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The Application of MASW Method on the Studying of the Vibrations in Civil Engineering Kun LUO1, a 1 East China Jiaotong University, Nanchang 330013, China aLK360111@163.com, Keywords: Surface wave; vibration; Shear wave; MASW; Inverse problems; Abstract.
Surface-wave dispersion analysis is widely used in civil engineering to infer a shear wave velocity model of the subsoil for a wide variety of applications.
While all the people enjoy the advantages of the railway, however, the buildings along the railway line will be influenced by the vibration caused by the railway, and the key point to solve the vibrations in civil engineering is to investigate the geologic parameters of the building foundation along the depth.
In this paper, the application of MASW method was used to solve this problem in the studying of the vibrations in civil engineering. 2 The entire procedure of MASW method The entire procedure of generating profile consists of three steps, shown in l The first step, acquiring ground roll data in the field.
A., 1991, Accuracy and resolution of surface wave inversion[A], American Society of Civil Engineers: 17-32

Innovation on Teaching Methods of Foundation Engineering Course Qingnian Yanga and Yuzhou Simab Department of Civil Engineering, Nanyang Institute of Technology, Nanyang 473004, China anewyear1230@163.com, bsmyzh9833@163.com Keywords: Foundation Engineering; teaching methods; revolution; teaching of practical.
Foundation Engineering is a professional and basic course which must be learnt by the students in the majors relating to Civil Engineering and Architecture.
Introduction Foundation Engineering is a compulsory course for the students who are major in Civil Engineering and Architecture [1-5].
The fast development of Civil Engineering and Architecture produces a large number of new researching subjects of Foundation Engineering, and the Foundation Engineering is also obtained unprecedented development, Unfortunately, the current teaching materials are difficult to reflect these new achievements and progresses.
Gu, Teaching reform for foundation engineering course of civil engineering specialty, Journal of Architectural Education in Institutions of Higher Learning, 5 (2010) 91-93

High-performance materials for civil air defense works can resolve the problem effectively.
Architectural Design & Research Institute, Shandong Province, has reinforced in the civil air defense engineering applications HRBF500 reinforcing bar preliminary studies [1], Recent issue of Technical guidelines for application of high strength hot rolled ribbed bars in concrete structure RISN-TG007-2009[2] put forward guiding on high strength steel in the air defense and high-performance fiber reinforced cement-based composite materials for civil air defense projects in the domestic limited to airtight blast door, explosion-proof door and other structural element.
Design features of civil air defense work Design of civil air defence work is different to general civil,load are occasional moments and duration is very short.
Therefore, the civil air defense engineering requirements for building materials not only strength but also high ductility, high energy capacity and impact resistance.
Practical example This project is a layer of underground garage, floors 5m, column spacing 8.4m, top of the casing 0.8m, engineering design life of 50 years, according to the nuclear 6 A defense basement design.

Collection of selected, peer reviewed papers from the 2014 International Conference on Civil, Architechture and Building Materials (CEABM 2014), May 24-25, 2014, Haikou, China.

The 638 papers are grouped as follows:
Chapter 1: Geotechnical Engineering,
Chapter 2: Geological Engineering,
Chapter 3: Tunnel, Subway and Underground Facilities,
Chapter 4: Seismic Engineering,
Chapter 5: Hydraulic Engineering, Water Resources and Hydrology,
Chapter 6: Coastal Engineering,
Chapter 7: Construction Technology,
Chapter 8: Water Supply and Drainage Engineering,
Chapter 9: Heating, Gas Supply, Ventilation, Air Conditioning Works and Daylighting Design,
Chapter 10: Oil, Gas and Mineral Exploration, Chapter 11: Disaster Prevention and Mitigation,
Chapter 12: Cartography and Geographic Information System,
Chapter 13: Surveying Engineering,
Chapter 14: Applied and Computational Mechanics,
Chapter 15: CAD/CAE/Computer Technology Keyword: Geotechnical Engineering; Geological Engineering, Tunnel, Subway and Underground Facilities; Seismic Engineering; Hydraulic Engineering, Water Resources and
Hydrology, Water Supply and Drainage Engineering; Heating, Gas Supply, Ventilation, Air Conditioning Works and Daylighting Design; Oil, Gas and Mineral Exploration

Collection of selected, peer reviewed papers from the 2013 International Conference on Civil Engineering and Transportation (ICCET 2013).

The 521 papers are grouped as follows:
Chapter 1: Geotechnical Engineering;
Chapter 2: Geological Engineering;
Chapter 3: Structural Engineering;
Chapter 4: Monitoring and Control of Structures;
Chapter 5: Structural Rehabilitation, Retrofitting and Strengthening;
Chapter 6: Reliability and Durability of Structures;
Chapter 7: Bridge Engineering;
Chapter 8: Seismic Engineering;
Chapter 9: Tunnel, Subway and Underground Facilities;
Chapter 10: Hydraulic Engineering;
Chapter 11: Coastal Engineering;
Chapter 12: Surveying Engineering;
Chapter 13: Construction Technology;
Chapter 14: Heating, Water and Gas Supply, Ventilation and Air Conditioning Works;
Chapter 15: Prevention Catastrophes and Disasters Mitigation;
Chapter 16: Computational and Applied Mechanics;
Chapter 17: Computer Applications and Information Technologies in Construction;
Chapter 18: Engineering Management in Construction
Keyword: Geotechnical Engineering; Geological Engineering; Structural Engineering; Monitoring and Control of Structures; Structural Rehabilitation, Retrofitting and Strengthening; Reliability and Durability of Structures; Bridge Engineering; Seismic Engineering; Tunnel, Subway and Underground Facilities; Hydraulic Engineering; Coastal Engineering; Surveying Engineering; Construction Technology; Heating, Water and Gas Supply, Ventilation and Air Conditioning Works; Prevention Catastrophes and Disasters Mitigation; Computational and Applied Mechanics; Computer Applications and Information Technologies in Construction; Engineering Management in Construction

Civil engineering uses steel as one of the basic structural materials.
Introduction Civil engineering uses steel as one of the basic structural materials.
Steel sheets in civil engineering Sheets are the basic steel products.
Hot-dip galvanised sheets [4] and organic-coated steel sheets [5] are mainly used in the civil engineering.
Gierzyńska-Dolna., Gorecki W., Corrosion Resistance of Galvanised Sheets Used in the Civil Engineering.

This volume was collected by results of the International Conference on Recent Advances in Materials, Mechanical and Civil Engineering (ICRAMMCE-2017, 1-2nd June, 2017, Hyderabad, India) and presents readers with the results of recent researches and achievements in the fields of the structural materials, technologies of materials processing, building materials and technologies in the construction, applied mechanics and practice of design in the mechanical engineering.
We hope that this collection will be useful for many specialists from area of mechanical engineering and construction.
Steel, Alloys, Composites, Ceramics, Coatings, Processing Technologies, Technological Parameters, Mechanics, Designing, Mechanical Engineering, Building Materials, Technologies in Construction

Test of solidification characteristics of grouting and the effect on strata deformation in shield tunnelling Xiaochun Zhong 1, a, Weike Qin 2,b, Hai Wang 3,c 1School of Civil Engineering, Hohai University, Nanjing, China 2School of Civil Engineering, Hohai University, Nanjing, China 3School of Civil Engineering, Hohai University, Nanjing, China axchzhong@tom, bvic.tsing@gmail.com,cwang3265616@gmail.com Keywords: shield tunnel; strata deformation; grouting; variable rigid body model,civil engineering Abstract-- Back-fill Grouting is a key procedure for the active control of strata settlement during shield tunnelling in civil engineering.
The paper establish a numerical model of shield tunnelling in civil engineering with the consideration of characteristics of grout deformation, and has analyzed law of strata settlement.
Acknowledgement The authors would like to acknowledge the financial support from “the Fundamental Research Funds for the Central Universities” Reference [1] Zhu Wei,Chen Junren.Shield tunneling technology status and prospects [J]．Geotechnical Engineering World,2001,4 (11) [2] Peck P.B.
Journal of Geotenical and Geoenviromental Engineering. 1999,125(4):289~300 [5] K M，Rowe R K．Finite element modeling of the three-dimensional ground deformations due to tunneling in soft cohesive soils: part Ι-method of analysis [J].
Computers and Geotechnics, 1990 [6] Zhu Hehua,Ding Wenqi,Li Xiaojun. construction simulation for the mechanical behavior of shield tunnel and its application[J].China Civil Engineering Journal,2000,33(3):100~105

Collection of selected, peer reviewed papers from the International Applied Science and Precision Engineering Conference 2013, October 18-22, 2013, Nan Tou, Taiwan.

The 228 papers are grouped as follows:
Chapter 1: Materials Engineering and Processing Technologies of Materials;
Chapter 2: Optoelectronics and Optical Systems;
Chapter 3: Machine Parts and Mechanisms, Design and Manufacturing;
Chapter 4: Medical Machinery and Technologies, Innovative Developments;
Chapter 5: Electronics, Electrical Engineering and Power Electronics;
Chapter 6: Energy and Power Engineering;
Chapter 7: Automation and Control;
Chapter 8: Sensors, Mechatronics and Robotics;
Chapter 9: Methods and Algorithms for Processing and Analysis of Data;
Chapter 10: Computer and Information Technologies;
Chapter 11: Environmental Sciences and Engineering, GIS;
Chapter 12: Architecture, Civil and Industrial Engineering;
Chapter 13: Related Topics Keyword: Materials Engineering and Processing Technologies of Materials; Optoelectronics and Optical Systems; Machine Parts and Mechanisms, Design and Manufacturing
; Medical Machinery and Technologies, Innovative Developments; Electronics, Electrical Engineering and Power Electronics; Energy and Power Engineering; Automation and Control; Sensors, Mechatronics and Robotics; Methods and Algorithms for Processing and Analysis of Data; Computer and Information Technologies; Environmental Sciences and Engineering, GIS; Architecture, Civil and Industrial Engineering

INCORPORATION OF CIVIL CONSTRUCTION REJECTS MATERIALS IN STRUCTURAL CERAMIC.
Cosin, S.1, a; Kozievitch, V.F.J.1, b Rito,J.E.Di.2, c, Albanez, N.E.K.1, d, Martín Cortés, G.R. 3, e Valenzuela-Diaz, F.R.1, f 1Particulate Raw Materials and Non-Metallic Solids Laboratory Department of Metallurgic Engineering and Materials of the Polytechnic School - USP.
Spherical samples had been conformed incorporating 1%, 5%, 10%, 20% and 30% of reject from the civil construction in mass.
Introduction Even in the middle of the economic world crisis, the sector of the civil construction in Brazil did not stop growing.
Rejects Materials from Civil Construction The Particulate Raw Materials and Non Metallic Solids Laboratory (LMPSOL) - Metallurgical & Materials Engineering Department – Polytechnic School – University of São Paulo comes being studied several types of powder wastes [1] seeking it application in different economy manners, and reducing costs in the final products, since that material possesses low cost, or same zero.