Design, simulation and control of air- and ground-source variable refrigerant flow heat pump systems

空气源和地源可变制冷剂流量热泵系统的设计、仿真和控制

• 批准号: RGPIN-2018-04471
• 负责人: Cimmino, Massimo
• 金额: $ 1.97万
• 依托单位: École Polytechnique de Montréal
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=754423
• 关键词: Design; simulation; control; air; ground

Variable refrigerant flow (VRF) systems are heat pump systems where a single outdoor unit (i.e. the evaporator in heating mode) is connected to multiple indoor units (i.e. the condensers in heating mode) on a single refrigerant network. The indoor units are distributed across the multiple zones of a building and provide the necessary heating or cooling to their zone. VRF systems have been shown to reduce energy consumption for space cooling when compared to variable air volume systems, but they are rarely considered for heating dominated applications in cold climates. In the context of the Paris Agreement, VRF systems offer a great potential for the reduction of Canada's greenhouse gases emissions.The research program addresses the design, modelling and control of both air-source and ground-source VRF heat pump systems. A simulation model will be developed and validated against measurements in laboratory experiments with controlled environmental conditions (air temperature and humidity). This will allow for the development of new control methods to optimize the operation of VRF systems based on knowledge of the system configuration (e.g. size, number and position of indoor units). The simulation of VRF systems coupled to geothermal heat exchangers necessitates the consideration of short-term effects that arise due to changes of the operating conditions of the system (e.g. fluid flow rate) and long-term effects due in part by thermal interference between individual geothermal heat exchangers. Improvements in simulation techniques of geothermal heat exchangers will allow for the evaluation of the energy performance of ground-source heat pump systems and the potential energetic, environmental and economical benefits of using these systems.In the context of the Montreal Protocol and the Kigali Amendment, alternative refrigerants are needed to replace the current generation of refrigerants, including hydrofluorocarbons (HFCs). With the high refrigerant charge of VRF systems, the use of carbon dioxide (CO2) as the refrigerant could significantly reduce the life-cycle greenhouse gases emissions, especially from leakage and decommissioning. Building upon the simulation tools developed in the research program, a prototype transcritical CO2 VRF system will be designed, built and tested. This project will contribute to the advancement of the next generation of heat pump systems using low-impact refrigerants.

可变制冷剂流量（VRF）系统是热泵系统，其中单个室外单元（即，加热模式下的蒸发器）连接到单个制冷剂网络上的多个室内单元（即，加热模式下的冷凝器）。室内机组分布在建筑物的多个区域，并为其区域提供必要的加热或冷却。与变风量系统相比，VRF系统已被证明可以降低空间冷却的能耗，但在寒冷气候中，很少考虑将其用于以加热为主的应用。在巴黎协定的背景下，VRF系统为减少加拿大的温室气体排放提供了巨大的潜力。该研究计划涉及空气源和地源VRF热泵系统的设计，建模和控制。将开发一个模拟模型，并根据受控环境条件（空气温度和湿度）的实验室实验中的测量值进行验证。这将允许开发新的控制方法，以根据系统配置的知识（例如室内单元的大小，数量和位置）优化VRF系统的操作。耦合到地热热交换器的VRF系统的模拟需要考虑由于系统的操作条件（例如流体流速）的变化而产生的短期影响和部分由于各个地热热交换器之间的热干扰而产生的长期影响。地热换热器模拟技术的改进将有助于评估地源热泵系统的能源性能以及使用这些系统可能带来的能源、环境和经济效益，在《蒙特利尔议定书》和《基加利修正案》的背景下，需要替代制冷剂来取代目前的制冷剂，包括氢氟碳化合物。由于VRF系统的制冷剂充注量很高，使用二氧化碳（CO2）作为制冷剂可以大大减少生命周期的温室气体排放，特别是泄漏和退役造成的排放。在研究计划中开发的仿真工具的基础上，将设计，建造和测试一个原型跨临界CO2 VRF系统。该项目将有助于推进使用低影响制冷剂的下一代热泵系统。