Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
The knowledge of the load in prestressed bolted connections is essential for the proper operation and safety of engineering structures. Recently, bolted joints have become an area of intensive research associated with non-destructive diagnostics, in particular in the context of wave propagation techniques. In this paper, a novel procedure of bolt load estimation based on the energy of Lamb wave signals was proposed. Experimental tests were performed on a single lap joint of two steel plates. Ultrasonic waves were excited and registered by means of piezo-electric transducers, while precise measurement of the bolt load was obtained by means of using the force washer transducer. Experimental tests were supported by the finite element method analysis based on Schoenberg’s concept. The results showed that the relationship between the bolt load and signal energy was strongly nonlinear and it depended on the location of acquisition points.
Rocznik
Tom
Strony
1161--1169
Opis fizyczny
Bibliogr. 28 poz., rys.
Twórcy
autor
- Department of Mechanics of Materials and Structures, Faculty of Civil and Environmental Engineering, Gdańsk University of Technologyul. Narutowicza 11/12, 80-233 Gdańsk, Poland
autor
- Department of Mechanics of Materials and Structures, Faculty of Civil and Environmental Engineering, Gdańsk University of Technologyul. Narutowicza 11/12, 80-233 Gdańsk, Poland
Bibliografia
- [1] D. Chen, Y. Ma, B. Hou, R. Liu, and W. Zhang, “Tightening Behavior of Bolted Joint with Non-parallel Bearing Surface”, Int. J. Mech. Sci., 153‒154, 240‒253 (2019).
- [2] J. Seo, J. Hu and K.-H. Kim, “Analytical Investigation of the Cyclic Behavior of Smart Recentering T-Stub Components with Superelastic SMA Bolts”, Metals, 7, 386, (2017).
- [3] J. Álvarez, R. Lacalle, B. Arroyo, S. Cicero, and F. Gutiérrez-So-lana, “Failure Analysis of High Strength Galvanized Bolts Used in Steel Towers”, Metals, 6, 163, (2016).
- [4] H. Cho and C.J. Lissenden, “Structural health monitoring of fatigue crack growth in plate structures with ultrasonic guided waves”, Struct. Heal. Monit. 11, 393–404 (2012).
- [5] B. Yang, F.-Z. Xuan, Y. Xiang, D. Li, W. Zhu, X. Tang, J. Xu, K. Yang, and C. Luo, “Lamb Wave-Based Structural Health Monitoring on Composite Bolted Joints under Tensile Load”, Materials, 10, 652, (2017).
- [6] M. Rucka, “Monitoring Steel Bolted Joints during a Monotonic Tensile Test Using Linear and Nonlinear Lamb Wave Methods: A Feasibility Study”, Metals, 8, 683, (2018).
- [7] J. Hoła, J. Bień, L. Sadowski, and K. Schabowicz, “Nondestructive and semi-destructive diagnostics of concrete structures in assessment of their durability, Bull. Pol. Ac.: Tech. 63, 87–96, (2015).
- [8] A. Garbacz, “Application of stress based NDT methods for concrete repair bond quality control”, Bull. Pol. Ac.: Tech. 63, 77–85, (2015).
- [9] B. Goszczyńska, G. Świt, and W. Trąmpczyński, “Analysis of the microcracking process with the Acoustic Emission method with respect to the service life of reinforced concrete structures with the example of the RC beams”, Bull. Pol. Ac.: Tech. 63, 55–63, (2015).
- [10] A. Mita and A. Fujimoto, “Active detection of loosened bolts using ultrasonic waves and support vector machines”, in: Proceeding 5th Int. Work. Struct. Heal. Monit., pp. 1017–1024, 2005.
- [11] S.-H. Park, C.-B. Yun, and Y. Roh, “PZT-induced Lamb Waves and Pattern Recognitions for On-line Health Monitoring of Jointed Steel Plates”, in: Proc. SPIE 5765, Smart Struct. Mater. 2005 Sensors Smart Struct. Technol. Civil, Mech. Aerosp. Syst., pp. 364–375, 2005.
- [12] J. Yang and F.K. Chang, “Detection of bolt loosening in C-C composite thermal protection panels: I. Diagnostic principle”, Smart Mater. Struct. 15, 581–590, (2006).
- [13] J. Yang and F.K. Chang, “Detection of bolt loosening in C-C composite thermal protection panels: II. Experimental verifica-tion”, Smart Mater. Struct. 15, 591–599, (2006).
- [14] D. Doyle, A. Zagrai, B. Arritt and H. Çakan, “Damage detec-tion in bolted space structures”, J. Intell. Mater. Syst. Struct. 21, 251–264, (2010).
- [15] Y.K. An and H. Sohn, “Integrated impedance and guided wave based damage detection”, Mech. Syst. Signal Process. 28, 50–62, (2012).
- [16] E. Sevillano, R. Su and R. Perera, “Damage detection based on power dissipation measured with PZT sensors through the combination of electro-mechanical impedances and guided waves”, Sensors, 16, 639, (2016).
- [17] F. Amerini and M. Meo, “Structural health monitoring of bolted joints using linear and nonlinear acoustic/ultrasound methods”, Struct. Heal. Monit. 10, 659–672, (2011).
- [18] J. Martinez, A. Sisman, O. Onen, D. Velasquez, and R. Guldiken, “A synthetic phased array surface acoustic wave sensor for quantifying bolt tension”, Sensors, 12, 12265–12278, (2012).
- [19] T. Wang, G. Song, Z. Wang, and Y. Li, “Proof-of-concept study of monitoring bolt connection status using a piezoelectric based active sensing method”, Smart Mater. Struct. 22, 087001, (2013).
- [20] J. Ruan, Z. Zhang, T. Wang, Y. Li, and G. Song, “An anti-noise real-time cross-correlation method for bolted joint monitoring using piezoceramic transducers”, Smart Struct. Syst. 16, 281–294, (2015).
- [21] W. Tao, L. Shaopeng, S. Junhua, and L. Yourong, “Health monitoring of bolted joints using the time reversal method and piezo-electric transducers”, Smart Mater. Struct. 25, 25010, (2016).
- [22] S.M. Parvasi, S.C.M. Ho, Q. Kong, R. Mousavi, and G. Song, “Real time bolt preload monitoring using piezoceramic transducers and time reversal technique – A numerical study with experimental verification”, Smart Mater. Struct. 25, 1–11, (2016).
- [23] M. Mandal and A. Asif, Continuous and Discrete Time Signals and Systems, Cambridge University Press, 2007.
- [24] M. Schoenberg, “Elastic wave behavior across linear slip inter-faces”, J. Acoust. Soc. Am. 68, 1516–1521, (1980).
- [25] R.D. Mindlin, “Compliance of elastic bodies in contact”, J. Appl. Mech. 16, 259–268, (1949).
- [26] S. Biwa, S. Hiraiwa, and E. Matsumoto, “Stiffness evaluation of contacting surfaces by bulk and interface waves”, Ultrasonics47 123–129 (2007).
- [27] R. Kędra and M. Rucka, “Modelling of elastic wave propagation in a bolted joint using a thin layer of shell elements”, in: Shell Struct. Theory Appl. 4, CRC Press/Balkema, pp. 293–296, 2018.
- [28] C. Ramadas, K. Balasubramaniam, A. Hood, M. Joshi, and C.V. Krishnamurthy, “Modelling of attenuation of lamb waves using rayleigh damping: Numerical and experimental studies”, Compos. Struct. 93, 2020–2025 (2011)
Uwagi
PL
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-86b61671-8a4c-43d1-8aa2-25f4ddfc6b88