Restricted accessReview articleFirst published online 2022-3
Creep evaluation and temperature dependence in self-sensing micro carbon polymer-based composites for further development as an Internet of Things Sensor device
This article investigates the dependency of temperature on electrical resistance (R) change in micro carbon fiber polymer composites (MCFPC), for further development as an Internet of Things sensor from previous research works. Three mixtures were prepared using Dow Corning’s Silastic 145 as base polymer and made vary fiber content weight percentages: fiber diameter to length ratio ∅⁄l 0.13 and carbon fiber content of 13%; ∅⁄l:0.66 and carbon fiber contents of 40% and 50%. Composites tested were submitted to temperature loading, with a constant strain of 0.0%, for assessment of R when a change in the composite’s temperature occurs. The composite response was observed to follow an Arrhenius function, for temperatures ranging from −10°C to 40°C. The apparent activation energy was calculated to evaluate further differences between carbon fiber contents and the sensitivity factor, due to temperature is determined. The specimens were also tested with a constant strain of 2.86% to assess creep. It was found that creep and R, over the period of time in the analysis, best fit a discrete latent variable model. The sensitivity factor change is determined in regard to stress relaxation, . The properties of MCFPC investigated here can be used to establish relationships between electrical resistance outputs and environmental loading conditions for this type of composites, enabling the possibility of deployment as part of a management system network for structural monitoring with real-time data acquisition.
MirazMHAliMExcellPS, et al.“A review on Internet of Things (IoT), Internet of Everything (IoE) and Internet of Nano Things (IoNT)”. In: 2015 internet technologies and applications, Wrexham, UK, 8–11 September 2015, pp. 219–224.
2.
RyanPJWatsonRB, Research challenges for the internet of things: what role can or play?Systems2017; 5(1): 1–34.
3.
PatelKKPatelSMScholarPG, et al.Internet of things IoT: definition, characteristics, architecture, enabling technologies, application future challenges. Int J Eng2016; 6(5): 6122–6131.
4.
JainR. A congestion control system based on VANET for Small Length Roads. AETC2018; 2(1): 17–21.
5.
SoomroSMirazMHPrasanthA, et al.Artificial intelligence enabled IoT: traffic congestion reduction in smart cities. In: Smart cities symposium 2018, Bahrain, 22–23 April 2018, pp. 81–86.
6.
MahmudSHAssanLIslamR. “Potentials of Internet of Things (IoT) in malaysian construction industry”. AETC2018; 2(1): 44–52.
7.
Nag-ChowdhurySBellegouHPillinI, et al.Non-intrusive health monitoring of infused composites with embedded carbon quantum piezo-resistive sensors. Compos Sci Technol2016; 123: 286–294.
8.
RobertCPillinICastroM, et al.Multifunctional carbon nanotubes enhanced structural composites with improved toughness and damage monitoring. J Compos Sci2019; 3: 109.
9.
SanliABenchiroufAMüllerC, et al.Piezoresistive performance characterization of strain sensitive multi-walled carbon nanotube-epoxy nanocomposites. J Sens Actuators A Phys2017; 254: 61–68.
10.
WangYWangYWanB, et al.Strain and damage self-sensing of basalt fiber reinforced polymer laminates fabricated with carbon nanofibers/epoxy composites under tension. J Compos A Appl Sci Manuf2018; 113: 40–52.
11.
MeeuwHVietsCLiebigWV, et al.Morphological influence of carbon nanofillers on the piezoresistive response of carbon nanoparticle/epoxy composites under mechanical load. J Eur Polym2016; 85: 198–210.
12.
SchulteKBaronC. Load and failure analyses of CFRP laminates by means of electrical resistivity measurements. Composites Sci Technol1989; 36(1): 63–76.
13.
PillinICastroMNag ChowdhuryS, et al.Robustness of carbon nanotube-based sensor to probe composites’ interfacial damage in situ. J Compos Mater2015; 50: 109–113.
14.
EsmaeiliASbarufattiCMaD, et al.Strain and crack growth sensing capability of SWCNT reinforced epoxy in tensile and mode I fracture tests. J Compos Sci Technol2020; 186: 107918.
15.
WangLChengL. Piezoresistive effect of a carbon nanotube silicone-matrix composite. Carbon2014; 71: 319–331.
16.
TomásMJalaliS. Piezoresistivity in micro carbon fiber silicone composites for electrical resistance to strain sensing. Adv Eng Forum2017; 23: 45–55.
17.
FradenJ. Handbook of Modern Sensors: Physics, Designs, and Applications. New York: Springer Science & Business Media, 2004.
18.
Anas Wasill Alhashimi. Statistical Sensor Calibration Algorithms. PhD thesis. Sweden: Department of Computer Science Electrical and Space Engineering, Division of Signals and Systems, Luleå University of Technology, 2018.
19.
WangSWangDChungDDL, et al.Method of sensing impact damage in carbon fiber polymer-matrix composite by electrical resistance measurement. J Mater Sci2006; 41(8): 2281–2289.
20.
HolmesCGodfreyMBullDJ, et al.Real-time through-thickness and in-plane strain measurement in carbon fibre reinforced polymer composites using planar optical Bragg gratings. Opt Lasers Eng2020; 133: 106111.
21.
WangDWangSChungDDL, et al.Comparison of the electrical resistance and potential techniques for the self-sensing of damage in carbon fiber polymer-matrix composites. J Intell Mater Syst Structures2006; 17(853): 1–10.
22.
WangDChungDDL. Through-thickness stress sensing of a carbon fiber polymer-matrix composite by electrical resistance measurement. Smart Mater Struct2007; 16(4): 1320–1330.
23.
WangSChungDDL. Negative piezoresistivity in continuous carbon fiber epoxy-matrix composite. J Mater Sci2007; 42(13): 4987–4995.
24.
TodorokiAYoshidaJ. Apparent negative piezoresistivity of single-ply CFRP due to poor electrical contact of four-probe method. Key Eng Mater2005; 297-300: 610–615.
25.
HussainMChoaY-HNiiharaK. Fabrication process and electrical behavior of novel pressure-sensitive composites’. Compos A: Appl Sci Manuf2001; 32(12): 1689–1696.
26.
WangP. Piezoresistivity of conductive composites filled by carbon black particles. AMCS2004; 21(6): 34–38.
27.
McLachlanDSBlaszkiewiczMNewnhamRE. Electrical Resistivity of Composites. J Am Ceram Soc1990; 73(8): 2187–2203.
28.
BlaszkiewiczMMcLachlanDSNewhamRE. Study of the volume fraction, temperature, and pressure dependence of the resistivity in a ceramic polymer composites using GEM equation. J Mater Sci1991; 26: 899–903.
29.
ChenLChenGHLuL. Piezoresistive behavior study on finger-sensing silicone rubber/graphite nanosheet nanocomposites. Adv Funct Mater2007; 17(6): 898–904.
30.
KniteMTeterisVKiplokaA, et al.“Polyisoprene-carbon black nanocomposites as tensile strain and pressure sensor materials”. Sens Actuators A2004; 110(1–3): 142–149.
KazuyukiOYoshihideN. A new resistor having an anomalously large positive temperature coefficient. Jpn J Appl Phys1971; 10(1): 99.
33.
ParkJLeeSChoiJ. Cure monitoring and residual stress sensing of single-carbon fiber reinforced epoxy composites using electrical resistivity measurement. Composites Sci Technol2005; 65: 571–580.
34.
TodorokiATanakaMShimamuraY. Electrical resistance change method for monitoring delaminations of CFRP laminates: effect of spacing between electrodes. Composites Sci Technol2005; 65(1): 37–46.
35.
TodorokiA. Electrical resistance change of unidirectional cfrp due to applied load. JSME Int J2004; 47(3): 1–8.
36.
WangSChungDDLChungJH. Self-sensing of damage in carbon fiber polymer-matrix composite by measurement of the electrical resistance or potential away from the damaged region. J Mater Sci2005; 40(24): 6463–6472.
37.
AbryJCChoiYKChateauminoisA, et al.In-situ monitoring of damage in CFRP laminates by means of AC and DC measurements. Composites Sci Technol2001; 61(6): 855–864.
38.
TodorokiATanakaYShimamuraY. Multi-prove electric potential change method for delamination monitoring of graphite/epoxy composite plates using normalized response surfaces. Composites Sci Technol2004; 64(5): 749–758.
39.
ChungDDLWangS. Carbon fiber polymer-matrix structural composite as a semiconductor and concept of optoelectronic and electronic devices made from it. Smart Mater Struct1999; 8: 161–166.
40.
McCarterWJStarrsGChrispTM, et al.Activation energy and conduction in carbon fiber-reinforced cement matrices. J Mater Sci2007; 42: 2200–2203.
41.
RosenCZHiremathB. “Piezoelectricity”. New York: American Institute of Physics, 1982.
42.
ZenerC. Elasticity and Anelasticity of Metals. Chicago, Illinois: University of Chicago Press, 1948.
43.
BackmanDGWilliamsJC. Advanced materials for aircraft engine applications. Science1992; 255: 1082–1087.
44.
TimothyMJFullwoodDTHansenG. Strain monitoring of carbon fiber composite via embedded nickel nano-particles. Composites2012; 43: 1155–1163.
45.
ShuiXChungDDL. A piezoresistive carbon filament polymer-matrix composite strain sensor. Smart Mater Struct1996; 5: 243–246.
46.
ReyTChagnonGLe CamJ-B, et al. Effects of temperature on the mechanical behavior of filled and unfilled silicone rubbers. In: European Conference on Constitutive Models for Rubber VIII, San Sebastian, Spain, June, 2013
