LEADER 04927nam 2201201z- 450 001 9910557629903321 005 20210501 035 $a(CKB)5400000000045115 035 $a(oapen)https://directory.doabooks.org/handle/20.500.12854/69325 035 $a(oapen)doab69325 035 $a(EXLCZ)995400000000045115 100 $a20202105d2020 |y 0 101 0 $aeng 135 $aurmn|---annan 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 00$aStructural Health Monitoring of Large Structures Using Acoustic Emission-Case Histories 210 $aBasel, Switzerland$cMDPI - Multidisciplinary Digital Publishing Institute$d2020 215 $a1 online resource (298 p.) 311 08$a3-03928-474-6 311 08$a3-03928-475-4 330 $aAcoustic emission (AE) techniques have successfully been used for assuring the structural integrity of large rocket motorcases since 1963, and their uses have expanded to ever larger structures, especially as structural health monitoring (SHM) of large structures has become the most urgent task for engineering communities around the world. The needs for advanced AE monitoring methods are felt keenly by those dealing with aging infrastructures. Many publications have appeared covering various aspects of AE techniques, but documentation of actual applications of AE techniques has been mostly limited to reports of successful results without technical details that allow objective evaluation of the results. There are some exceptions in the literature. In this Special Issue of the Acoustics section of Applied Sciences, we seek contributions covering these exceptions cited here. Here, we seek contributions describing case histories of AE applications to large structures that have achieved the goals of SHM by providing adequate technical information supporting the success stories. Types of structures can include aerospace and geological structures, bridges, buildings, factories, maritime facilities, off-shore structures, etc. Experiences with AE monitoring methods designed and proven for large stru 606 $aHistory of engineering and technology$2bicssc 610 $a2011 Tohoku earthquake 610 $a2D-MUSIC 610 $aacoustic emission 610 $aacoustic emission (AE) 610 $aacoustic emission swarm 610 $aalkali-silica reaction 610 $aasphalt pavements 610 $aattenuation 610 $ab-value 610 $abeam 610 $abridge 610 $abridges 610 $aclosed-form solution 610 $acomposite structure 610 $acomposites 610 $aconfinement 610 $acooling cycles 610 $acorrosion 610 $acrack growth 610 $acritical phenomena 610 $acrustal movement 610 $adamage evaluation 610 $adiagnostic methods 610 $adragline 610 $aembrittlement temperatures 610 $afatigue life prediction 610 $agas adsorber 610 $ahigh temperature 610 $ahigh-rate dynamics 610 $ahost rock 610 $ahydrotreater 610 $aimpact localization 610 $ain situ acoustic emission (AE) monitoring 610 $amines 610 $amultiplet 610 $an/a 610 $anatural time 610 $anon-destructive methods (NDT) 610 $anon-destructive testing 610 $anondestructive evaluation (NDE) 610 $anondestructive testing 610 $anuclear facilities 610 $aoptimized EEMD 610 $aoutlier 610 $apart qualification 610 $apattern recognition 610 $arecycled asphalt pavements 610 $arecycled asphalt shingles 610 $areliability 610 $aremote monitoring 610 $arepeating earthquake 610 $arotary kiln 610 $asensing 610 $asignal processing 610 $asource location 610 $astructural design 610 $astructural diagnosis 610 $astructural health monitoring 610 $astructural health monitoring (SHM) 610 $astructural integrity 610 $athermal cracking 610 $atime difference of arrival 610 $atime series analysis 610 $auncertainty analysis 610 $avibration 610 $aweight estimation 615 7$aHistory of engineering and technology 700 $aOno$b Kanji$4edt$01314054 702 $aShiotani$b Tomoki$4edt 702 $aWevers$b Martine$4edt 702 $aHamstad$b Marvin A$4edt 702 $aOno$b Kanji$4oth 702 $aShiotani$b Tomoki$4oth 702 $aWevers$b Martine$4oth 702 $aHamstad$b Marvin A$4oth 906 $aBOOK 912 $a9910557629903321 996 $aStructural Health Monitoring of Large Structures Using Acoustic Emission-Case Histories$93645621 997 $aUNINA