Passive load follow analysis of the STAR-LM and STAR-H2 systems.

Moisseytsev, Anton

30 September 2004

A steady-state model for the calculation of temperature and pressure distributions, and heat and work balance for the STAR-LM and the STAR-H2 systems was developed. The STAR-LM system is designed for electricity production and consists of the lead cooled reactor on natural circulation and the supercritical carbon dioxide Brayton cycle. The STAR-H2 system uses the same reactor which is coupled to the hydrogen production plant, the Brayton cycle, and the water desalination plant. The Brayton cycle produces electricity for the on-site needs. Realistic modules for each system component were developed. The model also performs design calculations for the turbine and compressors for the CO2 Brayton cycle. The model was used to optimize the performance of the entire system as well as every system component. The size of each component was calculated. For the 400 MWt reactor power the STAR-LM produces 174.4 MWe (44% efficiency) and the STAR-H2 system produces 7450 kg H2/hr. The steady state model was used to conduct quasi-static passive load follow analysis. The control strategy was developed for each system; no control action on the reactor is required. As a main safety criterion, the peak cladding temperature is used. It was demonstrated that this temperature remains below the safety limit during both normal operation and load follow.

load follow

steady state

nuclear reactor

hydrogen production

passive

Simulation of the copper–chlorine thermochemical cycle / Mapamba, L.S.

Mapamba, Liberty Sheunesu

January 2011

The global fossil reserves are dwindling and there is need to find alternative sources of energy. With global warming in mind, some of the most commonly considered suitable alternatives include solar, wind, nuclear, geothermal and hydro energy. A common challenge with use of most alternative energy sources is ensuring continuity of supply, which necessitates the use of energy storage. Hydrogen has properties that make it attractive as an energy carrier. To efficiently store energy from alternative sources in hydrogen, several methods of hydrogen production are under study. Several literature sources show thermochemical cycles as having high potential but requiring further development. Using literature sources, an initial screening of thermochemical cycles was done to select a candidate thermochemical cycle. The copper–chlorine thermochemical cycle was selected due to its relatively low peak operating temperature, which makes it flexible enough to be connected to different energy sources. Once the copper–chlorine cycle was identified, the three main copper–chlorine cycles were simulated in Aspen Plus to examine which is the best configuration. Using experimental data from literature and calculating optimal conditions, flowsheets were developed and simulated in Aspen Plus. The simulation results were then used to determine the configuration with the most favourable energy requirements, cycle efficiency, capital requirements and product cost. Simulation results show that the overall energy requirements increase as the number of steps decrease from five–steps to three–steps. Efficiencies calculated from simulation results show that the four and five–step cycles perform closely with 39% and 42%, respectively. The three–step cycle has a much lower efficiency, even though the theoretical calculations imply that the efficiency should also be close to that of the four and five–step cycles. The five–step reaction cycle has the highest capital requirements at US$370 million due to more equipment and the three–step cycle has the lowest requirement at US$ 275 million. Payback analysis and net present value analysis indicate that the hydrogen costs are highest for the three–step cycle at between US$3.53 per kg for a 5–10yr payback analysis and the five–step cycle US$2.98 per kg for the same payback period. / Thesis (M.Ing. (Chemical Engineering))--North-West University, Potchefstroom Campus, 2012.

Aspen Plus simulation

Thermochemical cycle

Hydrogen production

Efficiency

Economics

Simulation of the copper–chlorine thermochemical cycle / Mapamba, L.S.

Mapamba, Liberty Sheunesu

January 2011

The global fossil reserves are dwindling and there is need to find alternative sources of energy. With global warming in mind, some of the most commonly considered suitable alternatives include solar, wind, nuclear, geothermal and hydro energy. A common challenge with use of most alternative energy sources is ensuring continuity of supply, which necessitates the use of energy storage. Hydrogen has properties that make it attractive as an energy carrier. To efficiently store energy from alternative sources in hydrogen, several methods of hydrogen production are under study. Several literature sources show thermochemical cycles as having high potential but requiring further development. Using literature sources, an initial screening of thermochemical cycles was done to select a candidate thermochemical cycle. The copper–chlorine thermochemical cycle was selected due to its relatively low peak operating temperature, which makes it flexible enough to be connected to different energy sources. Once the copper–chlorine cycle was identified, the three main copper–chlorine cycles were simulated in Aspen Plus to examine which is the best configuration. Using experimental data from literature and calculating optimal conditions, flowsheets were developed and simulated in Aspen Plus. The simulation results were then used to determine the configuration with the most favourable energy requirements, cycle efficiency, capital requirements and product cost. Simulation results show that the overall energy requirements increase as the number of steps decrease from five–steps to three–steps. Efficiencies calculated from simulation results show that the four and five–step cycles perform closely with 39% and 42%, respectively. The three–step cycle has a much lower efficiency, even though the theoretical calculations imply that the efficiency should also be close to that of the four and five–step cycles. The five–step reaction cycle has the highest capital requirements at US$370 million due to more equipment and the three–step cycle has the lowest requirement at US$ 275 million. Payback analysis and net present value analysis indicate that the hydrogen costs are highest for the three–step cycle at between US$3.53 per kg for a 5–10yr payback analysis and the five–step cycle US$2.98 per kg for the same payback period. / Thesis (M.Ing. (Chemical Engineering))--North-West University, Potchefstroom Campus, 2012.

Aspen Plus simulation

Thermochemical cycle

Hydrogen production

Efficiency

Economics

Modelling and Experimental Study of Methane Catalytic Cracking as a Hydrogen Production Technology

Amin, Ashraf Mukhtar Lotfi

18 May 2011

Production of hydrogen is primarily achieved via catalytic steam reforming, partial oxidation,and auto-thermal reforming of natural gas. Although these processes are mature technologies, they are somewhat complex and CO is formed as a by-product, therefore requiring a separation process if a pure or hydrogen-rich stream is needed. As an alternative method, supported metal catalysts can be used to catalytically decompose hydrocarbons to produce hydrogen. The process is known as catalytic cracking of hydrocarbons. Methane, the hydrocarbon containing the highest percentage of hydrogen, can be used in such a process to produce a hydrogen-rich stream. The decomposition of methane occurs on the surface of the active metal to produce hydrogen and filamentous carbon. As a result, only hydrogen is produced as a gaseous product, which eliminates the need of further separation processes to separate CO2 or CO. Nickel is commonly used in research as a catalyst for methane cracking in the 500-700C temperature range. To conduct methane catalytic cracking in a continuous manner, regeneration of the deactivated catalyst is required and circulation of the catalysts between cracking and regeneration cycles must be achieved. Different reactor designs have been successfully used in cyclic operation, such as a set of parallel fixed-bed reactors alternating between cracking and regeneration, but catalyst agglomeration due to carbon deposition may lead to blockage of the reactor and elevated pressure drop through the fixed bed. Also poor heat transfer in the fixed bed may lead to elevated temperature during the regeneration step when carbon is burned in air, which may cause catalyst sintering. A fluidized bed reactor appears as a viable option for methane catalytic cracking, since it would permit cyclic operation by moving the catalyst between a cracker and a regenerator. In addition, there is the possibility of using fine catalyst particles, which improves catalyst effectiveness. The aims of this project were 1) to develop and characterize a suitable nickel-based catalyst and 2) to develop a model for thermal catalytic decomposition of methane in a fluidized bed.

Methane cracking

Hydrogen production

Fluidized bed

Nickel catalyst

Chemical Engineering

Nanostructured Catalysts for H2 Production by Aqueous Phase Reforming of Sugars

Tanksale, Akshat

Unknown Date

No description available.

Combined Chemical Looping Combustion and Calcium Looping for Enhanced Hydrogen Production from Biomass Gasification

Abdul Rahman, Ryad

January 2014

Production of hydrogen from biomass steam gasification can be enhanced by using calcium oxide sorbents for CO2 capture in the gasifier. Calcium looping suffers from two main drawbacks: the need for high-purity oxygen in order to regenerate the sorbent under oxy-fuel combustion conditions and the loss of sorbent reactivity over several cycles due to sintering of pores upon calcination at high temperatures. One method of addressing the issue of oxygen supply for calcination in calcium looping is to combine the calcium looping and chemical looping processes, where the heat produced by the reduction of an oxygen-carrier by a fuel such as natural gas or gasification syngas, drives the calcination reaction. The technologies can be integrated by combining an oxygen carrier such as CuO with limestone within a composite pellet, or by cycling CuO and limestone within distinct particles. The goal of this project is thus to investigate the different sequences of solids circulation and the cyclic performance of composite limestone-CuO sorbents under varied operating conditions for this novel process configuration. Using a thermogravimetric analyzer (TGA), it was found that using composite CaO/CuO/alumina-containing cement pellets for gasification purposes required oxidation of Cu to be preceded by carbonation (Sequence 2) as opposed to the post-combustion case where the pellets are oxidized prior to carbonation (Sequence 1). Composite pellets were tested using Sequence 2 using varying carbonation conditions over multiple cycles. While the pellets exhibited relatively high carbonation conversion, the oxidation conversion underwent a decrease for all tested conditions, with the reduction in oxygen uptake particularly drastic when the pellets were pre-carbonated in the presence of steam. It appears that the production of a layer of CaCO3 fills up the pellets pores, obstructing the passage of O2 molecules to the more remote Cu sites. Limestone-based pellets and Cu-based pellets were subsequently tested in separate CaL and CLC loops respectively to assess their performance in a dual-loop process (Sequence 3). A maximum Cu content of 50% could be accommodated in a pellet with calcium aluminate cement as support with no loss in oxidation conversion and no observable agglomeration.

Calcium Looping

Chemical Looping Combustion

Biomass Gasification

Hydrogen Production

Multi-scale and Complex Metallic Structure Networks for Novel Solar Energy Harvesting-Conversion Applications

Tian, Yi

05 1900

The global consumption of fossil fuels continues to increase due to the rapid growth of energy demand, as a consequence of expanding population and human activities. Fast climate change is another inescapable issue caused by humans that need to be addressed. The development of solar energy conversion technologies is widely considered as one of the most promising solutions to sustainably maintain a modern lifestyle of the society and create a carbon-neutral social development operation mode. The solar energy is carried and delivered in the form of electromagnetic fields. Therefore, the efficiency of photon collection is the primary factor to create any solar energy conversion systems. Through the inspiration from nature, the functionalized disorder, with a specific design and engineering, can introduce unusual light-matter interaction behaviors, and thus offer a potential capability to achieve perfect light harvesting. In my thesis, we develop complex Epsilon-Near-Zero (ENZ) metamaterials that can be used either as light capturing networks or the photoactive media by turning the energy damping ratio between radiative and non-radiative channels. We successfully integrate it into thin-film photovoltaic modules with showing an excellent performance enhancement led by broadband light localization effect. Thanks to universal of such complex ENZ metamaterials, with combining a thin layer of dielectric, we further develop efficient hot-carriers driven plasmonic photo-catalysts for artificial green chemical fuel synthesis. The detailed theoretic analysis is presented in this work.

Light harvesting

Broadband

Plasmonics

Hot Carriers

Hydrogen production

Solar energy

Development of heterogeneous catalysts for clean hydrogen production from biomass resources

Pastor Pérez, Laura

29 July 2016

El Capítulo I trata la actual crisis energética y hace una breve introducción sobre el uso del hidrógeno como vector energético, mencionando los diferentes métodos que pueden utilizarse para la producción/purificación de hidrógeno a partir de recursos renovables. También incluye una breve descripción del papel que puede jugar la biomasa como alternativa a los combustibles fósiles, y su conversión a biocombustibles y productos químicos de valor añadido. El reformado catalítico de glicerol para la producción de gas de síntesis o corrientes ricas en hidrógeno se presenta como una ruta potencial, alternativa y prometedora que ha llamado la atención en los últimos años. Esta reacción se suele llevar a cabo sobre catalizadores basados en metales soportados en materiales estables. En el Capítulo II se estudia el efecto de la adición de Sn sobre las propiedades y la estabilidad de catalizadores de Pt soportado en carbón en la reacción de reformado glicerol en fase gas. Para ello, se preparó y caracterizó una serie de catalizadores con diferentes relaciones atómicas Pt/Sn. El alto precio de los metales nobles motiva la búsqueda y empleo de metales más baratos y abundantes que también tengan un buen comportamiento catalítico en esta reacción. Por ello, en el Capítulo III se emplearon catalizadores basados en Ni promovidos por óxido de cerio para el reformado de glicerol. Por otro lado, se hace necesario optimizar el uso del CeO2 debido a su limitada disponibilidad y sus extensas aplicaciones. Así, en este trabajo se dispersó CeO2 sobre carbón activado de alta área superficial, obteniendo gran superficie de óxido de cerio expuesta al mismo tiempo que se redujo su consumo. También se estudió el efecto de la presencia de estaño en estos catalizadores. Se obtienen diversas ventajas al realizar el reformado de glicerol en fase líquida. Así, se obtienen corrientes más ricas en H2 con menor cantidad de CO. Esto se debe a las moderadas temperaturas y altas presiones empleadas, que favorecen la reacción de desplazamiento del gas de agua. También se suprime la necesidad de evaporar la disolución acuosa de glicerol, por lo que el requerimiento energético es menor y se evitan reacciones indeseadas de descomposición térmica. De este modo, en el Capítulo IV se hace un estudio comparativo sobre las propiedades catalíticas de tres muestras, Pt/CeO2, Ni/CeO2 y Pt-Ni/CeO2, en la reacción de reformado de glicerol en fase líquida. Además, se empleó espectroscopía de reflectancia total atenuada in situ para obtener información relevante sobre los intermedios de reacción y la evolución de los catalizadores durante la reacción, permitiendo así proponer los caminos de reacción más probables. Para obtener corrientes de hidrógeno suficientemente puro para su uso es las pilas de combustible, la corriente obtenida después del reformado debe ser procesada en varias etapas, entre las que se incluyen la eliminación del CO por medio de la reacción de desplazamiento del gas de agua (water-gas shift, WGS). En el Capítulo V se estudia la serie de catalizadores de Ni promovidos por CeO2 soportados en carbón en la reacción de desplazamiento del gas de agua a bajas temperaturas. Para este estudio se emplearon diferentes corrientes de entrada, tanto ideales (sólo CO y H2O) como reales (CO, CO2, H2 y H2O). Por último, en el Capítulo VI, el catalizador que presentó mejor comportamiento catalítico en el apartado anterior fue estudiado en mayor profundidad, relacionando sus propiedades con la actividad catalítica, sometiéndolo finalmente a ensayos de estabilidad en condiciones más demandantes.

Heterogeneous catalysts

Hydrogen production

Glycerol reforming

WGS

Química Inorgánica

Photocatalytic hydrogen evolution by using organic semiconductors nanoparticles

Sulaimani, Shahad

11 1900

Abstract: With the worldwide dependence on non-renewable fossil fuels and increasing concerns over their impact on our planet through greenhouse gas emissions finding an alternative source of clean energy is a global imperative. The solar energy is one source of renewable energy resources, and It has the highest potential to contribute substantially to the future of carbon-free power needs. Solar to hydrogen has attracted much attention in the past decade due to its abundance and the spotlessness of hydrogen as fuel for energy usage. However, practically the requirements to convert solar energy to hydrogen, require a stable photocatalyst that’s able to operate efficiently over a wide range of the UV-VIS spectrum. Organic semiconductors have been widely used in hydrogen evolution due to their earth abundance, aqueous stability, and optical absorption that can be tuned to the UV-VIS spectrum. In chapter 3, The effect of different sacrificial regents on hydrogen evolution activity was systemically investigated by using poly(9,9-dioctylfluorene-alt-benzothiadiazole) (F8BT) nanoparticles dispersion large and small diameter with Sodium dodecyl sulfate (SDS) as stabilizer. Ascorbic acid (AA), diethylamine (DEA), triethanolamine (TEOA), and triethylamine mixed with methanol (TEA/MeOH) were chosen as sacrificial reagents. The results indicate that the large diameter give improved efficiency with ascorbic acid, and the small diameter improved activity in the presence of diethylamine. The results indicated that the comparison between different sacrificial reagents is difficult because, the conditions of every experiment is different to another, depending on (the type of photocatalyst used, solubility, activity..) so to date, there is no clear concurrence in which sacrificial reagent is better than others. Photocatalysts formed from a single organic semiconductor typically suffer from inefficient intrinsic charge generation, which leads to low photocatalytic activities. In chapter 4, To overcome this limitation, we have used BTR, O-IDTBR, and PC71BM in binary and tertiary heterojunction nanoparticles between non fullerene donors’ small molecules and fullerene acceptor. The resulting photocatalyst display unprecedentedly a high hydrogen evolution rate over 12000 μmolh-1g-1 under AM 1.5g illumination.

Photocatlysis

Hydrogen Production

Organic semiconductors

Teritary blends

small molecules

Catalyse supportée sur nanotubes de carbone / Catalysis supported on carbon nanotubes

Donck, Simon

15 October 2015

Cette thèse porte sur la catalyse supportée sur nanotubes de carbone. Plusieurs aspects ont été étudiés, électrocatalyse pour la production d'hydrogène à partir d'eau, catalyse pour la synthèse organique et électrocatalyse de la réaction de réduction de l'oxygène. Différents catalyseurs ont été synthétisés à partir d'assemblages supramoléculaires de molécules amphiphiles autour de nanotubes de carbone ou d'adhésion de molécules polyaromatiques à la surface des nanotubes et ont impliqué l'utilisation de catalyseur moléculaire ou nanoparticulaire. L'utilisation de ces catalyseurs pour les différents types de réactions mentionnés plus haut ont abouti à des résultats intéressants. / This PhD thesis deals with the catalysis supported on carbon nanotubes. Several aspects have been studied such as electrocatalysis for hydrogen production form water, catalysis for organic synthesis and electrocatalysis of the oxygen reduction reaction. Many different catalysts have been synthesized based on supramolecular assembly of amphiphilic molecules around carbon nanotubes or assembly of polyaromatic molecules at the surface of the nanotubes. These catalysts are made of metallic complexes or metallic nanoparticles. These catalysts have been successfully used to perform the reactions mentioned above.

Nanotubes de carbone

Catalyse

Production d'hydrogène

Carbon nanotubes

Catalysis

Hydrogen Production