Abstract
This study focuses on the development and integrated design over a 24-month period of a high efficiency energy-harvesting (EH) temperature sensor, based on piezoelectric materials, with applications for the sustainability of smart buildings, structures and infrastructures. The EH sensor, harvests the airflow inside Heating, Ventilation and Air Conditioning (HVAC) systems, using a piezoelectric component and an appropriate customizable aerodynamic fin that takes advantage of specific air flow effects, and is implemented for optimizing the energy consumption in buildings. The project was divided in several work-packages (some running in parallel) that cover different aspects of the device development. Some of them focus on engineering aspects (starting from the numerical modeling, then prototyping, and concluding with experimental testing). Other aspects focus on the sensor promotion (including the development of a business plan, the intellectual property rights, the final design and the go-to-market actions). Considering the multidisciplinary character of the project (involving knowledge from fields such as wind engineering, electrical engineering, industrial design, entrepreneurship), this study tries to provide an insight on the complex design issues that arise when such complex, sometimes conflicting and overlapping aspects have to be managed within strict deadlines. In doing so, the most important design and development aspects are critically presented.
Highlights
E ngineers, designers and planners, are nowadays very sensitive to issues related to the sustainability of structures
The best solution is to employ wireless autonomous sensors powered by Energy Harvesting (EH) devices
This study focuses on an advanced autonomous sensor for the temperature sensing in building HVAC (Heating, Ventilation and Air Condition) systems
Summary
E ngineers, designers and planners, are nowadays very sensitive to issues related to the sustainability of structures. One of the objectives of Building Automation is to automatize the systems in the building through the monitoring of ambient parameters using properly installed sensors These sensors can be powered through the mains or in alternative, can be selfpowered. This study focuses on an advanced autonomous sensor for the temperature sensing in building HVAC (Heating, Ventilation and Air Condition) systems It consists in an energy harvesting device that uses a piezoelectric bender and an appropriate customizable aerodynamic appendix that takes advantage of specific airflow effects (vortex shedding and galloping) for producing energy. This kind of flow is typical in HVAC networks. The sensor is completed with a temperature probe, a wireless module and an USB dongle receiver (Fig. 1)
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