This beginner-friendly ANSYS Fluent tutorial explores wind flow patterns around three buildings using a steady-state CFD simulation. The episode focuses on utilizing the steady solver to analyze airflow interactions in a simple urban environment, providing a foundation for architectural engineering students new to CFD. Key aspects covered in this tutorial include: Boundary condition setup: Learning how to define basic inlet, outlet, and wall conditions to represent realistic wind scenarios around buildings. Turbulence modeling: Introduction to a simple turbulence model (e.g., standard k-epsilon) suitable for steady-state urban wind flow simulations. Solver settings: Understanding and configuring basic steady-state solver parameters for stable simulation runs. Post-processing basics: Exploring fundamental visualization techniques in Fluent, such as creating simple velocity contours and vector plots to understand wind patterns. Result interpretation: Learning to identify basic flow features like wind channeling between buildings and areas of low wind speed. This tutorial offers beginners practical insights into using ANSYS Fluent for urban wind flow analysis. It demonstrates how steady-state simulations can provide useful predictions of wind patterns around multiple buildings. Participants will gain introductory skills in setting up and interpreting basic CFD simulations for simple building configurations, laying the groundwork for more advanced studies in urban planning and building design.

This beginner-level ANSYS Fluent tutorial introduces the concept of transient CFD simulation for analyzing external wind flow around tall buildings. The episode focuses on using the transient solver to capture time-dependent flow phenomena, providing architectural engineering students with their first exposure to time-varying simulations. Key aspects covered in this tutorial include: Understanding transient simulations: Introduction to the concept of time-dependent flow and why it’s important for tall buildings. Basic transient solver settings: Learning how to set up simple time-stepping parameters and choose appropriate time steps for the simulation. Boundary condition setup: Defining basic inlet conditions to represent changing wind speeds or directions over time. Turbulence modeling: Brief introduction to a suitable turbulence model for transient external flows around buildings. Monitoring and convergence: Setting up basic monitoring points to track flow variables over time and understanding simple convergence criteria for transient simulations. Basic post-processing for transient results: Learning to create simple animations of flow fields and how to interpret changing flow patterns over time. Result interpretation: Identifying fundamental transient flow features such as vortex shedding or wind gusts around tall buildings. This tutorial provides beginners with an initial understanding of how transient CFD simulations can reveal time-dependent wind effects on tall buildings. Participants will gain basic skills in setting up and interpreting simple transient simulations, laying the foundation for more advanced studies in building aerodynamics and wind engineering.

This beginner-friendly ANSYS Fluent tutorial introduces the crucial topic of internal airflow analysis in architectural engineering, focusing on an atrium simulation. The episode highlights the significance of understanding indoor air movement for creating comfortable and efficient building designs. Key aspects covered in this tutorial include: Importance of internal airflow: Understanding why indoor air circulation is critical for occupant comfort, energy efficiency, and building performance. Basic setup for internal flow: Learning how to define simple boundary conditions for inlets, outlets, and walls within an atrium space. Thermal considerations: Introduction to basic thermal boundary conditions to simulate temperature differences in the atrium. Simple turbulence modeling: Brief overview of an appropriate turbulence model for indoor airflow simulations. Solver settings: Configuring basic solver parameters for a steady-state internal flow simulation. Essential post-processing: Creating basic velocity contours and temperature distributions to visualize airflow patterns in the atrium. Result interpretation: Learning to identify key airflow features such as air stratification, circulation zones, and potential draft areas. Practical applications: Discussing how the simulation results can inform design decisions, such as placement of ventilation systems or seating areas. This tutorial provides beginners with an introduction to the importance of CFD in analyzing internal building environments. Participants will gain foundational skills in simulating and interpreting basic indoor airflow patterns, understanding how these simulations can contribute to improved atrium designs, better indoor air quality, and enhanced occupant comfort. The episode emphasizes the practical relevance of internal flow analysis in modern architectural engineering practices.

This beginner-level ANSYS Fluent tutorial introduces the concept of windcatchers and their CFD simulation, highlighting the importance of this traditional architectural element in modern sustainable design. The episode focuses on how CFD can be used to analyze and optimize windcatcher performance for natural ventilation. Key aspects covered in this tutorial include: Introduction to windcatchers: Brief overview of windcatcher principles and their role in passive cooling and ventilation strategies. Simple geometry explanation: Understanding the basic components of a windcatcher model without delving into complex geometry creation. Basic boundary conditions: Setting up simple inlet and outlet conditions to represent wind entering and leaving the windcatcher. Fundamental flow physics: Introduction to key concepts like pressure differences and buoyancy effects in windcatcher operation. Simple solver settings: Configuring basic steady-state solver parameters for a windcatcher simulation. Essential post-processing: Creating basic velocity contours and vector plots to visualize airflow patterns through the windcatcher and into the building space. Result interpretation: Learning to identify main airflow features such as incoming fresh air, exhaust air, and circulation patterns within the connected space. Practical applications: Discussing how simulation results can inform windcatcher design, orientation, and integration into building plans. Sustainability aspect: Briefly exploring how windcatchers contribute to energy-efficient building design and reduced reliance on mechanical ventilation. This tutorial provides beginners with an introduction to simulating traditional architectural elements using modern CFD tools. Participants will gain basic skills in analyzing windcatcher performance, understanding how these simulations can contribute to improved natural ventilation strategies and sustainable building design. The episode emphasizes the practical relevance of combining traditional architectural wisdom with contemporary simulation techniques in the field of architectural engineering.

This beginner-friendly ANSYS Fluent tutorial introduces the concept of wind towers and their 2-D CFD simulation, highlighting the importance of these structures in modern sustainable architecture. The episode focuses on how simplified 2-D CFD analysis can provide valuable insights into wind tower performance for natural ventilation and passive cooling. Key aspects covered in this tutorial include: Introduction to wind towers: Brief overview of wind tower principles and their role in passive cooling and ventilation strategies in architecture. 2-D model explanation: Understanding the benefits of using a 2-D model for initial wind tower analysis. Basic boundary setup: Learning to define simple inlet and outlet conditions to represent wind entering and leaving the wind tower in a 2-D plane. Fundamental flow concepts: Introduction to key ideas like pressure gradients and air velocity changes within the wind tower structure. Simple solver configuration: Setting up basic steady-state solver parameters suitable for a 2-D wind tower simulation. Essential visualization techniques: Creating basic velocity contours and streamlines to visualize airflow patterns through the wind tower in 2-D. Result interpretation: Learning to identify main airflow features such as intake, downdraft, and exhaust regions within the wind tower. Practical implications: Discussing how 2-D simulation results can inform initial wind tower design decisions and orientation considerations. Sustainability aspect: Briefly exploring how wind towers contribute to energy-efficient building design and improved indoor air quality. This tutorial provides beginners with an introduction to simulating architectural elements using simplified 2-D CFD models. Participants will gain foundational skills in analyzing wind tower performance, understanding how these initial simulations can guide early-stage design decisions in sustainable architecture. The episode emphasizes the practical relevance of using basic CFD techniques to explore traditional cooling strategies in modern architectural engineering applications.

This beginner-level ANSYS Fluent tutorial introduces the concept of Double Skin Façades (DSF) and their CFD simulation, highlighting the importance of this modern architectural element in sustainable building design. The episode focuses on how CFD can be used to analyze and optimize DSF performance for improved energy efficiency and occupant comfort. Key aspects covered in this tutorial include: Introduction to Double Skin Façades: Brief overview of DSF principles and their role in building energy management, thermal comfort, and natural ventilation. Simple geometry setup: Understanding the basic components of a DSF model, including the outer and inner skins and the air cavity between them. Basic boundary conditions: Setting up simple inlet and outlet conditions to represent air movement within the DSF cavity and heat transfer through the façade layers. Fundamental heat transfer concepts: Introduction to key ideas like solar radiation, convection, and conduction as they apply to DSFs. Simple solver settings: Configuring basic steady-state solver parameters for a DSF simulation, including energy equations. Essential post-processing: Creating basic temperature contours and velocity vector plots to visualize heat distribution and airflow patterns within the DSF. Result interpretation: Learning to identify main thermal and flow features such as stack effect, heat accumulation, and air circulation within the façade cavity. Practical applications: Discussing how simulation results can inform DSF design decisions, including cavity width, material selection, and ventilation strategies. Energy efficiency aspect: Briefly exploring how DSFs contribute to building energy performance and potential reductions in heating and cooling loads. This tutorial provides beginners with an introduction to simulating advanced façade systems using CFD tools. Participants will gain basic skills in analyzing Double Skin Façade performance, understanding how these simulations can contribute to improved building envelope design and energy efficiency. The episode emphasizes the practical relevance of using CFD simulation in modern architectural engineering to optimize innovative façade solutions for sustainable building design.

This beginner-level ANSYS Fluent tutorial introduces the critical topic of dust particle simulation in indoor environments, highlighting its significance in architectural engineering and building design. The episode focuses on how CFD can be used to analyze and visualize the movement of dust particles entering a room, providing valuable insights for improving indoor air quality and occupant health. Key aspects covered in this tutorial include: Introduction to indoor air quality: Brief overview of the importance of managing dust and particulate matter in buildings for occupant health and comfort. Particle injection basics: Learning to define simple particle injection points or surfaces to represent dust entry into the room. Fundamental particle physics: Introduction to key concepts like particle size, density, and drag forces affecting dust movement, explained in simple terms. Simple airflow setup: Understanding basic inlet and outlet conditions to represent ventilation or natural air movement in the room. Discrete Phase Model (DPM) introduction: A beginner-friendly explanation of using the DPM in ANSYS Fluent for particle tracking. Basic solver settings: Overview of essential steady-state solver parameters for coupled airflow and particle simulation, suitable for beginners. Simple visualization techniques: Creating easy-to-understand particle tracks and concentration contours to visualize dust movement in the room. Interpreting results: Learning to identify basic particle behavior patterns, such as settling areas and suspension zones, in a straightforward manner. Practical applications: Discussing how simulation results can inform simple ventilation improvements and cleaning strategies in buildings. Health considerations: Briefly exploring the impact of dust control on occupant well-being, presented in an accessible way. This tutorial provides beginners with a gentle introduction to simulating dust particle movement in indoor environments using CFD tools. Participants will gain basic skills in analyzing dust distribution patterns, understanding how these simulations can contribute to improved indoor air quality strategies. The episode emphasizes the practical relevance of dust particle analysis in architectural engineering, highlighting its importance in creating cleaner, more comfortable indoor spaces, all presented at a pace suitable for newcomers to CFD simulation.