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Institute
- Westfälisches Energieinstitut (106) (remove)
Menschen verbringen einen großen Teil ihrer Zeit in Innenräumen. Um dafür die notwendige thermische Behaglichkeit zu gewährleisten, müssen schon bei der Nutzungsplanung die Temperaturen und Luftbewegungen im Raum vorhergesagt werden können. Bei anderen Anwendungen wiederum sind diese Größen relevant für die Prozesssicherheit (z. B. Labore, Operationssaal). Die Vorhersagen erfolgen zum Beispiel durch Strömungssimulationen oder an sogenannten Mock Up Räumen, die eine 1:1 Nachbildung des relevanten Raums darstellen. Bei größeren Räumen wie z. B. Konzertsälen steigt der Aufwand erheblich an.
Eine auf den ersten Blick vergleichsweise einfache Lösung ergibt sich durch Untersuchungen an skalierten Modellräumen. Allerdings ist hier die Ähnlichkeit zwischen Modell und Realausführung bei nicht-isothermen Strömungen nicht gegeben. Die dimensionslosen Kenngrößen Reynolds Zahl Re und Archimedes Zahl Ar sind nicht identisch, da sie mit unterschiedlichen Exponenten bei der charakteristischen Länge skalieren, so dass sie durch die Wahl eines anderen Mediums oder Anpassung der Temperaturen nicht hinreichend kompensiert werden können.
Im Labor für Klimatechnik an der Westfälischen Hochschule sollen mit Hilfe von experimentellen Modelluntersuchungen und dem Vergleich mit der Realausführung Erkenntnisse gewonnen werden, in wie weit ein Kompromiss aus Ähnlichkeit und Genauigkeit gefunden werden kann, um technisch relevante Fragestellungen am Modell zu beantworten.
Die Leitfragen dabei sind:
- Wie lassen sich Modellergebnisse auf reale Raumluftströmungen übertragen?
- Unter welchen Bedingungen ist die Ähnlichkeit zwischen Modell und Realausführung noch gegeben?
- Wie sehen Leitlinien für die praktische Anwendung der Ähnlichkeitsgesetze aus?
Ein Büroraum mit unterschiedlichen Luftführungsvarianten und thermischen Lasten stellt dabei die Realausführung dar. Das Modell ist im Maßstab 1:5 herunterskaliert.
A compact and efficient PEM electrolyser stack design based on hydraulic single cell compression
(2019)
For this study gas diffusion electrodes (GDE) with low platinum loading are prepared for the application as anode in polymer electrolyte membrane fuel cell (PEMFC) systems based on hydraulic compression. As catalyst support material, carbon nanofibers (CNF) are investigated because of their high specific surface area and high graphitization degree. The electrode preparation is optimized by an economic and environmental friendly pre-treatment process in oxygen plasma. For GDE manufacture an ink containing oxygen plasma activated CNFs as well as hydrophilic polymer is used. After spray coating of this CNF ink on a graphitic substrate, platinum is deposited using the pulse plating technique. Preliminary results showed a considerable improvement of CNF dispersibility as well as an increased amount and an optimized morphology of the deposited platinum. Morphology and microstructure are observed by scanning electron microscopy as well as transmission electron microscopy. Platinum loading is determined by thermogravimetric analysis to be in the range of 0.01 mg cm-2 to 0.017 mg cm-2. Furthermore, MEAs are prepared from these GDEs and testing is performed in a novel modular fuel cell test stack based on hydraulic compression. Technical information about stack design and functions is given in this work.
Membrane electrode assemblies (MEA) developed at the Westphalian Energy Institute for polymer electrolyte membrane fuel cells (PEMFC) are high tech systems containing various materials structured in nanoscale, at which electrochemical reactions occur on catalyst nano particle surfaces. For low reactance homogeneous compression of the MEA’s layers is necessary. A novel stack architecture for electrochemical cells, especially PEMFC as well as PEM electrolysers, has been developed according to achieve ideal cell operation conditions. Single cells of such a stack are inserted into flexible slots that are surrounded by hydraulic media. While operation the hydraulic media is pressurised which leads to an even compression and cooling of the stack’s cells. With this stack design it has been possible to construct a test facility for simultaneous characterisation of several MEA samples. As compression and temperature conditions of every single sample are equal, with the novel test system the effect of e.g. different electrode configurations can be investigated. Furthermore, the modular stack design leads to the development of hybrid energy applications combining fuel cells, electrolysers, batteries as well as metal hydride tanks in one system.
In this work, a novel polymer electrolyte membrane water electrolyzer (PEMWE) test cell based on hydraulic single-cell compression is described. In this test cell, the current density distribution is almost homogeneous over the active cell area due to hydraulic cell clamping. As the hydraulic medium entirely surrounds the active cell components, it is also used to control cell temperature resulting in even temperature distribution. The PEMWE single-cell test system based on hydraulic compression offers a 25 cm2 active surface area (5.0 × 5.0 cm) and can be operated up to 80°C and 6.0 A/cm2. Construction details and material selection for the designed test cell are given in this document. Furthermore, findings related to pressure distribution analyzed by utilizing a pressure-sensitive foil, the cell performance indicated by polarization curves, and the reproducibility of results are described. Experimental data indicate the applicability of the presented testing device for relevant PEMWE component testing and material analysis.
In this experimental work we present a novel electrolyzer system for the production of hydrogen and oxygen at high pressure levels without an additional mechanical compressor. Due to its control strategies, the operation conditions for this electrolyzer can be kept optimal for each load situation of the system. Furthermore, the novel system design allows for dynamic long-term operation as well as for easy maintainability. Therefore, the device meets the requirements for prospective power-to-gas applications, especially, in order to store excess energy from renewable sources. A laboratory scale device has been developed and high-pressure operation was validated. We also studied the long-term stability of the system by applying dynamic load cycles with load changes every 30 sec. After 80 h of operation the used membrane electrode assembly (MEA) was investigated by means of SEM, EDX and XRD analysis.