A methodology for TRNSYS using experimental design

Noah Pflugradt; Nirendra Lal Shrestha; Thorsten Urbaneck; Oscar Camera; Angel Carrera; Jaume Salom; Eduard Oro; Albert Garcia; Mieke Timmermann; Hans Trapman; Gilbert De Nijis; Joris Van Dorp; Bastian Beerens

A methodology for TRNSYS using experimental design

Noah Pflugradt
, Nirendra Lal Shrestha
, Thorsten Urbaneck
, Oscar Camera
, Angel Carrera
, Jaume Salom
, Eduard Oro
, Albert Garcia
, Mieke Timmermann
, Hans Trapman
, Gilbert De Nijis
, Joris Van Dorp
, Bastian Beerens

Research output: Contribution to journal › Article › peer-review

Abstract

As part of the RenewIT project with the objective of increasing renewable energy use in data centers, a number of advanced concepts were created that combine existing technologies such as PV, wind, free cooling, various chiller technologies and energy storage solutions to achieve synergetic effects. For these concepts meta-models are created based on Transient Systems Simulation (TRNSYS) models. To create such metamodels the input parameters for the simulations need to be varied across a wide range. Traditional TRNSYS models are usually only suitable for a narrow set of input conditions. This paper describes the methods used to develop and test TRNSYS models with a wide range of input conditions and shows how the simulations were stabilized across the entire parameter space.

Original language	English
Pages (from-to)	24-29
Number of pages	6
Journal	Euroheat and Power (English Edition)
Volume	14
Issue number	4
Publication status	Published - 2017
Externally published	Yes

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Cite this

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title = "A methodology for TRNSYS using experimental design",

abstract = "As part of the RenewIT project with the objective of increasing renewable energy use in data centers, a number of advanced concepts were created that combine existing technologies such as PV, wind, free cooling, various chiller technologies and energy storage solutions to achieve synergetic effects. For these concepts meta-models are created based on Transient Systems Simulation (TRNSYS) models. To create such metamodels the input parameters for the simulations need to be varied across a wide range. Traditional TRNSYS models are usually only suitable for a narrow set of input conditions. This paper describes the methods used to develop and test TRNSYS models with a wide range of input conditions and shows how the simulations were stabilized across the entire parameter space.",

author = "Noah Pflugradt and Shrestha, \{Nirendra Lal\} and Thorsten Urbaneck and Oscar Camera and Angel Carrera and Jaume Salom and Eduard Oro and Albert Garcia and Mieke Timmermann and Hans Trapman and \{De Nijis\}, Gilbert and \{Van Dorp\}, Joris and Bastian Beerens",

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language = "English",

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AU - Pflugradt, Noah

AU - Shrestha, Nirendra Lal

AU - Urbaneck, Thorsten

AU - Camera, Oscar

AU - Carrera, Angel

AU - Salom, Jaume

AU - Oro, Eduard

AU - Garcia, Albert

AU - Timmermann, Mieke

AU - Trapman, Hans

AU - De Nijis, Gilbert

AU - Van Dorp, Joris

AU - Beerens, Bastian

PY - 2017

Y1 - 2017

N2 - As part of the RenewIT project with the objective of increasing renewable energy use in data centers, a number of advanced concepts were created that combine existing technologies such as PV, wind, free cooling, various chiller technologies and energy storage solutions to achieve synergetic effects. For these concepts meta-models are created based on Transient Systems Simulation (TRNSYS) models. To create such metamodels the input parameters for the simulations need to be varied across a wide range. Traditional TRNSYS models are usually only suitable for a narrow set of input conditions. This paper describes the methods used to develop and test TRNSYS models with a wide range of input conditions and shows how the simulations were stabilized across the entire parameter space.

AB - As part of the RenewIT project with the objective of increasing renewable energy use in data centers, a number of advanced concepts were created that combine existing technologies such as PV, wind, free cooling, various chiller technologies and energy storage solutions to achieve synergetic effects. For these concepts meta-models are created based on Transient Systems Simulation (TRNSYS) models. To create such metamodels the input parameters for the simulations need to be varied across a wide range. Traditional TRNSYS models are usually only suitable for a narrow set of input conditions. This paper describes the methods used to develop and test TRNSYS models with a wide range of input conditions and shows how the simulations were stabilized across the entire parameter space.

UR - https://www.scopus.com/pages/publications/85037372518

M3 - Article

AN - SCOPUS:85037372518

SN - 1613-0200

VL - 14

SP - 24

EP - 29

JO - Euroheat and Power (English Edition)

JF - Euroheat and Power (English Edition)

IS - 4

ER -

A methodology for TRNSYS using experimental design

Abstract

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