Deterministic and probabilistic occupant-centric control's impacts on the indoor environment in free-running households

IF 3.5 Q3 GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY
F. Akhlaghinezhad, Amir Tabadkani, Hadi Bagheri Sabzevar, Nastaran Seyed Shafavi, Arman Nikkhah Dehnavi
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引用次数: 0

Abstract

PurposeOccupant behavior can lead to considerable uncertainties in thermal comfort and air quality within buildings. To tackle this challenge, the use of probabilistic controls to simulate occupant behavior has emerged as a potential solution. This study seeks to analyze the performance of free-running households by examining adaptive thermal comfort and CO2 concentration, both crucial variables in indoor air quality. The investigation of indoor environment dynamics caused by the occupants' behavior, especially after the COVID-19 pandemic, became increasingly important. Specifically, it investigates 13 distinct window and shading control strategies in courtyard houses to identify the factors that prompt occupants to interact with shading and windows and determine which control approach effectively minimizes the performance gap.Design/methodology/approachThis paper compares commonly used deterministic and probabilistic control functions and their effects on occupant comfort and indoor air quality in four zones surrounding a courtyard. The zones are differentiated by windows facing the courtyard. The study utilizes the energy management system (EMS) functionality of EnergyPlus within an algorithmic interface called Ladybug Tools. By modifying geometrical dimensions, orientation, window-to-wall ratio (WWR) and window operable fraction, a total of 465 cases are analyzed to identify effective control scenarios. According to the literature, these factors were selected because of their potential significant impact on occupants’ thermal comfort and indoor air quality, in addition to the natural ventilation flow rate. Additionally, the Random Forest algorithm is employed to estimate the individual impact of each control scenario on indoor thermal comfort and air quality metrics, including operative temperature and CO2 concentration.FindingsThe findings of the study confirmed that both deterministic and probabilistic window control algorithms were effective in reducing thermal discomfort hours, with reductions of 56.7 and 41.1%, respectively. Deterministic shading controls resulted in a reduction of 18.5%. Implementing the window control strategies led to a significant decrease of 87.8% in indoor CO2 concentration. The sensitivity analysis revealed that outdoor temperature exhibited the strongest positive correlation with indoor operative temperature while showing a negative correlation with indoor CO2 concentration. Furthermore, zone orientation and length were identified as the most influential design variables in achieving the desired performance outcomes.Research limitations/implicationsIt’s important to acknowledge the limitations of this study. Firstly, the potential impact of air circulation through the central zone was not considered. Secondly, the investigated control scenarios may have different impacts on air-conditioned buildings, especially when considering energy consumption. Thirdly, the study heavily relied on simulation tools and algorithms, which may limit its real-world applicability. The accuracy of the simulations depends on the quality of the input data and the assumptions made in the models. Fourthly, the case study is hypothetical in nature to be able to compare different control scenarios and their implications. Lastly, the comparative analysis was limited to a specific climate, which may restrict the generalizability of the findings in different climates.Originality/valueOccupant behavior represents a significant source of uncertainty, particularly during the early stages of design. This study aims to offer a comparative analysis of various deterministic and probabilistic control scenarios that are based on occupant behavior. The study evaluates the effectiveness and validity of these proposed control scenarios, providing valuable insights for design decision-making.
以住户为中心的确定性和概率性控制对自由运行家庭室内环境的影响
目的 使用者的行为会导致建筑物内热舒适度和空气质量出现相当大的不确定性。为了应对这一挑战,使用概率控制来模拟住户行为已成为一种潜在的解决方案。本研究试图通过研究适应性热舒适度和二氧化碳浓度(这两个都是室内空气质量的关键变量)来分析自由运行家庭的性能。特别是在 COVID-19 大流行之后,对由居住者行为引起的室内环境动态的研究变得越来越重要。具体而言,本文研究了四合院中 13 种不同的窗户和遮阳控制策略,以确定促使居住者与遮阳和窗户互动的因素,并确定哪种控制方法能有效地将性能差距降至最低。这些区域根据面向庭院的窗户来区分。该研究在名为瓢虫工具的算法界面中使用了 EnergyPlus 的能源管理系统(EMS)功能。通过修改几何尺寸、朝向、窗墙比(WWR)和窗户可操作部分,共分析了 465 个案例,以确定有效的控制方案。根据文献资料,除自然通风流量外,这些因素还可能对居住者的热舒适度和室内空气质量产生重大影响,因此被选中。此外,还采用了随机森林算法来估算每种控制方案对室内热舒适度和空气质量指标(包括工作温度和二氧化碳浓度)的单独影响。研究结果研究结果证实,确定性和概率性窗户控制算法都能有效减少热不适时间,分别减少了 56.7% 和 41.1%。确定性遮阳控制减少了 18.5%。实施窗户控制策略后,室内二氧化碳浓度显著降低了 87.8%。敏感性分析表明,室外温度与室内工作温度呈最强的正相关,而与室内二氧化碳浓度呈负相关。此外,区域方向和长度被认为是对实现预期性能结果影响最大的设计变量。首先,没有考虑通过中心区域的空气循环的潜在影响。其次,调查的控制方案可能会对空调建筑产生不同的影响,特别是在考虑能耗时。第三,本研究严重依赖模拟工具和算法,这可能会限制其在现实世界中的适用性。模拟的准确性取决于输入数据的质量和模型中的假设。第四,案例研究是假设性的,以便比较不同的控制方案及其影响。最后,比较分析仅限于特定的气候条件,这可能会限制研究结果在不同气候条件下的通用性。原创性/价值住户行为是不确定性的重要来源,尤其是在设计的早期阶段。本研究旨在对基于居住者行为的各种确定性和概率性控制方案进行比较分析。研究评估了这些拟议控制方案的有效性和正确性,为设计决策提供了宝贵的见解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Smart and Sustainable Built Environment
Smart and Sustainable Built Environment GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY-
CiteScore
9.20
自引率
8.30%
发文量
53
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