Experimental Validation of a Co-Simulation Architecture for Modeling Whole-Building and Detailed Electrical Distribution Performance: Article No. 115917

Stephen Frank; Omkar Ghatpande; Jordan Shackelford; Matthew Steen; Brian Ball; Daniel Gerber; Arthur Santos; Richard Brown

doi:10.1016/j.enbuild.2025.115917

Experimental Validation of a Co-Simulation Architecture for Modeling Whole-Building and Detailed Electrical Distribution Performance: Article No. 115917

Stephen Frank, Omkar Ghatpande, Jordan Shackelford, Matthew Steen, Brian Ball, Daniel Gerber, Arthur Santos, Richard Brown

Building Technologies and Science Center

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

Abstract

This article presents an experimental validation of a co-simulation architecture for simultaneously modeling whole-building energy performance and detailed building electrical distribution system performance. The co-simulation architecture consists of a whole-building energy model (EnergyPlus(R)) embedded within a Modelica-based building electrical distribution system library called the Building Electrical Efficiency Analysis Model (BEEAM) using the Functional Mock-up Interface standard. We validate the model using experimental data collected at a full-scale test cell within Lawrence Berkeley National Laboratory's FLEXLAB(R) facility. We show that the co-simulation model accurately predicts the electrical, mechanical, and thermal performance of the test cell for typical loads with both an AC and a DC electrical distribution topology.

Original language	American English
Number of pages	17
Journal	Energy and Buildings
Volume	344
DOIs	https://doi.org/10.1016/j.enbuild.2025.115917
State	Published - 2025

NREL Publication Number

NREL/JA-3500-79590

Keywords

building performance simulation
co-simulation
electrical distribution systems
model validation

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10.1016/j.enbuild.2025.115917

Cite this

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title = "Experimental Validation of a Co-Simulation Architecture for Modeling Whole-Building and Detailed Electrical Distribution Performance: Article No. 115917",

abstract = "This article presents an experimental validation of a co-simulation architecture for simultaneously modeling whole-building energy performance and detailed building electrical distribution system performance. The co-simulation architecture consists of a whole-building energy model (EnergyPlus(R)) embedded within a Modelica-based building electrical distribution system library called the Building Electrical Efficiency Analysis Model (BEEAM) using the Functional Mock-up Interface standard. We validate the model using experimental data collected at a full-scale test cell within Lawrence Berkeley National Laboratory's FLEXLAB(R) facility. We show that the co-simulation model accurately predicts the electrical, mechanical, and thermal performance of the test cell for typical loads with both an AC and a DC electrical distribution topology.",

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author = "Stephen Frank and Omkar Ghatpande and Jordan Shackelford and Matthew Steen and Brian Ball and Daniel Gerber and Arthur Santos and Richard Brown",

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doi = "10.1016/j.enbuild.2025.115917",

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T1 - Experimental Validation of a Co-Simulation Architecture for Modeling Whole-Building and Detailed Electrical Distribution Performance

T2 - Article No. 115917

AU - Frank, Stephen

AU - Ghatpande, Omkar

AU - Shackelford, Jordan

AU - Steen, Matthew

AU - Ball, Brian

AU - Gerber, Daniel

AU - Santos, Arthur

AU - Brown, Richard

PY - 2025

Y1 - 2025

N2 - This article presents an experimental validation of a co-simulation architecture for simultaneously modeling whole-building energy performance and detailed building electrical distribution system performance. The co-simulation architecture consists of a whole-building energy model (EnergyPlus(R)) embedded within a Modelica-based building electrical distribution system library called the Building Electrical Efficiency Analysis Model (BEEAM) using the Functional Mock-up Interface standard. We validate the model using experimental data collected at a full-scale test cell within Lawrence Berkeley National Laboratory's FLEXLAB(R) facility. We show that the co-simulation model accurately predicts the electrical, mechanical, and thermal performance of the test cell for typical loads with both an AC and a DC electrical distribution topology.

AB - This article presents an experimental validation of a co-simulation architecture for simultaneously modeling whole-building energy performance and detailed building electrical distribution system performance. The co-simulation architecture consists of a whole-building energy model (EnergyPlus(R)) embedded within a Modelica-based building electrical distribution system library called the Building Electrical Efficiency Analysis Model (BEEAM) using the Functional Mock-up Interface standard. We validate the model using experimental data collected at a full-scale test cell within Lawrence Berkeley National Laboratory's FLEXLAB(R) facility. We show that the co-simulation model accurately predicts the electrical, mechanical, and thermal performance of the test cell for typical loads with both an AC and a DC electrical distribution topology.

KW - building performance simulation

KW - co-simulation

KW - electrical distribution systems

KW - model validation

U2 - 10.1016/j.enbuild.2025.115917

DO - 10.1016/j.enbuild.2025.115917

M3 - Article

SN - 0378-7788

VL - 344

JO - Energy and Buildings

JF - Energy and Buildings

ER -

Experimental Validation of a Co-Simulation Architecture for Modeling Whole-Building and Detailed Electrical Distribution Performance: Article No. 115917

Abstract

NREL Publication Number

Keywords

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