Membrane Electrode Assembly Fabrication and Test Method Development for a Novel Thermally Regenerative Fuel Cell

Allward, Todd

13 October 2012

A test system for the performance analysis of a novel thermally regenerative fuel cell (TRFC) using propiophenone and hydrogen as the oxidant and fuel respectively was designed and built. The test system is capable of either hydrogen-air or hydrogen-propiophenone operation. Membrane electrode assemblies (MEAs) were made using commercial phosphoric acid-doped polybenzimidazole (PBI) membranes and commercial electrodes. Using Pt/carbon paper electrodes with a catalyst loading of 1mg/cm2 and a membrane with an acid doping level of 10.2 mol acid/mol of polymer repeat unit, a maximum performance of 212 mW/cm2 at a current density of 575 mA/cm2 was achieved for baseline hydrogen-air testing at 110°C. Problems were encountered, however, in achieving consistent, reproducible performance for in-house fabricated MEAs. Furthermore, ex-situ electrochemical impedance spectrometry (EIS) showed that the phosphoric acid-doped PBI was unstable in the propiophenone and that acid-leaching was occurring. In order to have MEAs with consistent characteristics for verifying the test system performance, commercial phosphoric acid-doped PBI membrane electrode assemblies were used. At a temperature of 160°C and atmospheric pressure with hydrogen and air flowrates of 150 mL/min and 900 mL/min respectively a maximum power density of 387 mW/cm2 at a current density of 1.1 A/cm2 was achieved. This performance was consistent with the manufacturer’s specifications and these MEAs were subsequently used to verify the performance of TRFC test system despite the EIS results that indicated that acid-leaching would probably occur. The Pt catalyzed commercial MEAs achieved very limited performance for the hydrogenation of the ketone. However, the performance was less than but comparable to similar results previously reported in the literature by Chaurasia et al. [1]. For pure Pt catalyst loading of 1 mg/cm2, using a commercial PBI MEA operating at 160°C and atmospheric pressure, the maximum power density was 40 µW/cm2 at a current density of 1.3 mA/cm2. A 16 hour test was conducted for these conditions with a constant 1 ohm load, successfully demonstrating the operation of the test system. The test system will be used in the development of better catalysts for ketone hydrogenation. / Thesis (Master, Chemical Engineering) -- Queen's University, 2012-10-12 10:00:58.854

Hydrogenation

Polybenzimidazole

Thermally Regenerative

Design of a Polymeric Coating for Protecting Thermoelectric Materials from Sublimation and Oxidation

Chen, I Kang

08 1900

Thermoelectric (TE) devices can undergo degradation from reactions in corrosive environments and at higher operating temperatures by sublimation and oxidation. To prevent the degradation, we have applied two high temperature polymers (HTPs) as coatings for TE materials. Sintering temperatures were from 250°C to 400°C. We explain why dip coating is better technique in our study and had two potential HTPs for tests. By applying TGA (thermogravimetric analysis), we were able to figure out which HTPs have better thermal resistivity. Besides, TGA also help us to find proper curing cycles for HTPs. EDS and SEM results show that the coatings prevent oxidation and sublimation of TE materials. We also shorten HTP curing cycle time and lower the energy costs.

Thermoelectric Materials

High Temperature Polymer

Thermal Stability

Polymeric Coating

Thermal Resistivity.

Engineering, Materials Science

SYNTHESIS AND ELECTRICAL PROPERTIES OF FLUORENYL POLYESTERS INCORPORATING DIAMOND FRAGMENTS

Wiacek, Kevin John

30 July 2007

No description available.

Capacitor

Energy Storage

High temperature polymer

Diamondoid

Adamantane

Diamantane

Self-healing

Cyclotene

Vapor-liquid Equilibrium of Polymer Solutions During Thermal Decomposition of Rigid Foams

King, Nathan H.

15 July 2008

Removable Epoxy Foam (REF) and other rigid foams experience severe changes in structure and properties when exposed to high heat. As thermal energy breaks network bonds in the foam many species are formed, including large polymer-like network fragments and smaller solvent-like molecules. During this process a liquid phase may form. The vapor-liquid equilibrium (VLE) behavior of the polymer solutions formed during initial decomposition can be highly non-ideal. In this research VLE behavior of high-temperature polymer solutions was studied and a procedure was developed for predicting that behavior during decomposition of rigid foams. A high-temperature VLE facility was built and validated, and equilibrium pressures were measured at temperatures between 75 and 250ºC for six polymer/solvent systems: two polymers – polyethylene glycol and polystyrene – with each of three solvents – benzene, furan, and 4-isopropylphenol. Calculations from eighteen polymer solution models were compared with experimental results to determine which model best described the VLE behavior. These models included six existing activity coefficient models used alone, as well as in combinations with the Peng-Robinson equation of state (EOS) through the Wong-Sandler mixing rules. Because several of the models required values for polymer volumes, a comparison of the GCVOL and GCMCM group-contribution volume estimation methods was performed. GCMCM was found to give lower overall deviations from literature polymer volume data. The models involving an equation of state required EOS parameter values for the pure polymers. A new method for determining these parameters was proposed. Models using parameters from the new method gave better agreement with equilibrium pressure data than models using parameters from the recommended method in the literature. While agreement with equilibrium pressure data was similar for several models, some models predicted a liquid phase split under certain conditions. Data were not available to verify the presence of two liquid phases, but are needed to make an appropriate recommendation of the best model. If liquid phase splitting does not occur, it is recommended that the UNIFAC-ZM activity coefficient model be used alone. If phase splitting behavior is observed, it is recommended that the UNIFAC-FV activity coefficient model be used in combination with the Peng-Robinson EOS.

vapor-liquid equilibrium

high-temperature polymer solutions

Removable Epoxy Foam

GCVOL

GCMCM

equation of state parameters

Chemical Engineering

Ανάπτυξη και μελέτη γραμμικών σουλφονωμένων και θερμικά διασυνδεδεμένων αρωματικών πολυμερικών μεμβρανών

Καλαμαράς, Ιωάννης

31 January 2013

Τα κελιά καυσίμου είναι ηλεκτροχημικές διατάξεις που μετατρέπουν με συνεχή τρόπο τη χημική ενέργεια ενός καυσίμου και ενός οξειδωτικού σε ηλεκτρική με ταυτόχρονη παραγωγή νερού. Μια πολύ σημαντική κατηγορία κελιών είναι είναι τα κελιά καυσίμου πολυμερικής μεβράνης.Λειτουργία σε θερμοκρασίες πάνω από 100ºC έχει διάφορα πλεονεκτήματα.Ένας ιδανικός πολυμερικός ηλεκτρολύτης θα πρέπει να είναι ανθεκτικός, να έχει καλές μηχανικές ιδιότητες, υψηλή θερμική και οξειδωτική σταθερότητα και υψηλή ιοντική αγωγιμότητα, η οποία εξαρτάται από την ικανότητά του να εμποτίζεται με κάποιο μέσο όπως ένα ισχυρό οξύ, π.χ. το φωσφορικό οξύ. Το πρώτο μέρος της παρούσας διατριβής αφορά τη σύνθεση αρωματικών πολυαιθέρων που φέρουν πολικές ομάδες πυριδίνης στη κύρια αλυσίδα, μαζί με πλευρικές σουλφονομάδες με στόχο τη δημιουργία μιας μεμβράνης που θα είναι ικανή να απορροφά φωσφορικό οξύ αλλά και νερό.Το οξύ θα διασφαλίσει υψηλές τιμές ιοντικής αγωγιμότητας ενώ η παρουσία νερού θα αυξήσει την ιοντική αγωγιμότητα.Επιπλέον παρασκευάστηκαν σύνθετες μεμβράνες, με την εισαγωγή ανόργανων εγκλεισμάτων(τροποποιημένος με όξινες σουλφονικές ομάδες μοντμοριλλονίτης (SO3-MMT) στην υδρόφοβη πολυμερική μήτρα του TPS®. Στο δεύτερο μέρος της παρούσας διατριβής αναπτύχθηκαν θερμικά διασυνδεδεμένοι πολυμερικοί ηλεκτρολύτες. Συντέθηκαν 3 νέα μονομερή και συμπολυμερή με πλευρικές ομάδες στυρολίου στη κύρια αλυσίδα.Η θερμική κατεργασία των συμπολυμερών σε υψηλή θερμοκρασία οδήγησε σε διασύνδεση της δομής χωρίς τη χρήση θερμικών εκκινητών. Ακολούθησε πλήρης χαρακτηρισμός των ιδιοτήτων όλων των νέων δομών. Τέλος, έλαβε χώρα εφαρμογή και μελέτη της απόδοσης σε μοναδιαία κυψελίδα καυσίμου. / Fuel cells are devices that convert the chemical energy of a fuel and an oxidant to electrical with simultaneous production of water. Polymer Exchange Membrane Fuel Cell (PEMFC) represents an important class of fuel cells.Operating above 150ºC has many advantages. The ideal polymer electrolyte should exhibit long term durability, good mechanical properties, high thermal/chemical and oxidative stability and high ionic conductivity which depends on the ability to be doped with a strong acid. In the first part of this thesis aromatic copolymers bearing in the main chain basic pyridine groups combined with side chain acidic sulfonate groups were synthesized, making them capable of absorbing phosphoric acid and water. The phosphoric acid will ensure high proton conductivities while presence of water will further improve the performance of the cell. Furthermore composite membranes were prepared by adding inorganic fillers( functionalized montmorrilonite with sulfonic groups, SO3-MMT)in TPS® polymer matrix. In the second part of this thesis thermal cross- linked polymer electrolytes were developed for their use in high temperature PEMFC.Three new monomers and a series of copolymers in high temperature led to crosslinking without using thermal initiators.These properties of all the new structures were fully characterized with conventional techniques. thermal cross-linked copolymers were .chosen for the membrane electrode assembly (MEA) preparation for a preliminary study of the performance of the cell in high temperatures.

Θερμική διασύνδεση

621.312 429

Polymer electrolyte fuel cells

High temperature polymer electrolyte

Sulfonated aromatic polymers

Thermal crosslinking

Nanocomposites

Studium vlastností plniv do kompozitů s požadavkem na vysokou teplotní odolnost / Study of the properties of fillers to the composites requiring high temperature resistance

Vovesný, Václav

January 2016

The diploma thesis is focused on the behaviour of natural and synthetic aggregates and their behaviour in polymer – cement composites, while being exposed to high temperature. The processes, happening in aggregates and mortar under the thermal load, were described in the theoretical part of the thesis same as the testing of heat effects on the aggregates and mortar. Further, the influence of high temperature on each component of concrete was described, followed by the suggestion of the appropriate components for concrete exposed to high temperature. Various aggregates were tested in the experimental part of the thesis. The basic physical and mechanical properties of aggregates were examined same as their mineralogical composition with using XRD, DTA and SEM methods. At the mortar, the influence of high temperature on the concrete density, compressive strength and tensile strength was defined. The gained knowledge was evaluated in the final part of the thesis