The Zero-Energy Building Design course, offered by the British Academy for Training and Development, is tailored to equip professionals with the knowledge needed to design buildings that balance energy consumption and production. With the increasing focus on sustainability, zero-energy buildings (ZEBs) have become a cornerstone in the future of construction. These buildings rely on a combination of efficient design and renewable energy sources to meet their energy needs, making them integral to reducing our environmental footprint.

Throughout the course, participants will explore key design strategies, from passive building techniques to the integration of renewable energy systems. The program also covers energy modeling and how to monitor the performance of these buildings. This course is ideal for architects, engineers, sustainability experts, and construction professionals who want to develop practical skills for creating energy-positive buildings.

Who Should Attend?

• Professionals in the planning and design of buildings who want to incorporate energy-efficient and sustainable practices into their work.
• Civil, structural, and mechanical engineers interested in expanding their expertise in energy-efficient design and renewable energy systems.
• Sustainability Consultants advising organizations on green building practices and looking to deepen their understanding of zero-energy construction.
• Construction Managers and Developers overseeing building projects with an interest in integrating energy-efficient and sustainable technologies.
• Students and Researchers studying or researching sustainable building practices and energy systems.

Knowledge and Benefits:

After completing the program, participants will be able to master the following:

• Gain a comprehensive understanding of zero-energy building concepts, focusing on the integration of energy-efficient systems and renewable energy.
• Develop expertise in implementing renewable energy technologies such as solar, wind, and geothermal to reduce a building's reliance on external energy sources.
• Learn how to use energy modeling tools to assess and optimize the energy performance of buildings.
• Understand the practical considerations for meeting zero-energy performance standards and how to balance energy generation with consumption.
• Explore common challenges in zero-energy building design and how to address them, from regulatory hurdles to technical barriers.

• Defining Zero-Energy Buildings
  • Key characteristics of zero-energy buildings and how they achieve energy self-sufficiency.
  • Understanding the difference between net-zero energy and near-zero energy buildings.
  • Overview of the technologies and design elements that make ZEBs possible.
• Environmental Impact and Sustainability
  • The role of zero-energy buildings in reducing carbon footprints.
  • How ZEBs contribute to global sustainability efforts and climate change mitigation.
  • Benefits of zero-energy buildings beyond energy savings, including health and comfort for occupants.
• Energy Balance Concept
  • The fundamental principle of energy balance: energy consumption vs. energy production.
  • How to calculate and measure the net energy consumption of a building over a year.
  • The importance of creating buildings that can generate as much energy as they use.

• Passive Design Strategies
  • Using natural elements like sunlight and ventilation to reduce energy consumption.
  • Importance of insulation, airtightness, and thermal mass in reducing heating and cooling needs.
  • How building orientation and window placement contribute to energy efficiency.
• Building Envelope Design
  • The critical role of a building’s exterior in controlling energy loss.
  • Choosing the right materials for insulation and reducing heat transfer.
  • Methods for creating airtight buildings to minimize energy wastage.
• Energy-efficient HVAC Systems
  • Designing heating, ventilation, and air conditioning (HVAC) systems that use minimal energy.
  • The role of heat recovery ventilation (HRV) and energy-efficient air conditioning.
  • Integrating passive cooling and heating to reduce dependency on mechanical systems.

• Solar Energy Integration
  • Understanding photovoltaic (PV) systems and how they generate electricity.
  • How solar thermal systems can be used for heating and hot water.
  • Determining the best solar energy system for your building based on location and design.
• Wind and Geothermal Systems
  • Using wind energy for electricity in small-scale applications.
  • Exploring geothermal heating and cooling systems for efficient energy use.
  • How these systems work together to meet energy needs in zero-energy buildings.
• Energy Storage Solutions
  • The importance of energy storage in balancing energy generation and consumption.
  • Overview of battery storage systems and their role in zero-energy buildings.
  • How to integrate energy storage with other renewable energy systems for optimal performance.

• Energy Simulation Software
  • Introduction to popular software tools for energy modeling, including EnergyPlus and IES VE.
  • How to use energy simulations to predict building performance and identify energy-saving opportunities.
  • Interpreting simulation data to make informed design decisions.
• Thermal Simulation and Heat Transfer Analysis
  • The role of thermal modeling in predicting building performance.
  • Understanding heat transfer and how it affects energy use in a building.
  • Techniques for analyzing heat loss through windows, walls, and roofs.
• Lighting and Electrical Systems Modeling
  • Optimizing daylighting to reduce electrical lighting needs.
  • Designing energy-efficient electrical systems for lighting and appliances.
  • How to use modeling to improve electrical load management and reduce energy use.

• Choosing Low-Impact Materials
  • Selecting sustainable building materials with low environmental impact.
  • How to source materials with a focus on reducing embodied energy.
  • The importance of using recycled, reusable, or locally sourced materials in construction.
• Building Orientation and Site Analysis
  • How to select an optimal building site to maximize energy efficiency.
  • The impact of building orientation on solar energy collection and passive heating.
  • Analyzing site features like shading, wind exposure, and terrain to improve performance.
• Advanced Construction Techniques
  • Innovations in building techniques that enhance energy efficiency.
  • The role of prefabrication and modular construction in reducing energy consumption.
  • Using sustainable construction methods to minimize waste and improve long-term performance.

• Post-Occupancy Monitoring
  • The importance of monitoring energy use once the building is in use.
  • Using sensors and real-time data to track energy consumption and make adjustments.
  • Best practices for monitoring systems to ensure the building meets energy goals.
• Energy Efficiency Standards and Certifications
  • An overview of key energy efficiency standards like LEED, BREEAM, and Passive House.
  • How these certifications drive energy-efficient design and influence building performance.
  • The benefits of earning these certifications and their impact on building reputation.
• Future Trends and Innovations
  • The latest technologies in smart grids, building automation, and energy management systems.
  • How innovations in construction and materials are pushing the boundaries of zero-energy design.
  • The potential for zero-energy buildings to evolve into zero-energy communities and urban environments.