• Energy Research

Abstract Rapid urban growth and enhanced quality of life have significantly increased the demands for indoor heating, especially in the developing world. In Chile, this demand is provided largely through low quality biomass which creates pollution problems. Due to the medium to high solar resource in most of Chile, solar thermal networks with seasonal thermal storage should be considered. In this paper, we assessed the use of solar energy with seasonal thermal energy storage to provide domestic heating through a heat network. For this, we performed a simulation-based multi-objective optimisation of the system’s design with cost and greenhouse gas emissions as objectives for two locations in Chile. Our results show that solar thermal networks are cost-competitive with conventional alternatives. Furthermore, the inclusion of seasonal thermal storage could improve the system performance decreasing the emissions by around 90% while increasing the L C O E by less than 20% compared with a conventional gas-heated network or resistive electric heating. We found that for specific system configurations and locations solar district heating with long term storage could be cost-competitive with burning firewood if externalities such as the social costs of local pollution were considered in the economic analysis.

Offshore wind farms are a rapidly developing source of clean, low-carbon energy and as they continue to grow in scale and capacity, so does the requirement for their efficient and optimised operation and maintenance. Historically, approaches to maintenance have been purely reactive. However, there is a movement in offshore wind, and wider industry in general, towards more proactive, condition-based maintenance approaches which rely on operational data-driven decision making. This paper reviews the current efforts in proactive maintenance strategies, both predictive and prescriptive, of which the latter is an evolution of the former. Both use operational data to determine whether a turbine component will fail in order to provide sufficient warning to carry out necessary maintenance. Prescriptive strategies also provide optimised maintenance actions, incorporating predictions into a wider maintenance plan to address predicted failure modes. Beginning with a summary of common techniques used across both strategies, this review moves on to discuss their respective applications in offshore wind operation and maintenance. This review concludes with suggested areas for future work, underlining the need for models which can be simply incorporated by site operators and integrate live data whilst handling uncertainties. A need for further focus on medium-term planning strategies is also highlighted along with consideration of the question of how to quantify the impact of a proactive maintenance strategy.

One of the greatest challenges for long-term emissions reduction is the decarbonisation of heating and cooling due to the large scale, seasonal variation and distributed nature. Energy flexible buildings with electric heating, smart demand-side management and efficient thermal energy storage are one of the most promising strategies to deploy low-carbon technologies which can benefit the electricity system by reducing the need of reinforcing existing networks and their ability to use electricity in times of low demand and high supply. Combined with spot price contracts, in which the electricity tariff changes every half-hour depending on supply and demand, they can effectively reduce on-peak demand periods, achieve economic profits for end-users and retailers, and reduce the environmental impact of the electricity grid by operating in periods with lower CO2 emissions rate. To achieve these benefits, it is crucial to develop accurate models for energy flexible buildings as well as control strategies to optimise the complex system operation. This paper proposes a novel flexible energy building concept, based on smart control, high density latent heat storage and smart grids, able to predict the best operational strategy according to the environmental conditions, economic rates and expected occupancy patterns. The smart integration model, carried out in TRNSYS for a Scottish case study, solves a multi-criteria assessment based on future energy demand prediction (learning machine model supported by end-user’s predefined occupancy by Internet of Things, present and forecast weather data, and building load monitoring), electricity tariff evolution and building performance. The results show that end-user’s electricity bill savings of 20% are obtained and retailer’s associated electricity cost is reduced by 25%. In addition, despite an increase in final energy consumption of up to 8%, the environmental impact remains constant due to operation at times with lower CO2 emissions rate in electricity generation. The developed tools enable the design of smart energy systems for energy flexible buildings which can have a large positive impact on the building sector decarbonisation. Premio Trimestral Publicación Científica Destacada de la US. Instituto Universitario de Arquitectura y Ciencias de la Construcción

Abstract Heat demand in buildings is responsible for around 40% of all energy use in middle to high latitude countries. The combination of district heating systems with solar thermal energy and seasonal thermal energy storage has successfully reduced the carbon intensity of heating in different countries, such as Denmark, Germany and Canada. The potentials of such systems to decarbonise the heat demand in the UK has also been highlighted in different reports. Nevertheless, bottom-up quantitative studies to support or dismissive these potentials are very limited. The quantification can be provided by simulating a solar district heating system using UK-specific inputs, such as heat demand and weather profiles. In this study, a validated simulation model is used to study the performance of solar district heating systems with seasonal thermal storage deployed in the UK. The case study is based on the Drake Landing Solar Community in Okotoks, Canada, which has a relatively high solar fraction. The results show that the system is technically feasible to be implemented in the UK but that it has lower technical performance. A systematic analysis of the influence of the main components on the system performance shows that not only the solar supply and heat demand need to be balanced but also that the long-term storage needs to be appropriately sized. The relatively lower solar fraction could be offset by installing more long-term storage and implementing the system to supply new-built houses with better energy performance rather than the current building stock of older homes. Financially, the system still needs to be supported by encouraging policies to make it competitive with incumbent technologies. The results and the validated model open the possibility to design bespoke solar district heating systems for the UK and other countries in middle to high latitudes.

AbstractIntegrated Gasification Combined Cycles (IGCCs) are one of the emerging clean coal technologies which paves the way for producing power from coal with a higher net power efficiency than conventional PC-fired boiler power plants. It is also advantageous that in an IGCC power plant a carbon capture unit can be applied to a stream having a very high CO2 partial pressure upstream of gas combustion that would not be available in case of a PC-fired boiler power plant, leading to less energy penalty involved in the carbon capture. In this study it is aimed to design a cogeneration process where a Hydrogen Pressure Swing Adsorption (H2 PSA) unit is retrofitted to an IGCC power plant with pre-combustion capture for producing ultrapure hydrogen (99.99+ vol%). The ultrapure hydrogen is commonly utilised as feedstock for deep desulphurisation and hydrocracking units at refineries as well as H2 fuel cells. It is found that, at the same H2 purity of 99.99+%, the hydrogen recovery could be improved up to 93% with the increasing number of columns. Improving the H2 recovery at the H2 PSA to its maximum can contribute to reducing the power consumption for compressing the H2 PSA tail gas by minimizing the yield of the H2 PSA tail gas by-product. Furthermore, it is demonstrated that the H2 PSA can also be designed to achieve 90% H2 recovery even when a portion of the tail gas is recycled to the shift reactors in order to improve the overall advanced IGCC performance by increasing the H2 yield and by reducing the auxiliary power consumption at carbon capture unit.

De nouveaux systèmes de refroidissement renouvelables sont nécessaires dans le monde entier pour répondre à la demande croissante de refroidissement. Cette étude propose et démontre une nouvelle intégration du refroidissement par absorption solaire avec le stockage de chaleur latente afin de maximiser l'utilisation de l'énergie renouvelable pour le refroidissement dans des climats extrêmement chauds. Une analyse paramétrique a été réalisée dans TRNSYS pour identifier les paramètres critiques pour un dimensionnement optimal liés à la taille du champ solaire, au volume du réservoir, à l'isolation du réservoir, au point de consigne de chauffage auxiliaire et à l'angle d'inclinaison du collecteur. De plus, l'intégration a été comparée à un système de refroidissement par absorption solaire conventionnel utilisant un stockage de chaleur sensible (un réservoir d'eau chaude) et un système de refroidissement par compression de vapeur électrique. Les résultats montrent qu'une taille de champ solaire de 1,5 m2/kWc, un volume de réservoir de stockage de chaleur latente de 30 L/m2, une isolation adéquate inférieure à 0,8 W/m2.K et des températures de consigne appropriées pour la chaudière auxiliaire fournissent les performances optimales pour maximiser la fraction solaire. Par rapport au refroidissement par absorption solaire conventionnel, l'étude démontre comment le matériau à changement de phase (PCM) a augmenté la fraction solaire de 4,2 % (de 70,3 à 74,5 %) en raison d'une température stable plus élevée et de pertes de réservoir plus faibles (réduites de 44 %). En outre, malgré le coût d'investissement initial plus élevé du système de refroidissement solaire à base de PCM proposé par rapport au système de refroidissement par compression de vapeur, les résultats soulignent que le coût du cycle de vie est beaucoup plus faible dans les climats extrêmement chauds. Après 25 ans, le coût du cycle de vie a été réduit de 34 % par rapport à la compression de vapeur et de 9 % par rapport à un système de refroidissement solaire conventionnel. Par rapport à la technologie de réfrigérant à compression de vapeur, le système proposé peut économiser 31,6 % d'énergie primaire et 1 222 kg de CO2eq par an. Cette recherche fournit des informations précieuses sur la conception et l'intégration optimales du refroidissement renouvelable pour les applications résidentielles dans les régions extrêmement chaudes. Se requieren nuevos sistemas de refrigeración renovables en todo el mundo para hacer frente a la creciente demanda de refrigeración. Este estudio propone y demuestra una nueva integración de la refrigeración por absorción solar con el almacenamiento de calor latente para maximizar el uso de energía renovable para la refrigeración en climas extremadamente cálidos. Se realizó un análisis paramétrico en TRNSYS para identificar los parámetros críticos para el dimensionamiento óptimo relacionados con el tamaño del campo solar, el volumen del tanque, el aislamiento del tanque, el punto de ajuste de la calefacción auxiliar y el ángulo de inclinación del colector. Además, la integración se comparó con un sistema de enfriamiento por absorción impulsado por energía solar convencional que utiliza almacenamiento de calor sensible (un tanque de agua caliente) y un sistema de enfriamiento por compresión de vapor impulsado por electricidad. Los resultados muestran que un tamaño del campo solar de 1,5 m2/kWc, un volumen del tanque de almacenamiento de calor latente de 30 L/m2, un aislamiento adecuado por debajo de 0,8 W/m2.K y temperaturas de consigna adecuadas para la caldera auxiliar proporcionan el rendimiento óptimo para maximizar la fracción solar. En comparación con el enfriamiento por absorción solar convencional, el estudio demuestra cómo el material de cambio de fase (PCM) aumentó la fracción solar en un 4,2 % (de 70,3 a 74,5 %) debido a una mayor temperatura estable y menores pérdidas del tanque (reducidas en un 44 %). Además, a pesar del mayor coste de inversión inicial del sistema de refrigeración solar basado en PCM propuesto en comparación con el sistema de refrigeración por compresión de vapor, los hallazgos destacan que el coste del ciclo de vida es mucho menor en climas extremadamente cálidos. Después de 25 años, el coste del ciclo de vida se redujo en un 34 % en comparación con la compresión de vapor y en un 9 % en comparación con un sistema de refrigeración convencional impulsado por energía solar. En comparación con la tecnología de refrigerante por compresión de vapor, el sistema propuesto puede ahorrar el 31,6 % de la energía primaria y 1222 kgCO2eq al año. Esta investigación proporciona información valiosa sobre el diseño y la integración óptimos de la refrigeración renovable para aplicaciones residenciales en regiones extremadamente calurosas. Novel renewable cooling systems are required worldwide to address the growing demand for cooling. This study proposes and demonstrates a novel integration of solar-driven absorption cooling with latent heat storage to maximise the use of renewable energy for cooling in extremely hot climates. A parametric analysis was performed in TRNSYS to identify the critical parameters for optimal sizing related to the solar field size, tank volume, tank insulation, auxiliary heating set point, and collector tilt angle. Moreover, the integration was compared with a conventional solar-driven absorption cooling system using sensible heat storage (a hot water tank) and an electric-driven vapour compression cooling system. The results show that a solar field size of 1.5 m2/kWc, a latent heat storage tank volume of 30 L/m2, adequate insulation below 0.8 W/m2.K, and appropriate set-point temperatures for the auxiliary boiler provide the optimal performance to maximise the solar fraction. Compared with conventional solar-driven absorption cooling, the study demonstrates how the phase change material (PCM) increased the solar fraction by 4.2 % (from 70.3 to 74.5 %) due to higher stable temperature and lower tank losses (reduced by 44 %). In addition, despite the higher initial investment cost of the proposed PCM-based solar-driven cooling system compared to the vapour compression cooling system, the findings highlight that the life cycle cost is much lower in extremely hot climates. After 25 years, the life cycle cost was lowered by 34 % compared to vapour compression and by 9 % compared to a conventional solar-driven cooling system. Compared to vapour compression refrigerant technology, the proposed system can save 31.6 % of primary energy and 1222 kgCO2eq annually. This research provides valuable insights into the optimal design and integration of renewable cooling for residential applications in extremely hot regions. هناك حاجة إلى أنظمة تبريد متجددة جديدة في جميع أنحاء العالم لتلبية الطلب المتزايد على التبريد. تقترح هذه الدراسة وتوضح تكاملًا جديدًا للتبريد بالامتصاص المدفوع بالطاقة الشمسية مع التخزين الحراري الكامن لتعظيم استخدام الطاقة المتجددة للتبريد في المناخات الحارة للغاية. تم إجراء تحليل بارامتري في TRNSYS لتحديد المعلمات الحرجة للتحجيم الأمثل المتعلق بحجم الحقل الشمسي وحجم الخزان وعزل الخزان ونقطة ضبط التسخين الإضافية وزاوية إمالة المجمع. علاوة على ذلك، تمت مقارنة التكامل مع نظام تبريد الامتصاص التقليدي الذي يعمل بالطاقة الشمسية باستخدام تخزين الحرارة المعقول (خزان الماء الساخن) ونظام تبريد ضغط البخار الذي يعمل بالكهرباء. تظهر النتائج أن حجم الحقل الشمسي 1.5 متر مربع/كيلو واط مكعب، وحجم خزان تخزين الحرارة الكامن 30 لتر/متر مربع، والعزل الكافي أقل من 0.8 واط/متر مربع، ودرجات حرارة نقطة الضبط المناسبة للغلاية المساعدة توفر الأداء الأمثل لتحقيق أقصى قدر من الجزء الشمسي. مقارنة بالتبريد بالامتصاص التقليدي القائم على الطاقة الشمسية، توضح الدراسة كيف زادت مادة تغيير الطور (PCM) من الجزء الشمسي بنسبة 4.2 ٪ (من 70.3 إلى 74.5 ٪) بسبب ارتفاع درجة الحرارة المستقرة وانخفاض خسائر الخزان (انخفضت بنسبة 44 ٪). بالإضافة إلى ذلك، على الرغم من ارتفاع تكلفة الاستثمار الأولي لنظام التبريد المقترح القائم على الطاقة الشمسية PCM مقارنة بنظام تبريد ضغط البخار، فإن النتائج تسلط الضوء على أن تكلفة دورة الحياة أقل بكثير في المناخات الحارة للغاية. بعد 25 عامًا، انخفضت تكلفة دورة الحياة بنسبة 34 ٪ مقارنة بضغط البخار وبنسبة 9 ٪ مقارنة بنظام التبريد التقليدي الذي يعمل بالطاقة الشمسية. بالمقارنة مع تقنية تبريد ضغط البخار، يمكن للنظام المقترح توفير 31.6 ٪ من الطاقة الأولية و 1222 كجم من مكافئ ثاني أكسيد الكربون سنويًا. يوفر هذا البحث رؤى قيمة حول التصميم الأمثل ودمج التبريد المتجدد للتطبيقات السكنية في المناطق شديدة الحرارة.

Abstract Concentrated solar power (CSP) and photovoltaics (PV) systems integrated with energy storage have large potential to provide cost-competitive and baseload renewable energy. On the one hand, CSP with thermal energy storage (TES) is an affordable and dispatchable option. On the other hand, Electrical Energy Storage (EES) gives dispatchability to PV systems but at high costs due to current prices of EES systems, however an extreme reduction in EES costs is expected. Therefore, there could be a tipping point at which PV + EES becomes the best technology to provide dispatchable power. Here, we explore different scenarios, representing snapshots of technology investment costs according to published projections, in order to identify the dominant technology in a hybrid solar power plant that provides sustainable and dispatchable energy by 2050. The study uses our two-stage multi-objective optimisation framework, in order to optimise the design and operation of a hybrid power plant with energy storage. We found that nowadays CSP with TES is the most affordable technology, but a shift to PV with EES is expected mainly due to the large reduction in the cost of both PV and EES systems. Thus, the presented optimisation analysis can improve the strategies for the design of an effective and economic pathway to decarbonise the power sector.