Exergy-based Planning and Thermography-based Monitoring for energy efficient buildings - Progress Report (KIT Scientific Reports ; 7632)

Designing and monitoring energy efficiency of buildings is vital since they account for up to 40% of end-use energy. In this study, exergy analysis is investigated as a life cycle design tool to strike a balance between thermodynamic efficiency of energy conversion and economic and environmental costs of construction. Quantitative geo-referenced thermography is proposed for monitoring and quantitative assessment via continued simulation and parameter estimation during the operating phase

Characterization of Aggregated Building Heating, Ventilation, and Air Conditioning Load as a Flexibility Service Using Gray‐Box Modeling

Integrating large amounts of volatile renewable power into the electricity grid requires ancillary services (ASs) from multiple providers including flexible demand. These should be comparable by uniform and efficiently evaluable performance criteria. The objective is to characterize the technical flexibility of aggregated building heating, ventilation, and air conditioning (HVAC) under different operating conditions. New bounds of flexible power and holding durations, accordingly pay-back power and recovery times, and ramping rates are derived, using a new gray-box model of stochastically actuated aggregations of thermostatically controlled loads (TCLs) that can serve as well for load control. New closed formulas of the expected switching temperatures are derived using survival processes and hazard functions. This ex-ante characterization enables fast decision tools for AS feasibility testing and planning by demand aggregators, as it neither relies on simulation or optimization, nor on the identification and clustering of unit-level parameters. The estimates are explored in a sensitivity study of urban-level heat pump heating with respect to six key input factors. A case study using dynamic regulation signals from Pennsylvania–New Jersey–Maryland (PJM) demonstrates the benefit, in terms of tracking precision, of the refined energy measures over pure energy or power capacity bounds

Simultaneous 3D mapping and localization from segmented range views by similarity optimization

Ein neuer Ansatz wurde für mobile Roboter zur gleichzeitigen 3D (Drei-Dimensionaler) Kartierung und Lokalisierung vorgestellt. Die Grundlage bilden attributierte Flächenmodelle, die z.B. von segmentierten Laserscanner-Tiefenbildern stammen. Zur Optimierung der Gesamtähnlichkeit zwischen Flächenmodellen unter Zeitbedingungen werden mehrere Verfahren (Beschränkte Baumsuche, Iterative Verfeinerung, Evolutionäralgorithmus) kombiniert. Es wird speziell anhand der Ähnlichkeitsmaße gezeigt, wie das Wissen über die Lage stufenweise generiert und verwendet wird. Erste Messungen an realen segmentierten Tiefenbildfolgen zeigen, dass das Verfahren unbekannte übelappung, Verdeckung und Segmentierungsfehler toleriert sowie Echtzeitpotenzial besitzt.An increasing number of service robots do not only operate in a three-dimensional world, but truly require 3D models of their work space. We propose a new approach for the simultaneous 3D mapping and localization problem from multiple segmented range views. Attributed surface graphs provide a compact representation which is at hand for symbolic action planning while being extended by new sensor data. To achieve real-time operation, the similarity between surface models is maximized on three cooperative and competitive layers: bounded tree search with landmark ordering on the bottom, iterative refinement of surface assignment and pose at the middle layer, and an evolutionary algorithm on top. Different degrees of knowledge about relative location are generated and used, by plugging in different measures of surface and relation similarity. Reconstruction results from real range image sequences show that occlusion, unknown overlap and segmentation errors are tolerated

Formation of Die Soldering and the Influence of Alloying Elements on the Intermetallic Interface

Die soldering of die castings is a serious problem in the aluminum casting industry. The precise mechanism, the influence of the alloy composition, and the options for prevention have not yet been fully elaborated. A well-established solution for alloys with low iron content is the addition of manganese. However, up to 0.8 wt.% is necessary, which increases the amount of brittle phases in the material and consequently reduces ductility. Immersion tests with 1.2343 tool steel and pure aluminum as well as a hypoeutectic AlSi-alloy with Mn, Mo, Co, and Cr additions were carried out to systematically investigate the formation of die soldering. Three different intermetallic layers and a scattered granular intermetallic phase formed at the interface between steel and Al-alloy after immersion into the melt for a duration of 6 min at 710 °C. The combined presence of the irregular, needle-shaped β-Al5FeSi phase and the surrounding alloy was responsible for the bond between the two components. Mn and Mo inhibited the formation of the β-phase, and instead promoted the αC-Al15(Fe,X)3Si2 phase. This led to an evenly running boundary to the AlSi-alloy and thus prevented bonding. Cr has proven to be the most efficient addition against die soldering, with 0.2 wt.% being sufficient. Contrary to the other elements investigated, Cr also reduced the thickness of the intermetallic interface.ISSN:1996-194

Molecular Characterization of Chlamydophila Pneumoniae Isolates from Western Barred Bandicoots

Chlamydophila pneumoniae is an obligate intracellular respiratory pathogen that has been associated with pneumonia and chronic bronchitis, atherosclerosis, asthma and other chronic diseases in humans. However, C. pneumoniae is not restricted to humans, as originally thought, and can cause infections in several animal hosts. C. pneumoniae was isolated in cell culture from nine Western barred bandicoots (Perameles bougainville) from Australia. The sequences of five genomic regions were determined, including full-length sequences of the 16S rRNA and ompA genes and the ygeD-urk intergenic spacer, and partial sequences of the 23S rRNA and rpoB genes. Sequence analysis of the entire 16S rRNA and ompA genes from bandicoot isolates demonstrated that they were 98.2-98.3% similar to human isolates, 94.6-99.3% similar to the equine biovar and almost identical, with 99.5-99.9% similarity, to the koala biovar. Comparative genotyping of the variable domain 4 region of the ompA gene demonstrated that bandicoot isolates seemed to be identical to the animal genotype that has been recently identified in human carotid plaque specimens. Minor sequence polymorphism observed in ompA, 16S rRNA and rpoB genes of animal isolates, indicating genomic diversity within C. pneumoniae, may have important implications for diagnostic PCR assays leading to false negative results. Forty percent of selected published species-specific PCR assays were found to have sequence variability in primer and/or probe that might affect their performance in detecting bandicoot isolates of C. pneumoniae, or possibly other animal and human strains where minor sequence polymorphisms may be present. The data from this study support the previous observations that C. pneumoniae is not restricted to humans and may be widespread in an animal reservoir with a potential risk of transmission to humans