Abstract
Magnetorheological materials have attracted a great deal of interests nowadays due to its controllable mechanical properties upon the application of external magnetic field. Its ability to change its rheological properties in a split second has found its way in the applications that require absorption and isolation of vibration and noise. However, the problems with oxidation, sedimentation and aggregation of the magnetic particles hinder the optimum performance that can be utilised with this smart material. This includes the reduced performance of yield stress, shear stress, shear modulus and storage modulus and over a long operational period, will affect its magnetisation properties. Hence, there is a need to protect the magnetic particles with coating layer which can overcome these drawbacks. The main focus of this work is to present an overview on the aforementioned problems in MR materials that can be controlled by applying protective coating on the magnetic particles. Several works have reported the enhancement of performances such as oxidation resistance, interface between particles and the carrier medium as well as sedimentation stability by introducing coated magnetic particles in the MR materials.
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References
Stenberg B, Lokander M, Reitberger T (2004) Magnetorheological elastomers—possibilities and limitations. Annu Trans Nordic Rheol Soc 12:163–170
Li W, Zhang X, Du H (2013) Magnetorheological elastomers and their applications. In: Visakh PM, Thomas S, Chandra AK, Mathew AP (eds) Advances in elastomers I: blends and interpenetrating networks. Springer, Berlin, pp 357–374
Hu B, Fuchs A, Huseyin S, Gordaninejad F, Evrensel C (2006) Atom transfer radical polymerized MR fluids. Polymer (Guildf) 47:7653–7663
Carlson JD, Jolly MR (2000) MR fluid, foam and elastomer devices. Mechatronics 10:555–569
Leong SAN et al (2016) An overview of nanoparticles utilization in magnetorheological materials. AIP Conf Proc 1710:020002
Mazlan SA, Ekreem NB, Olabi AG (2008) An investigation of the behaviour of magnetorheological fluids in compression mode. J Mater Process Technol 201:780–785
Malecki P, Krolewicz M, Krzak J, Kaleta J, Piglowski J (2015) Dynamic mechanical analysis of magnetorheological composites containing silica-coated carbonyl iron powder. J Intell Mater Syst Struct 26(14):1899–1905
Ubaidillah, Sutrisno J, Purwanto A, Mazlan SA (2014) Recent progress on magnetorheological solids: materials, fabrication, testing, and applications. Adv Eng Mater 1–35
Plachy T, Kutalkova E, Sedlacik M, Vesel A, Masar M (2018) Impact of corrosion process of carbonyl iron particles on magnetorheological behavior of their suspensions. J Ind Eng Chem 66:362–369
Zhang P, Zhen Y, Jin H, Lee C (2018) Tribological and rheological tests of core-shell typed carbonyl iron/polystyrene particle-based magnetorheological fluid. J Ind Eng Chem 68:342–349
Lee JH, Choi HJ (2018) Synthesis of core-shell formed carbonyl iron/polydiphenylamine particles and their rheological response under applied magnetic fields. Colloid Polym Sci 296:1857–1865
Wang G, Ma Y, Tong Y, Dong X (2017) Development of manganese ferrite/graphene oxide nanocomposites for magnetorheological fluid with enhanced sedimentation stability. J Ind Eng Chem 48:142–150
Bramantya MA, Sawada T (2011) The influence of magnetic field swept rate on the ultrasonic propagation velocity of magnetorheological fluids. J Magn Magn Mater 323:1330–1333
Lanzetta M, Iagnemma K (2013) Gripping by controllable wet adhesion using a magnetorheological fluid. CIRP Ann Manuf Technol 62(1):21–25
Bica I, Anitas EM (2018) Magnetic field intensity effect on electrical conductivity of magnetorheological biosuspensions based on honey, turmeric and carbonyl iron. J Ind Eng Chem 64:276–283
Mohamad N, Mazlan SA, Ubaidillah (2016) Effect of carbonyl iron particles composition on the physical characteristics of MR grease. AIP Conf Proc 1717:040027
Gordaninejad F, Miller M, Wang X, Sahin H, Fuchs A (2007) Study of a magneto-rheological grease (MRG) damper. In: Active and passive smart structures and integrated systems, vol 6525, pp 1–6
Zheng J, Li Y, Wang J, Shiju E, Li X (2018) Accelerated thermal aging of grease-based magnetorheological fluids and their lifetime prediction. Mater Res Express 5:085702
Yang P, Yu M, Luo H, Fu J, Qu H, Xie Y (2017) Improved rheological properties of dimorphic magnetorheological gels based on flower-like carbonyl iron particles. Appl Surf Sci 416:772–780
Sung G, Wan J, Hyeun J (2016) Fabrication of polyurethane composite foams with magnesium hydroxide filler for improved sound absorption. J Ind Eng Chem 44:99–104
Bandarian M, Shojaei A, Rashidi AM (2011) Thermal, mechanical and acoustic damping properties of flexible open-cell polyurethane/multi-walled carbon nanotube foams: effect of surface functionality of nanotubes. Polym Int 60:475–482
Baferani AH, Katbab AA, Ohadi AR (2017) The role of sonication time upon acoustic wave absorption efficiency, microstructure, and viscoelastic behavior of flexible polyurethane/CNT nanocomposite foam. Eur Polym J 90:383–391
Makarova LA et al (2019) Magnetorheological foams for multiferroic applications. J Magn Magn Mater 485:413–418
Agirre-Olabide I, Kuzhir P, Elejabarrieta MJ (2018) Linear magneto-viscoelastic model based on magnetic permeability components for anisotropic magnetorheological elastomers. J Magn Magn Mater 446:155–161
Seung HK, Ji SA, So YC, Kyoung HC, Hyoung JC (2019) Poly(glycidyl methacrylate) coated soft-magnetic carbonyl iron/silicone rubber composite elastomer and its magnetorheology. Macromol Res
Guan X, Dong X, Ou J (2008) Magnetostrictive effect of magnetorheological elastomer. J Magn Magn Mater 320:158–163
Abdul Aziz SA et al (2018) Effects of multiwall carbon nanotubes on viscoelastic properties of magnetorheological elastomer. Smart Mater Struct 25:077001
Yunus NA et al (2016) Rheological properties of isotropic magnetorheological elastomers featuring epoxidised natural rubber. Smart Mater Struct 25:107001
Lokander M, Reitberger T, Stenberg B (2004) Oxidation of natural rubber-based magnetorheological elastomers. Polym Degrad Stab 86(3):467–471
Cvek M, Mrlik M, Ilcikova M, Mosnacek J, Munster L, Pavliner V (2017) Synthesis of silicone elastomers containing silyl-based polymer-grafted carbonyl iron particles: an efficient way to improve magnetorheological, damping, and sensing performances. Macromolecules 50(5):2189–2200
Yao J, Sun Y, Wang Y, Fu Q, Xiong Z, Liu Y (2018) Magnet-induced aligning magnetorheological elastomer based on ultra-soft matrix. Compos Sci Technol 162:170–179
Wu J, Gong X, Chen L, Xia H, Hu Z (2009) Preparation and characterization of isotropic polyurethane magnetorheological elastomer through in situ polymerization. J Appl Polym Sci 114:901–910
Xu J et al (2018) The dynamic mechanical properties of magnetorheological plastomers under high strain rate. Compos Sci Technol 159:50–58
Zhao W, Pang H, Gong X (2017) A novel magnetorheological plastomer filled with NdFeB particles: preparation, characterization and magnetic-mechanic coupling properties. Ind Eng Chem Res 56(31):8857–8863
Xuan S, Zhang Y, Zhou Y, Gong X (2012) Magnetic plasticine: a versatile magnetorheological material. J Mater Chem 22:13395–13400
Pu H, Jiang F, Wang Y, Yan B (2010) Soft magnetic composite particles of reduced iron coated with poly (p-xylylene) via chemical vapor deposition polymerization. Colloids Surf A Physicochem Eng Asp 361(1–3):62–65
Wang G et al (2015) Facile synthesis and magnetorheological properties of superparamagnetic CoFe2O4/GO nanocomposites. Appl Surf Sci 357:2131–2135
Schubert G, Harrison P (2016) Magnetic induction measurements and identification of the permeability of magneto-rheological elastomers using finite element simulations. J Magn Magn Mater 404:205–214
Sohoni GB, Mark JE (1987) Anisotropic reinforcement in elastomers containing magnetic filler particles. J Appl Polym Sci 34(8):2853–2859
Tian T, Nakano M (2018) Fabrication and characterisation of anisotropic magnetorheological elastomer with 45° iron particle alignment at various silicone oil concentrations. J Intell Mater Syst Struct 29(2):151–159
Kukla M, Górecki J, Malujda I, Tala K, Tarkowski P (2017) The determination of mechanical properties of magnetorheological elastomers (MREs). Procedia Eng 177:324–330
Puente-Córdova JG, Reyes-Melo ME, Palacios-Pineda LM, MartÃnez-Perales IA, MartÃnez-Romero O, ElÃas-Zúñiga A (2018) Fabrication and characterization of isotropic and anisotropic magnetorheological elastomers, based on silicone rubber and carbonyl iron microparticles. Polymers (Basel) 10(12):1343
Sapouna K, Xiong YP, Shenoi RA (2017) Dynamic mechanical properties of isotropic/anisotropic silicon magnetorheological elastomer composites. Smart Mater Struct 26(11):115010
Cvek M et al (2015) A facile controllable coating of carbonyl iron particles with poly (glycidyl methacrylate): a tool for adjusting MR response and stability properties. J Mater Chem C 3:4646–4656
Nguyen P, Do X, Jeon J, Choi S, Liu YD, Choi HJ (2014) Brake performance of core–shell structured carbonyl iron/silica based magnetorheological suspension. J Magn Magn Mater 367:69–74
Park BJ, Kim MS, Choi HJ (2009) Fabrication and magnetorheological property of core/shell structured magnetic composite particle encapsulated with cross-linked poly (methyl methacrylate). Mater Lett 63(24–25):2178–2180
Tae HM, Hyoung JC, Kim N-H, Park K, You C-Y (2017) Effects of surface treatment on magnetic carbonyl iron/polyaniline microspheres and their magnetorheological study. Colloids Surf A 531:48–55
Hu ZD, Yan H, Qiu HZ, Zhang P, Liu Q (2012) Friction and wear of magnetorheological fluid under magnetic field. Wear 278–279:48–52
Zhang P, Lee KH, Lee CH (2017) Fretting friction and wear characteristics of magnetorheological fluid under different magnetic field strengths. J Magn Magn Mater 421:13–18
Jamari SKM (2015) Corrosion coatings using conducting polymer and green corrosion inhibitors. University of Malaya
Behrooz M, Sutrisno J, Zhang L, Fuchs A, Gordaninejad F (2015) Behavior of magnetorheological elastomers with coated particles. Smart Mater Struct 24(3):35026
Roupec J, Mazurek I (2011) Stability of magnetorheological effect during long term operation. In: Jablonski R, Brezina T (eds) Mechatronics. Springer, Berlin, Heidelberg
Fuchs A, Sutrisno J, Gordaninejad F, Caglar MB, Yanming L (2010) Surface polymerization of iron particles for magnetorheological elastomers. J Appl Polym Sci 117:934–942
Yu M, Qi S, Fu J, Zhu M, Chen D (2017) Understanding the reinforcing behaviors of polyaniline-modified carbonyl iron particles in magnetorheological elastomer based on polyurethane/epoxy resin IPNs matrix. Compos Sci Technol 139:36–46
Cvek M et al (2015) The chemical stability and cytotoxicity of carbonyl iron particles grafted with poly (glycidyl methacrylate) and the magnetorheological activity of their suspensions. RSC Adv 5:72816–72824
Fan M, He Z, Pang H (2013) Microwave absorption enhancement of CIP/PANI composites. Synth Met 166:1–6
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Jamari, S.K.M., Ubaidillah, U., Aziz, S.A.A., Nordin, N.A., Fajrin, A., Mazlan, S.A. (2020). Mini Review on Effect of Coatings on the Performance of Magnetorheological Materials. In: Sabino, U., Imaduddin, F., Prabowo, A. (eds) Proceedings of the 6th International Conference and Exhibition on Sustainable Energy and Advanced Materials. Lecture Notes in Mechanical Engineering. Springer, Singapore. https://doi.org/10.1007/978-981-15-4481-1_19
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