Your search keyword '"Thermal signature"' showing total 186 results

1. Similarity analysis for thermal signature comparison in metal additive manufacturing

Author

Sujana Chandrasekar, Jamie B. Coble, Fred List, III, Keith Carver, Serena Beauchamp, Amy Godfrey, Vincent Paquit, and Sudarsanam S. Babu

Subjects

Additive Manufacturing, Thermal signature, Similarity analysis, Infrared thermography, In-situ monitoring, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Metal additive manufacturing differs from traditional manufacturing processes primarily due to repeated heating and cooling cycles that are inherent to the process. Such cycling leads to different thermal signatures and associated heterogeneities in solidification, solid-state transformation, microstructure, and properties of the printed part. There is, therefore, a need to develop methods to compare thermal signatures in a part with reference to part qualification criteria. In this work, we have developed and demonstrated a similarity analysis procedure to meet this need. Thermal signatures are extracted from in-situ infrared (IR) thermography during a part built using a laser powder bed fusion (l-PBF) machine. Layer-wise variations in thermal signature as a function of part geometry were revealed. Ex-situ microstructure characterization was used to validate the results from similarity analysis. Results and analysis confirmed that our similarity analysis is indeed a useful tool for rapid comparison of thermal signatures, i.e., heterogeneity within the part. Similarity analysis was also useful in identification of anomalous thermal signatures. The analysis method paves the way for deploying in-situ monitoring of AM parts for qualification of AM components.

Published

2022

2. Effects of changing partial cell shading on the electrical and thermal characteristics of crystalline silicon photovoltaic module.

Author

Vumbugwa, M., Vorster, F.J., Crozier McCleland, J.L., and van Dyk, E.E.

Subjects

*PHOTOVOLTAIC power systems, *OPEN-circuit voltage, *BUILDING-integrated photovoltaic systems, *ENERGY dissipation, *SILICON, *THERMOGRAPHY, *DIODES

Abstract

• Studying the thermal and electrical characteristics of individual crystalline silicon cells under different shading levels shows the impact on the module performance. • Advancing the understanding of the impact of partial shading and mismatch on thermal and electrical characteristics of cells, substrings, and modules. • This study improves the interpretation and understanding of thermal images of PV modules operating under varying shading conditions. Variable partial shading was used to analyse the electrical and thermal behaviour of 60 individual cells in an operational crystalline silicon (c-Si) Photovoltaic (PV) module by recording Thermal Infrared (TIR) images concurrently with electrical measurements of individual cells when shading levels between 0 and 100% were applied on one cell. This study investigated the relative changes in each of the individual cells' operational cell voltage and the current of the substring containing the shaded cell. These changes are significant and can give additional insights into the loss of energy production of a module containing a shaded cell. The role of bypass diodes in mitigating these energy losses was also highlighted in this study. The bypass diode gets activated at 40% cell shading level and when the shading level increased from 40- to 100%, the operational voltage and current of the module remain unchanged while that of the shaded cell and substring containing the shaded cell is reduced. The operational temperature of the shaded cell increases to a maximum with an increase in shading level and drops when the substring's bypass diode is activated. As expected, the substring containing the shaded cell tends to operate closer to open-circuit voltage (V OC) as the cells contribute less current than cells in unshaded substrings. The study gives insight into the performance of a c-Si module down to cell level under partial shading on real field conditions and can add value into the operation and TIR imaging of crystalline modules. [ABSTRACT FROM AUTHOR]

Published

2022

3. Fabrication of Recycled Polycarbonate Fibre for Thermal Signature Reduction in Camouflage Textiles.

Author

Soekoco, Asril, Rehman, Ateeq Ur, Fauzi, Ajisetia, Tasya, Hamdi, Diandra, Purnama, Tasa, Islami, Nugraha, and Yuliarto, Brian

Subjects

*POLYCARBONATES, *MELT spinning, *FIBERS, *THERMOGRAPHY, *KNITTING machines, *SURFACE temperature

Abstract

Thermal signature reduction in camouflage textiles is a vital requirement to protect soldiers from detection by thermal imaging equipment in low-light conditions. Thermal signature reduction can be achieved by decreasing the surface temperature of the subject by using a low thermally conductive material, such as polycarbonate, which contains bisphenol A. Polycarbonate is a hard type of plastic that generally ends up in dumps and landfills. Accordingly, there is a large amount of polycarbonate waste that needs to be managed to reduce its drawbacks to the environment. Polycarbonate waste has great potential to be used as a material for recycled fibre by the melt spinning method. In this research, polycarbonate roofing-sheet waste was extruded using a 2 mm diameter of spinnerette and a 14 mm barrel diameter in a 265 °C temperature process by using a lab-scale melt spinning machine at various plunger and take-up speeds. The fibres were then inserted into 1 × 1 rib-stitch knitted fabric made by Nm 15 polyacrylic commercial yarns, which were manufactured by a flat knitting machine. The results showed that applying recycled polycarbonate fibre as a fibre insertion in polyacrylic knitted fabric reduced the emitted infrared and thermal signature of the fabric. [ABSTRACT FROM AUTHOR]

Published

2022

4. Study of Polymer Binders to Develop Low Emissive Paints for Thermal Radiation Management Applications.

Author

Dev, Om, Daya, Shanker, Dubey, Ashish, and Dixit, Alok K.

Subjects

HEAT radiation & absorption, POLYURETHANES, POLYMER films, INFRARED spectra, TEMPERATURE control

Abstract

The management of thermal emittance always possess challenges in both military and civil domains. The low emissive materials in form of paints offers viable solution for minimising thermal emittance of military objects for camouflage and enhancing infrared reflectivity of roof to reduce cooling loads. Binder apart from pigments is one of the critical components of low emissive paint formulation to decide its ultimate performance. For selection of appropriate resin and binder, a comparative study of five prevalent polymers viz. polyurethane (PU), poly vinyl chloride (PVC), polyethylene (PE), polypropylene (PP) and poly methyl methacrylate (PMMA) has been carried out. Polymeric film of thickness 100µm of each of the polymer is prepared by Elcometer 4340 motorized film applicator. Infrared spectra and thermogravimetric profile have been obtained by Bruker make Tensor 27 FTIR in spectral range 4000 - 600 cm-1 and TGA Q 500. Film formation of PU is excellent and transmission in 3-5 µm is almost 100%. Hence, it may be chosen as binder in low emissive paint for MWIR band. PVC and PMMA among the polymers offer excellent transmission 87-99% in both thermal transmission windows 3-5 µm and 8-12 µm. Thermogravimetric (TG) profile of polymer films evident of thermal stability of PVC, PMMA and PU polymers up to 200 °C. Infrared transmission, TG profile and film formability manifest that both binders-PVC and PMMA are suitable for development of low emissive paints applicable up to temperature 200 °C for both IR transmission windows to evade thermal detectors working for detection of military objects and reducing cooling load in buildings by enhancing reflectivity of roof by application of low emissive paint. [ABSTRACT FROM AUTHOR]

Published

2022

5. Human Stress Recognition from Facial Thermal-Based Signature: A Literature Survey.

Author

Arasu, Darshan Babu L., AzlanMohamed, Ahmad Sufril, Ruhaiyem, Nur Intan Raihana, Annamalai, Nagaletchimee, Lutfi, Syaheerah Lebai, and Al Qudah, Mustafa M.

Subjects

THERMOGRAPHY, HUMAN facial recognition software, PUPILLARY reflex, STRESS management, SOCIAL interaction, SOCIAL media, SKIN temperature

Abstract

Stress is a normal reaction of the human organism which triggered in situations that require a certain level of activation. This reaction has both positive and negative effects on everyone's life. Therefore, stress management is of vital importance in maintaining the psychological balance of a person. Thermal-based imaging technique is becoming popular among researchers due to its non-contact conductive nature. Moreover, thermal-based imaging has shown promising results in detecting stress in a non-contact and non-invasive manner. Compared to other non-contact stress detection methods such as pupil dilation, keystroke behavior, social media interaction and voice modulation, thermal-based imaging provides better features with clear boundaries and requires no heavy methodology. This paper presented a brief review of previous work on thermal imaging related stress detection in humans. This paper also presented the stages of stress detection based on thermal face signatures such as dataset type, thermal image face detection, feature descriptors and classification performance comparisons are presented. This paper can help future researchers to understand stress detection based on thermal imaging by presenting the popular methods previous researchers use for stress detection based on thermal images. [ABSTRACT FROM AUTHOR]

Published

2022

6. Qualitative visualization of the development of stresses through infrared thermography

Author

Even Stange, Zahra Andleeb, and Hassan A. Khawaja

Subjects

ir thermography, tensile tests, thermal signature, ик-термография, испытания на растяжение, тепловая характеристика, General Works

Abstract

In this work, the IR thermography has been used to study the steel specimens (DIN 50125 Standard) undergoing the tensile tests. The tensile tests were performed using GUNT® Hamburg Universal Material Tester. The tensile specimens were clamped, and the test force was applied using a hand-operated hydraulic system. A dial gauge measured the elongation of the specimens. The steel specimens were coated with high emissivity paint. Using the WP 300.20 system for data acquisition, the measured values for force and displacement were recorded in a PC. The IR thermographic imaging was performed using the FLIR® T1030sc IR camera and ResearchIR Max software. The tests have revealed that the steel specimens show noticeable thermal signature when undergoing tensile loading.

Published

2019

7. Effects of Dynamic Operational Conditions on Thermal Infrared Imaging of Monocrystalline Silicon Photovoltaic Modules.

Author

Vumbugwa, M., McCleland, J. L. Crozier, van Dyk, E. E., and Vorster, F. J.

Subjects

*INFRARED imaging, *THERMOGRAPHY, *ELECTRICAL load, *SOLAR cells, *SILICON solar cells, *SHORT circuits

Abstract

Photovoltaic (PV) modules installed in the field generate electrical power under different meteorological and operational conditions; therefore, maintenance of the modules is crucial for the longevity of the PV modules. Thermal infrared (TIR) imaging is a widely used monitoring technique for quality checks of PV modules in plants. It is ideally conducted on operational PV modules under steady ambient conditions; however, PV modules operate under dynamic climatic conditions which influence the overall operation of all solar cells and modules. The dynamic nature of thermal signatures was observed on TIR images when monocrystalline PV modules operated under varying electrical loads and irradiance. A change in operating conditions affected the level of current mismatch between cells since at high irradiance of about 1000 watts per square meter (W m-2) and while operating close to short circuit current at reduced load, the PV cells generated a higher current which led to significant current mismatch. This resulted in several abnormally hot cells being identified on TIR images. Under lower irradiance and larger electrical loads, fewer hot cells were observed and cracked cells (identified through Electroluminescence (EL)) appeared as good cells due to minimal current mismatch. The effectiveness of TIR imaging to reveal underperforming defective cells as hot cells depends on the operating conditions and can mislead decision-making when PV module maintenance is carried out. This work gives valuable information which can be of importance in improving the maintenance systems of PV modules when TIR imaging is conducted. [ABSTRACT FROM AUTHOR]

Published

2021

8. Fabrication of Recycled Polycarbonate Fibre for Thermal Signature Reduction in Camouflage Textiles

Author

Asril Soekoco, Ateeq Ur Rehman, Ajisetia Fauzi, Hamdi Tasya, Purnama Diandra, Islami Tasa, Nugraha, and Brian Yuliarto

Subjects

polycarbonate waste, recycled fibre, thermal signature, camouflage textiles, Organic chemistry, QD241-441

Abstract

Thermal signature reduction in camouflage textiles is a vital requirement to protect soldiers from detection by thermal imaging equipment in low-light conditions. Thermal signature reduction can be achieved by decreasing the surface temperature of the subject by using a low thermally conductive material, such as polycarbonate, which contains bisphenol A. Polycarbonate is a hard type of plastic that generally ends up in dumps and landfills. Accordingly, there is a large amount of polycarbonate waste that needs to be managed to reduce its drawbacks to the environment. Polycarbonate waste has great potential to be used as a material for recycled fibre by the melt spinning method. In this research, polycarbonate roofing-sheet waste was extruded using a 2 mm diameter of spinnerette and a 14 mm barrel diameter in a 265 °C temperature process by using a lab-scale melt spinning machine at various plunger and take-up speeds. The fibres were then inserted into 1 × 1 rib-stitch knitted fabric made by Nm 15 polyacrylic commercial yarns, which were manufactured by a flat knitting machine. The results showed that applying recycled polycarbonate fibre as a fibre insertion in polyacrylic knitted fabric reduced the emitted infrared and thermal signature of the fabric.

Published

2022

9. Application of forward‐looking infrared (FLIR) imaging from an unmanned aerial platform in the search for decomposing remains.

Author

Butters, Owyn, Krosch, Matt N., Roberts, Michell, and MacGregor, Donna

Subjects

*ELEVATING platforms, *THERMOGRAPHY, *DRONE aircraft, *KNOWLEDGE gap theory

Abstract

Traditional methods of cadaver detection in outdoor environments include manual ground search, cadaver dogs, and manned aerial reconnaissance during daylight. These methods have limitations; however, a potential low‐cost alternative may be to employ thermal imaging equipment mounted on an unmanned aerial vehicle (UAV) to detect heat emitted by insect and bacterial activity on the decomposing remains. No studies have addressed the influence of wrappings on detection of maggot mass thermal signatures nor assessed thermal detection of smaller body fragments. We addressed these knowledge gaps by utilizing a two‐phase experimental approach to explore thermal detection of carcasses using UAV‐mounted infrared imaging. In Phase 1, pig body fragments were deposited on the surface or shallow buried. In Phase 2, whole pig carcasses were deposited in four conditions: on the surface uncovered, wrapped in plastic or carpet, or buried. Our results demonstrated that observable heat emissions from remains corresponded to peak insect activity during active decay and could be readily detected in uncovered whole carcasses and fragments. Although plastic and carpet wrappings partly impeded detection of insect heat signatures, these materials were clearly detectable themselves because of their contrast to the background ground surface. Thermal signatures of buried partial remains and disturbed gravesoil were also observed; however, the buried whole carcass transitioned to adipocere prior to the decay stage and without any insect colonization or heat signature. These data can inform operational implementation of this technique to complement existing search strategies to offer a robust, low‐cost alternative for use where scene characteristics allow. [ABSTRACT FROM AUTHOR]

Published

2021

10. Reduced graphene oxide: a novel black body emitter for advanced infrared decoy flares.

Author

Elbasuney, Sherif, Elmotaz, Amr A., Sadek, M. A., Tantawy, Hesham, Yehia, M., and El-Sayyad, Gharieb S.

Subjects

*GRAPHENE oxide, *FLUOROPOLYMERS, *METAL-base fuel, *RADIANT intensity, *IR spectrometers, *FLUOROCARBONS, *CARBONACEOUS aerosols

Abstract

Reduced graphene oxide (RGO) possesses unique thermal and optical properties. It could act as black body emitter with high-infrared emissivity. RGO could meet wide applications in advanced infrared decoy flares. In this study, RGO nano-sheets were synthesized through the reduction of GO after applying Hummers' method using graphite powder as a precursor. The synthesized RGO owns 10 µm dimensions and 10 nm thicknesses. TEM analysis revealed the amorphous structure of the prepared nano-sheets. XRD diffractogram demonstrated the amorphous RGO structure. Moreover, Raman spectroscopy confirmed the complete reduction of GO into RGO. In addition, decoy flare formulations based on RGO, reactive metal fuels, and fluorocarbon polymer were developed. Additionally, thermal signature was evaluated using Arc-Optics IR spectrometer (1–6 µm) to reference formulation. Our results revealed that nanocomposite flare based on 6 wt % RGO demonstrated superior spectral intensity with an increase in average intensity by 147%. Moreover, advanced radiometric performance with superior relative intensity value (Ɵ) of 0.7 was recorded. To sum up, RGO can act as an excellent source of carbonaceous materials that can strengthen incandescence emission. Surplus magnesium could vaporize and combust with substantial heat output that could promote black body emission. [ABSTRACT FROM AUTHOR]

Published

2021

11. Evaluating the Correlation between Thermal Signatures of UAV Video Stream versus Photomosaic for Urban Rooftop Solar Panels

Author

Young-Seok Hwang, Stephan Schlüter, Jung-Joo Lee, and Jung-Sup Um

Subjects

unmanned aerial vehicle (UAV), video, urban rooftop solar panel, photomosaic, co-relationship, thermal signature, Science

Abstract

The unmanned aerial vehicle (UAV) autopilot flight to survey urban rooftop solar panels needs a certain flight altitude at a level that can avoid obstacles such as high-rise buildings, street trees, telegraph poles, etc. For this reason, the autopilot-based thermal imaging has severe data redundancy—namely, that non-solar panel area occupies more than 99% of ground target, causing a serious lack of the thermal markers on solar panels. This study aims to explore the correlations between the thermal signatures of urban rooftop solar panels obtained from a UAV video stream and autopilot-based photomosaic. The thermal signatures of video imaging are strongly correlated (0.89–0.99) to those of autopilot-based photomosaics. Furthermore, the differences in the thermal signatures of solar panels between the video and photomosaic are aligned in the range of noise equivalent differential temperature with a 95% confidence level. The results of this study could serve as a valuable reference for employing video stream-based thermal imaging to urban rooftop solar panels.

Published

2021

12. Applications in Compartment Fires (Type I Problem)

Author

Ma, Tingguang and Ma, Tingguang

Published

2015

13. Thermal Balance Method

Author

Ma, Tingguang and Ma, Tingguang

Published

2015

14. Thermal Signature Using Non-redundant Temporal Local Binary-Based Features

Author

Al Alwani, Adnan, Chahir, Youssef, Jouen, Francois, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Kobsa, Alfred, Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Nierstrasz, Oscar, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Weikum, Gerhard, Series editor, Campilho, Aurélio, editor, and Kamel, Mohamed, editor

Published

2014

15. Infrared Spectra of Customized Magnesium/Teflon/Viton Decoy Flares.

Author

Elbasuney, Sherif, Elsaidy, Amir, Kassem, Mohamed, Tantawy, Hesham, Sadek, Ramy, and Fahd, Ahmed

Subjects

*INFRARED spectra, *FLARES, *MAGNESIUM, *JET nozzles, *GUIDED missiles, *SOLAR flares, *JET engines, *FLAME

Abstract

Infrared (IR) guided missile is known to cause 90% of aircraft damage. Magnesium/Teflon/Viton (MTV) decoy flares are customized materials, which are capable of yielding thermal signature to interfere with IR guided missile seekers. In this study, the IR-signature of an MTV flare is measured in a jet engine nozzle. The jet engine IR-signature is characterized with two characteristic peaks over the α-band (2–3 µm) and β-band (3–5 µm); this is correlated to black body emission at 690° C. The MTV decoy flare with 65% Mg offers an increase in the average intensity of the α- and β-bands by 21 and 4 times, respectively, to that of the jet engine. Quantification of emitting species in the combustion flame is conducted by using the ICT thermodynamic code. The developed MTV formulation offers the relative intensity ratio of the α- and β-bands equal to 0.96, which is comparable to that of an aircraft (0.7). [ABSTRACT FROM AUTHOR]

Published

2019

16. Pedestrians’ detection in thermal bands – Critical survey

Author

Nermin K. Negied, Elsayed E. Hemayed, and Magda B. Fayek

Subjects

Thermography, Infrared bands, Near IR imaging, Thermal signature, Pedestrians detection, Crowd counting, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Information technology, T58.5-58.64

Abstract

Thermal imaging is simply the technique of using the heat given off by an object to produce an image of it or locate it. New thermal imaging frameworks for detection, segmentation and unique feature extraction and similarity measurements for human physiological biometrics recognition have been introduced in literature. The research investigates specialized algorithms that would use the individual's heat signature for human detection, crowd counting and applications that take benefits of this new technology. The highly accurate results obtained by the algorithms presented clearly demonstrate the ability of the thermal infrared systems to extend in application to other thermal imaging based systems.

Published

2015

17. Super-Thermite (Al/Fe2O3) Fluorocarbon Nanocomposite with Stimulated Infrared Thermal Signature via Extended Primary Combustion Zones for Effective Countermeasures of Infrared Seekers.

Author

Elbasuney, Sherif, Elsaidy, Amir, Kassem, Mohamed, Tantawy, Hesham, Sadek, Ramy, Fahd, Ahmed, and Gobara, Mohamed

Subjects

*FLUOROCARBONS, *FOURIER transforms, *IMAGE analysis, *ACETONE, *PARTICLE size determination

Abstract

Super-thermites can offer large amount of energy up to 16736 J/g. Flares based on super-thermites can offer superior thermal signature to countermeasure infrared (IR) guided missile seekers. This study reports on the sustainable fabrication of mono-dispersed Fe2O3 nanoparticles of 3 nm average particle size. Colloidal Fe2O3 nanoparticles were harvested from their synthesis medium and re-dispersed in acetone. Fluorocarbon polymers (teflon and viton) as well as aluminum metal fuel were integrated into Fe2O3/acetone colloid. The colloid mixture was granulated and mold pressed to develop the desired grain. The impact of Fe2O3 nanoparticles on thermal signature was assessed using (FT-MIR 1-6 µm) spectrometer. Flame propagation was investigated by video imaging of combustion wave. Combustion zones were quantified using image analysis. Quantification of flame temperature and main IR emitting species was performed using ICT thermodynamic code (virgin 2008). Nanocomposite flare with 12 wt% Fe2O3 offered an increase in the intensity of β band by 230% to that of reference formulation. The primary reaction zone was extended by 164%. Super-thermite particles not only offered superior spectral performance but also altered the combustion mechanism. [ABSTRACT FROM AUTHOR]

Published

2018

18. Infrared Signature of Novel Super-Thermite (Fe2O3/Mg) Fluorocarbon Nanocomposite for Effective Countermeasures of Infrared Seekers.

Author

Elbasuney, Sherif, Elsaidy, Amir, Kassem, Mohamed, and Tantawy, Hesham

Subjects

*INFRARED spectroscopy, *IRON oxide nanoparticles, *MAGNESIUM compound synthesis, *FLUOROPOLYMERS, *MANUFACTURING of nanocomposite materials

Abstract

Infrared (IR) guided missiles are real threat; they caused 90% of aircraft damage. Fluorocarbon polymer nanocomposite based on super-thermites can offer superior thermal signature to countermeasure IR guided missile seekers. This study reports on the sustainable fabrication of mono-dispersed colloidal Fe2O3 nanoparticles with 3 nm average particle size. Fe2O3 nanoparticles were dispersed in acetone for subsequent integration in fluorocarbon polymer. The impact of Fe2O3 content on thermal signature was evaluated using (FT-MIR 2-6 μm) spectrophotometer. Nanocomposite polymer with 8 wt% Fe2O3 offered an increase in the average intensity of α (2-3 μm) and β (4-5 μm) bands by 50 and 85% respectively to that of reference formulation. Quantification of stimulated emitting species in the combustion flame was conducted using ICT thermodynamic code. The developed nanothermite particles extended the primary reaction zone by 183%. Full discussions about combustion zones with associated exothermic chemical reactions have been represented. [ABSTRACT FROM AUTHOR]

Published

2018

19. Hot spot method for pedestrian detection using saliency maps, discrete Chebyshev moments and support vector machine.

Author

Lahouli, Ichraf, Karakasis, Evangelos, Haelterman, Robby, Chtourou, Zied, De Cubber, Geert, Gasteratos, Antonios, and Attia, Rabah

Abstract

The increasing risks of border intrusions or attacks on sensitive facilities and the growing availability of surveillance cameras lead to extensive research efforts for robust detection of pedestrians using images. However, the surveillance of borders or sensitive facilities poses many challenges including the need to set up many cameras to cover the whole area of interest, the high bandwidth requirements for data streaming and the high‐processing requirements. Driven by day and night capabilities of the thermal sensors and the distinguished thermal signature of humans, the authors propose a novel and robust method for the detection of pedestrians using thermal images. The method is composed of three steps: a detection which is based on a saliency map in conjunction with a contrast‐enhancement technique, a shape description based on discrete Chebyshev moments and a classification step using a support vector machine classifier. The performance of the method is tested using two different thermal datasets and is compared with the conventional maximally stable extremal regions detector. The obtained results prove the robustness and the superiority of the proposed framework in terms of true and false positives rates and computational costs which make it suitable for low‐performance processing platforms and real‐time applications. [ABSTRACT FROM AUTHOR]

Published

2018

20. Hydrodynamics of The South Main Lake and South Lake, Lake Champlain

Author

Manley, T. O., Manley, Thomas O., editor, Manley, Patricia L., editor, and Mihuc, Timothy B., editor

Published

2004

21. Reduction of Thermal Signature Using Fabrics with Conductive Additives

Author

Vitalija RUBEŽIENĖ, Ingrida PADLECKIENĖ, Sandra VARNAITĖ ŽURAVLIOVA, and Julija BALTUŠNIKAITĖ

Subjects

camouflage materials, thermal signature, metal fibres, silver coated fibres, far infrared spectral range, Mining engineering. Metallurgy, TN1-997

Abstract

The most effective way to reduce the thermal signature is to reduce the emissivity. The goal of our research is to create the material, which can reduce the thermal signature, and make it interflow with environment. The materials and material compositions concealing the thermal signature of the object were developed using aluminium coatings and conductive metalized fibres, i. e. yarns with stainless steel staples or coated with silver. The analysis of the prepared samples was carried out with equipment consisting of a stand with integrated heating controller imitating the human body. The concealing properties of the samples in the far infrared (FIR) spectral range were evaluated using ThermaCAM Reporter 7.0. The thermal signature analysis of prepared samples demonstrates that respectable results could be obtained using yarns coated with silver and materials coated with aluminium, but the first one is more flexible and preferable for clothing.DOI: http://dx.doi.org/10.5755/j01.ms.19.4.1730

Published

2013

22. Rice Acreage Delineation in the Nile Delta Based on Thermal Signature

Author

Tolba, Ramadan Abdelaziz, El-Shirbeny, Mohammed Ahmed, Abou-Shleel, Samir Masoud, and El-Mohandes, Mohsen Ahmed

Published

2020

23. HPM/IR Detection of Landmines: Review and Update

Author

Seregelyi, J. S., Khanna, S. M., Apps, R., Boyle, M., Paquet, F., Schubert, Hiltmar, editor, and Kuznetsov, Andrey, editor

Published

2002

24. The face of salutogenesis: an interdisciplinary Swiss thermal imaging case report.

Author

Meier Magistretti, Claudia and Topalidou, Anastasia

Subjects

HEALTH promotion, MATERNAL health services, CASE studies, MEDICAL thermography, MIDWIVES, VIDEO recording, MIDWIFERY, PILOT projects, OCCUPATIONAL roles, SOCIAL support, ATTITUDE (Psychology)

Abstract

Background. Health-oriented practice is advocated, since 'too much medicine' has led to increased health costs without an increase in health. Conversely, negative iatrogenic outcomes have been reported in both medicine and midwifery care. Recent research has described health-oriented midwifery practice, but little is known about how health-oriented practice can be measured. Aim. This pilot study investigated whether infrared thermal imaging is able to distinguish between health-oriented and clinically-oriented practice. Building upon previous studies that distinguished specific thermal imaging patterns related to specific emotional states, this study attempted to record the specific thermal signatures relating to health-oriented and clinically-oriented practice. Thus it aimed to provide a quantitative definition of health-oriented practice in midwifery consulting sessions. This single case study is the first attempt to assess professionals' health orientation in maternity care. Methods. For this initial purpose two midwives with differing professional orientations were required to enroll in the study. Following consent for participation, the consulting session of a health-oriented midwife was compared to the consulting session of a midwife with a clinical orientation. Both sessions were assessed using thermal imaging and voice recording. Results. Two distinct profiles emerged from the descriptive analysis of the thermal images. While the health-oriented midwife showed significant changes in facial, neck and hand temperature, there were almost no changes in the thermal images taken of the clinically-oriented midwife, both in terms of temperature values and temperature diffusion. Discussion/conclusion. These differences are assumed to be related to the professional orientation of the midwives. To examine these assumptions, further studies on larger samples are needed. [ABSTRACT FROM AUTHOR]

Published

2017

25. Numerical predictions of internal waves and surface thermal signatures by underwater vehicles in density-stratified water using OpenFOAM.

Author

Wang, Cheng-An, Zhang, Hao, and Zhu, Hui-Long

Subjects

*INTERNAL waves, *AIR-water interfaces, *STRATIFIED flow, *SUBMERSIBLES, *FREE surfaces, *WATER temperature, *DRAG (Aerodynamics)

Abstract

The accurate and efficient prediction of the flow and temperature fields on water surface modulated by internal waves induced by underwater vehicles in a density-stratified ocean can serve as the basis for indirect detection. The disturbance of an underwater object on density-stratified water can be considered as the mixing of two incompressible fluids: freshwater and saltwater. Furthermore, the modulation effect of internal waves on the convergence and divergence of flow field and thermal skin layer is captured at the air–water interface. Therefore, in this study, a CFD solver called "interMixing_skin_Foam" based on OpenFOAM is proposed. It can manage three incompressible fluids, two of which disperse, and the interface between the immiscible fluids (air–water) is captured using the VOF technique. In addition, the energy equation is implemented to investigate the thermal signature variations at the air–water interface. Comparison analysis of experimental results and those obtained from the CFD solver "twoLiquidMixing_skin_Foam" developed in a previous study, wherein only two incompressible fluids were considered, is performed for standard cases in literature. Subsequently, the influence of the air–water interface on the flow and temperature fields is studied for a submerged sphere travelling horizontally in linearly and strongly density-stratified water. • The thermal signature variations of internal waves by underwater target at the air–water interface were investigated. • A solver based on OpenFOAM platform for flow and temperature fields of three incompressible fluids was developed. • The viscosity drag effect, surface tension, and movable free surface have significant influence on thermal signatures. • In strongly density-stratified water, the upper fresh-water layer could suppress the thermal signatures. [ABSTRACT FROM AUTHOR]

Published

2023

26. Application of forward‐looking infrared (FLIR) imaging from an unmanned aerial platform in the search for decomposing remains

Author

Matt N. Krosch, Donna M. MacGregor, Michell Roberts, and Owyn Butters

Subjects

Insecta, Aircraft, Infrared Rays, Swine, Thermal signature, Thermogenesis, Feeding Behavior, Forensic Medicine, Imaging equipment, Body Remains, Body Temperature, Pathology and Forensic Medicine, Postmortem Changes, Models, Animal, Genetics, Bacterial activity, Animals, Humans, Environmental science, Aerial reconnaissance, Forward looking infrared, Remote sensing

Abstract

Traditional methods of cadaver detection in outdoor environments include manual ground search, cadaver dogs, and manned aerial reconnaissance during daylight. These methods have limitations; however, a potential low-cost alternative may be to employ thermal imaging equipment mounted on an unmanned aerial vehicle (UAV) to detect heat emitted by insect and bacterial activity on the decomposing remains. No studies have addressed the influence of wrappings on detection of maggot mass thermal signatures nor assessed thermal detection of smaller body fragments. We addressed these knowledge gaps by utilizing a two-phase experimental approach to explore thermal detection of carcasses using UAV-mounted infrared imaging. In Phase 1, pig body fragments were deposited on the surface or shallow buried. In Phase 2, whole pig carcasses were deposited in four conditions: on the surface uncovered, wrapped in plastic or carpet, or buried. Our results demonstrated that observable heat emissions from remains corresponded to peak insect activity during active decay and could be readily detected in uncovered whole carcasses and fragments. Although plastic and carpet wrappings partly impeded detection of insect heat signatures, these materials were clearly detectable themselves because of their contrast to the background ground surface. Thermal signatures of buried partial remains and disturbed gravesoil were also observed; however, the buried whole carcass transitioned to adipocere prior to the decay stage and without any insect colonization or heat signature. These data can inform operational implementation of this technique to complement existing search strategies to offer a robust, low-cost alternative for use where scene characteristics allow.

Published

2020

27. Gender Discrimination based on the Thermal Signature of the Face and the External Ear

Author

Vassilis Anastassopoulos and Georgia Koukiou

Subjects

Gender discrimination, Speech recognition, Face (geometry), Thermal signature, Psychology

Published

2020

28. The effect of thermal cycling on the fracture toughness of metallic glasses

Author

Benjamin Sol Schroers, Rui Yamada, Wojciech Dmowski, Derek Kuldinow, Hui Wang, Jan Schroers, Takeshi Egami, and Jittisa Ketkaew

Subjects

010302 applied physics, Amorphous metal, Materials science, Polymers and Plastics, Thermal signature, Metals and Alloys, 02 engineering and technology, Temperature cycling, 021001 nanoscience & nanotechnology, 01 natural sciences, Homogenization (chemistry), Electronic, Optical and Magnetic Materials, Fracture toughness, 0103 physical sciences, Thermal, Ceramics and Composites, Composite material, 0210 nano-technology, Cycling

Abstract

A wide range of behaviors, including non-monotonic rejuvenation and relaxation, and the ability to qualitatively change the effect by varying the structural state of the glass was observed during thermal cycling of bulk metallic glasses. For this, we considered various bulk metallic glasses, Zr44Ti11Cu10Ni10Be25, Pd43Cu27Ni10P20, Pt57.5Cu14.7Ni5.3P22.5, and La55Al25Ni20, at various fictive temperatures to study the effect of thermal cycling on structure, thermal signature, and fracture toughness. For some BMGs and conditions considered here, thermal cycling results in a looser structure and an increase in fracture toughness. We found that for certain other BMGs and conditions, thermal cycling results in relaxation, reflected in a denser structure, and a decrease in fracture toughness. All these responses are non-monotonic and reveal a pronounced extremum with fracture toughness values of ± 50% of the original value, before approaching a value similar to the original value prior to thermal cycling. Such richness in response to thermal cycling suggests incompleteness of the previous picture where monotonically decreasing local stresses resulting in a homogenization of the structure with increasing cycle number. Our finding suggests that relative comparisons of various contributions including activation barriers for α-relaxation have to be considered which are also constantly changing, to decide if further cycling results in an increase or a decrease in fracture toughness. The fracture toughness’ response to thermal cycling can be correlated with the average atomic structures’ response to thermal cycling, while the thermal response does not exhibit an obvious correlation.

Published

2020

29. Debonding detection in asphalt pavements using infrared thermography

Author

Vidhi Vyas, Vedant Jagdish Patil, Anshuman, and Ajit Pratap Singh

Subjects

050210 logistics & transportation, business.industry, Infrared, 05 social sciences, Thermal signature, 0211 other engineering and technologies, 02 engineering and technology, Structural engineering, Time duration, Asphalt pavement, Asphalt, Destructive testing, Road networks, 021105 building & construction, 0502 economics and business, Thermography, Environmental science, business

Abstract

For sustainable growth of road networks in a country, their effective maintenance is an essential element of pavement evaluation and management strategies. Destructive testing practices are slow, labor-intensive and do not represent the entire pavement area. Advances in non-destructive testing technologies offer a convenient and reliable means of quickly scanning large areas. Infrared thermography based on capturing the thermal signature of any structure is found to be very useful for detecting pavement subsurface flaws. This study aims at exploring the potential of infrared thermography to detect subsurface interlayer debonding in asphalt pavements. An in-situ asphalt pavement test section has been constructed with different bonding conditions, and infrared thermography has been performed. A novel approach for quantitative and qualitative analyses of these thermal images has been carried out using MATLAB. Suitable time durations to perform thermographic inspections based on interchange time duration have been suggested.

Published

2020

30. Evaluating the Correlation between Thermal Signatures of UAV Video Stream versus Photomosaic for Urban Rooftop Solar Panels

Author

Jung-Joo Lee, Jung-Sup Um, Stephan Schlüter, and YoungSeok Hwang

Subjects

Flight altitude, Science, Thermal signature, photomosaic, urban rooftop solar panel, video, law.invention, Video imaging, co-relationship, unmanned aerial vehicle (UAV), law, Range (aeronautics), thermal signature, Thermal, Autopilot, General Earth and Planetary Sciences, Environmental science, Noise (video), Rooftop photovoltaic power station, Remote sensing

Abstract

The unmanned aerial vehicle (UAV) autopilot flight to survey urban rooftop solar panels needs a certain flight altitude at a level that can avoid obstacles such as high-rise buildings, street trees, telegraph poles, etc. For this reason, the autopilot-based thermal imaging has severe data redundancy—namely, that non-solar panel area occupies more than 99% of ground target, causing a serious lack of the thermal markers on solar panels. This study aims to explore the correlations between the thermal signatures of urban rooftop solar panels obtained from a UAV video stream and autopilot-based photomosaic. The thermal signatures of video imaging are strongly correlated (0.89–0.99) to those of autopilot-based photomosaics. Furthermore, the differences in the thermal signatures of solar panels between the video and photomosaic are aligned in the range of noise equivalent differential temperature with a 95% confidence level. The results of this study could serve as a valuable reference for employing video stream-based thermal imaging to urban rooftop solar panels.

Published

2021

31. Experimental Study of White Heat Line Formation in Burned Bone Using Fourier Transform Infrared Spectroscopy

Author

Megan Gough, James T. Pokines, and Sabra Botch-Jones

Subjects

chemistry.chemical_compound, Animal science, chemistry, Thermal signature, Vibrational bands, Cervus elaphus, Composition (visual arts), Fourier transform infrared spectroscopy, Phosphate, Chemical composition, Additional research

Abstract

In anthropological analysis of burned bone, the presence of a white heat line (WHL) aids in determining a bone’s physical condition prior to burning, distinguishing between those burned fleshed or wet versus dry, making this thermal signature an important source of information regarding the relative timing of burning. While the relationship between WHLs and a bone’s physical condition has been studied, there is a lack of research concerning WHL chemical composition. The present study assessed the composition of WHLs that form on burned bone using Fourier Transform Infrared Spectroscopy (FTIR), including the effects of soft tissue and retention of bone’s organic material on a WHL’s development and appearance. Experimental remains consisted of isolated bones from pig (Sus scrofa), sheep (Ovis aries), white-tailed deer (Odocoileus virginianus), and elk (Cervus elaphus) in five physical conditions: fleshed, defleshed/very wet, partially wet, dry, and dry/soaked. Chemical composition was analyzed using spectral peak heights of the carbonate (CO3) ν3 (1415 cm-1), phosphate (PO4) ν3 (1035 cm-1), and amide I (1660 cm-1) vibrational bands. WHLs formed on 8 of 16 bones burned fleshed (50%) compared to 8 of 27 defleshed/very wet (29.6%). The partially wet, dry, and dry/soaked sample groups did not develop a WHL. Results indicate WHLs that formed on fleshed bone contained an increased amount of CO3, PO4, and amide I versus unburned controls. In contrast, WHLs that formed on defleshed/very wet bone contained decreased amounts. Additional research is needed to explore the exact mechanisms causing the formation of WHLs and their physical appearance.

Published

2021

32. Printed electronics based adaptive decoy:Invited paper

Author

Huttunen, Arttu, Kololuoma, Terho, Stein, Karin U., and Schleijpen, Ric

Subjects

Thermal signature, Decoy, Printed electronics

Abstract

Decoys can be used in warfare to affect the enemy intelligence and situational awareness as well as to protect military equipment and soldiers. Since much of current and especially future, reconnaissance is based on advanced wide spectral range sensors, especially airborne sensors carried by drones and satellites, it is imperative that a modern decoy is capable of creating a credible sensor signature in the most commonly used sensors. For this goal, a foil system was designed and fabricated using printed electronics technologies that has sensor responses to thermal imaging, radar and visible or hyperspectral imaging. The foil has a matrix of heating elements, which can be heated in an arbitrary pattern to form any thermal signature desired. Radar response was created by laminating a metal layer on the foil. The foil was painted with a layer of camouflage paint in order to achieve authentic hyperspectral and visible response. The roll-to-roll manufactured, general-purpose decoy foil allows mass production scale benefits since the same foil can be used to mimic any target by using a programmable heater controller.

Published

2021

33. Printed electronics based adaptive decoy

Subjects

Thermal signature, Decoy, Printed electronics

Abstract

Decoys can be used in warfare to affect the enemy intelligence and situational awareness as well as to protect military equipment and soldiers. Since much of current and especially future, reconnaissance is based on advanced wide spectral range sensors, especially airborne sensors carried by drones and satellites, it is imperative that a modern decoy is capable of creating a credible sensor signature in the most commonly used sensors. For this goal, a foil system was designed and fabricated using printed electronics technologies that has sensor responses to thermal imaging, radar and visible or hyperspectral imaging. The foil has a matrix of heating elements, which can be heated in an arbitrary pattern to form any thermal signature desired. Radar response was created by laminating a metal layer on the foil. The foil was painted with a layer of camouflage paint in order to achieve authentic hyperspectral and visible response. The roll-to-roll manufactured, general-purpose decoy foil allows mass production scale benefits since the same foil can be used to mimic any target by using a programmable heater controller.

Published

2021

34. Similarity analysis for thermal signature comparison in metal additive manufacturing.

Author

Chandrasekar, Sujana, Coble, Jamie B., List III, Fred, Carver, Keith, Beauchamp, Serena, Godfrey, Amy, Paquit, Vincent, and Babu, Sudarsanam S.

Subjects

*ELECTRON beam furnaces, *ELECTRIC furnaces, *THERMAL analysis, *MANUFACTURING processes, *GRAIN size, *THERMOGRAPHY

Abstract

[Display omitted] • An in-situ monitoring method and similarity analysis algorithm has been developed as a potential tool for part qualification based on thermal signature comparison in additive manufacturing. • The similarity analysis algorithm combines shape and magnitude similarity in a manner unique to additive manufacturing. • Using similarity analysis, variations in thermal signatures associated with change in part geometry have been demonstrated. • Comparison with microstructure characterized using ex-situ microscopy indicated that similarity analysis correlates well with grain size and microstructure variation within a part. • A proof of concept is also presented to demonstrate similarity analysis to identify anomalous regions corresponding to potential defects in the part. Metal additive manufacturing differs from traditional manufacturing processes primarily due to repeated heating and cooling cycles that are inherent to the process. Such cycling leads to different thermal signatures and associated heterogeneities in solidification, solid-state transformation, microstructure, and properties of the printed part. There is, therefore, a need to develop methods to compare thermal signatures in a part with reference to part qualification criteria. In this work, we have developed and demonstrated a similarity analysis procedure to meet this need. Thermal signatures are extracted from in-situ infrared (IR) thermography during a part built using a laser powder bed fusion (l -PBF) machine. Layer-wise variations in thermal signature as a function of part geometry were revealed. Ex-situ microstructure characterization was used to validate the results from similarity analysis. Results and analysis confirmed that our similarity analysis is indeed a useful tool for rapid comparison of thermal signatures, i.e., heterogeneity within the part. Similarity analysis was also useful in identification of anomalous thermal signatures. The analysis method paves the way for deploying in-situ monitoring of AM parts for qualification of AM components. [ABSTRACT FROM AUTHOR]

Published

2022

35. Internal Thermal Stimulation: Methods and Image Processing

Author

Maldague, Xavier P. V. and Maldague, Xavier P. V.

Published

1993

36. Infrared Imaging in Cryogenic Wind Tunnels

Author

Gartenberg, Ehud, Tanida, Yoshimichi, editor, and Miyashiro, Hiroshi, editor

Published

1992

37. Inspection of electronic component using pulsed thermography

Author

Sri Addepalli, Haochen Liu, Wayne Lam, Yifan Zhao, and Lawrence Tinsley

Subjects

Production line, 0209 industrial biotechnology, Computer science, 02 engineering and technology, Industrial and Manufacturing Engineering, NDT, 020901 industrial engineering & automation, 0203 mechanical engineering, Artificial Intelligence, Nondestructive testing, Throughput (business), Reliability (statistics), business.industry, Thermal signature, TSR, Reliability engineering, Counterfeit, Correlation, 020303 mechanical engineering & transports, Life-critical system, visual_art, Electronic component, Thermography, Counteifeit detection, visual_art.visual_art_medium, business

Abstract

Counterfeit electronic components (CEC) are of great concern to governments and industry globally as they could lead to systems and mission failure, malfunctioning of safety critical systems, and reduced reliability of high-hazard assets. Depending on the cost of CEC going into the production line, some industries might look to have some sort of inspection capability in-house to screen critical components before they go to assembly. Although advanced counterfeit inspection methods have been developed for a variety of components, they generally exhibit a combination of disadvantages such as destructive, low throughput, high unit cost, or inaccessible to unskilled operator. This paper investigates the potential of pulsed thermography on detection of CEC in a fast and non-destructive manner. The second derivative of post-heat thermal response is used to construct a fingerprint to differentiate genuine and counterfeit components. Results successfully demonstrate the potential of the proposed solution.

Published

2021

38. Identification of drone thermal signature by convolutional neural network

Author

Chong Yu Quan, Ong Le Wei Edmond, and Sutthiphong Srigrarom

Subjects

Identification (information), Thermal infrared, Training set, business.industry, Minimum bounding box, Computer science, Thermal signature, Computer vision, Artificial intelligence, business, Convolutional neural network, Drone

Abstract

This paper presents the work on drone detection and identification using thermal infrared emission, which is primarily aimed towards night operation. Through both indoor and outdoor trials, the characteristics of the thermal signature emitted by a drone when captured by a drone detection system is examined, and their implications on a machine learning problem are studied. Thermal maps are processed through a YOLOv3 based CNN model to detect and generate a bounding box around the thermal signature of the drone. The presented approach also seeks to utilise the characteristics of drone motion for more effective drone detection through machine learning.

Published

2021

39. Getting Information on Impact Damage of Carbon Fibre-Reinforced Composites from Thermal Signature Evolution

Author

Simone Boccardi, Fabrizio Ricci, Giovanni Maria Carlomagno, N.D. Boffa, and Carosena Meola

Subjects

Design phase, Computer science, visual_art, Thermal signature, Impact energy, Carbon fibers, visual_art.visual_art_medium, New materials, Pharmacology (medical), Duration (project management), Impact test, Reliability engineering, Contact force

Abstract

The susceptibility of carbon fibre-reinforced polymers to impact damage is a well-known problem and drives efforts of researchers towards the creation of new materials, which may be able to contrast impact. Being difficult to predict the behaviour of a newly conceived material during the design phase, specific tests are necessary to assess its impact resistance. This is generally obtained through lengthy tests, which, amongst others, are aimed to find a relationship between the impact energy and the size of the produced damage. A fast and relatively cheap way appears to be in-line monitoring of impacts with an infrared imaging device; the obtained information can contribute to enhance the knowledge of impact damage mechanisms. The attention of this paper is mostly focused on post-processing and analysis of thermal images, which were recorded during in-line monitoring of impact tests. The obtained results are compared with the existing literature and a general agreement is found. As important points, from mechanical-coupled thermal effects, it is possible to get information about some characteristic times such as the impact duration and the time at which peak contact force occurs as well as to individuate damage initiation. These findings can be achieved in a remote way, without any contact with the part under investigation and without any interference with the test execution.

Published

2019

40. The application of a gravimetric forward modelling of the lithospheric structure for an estimate of the average density of the upper asthenosphere

Author

Wenjin Chen and Robert Tenzer

Subjects

lcsh:QB275-343, 010504 meteorology & atmospheric sciences, Density model, lcsh:Geodesy, lcsh:QC801-809, Thermal signature, Geophysics, 010502 geochemistry & geophysics, 01 natural sciences, Mantle (geology), law.invention, lcsh:Geophysics. Cosmic physics, law, Lithosphere, Asthenosphere, Seismic modeling, Gravimetric analysis, Computers in Earth Sciences, Preliminary reference Earth model, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

The average density of 3300 kg m−3 is often attributed for the asthenosphere. In this study, we inspect this value by estimating the average value of the (upper) asthenosphere based on applying the gravimetric forward modelling of major known lithospheric density structures. The LITHO1.0 global seismic model of the lithospheric density structure is used for this purpose, while considering that the lithosphere-asthenosphere boundary (LAB) is rheological, conventionally taken at the 1300 °C isotherm, above which the mantle behaves in a rigid fashion and below which it behaves in a ductile fashion. According to our result, the average density of the upper asthenosphere is roughly 3400 kg m−3. This density value closely agrees with the corresponding average value 3371 kg m−3 computed based on an empirical density model provided in the Preliminary Reference Earth Model (PREM), while using the LITHO1.0 LAB depth data. We also demonstrate that the sub-lithospheric mantle gravity map exhibits mainly a thermal signature. The most prominent features in this gravity map are mid-oceanic spearing ridges marked by gravity lows, while oceanic subductions in the West Pacific are characterized by the most pronounced gravity highs. Keywords: Asthenosphere, Density, Forward modelling, Gravity, Lithosphere

Published

2019

41. Application of infrared thermography for debonding detection in asphalt pavements

Author

Ajit Pratap Singh, Anshuman Srivastava, Vedant Jagdish Patil, and Vidhi Vyas

Subjects

Infrared, business.industry, 010401 analytical chemistry, Thermal signature, Extrapolation, 020101 civil engineering, 02 engineering and technology, Structural engineering, 01 natural sciences, Coring, 0201 civil engineering, 0104 chemical sciences, Asphalt, Thermography, Thermal, Environmental science, Safety, Risk, Reliability and Quality, business, Heat flow, Civil and Structural Engineering

Abstract

Conventional testing practices in pavement damage surveillance and maintenance such as coring tend to be slow, destructive in nature and not wholly representative of the entire stretch of the pavement. Newly emerging technologies based on non-destructive testing techniques, do not demand implementing destructive measures or relying on extrapolation of point data and can be implemented after developing them into a proper technique and a set testing protocol. One such emerging technique that uses infrared emissions from any structure to inspect underlying defects is infrared thermography (IRT). In a patch of pavement containing subsurface defects, the heat flow to the surface of the pavement, which itself depends on the incident solar radiation, ambient temperature and other meteorological factors, gets disrupted causing a difference in the thermal signature of the defective and the sound patches. This difference in thermal signature can potentially be detected by a thermal imaging camera. This study aims at exploring the potential of IRT technique to assess the subsurface debonding defect in asphalt pavements. For this purpose, an in situ asphalt pavement test section has been constructed and different interlayer bonding conditions have been artificially induced in it. A novel way for quantitative and qualitative analyses of thermal signatures, using MATLAB for each of these bonding conditions has been carried out. The effect of different debonding agents on the overall thermal behavior of asphalt pavement has also been evaluated. Interchange time duration between day heating and night cooling cycles has been estimated, to determine the suitable time duration for asphalt pavement inspection. The results, advantages, and limitations of the method have been presented.

Published

2019

42. Thermal Signature Characteristics of Clothed Human Considering Thermoregulation Effects

Author

Hwykuen Kwak, Ji-Yeul Bae, Injoong Chang, Namkyu Lee, and Hyung Hee Cho

Subjects

Physics, Thermal signature, Mechanics, Thermoregulation

Published

2019

43. Investigation of IR pyrometer-captured thermal signatures and their role on microstructural evolution and properties of Inconel 625 tracks in DED-based additive manufacturing.

Author

Misra, Saurav, Mohanty, Ipsita, Raza, Mohammad Shahid, Chakraborty, Rajib, Chatterjee, Pallav, Gopal, Manish, Ponkshe, Shripadraj, Saha, Partha, and Kumar, C.S.

Subjects

*INCONEL, *MICROHARDNESS, *THERMOCYCLING, *GRAIN size, *SOLIDIFICATION, *PYROMETERS

Abstract

In Laser Directed Energy Deposition (DED-L) process, based on the particular thermal cycle followed during the laser processing, a wide range of microstructural and dimensional outcomes are envisaged in the end product on account of the interaction of the material or the alloy with the laser. Various parameters can influence the thermal cycle and a direct correlation between the thermal characteristics with the mechanical/metallurgical properties would be helpful to control the process in a better way. Keeping in view of this, the present study is aimed at analyzing thermal signals received from infrared pyrometer and understanding the correlation between thermal signatures, phase prediction data using CALPHAD simulation, microstructure and deposition characteristics. The thermal signatures captured from infrared pyrometer revealed close interrelationship between the input process parameters and the molten pool characteristics, which have a huge influence on the solidification rate vis-à-vis microstructural properties. Total life of melt-pool showed an increase in magnitude from 137 ms to 264 ms with decrease in cooling rates from 3000 °C/s to 1750 °C/s. The grain size increased from 3.48 μm to 7.74 μm with increase in solidification shelf life from 32 ms to 110 ms. The higher solidification shelf life and lower cooling rates also resulted in the larger and the more prominent metal carbide precipitate and intermetallic formations as evident from XRD analysis. Microhardness of the deposits also increased with decrease in solidification shelf life and increase in cooling rates of molten pool. The dimensions of laser deposited tracks were also found to increase with increment in total molten pool lifetime both at increasing laser power and decreasing laser scan peed conditions. • Inconel 625 tracks were deposited at constant power, scan speed and fluence conditions by DED-L. • Shift in solidification shelf life indicated dilution of Fe from SS 304 L substrate. • Increment of solidification shelf life at constant fluence was detected. • Solidification shelf life and cooling rate influenced microstructure and microhardness. • 244 % increase in shelf life led to 122 % increase in grain size at constant scan speed. • Increase in track cross-sectional dimension at constant fluence condition was observed. [ABSTRACT FROM AUTHOR]

Published

2022

44. Delineating seasonal porewater displacement on a tidal flat in the Bay of Bengal by thermal signature: Implications for submarine groundwater discharge.

Author

Debnath, Palash, Mukherjee, Abhijit, Singh, Hemant Kumar, and Mondal, Sourav

Subjects

*PORE water, *TIDAL flats, *THERMAL analysis, *GROUNDWATER, *WATER temperature

Abstract

Summary Submarine groundwater discharge (SGD) to the Bay of Bengal is an important groundwater discharge process to southern Asia as well as to the global oceans. Water-fluxes in these regions are not very well understood. The present study demonstrates the use of sea-bed porewater temperature as a tracer for delineating seasonal SGD from a shallow coastal aquifer to the Bay of Bengal. Porewater temperature mapping along with chemical profile of porewater column were used to delineate groundwater discharge zones for different seasons in a hydrologic year. While, the temperature profiles were used to evaluate total groundwater discharge (both terrestrial and marine), the salinity and total dissolved solids profiles were used to evaluate the component due to terrestrial (freshwater) discharge. Several springs and seeps were mapped to finger-print the freshwater discharge zones and identify the terrestrial sourced-SGD temperature windows. These zones are also identified to be enriched with algal mats, and hence may indicate the pathways of nutrient–solute discharge that enhance the primary productivity in the marine ecosystem. Assuming vertical flow in the seabed, simulated rates of discharged groundwater provided a good match with measured discharge rates. The porewater fluxes were estimated by applying analytical solutions of the heat conduction–advection equations to the observed vertical temperature profiles. High resolution thermal profiles to identify T-SGD signatures and chemical profiles along mapped transects reveal the nuances of 3-D seasonal hydrodynamics of groundwater–seawater interactions. The calculated vertical porewater fluxes through the seabed ranged from negligible to 2.45 × 10 −2 m 3 /m 2 /d 1 within a zone extending from high tide line to 40 m offshore, and represent the vertical porewater velocity and the average vertical porewater velocity is found as 8.2 × 10 −3 m 3 /m 2 /d 1 . Approximations suggest that in present-day condition, total average annual SGD to Bay of Bengal is about 1.16 × 10 7 m 3 /y. Seasonal estimates suggest that the averages SGD during pre-monsoon and post-monsoon seasons are ranges 0.6–0.8 × 10 7 m 3 /y for pre-monsoon and 0.8–1.5 × 10 7 m 3 /y for post-monsoon, respectively. The findings suggest that monsoonal activity result in a significant porewater displacement from tidal flat sediments by increased groundwater discharge. [ABSTRACT FROM AUTHOR]

Published

2015

45. A multi-method approach revealing the groundwater-stream water interaction in the Inbuk stream, Korea.

Author

Jeon, Woo-Hyun, Lee, Jin-Yong, Cheong, Woo-Yeong, Park, Yeo-Hyun, Oh, Sang-Hyun, Eum, Dong-Hwi, and Park, Jae-Yong

Subjects

*GROUNDWATER research, *STREAM chemistry, *WATER levels, *HYDRAULICS, *RIVERS

Abstract

We examined groundwater and stream water interaction in the Inbuk stream, Korea, using various approaches including hydrologic, thermal, hydrochemical, and isotopic methods. For this purpose, we installed four piezometers (IYHW1-4) in the streambed at 10 m interval across the stream and at depths of 0.90 to 1.54 m. We monitored water levels and water temperatures every hour using automatic transducers at the piezometers and in the stream (IYSW1) from September 2013 to April 2014. We also analyzed chemical and isotopic compositions for the hyporheic waters, stream water, and nearby groundwater in early September and late November in 2013. The water levels and hydraulic gradients revealed that three (IYHW1, 2, and 4) of the piezometers were in upwelling conditions for most of the monitoring period, except for the earliest short period (considered to be the wet season), whereas one piezometer (IYHW3) showed a reverse behavior, indicating that the gaining was dominant in the dry period. The mean calculated influx to the stream was 3.04 × 10 cm/sec. Observed temperatures of stream water, hyporheic waters, and groundwater also revealed that stream water was downwelling in the early monitoring period (wet season), whereas the groundwater was generally upwelling in most of the resting period, which is consistent with the water level interpretation. Chemical composition analysis indicated that most of the waters were Ca-HCO type for both seasons. However, no distinctive difference between chemical compositions of water without substantial seasonal variation negated any inference on the flow conditions. The mixing ratios computed from oxygen and hydrogen isotopic compositions indicated that losing conditions were dominant in the wet season, whereas gaining conditions prevailed in the dry season. The interpretations of stream water and groundwater interactions based on these different methods are relatively consistent for this study area, indicating that such combined methods will be very useful in enhancing understanding of groundwater and stream water interaction. [ABSTRACT FROM AUTHOR]

Published

2015

46. Experimental study of the crystallization of sodium sulfate hydrates through temperature monitoring.

Author

Denecker, M., Hebert, R., Wassermann, J., Dosseh, G., Menendez, B., and Bourgès, A.

Subjects

SODIUM sulfate, ENVIRONMENTAL monitoring, EFFECT of temperature on building materials, CRYSTALLIZATION, SALT weathering

Abstract

Sodium sulfates are well known to be the most damaging salts in building materials and rocks. Unfortunately, the crystallization processes of sodium sulfates are not completely understood. In addition, the metastable heptahydrate has long been neglected in scientific works on salt damage until recently. In this study, we use temperature monitoring and differential scanning calorimetry to detect and identify the crystallization of sodium sulfate hydrates (i.e., mirabilite and heptahydrate) upon cooling/heating a bulk solution. The presence of impurities seems to play a major role in the crystallization sequence and can explain the crystallization of mirabilite and ice close to −10 °C. The crystallization of heptahydrate does not seem to be sensitive to the presence of impurities and does not always occur prior to the crystallization of mirabilite as commonly observed. The heptahydrate and mirabilite show different and characteristic thermal signatures that enable to distinguish each other. The shape, the intensity and the duration of the peak of temperature due to the crystallization depict these differences. Therefore, the thermal signatures can be used in further experimental studies to estimate the role of the different sodium sulfate hydrates involved in the salt weathering of rocks. [ABSTRACT FROM AUTHOR]

Published

2014

47. Aircraft thermal signature

Author

Slobodan Bursać

Subjects

thermal signature, infrared signature, thermal image of aircraft, Military Science, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Aircraft thermal signature has been modelled by calculating irradiance at ihe observer's spot (detector position) from aircraft elementary surfaces. The elementary surface is a triangle determined by its corner temperatures and the cosine of the angle between the normal surface in the angle centre of gravity and the detector direction. Visibility and overlapping of elementary surfaces are controlled using the perspective transformation of an object into the plane. The mathematical model of aircraft thermal signature also includes the atmosphere influence through the LOWTRAN software.

Published

1999

48. On the Thermal Signature of the Residual Foam in Breaking Waves

Author

Andrew T. Jessup, Naeem Masnadi, and C Christopher Chickadel

Subjects

Physics, 010504 meteorology & atmospheric sciences, Infrared, Thermal signature, Breaking wave, Mechanics, Dissipation, Oceanography, Residual, 01 natural sciences, Momentum, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), 0105 earth and related environmental sciences

Abstract

Quantifying energy dissipation due to wave breaking remains an essential but elusive goal for studying and modeling air-sea fluxes of heat, gas, and momentum. Previous observations have shown that ...

Published

2021

49. Super-Thermite (Al/Fe2O3) Fluorocarbon Nanocomposite with Stimulated Infrared Thermal Signature via Extended Primary Combustion Zones for Effective Countermeasures of Infrared Seekers

Author

Elbasuney, Sherif, Elsaidy, Amir, Kassem, Mohamed, Tantawy, Hesham, Sadek, Ramy, Fahd, Ahmed, and Gobara, Mohamed

Published

2018

50. Infrared Signature of Novel Super-Thermite (Fe2O3/Mg) Fluorocarbon Nanocomposite for Effective Countermeasures of Infrared Seekers

Author

Elbasuney, Sherif, Elsaidy, Amir, Kassem, Mohamed, and Tantawy, Hesham

Published

2018