3,013 research outputs found

    Temperature Reduction Technologies Meet Asphalt Pavement: Green and Sustainability

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    This Special Issue, "Temperature Reduction Technologies Meet Asphalt Pavement: Green and Sustainability", covers various subjects related to advanced temperature reduction technologies in bituminous materials. It can help civil engineers and material scientists better identify underlying views for sustainable pavement constructions

    Proceedings of SIRM 2023 - The 15th European Conference on Rotordynamics

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    It was our great honor and pleasure to host the SIRM Conference after 2003 and 2011 for the third time in Darmstadt. Rotordynamics covers a huge variety of different applications and challenges which are all in the scope of this conference. The conference was opened with a keynote lecture given by Rainer Nordmann, one of the three founders of SIRM “Schwingungen in rotierenden Maschinen”. In total 53 papers passed our strict review process and were presented. This impressively shows that rotordynamics is relevant as ever. These contributions cover a very wide spectrum of session topics: fluid bearings and seals; air foil bearings; magnetic bearings; rotor blade interaction; rotor fluid interactions; unbalance and balancing; vibrations in turbomachines; vibration control; instability; electrical machines; monitoring, identification and diagnosis; advanced numerical tools and nonlinearities as well as general rotordynamics. The international character of the conference has been significantly enhanced by the Scientific Board since the 14th SIRM resulting on one hand in an expanded Scientific Committee which meanwhile consists of 31 members from 13 different European countries and on the other hand in the new name “European Conference on Rotordynamics”. This new international profile has also been emphasized by participants of the 15th SIRM coming from 17 different countries out of three continents. We experienced a vital discussion and dialogue between industry and academia at the conference where roughly one third of the papers were presented by industry and two thirds by academia being an excellent basis to follow a bidirectional transfer what we call xchange at Technical University of Darmstadt. At this point we also want to give our special thanks to the eleven industry sponsors for their great support of the conference. On behalf of the Darmstadt Local Committee I welcome you to read the papers of the 15th SIRM giving you further insight into the topics and presentations

    Beam scanning by liquid-crystal biasing in a modified SIW structure

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    A fixed-frequency beam-scanning 1D antenna based on Liquid Crystals (LCs) is designed for application in 2D scanning with lateral alignment. The 2D array environment imposes full decoupling of adjacent 1D antennas, which often conflicts with the LC requirement of DC biasing: the proposed design accommodates both. The LC medium is placed inside a Substrate Integrated Waveguide (SIW) modified to work as a Groove Gap Waveguide, with radiating slots etched on the upper broad wall, that radiates as a Leaky-Wave Antenna (LWA). This allows effective application of the DC bias voltage needed for tuning the LCs. At the same time, the RF field remains laterally confined, enabling the possibility to lay several antennas in parallel and achieve 2D beam scanning. The design is validated by simulation employing the actual properties of a commercial LC medium

    A review of solar hybrid photovoltaic-thermal (PV-T) collectors and systems

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    In this paper, we provide a comprehensive overview of the state-of-the-art in hybrid PV-T collectors and the wider systems within which they can be implemented, and assess the worldwide energy and carbon mitigation potential of these systems. We cover both experimental and computational studies, identify opportunities for performance enhancement, pathways for collector innovation, and implications of their wider deployment at the solar-generation system level. First, we classify and review the main types of PV-T collectors, including air-based, liquid-based, dual air–water, heat-pipe, building integrated and concentrated PV-T collectors. This is followed by a presentation of performance enhancement opportunities and pathways for collector innovation. Here, we address state-of-the-art design modifications, next-generation PV cell technologies, selective coatings, spectral splitting and nanofluids. Beyond this, we address wider PV-T systems and their applications, comprising a thorough review of solar combined heat and power (S–CHP), solar cooling, solar combined cooling, heat and power (S–CCHP), solar desalination, solar drying and solar for hydrogen production systems. This includes a specific review of potential performance and cost improvements and opportunities at the solar-generation system level in thermal energy storage, control and demand-side management. Subsequently, a set of the most promising PV-T systems is assessed to analyse their carbon mitigation potential and how this technology might fit within pathways for global decarbonization. It is estimated that the REmap baseline emission curve can be reduced by more than 16% in 2030 if the uptake of solar PV-T technologies can be promoted. Finally, the review turns to a critical examination of key challenges for the adoption of PV-T technology and recommendations

    Responsive Building Envelope for Grid-Interactive Efficient Buildings – Thermal Performance and Control

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    The building sector accounts for 30% of total energy consumption worldwide. Responsive building envelopes (or RBEs) are one of the approaches to achieving net-zero energy and grid-interactive efficient buildings. However, research and development of RBEs are still in the early stages of technologies, simulation, control, and design. The control strategies in prior studies did not fully explore the potential of RBEs or they obtained good performance with high design and deployment costs. A low-cost strategy that does not require knowledge of complex systems is needed, while no studies have investigated online implementations of model-free control approaches for RBEs. To address these challenges, this dissertation describes a multidisciplinary study of the modeling, control, and design of RBEs, to understand mechanisms governing their dynamic properties and synthesis rules of multiple technologies through simulation analyses. Widely applicable mathematical models are developed that can be easily extended for multiple RBE types with validation. Computational frameworks (or co-simulation testbeds) that flexibly integrate multiple control methods and building simulation models are established with higher computation efficiency than that using commercial software during offline training. To overcome the limitations of the control strategies (e.g., rule-based control and MPC) in prior research, a novel easy-to-implement yet flexible ‘demand-based’ control strategy, and model-free online control strategies using deep reinforced learning are proposed for RBEs composed of active insulation systems (AISs). Both the physics-derived and model-free control strategies fully leverage the advantages of AISs and provide higher energy savings and thermal comfort improvement over traditional temperature-based control methods in prior research and demand-based control. The case studies of RBEs that integrate AISs and high thermal mass or self-adaptive/active modules (e.g., evaporative cooling techniques and dynamic glazing/shading) demonstrate the superior performance of AISs in regulating thermal energy transfer to offset AC demands during the synergy. Moreover, the controller design and training implications are elaborated. The applicability assessment of promising RBE configurations is presented along with design implications based on building energy analyses in multiple scenarios. The design and control implications represent an interactive and holistic way to operate RBEs allowing energy and thermal comfort performances to be tuned for maximum efficiency

    A Review of Solar Hybrid Photovoltaic-Thermal (PV-T) Collectors and Systems

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    In this paper, we provide a comprehensive overview of the state-of-the-art in hybrid PV-T collectors and the wider systems within which they can be implemented, and assess the worldwide energy and carbon mitigation potential of these systems. We cover both experimental and computational studies, identify opportunities for performance enhancement, pathways for collector innovation, and implications of their wider deployment at the solar-generation system level. First, we classify and review the main types of PV-T collectors, including air-based, liquid-based, dual air–water, heat-pipe, building integrated and concentrated PV-T collectors. This is followed by a presentation of performance enhancement opportunities and pathways for collector innovation. Here, we address state-of-the-art design modifications, next-generation PV cell technologies, selective coatings, spectral splitting and nanofluids. Beyond this, we address wider PV-T systems and their applications, comprising a thorough review of solar combined heat and power (S–CHP), solar cooling, solar combined cooling, heat and power (S–CCHP), solar desalination, solar drying and solar for hydrogen production systems. This includes a specific review of potential performance and cost improvements and opportunities at the solar-generation system level in thermal energy storage, control and demand-side management. Subsequently, a set of the most promising PV-T systems is assessed to analyse their carbon mitigation potential and how this technology might fit within pathways for global decarbonization. It is estimated that the REmap baseline emission curve can be reduced by more than 16% in 2030 if the uptake of solar PV-T technologies can be promoted. Finally, the review turns to a critical examination of key challenges for the adoption of PV-T technology and recommendations

    Advanced Manufacturing of Multilayer Ceramic Composites for Application in Solid Oxide Fuel Cells

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    This thesis investigates advanced techniques to control multilayer ceramic composite (MCC) 3D geometry and layer architecture. MCCs have tremendous potential to significantly change a variety of fields due to their ability to withstand extreme environments. However, our limited ability to shape them into complex objects impedes these efforts. To address this issue, two techniques have been introduced: fill coating and bilayer shrinkage driven self-shaping. Central to both techniques is the control of residual stresses experienced by MCCs during sintering. In the case of fill coating and the control of layer architecture, these residual stresses needed to be reduced to prevent the fracture of the novel internal cathode tubular solid oxide fuel cell (IC-tSOFC). This was achieved with the adoption of extended sintering procedures which promoted plastic deformation processes like creep stress relaxation. The novel fill coating technique used to produce IC-tSOFCs was then investigated using scanning electron microscopy (SEM) to ensure that the deposited films were highly uniform and comparable to films deposited using the more mature dip coating technique. The electrochemical performance of the IC-tSOFC was then thoroughly evaluated on a variety of fuel streams including pure hydrogen, dilute hydrogen, simulated exhaust from a boiler, and simulated exhaust from a two-stroke internal combustion engine. The second focus of this thesis takes advantage of the residual stresses that complicated IC-tSOFC development rather than dissipating them. By using the mismatch in the thermal expansion coefficient between adjacent layers within planar MCCs, curvature may be introduced. Substrates were produced using tape casting and a thin film was then added to this substrate using aerosol spray deposition. By controlling the thickness of the substrate and film, as well as the 2D shape of the substrate and pattern of the applied film, the curvature and shape of the final self-formed part was controlled. Beyond demonstration of this novel manufacturing technique, investigation into curvature and shape prediction using analytical and finite element method (FEM) modeling enabled the development of a methodology to design parts using self-shaping. Initial investigations focused on predicting curvature. Though a disagreement between modeling and experiment was observed, an experimental TEC was introduced to replicate experimental results in FEM modeling. This understanding of the 2D curvature was then extended to three dimensions to analyze shape. Predictions regarding bifurcation between cap-like and tube-like deformation modes was applied to the ceramic system using FEM modeling and experiment. These predictions were shown to be consistent with theoretical understanding. Similarly, bending direction for tube-like deformation was shown to be generally consistent with theoretical understanding, but here FEM modeling struggled to reliably predict the final 3D geometry of shapes with high degrees of symmetry, and experimental samples experienced misorientation of bending, indicating that models may need to be expanded to include a greater variety of forces controlling deformation. Overall, this thesis shows successful development of novel manufacturing techniques to enable wider application of ceramic materials. While the IC-tSOFC introduces new combined heat and power-SOFC systems to be explored, self-shaping ceramics introduces a variety of fundamental questions regarding the underlying mechanism driving bilayer shrinkage within MCCs as well as full understanding of the interaction between 2D substrate shape and film pattern at any scale
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