Return to search

Dynamic Modeling and Optimization of Cryogenic Air Separations Units: Design and Operation Strategies / Dynamic Modeling and Optimization of Cryogenic Air Separations Units

Support for this work from Praxair; the McMaster Advanced Control Consortium; and the Natural Sciences and Engineering Research Council of Canada (NSERC), Grant CRDPJ 445717, is gratefully acknowledged. / In the air separation industry, cryogenic distillation is the dominant technology for separating
large quantities of air into individual high purity component products. Due to the complexity
of the process, in addition to significant energy input, air separation units (ASUs) also have
high degrees of material and thermal integration and low process agility. As markets become
more competitive and dynamic, especially after electricity market deregulation, ASUs can
no longer practice mostly stationary operations, and are in need for design and control
strategies to achieve high adaptability. In this study, we address such issues through a
dynamic optimization framework. The use of rigorous dynamic models is important for
developing economically beneficial designs and operating practices.
The first part of this study focuses on the modeling aspect. For the column section of
the plant, a full-order stage-wise model and a collocation based reduced order model are
proposed. Model size, simulation time and predication accuracy are compared. For the
primary heat exchanger, a novel moving boundary model is derived to handle the phase
change in such a multi-stream heat exchanger. Simulation results demonstrate the capability
of the proposed model in tracking the boundary points of the phase change occurrence, as
well as the potential pinch point, along the length of the heat exchanger.
The second part of the study addresses the operation aspects of ASUs through conducting
dynamic optimization studies with collocation based dynamic models. We first performed a
comprehensive analysis for a storage-then-utilization strategy on a nitrogen plant, following a
two-tier multi-period formulation. As the parameter varies with time, the plant collects liquid,
either directly from liquid product or by liquefaction of overproduced gas product, and then
redistributes it for meeting gas product demand or as additional reflux. Effects of electricity
price and demand profiles, additional operation costs, as well as product specifications are
explored. Then we investigated the economic incentive for employing preemptive actions
on a super-staged argon system, which allows the plant to take actions before external changes arrive. In the evaluation, changes are in the gas oxygen product demand. During
the preemptive period, the plant takes either a single set or multiple sets of control actions.
In the demand increase case, operation degrees of freedom are introduced to or removed
from the set of decision variables. The demand decrease scenarios are explored with an
under-supplied or saturated liquid oxygen market. / Dissertation / Doctor of Philosophy (PhD)

Identiferoai:union.ndltd.org:mcmaster.ca/oai:macsphere.mcmaster.ca:11375/20641
Date January 2016
CreatorsCao, Yanan
ContributorsSwartz, Christopher L.E., Chemical Engineering
Source SetsMcMaster University
LanguageEnglish
Detected LanguageEnglish
TypeThesis

Page generated in 0.0017 seconds