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Damage Identification For Masonry Materials Based On Bayesian Inference Xiangping Fu1,a, Bin Peng 1, band Zheng Ji1,c 1School of Environment and Architecture, University of Shanghai for Science and Technology, 516 Jungong Road, Shanghai 200093, China akuai5237@hotmail.com, bpengtj77@hotmail.com, cjizheng0903@gmail.com Keywords: Dynamic test; Basic frequency; Elastic modulus; Bayesian inference; Damage factor; Masonry Abstract.
The methodology was applicable, and can be used in the damage identification for other materials or structures.
This study attempts to deal with the uncertainty in test data, then to identify the degree and location of damages in masonry materials.
Journal of Vibration.(2005) In Chinese
Journal of Engineering Mechanics, 1998, 124(4): 455-461

Voorwald: submitted to Brazilian Conference on Composite Materials Matéria (Rio de Janeiro) (2017) [37] N.
Rahman: submitted to Materials Research Innovations (2014) [40] S.G.
Umar: submitted to Journal of food science (2019) [41] I.S.M.
Umehara: submitted to Materials & Design (2015) [43] M.
Jung: submitted to International Journal of Medical Sciences (2017)

Compared to low carbon galvanized sheet, ST14 materials is of high hardness, and is poor in plasticity and toughness.
ST14 material is equivalent as SPCE material mainly domestic use ST14 materials Baosteel production.
Analysis and comparison of different materials ST14 material around the back door window frames of the front bracket symmetrical parts stamping process analysis, process design and experience structure made ​​a good combining effects, ST14 material stamping process parameter settings are also within reasonable limits.
Fig.7 Materials set Cracking at Fig.8 Focusing on the results of analysis of Japanese grade material (stamping) SGCD1 in Figure 8, the space of the material of the material cracking position of the forming process, the cracking phenomenon is relatively heavy, cracking defects appear in the plurality of positions; This shows that the process set in accordance with the ST14 material, the structure is specific, and replaced with other materials require different process structure.
Hefei University of Technology，2005,12(1O):1547～1551 [7] Huang Q，Kajita S，Kaneko K,et a1.Planning walking patterns for a bipedrobot [J]IEEE Transactions on Robotics andAutoma-tion,2001，17(3):280～289 [8] Makinouchi A．Sheet metal forming simulation in industry [J].Journal of Materials Processing Technology,1996,60(1～4):19～26 [9] MEINDERS T,CARLEER B D,GEIJSLAERS H J M,et a1.The implementation of an equivalent dread model in a finite-element code sheet metal forming[J].Journal of Material Processing Technology,1998,83：234～244 [10] Lin Tong,Zhang Kan,Hu Renxi.

The temperature-rise and shear force are measured for three different materials (i.e. copper, aluminum and silicon wafer) during mechanical polishing process.
Three kinds of test materials are compared: a silicon wafer (E=190 Gpa), copper (E=110 Gpa) and aluminium (E=70 Gpa).
Different kinds of materials (i.e. copper, aluminum and silicon wafer) are tested and compared in the mechanical polishing process.
Cook: Journal of Non-Crystal Solids Vol. 120 (1990), p. 152 [4] G.
Eyman: Journal of Electrochemical.

Research on Coal Mining Material Active Perception System based on IOT and Coal Resources Jingzhao Li 1,a, Huimei Deng 1,b 1 School of Computer Science and Engineering, Anhui University of Science and Technology, Huainan,China ajzhli@aust.edu.cn, bdenghuimei@sina.com Keywords: IOT, coal mining, material, active perception Abstract.
On this basis, coal mining material active perception system is designed.
This work is supported by National Nature Science Foundation under Grant (61170060),Anhui Provincial Natural Science Foundation (11040606M135), Anhui Provincial Natural Science Foundation of Universities Key Projects Project Approval (KJ2011A083).
THE 2ND International Conference on Information Engineering and Computer Science, 2010:1944-194 [2] Jingzhao Li Qian Liu.
Journal of Parallel and Distributed Computing, 2011,45(3): 460-470

Roll bonding of two materials using temperature to compensate the material strength difference A.
Schultz, Macro- and micro-surface engineering to improve hot roll bonding of aluminum plate and sheet, Materials Science and Engineering A 479 (2008) 45–57
Daehn, Vaporizing foil actuator: A tool for collision welding, Journal of Materials Processing Technology 213 (2013) 2304–2311
Yin, F., Progress in cold roll bonding of metals, Science and Technology of Advanced Materials 9 (2008) 1–11
Prediction of rolling loads and finish rolling temperature, Journal of Materials Processing Technology 170 (2005) 323–335.

The results show that the stiffer materials may always give retardation effect on stress intensity factors when a crack approaching interfaces.
On the other hand, the softer materials may always give enhancement effect on stress intensity factors.
Since they are checked to achieve a good approximation for most combination materials, this demonstrates the accuracy and the efficiency of the proposed method.
CMES: Computer Modeling in Engineering & Sciences, 84-5 (2012) 439-458
Journal of Mechanics, 29-1 (2013) 391-399.

Most roofs on Earth are made of dark materials.
Reflective materials are also referred to as cool materials because, under the same conditions, they remain colder than standard materials due to their optical characteristics [4].
Solar Energy Materials and Solar Cells, 236, 111492
Applied Sciences, 11(7), 3263
Journal of applied polymer science, 96(4), 1126-1137

Introduction With the modern industry’s rapidly development,the contradiction between man and nature has been deteriorated.The wall building material is one of the largest amount of construction materials in the world,it has caused a lot of load on the environment during its entire life cycle,including the production,construction,use and discard stage.How to evaluate the wall building material’s environment impact quantitative is becoming a key issue for the wall building material’s sustainable development.
The model based on China's national conditions, not only considered the wall material in the life cycle of the negative impact on the environment , Also taking into account the benefits of waste materials in the wall and other aspects of an active role.It can not only be used to evaluate the different wall building material’s enviorment impact ,but also can be used on the same wall at different stages of life cycle assessment analysis.
[M].Beijing: Science Press,2002 ,in Chinese
[2]Gong Ping, Study on Green Degree Evaluation System of Wall Building Materials [D].
[3] Wang jin, Zhang xu, Model improvement of inventory analysis on energy upstream phase based on life cycle assessment, Journal of Tongji university (natural science):2009,37(4):520-524,in Chinese

Gerlich, Joining of automotive sheet materials by friction-based welding methods: A review, Engineering science and technology, an international journal 21.1 (2018) 130-148
Anawa, and Abdul-Ghani Olabi, Control of welding residual stress for dissimilar laser welded materials, Journal of materials processing technology 204.1-3 (2008) 22-33
Chattopadhyay, Microstructure development during dissimilar welding: Case of laser welding of Ti with Ni involving intermetallic phase formation, Journal of materials science. 41 (2006) 643-652
Chattopadhyay, Phase formation in Ti/Ni dissimilar welds,  Materials Science and Engineering.
Kasai, Morisada, Y,Fujii, H, Dissimilar FSW of immiscible materials: steel/magnesium, Materials Science and Engineering: A 624 (2015) 250-255