Environmental Thermal Energy Scavenging Powered Wireless Sensor Network for Building Monitoring

Huang, Qian; Lü, Chao; Shaurette, Mark; Cox, Robert F.

doi:10.22260/isarc2011/0258

Cited by 9 publications

(16 citation statements)

References 8 publications

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“…One side of the module is to be the hot side where heat is applied, while the other side is called the cold side where heat gets dissipated or rejected, Figure 1 below shows a schematic of a TEG module. [3,4] The generated voltage from a TEG is directly proportional to the temperature difference between both sides of the module and the Seebeck coefficient of the material used is shown in Equation 1.…”

Section: Introductionmentioning

confidence: 99%

Thermoelectric generator experimental performance testing for wireless sensor network application in smart buildings

et al. 2017

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Abstract. In order to make a conventional building more efficient or smarter, systems feedbacks are essential. Such feedbacks can include realtime or logged data from various systems, such as temperature, humidity, lighting and CO2 levels. This is only possible by the use of a network of sensors which report to the building management system. Conventional sensors are limited due to wiring and infrastructure requirements. Wireless Sensor Networks (WSN) however, eliminates the wiring limitations but still in certain cases require periodical battery changes and maintenance. A suitable solution for WSN limitations is to use different types of ambient energy harvesters to power battery-less sensors or alternatively to charge existing batteries so as to reduce their changing requirements. Such systems are already in place using various energy harvesting techniques. Thermoelectric Generators (TEG) are one of them where the temperature gradient is used to generate electricity which is conditioned and used for WSN powering applications. Researchers in this field often face difficulty in estimating the TEG output at the low-temperature difference as manufacturers' datasheets and performance data are not following the same standards and in most cases cover the high-temperature difference (more than 200C o ). This is sufficient for industrial applications but not for WSN systems in the built environment where the temperature difference is much smaller (1-20C o is covered in this study). This paper presents a TEG experimental test setup using a temperature controlled hotplate in order to provide accurate TEG performance data at the low-temperature difference range.

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Section: Introductionmentioning

confidence: 99%

Thermoelectric generator experimental performance testing for wireless sensor network application in smart buildings

et al. 2017

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“…The TEG generated power is measured at 0.95 mW with a 4 ∘ C temperature difference in this work, whilst in [35], 0.2 mW is generated with a 3.5 ∘ C temperature difference. In addition to the higher output power, the bulk Time interval between two WSN mote measurements (s) Figure 22: Thermoelectric energy harvester prototype charging supercapacitor.…”

Section: Thermoelectric Energy Harvester Implementation and Experimenmentioning

confidence: 86%

Thermoelectric Energy Harvesting for Building Energy Management Wireless Sensor Networks

Wang¹,

Cionca²,

Wang³

et al. 2013

International Journal of Distributed Sensor Networks

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A thermoelectric energy harvester powered wireless sensor networks (WSNs) module designed for building energy management (BEM) applications is built and tested in this work. An analytic thermoelectric generator (TEG) electrical model is built and verified based on parameters given in manufacturer data sheets of Bismuth Telluride TEGs. A charge pump/switching regulator two-stage ultra-low voltage step-up DC/DC converter design is presented in this work to boost the <0.5 V output voltage of TEG to usable voltage level for WSN (3.3 V). The design concept, device simulation, circuits schematic, and the measurement results are presented in detail. The prototype device test results show 25% end-to-end conversion efficiency in a wide range of input temperatures/voltages. Further tests demonstrate that the proposed thermoelectric generator design can effectively power WSN module which operates with a 1.7% duty cycle (5.8 seconds measurement time interval) when the prototype is placed on a typical wall-mount heater (60 ∘ C surface temperature). The thermoelectric energy harvesting powered WSN demonstrates duty cycles significantly higher than the required duty cycle for BEM WSN applications.

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“…As time goes on, the controllable load queues evolve based on Equation (13). The problem can be expressed as: (7) and (11), controllable load queues are mean rate stable ∀i, t.…”

Section: Problem Formulationmentioning

confidence: 99%

“…The original problem Equation (20) is transformed into the following problem by minimizing the right-hand side of Equation (30). (7) and (11), ∀i, t.…”

Section: Lemma 2 (Drift Bound) For Any Control Policy That Satisfiesmentioning

confidence: 99%

“…An important way to improve the operation utility of households is through a Home Energy Management System (HEMS) [6]. It is employed to collect data from household appliances using smart meters and sensors [7] and then to optimize power supply and management with this information [8,9]. It is expected to guarantee economic efficiency and operation security in households.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

An Event-Triggered Online Energy Management Algorithm of Smart Home: Lyapunov Optimization Approach

Fan¹,

Liu²,

Zhang³

2016

Energies

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As an important component of the smart grid on the user side, a home energy management system is the core of optimal operation for a smart home. In this paper, the energy scheduling problem for a household equipped with photovoltaic devices was investigated. An online energy management algorithm based on event triggering was proposed. The Lyapunov optimization method was adopted to schedule controllable load in the household. Without forecasting related variables, real-time decisions were made based only on the current information. Energy could be rapidly regulated under the fluctuation of distributed generation, electricity demand and market price. The event-triggering mechanism was adopted to trigger the execution of the online algorithm, so as to cut down the execution frequency and unnecessary calculation. A comprehensive result obtained from simulation shows that the proposed algorithm could effectively decrease the electricity bills of users. Moreover, the required computational resource is small, which contributes to the low-cost energy management of a smart home.

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Environmental Thermal Energy Scavenging Powered Wireless Sensor Network for Building Monitoring

Cited by 9 publications

References 8 publications

Thermoelectric generator experimental performance testing for wireless sensor network application in smart buildings

Thermoelectric generator experimental performance testing for wireless sensor network application in smart buildings

Thermoelectric Energy Harvesting for Building Energy Management Wireless Sensor Networks

An Event-Triggered Online Energy Management Algorithm of Smart Home: Lyapunov Optimization Approach

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