air Curtain Gates on Thermal and Wind Conditions in Stadiums for Hot Climates

Author

John Kaiser Calautit, Fangliang Zhong, and Hassam Nasarullah Chaudhry

Subjects

Technology, Control and Optimization, thermal comfort, 020209 energy, Energy Engineering and Power Technology, 02 engineering and technology, computational fluid dynamics, 010501 environmental sciences, Computational fluid dynamics, 01 natural sciences, building energy simulation, Thermal, 0202 electrical engineering, electronic engineering, information engineering, Water cooling, stadium cooling, air curtain, hot climates, Electrical and Electronic Engineering, Engineering (miscellaneous), Roof, Building energy simulation, 0105 earth and related environmental sciences, Renewable Energy, Sustainability and the Environment, business.industry, Thermal comfort, Energy consumption, Infiltration (HVAC), Environmental science, business, Energy (miscellaneous), Marine engineering

Abstract

To host the 2022 FIFA World Cup, Qatar is facing the greatest challenge in balancing the energy consumptions for cooling the stadiums and the thermal comfort for both players and spectators. Previous studies have not considered using a combined configuration of air curtain and roof cooling supply slot in stadiums to prevent the infiltration of outside hot air and reduce the cooling system’s energy consumption. This paper presents a Computational Fluid Dynamics (CFD) study of thermal and wind modeling around a baseline stadium and simulates the cooling scenarios of air curtains and roof cooling along with the energy consumption estimations for the World Cup matches using Building Energy Simulation (BES). Sensitivity analysis of different supply speeds and supply temperatures of air curtain gates and roof cooling was carried out, and the results showed that scenario six, which provides supply air of 25 m/s and 20 m/s at the roof and air curtain gates with a supply temperature of 10 °C, demonstrates optimal thermal performances on both the spectator tiers and the pitch. Compared with the baseline stadium performance, the average reductions in temperature on the pitch and spectator tiers under scenario six could reach 15 °C and 14.6 °C. The reductions in the Predicted Percentage of Dissatisfied values for the upper and lower tiers as well as the pitch were 63%, 74%, and 78%. In terms of the estimated energy consumptions, scenario six would consume electric energy per match at a rate of 25.5 MWh compared with 22.8 MWh for one of the stadiums in the 2010 South Africa World Cup and 42.0 MWh for the 2006 Germany World Cup. Future research is recommended to explore the influence of supply angle on air curtain gates and roof cooling supply slots’ performances.

Published

2021

10. Analysis of the influence of cooling jets on the wind and thermal environment in football stadiums in hot climates

Author

Fangliang Zhong, John Kaiser Calautit, and Ben Richard Hughes

Subjects

010504 meteorology & atmospheric sciences, business.industry, 0211 other engineering and technologies, 02 engineering and technology, Building and Construction, Football, Computational fluid dynamics, 01 natural sciences, Stadium, Thermal, Environmental science, 021108 energy, Energy simulation, Aerospace engineering, business, Built environment, 0105 earth and related environmental sciences

Abstract

After winning the bid of the FIFA’s World Cup 2022, Qatar is facing the greatest challenges in terms of minimizing substantial energy consumptions for air-conditioning of stadiums and maintaining aero-thermal comfort for both players and spectators inside stadiums. This paper presents the results of temperature distributions and wind environment of the original stadium under the hot-humid climate and improvements on them for optimized scenarios of cooling jets. A combined computational fluid dynamics and building energy simulation approach was used to analyse the cooling performance and energy consumption per match of cooling air jets for 10 scenarios with different supply velocities, supply temperatures and locations of jets. The optimal scenario is to employ vertical jets above the upper tiers at supply temperature of 20°C and velocities of 2–12 m/s, integrated with horizontal jets of the same temperature at the lower tiers with 4 m/s and around the pitch with 7 m/s. This scenario can maintain the spectator tiers at an average temperature of 22°C and reduce the maximum predicted percentage of dissatisfied of thermal comfort from the original 100% to 63% for the pitch and 19% for the tiers, respectively. In terms of the energy consumption for the air-conditioning system per match, compared with one of the 2010 South Africa World Cup stadiums Royal Bafokeng stadium which consumed approximately 22.8 MWh energy for air-conditioning in winter (highest outdoor temperature 24.4°C), the maximum energy consumption of the optimal scenario in November (highest outdoor temperature 34.2°C) can reach 108 MWh. In addition, the spectator zones with scenario 8 have the potential to be resilient to the seasonal change of outdoor temperature if slight modifications of the supply velocities and precise temperature control on the spectator zones are applied. Moreover, the configurations presented in this paper can be used as a foundation of jets arrangement for future stadium retrofits in the hot climates. Practical application: This study assesses the aero-thermal conditions of a case study stadium under the hot climate of Qatar and explores the potential of applying cooling jets with different supply velocities, supply temperatures and their locations on the enhancement of both thermal and wind environment of spectator tiers and pitch. The assessment of the original stadium indicates that the ascending curved roof structure impedes the fresh air entering into the stadium and results in an asymmetric temperature distribution on the spectator tiers. The optimized design suggests a combination of vertical jets under the roof and both three arrays of horizontal jets at lower tiers and around pitch for future stadium optimizations in hot climates. It also recommends enhancing the thermal conditions on the pitch by optimizing the velocity of horizontal jets around the pitch. Moreover, the future design of the exact stadiums to be resilient to the seasonal changing outdoor temperature can be implemented based on scenario 8.

Published

2019