Periodic Reporting for period 3 - BRESAER (Breakthrough solutions for adaptable envelopes for building refurbishment)
Période du rapport: 2018-02-01 au 2019-07-31
BRESAER has the potential to solve this gap for innovation by using a combination of known and novel technologies, having potential for success when applied in residential and non-residential building refurbishment projects. The buildings’ envelope is the key element to address in order to significantly increase the energy efficiency and the use of RES.
The overall objective is to design, develop and demonstrate an innovative, cost-effective, adaptable and industrialized envelope system for buildings refurbishment including combined active and passive prefabricated solutions integrated in a versatile lightweight structural mesh. The whole building will be governed by an innovative Building Energy Management System covering a specific control system for governing the envelope, the energy use of the building and the strategies for the electrical energy storage. The solutions that integrate the envelope are:
• Dynamic window with automatic and controlled air-tightness and insulated solar blinds.
• Multifunctional lightweight ventilated façade module
• Multifunctional and multilayer insulation panels made of Ultra High Performance Fibre Reinforced Concrete.
• Combined solar thermal air and PV envelope component
• Cutting-edge Building Energy Management System.
IMAGE 1_BRESAER system overview
The BRESAER solution was demonstrate in a real case study in a building located in Burgos, Spain. The building hosts lecture rooms in a single floor with a total of 545m2 area and is part of Burgos’ University campus. Four additional virtual demonstrations were assessed in real building (Turkey, Norway, Estonia and Romania) covering European climatic zones and guaranteeing its replication potential.
IMAGE 2_Demonstration building in Burgos, Spain
To achieve BRESAER objectives, the work plan is structured in 7 Work Packages closely related to the project’s specific objectives.
IMAGE 3_BRESAER Work Packages structure
The main impacts of the implementation of the BRESAER system, which were evaluated throughout the project and which will continue to be assessed after the end of the project, are as follows: Energy demand reduction for space heating and cooling 30,7%, Contribution of renewable energy, conditioning of 37,3% after the retrofitting, Contribution of renewable energy (solar PV) for electricity of 12,8% after the retrofitting, The combination gives a total primary energy consumption reduction of 76,4%, Improved indoor environment quality by improving thermal, acoustics, illumination comfort and IAQ, Provide solutions with an appealing pay-back time for investors, Validation and market uptake of active building elements
Some of the main results of the 3rd period were
• Both the economic and environmental sustainability of the system were assessed through LCA and LCC studies
• The software tools to support future users when designing and implementing BRESAER system were optimized and are available at BRESAER’s website
• It was completed the CEN Workshop Agreement (CWA) entitled “Guideline to design, implement and economically assess an innovative and adaptable envelope system in building refurbishment”
• An interactive video was produced displaying all BRESAER technologies, (BRESAER website)
To sum up, all the targets have been achieved, which has allowed the successful achievement of the objectives of the BRESAER Project
IMAGE 4_BRESAER solutions strategically integrated
IMAGE 5_BRESAER Real Demo
The BRESAER solution is therefore a business opportunity as it is an energy efficient integrated and adaptable system that can be easily and quickly fitted to the façade of any residential building in Europe.
Socio-economic impacts created by the increase of building performance:
• Reduction of energy demand and associated costs. This reduction is maximized by the use of built-in renewables
• Reduction of greenhouse gas emissions, and to the reduction of local pollution
• Improvement of the thermal comfort of occupants and indoor environment quality
Socio-economic impact on the construction value chain:
• Green job creation: acceleration of the creation of new jobs in industries and construction companies
• Reduction of the construction time and occupational hazard, increase of the installation security
• Facilitation and acceleration of the renovation process in Europe thanks to the optimized industrialization of components
Finally, the demo sites (physical and virtual) of the project provided some recommendations in its political and geographical context and could be a reference for replication