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Solution of thermal bridge under the opening in the cladding by means of support structure for a doors threshold made of thermal insulation composite material Tomas Pospisil a, Jan Pencik b, Libor Matejkac, Libor Matejkad, Alena Kaluzovae and Darina Dostalovaf Brno University of Technology, Faculty of Civil Engineering, Institute of Civil Engineering, Veveri 331/95, 602 00 Brno, Czech Republic apospisil.p@fce.vutbr.cz, bpencik.j@fce.vutbr.cz, cmatejka.l@fce.vutbr.cz, dmatejka.l1@fce.vutbr.cz, ekaluzova.a@fce.vutbr.cz, fdostalova.d@fce.vutbr.cz Keywords: Composite, Elimination, Energy Saving, Heat Loss, Polymers, Thermal Bridge, Waste.
[2] ČSN EN ISO 10211 Tepelné mosty ve stavebních konstrukcích – Tepelné toky a povrchové teploty – Podrobné výpočty (Thermal bridges in civil structures – Thermal flows and surface temperatuers – Detailed calculations).

Design Study of Steel Structure Fire-retardant Coatings under High Temperature (Fire) Conditions Manli Ou 1, a, Weijun Cao 2,b ,and Longmin Jiang 3,c and Hui Cao4,d 1College of Civil Engineering, Hunan University of Technology,Hunan,Zhuzhou ,412008,China 2College of Civil Engineering, Hunan University of Technology, Hunan,Zhuzhou ,412008,China 3College of Civil Engineering, Hunan University of Technology, Hunan,Zhuzhou ,412008,China 4College of Civil Engineering, Hunan University of Technology, Hunan,Zhuzhou ,412008,China a445698185@qq.com, b120996961@qq.com, c527943658@qq.com , d 296992028@qq.com Key words: Steel structure, High temperature, Fire-resistant coating, Fire-resistance analysis, Design examples Abstract: As the result of great changes occurring to mechanical properties under high temperature (fire) conditions, steel structures will soon lose the strength and stiffness and lead to structural damage.
This shows that the impact of fire on steel structures is much larger than that on the reinforced concrete structure; steel structure fire resistance performance studies have become a problem in the urgent need of resolution for the engineering sector [2].
(12) Fire Protection design example of steel structures protected by fire-resistant coatings Project Overview.This project is steel structure engineering of Dongfeng Nissan Car 4S Shop at Xiangfu Rd, Changsha afflicted to Hunan Lantian Industrial Co., Ltd.
Dongfeng Nissan Auto 4S Shop at Xiangfu Rd in Changsha has been completed (see Figure 9), the whole structure adopts steel structure engineering.
Changsha: Hunan University, School of Civil Engineering(2007) In Chinese [3] National Standards of the People’s Republic of China.

Exploration and Practice on Remote Monitoring & Management of Excavation engineering Liu Jun-yan1，a, Liu Yan1,b and Liu Tao2,c 1School of Civil Engineering and Architecture of University of JINAN, Ji’Nan 250022, China， 2Ocean University of China，Qingdao 266033，China aLiujunyan@vip.sina.com, bliuyan322@163.com, cltmilan@163.com Keywords: construction management, remote monitoring, informatization Abstract.
The management system is a meaningful attempt of information based subway engineering management.
The problems in engineering construction will be found and solved as soon as possible to ensure the safe ongoing of the engineering.
Management division holds the power of allocating all resources and information in engineering construction and is the decision maker in engineering construction.
If the construction continued, engineering accidents would occur.

Research on material properties of engineering materials with construct disaster preparedness of the four-dimensional space in hilly cities’ communities Qian Si-ru Institute of Civil Engineering and Building Southwest University of Science and Technology，Mianyang, China, 621002 358125700@qq.com Keywords: hilly cities, disaster, community , comprehensive disaster ,disaster preparedness in cities窗体顶端 Abstract:We take “5.12 Wenchuan earthquake” influence and one of the university in Mianyang urban area as the typical examples of the disaster preparedness community.
We discuss how to plan the multiply disaster preparedness which in accordance to the geographical feature of hilly cities through the material properties of engineering materials research and study of the four-dimensional space disaster preparedness model. 1 Introduction of example situation 1 .1 Landsacape and environment Mianyang located in the northwest Basin of Sichuan province , Southeast of the terrain.
It is very vulnerable to floods.And the material properties of engineering materials is fluent. 1. 2 Example’s current situation The campus covers an area of 4088 acres(2725333 square meters),the topography feature is east high and west low.
shortcoming of the community disaster preparedness facilities can not meet the actual needs .These problems which appear after the great disaster, reminding us disaster preparedness facilities are the basis and guarantees of the disaster preparedness function,we systematically plan not only for the community disaster space system , but also the disaster preparedness facilities in the building should be synchronized to keep up the pace .Therefore, according to the actual situation of the community,we made a number of recommendations of disaster preparedness facilities planning (picture 1): (5)Facilities Planning Recommendations of disaster preparedness facilities: ①rational refuge entrance location ② perfect shelter ③ set up different types of water bodies.Including 1) a natural water body 2) artificial water body 3)underground storage facilities and backup wells ④ increase Fire Barrier ,temporary toilets and emergency lighting facilities ⑤ increase research on material properties of engineering

Pile bearing properties analysis based on energy method Sisi Liu 1, a, Zhongqiu Xie1,b 1 College of Civil Engineering and Mechanics, Central South University of Forestry and Technology, Changsha, Hunan, 410004, China a30849650@qq.com, b1152268618@qq.com Keywords: Bridge engineering; Pile foundation; Load capacity; Settlement; Energy method Abstract.
The conclusions are pile bearing properties can be analyzed reasonably by this method, and the calculation results can provide a reference to engineering practice.
[2] QIAN Jiahuan, YIN Zengze, Soil Engineering Theory and Calculation,Beijing,1996
[6] BENGT H,FELL ENIUS, Axial Load Test s on Bored Piles and Pile Groups in Cemented Sands, Journal of Geotechnical and Geoenvironmental Engineering, 129(2003)183-185
[10] CHEN Longzhu, Analytical Solution for Axial Loading -settlement Curve of Piles, Chinese Journal of Geotechnical Engineering, 16(1994)30-38

Test study on the influence of periodical temperature stress on the loss of structural prestress Xi Li, Tingting Cai and Anbang Gu School of civil Engineering & Architecture, Chongqing Jiaotong University, Chongqing 400074, China lixi514@126.com Keywords: prestressed concrete, bridge engineering, crack, temperature stress, test study Abstract.
The test takes Baiguodu Bridge in Chongqing Municipality as the supporting engineering to simulate the continuous effect of annual temperature change, for the measurement of prestress loss of the concrete structure.
Therefore in the engineering design, it is only simplified as the joint expansion of concrete and reinforcement.
Take Baiguodu Bridge in Chongqing Municipality as the engineering background, the closure temperature is 25°C, and according to the annual temperature difference, and the beam changes along the length direction, taking the maximum and minimum temperatures as 45°C and -5°C in the beam within one year, thus getting the temperature difference 20°C for temperature rise and temperature difference 30°C for temperature fall.
From the previous engineering experience, it can be seen that this loss is obviously underestimated, and it is necessary to take certain measures to give correct correction on this loss.

Shakhaout Hossain4,d 1Assistant Professor, Department of Civil Engineering, Dhaka University of Engineering and Technology, Gazipur-1700, Bangladesh 2Assistant Professor, Department of Civil Engineering, Daffodil International University, Dhaka-1207, Bangladesh 3Assistant Professor, Department of Civil Engineering, Dhaka University of Engineering and Technology, Gazipur-1700, Bangladesh 4Undergraduate Student, Department of Civil Engineering, Dhaka University of Engineering and Technology, Gazipur-1700, Bangladesh E-mails: amkrahma@g.clemson.edu, b*saurav.ce@diu.edu.bd, cpronab_ce@duet.ac.bd dsahadat.tj09@gmail.com *Corresponding author Keywords: Porous asphalt pavement, heavy metal adsorbent, coconut husk, stormwater runoff, attenuation of heavy metals Abstract.
Acknowledgement The authors would like to acknowledge Department of Civil Engineering, Dhaka University of Engineering and Technology (DUET) for providing funds to conduct this research.
Journal of Hydrologic Engineering, 15, 6 (2010), 475-485
International Journal of Civil Engineering and Technology, 8, 4 (2017)
Ecological Engineering, 18, 4, (2002), 407-414

., Křižíkova 682/34a, 186 00 Praha 8, Czech Republic 2Faculty of Civil Eng., Czech Technical University in Prague, Thákurova 7, 166 29 Praha 6, Czech Republic ajan.tichy@skanska.cz, bpavel.ryjacek@fsv.cvut.cz, cvit.smilauer@fsv.cvut.cz, dbohuslav.slansky2@skanska.cz, estanislav.sevcik@skanska.cz Keywords: UHPC, railing panel, GFRP reinforcement bars, fibre concrete.
UHPC (ultra high performance concrete) is used mainly within bridge engineering, due to the demand for subtle but strong material, with high durability against aggressive environment.
The designer of the bridge renovation was a collective team from the Faculty of Civil Engineering, lead by doc.

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Analysis of Slope Instability Based on Strength Reduction Method Xuewei Li1, a, Xin Yuan2, b and Xiaowei Li1, c 1College of Civil Engineering, Panzhihua University, Panzhihua, Sichuan, 617000, China 2College of Civil Engineering, Southeast University, Nanjing, Jiangsu, 210096, China alixuewei6688@163.com, byuanxin9988@163.com, clilixxxwww@126.com Key words: Strength reduction method, Slope instability, Safety coefficient, ABAQUS.
Analysis of Engineering Example Engineering Situation A homogeneous slope is 15m high.
So it meets the engineering application.
Zhao: Chinese Journal of Rock Mechanics and Engineering, Vol. 23 (2004) No.19, P.3381.
Zhang: The Application of ABAQUS in Geotechnical Engineering (China Waterpower Press, Nanjing 2009).