Optimizing components and evaluating technical performance of IR thermographic NDT systems; Proceedings of SPIE; Vol. 9861 : Thermosense: Thermal Infrared Applications XXXVIII

Optimizing components and evaluating technical performance of IR thermographic NDT systems; Proceedings of SPIE; Vol. 9861 : Thermosense: Thermal Infrared Applications XXXVIII

Dettagli Bibliografici
Parent link:	Proceedings of SPIE Vol. 9861 : Thermosense: Thermal Infrared Applications XXXVIII.— 2016.— [98610M]
Autore principale:	Chulkov A. O. Arseniy Olegovich
Ente Autore:	Национальный исследовательский Томский политехнический университет (ТПУ) Институт неразрушающего контроля (ИНК) Лаборатория № 34 (Тепловых методов контроля)
Altri autori:	Vavilov V. P. Vladimir Platonovich, Pawar S. S. Sachin Sampatrao
Riassunto:	Title screen A typical infrared (IR) thermographic system intended for active thermal/IR nondestructive testing includes a heat source, an IR imager and a computer. The software ensures acquisition and processing of IR image sequences to result in a binary map of defects or other image which is to be interpreted by a thermographer in order to meet inspection requirements. Typically, hardware developers supply a certain set of technical parameters of their units, such as heater power, imager temperature resolution, acquisition rate and a set of available data processing algorithms. The suggested approach allows optimization of inspection parameters if thermal and optical parameters of test materials are known. © (2016) COPYRIGHT Society of Photo-Optical Instrumentation Engineers (SPIE). Downloading of the abstract is permitted for personal use only. Режим доступа: по договору с организацией-держателем ресурса
Lingua:	inglese
Pubblicazione:	2016
Serie:	Nondestructive Testing and Composites
Soggetti:	электронный ресурс труды учёных ТПУ инфракрасное излучение неразрушающий контроль обработка данных алгоритмы
Accesso online:	http://dx.doi.org/10.1117/12.2222981
Natura:	Elettronico Capitolo di libro
KOHA link:	https://koha.lib.tpu.ru/cgi-bin/koha/opac-detail.pl?biblionumber=654083

Documenti analoghi

Active thermal NDT: problems and solutions; Proceedings of SPIE; Vol. 9861 : Thermosense: Thermal Infrared Applications XXXVIII
di: Vavilov V. P. Vladimir Platonovich
Pubblicazione: (2016)

Evaluating impact damage in graphite epoxy composite by using low-power vibrothermography; Proceedings of SPIE; Vol. 9861 : Thermosense: Thermal Infrared Applications XXXVIII
di: Derusova D. A. Dariya Aleksandrovna
Pubblicazione: (2016)

Detecting water in aviation honeycomb structures by using transient infrared thermographic NDT; Thermosense XXV, Orlando, April 21, 2003
Pubblicazione: (2003)

Pulsed thermal NDT in tables, figures, and formulas; Proceedings of SPIE; Vol. 9485 : Thermosense: Thermal Infrared Applications XXXVII
di: Vavilov V. P. Vladimir Platonovich
Pubblicazione: (2015)

Principle, Equipment and Applications of Line-Scanning Infrared Thermographic NDT; Journal of Nondestructive Evaluation; Vol. 42
Pubblicazione: (2023)

Statistical evaluation of thermographic NDT performance applied to CFRP; Thermosense XVIII: An International Conference on Thermal Sensing and Imaging, Orlando, April 08, 1996
di: Vavilov V. P. Vladimir Platonovich
Pubblicazione: (1996)

Noise suppression in pulsed IR thermographic NDT: Efficiency of data processing algorithms; NDT & E International; Vol. 148
Pubblicazione: (2024)

Ultrasonic and optical stimulation in IR thermographic NDT of impact damage in carbon composites; Quantitative InfraRed Thermography Journal; Vol. 12, № 2
di: Vavilov V. P. Vladimir Platonovich
Pubblicazione: (2015)

Quantitative evaluation of water content in composite honeycomb structures by using one-sided IR thermography: is there any promise?; Proceedings of SPIE; Vol. 10214 : Thermosense: Thermal Infrared Applications XXXIX
Pubblicazione: (2017)

Infrared thermographic evaluation of flame turbulence scale; Infrared Physics & Technology; Vol. 72
Pubblicazione: (2015)

Infrared corrosion detection; Неразрушающий контроль
di: Tuhtamishov S. R.
Pubblicazione: (2011)

Inspecting smokestacks by IR thermographic surveying and heat conduction modeling; Thermosense XXIII, Orlando, April 16, 2001
di: Vavilov V. P. Vladimir Platonovich
Pubblicazione: (2001)

Enhancing Generalizability of a Machine Learning Model for Infrared Thermographic Defect Detection by Using 3D Numerical Modeling; Fracture and Structural Integrity; Vol. 18, iss. 70
di: Chulkov A. O. Arseniy Olegovich
Pubblicazione: (2024)

Comparing thermal stimulation techniques in infrared thermographic inspection of corrosion in steel; IOP Conference Series: Materials Science and Engineering; Vol. 81 : Radiation-Thermal Effects and Processes in Inorganic Materials
di: Chulkov A. O. Arseniy Olegovich
Pubblicazione: (2015)

IR thermographic inspection of filament wound CFRP shell samples; Thermosense XXIX, Orlando, April 09-12, 2007
Pubblicazione: (2007)

How accurate is the IR thermographic evaluation of heat losses from buildings?; Quantitative InfraRed Thermography Journal; Vol. 7, iss. 2
di: Vavilov V. P. Vladimir Platonovich
Pubblicazione: (2010)

Reply to comment on "how accurate is the IR thermographic evaluation of heat losses from buildings?"; Quantitative InfraRed Thermography Journal; Vol. 8, № 1
di: Vavilov V. P. Vladimir Platonovich
Pubblicazione: (2011)

Using the theory of heat conduction in the IR thermographic inspection of rotating cement kilns; Thermosense XXVI, Orlando, April 12, 2004
di: Torgunakov V. Vladimir
Pubblicazione: (2004)

Identifying hidden defects in thermal insulation of revolving kilns by IR thermographic monitoring; Thermosense XXIX, Orlando, April 09-12, 2007
di: Vavilov V. P. Vladimir Platonovich
Pubblicazione: (2007)

Inspecting aviation composites at the stage of airplane manufacturing by applying 'classical' active thermal NDT, ultrasonic thermography and laser vibrometry; Proceedings of SPIE; Vol. 10661 : Thermosense: Thermal Infrared Applications XL
Pubblicazione: (2018)

Numerical and experimental analyses for natural and non-natural impacted composites via thermographic inspection, ultrasonic C-scan and terahertz imaging; Proceedings of SPIE; Vol. 10214 : Thermosense: Thermal Infrared Applications XXXIX
Pubblicazione: (2017)

Evaluating the efficiency of data processing algorithms in transient thermal NDT; Thermosense XXVI, Orlando, April 12, 2004
di: Vavilov V. P. Vladimir Platonovich
Pubblicazione: (2004)

Ultrasonic and optical stimulation in IR thermographic NDT of impact damage in carbon composites; The e-Journal of Nondestructive Testing; Vol 20, iss. 5
di: Vavilov V. P. Vladimir Platonovich
Pubblicazione: (2015)

Determining thermal diffusivity components in thick anisotropic composites by IR thermography; Thermosense XXVIII,Orlando, Kissimmee, April 17, 2006
di: Vavilov V. P. Vladimir Platonovich
Pubblicazione: (2006)

Evaluating water content in aviation honeycomb panels by transient IR thermography; Thermosense XXVII, Orlando, March 28, 2005
di: Vavilov V. P. Vladimir Platonovich
Pubblicazione: (2005)

Hidden corrosion detection in thick metallic components by transient IR; Infrared Physics & Technology; Vol. 49
Pubblicazione: (2007)

Infrared thermographic evaluation of large composite grid parts subjected to axial loading; Polymer Testing; Vol. 41
di: Vavilov V. P. Vladimir Platonovich
Pubblicazione: (2015)

Quantitative infrared thermographic nondestructive testing of thermal barrier coatings; Materials Evaluation; Vol. 61, iss. 6
Pubblicazione: (2003)

Infrared thermographic surveying of building debris: Tomsk High Military School of Communication Engineering catastrophe case study; Thermosense XX, Orlando, April 13, 1998
di: Vavilov V. P. Vladimir Platonovich
Pubblicazione: (1998)

Quantitative evaluation of building thermal performance by IR thermography inspection data; Thermosense XIX: An International Conference on Thermal Sensing and Imaging, Orlando, April 21, 1997
Pubblicazione: (1997)

Thermal (IR) and Other NDT Techniques for Improved Material Inspection; Journal of Nondestructive Evaluation; Vol. 35, iss. 1
Pubblicazione: (2016)

Evaluating characteristics of turbulent flames by using IR thermography and PIV; Infrared Physics & Technology; Vol. 92
Pubblicazione: (2018)

Optimizing input data for training an artificial neural network used for evaluating defect depth in infrared thermographic nondestructive testing; Infrared Physics and Technology; Vol. 102
Pubblicazione: (2019)

A novel data processing algorithm in thermal property measurement and defect detection by using one-sided active infrared thermography; Proceedings of SPIE; Vol. 9485 : Thermosense: Thermal Infrared Applications XXXVII
di: Vavilov V. P. Vladimir Platonovich
Pubblicazione: (2015)

Infrared thermographic inspection of operating smokestacks; Infrared Physics and Technology; Vol. 43, iss. 3-5
di: Vavilov V. P. Vladimir Platonovich
Pubblicazione: (2002)

Airborne laser IR thermographic system for detecting gas leaks from underground pipelines; Quantitative InfraRed Thermography Journal; Vol. 3, iss. 1
di: Ershov O. V.
Pubblicazione: (2006)

XXXVIII. Altars and Incense
di: Nathaniel H.
Pubblicazione: (Санкт-Петербург, Лань, 2014)

Accuracy issues in modeling thermal NDT problems; Thermosense XXI, Orlando, March 16, 2008
di: Vavilov V. P. Vladimir Platonovich
Pubblicazione: (2008)

Evaluating impact damage to fabric-based personal armor by infrared NDT; International Journal of Damage Mechanics; Vol. 28, No. 9
Pubblicazione: (2019)

Modeling and image processing in infrared thermographic NDT of composite materials; Beijing Hangkong Hangtian Daxue Xuebao/Journal of Beijing University of Aeronautics and Astronautics; Vol. 30, iss. 4
Pubblicazione: (2004)