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Kim, Investigation of lock-in infrared thermography for evaluation of subsurface defects size and depth, International Journal of Precision Engineering and Manufacturing. 16 (2015) 2255–2264. https://doi.org/10.1007/s12541-015-0290-z
Jung, Detection of hidden corrosion in metal roofing shingles utilizing infrared thermography, Journal of Building Engineering. 20 (2018) 201–207. https://doi.org/10.1016/j.jobe.2018.07.018
Chiou, Improving the detectability and confirmation of hidden surface corrosion on metal sheets using active infrared thermography, Journal of Building Engineering. (2023) 105931. https://doi.org/10.1016/J.JOBE.2023.105931
Lagüela, Introduction of active thermography and automatic defect segmentation in the thermographic inspection of specimens of ceramic tiling for building façades, Infrared Phys Technol. 121 (2022). https://doi.org/10.1016/j.infrared.2021.104012.

Cheang, International Journal of Mass Spectrometry and Ion Processes 116 (1992) 249–256
Soo, International Journal of Mass Spectrometry and Ion Processes 134 (1994) 221–228
Milberg, Journal of the American Ceramic Society 51 (1968) 326–329
Button, Materials Science and Engineering: B 13 (1992) 157–164
Charles, Journal of the American Ceramic Society 48 (1965) 432-&

Since BMGs can be applied as potential structural materials, their fatigue behavior is very important for engineering applications.
Masumoto: Materials Science And Engineering A Vol. 173 (1993), p. 1
Liaw: Journal of Non-Crystalline Solids Vol. 317 (2003), p. 187
Brooks: Key Engineering Materials Vols. 345-346 (2007), p. 217
Brooks: Journal of Materials Research Vol. 22 (2007), p. 493

Modeling and Analysis for Hardness and Structure of Nonferrous Alloy castings produced using Zcast Metal casting Process through Response Surface Methodology Rajesh Kumar1,a, Rupinder Singh2,b, Inderpreet Singh Ahuja3,c 1Research Scholar, Department of Mechanical engineering, Punjabi university, Patiala (India) 2Professor, Department of Production engineering, Guru Nanak Dev Engineering College, Ludhiana (India) 3Professor, Department of Mechanical engineering, Punjabi university, Patiala (India) arajeshseptus@yahoo.com (corresponding Author), brupindersingh78@yahoo.com, cahujaips@yahoo.co.in Keywords: Hardness, structure, Mathematical Modeling, Three Dimensional Printing, Response Surface Method Abstract: The purpose of this investigation is to develop a mathematical model for predicting the influence of casting parameters on hardness of non ferrous alloy (NFA) castings produces using Zcast process by employing response surface methodology (RSM).
ZCast process uses ZCast501 powder, which is a proprietary mixture of powdered metal, plaster and ceramic composite designed for casting non-ferrous alloy metals [9].
Joshi, “Growth and characterization of Struvite crystals” National Journal of Pure & Applied Physics, Volume 46, Page No. 507-512, 2008
Mukunda, "Effect Of Mould Wall Thickness On Rate Of Solidification Of Centrifugal Casting" International Journal of Engineering Science and Technology Vol. 2(11), 6092-6096 ISSN: 0975-5462, 2010
M., “Science and Engineering of Casting Solidification”, Kluwer Academic/Plenum Publisher, 2002

Prediction of Melt Pool Dimension, Porosity Generation and Thermal Behavior of Ti-6Al-4V During Powder Bed Fusion at Various Scan Speeds and Laser Powers Nada Hassine1,a , Sami Chatti1,b* , Mouna Ben Slama1,c and Lioua Kolsi2,3,d 1Laboratory of Mechanical Engineering (LGM), National Engineering School of Monastir (ENIM), University of Monastir, Rue Ibn El Jazzar, 5000 Monastir, Tunisia 2Department of Mechanical Engineering, College of Engineering, University of Ha’il, Ha’il City 81451, Saudi Arabia 3Laboratory of Metrology and Energy Systems, Department of Energy Engineering, University of Monastir, 5000 Monastir, Tunisia anada.hassine@enim.u-monastir.tn, bsami.chatti@udo.edu, cmounaslama@hotmail.fr, dl.kolsi@uoh.edu.sa *Corresponding author Keywords: additive manufacturing; laser powder bed fusion; melt pool size; process parameters; porosity prediction.
Zhang, Effects of processing parameters on the temperature field of selective laser melting metal powder, Powder Metallurgy and Metal Ceramics (2009) vol. 48, no. 3–4, pp. 186–195
Lutzmann, Modelling and simulation of electron beam melting, Production Engineering (2010) vol. 4, no. 1, pp. 15–23
Luo, Thermal Behavior and Densification Mechanism during Selective Laser Melting Additive Manufacturing of Metal Powder, Steel research international (2020) vol. 91, no. 8, pp. 1–13
Jin, Numerical analyses of molten pool evolution in laser polishing Ti6Al4V, Journal of Manufacturing Processes (2020) vol. 58, no.

Department of Civil Engineering and Architecture，Xiamen University of Technology, Xiamen, 361024 2.
Xiamen Engineering Research Center of Ecological Building Materials, Xiamen, 361024 3.
[2] Malolepszy, J., 1986, Activation of synthetic melitite slags by alkalis. 8th International Congress on the Chemistry of Cement, Rio de Janeiro, Brazil, 4, 104-107
[10] Wu, Q., 1999, Cemeng Engineering (in Chinese), 5, 10-11
[29] Xu zhong zi, 1994, JOURNAL OF THE CHINESE CERAMIC SOCIETY, Vol. 22, No.2.

Journal of International Economic Law 7 (2) (2004), pp. 359-370
IEEE Transactions on Engineering Management 46 (3) (1999), pp. 311-320
IEEE Transactions on Engineering Management 42 (3)(1995), pp. 203-214
Proceedings of the First International Congress on Ceramics, Toronto.
Suh: A Theory of Complexity, Periodicity and Design Axioms, Research in Engineering Design, Volume 11, pp. 116-131 (1999)

Masonry as Simulation Object OLEG KABANTSEV National Research University Moscow State University of Civil Engineering, 129337, Russia, Moscow, Yaroslavskoye shosse, 26 email:ovk531@gmail.com Keywords: masonry, brick, mortar, modeling, numerical methods, design model, stress-and-strain state.
The study phases of inelastic strain and destruction of masonry are the basis for the actual provision of masonry structures in such a crucial area of ​​earthquake engineering.
Towards a multiscale analysis of periodic masonry brickwork: a FEM algorithm with damage and friction. (2006) International Journal of Solids and Structures, 43, pp. 3739–3769
[Structural behavior analysis taken into account changes of design model] (2014) Magazine of Civil Engineering, 5, pp. 15–26.
Verifikatsiya raschetnoy tekhnologii “Montazh» programmnogo kompleksa “SCAD” [Verification of computational technology "Mountihg" from software complex “SCAD”] (2011) International Journal for Computational Civil and Structural Engineering (ISSUE), 3, vol. 7, pp. 103–109.

Developing the Ecology Residence According with the State of China Yiding Zhu 1,2 ,a, Qiang Zhang 1,2,b 1 School of Civil & Hydraulic Engineer of Ningxia University, Yinchuan, Ningxia, 750021, China 2 Engineering Research Center of Efficient Use of Water Resources in Arid Modern Agriculture Ministry of Education, Yinchuan , Ningxia, 750021, China a13995475126@163.com, bnxdxzq@163.com Keywords: ecology residence, state of a country, economizing energy, economizing water economizing land, economizing material, environmental protection, green color.
Really construction of ecology residence is a systems engineering.
The total consumption of our country energy quantity rowed second in the world, is an great nation of energy consumption ,only constructs the steel and iron,the cement,the plate glass,the structural ceramics,the bricks,tiles sand,crushed stone consumes and so on,several item of material productions consumed energy reaches the 1.6×108t standard coal,occupies the national energy production 13%,the consumption of building energy occupied the energy of national commodity 27.65% in 1998;Because of the winter heating consumption's energy reaches the 1.3×108t standard coal in our northern area,occupies the national energy production 11%.It is in heats that is about 70% land in our country,about the floor space area occupies 50% in whole country,occupies 85.6% about the heating and air conditioning energy consumption with the housing related heating and energy consumption[3].
The green construction is referred to the people providing the health, comfortable, the safe housing, the work and the active space, simultaneously constructs the cycle of entire life(material production, construction plan, design, construction, operation maintenance and demolition,the process of sales commission).Using the resources to realize the high efficiency(energy, land, water resources, material),threshold influenced the environment building[1].According to the association's definition of international green construction,the evaluation of green ecologically-safe building's includes:The energy, the water,the sound,the light,the heat,the afforestation,the environment,the green building materials and the waste treatment and so on nine large-scale system[2],is mainly requests the building entire process the nurse resources,the satisfied person's request and the protection of environment.
[2] Li Luming :Overview of green building assessment abroad,World Architecture 2002(1),p.11-12; [3] Zhang Kai:Study on the construction of Ecological Residential District of city,Science Press, Beijing,2003,p.22-23 [4] Zhu Yiding,He Shengyun: Problems and development tendency of housing construction in China,Journal of HeFei University of technology (Natural science),2008(2),p.237-240 [5] Runming Yao,Koen Steemers,Baizhan Li:Sustainable Urban and Architectural Design,China Architecture & building Press, Beijing ,2006,p.159-237 [6] Jiang Yi,Lin Borong,Zeng JianNong,Zhu YingXin: Energy Efficiency in Residential Building, China Architecture & building Press, Beijing ,2006,p.3-8 [7] Yuan Bin,wang DaWei: Analytic on our Green Building Evaluation Criteria, Intelligent Building and City information,2007(4),p.14-18

College of Material Science and Engineering, Jiangsu University of Science and Technology, Zhenjiang 212003, China; 2.
Chemical Engineering Journal, Vol. 192 (2012), p. 99–104
Chemical Engineering Journal, Vol. 192 (2012), p. 232–241 [24] J.H Li, JJ.
Chemical Engineering Journal, Vol. 192 (2012), p. 232–241
Chemical Engineering Journal, Vol.181– 182 (2012), p. 169– 173