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Combustion 2000
This report is a presentation of work carried out on Phase II of the HIPPS program under DOE contract DE-AC22-95PC95144 from June 1995 to March 2001. The objective of this report is to emphasize the results and achievements of the program and not to archive every detail of the past six years of effort. These details are already available in the twenty-two quarterly reports previously submitted to DOE and in the final report from Phase I. The report is divided into three major foci, indicative of the three operational groupings of the program as it evolved, was restructured, or overtaken by events. In each of these areas, the results exceeded DOE goals and expectations. HIPPS Systems and Cycles (including thermodynamic cycles, power cycle alternatives, baseline plant costs and new opportunities) HITAF Components and Designs (including design of heat exchangers, materials, ash management and combustor design) Testing Program for Radiative and Convective Air Heaters (including the design and construction of the test furnace and the results of the tests) There are several topics that were part of the original program but whose importance was diminished when the contract was significantly modified. The elimination of the subsystem testing and the Phase III demonstration lessened the relevance of subtasks related to these efforts. For example, the cross flow mixing study, the CFD modeling of the convective air heater and the power island analysis are important to a commercial plant design but not to the R&D product contained in this report. These topics are of course, discussed in the quarterly reports under this contract. The DOE goal for the High Performance Power Plant System ( HIPPS ) is high thermodynamic efficiency and significantly reduced emissions. Specifically, the goal is a 300 MWe plant with > 47% (HHV) overall efficiency and {le} 0.1 NSPS emissions. This plant must fire at least 65% coal with the balance being made up by a premium fuel such as natural gas. To achieve these objectives requires a change from complete reliance of coal-fired systems on steam turbines (Rankine cycles) and moving forward to a combined cycle utilizing gas turbines (Brayton cycles) which offer the possibility of significantly greater efficiency. This is because gas turbine cycles operate at temperatures well beyond current steam cycles, allowing the working fluid (air) temperature to more closely approach that of the major energy source, the combustion of coal. In fact, a good figure of merit for a HIPPS design is just how much of the enthalpy from coal combustion is used by the gas turbine. The efficiency of a power cycle varies directly with the temperature of the working fluid and for contemporary gas turbines the optimal turbine inlet temperature is in the range of 2300-2500 F (1260-1371 C). These temperatures are beyond the working range of currently available alloys and are also in the range of the ash fusion temperature of most coals. These two sets of physical properties combine to produce the major engineering challenges for a HIPPS design. The UTRC team developed a design hierarchy to impose more rigor in our approach. Once the size of the plant had been determined by the choice of gas turbine and the matching steam turbine, the design process of the High Temperature Advanced Furnace (HITAF) moved ineluctably to a down-fired, slagging configuration. This design was based on two air heaters: one a high temperature slagging Radiative Air Heater (RAH) and a lower temperature, dry ash Convective Air Heater (CAH). The specific details of the air heaters are arrived at by an iterative sequence in the following order:-Starting from the overall Cycle requirements which set the limits for the combustion and heat transfer analysis-The available enthalpy determined the range of materials, ceramics or alloys, which could tolerate the temperatures-Structural Analysis of the designs proved to be the major limitation-Finally the commercialization issues of fabrication and reliability, availability and maintenance. The program that has sought to develop and implement these HIPPS designs is outlined below
Modelling and simulation based assessment in sustainable bioprocess development
Modelling and simulation enhance our insight and understanding of chemical processes and aid in identifying bottlenecks and potential improvements. A simplified simulation package, providing a reasonable estimate of material and energy usage and process emissions is often valuable in very early stages of process development, when temporal and financial limitations do not allow for more detailed estimates. Environmental burdens are an increasing concern in industrial processes and various methodologies and tools have been developed for gathering and analysis of process information to enhance understanding of the process system and inform decision makers. The systems nature of these approaches is aimed at mitigation of environmental burdens through improved technologies, sustainable resource consumption and screening of process alternatives. Ideally, the process design team should bring together these tools in early stages of development when design flexibility is greatest. In the present study, such a simplified approach to bioprocess design is demonstrated using a case study for the large-scale production of citric acid
ECOS 2010 Volume II (Biomass & Renewable)
ECOS2010 - 23rd International Conference on Efficiency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems, June 14-17 2010, Lausanne, Switzerland Ecoefficiency and renewable energy for a sustainable world + Developments, application and teaching of methods in: - Basic and applied thermodynamics - Thermoeconomics and environomics - Simulation, improvement and optimization of energy conversion systems - Process design, analysis and integration of thermal and chemical systems - Diagnostic and control of thermal systems - Environmental impact and sustainability of energy systems + Relevant physical systems - Conventional and advanced power plants - Polygeneration and District heating/cooling systems - New technologies in heat pumps, refrigeration and air conditioning - New technologies for electricity (co)generation - Industrial process plants - Energy storage - Carbon Capture and Storage - Hydrogen and natural gas technologies - Biomass conversion systems - Energy conversion systems for transportation - Water Desalination and Treatment + Focus points - Technology, environmental and economical aspects of biofuels and other renewable energies (biomass, geothermal, thermal solar) - Fuel cells systems - Heat pumps and Organic Rankine Cycle
Book of abstracts of the 10th International Chemical and Biological Engineering Conference: CHEMPOR 2008
This book contains the extended abstracts presented at the 10th International Chemical and Biological
Engineering Conference - CHEMPOR 2008, held in Braga, Portugal, over 3 days, from the 4th to the 6th of
September, 2008. Previous editions took place in Lisboa (1975, 1889, 1998), Braga (1978), PĂłvoa de
Varzim (1981), Coimbra (1985, 2005), Porto (1993), and Aveiro (2001).
The conference was jointly organized by the University of Minho, âOrdem dos Engenheirosâ, and the IBB -
Institute for Biotechnology and Bioengineering with the usual support of the âSociedade Portuguesa de
QuĂmicaâ and, by the first time, of the âSociedade Portuguesa de Biotecnologiaâ.
Thirty years elapsed since CHEMPOR was held at the University of Minho, organized by T.R. Bott, D. Allen,
A. Bridgwater, J.J.B. Romero, L.J.S. Soares and J.D.R.S. Pinheiro. We are fortunate to have Profs. Bott, Soares
and Pinheiro in the Honor Committee of this 10th edition, under the high Patronage of his Excellency the
President of the Portuguese Republic, Prof. AnĂbal Cavaco Silva. The opening ceremony will confer Prof.
Bott with a âLong Term Achievementâ award acknowledging the important contribution Prof. Bott brought
along more than 30 years to the development of the Chemical Engineering science, to the launch of
CHEMPOR series and specially to the University of Minho. Prof. Bottâs inaugural lecture will address the
importance of effective energy management in processing operations, particularly in the effectiveness of
heat recovery and the associated reduction in greenhouse gas emission from combustion processes.
The CHEMPOR series traditionally brings together both young and established researchers and end users
to discuss recent developments in different areas of Chemical Engineering. The scope of this edition is
broadening out by including the Biological Engineering research. One of the major core areas of the
conference program is life quality, due to the importance that Chemical and Biological Engineering plays in
this area. âIntegration of Life Sciences & Engineeringâ and âSustainable Process-Product Development
through Green Chemistryâ are two of the leading themes with papers addressing such important issues.
This is complemented with additional leading themes including âAdvancing the Chemical and Biological
Engineering Fundamentalsâ, âMulti-Scale and/or Multi-Disciplinary Approach to Process-Product
Innovationâ, âSystematic Methods and Tools for Managing the Complexityâ, and âEducating Chemical and
Biological Engineers for Coming Challengesâ which define the extended abstracts arrangements along this
book.
A total of 516 extended abstracts are included in the book, consisting of 7 invited lecturers, 15 keynote,
105 short oral presentations given in 5 parallel sessions, along with 6 slots for viewing 389 poster
presentations. Full papers are jointly included in the companion Proceedings in CD-ROM. All papers have
been reviewed and we are grateful to the members of scientific and organizing committees for their
evaluations. It was an intensive task since 610 submitted abstracts from 45 countries were received.
It has been an honor for us to contribute to setting up CHEMPOR 2008 during almost two years. We wish
to thank the authors who have contributed to yield a high scientific standard to the program. We are
thankful to the sponsors who have contributed decisively to this event. We also extend our gratefulness to
all those who, through their dedicated efforts, have assisted us in this task.
On behalf of the Scientific and Organizing Committees we wish you that together with an interesting
reading, the scientific program and the social moments organized will be memorable for all.Fundação para a CiĂȘncia e a Tecnologia (FCT