THE IDEALIZED AND THE REALISTIC VALIDATION STUDIES OF BUILDING SIMULATION MODELS IN GHANA
Author:
Koranteng C.,Simons B.,Gyimah K.A.,Amos-Abanyie S.
Abstract
ABSTRACT
The research is based on the premise that in order for a building energy model to contribute to a sustainable energy future, the model’s accuracy must be ensured in order for the model’s results to be trusted. Therefore, validation processes in continuing Ghanaian building performance studies are outlined. The process started with long-term monitoring of low-rise, multi-storey and test cells structures. Combined with weather data from meteorological offices, reliance on synthetic weather files and local measurements, appropriate matching periods of weather data and measurements were used to simulate indoor parameters. Further, the simulated and measured data were in good agreement in terms of regression values (r2of 0.53–0.96). Energy use bills were used to validate energy loads of a multi-story building which resulted in a difference of 0.09% between the simulated and billed data. Furthermore, an approach of using the Coefficient of Variance for Root Mean Square Error (CV (RMSE)) was also presented. Considering the range of the regression values which could be due to the difficulty in the validating process; one can confidently rely on the outcome to predict building performance. Sampled challenges are the potential of synthetic weather files to overlook microclimatic conditions such as urban heat island effects; difficulty in predicting internal loads as comprehensive monitoring devices are lacking, e.g., occupancy sensors to monitor the actual number of people present at a time and their behaviour within spaces; system performance values which are known to decline with time, therefore, affecting measured versus simulated values; most firms not keeping energy bills and their unwillingness to provide the information to researchers; etc. The validated models can be used as scientific-based data and analysis to inform building designers decisions to reduce the economic and environmental burden in Ghana.
Publisher
College Publishing
Subject
General Environmental Science,Geography, Planning and Development,Civil and Structural Engineering,Building and Construction,Architecture,Environmental Engineering,Management, Monitoring, Policy and Law,Nature and Landscape Conservation,Public Health, Environmental and Occupational Health
Reference25 articles.
1. Validation of Simulated Mean Air Temperature and Mean Radiant Temperature Using Monitored Data from an Experimental Test Cell;Amos-Abanyie,,2017
2. Buyak
N.A.,
Deshko
V.I.
and
SukhodubI.O.(2017).
Buildings energy use and human thermal comfort according to energy and exergy approach.
http://www.elsevier.com/locate/enbuild. Date assessed 24th January, 2021.
3. Contrasting the Capabilities of Building Energy Performance Simulation Programs;Crawley,;Build Environ,2009
4. Fukuda
T.,
Kazuki
Y.,
Nobuyoshi
Y.
and
AliM.(2019).
An indoor thermal environment design system for renovation using augmented reality.
Division of Sustainable Energy and Environmental Engineering,
Graduate School of Engineering, Osaka University,
Suita, Osaka, Japan.
http://www.elsevier.com/locate/jcde. Date assessed 24th Janaury, 2021.
5. Windows for Quality Indoor Environments: A Case in the Warm Humid Climate of Ghana;Gyimah,2019