Green building envelope designs in different climate and seismic zones: Multi-objective ANN-based genetic algorithm
Abstract
In recent years, the major component of green building designs adopted by governments in order to reduce CO2
emissions as well as energy consumption is the green building envelope. The green envelope has the most
important share in terms of thermal energy consumption, environment, and indoor comfort criteria. Determining
the most suitable building envelope combination in the building life cycle is an important problem for designers.
This study presents a new multi-objective approach that determines the most suitable green envelope designs for
the buildings in different climate and earthquake zones, taking into account CO2 emissions, heating/cooling
energy consumption, and material cost in terms of life cycle cost analysis. To this end, EnergyPlus building
performance simulation program, artificial neural network (ANN), and genetic algorithm are used together. After
the heating and cooling energy consumption, CO2 emissions, and material cost values are obtained for a certain
number of the envelope alternatives with the EnergyPlus, ANN models that learn the working mechanism of
EnergyPlus are trained according to these values. An ANN-based genetic algorithm procedure is developed to
search the whole envelope alternative space by using the trained ANN models with EnergyPlus. The proposed
approach allows searching in a very short time the whole alternative space, which is almost impossible to scan
with EnergyPlus by reducing the time spent and the number of alternatives required for the design and simulation processes of the green building envelope. The proposed approach is performed for a design-stage city
hospital structure in Turkey. Window type, the internal/external plaster, wall, and insulation materials along
with the thicknesses of these materials, which consist of 46 different variables, are determined as envelope attributes for four different climate and seismic zones. The green building envelope designs obtained with the
proposed approach are entered into EnergyPlus and the consistency of the results is compared. ANN models with
an average accuracy of over 97% are developed. Without the CO2 emission cost in the life cycle cost, the mean
absolute percent error (MAPE) values for each region are 0.67%, 0.6%, 0.58%, and 1.78%, respectively. With the
CO2 emission cost in life cycle cost, the MAPE values for each region are 0.96%, 0.88%, 0.86%, and 0.43%,
respectively. According to the obtained results, there is a consistency of over 99% between EnergyPlus and the
proposed approach.