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Sowohl für die etablierten als auch für potenzielle neue Akteure im Bildungswesen ist gegenwärtig eine systematische Planung bzw. Analyse ihrer Aktivitäten angesichts der sich wandelnden Wertschöpfungs- und Wettbewerbsstrukturen von hoher Relevanz. Peter Weber zeigt in dieser Arbeit exemplarisch für den Hochschulbereich auf der Basis des diesbezüglich in der Betriebswirtschaftslehre anerkannten Instruments der Geschäftsmodellanalyse Ansatzpunkte für eine Lern-Service-spezifische Interpretation des integrierten Geschäftsmodellansatzes auf. Die besonderen Herausforderungen liegen dabei zum einen in der für eine solche Betrachtung notwendigen ökonomischen Interpretation der implizit thematisierten Bildungsangebote, für die der Begriff der Lern-Services entwickelt wird. Zum anderen zeichnet sich das Handlungsfeld von Lern-Service-Anbietern durch eine Interdisziplinarität aus, die neben der Berücksichtigung ökonomischer auch die Berücksichtigung didaktischer Aspekte notwendig macht.
Education --- Management & management techniques --- Analyse --- Bildungsangebot --- Bildungsbranche --- Bildungseinrichtung --- Bildungsökonomie --- Bildungswesens --- Blended Learning --- Branchentransformation --- eines --- E-Learning --- Geschäfts --- Geschäftsmodellanalyse --- Geschäftsmodellen --- Geschäftsplan --- Hintergrund --- Lern --- Lern-Service-Engineering --- Service --- sich --- transformierenden --- Weber
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Whether it's called "fixed equipment? (at ExxonMobil), "stationary equipment? (at Shell), or "static equipment? (in Europe), this type of equipment is the bread and butter of any process plant. Used in the petrochemical industry, pharmaceutical industry, food processing industry, paper industry, and the manufacturing process industries, stationary equipment must be kept operational and reliable for companies to maintain production and for employees to be safe from accidents. This series, the most comprehensive of its kind, uses real-life examples and time-tested rules of thumb to guide the mec
Piping - Maintenance and repair. --- Piping--Maintenance and repair.Pipelines--Maintenance and repair.Service life (Engineering). --- Service life (Engineering). --- Piping --- Pipelines --- Service life (Engineering) --- Maintenance and repair. --- Life, Service (Engineering) --- Operating life (Engineering) --- Pipe lines --- Piping systems --- Reliability (Engineering) --- Economic life of fixed assets --- Maintenance --- Pipe --- Plumbing
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Safety and reliability are important for the whole expected service duration of an engineering structure. Therefore, prognostical solutions for different building types are needed and uncertainties have to be handled. Life-cycle strategies to control future structural degradations by concepts of appropriate design have to be developed, in case including means of inspection, maintenance, and repair. Aspects of costs and sustainability also matter. The Cooperative Research Center for Lifetime-Oriented Design Concepts (SFB 398) at Ruhr University in Bochum combines the wide range of scientific topics between structural engineering, structural and soil mechanics and material sciences regarding structural lifetime management in this present extraordinary monolithic format. The characterization and modeling of lifetime-related external actions of multiple origin are presented in this book as well as the physical description, the modeling and the validation of material degradation. Adaptive numerical methods and simulation techniques are provided for the lifetime-oriented design concepts to forecast material and structural degradation. Stochastic aspects, mathematical optimization methods and interactions between various influences are included. Thus, a solid basis is provided for future practical use and also for standardization of structural design with respect to lifetime-prediction.
Building materials. --- Structural design. --- Materials Science --- Chemical & Materials Engineering --- Engineering & Applied Sciences --- Service life (Engineering) --- Evaluation. --- Mathematical models. --- Life, Service (Engineering) --- Operating life (Engineering) --- Engineering. --- Structural mechanics. --- Buildings --- Building. --- Construction. --- Engineering, Architectural. --- Building repair. --- Materials science. --- Building Materials. --- Building Repair and Maintenance. --- Materials Science, general. --- Structural Mechanics. --- Building Construction. --- Design and construction. --- Repair and reconstruction. --- Reliability (Engineering) --- Economic life of fixed assets --- Maintenance --- Building construction. --- Materials. --- Mechanics. --- Mechanics, Applied. --- Solid Mechanics. --- Building Construction and Design. --- Applied mechanics --- Engineering, Mechanical --- Engineering mathematics --- Classical mechanics --- Newtonian mechanics --- Physics --- Dynamics --- Quantum theory --- Engineering --- Engineering materials --- Industrial materials --- Engineering design --- Manufacturing processes --- Materials --- Buildings—Repair and reconstruction. --- Buildings—Design and construction. --- Architectural engineering --- Construction --- Construction science --- Engineering, Architectural --- Structural design --- Structural engineering --- Architecture --- Construction industry --- Material science --- Physical sciences --- Building reconstruction --- Building renovation --- Building repair --- Reconstruction of buildings --- Remodeling of buildings --- Renovation of buildings --- Repairing --- Architectural materials --- Building --- Building supplies --- Construction materials --- Structural materials --- Design and construction --- Reconstruction --- Remodeling --- Renovation --- Protection --- Conservation and restoration
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This book is the result of a Special Issue of the journal Resources. The Special Issue was initiated to identify promising solutions and specific challenges in the context of underused resources in urban environments. Authors focus on two main areas: the establishment of circular economy schemes based on valorizing wastes that occur in urban areas and the exploitation of renewable energies. The circular economy and renewable resources hold key potential for increasing the sustainability of cities, and the presented studies enhance our understanding of how to unlock this potential. Effective regulatory frameworks and policymaking processes that balance the power between stakeholders are required to successfully manage energy transition and the transition to more circular economies. The positive role of community engagement merits high attention. To recover valuable resources from household waste, a focus on technology and infrastructure is required but is insufficient; motivational factors and knowledge of citizens are the most essential elements. The need to more reliably quantify and better characterize recyclable material streams also evidently remains, especially where population numbers are further growing. This book provides a rich source to explore promising solutions, challenges, and research needed for the sound management of resources in urban settings.
History of engineering & technology --- source separation of waste --- waste management --- household waste --- polymer recycling --- sustainable development --- Lagos megacity --- value chain --- waste-to-wealth --- city planning --- Energiewende --- post-Brexit --- renewable energy systems --- resource-use policy --- sustainable energy transitions --- underutilised resources --- waste cooking oil --- recycling --- biodiesel --- non-fuel use --- regulatory promotion --- circular economy --- European horse chestnut --- seed coat --- additive --- antioxidant --- proanthocyanidins --- UV spectrum --- extraction --- size exclusion chromatography --- polyphenols --- renewable energy --- energy transition --- energy policies --- urban energy --- particle size reduction --- pre-treatment --- shredding --- mechanical–biological treatment --- bioprocessing --- wastewater management --- environmental sustainability --- waste resources --- household solid waste (HSW) --- waste composition analysis --- waste generation rate --- solid waste measurement --- remote sensing --- building type --- garden waste arising --- green waste --- yard waste --- home composting --- backyard burning --- municipal and public service engineering --- urban resources --- resource management --- sustainable urbanisation --- community engagement --- solid waste recycling --- energy governance --- policy-making
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This book introduces data-driven remaining useful life prognosis techniques, and shows how to utilize the condition monitoring data to predict the remaining useful life of stochastic degrading systems and to schedule maintenance and logistics plans. It is also the first book that describes the basic data-driven remaining useful life prognosis theory systematically and in detail. The emphasis of the book is on the stochastic models, methods and applications employed in remaining useful life prognosis. It includes a wealth of degradation monitoring experiment data, practical prognosis methods for remaining useful life in various cases, and a series of applications incorporated into prognostic information in decision-making, such as maintenance-related decisions and ordering spare parts. It also highlights the latest advances in data-driven remaining useful life prognosis techniques, especially in the contexts of adaptive prognosis for linear stochastic degrading systems, nonlinear degradation modeling based prognosis, residual storage life prognosis, and prognostic information-based decision-making.
Engineering. --- Operations research. --- Decision making. --- Probabilities. --- Statistics. --- Quality control. --- Reliability. --- Industrial safety. --- Quality Control, Reliability, Safety and Risk. --- Probability Theory and Stochastic Processes. --- Operation Research/Decision Theory. --- Statistics for Engineering, Physics, Computer Science, Chemistry and Earth Sciences. --- Economic life of fixed assets. --- Service life (Engineering) --- Mathematical models. --- Life, Service (Engineering) --- Operating life (Engineering) --- Economic life (of economic goods) --- Fixed assets, Economic life of --- Life, Economic --- Useful life of fixed assets --- Reliability (Engineering) --- Economic life of fixed assets --- Maintenance --- Accounting --- Depreciation --- System safety. --- Distribution (Probability theory. --- Operations Research/Decision Theory. --- Operational analysis --- Operational research --- Industrial engineering --- Management science --- Research --- System theory --- Statistical analysis --- Statistical data --- Statistical methods --- Statistical science --- Mathematics --- Econometrics --- Distribution functions --- Frequency distribution --- Characteristic functions --- Probabilities --- Safety, System --- Safety of systems --- Systems safety --- Accidents --- Industrial safety --- Systems engineering --- Prevention --- Statistics . --- Deciding --- Decision (Psychology) --- Decision analysis --- Decision processes --- Making decisions --- Management --- Management decisions --- Choice (Psychology) --- Problem solving --- Probability --- Statistical inference --- Combinations --- Chance --- Least squares --- Mathematical statistics --- Risk --- Industrial accidents --- Industries --- Job safety --- Occupational hazards, Prevention of --- Occupational health and safety --- Occupational safety and health --- Prevention of industrial accidents --- Prevention of occupational hazards --- Safety, Industrial --- Safety engineering --- Safety measures --- Safety of workers --- System safety --- Dependability --- Trustworthiness --- Conduct of life --- Factory management --- Sampling (Statistics) --- Standardization --- Quality assurance --- Quality of products --- Decision making
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