Carbon neutrality refers to achieving net zero carbon dioxide emissions by balancing carbon dioxide emissions with removal. It is critical for achieving the global climate change targets. At present, tackling climate change has become the biggest challenge facing human development, and taking active measures to cope with climate change has become the consensus of all mankind. Under such circumstances, more and more countries and regions have joined the carbon reduction camp, issued carbon neutral targets one after another, actively challenged climate policies, and spawned a new round of energy technology and industrial revolution. Under this target, the major countries in the world have an arduous task to reduce emissions. They must build a clean, low-carbon, secure and efficient new energy system, accelerate the transformation to an energy system centered on renewable energy, and accelerate the process of deep decarbonization of the energy system.
The integrated energy system refers to the use of advanced physical information technology and innovative management mode in a certain region to integrate coal, oil, natural gas, electric energy, heat energy and other energy sources in the region to achieve coordinated planning, optimized operation, cooperative management, interactive response and mutual complementarity among various heterogeneous energy subsystems. It is a new integrated energy system that can effectively improve energy efficiency and promote sustainable energy development while meeting diversified energy demand in the system. In this context, it is urgent to carry out key technology research and practice of low-carbon integrated energy systems to provide theoretical support and technical reference for the current and future development of low-carbon integrated energy systems.
Potential topics include but are not limited to the following:
• Form structure and development path of the integrated energy system
• Integrated energy system architecture design and optimization planning
• Integrated energy system energy management and operation scheduling
• "Source-load" prediction and collaborative control of integrated energy system
• Market mechanism and trading mode of the integrated energy system
• Integrated energy system engineering practice and demonstration application
• Integrated energy systems on disruptive technologies and cases
Carbon neutrality refers to achieving net zero carbon dioxide emissions by balancing carbon dioxide emissions with removal. It is critical for achieving the global climate change targets. At present, tackling climate change has become the biggest challenge facing human development, and taking active measures to cope with climate change has become the consensus of all mankind. Under such circumstances, more and more countries and regions have joined the carbon reduction camp, issued carbon neutral targets one after another, actively challenged climate policies, and spawned a new round of energy technology and industrial revolution. Under this target, the major countries in the world have an arduous task to reduce emissions. They must build a clean, low-carbon, secure and efficient new energy system, accelerate the transformation to an energy system centered on renewable energy, and accelerate the process of deep decarbonization of the energy system.
The integrated energy system refers to the use of advanced physical information technology and innovative management mode in a certain region to integrate coal, oil, natural gas, electric energy, heat energy and other energy sources in the region to achieve coordinated planning, optimized operation, cooperative management, interactive response and mutual complementarity among various heterogeneous energy subsystems. It is a new integrated energy system that can effectively improve energy efficiency and promote sustainable energy development while meeting diversified energy demand in the system. In this context, it is urgent to carry out key technology research and practice of low-carbon integrated energy systems to provide theoretical support and technical reference for the current and future development of low-carbon integrated energy systems.
Potential topics include but are not limited to the following:
• Form structure and development path of the integrated energy system
• Integrated energy system architecture design and optimization planning
• Integrated energy system energy management and operation scheduling
• "Source-load" prediction and collaborative control of integrated energy system
• Market mechanism and trading mode of the integrated energy system
• Integrated energy system engineering practice and demonstration application
• Integrated energy systems on disruptive technologies and cases