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Building Information Modeling (BIM) wird im Bauwesen immer stärker gefordert. Der vorliegende Artikel befasst sich mit dem Datenaustausch für die TGA. Am Beispiel eines RLT-Gerätes werden der Detaillierungsgrad und der Datenaufbau mit IFC erläutert. Insbesondere zeigt sich hierbei, dass der Datenimport aufgrund fehlender Standards und Definitionen mit Datenverlust einhergeht. Damit ergibt sich ein Auftrag an die Softwareunternehmen hier für eindeutige Standards zu sorgen.
TGA-Planung mit BIM-Objekten
(2019)
Die BIM-Methode erfasst in Deutschland mittlerweile alle Gewerke im Bauhauptgewerbe. Für die TGA-Branche hat sich gezeigt, dass die Priorität der Produkthersteller auf der Bereitstellung der Geometriedaten liegt. Weiterführende Metadaten und Attribute (z. B. Material, Masse, Preise, Leistungsdaten) sind oftmals nur in reduzierter Form oder gar nicht vorhanden. An exemplarischen Beispielen von RLT-Reräten und Komponenten werden die geometrischen und semantischen Möglichkeiten beim IFC-Format untersucht.
Carbon Nanofibers (CNF) are considered to be a promising catalyst support material due to their unique characteristics, excellent mechanical, electrical and structural properties, high surface area and nevertheless, good interaction with metallic catalyst particles. The possibility of preparing CNF decorated with platinum by an electrochemical method was tested, using a hexachloroplatinic bath solution. The experiments were carried out with the aid of a Potentiostat/Galvanostat Ivium Technologies Vertex, in a three – electrode cell. The aim of the present work was to determine the electrochemical surface area (ECSA) of the CNF-Pt catalysts in relation to the functionalization treatment of fibers, using an electrochemical method. ECSA for different functionalized CNF-Pt catalysts was determined by cyclic voltammetry in 0.5 M H2SO4 solution. The highest active surface of platinum was obtained for the samples with CNF functionalized by plasma treatment using 80 W for 1800 s. The obtained results correlate very well with the particles size and distribution of platinum, revealed by scanning electron microscopy (SEM) and the quantity of deposited platinum determined by thermo gravimetrical analysis (TGA) respectively. Cyclic voltammetry (CV) has been proven to be a suitable method for estimation of the ECSA of the electrocatalysts.
Platinum nanoparticles electrodeposition on carbon nanofibers (CNF) support has been performed with the purpose to obtain electrodes that can be further used especially in a polymer electrolyte membrane fuel cell (PEMFC). A pretreatment of CNF is required in order to enhance the surface energy, which simultaneously improves handling and wettability as well as interaction with the platinum cations. This step was performed using oxygen plasma functionalization. To produce CNF supported Pt catalysts, an electrochemical method was applied and the deposition parameters were adjusted to obtain nanosized platinum particles with a good distribution onto the graphitic surface. The morphology and structure of the obtained particles were investigated by scanning electron microscopy combined with energy dispersive X-Ray spectroscopy. The amount of deposited platinum was established using thermogravimetrical measurements. Cyclic voltammetry performed in 0.5 M H2SO4 solution was applied for determining the electrochemical surface area (ECSA) of the obtained electrodes.The functionalization degree of the CNF outer surface has a strong influence on the structure, distribution and amount of platinum particles. Moreover, the current densities, which were set for the deposition process influenced not only the particles size but also the platinum amount. Applying an oxygen plasma treatment of 80 W for 1800 s, the necessary degree of surface functionalization is achieved in order to deposit the catalyst particles. The best electrodes were prepared using a current density of 50 mA cm-2 during the deposition process that leads to a homogenous platinum distribution with particles size under 80 nm and ECSA over 6 cm2
A systematic method for obtaining a novel electrode structure based on PtCoMn ternary alloy catalyst supported on graphitic carbon nanofibers (CNF) for hydrogen evolution reaction (HER) in acidic media is proposed. Ternary alloy nanoparticles (Co0.6Mn0.4 Pt), with a mean crystallite diameter under 10 nm, were electrodeposited onto a graphitic support material using a two-step pulsed deposition technique. Initially, a surface functionalisation of the carbon nanofibers is performed with the aid of oxygen plasma. Subsequently, a short galvanostatic pulse electrodeposition technique is applied. It has been demonstrated that, if pulsing current is employed, compositionally controlled PtCoMn catalysts can be achieved. Variations of metal concentration ratios in the electrolyte and main deposition parameters, such as current density and pulse shape, led to electrodes with relevant catalytic activity towards HER. The samples were further characterised using several physico-chemical methods to reveal their morphology, structure, chemical and electrochemical properties. X-ray diffraction confirms the PtCoMn alloy formation on the graphitic support and energy dispersive X-ray spectroscopy highlights the presence of the three metallic components from the alloy structure. The preliminary tests regarding the electrocatalytic activity of the developed electrodes display promising results compared to commercial Pt/C catalysts. The PtCoMn/CNF electrode exhibits a decrease in hydrogen evolution overpotential of about 250 mV at 40 mA cm−2 in acidic solution (0.5 M H2SO4) when compared to similar platinum based electrodes (Pt/CNF) and a Tafel slope of around 120 mV dec−1, indicating that HER takes place under the Volmer-Heyrovsky mechanism.
Gebäude sind immer auch ein Ausdruck der Zeit, in der sie erbaut wurden. Oft bleiben sie sehr lange erhalten und erfahren über die Jahrzehnte mehrfache Nutzungsänderungen. Betroffen sind alte Produktionshallen ebenso wie Verwaltungsimmobilien. Die Gebäudehülle bleibt bei einer Umnutzung meist unangetastet. Aufgabe der Technischen Gebäudeausrüstung ist es dann, das Raumklima für die Nutzer unter den geänderten Bedingungen behaglich zu gestalten und die Aspekte der Energieeffizienz und Nachhaltigkeit nicht aus den Augen zu verlieren. Insbesondere die Kühlung der Gebäude im Sommer steht aufgrund der steigenden internen Lasten und der solaren Gewinne durch große Glasfassaden im Vordergrund.