• Energy Research
• 2016-2025close

Le défi dans la conception de bâtiments à énergie zéro (ZEB) est de trouver la meilleure combinaison de stratégies de conception qui seraient confrontées aux problèmes de performance énergétique d'un bâtiment particulier. Cet article décrit la méthodologie et le potentiel de rentabilité pour optimiser la conception d'un bâtiment à énergie nette nulle (NZEB) dans une région à climat froid au Liban ; Cèdres. Plus précisément, l'algorithme génétique de non tri (NSGA-II) est choisi afin de minimiser les demandes thermiques, électriques et le coût du cycle de vie (LCC) tout en atteignant le bilan énergétique net nul ; et ainsi obtenir le front de Pareto. Une technique de prise de décision de classement (ELECTRE III) est appliquée au front de Pareto afin d'obtenir une solution optimale. Un large éventail de mesures d'efficacité énergétique sont étudiées, en plus des systèmes d'énergie solaire utilisés pour produire l'électricité et l'eau chaude nécessaires à des fins domestiques. Les résultats indiquent clairement que, pour la conception d'un NZEB résidentiel en climat froid, il est essentiel de minimiser la charge thermique de l'espace à travers une enveloppe de bâtiment à haute performance thermique. Envelopper un niveau élevé d'isolation est une étape essentielle pour réduire la forte demande de chauffage. Les charges thermiques des bâtiments sont réduites de 33,19 %. De plus, le LCC est diminué de 31,09%. El desafío en el diseño de edificios de energía cero (ZEB) es encontrar la mejor combinación de estrategias de diseño que enfrenten los problemas de rendimiento energético de un edificio en particular. Este documento describe la metodología y el potencial de rentabilidad para optimizar el diseño de edificios de energía neta cero (NZEB) en una región de clima frío en el Líbano; Cedars. Específicamente, se elige el algoritmo genético no clasificador (NSGA-II) para minimizar las demandas térmicas, eléctricas y el coste del ciclo de vida (LCC) mientras se alcanza el balance energético neto cero; y así obtener el frente de Pareto. Se aplica una técnica de toma de decisiones de clasificación (ELECTRE III) al frente de Pareto para obtener una solución óptima. Se investiga una amplia gama de medidas de eficiencia energética, además de que se emplean sistemas de energía solar para producir la electricidad y el agua caliente necesarios para fines domésticos. Los resultados indican claramente que, para diseñar un NZEB residencial en clima frío, es esencial minimizar la carga térmica del espacio a través de una envolvente de edificio con alto rendimiento térmico. Envolver un alto nivel de aislamiento es un paso esencial para disminuir la alta demanda de calefacción. Las cargas térmicas de los edificios disminuyen un 33,19%. Además, el LCC se reduce en un 31,09%. The challenge in Zero energy building (ZEB) design is to find the best combination of design strategies that would face the energy performance problems of a particular building. This paper outlines the methodology and the cost-effectiveness potential for optimizing the design of net-zero energy building (NZEB) in a cold climate region in Lebanon; Cedars. Specifically, the non-sorting genetic algorithm (NSGA-II) is chosen in order to minimize thermal, electrical demands and life cycle cost (LCC) while reaching the net zero energy balance; and thus getting the Pareto-front. A ranking decision making technique (ELECTRE III) is applied to the Pareto-front so as to obtain one optimal solution. A wide range of energy efficiency measures are investigated, besides solar energy systems are employed to produce required electricity and hot water for domestic purposes. The results clearly indicate that, for designing a residential NZEB in cold climate, it is essential to minimize the space thermal load through a building envelope with high thermal performance. Envelop high level of insulation is an essential step to decrease the high heating demand. Building thermal loads are decreased by 33.19%. Moreover the LCC is decreased by 31.09%. يتمثل التحدي في تصميم مبنى الطاقة الصفرية (ZEB) في العثور على أفضل مزيج من استراتيجيات التصميم التي ستواجه مشاكل أداء الطاقة لمبنى معين. تحدد هذه الورقة المنهجية وإمكانية الفعالية من حيث التكلفة لتحسين تصميم بناء الطاقة الصافية الصفرية (NZEB) في منطقة مناخية باردة في لبنان ؛ الأرز. على وجه التحديد، يتم اختيار الخوارزمية الجينية غير الفرز (NSGA - II) من أجل تقليل المتطلبات الحرارية والكهربائية وتكلفة دورة الحياة (LCC) مع الوصول إلى صافي توازن الطاقة الصفري ؛ وبالتالي الحصول على واجهة باريتو. يتم تطبيق تقنية اتخاذ القرار التصنيفي (ELECTRE III) على واجهة باريتو للحصول على حل مثالي واحد. يتم التحقيق في مجموعة واسعة من تدابير كفاءة الطاقة، إلى جانب استخدام أنظمة الطاقة الشمسية لإنتاج الكهرباء والماء الساخن المطلوبين للأغراض المنزلية. تشير النتائج بوضوح إلى أنه لتصميم NZEB سكني في المناخ البارد، من الضروري تقليل الحمل الحراري الفضائي من خلال غلاف مبنى ذو أداء حراري عالٍ. يعد غلاف مستوى عالٍ من العزل خطوة أساسية لتقليل الطلب المرتفع على التدفئة. انخفضت الأحمال الحرارية للمبنى بنسبة 33.19 ٪. علاوة على ذلك، انخفض LCC بنسبة 31.09 ٪.

Abstract Worldwide, the residential buildings are consuming a considerable amount of energy. The high potential of buildings towards energy efficiency has drawn special attention to the passive design parameters. A comprehensive study on optimal passive design for residential buildings is presented in this paper. Twenty-five different climates are simulated with the aim to produce best practices to reduce building energy demands (for cooling and heating) in addition to the life-cycle cost (LCC). The occupants' adaptive thermal comfort is also improved by implementing the appropriate passive cooling strategies such as blinds and natural ventilation. In this respect, the implemented methodology is composed of four phases: building energy simulation, optimization, Multi-criteria Decision Making (MCDM), sensitivity study, and finally an adaptive comfort analysis. An optimal passive solution of the studied building indicates the potential to save up to 54%, 87% and 52% of the cooling demands (Qcool), heating demands (Qheat) and LCC respectively with respect to the initial configuration. The obtained optimal passive parameters are validated with the National Renewable Energy Laboratory NREL benchmark for low energy building's envelope. Additionally, the integrated passive cooling strategies have demonstrated its competency since it leads to a significant overheating decrease.

The thermal conductivity of commonly used phase change materials (PCM) for thermal energy storage (TES), such as, fatty acids, paraffin etc., is relatively poor, which is one of the main drawbacks for limiting their utility. In the recent past, few attempts have been made to enhance the thermal conductivity of PCM by mixing different additives in the appropriate amount. Graphene nanoparticles, having higher thermal conductivity may be a potential candidate for the same, when mixed appropriately with different PCM. In present study authors have carried out the numerical investigation for the melting of graphene nano-particles dispersed PCM filled in an aluminum square cavity heated from one side. In this work, the graphene nanoparticles are mixed in three different volumetric ratios (1%, 3%, and 5%), with three different commonly used categories of organic, inorganic and paraffin PCM (namely, Capric Acid, CaCl2·6H2O, and n-octadecane) to see the effect on melting of composite PCM developed. The resulting transient isotherms, velocity fields, and melting front and melt fractions thus have been deliberated in detail. These results clearly indicate that the addition of graphene nanoparticles increases melting rate but can also hamper the convection heat transfer within large cavities. The study also shows that such enhanced PCM can be effectively used for different TES applications in different fields. The prediction of temperature variation and rate of melting or solidification may be found useful especially for designing such TES devices.

The challenge in Net Zero Energy Building (NZEB) design is to find the best combination of design strategies that will face the energy performance problems of a particular building. This paper presents a methodology for the simulation-based multi-criteria optimization of NZEBs. Its main features include four steps: building simulation, optimization process, multi-criteria decision making (MCDM) and testing solution's robustness. The methodology is applied to investigate the cost-effectiveness potential for optimizing the design of NZEBs in different case studies taken as diverse climatic zones in Lebanon and France. The investigated design parameters include: external walls and roof insulation thickness, windows glazing type, cooling and heating set points, and window to wall ratio. Furthermore, the inspected RE systems include: solar domestic hot water (SDHW) and photovoltaic (PV) array. The proposed methodology is a useful tool to enhance NZEBs design and to facilitate decision making in early phases of building design. Specifically, the non-dominated sorting genetic algorithm (NSGA-II) is chosen in order to minimize thermal, electrical demands and life cycle cost (LCC) while reaching the net zero energy balance; thus getting the Pareto-front. A ranking decision making technique Elimination and Choice Expressing the Reality (ELECTRE III) is applied to the Pareto-front so as to obtain one optimal solution.

Abstract In this paper, melting of a phase change material (PCM) inside a rectangular enclosure, possibly finned and inclined, is studied numerically. The application of this work is related to the temperature control of a finned PV panel filled with PCM and installed at different tilt angles. The studied system is modeled as a 2D rectangular enclosure filled with PCM (RT25) and packed between two aluminum plates, where the front side is exposed to a constant heat flux of 1000 W/m2 for 2 h. Four geometries were considered including a non-finned PCM enclosure, a PCM enclosure with one centered full-width fin, one half-width fin attached to the front plate, and one half-width fin attached to the back plate. Results have shown that the most efficient thermal management of the PV-PCM panel is obtained when the PCM enclosure is equipped with a full-width fin simultaneously attached to the front and back plates. With such a PV panel design, the PCM melting is dominated by natural convection heat transfer from both sides of the PCM enclosure at an early stage, with added heat losses from the back plate to the external environment. Accordingly, low values of the front and back plates temperatures can be maintained during a stabilization time of 80 min as long as the tilt angle is varied from 0° to 75° from the vertical. The efficient temperature control resulting from the full-width fin geometry is mainly related to the high overall heat transfer coefficient obtained during the whole melting process.

International audience

Abstract Phase change materials (PCM) are promising technology to store thermal energy at a constant temperature. A large amount of energy can be stored or released in latent heat form during the transition of material from one phase to another. Despite the great benefits, most PCMs have their own limitations i.e., low phase change enthalpy, poor specific heat and thermal conductivity, supercooling, volume change, phase segregation, etc. Consequently, efficient thermal energy storage requires improving the thermophysical properties of PCMs. The present study is a comprehensive review of existing techniques for PCMs thermophysical properties enhancement. The research progresses on adding zero, one, two, and three-dimensionally structured additives to PCM is assessed to improve the thermal transport by enhancing the PCM effective thermal conductivity. The enhancement of latent heat of fusion and specific heat using various additives is also discussed. Further, the latest techniques on supercooling and phase segregation reduction are also presented. Last, the modelling of the novel composite materials formed by combining a PCM with other materials is presented. Despite the fact that the majority of these methods are still in the research and development stage, some of them have the potential to be commercialized in the near future. Reliable and efficient PCMs are exceptionally useful for storing solar energy and industrial waste heat, especially for constant temperature applications.