• Energy Research
• 7. Clean energy close
• 12. Responsible consumption close
• GB close
• EU close
• University of Oxford close

Abstract Transient thermal behaviors of ultra-supercritical steam turbine control valves during the cold start warm-up process of steam turbine systems were comprehensively studied using conjugate heat transfer (CHT) simulation. The geometrical configurations and boundary conditions used in simulation were identical to the field setup in a thermal power plant. The simulated temperature variations were first validated using measurements by the flush-mounted thermocouples inside the solid valve bodies. The CHT simulation implementing the shear stress transport (SST) turbulence model demonstrated good agreement with the field data, and the overall numerical errors were below 10%; however, the numerical errors of the simulation, which used empirical heat transfer coefficients at the fluid–solid interfaces, reached 40%. The determined temperature differences between the cold valve bodies with the hot steam flow decreased significantly. Specifically, the temperature differences along the inner wall surfaces of the valve bodies decreased to less than 50 °C. Further investigation of the transient heat flux distributions and Nusselt number distributions confirmed that the unsteady flow behaviors, such as the alternating oscillations of the annular wall-attached jet, the central reverse flow and the intermediate shear layer instabilities, enhanced the fluid–solid heat convection process and thus contributed to the warming up of the solid valve bodies.

Driven by the need to develop a wide variety of products with low environmental impact, biorefineries need to emerge as highly integrated facilities. This becomes effective when overall mass and energy integration through a centralised utility system design is undertaken. An approach combining process integration, energy and greenhouse gas (GHG) emission analyses is shown in this paper for Jatropha biorefinery design, primarily producing biodiesel using oil-based heterogeneously catalysed transesterification or green diesel using hydrotreatment. These processes are coupled with gasification of husk to produce syngas. Syngas is converted into end products, heat, power and methanol in the biodiesel case or hydrogen in the green diesel case. Anaerobic digestion of Jatropha by-products such as fruit shell, cake and/or glycerol has been considered to produce biogas for power generation. Combustion of fruit shell and cake is considered to provide heat. Heat recovery within biodiesel or green diesel production and the design of the utility (heat and power) system are also shown. The biorefinery systems wherein cake supplies heat for oil extraction and seed drying while fruit shells and glycerol provide power generation via anaerobic digestion into biogas achieve energy efficiency of 53 % in the biodiesel system and 57 % in the green diesel system. These values are based on high heating values (HHV) of Jatropha feedstocks, HHV of the corresponding products and excess power generated. Results showed that both systems exhibit an energy yield per unit of land of 83 GJ ha−1. The global warming potential from GHG emissions of the net energy produced (i.e. after covering energy requirements by the biorefinery systems) was 29 g CO2-eq MJ−1, before accounting credits from displacement of fossil-based energy by bioenergy exported from the biorefineries. Using a systematic integration approach for utilisation of whole Jatropha fruit, it is shown that global warming potential and fossil primary energy use can be reduced significantly if the integrated process schemes combined with optimised cultivation and process parameters are adopted in Jatropha-based biorefineries.

Nearly three billion people in low- and middle-income countries (LMICs) rely on polluting fuels, resulting in millions of avoidable deaths annually. Polluting fuels also emit short-lived climate forcers and greenhouse gases (GHGs). Liquefied petroleum gas (LPG) and grid-based electricity are scalable alternatives to polluting fuels but have raised climate and health concerns. Here, we compare emissions and climate impacts of a business-as-usual household cooking fuel trajectory to four large-scale transitions to gas and/or grid electricity in 77 LMICs. We account for upstream and end-use emissions from gas and electric cooking, assuming electrical grids evolve according to the 2022 World Energy Outlook’s “Stated Policies” Scenario. We input the emissions into a reduced-complexity climate model to estimate radiative forcing and temperature changes associated with each scenario. We find full transitions to LPG and/or electricity decrease emissions from both well-mixed GHG and short-lived climate forcers, resulting in a roughly 5 millikelvin global temperature reduction by 2040. Transitions to LPG and/or electricity also reduce annual emissions of PM2.5 by over 6 Mt (99%) by 2040, which would substantially lower health risks from Household Air Pollution. Primary input data was collected from the following sources: Baseline household fuel choices - WHO household energy database (https://www.nature.com/articles/s41467-021-26036-x) End-use emissions - US EPA lifecycle assessment of household fuels (https://cfpub.epa.gov/si/si_public_record_report.cfm?dirEntryId=339679&Lab=NRMRL&simplesearch=0&showcriteria=2&sortby=pubDate&timstype=Published+Report&datebeginpublishedpresented) Upstream emissions - Argonne National Labs GREET Model (https://greet.es.anl.gov/index.php) Current and future population estimates - UNECA (http://data.un.org/Explorer.aspx?d=EDATA) Input data was processed by defining household fuel choice scenarios, estimating national household fuel consumption based on these scenarios, and applying fuel-specific emission factors to create country-specific emission pathways. These emission pathways were input into the FaIR model (https://zenodo.org/record/5513022#.Yt_jfHbMLb0) which generated additional data for each scenario including time series of pollution concentrations, radiative forcing, and temperature changes. All data is provided in CSV format. Nothing proprietary is required. 

This thesis examines the opposition to civil nuclear energy in France and West Germany during the 1970s, arguing that small-scale interactions among its diverse participants led to broad changes in their personal lives and political environments. Drawing extensively on oral history interviews with former activists as well as police reports, media coverage and protest ephemera, this thesis shows how individuals at the grassroots built up a movement that transcended national (and social) borders. They were able to do so in part because nuclear power was such a multivalent symbol at the time. Residents of towns near planned power stations felt that nuclear technology represented an intervention in their community by state and industry, a potential threat to their health, wealth and way of life. In the decade after 1968, concerns like these coalesced with criticisms of capitalism, the state, militarism and consumer society that were being made by a more politicised constituency. This made the anti-nuclear movement both broad-based and highly fragmented. Activist networks linked people across existing national, political and social boundaries, but the social world of activism was subject to its own divisions (such as between locals and outsiders or between militant and non-violent activists). By analysing both the transnational dimensions and internal divisions of the anti-nuclear movement, this thesis revises the homogenising concepts of social movements that are prevalent in much of the existing sociological and political science literature. At the same time, it situates the anti-nuclear movement historically within the decade of upheaval that was the 1970s, while moving individual activists from the margins to the centre of protest history.

We quantify the conditions that might trigger wide spread adoption of alternative fuel vehicles (AFVs) to support energy policy. Empirical review shows that early adopters are heterogeneous motivated by financial benefits, environmental appeal, new technology, and vehicle reliability. A probabilistic Monte Carlo simulation model is used to assess consumer heterogeneity for early and mass market adopters. For early adopters full battery electric vehicles (BEVs) are competitive but unable to surpass diesels or hybrids due to purchase price premium and lack of charging availability. For mass adoption, simulations indicate that if the purchase price premium of a BEV closes to within 20% of an in-class internal combustion engine (ICE) vehicle, combined with a 60% increase in refuelling availability relative to the incumbent system, BEVs become competitive. But this depends on a mass market that values the fuel economy and CO2 reduction benefits associated with BEVs. We also find that the largest influence on early adoption is financial benefit rather than pro-environmental behaviour suggesting that AFVs should be marketed by appealing to economic benefits combined with pro-environmental behaviour to motivate adoption. Monte Carlo simulations combined with scenarios can give insight into diffusion dynamics for other energy demand-side technologies.

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 Social learning is a prerequisite for sustainable energy use. This paper sets out some considerations from learning theory that offer a useful way of looking at domestic energy awareness and at actions to improve energy efficiency and conserve energy. Findings from a survey of residents of an English village that had won an ‘energy-conscious village’ competition are used to illustrate how individual and social learning can occur over a period of time, and how a ‘top down’ initiative may relate to other more informal sources of motivation and information. A model of learning about domestic energy use that incorporates awareness, action and feedback is proposed, and the implications for policy and further research are discussed.

Transit-Oriented Development (TOD) is advocated for achieving sustainable transportation through development around transit stations. TOD’s global implementation revealed varied outcomes, with many cities failing to achieve the intended objectives. TOD implementation in the Jakarta Metropolitan area still in its infancy. Through a geospatial information system and a survey of 400 commuters who live inside the 1 km radius of planned TOD, this longitudinal study aimed to examine an eight-year lapse between 2013 and 2020 of changes in two aspects, specifically land-use and spatial distribution as well as commuters’ travel behavior and preferences in TOD implementation and travel changes due to the COVID-19 pandemic. Key findings are as follows: increased diversity in the residential function around planned TOD areas in the Jakarta capital and a decrease in the suburbs, reflecting the commuters’ improved readiness to reside in planned TOD areas. Furthermore, kinship relations were the commuters’ main reason when selecting house locations, with no capacity to change their workplaces. A significant increase in public facilities at the expense of green open space (GOS) indicates that TOD implementation was conducted by the government with the sole authority to manage GOS, lacking private sector involvement. The cost factor was the most dominant reason for the commuter’s use of public transportation, instead of new transport modes such as MRT and LRT. Moreover, the commuter’s travel behavior in all studied transit stations, whilst it showed evidence of changes in time and frequency, was not greatly influenced by the COVID-19 related restrictions.

To meet the challenges of increased thermal loads and performance demands on aero-engine turbine blades, more advanced cooling techniques are required. This study used a modification of the well-known Goldstein equation to predict film effectiveness for an individual film cooling hole and applied the Sellers’ superposition method to apply these films across effusion-cooled configurations. In doing so, it tackles a relatively unchallenged problem of film holes in close spanwise proximity. An experimental set-up utilised infrared cameras to assess the film effectiveness of nine geometries of varying spanwise and streamwise spacings. Higher porosity led to increased thermal protection, and the spanwise spacing had the most profound impact, with film effectiveness approaching 0.9. Additionally, greater uniformity in the spanwise direction was observed. The modified Goldstein-Sellers method showed good agreement with experimental results although lateral mixing was underestimated. This method represents a tool that could be easily implemented in the industry for rapid assessment of novel cooling geometries.