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Currently active suspension system is more applicable than passive for improving the suspension performance, ensuring the stability and passenger safety in modern automotive suspension system. However, high energy consumption is one of the main disadvantages of implementing this system in real applications. In this paper, the energy consumption of electromagnetic actuators used for an active suspension system controlled by proportional-integral-derivative (PID), fuzzy adaptive PID, and neuron adaptive PID are investigated through simulation studies. Based on the energy consumption and the performance analysis, it has found that it is potential to develop a vibration energy recovery system to achieve the energy balance requirement in active suspension systems.

The EU has set out to reduce negative impacts from electricity generation on the environment, human health and towards our dependence on fossil fuels. As the fastest growing renewable source of electricity, photovoltaics plays an important role in the energy transition. The manufacturing of photovoltaic modules requires materials classified as critical, making them prone to supply disruptions. Although these materials are essential to the EU economy, they are not sufficiently recovered at the end of a photovoltaic module’s life. An alternative intermediate solution could be to extend the lifespan of existing modules, to slow down demand for these materials in the future. The aim of this study was to analyse the theoretical options and practical examples of product life extension strategies for photovoltaics. The R-Ladder was used as a guiding framework, which provided examples of life extension strategies. These include Reuse, Repair, Refurbishment, Remanufacture and Repurpose. Aspects for each of these strategies were analysed to find potential benefits and challenges related to four aspects: economics, environment, energy, and materials. The approach of this study includes a literature review to identify the life extension strategies discussed specifically for photovoltaics in the context of the circular economy. This was followed by a multi-case study on practical applications of Reuse, Repair and Repurposing of photovoltaic modules. Findings from literature and the case study were further supplemented with the insights from six experts. These experts had diverse backgrounds in research, manufacturing, and procurement to offer a variety of insights and perspectives on life extension strategies for photovoltaics. Finally, two scenarios were created for possible life extension pathways for used photovoltaic modules to illustrate the potential impacts compared to a commonplace premature replacement scenario. Economics and module performance are key factors in decision-making and acquisition of a photovoltaic ...

This deliverable includes the methodology in EnergyPROSPECTS for an in-depth study of energy citizenship. It features the criteria used for selecting the cases for indepth study, the list of cases selected for in-depth study as well as key research foci and empirical research questions.

Two types of wind lidar?s have become available for ground-based vertical mean wind and turbulence profiling. A continuous wave (CW) wind lidar, and a pulsed wind lidar. Although they both are build upon the same recent 1.55 μ telecom fibre technology, they possess fundamental differences between their temporal and spatial resolution capabilities. A literature review of the two lidar systems spatial and temporal resolution characteristics will be presented, and the implication for the two lidar types vertical profile measurements of mean wind and turbulence in the lower atmospheric boundary layer will be discussed.

The level of advancement in the understanding of the mechanical properties of volcanic rocks is comparatively lower than that of sedimentary rocks. As part of the SUCCEED Project (Synergetic Utilisation of CO2 Storage Coupled with Geothermal Energy Deployment), which aims to investigate the feasibility of injecting captured and produced CO2 into the reservoirs to enhance geothermal production and achieve permanent CO2 storage at the Hellisheiði Geothermal Field in Iceland, this experimental research provides significant insights into the petrophysical and mechanical properties of the volcanic rocks collected from surface outcrops. The subsurface in Hellisheiði is mainly built up of hyaloclastite formations and interglacial basaltic lavas. During a field campaign samples were collected in different outcrops, ensuring that the samples were of high quality and sufficiently diverse to enable comprehensive analysis. Four samples per block and rock type have been prepared from the collected blocks, and they have been subjected to different laboratory tests to evaluate their petrophysical properties, such as porosity, density, and permeability, and their geomechanical behavior, using Unconfined Compression Test (UCS), Active-Source Acoustic Test, and Splitting Tensile Strength Test. Additionally, laboratory experiments have been conducted to investigate the impact of rapid cooling on rock damage due to thermal fracturing. The results show that there are interdependent relationships between porosity, bulk density, ultimate strength, Young's modulus, and wave velocities that can be observed when considering average values per rock. The rocks studied showed a negative correlation between porosity and other parameters and a direct correlation between ultimate strength and Young's Modulus. When examining individual rock samples, no significant correlations were observed between porosity and other parameters, however, those correlations where evident when comparing between different rock types, emphasizing the importance of ...

> Les pays riches doivent faire beaucoup plus, beaucoup plus vite. L'Assemblée générale des Nations Unies en septembre 2021 réunira les pays à un moment critique pour organiser une action collective pour faire face à la crise environnementale mondiale. Ils se réuniront à nouveau lors du sommet sur la biodiversité à Kunming, en Chine, et de la conférence sur le climat (Conférence des Parties (COP)26) à Glasgow, au Royaume-Uni. Avant ces réunions cruciales, nous - les rédacteurs en chef des revues de santé du monde entier - appelons à une action urgente pour maintenir les augmentations moyennes de la température mondiale en dessous de 1,5 ° C, arrêter la destruction de la nature et protéger la santé. La santé est déjà affectée par l'augmentation de la température mondiale et la destruction du monde naturel, un état de fait sur lequel les professionnels de la santé attirent l'attention depuis des décennies.1 La science est sans équivoque ; une augmentation mondiale de 1,5 ° C au-dessus de la moyenne préindustrielle et la perte continue de la biodiversité risquent de causer des dommages catastrophiques à la santé qu'il sera impossible d'inverser.2 3 Malgré la préoccupation nécessaire du monde concernant la COVID-19, nous ne pouvons pas attendre que la pandémie passe pour réduire rapidement les émissions. Reflétant la gravité du moment, cet éditorial apparaît dans des revues de santé à travers le monde. Nous sommes unis pour reconnaître que seuls des changements fondamentaux et équitables dans les sociétés inverseront notre trajectoire actuelle. Les risques pour la santé des augmentations supérieures à 1,5 °C sont maintenant bien établis.2 En effet, aucune augmentation de température n'est « sûre ». Au cours des 20 dernières années, la mortalité liée à la chaleur chez les personnes âgées de plus de 65 ans a augmenté de plus de 50 %.4 Des températures plus élevées ont entraîné une augmentation de la déshydratation et de la perte de la fonction rénale, des tumeurs malignes dermatologiques, des infections tropicales, des problèmes de santé mentale, des complications de grossesse, des allergies et une morbidité et une mortalité cardiovasculaires et pulmonaires.5 6 Les préjudices affectent de manière disproportionnée les plus vulnérables, notamment les enfants, les populations plus âgées, les minorités ethniques, les communautés les plus pauvres et les personnes ayant des problèmes de santé sous-jacents.2 4 Le réchauffement climatique contribue également à la baisse de ... > Las naciones ricas deben hacer mucho más, mucho más rápido. La Asamblea General de las Naciones Unidas en septiembre de 2021 reunirá a los países en un momento crítico para organizar la acción colectiva para abordar la crisis ambiental mundial. Se reunirán nuevamente en la cumbre de biodiversidad en Kunming, China, y en la conferencia climática (Conferencia de las Partes (COP)26) en Glasgow, Reino Unido. Antes de estas reuniones fundamentales, nosotros, los editores de revistas de salud de todo el mundo, pedimos medidas urgentes para mantener el aumento promedio de la temperatura global por debajo de 1,5 ° C, detener la destrucción de la naturaleza y proteger la salud. La salud ya se está viendo perjudicada por el aumento de la temperatura global y la destrucción del mundo natural, una situación a la que los profesionales de la salud han estado prestando atención durante décadas.1 La ciencia es inequívoca; un aumento global de 1,5 ° C por encima del promedio preindustrial y la continua pérdida de biodiversidad corren el riesgo de causar daños catastróficos a la salud que serán imposibles de revertir.2 3 A pesar de la preocupación necesaria del mundo por el COVID-19, no podemos esperar a que la pandemia pase para reducir rápidamente las emisiones. Como reflejo de la gravedad del momento, este editorial aparece en revistas de salud de todo el mundo. Estamos unidos en el reconocimiento de que solo los cambios fundamentales y equitativos en las sociedades revertirán nuestra trayectoria actual. Los riesgos para la salud de aumentos superiores a 1,5 °C están ahora bien establecidos.2 De hecho, ningún aumento de temperatura es "seguro". En los últimos 20 años, la mortalidad relacionada con el calor entre las personas mayores de 65 años ha aumentado en más del 50%.4 Las temperaturas más altas han provocado un aumento de la deshidratación y la pérdida de la función renal, neoplasias malignas dermatológicas, infecciones tropicales, resultados adversos para la salud mental, complicaciones del embarazo, alergias y morbilidad y mortalidad cardiovascular y pulmonar.5 6 Los daños afectan de manera desproporcionada a los más vulnerables, incluidos los niños, las poblaciones mayores, las minorías étnicas, las comunidades más pobres y las personas con problemas de salud subyacentes.2 4 El calentamiento global también está contribuyendo a la disminución de ... > Wealthy nations must do much more, much faster. The United Nations General Assembly in September 2021 will bring countries together at a critical time for marshalling collective action to tackle the global environmental crisis. They will meet again at the biodiversity summit in Kunming, China, and the climate conference (Conference of the Parties (COP)26) in Glasgow, UK. Ahead of these pivotal meetings, we—the editors of health journals worldwide—call for urgent action to keep average global temperature increases below 1.5°C, halt the destruction of nature and protect health. Health is already being harmed by global temperature increases and the destruction of the natural world, a state of affairs health professionals have been bringing attention to for decades.1 The science is unequivocal; a global increase of 1.5°C above the preindustrial average and the continued loss of biodiversity risk catastrophic harm to health that will be impossible to reverse.2 3 Despite the world's necessary preoccupation with COVID-19, we cannot wait for the pandemic to pass to rapidly reduce emissions. Reflecting the severity of the moment, this editorial appears in health journals across the world. We are united in recognising that only fundamental and equitable changes to societies will reverse our current trajectory. The risks to health of increases above 1.5°C are now well established.2 Indeed, no temperature rise is 'safe'. In the past 20 years, heat-related mortality among people aged over 65 has increased by more than 50%.4 Higher temperatures have brought increased dehydration and renal function loss, dermatological malignancies, tropical infections, adverse mental health outcomes, pregnancy complications, allergies, and cardiovascular and pulmonary morbidity and mortality.5 6 Harms disproportionately affect the most vulnerable, including children, older populations, ethnic minorities, poorer communities and those with underlying health problems.2 4 Global heating is also contributing to the decline in … > يجب على الدول الغنية أن تفعل أكثر من ذلك بكثير، وأسرع بكثير. ستجمع الجمعية العامة للأمم المتحدة في سبتمبر 2021 البلدان في وقت حرج لحشد العمل الجماعي لمعالجة الأزمة البيئية العالمية. وسيجتمعون مرة أخرى في قمة التنوع البيولوجي في كونمينغ، الصين، ومؤتمر المناخ (مؤتمر الأطراف 26) في غلاسكو، المملكة المتحدة. قبل هذه الاجتماعات المحورية، ندعو - نحن محرري المجلات الصحية في جميع أنحاء العالم - إلى اتخاذ إجراءات عاجلة للحفاظ على متوسط الزيادات في درجات الحرارة العالمية أقل من 1.5 درجة مئوية، ووقف تدمير الطبيعة وحماية الصحة. الصحة تتضرر بالفعل من ارتفاع درجات الحرارة العالمية وتدمير العالم الطبيعي، وهو وضع يلفت الانتباه إليه المهنيون الصحيون منذ عقود. 1 العلم لا لبس فيه ؛ زيادة عالمية قدرها 1.5 درجة مئوية فوق متوسط ما قبل الصناعة واستمرار فقدان التنوع البيولوجي خطر ضرر كارثي على الصحة سيكون من المستحيل عكسه. 2 3 على الرغم من الانشغال العالمي الضروري بـ COVID -19، لا يمكننا الانتظار حتى ينتقل الوباء لتقليل الانبعاثات بسرعة. مما يعكس شدة اللحظة، تظهر هذه الافتتاحية في المجلات الصحية في جميع أنحاء العالم. نحن متحدون في الاعتراف بأن التغييرات الأساسية والعادلة في المجتمعات هي وحدها التي ستعكس مسارنا الحالي. أصبحت المخاطر الصحية للزيادات التي تزيد عن 1.5 درجة مئوية ثابتة الآن. 2 في الواقع، لا يوجد ارتفاع في درجة الحرارة "آمن". في السنوات العشرين الماضية، زادت الوفيات المرتبطة بالحرارة بين الأشخاص الذين تزيد أعمارهم عن 65 عامًا بأكثر من 50 ٪.4 وقد أدت درجات الحرارة المرتفعة إلى زيادة الجفاف وفقدان وظائف الكلى، والأورام الخبيثة الجلدية، والالتهابات الاستوائية، والنتائج السلبية للصحة العقلية، ومضاعفات الحمل، والحساسية، واعتلال القلب والأوعية الدموية والرئوية والوفيات .5 6 تؤثر الأضرار بشكل غير متناسب على الفئات الأكثر ضعفًا، بما في ذلك الأطفال وكبار السن والأقليات العرقية والمجتمعات الفقيرة وأولئك الذين يعانون من مشاكل صحية كامنة .2 4 يساهم التدفئة العالمية أيضًا في انخفاض...

Global endeavors to reduce emissions in the shipping industry are accelerating the interest in fuel cell systems. This paper explores the application of different fuel cell types (LT-PEMFC, HT-PEMFC and SOFC) in combination with different fuels (LH2, LNG,MeOH and NH3) in expedition cruise ships. An impact model is developed for the first design phase. The goal of this paper is to evaluate the impact of the combination of fuel cell system implementation and operational profile on expedition cruise vessels. Impact is expressed in ship size, capital cost, operational cost and emissions. The model takes into account: fuel storage, on-board fuel processing, fuel cell system characteristics, balance of plant components, fuel cost over operational lifetime and all onboard emissions. In the research, seven different fuel cell systems and three different hybridization strategies are considered. For the six best performing combinations of fuel cell system and hybridization strategy, the range, endurance and capacity requirements are systematically varied to determine whether the best performing option depends on these requirements. Finally, hybrid option 2 (using diesel generators to support during long transits) combined with a methanol fueled LT-PEMFC system results in the lowest newbuild price. This option does comply with emission regulations and CO2 goals for 2030. Hybrid option 2 combined with an LNG fueled LT-PEMFC system results in the lowest total cost (newbuild price and fuel cost). This option does comply with emission regulations, but does not meet CO2 goals for 2030. When it is desired to reach this CO2 target, hybrid option 2 with methanol fueled LT-PEMFC is also recommended from a total cost perspective. ; Marine Technology

River systems play an important role in the filling of sedimentary basins and record the history of external forcing processes, such as climate, tectonics and sea-level change, acting on them. They are potential reservoirs for oil, gas and water, and can host coal and placer mineral deposits. Because of the complex interplay between the external forcing processes, however, understanding of the genesis of the stratigraphy of river systems and interpreting the stratigraphy correctly is far from straightforward. Current conceptual models are oversimplified, and more insight into the impact of external forcing processes must be gained to improve these models. The aim of this study was to assess the impact of climate (i.e., discharge and sediment influx) on the development of the large-scale stratigraphic architecture of river systems, in isolation and in conjunction with sea-level fluctuations, through an analogue modelling approach. Analogue physical models reproduce the long-term average effects and products of the transport processes in a river system, rather than the transport processes themselves. An advantage of analogue modelling over numerical modelling is that it is hard to make the model fit preconceived notions about the results, making it possible to test and develop conceptual models. The impact of climate (i.e., discharge and sediment influx) on the large-scale stratigraphic architecture of river-delta-shelf-basin systems appears not to be as dominant as the impact of sea-level change, but it does significantly affect the smaller scale stratigraphic architecture, such as the relative size of systems tracts and the rate and extent of erosion. Furthermore, we found a fundamental difference between the impact of changes in discharge and the impact of changes in sediment influx on the yield and mass accumulation at the mouth of a river system. River systems can act as buffers for rapid changes in sediment influx, while they react very rapidly to changes in discharge. Thus, the small-scale stratigraphy at the river mouth is controlled mainly by changes in discharge, and the large-scale stratigraphy is controlled by changes in sediment influx (and sea-level fluctuations). Also, because the response of the river gradient to an increase in discharge is the opposite to its response to an increase in sediment influx (and vice versa), the mass accumulation at the river mouth, combined with the overall stratigraphic architecture of the system, can be used to constrain paleo-discharge and paleo-sediment influx scenarios. Finally, our experiments show that a complex stratigraphic architecture is not necessarily the result of complex forcing, but can result from very simple changes in discharge. To assess the development of the stratigraphy in physical models, a new method for processing the data obtained in the experiments was developed. Series of subsequent digital elevation models of the surface of the model are converted, using custom-made software, into synthetic three-dimensional stratigraphy, containing true isochronous surfaces. This data set contains the development of the system through time in three dimensions, and can be presented in various formats, such as geological maps, geological sections and Wheeler diagrams.