A novel self-powered condition monitoring sensor for harsh environments - feasibility study

A.J. Reid, M.D. Judd

Research output: Contribution to conferencePaper

Abstract

Decreasing power requirements for wireless sensors coupled with the abundant supply of electromagnetic energy available within an electrical substation opens up the possibility of self-powered condition monitoring sensors that operate without the use of a battery by harnessing energy from the surrounding electric field. This paper investigates the feasibility of powering a wireless sensor by scavenging energy from an ambient electric field. Theoretical calculations are presented regarding the short circuit current and open circuit voltage available from the device. Practical measurements have also been carried out using a high voltage test rig. A prototype device has been built and the short circuit current extracted from the electric field measured directly using a small panel-mount ammeter located within the device. Two parallel plates of radius 10 cm separated be a distance of 10 cm and placed within a 200 kVm-1 electric field have the potential to supply about 300 mW to a sensor circuit. Although there is useful power available, the high output impedance of the device renders it inherently inefficient. More efficient means of converting the available power into a useful form are discussed
Original languageEnglish
Number of pages5
Publication statusPublished - 2007
Event15th International Symposium on High Voltage Engineering - Ljubljana, Slovenia
Duration: 27 Aug 200731 Aug 2007

Conference

Conference15th International Symposium on High Voltage Engineering
Abbreviated titleISH2007
CountrySlovenia
CityLjubljana
Period27/08/0731/08/07

Keywords

  • power requirements
  • wireless sensors
  • electromagnetic energy
  • self-powered condition monitoring sensors
  • harsh environments

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