The results obtained in the first stage of this complex project were achieved in all component projects, the indicators being fulfilled for each activity.

The first component project identified the typologies of materials that can be integrated for the facades used for the experimental laboratory. The sorting of the results was based on several criteria, such as the market systems availability, thermal insulation degree and load-bearing capacity. In the second analysis phase, the materials proposed for closure were tested in parallel using experimental static tests (compression, bending and stretching) and toughness. The results show that the mechanical properties of sandwich panels depend both on the coating (aluminum, PVC or textile) but also on the panel core (PIR, PUR, MF foams, expanded polystyrene).

The second component project analyzes were focused on low thermal conductivity materials synthesis was structured on three directions of action:

• porous glass products - recipes for porous glass synthesis using two types of glass waste - glass panes and kinescope tube, together with other common wastes (fly ashes). The obtained results confirm the viability of the proposed solution;
• porous glass-ceramic products obtained using glass wastes (glass panes and CRT glass) together with fly ash from thermal power plant, previously used as adsorbent material. The results highlight that it is possible to obtain glass ceramic products with very good chemical resistance under economically advantageous conditions;
• coating deposition on porous glass substrate: TiO₂ and WO₃, synthesized in laboratory conditions by obtaining TiO₂ and WO₃ nanocrystals at temperatures lower than 250 ° C and pressures below 100 bars.

The third component project performed an analysis of the “smart grid” systems implementation on the facades of light structures. This phase established the voltage levels for the electricity distribution in d.c., the supply network structure and the consumers requirements. The main components were modeled: necessary static converters, electricity storage elements, new generators for the conversion of renewable energies, as well as the main control elements.

The fourth component project, carried out the following tasks:

• architectural optimization of the mobile modular laboratory EXPERIMENTARIUM, by ideal orientation towards the cardinal points and optimal roof inclinations in order to maximize the energy input given by the photovoltaic panels;
• resistance structure design for the mobile modular laboratory EXPERIMENTARIUM. The structural solution was chosen in frames made of lightweight cold profiles elements. This solution has multiple advantages, including quick and easy installation, no need for heavy equipment etc. In addition, the system transmits low loads to the foundations and the foundation ground;
• infrastructure design made through innovative foundation systems, on prefabricated foundations in the pyramid trunk shape, introduced into the soil by vibropressing. During the stage, soil research was also performed through geotechnical studies;
• studies on facade systems. Solar absorbing systems were considered and optimization studies were performed based on finite element analyzes for integration into the experimental model.