PEC12-25 CAPEC-PROCESS Industrial Consortium ... - DTU Orbit
PEC12-25 CAPEC-PROCESS Industrial Consortium ... - DTU Orbit
PEC12-25 CAPEC-PROCESS Industrial Consortium ... - DTU Orbit
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<strong>CAPEC</strong>-<strong>PROCESS</strong><br />
Anna Katrine Vangsgaard Validation of structured model for autotrophic nitrogen<br />
(AKV)<br />
removal in high strength wastewater<br />
<strong>CAPEC</strong>-<strong>PROCESS</strong><br />
to be designed as well. Therefore the use of the generic model is<br />
illustrated through the ICAS-PAT PAT software for design of process<br />
monitoring and control systems. ICAS-PAT PAT consists of a model<br />
library and a knowledge base that allows the user to<br />
design/validate n/validate PAT systems through a systematic computeraided<br />
framework. The generic crystallizer model has been<br />
implemented in the ICAS-PAT PAT model library. The application<br />
of the model-based based framework has been tested through a batch<br />
cooling crystallization process ocess case studies (potassium<br />
dichromate, paracetamol, sucrose etc.) where the objective is to<br />
obtain a desired CSD.<br />
Supervisors: RaG, KVG, GSI<br />
Start: 15-01-2009; End: 31-12-2011<br />
Research area: B, C, D<br />
Autotrophic nitrogen removal is a relatively new and emerging<br />
technology for treatment of sidestream wastewaters with high<br />
nitrogen concentrations, such as sludge digestion liquor or<br />
landfill leachate. It is therefore of great importance that a better<br />
understanding of the process dynamics is established. In this<br />
project, a model to be used for design of experiments will be<br />
developed according to a structured modelin modeling framework. The<br />
aim of this project is to develop a detailed metabolic model for<br />
the selected bacterial groups, performing autotrophic nitrogen<br />
conversion, and integrate that into complete ecosystems models,<br />
which describe how the major microbial groups iinteract.<br />
This<br />
insight will be used to design experiments in which relevant<br />
operational conditions will be identified and tested. The relevant<br />
conditions are under which the nitrogen removal process is<br />
optimized through the development of selection principl principles, for a<br />
targeted removal or enhancement of specific microbial groups.<br />
The final objective is to obtain a validated model which can be<br />
used for process prediction and thus determination of optimal<br />
operational conditions.<br />
Supervisors: GSI, KVG, Barth F. Smets<br />
Started: 01-09-2010; Finish: 31-08-2013<br />
Research area: B, E<br />
Nor Alafiza Yunus (NO (NOY) Tailor-made made design of chemical products: Bio Bio-fuel and other<br />
blended products<br />
This study proposes a methodology for tailor tailor-made design of<br />
chemical products more specifically bio-fuels fuels and other blended<br />
products. This project emphasize on product blends because<br />
most of the chemical based products are mixed of several<br />
chemicals. A single gle chemical is not always able to meet all the<br />
product specifications. Therefore, a mixture/blend of chemicals<br />
is likely to improve and enhance the product qualities.<br />
Identifying mixture of appropriately identified compounds that<br />
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