Quantitative health monitoring of bolted joints using a piezoceramic actuator–sensor

Ritdumrongkul, Sopon; Abé, Masato; Fujino, Yozo; Miyashita, Takeshi

doi:10.1088/0964-1726/13/1/003

Cited by 132 publications

(102 citation statements)

References 25 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In addition to the studies on modeling of this method, there have been other researchers who conducted studies on adequacy of this method in detection and evaluation of looseness of bolted structures. Ritdumrongkul et al, besides modeling the electrical impedance of a structure, studied the efficiency of the method empir- ically, having a wave dispersal approach; while they provided indices to quantify the amount of looseness, they examined the sensitivity of indices to firmness and attenuation of joints (Ritdumrongkul, et al, 2004). Providing an index for evaluation of the looseness of bolts, Park et al surveyed the efficiency of the method in detecting looseness in bolted joints of pipelines (Overly, et al, 2007;Park, et al, 2001).…”

Section: Impedance Based Methodsmentioning

confidence: 99%

A Review Paper on Looseness Detection Methods in Bolted Structures

Nikravesh

Goudarzi

2017

Lat. Am. j. solids struct.

101

View full text Add to dashboard Cite

Bolted structures are widely utilized in industrial structures and equipment due to the numerous advantages they possess. However, the use of bolts in these structures by itself can cause considerable flaws or damages. One of the major reasons of flaw in such structures is looseness. Since the looseness is initiated with a reduction in the axial force, measurement and estimation of this force can contribute to a healthy performance of the structure. The methods used to measure axial force of bolts are divided into two: those which measure or estimate the force directly and those which, by controlling physical parameters, do this indirectly. Ba-sed on this categorization, this paper examines over 16 methods used for evaluation of axial force of bolted structures, and presents their theoretical bases, drawbacks and advantages, with the litera-ture on each method being discussed separately. Finally, the met-hods are compared and the most important criteria in selecting the methods are introduced.

show abstract

Section: Impedance Based Methodsmentioning

confidence: 99%

A Review Paper on Looseness Detection Methods in Bolted Structures

Nikravesh

Goudarzi

2017

Lat. Am. j. solids struct.

101

View full text Add to dashboard Cite

show abstract

“…Structural health monitoring (SHM) has made significant advances in the past decades [1][2][3][4][5][6][7][8]. Monitoring of refractories, which are widely used in furnace, iron, and steel industries due to their ability to gain strength rapidly and to withstand aggressive environments and high temperature [9], receives increasing attention [10][11][12][13].…”

Section: Introductionmentioning

confidence: 99%

Damage Detection of Refractory Based on Principle Component Analysis and Gaussian Mixture Model

et al. 2018

View full text Add to dashboard Cite

Acoustic emission (AE) technique is a common approach to identify the damage of the refractories; however, there is a complex problem since there are as many as fifteen involved parameters, which calls for effective data processing and classification algorithms to reduce the level of complexity. In this paper, experiments involving three-point bending tests of refractories were conducted and AE signals were collected. A new data processing method of merging the similar parameters in the description of the damage and reducing the dimension was developed. By means of the principle component analysis (PCA) for dimension reduction, the fifteen related parameters can be reduced to two parameters. The parameters were the linear combinations of the fifteen original parameters and taken as the indexes for damage classification. Based on the proposed approach, the Gaussian mixture model was integrated with the Bayesian information criterion to group the AE signals into two damage categories, which accounted for 99% of all damage. Electronic microscope scanning of the refractories verified the two types of damage.

show abstract

“…The analytical relationship between the piezoelectric impedance and the mechanical impedance of the host structure was established for the first time. Sopon et al [18] used a piezoelectric transducer (PZT) as an actuator-sensor collectively in conjunction with the numerical model-based spectral element method (SEM) in structural health monitoring to quantitatively detect damage of bolted joints. By analyzing the characteristics of the piezoelectric element under the bolt looseness condition, Gao et al [19] concluded that the conductance of the piezoelectric patches changes significantly under the high-frequency (more than 50 kHz) voltage excitation.…”

Section: Introductionmentioning

confidence: 99%

A Smart Washer for Bolt Looseness Monitoring Based on Piezoelectric Active Sensing Method

et al. 2016

View full text Add to dashboard Cite

Piezoceramic based active sensing methods have been researched to monitor preload on bolt connections. However, there is a saturation problem involved with this type of method. The transmitted energy is sometimes saturated before the maximum preload which is due to it coming into contact with flat surfaces. When it comes to flat contact surfaces, the true contact area will easily saturate with the preload. The design of a new type of bolt looseness monitoring sensor, a smart washer, is to mitigate the saturation problem. The smart washer is composed of two annular disks with contact surfaces that are machined into convex and concave respectively, to eliminate the complete flat contact surfaces and to reduce the saturation effect. One piezoelectric patch is bonded on the non-contact surface of each annular disk. These two mating annular disks form a smart washer. One of the two piezoelectric patches serves as an actuator to generate an ultrasonic wave that propagates through the contact surface; the other one serves as a sensor to detect the propagated waves. The wave energy propagated through the contact surface is proportional to the true contact area which is determined by the bolt preload. The time reversal method is used to extract the peak of the focused signal as the index of the transmission wave energy; then, the relationship between the signal peak and bolt preload is obtained. Experimental results show that the focused signal peak value changes with the bolt preload and presents an approximate linear relationship when the saturation problem is experienced. The proposed smart washer can monitor the full range of the rated preload.

show abstract

Quantitative health monitoring of bolted joints using a piezoceramic actuator–sensor

Cited by 132 publications

References 25 publications

A Review Paper on Looseness Detection Methods in Bolted Structures

A Review Paper on Looseness Detection Methods in Bolted Structures

Damage Detection of Refractory Based on Principle Component Analysis and Gaussian Mixture Model

A Smart Washer for Bolt Looseness Monitoring Based on Piezoelectric Active Sensing Method

Contact Info

Product

Resources

About