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@PHDTHESIS{Chen:571311,
author = {Chen, Kan},
othercontributors = {Müller, Dirk and Monti, Antonello},
title = {{A}ctive thermal management for residential air source heat
pump systems; 1. {A}uflage},
volume = {35},
school = {RWTH Aachen},
type = {Dissertation},
address = {Aachen},
publisher = {E.ON Energy Research Center},
reportid = {RWTH-2016-01973},
isbn = {978-3-942789-34-9},
series = {E.On Energy Research Center : EBC, Energy Efficient
Buildings and Indoor Climate},
pages = {XIX, 137 Seiten : Illustrationen, Diagramme},
year = {2016},
note = {Auch veröffentlicht auf dem Publikationsserver der RWTH
Aachen University; Dissertation, RWTH Aachen, 2016},
abstract = {As the future melting pot of different forms of energy,
home energy system is one of the key enablersto the smart
grid technology. The development of such kind of smart home
technologies with focus on demand response has gained
interest in order to exploit potential demand and supply
flexibility of decentralized energy systems. This
flexibility could be used to support the optimized operation
of the renewable home energy systems, which may have
volatile power output depending on fluctuating environmental
conditions. An optimized demand response strategy leads
directly to the reduction of carbon emission, energy cost
saving as well as thermal comfort improvement. As one
representative type of the renewable home energy systems,
the air source heat pump has a considerable penetration rate
on the electrical grid of residential quarters due to its
low commissioning expenditure, high installation flexibility
and better access possibility to the smart grid. Thus, the
research and development of the active thermal management
strategy based on residential air source heat pump system
with respect to the evolving demand response technologies is
selected as the focus of this dissertation. In Chapter 1,
the developing trend of home energy systems and some basic
demand response backgrounds are introduced. The drawbacks
and difficulties of the existing home energy management
system are argued while being merged into the future smart
grid framework. Based on the requirement analysis and the
state-of-the-art technologies, the solution approach from
conception to validation of the active management strategy
is proposed in Chapter 2. The target system to be
investigated, comprising a typical air source heat pump
system with a domestic hot water storage tank and a
single-family house, are described in Chapter 3. The idea
and technical implementation of the proposed solution are
depicted in Chapter 4 and 5, including the self-adaptive
system modeling approach, the predictive modulation solver
for the electrical compressor as well as the demand-actuated
domestic hot water tank management strategy. As another
highlight of this dissertation, the Hardware-in-the-Loop
test approach for home energy systems is developed in order
to test, validate and evaluate the implemented control
prototype under realistic operation conditions. In Chapter
6, the function principle and the composition of the
Hardware-in-the-Loop test platform are introduced, including
the multiphysical emulation system, the infrastructural
design on signal level as well as the interfacing and
integration of the software components. Following the
proposed dynamic test approach, the developed prototype of
the home energy management system is quantitatively
evaluated by various assessment criteria under different
realistic test scenarios in comparison to several existing
commercialized solutions, which are explicitly analyzed in
Chapter 7.},
cin = {419510 / 080052},
ddc = {620},
cid = {$I:(DE-82)419510_20140620$ / $I:(DE-82)080052_20160101$},
typ = {PUB:(DE-HGF)3 / PUB:(DE-HGF)11},
urn = {urn:nbn:de:hbz:82-rwth-2016-019730},
url = {https://publications.rwth-aachen.de/record/571311},
}
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