表征温度场的空间变异性，以支持自然通风建筑的热模型验证

IF 2.2 4区工程技术 Q2 CONSTRUCTION & BUILDING TECHNOLOGY

Journal of Building Performance Simulation Pub Date : 2023-02-14 DOI:10.1080/19401493.2023.2179115

Chen Chen, Lup Wai Chew, C. Gorlé

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引用次数: 2

摘要

夜间被动冷却是一种节能的冷却策略，但被动冷却系统的设计依赖于不完善的计算模型，这需要验证。在进行模型验证时，本文评估了温度场空间变异性的重要性。对三层中庭建筑的全面温度测量揭示了在自然通风过程中每层的空间变化。用不确定性量化的动态热模型的验证揭示了准确的体积平均空气温度预测。差异在传感器精度()的数量级上，并且主要是由于模型中稍微低估了冷却速率。重要的是，当根据建筑物的内置传感器验证模型时，这种趋势将被错误地识别出来，这些传感器始终记录的温度比体积平均温度高0.05-1.63。这些发现强调了空间可变性和在自然通风的建筑物中仔细放置温度传感器的重要性。

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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Characterizing spatial variability in the temperature field to support thermal model validation in a naturally ventilated building

ABSTRACT Night-time passive cooling is an energy-efficient cooling strategy, but the design of passive cooling systems relies on imperfect computational models, which require validation. This paper assesses the importance of spatial variability in the temperature field when performing model validation. Full-scale temperature measurements in a three story atrium building reveal spatial variability of up to on each floor during the natural ventilation process. Validation of a dynamic thermal model with uncertainty quantification reveals accurate volume-averaged air temperature predictions. Discrepancies are on the order of the sensor accuracy ( ), and are primarily due to slightly under-predicted cooling rates in the model. Importantly, this trend would be identified incorrectly when validating the model against the building's built-in sensors, which consistently record 0.05–1.63 higher temperatures than the volume-averaged air temperature. These findings highlight the importance of spatial variability and careful temperature sensor placement in naturally ventilated buildings.

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来源期刊

Journal of Building Performance Simulation CONSTRUCTION & BUILDING TECHNOLOGY-

CiteScore

5.50

自引率

12.00%

发文量

审稿时长

12 months

期刊介绍： The Journal of Building Performance Simulation (JBPS) aims to make a substantial and lasting contribution to the international building community by supporting our authors and the high-quality, original research they submit. The journal also offers a forum for original review papers and researched case studies We welcome building performance simulation contributions that explore the following topics related to buildings and communities: -Theoretical aspects related to modelling and simulating the physical processes (thermal, air flow, moisture, lighting, acoustics). -Theoretical aspects related to modelling and simulating conventional and innovative energy conversion, storage, distribution, and control systems. -Theoretical aspects related to occupants, weather data, and other boundary conditions. -Methods and algorithms for optimizing the performance of buildings and communities and the systems which service them, including interaction with the electrical grid. -Uncertainty, sensitivity analysis, and calibration. -Methods and algorithms for validating models and for verifying solution methods and tools. -Development and validation of controls-oriented models that are appropriate for model predictive control and/or automated fault detection and diagnostics. -Techniques for educating and training tool users. -Software development techniques and interoperability issues with direct applicability to building performance simulation. -Case studies involving the application of building performance simulation for any stage of the design, construction, commissioning, operation, or management of buildings and the systems which service them are welcomed if they include validation or aspects that make a novel contribution to the knowledge base.