Detoxification of crude oil

Jarullah, A.T., Mujtaba, Iqbal M., Wood, Alastair S.

22 December 2017

No / Petroleum contributes significantly to our lives and will continue do so for many years to come. Petroleum derivatives supply more than 50% of the world's total supply of energy (Jarullah, 2011). Traditionally crude oil goes though fractional distillation to produce different grades of fuel such as gasoline, kerosene, diesel oil, etc. providing fuel for automobiles, tractors, trucks, aircraft, and ships. Catalytic hydrotreating (HDT) is used to detoxify the oil fractions produced by fractional distillation in the petroleum refining industries which involve removal of pollutants such as sulfur, nitrogen, metals, and asphaltene in trickle bed reactors. Recently Jarullah and co-workers proposed detoxification of whole crude oil a priori before the crude oil enters further processing in a fractionating column. This chapter highlights this new technology.

Methodical and technical aspects of functional-structural plant modelling

Henke, Michael

13 March 2017

No description available.

510

functional-structural plant modelling

plant modelling

modularisation

data acquisition

data analysis

FSPM

GroIMP

model prototype

Informatik (PPN619939052)

Extension of the Rule-Based Programming Language XL by Concepts for Multi-Scaled Modelling and Level-of-Detail Visualization

Ong, Yongzhi

27 April 2015

No description available.

510

multiscale

graph grammar

functional-structural plant modelling

XL

relational growth grammars

scene graph

forest modelling

Informatik (PPN619939052)

Impact on heat rate and subsequent emissions due to varying operation of coal fired power plants

Akpan, Patrick Udeme-Obong

21 April 2020

Energy mix modellers often use a constant emissions factor model, which more or less implies a constant heat rate, when trying to show the emissions reduction benefits of integrating renewable power generation system on the grid. This approach does not consider the fact that there is a deterioration in the heat rate with load for the Coal Fired Power Plants that need to accommodate the additional renewable supply. If varying heat rate were to be included in a study, it is often limited to plant specific cases. This PhD presents a novel Variable Turbine Cycle Heat Rate (V-TCHR) model for predicting the part load Turbine cycle heat rate (TCHR) response of various Coal Fired Power Plant (CFPP) architectures, without detail knowledge of the entire steam cycle parameters. A total of 192 process models of representative CFPP architectures were developed using a Virtual Plant software. The models had different combinations of the degree of reheat; the throttle temperature; throttle pressure; and condenser cooling technology. The part load response of all the models were simulated using the software.

Coal fired Power Plants

Heat rates

CO2 emissions

Renewable Power Integration

Power Plant modelling and simulation

Energy Mix Modelling

Modélisation de la croissance des plantes supérieures pour les systèmes de support-vie : conception d'un modèle global et simulation des transferts de masse et d'énergie à l'échelle de la plante / Higher plant growth modelling for life support systems : global model design and simulation of mass and energy transfers at the plant level

Hezard, Pauline

12 September 2012

Les missions spatiales habitées de longue durée nécessitent des systèmes de support-vie efficaces recyclant l’air, l’eau et la nourriture avec un apport extérieur minimum en matière et énergie. L’air et l’eau peuvent être recyclés par des méthodes purement physico-chimiques, tandis que la production de nourriture ne peut être faite sans la présence d’organismes vivants. Le projet Micro-Ecological Life Support System Alternative (MELiSSA, alternative de système de support-vie micro-écologique) de l’Agence Spatiale Européenne inclut des plantes supérieures cultivées dans une chambre close contrôlée, associée à d’autres compartiments microbiens. Le contrôle à long terme de la chambre de culture et du système de support-vie entier requiert des modèles prédictifs efficaces. Le bouclage du bilan massique et la prédiction de la réponse de la plante dans un environnement extraterrestre inhabituel mettent en avant l’importance de modèles mécanistes basés sur le principe des bilans de matière et d’énergie.Une étude bibliographique poussée a été réalisée afin de lister et analyser les modèles de croissance de plantes supérieures existants. De nombreux modèles existent, ils simulent la plupart des processus de la plante. Cependant aucun des modèles structurés globaux n’est suffisamment mécaniste ni équilibré en terme d’échange de masse pour une application dans un système de support-vie clos. Ainsi, une nouvelle structure est proposée afin de simuler tous les termes du bilan massique au niveau de la plante, en incluant les différentes échelles de l’étude : les processus généraux, l’échelle de l’organe et l’échelle de la molécule. Les résultats d’une première approche utilisant des lois physiques mécanistes simples pour les échanges de matière et d’énergie, une stoechiométrie unique pour la production de biomasse et quelques lois empiriques pour la prédiction des paramètres architecturaux sont illustrés et comparés avec des résultats expérimentaux obtenus dans un environnement contrôlé. Une analyse mathématique du modèle est réalisée et tous ces résultats sont discutés afin de proposer les prochaines étapes de développement. Ceci est décrit en détail pour l’inclusion de modèles de processus plus complexes dans les futures versions du modèle ; les expériences qui devraient être réalisées ainsi que les mesures nécessaires sont proposées. Ceci conduit à la description d’une nouvelle conception de chambre de culture expérimentale. / For long-term manned space missions, it is necessary to develop efficient life support systems recycling air, water and food with a minimum supply of matter and energy. Air and water can be recycled from purely physico-chemical systems; however food requires se presence of living organisms. The Micro-Ecological Life Support System Alternative (MELiSSA) project of the European Space Agency includes higher plants grown in a closed and controlled chamber associated with other microbial compartments. The long-term control of the growth chamber and entire life support system requires efficient predictive models. The mass balance closure and the prediction in uncommon extraterrestrial environments highlight the importance of mechanistic models based on the mass and energy balances principles.An extensive bibliographic study has been performed in order to list and analyse the existing models of higher plant growth. Many models already exist, simulating most of the plant processes. However none of the global, structured models is sufficiently mechanistic and balanced in terms of matter exchange for an application in closed life support systems. Then a new structure is proposed in order to simulate all the terms of the mass balance at the plant level, including the different scales of study: general processes, organ scale and molecular scale. The results of the first approach using simple mechanistic physical laws for mass and energy exchange, a unique stoichiometry for biomass production and few empirical laws for the prediction of architectural parameters are illustrated and compared with experimental results obtained in a controlled environment. A mathematical analysis of the model is performed and all these results are discussed in order to propose further developments. This is described in detail for the implementation of more complex models of processes in the future model versions; the experiments that should be performed including the main measurements are proposed. This leads to the description of a new design of experimental growth chamber.

Modélisation des plantes supérieures

Environnement contrôlé

Système de support-vie clos

Bilans matière et énergie

Phénomènes de transport

Modèle métabolique structuré

Higher plant modelling

Controlled environment

Closed life support system

Mass and energy balances

Transport phenomena

Structured metabolic model

Linking structural and process-oriented models of plant growth / Development and test of the software NEXUS as a multiple interface for functional-structural models / Kopplung von Struktur- und Prozessmodelle des Pflanzenwachstums / Entwicklung und Prüfung der NEXUS-Software als Mehrfachinterface für Struktur-Funktions-Modelle

Anzola Jürgenson, Gustavo Alejandro

19 April 2002

No description available.

500 Naturwissenschaften allgemein

Forest Sciences and Forest Ecology

Pflanzenmodellierung

Pflanzenwachstum

Pflanzenphysiologie

Modellkopplung

Structurmodelle

Processmodelle

Structur-Funktions-Modelle

Forstwissenschaft

Biometrie

Plant modelling

Plant growth

plant physiology

linking models

structural models

process model

structural-funktional models

forestry

biometry

48.00

YO 000: Forstwirtschaft

YQE 000: Physiologie {Forstbotanik}

YQC 000: Morphologie {Forstbotanik}