Coupling Phase Change Materials and Model Predictive Controls for Energy Efficiency and Thermal Comfort in Canadian Buildings

耦合相变材料和模型预测控制以提高加拿大建筑的能源效率和热舒适度

• 批准号: RGPIN-2017-05481
• 负责人: Kavgic, Miroslava
• 金额: $ 1.68万
• 依托单位: University of Ottawa
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=711665
• 关键词: Coupling; Phase; Change; Materials; Model

Envelope thermal performance requirements are becoming more stringent and the most common compliance approach is to add more insulation. In many cases this may not be practical due to space constraints and greater use of glazing façade systems. An alternative approach is to increase building envelope's thermal storage capacity by incorporating Phase Change Materials. PCMs are innovative products able to store and release large quantities of heat per unit of mass through a phase change from liquid to solid and back near typical room temperatures. The idea is that PCM absorbs part of a building's heat load during the daytime as it melts and releases this heat during the cooler night-time by returning to its solid phase. In the summer, the released heat would be flushed out using natural ventilation or fans, while in the winter it would reduce the heating requirements. However, successful and cost effective application of PCMs in buildings depends on careful selection of many factors including: working temperature range, material thickness, location within the space, and location within the building component. Additionally, the PCM material should be able to completely discharge its absorbed energy during the night to be fully effective. This often requires changes in the operation of heating, ventilation and air-conditioning (HVAC) systems. Model predictive control (MPC) is a multivariable control algorithm that can be used to override conventional HVAC control strategies and provide optimal conditions for a complete phase transition of PCMs in 24-hr. MPC considers thermal response of building systems and future projected climatic conditions to predict the behavior of the systems and apply the appropriate control inputs in advance. Therefore, coupling PCM and MPC-based systems could result in energy savings and thermal comfort improvement in buildings. There is wide interest in PCM and MPC-based building systems by researchers, the construction industry, energy policy makers and home owners. The global PCM market is estimated to grow from $460 million in 2013 to $1.5 billion by 2019. However, the thermo-physical properties of PCM-enhanced materials and their effective building integration have not been fully understood. Further research on development of more robust and reliable algorithms is needed to address challenges that inhibit commercial feasibility of MPC-based technologies. The objective of the proposed research program is to develop optimal design strategies and solutions for integrating PCM and MPC-based systems into buildings that will promote and support changes in the national building codes and the wider use of these technologies. In this 5-year cycle, five students will be trained through a series of innovative laboratory experiments, field studies, and modeling exercises to become Canada's future experts in latent heat and advanced HVAC control technologies.

外壳热性能要求变得越来越严格，最常见的合规方法是增加更多的绝缘。在许多情况下，由于空间限制和更多地使用玻璃幕墙系统，这可能是不实际的。另一种方法是通过加入相变材料来增加建筑围护结构的蓄热能力。相变材料是一种创新产品，能够通过从液体到固体的相变来存储和释放每单位质量的大量热量，并返回到典型的室温附近。这个想法是，PCM吸收建筑物的热负荷的一部分，在白天，因为它融化和释放这些热量在较冷的夜间返回到其固体相。在夏季，释放的热量将通过自然通风或风扇排出，而在冬季，它将减少供暖需求。 然而，PCM在建筑物中的成功和成本效益的应用取决于许多因素的仔细选择，包括：工作温度范围，材料厚度，空间内的位置以及建筑构件内的位置。此外，PCM材料应该能够在夜间完全释放其吸收的能量，以充分发挥作用。这通常需要改变供暖、通风和空调（HVAC）系统的运行。模型预测控制（MPC）是一种多变量控制算法，可用于超越传统的HVAC控制策略，并为PCM在24小时内完成相变提供最佳条件。MPC考虑建筑系统的热响应和未来预计的气候条件，以预测系统的行为，并提前应用适当的控制输入。因此，耦合PCM和MPC为基础的系统可以导致节能和热舒适性的改善建筑。 研究人员、建筑行业、能源政策制定者和业主对基于PCM和MPC的建筑系统有着广泛的兴趣。全球PCM市场预计将从2013年的4.6亿美元增长到2019年的15亿美元。然而，PCM增强材料的热物理性能及其有效的建筑一体化尚未得到充分理解。需要进一步研究开发更强大和可靠的算法，以解决抑制基于MPC的技术的商业可行性的挑战。拟议研究计划的目标是开发最佳设计策略和解决方案，将PCM和MPC系统集成到建筑物中，促进和支持国家建筑法规的变化以及这些技术的更广泛使用。在这个为期5年的周期中，五名学生将通过一系列创新的实验室实验，实地研究和建模练习进行培训，成为加拿大未来潜热和先进HVAC控制技术的专家。