Antenna/sensor multifunctional composites for the wireless detection of damage

Wireless structural health monitoring (SHM) techniques generally rely on the integration of sensors, transmitters, and antennas into structures; however, the ideal solution would entail the material itself acting as a monitoring system. The current work investigates the application of antenna/sensing multifunctional composites. In this technique, carbon fiber reinforced plastic (CFRP) structures are modeled as half-wavelength dipole antennas. The electrical or antenna property varies in accordance with damage occurrence and can be monitored wirelessly at a remote location. The feasibility of wireless SHM using the self-sensing antenna technique is investigated analytically and experimentally using unidirectional CFRP laminates and rotor blades of woven CFRP. The CFRP radiates radio energy well when it is used as a half-wavelength dipole antenna, and damages to the CFRP can be wirelessly detected by monitoring an increase in the resonant frequency of the CFRP antenna.

[1]  Vijay K. Varadan Wireless microsensors for health monitoring of aircraft structures , 2003, SPIE MOEMS-MEMS.

[2]  Hoon Sohn,et al.  A review of structural health monitoring literature 1996-2001 , 2002 .

[3]  Akira Todoroki,et al.  Time-synchronized wireless strain and damage measurements at multiple locations in CFRP laminate using oscillating frequency changes and spectral analysis , 2008 .

[4]  Jennifer M. English,et al.  A flexible, self-healing sensor skin , 2006 .

[5]  Jayanth N. Kudva,et al.  Design and development of a conformal load-bearing smart skin antenna: overview of the AFRL Smart Skin Structures Technology Demonstration (S3TD) , 1999, Smart Structures.

[6]  Donald G. Krantz,et al.  Remotely queried wireless embedded microsensors in composites , 1997, Smart Structures.

[8]  A. Todoroki,et al.  Strain and Damage Monitoring of CFRP Laminates by Means of Electrical Resistance Measurement , 2007 .

[9]  Joseph J. Carr,et al.  Practical Antenna Handbook , 1990 .

[10]  Jayanth N. Kudva,et al.  Structural finite-element modeling strategies for conformal load-bearing antenna structure (CLAS) (Air Force contract F33615-C-93-3200) , 1997, Smart Structures.

[11]  A. Todoroki,et al.  Wireless detection of internal delamination cracks in CFRP laminates using oscillating frequency changes , 2006 .

[12]  Woonbong Hwang,et al.  Buckling characteristics of smart skin structures , 2004 .

[13]  Constantine A. Balanis,et al.  Antenna Theory: Analysis and Design , 1982 .

[14]  Wee Sang Park,et al.  Fatigue Characteristics of a Surface Antenna Structure Designed for Satellite Communication , 2005 .

[15]  Vijay K. Varadan,et al.  Design and development of smart skin conformal antenna with MEMS structural sensors and actuators , 1997, Smart Structures.

[16]  W. Hwang,et al.  Antenna Integration with Composite Sandwich Structures using Gain Enhancement Methods , 2007 .

[17]  Jayanth N. Kudva,et al.  Development of a structurally integrated conformal load-bearing multifunction antenna: overview of the Air Force Smart Skin Structures Technology Demonstration Program , 1996, Smart Structures.

[18]  Lan Yao,et al.  Design and fabrication of microstrip antennas integrated in three dimensional orthogonal woven composites , 2009 .

[19]  Woonbong Hwang,et al.  Design of load-bearing antenna structures by embedding technology of microstrip antenna in composite sandwich structure , 2005 .