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Projects / Programmes source: ARIS

Mehanika konstrukcij (Slovene)

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Periods
January 1, 2009 - December 31, 2014
Research activity

Code Science Field Subfield
2.05.00  Engineering sciences and technologies  Mechanics   
2.01.00  Engineering sciences and technologies  Civil engineering   

Code Science Field
T220  Technological sciences  Civil engineering, hydraulic engineering, offshore technology, soil mechanics 
T210  Technological sciences  Mechanical engineering, hydraulics, vacuum technology, vibration and acoustic engineering 

Code Science Field
2.01  Engineering and Technology  Civil engineering 
Evaluation (rules)
source: COBISS
Evaluation of bibliographic research performance indicators according to ARIS methodology
Citations Citations for bibliographic records in COBIB.SI that are linked to records in citation databases
source: WoS source: Scopus source: COBISS
Researchers (22)
no. Code Name and surname Research area Role Period No. of publications
1.  33102  PhD Urška Bajc  Civil engineering  Junior researcher  2010 - 2014 
2.  20157  PhD Bojan Čas  Civil engineering  Researcher  2009 - 2013 
3.  30809  PhD Peter Češarek  Civil engineering  Researcher  2009 - 2014 
4.  33293  PhD Jerneja Češarek Kolšek  Civil engineering  Technical associate  2012 
5.  16142  PhD Rado Flajs  Civil engineering  Researcher  2009 - 2014 
6.  25423  PhD Tomaž Hozjan  Civil engineering  Researcher  2009 - 2014 
7.  30509  PhD Anka Ilc  Mechanics  Technical associate  2012 
8.  34257  Miha Jakšič    Technical associate  2011 - 2013 
9.  29320  PhD Aleš Kroflič  Civil engineering  Researcher  2009 - 2013 
10.  28340  Mojca Markovič  Civil engineering  Junior researcher  2009 - 2013 
11.  36444  PhD Anita Ogrin  Civil engineering  Junior researcher  2013 - 2014 
12.  34368  PhD Robert Pečenko  Mechanics  Junior researcher  2011 - 2014 
13.  32030  PhD Klara Pirmanšek  Civil engineering  Junior researcher  2009 - 2014 
14.  14507  PhD Igor Planinc  Civil engineering  Researcher  2009 - 2014 
15.  28380  PhD Urban Rodman  Civil engineering  Researcher  2009 
16.  02189  PhD Miran Saje  Civil engineering  Head  2009 - 2014 
17.  23474  PhD Simon Schnabl  Civil engineering  Researcher  2009 - 2014 
18.  09217  PhD Stanislav Srpčič  Civil engineering  Researcher  2009 - 2014 
19.  27666  PhD Gregor Trtnik  Civil engineering  Junior researcher in economics  2009 
20.  08437  PhD Goran Turk  Civil engineering  Researcher  2009 - 2014 
21.  19121  PhD Dejan Zupan  Civil engineering  Researcher  2009 - 2014 
22.  27673  PhD Eva Zupan  Mechanics  Researcher  2010 - 2014 
Organisations (1)
no. Code Research organisation City Registration number No. of publications
1.  0792  University of Ljubljana, Faculty of Civil and Geodetic Engineering  Ljubljana  1626981 
Significance for science
• The achievements of the research group regarding new numerical formulations of geometrically exact beams are now very well recognized and well cited in international community. There are 6 formulations of ours. The first one (Jelenić & Saje 1995) uses PVW in conjunction with the variation of rotational vector interpolation; the second one makes only bending strains with respect to the fixed coordinate system to be interpolated (Zupan & Saje 2003); the third one is a pure strain-based formulation using the collocation method where the consistency condition is satisfied in a strong way (Zupan & Saje 2003); the fourth formulation is the collocation-quaternion-based one, where the displacements and quaternions are interpolated (Zupan E., Zupan & Saje 2009); the fifth formulation is the strain-based but specific in having constant strain interpolation (Češarek, Zupan & Saje 2012); the sixth formulation again employs quaternions, yet this time they are combined with the PVW (E. Zupan, Saje & Zupan 2013). Some of the above formulations are also extended to dynamics (2012-2013) and/or non-linear materials like steel, concrete, reinforced concrete and wood. •The majority of citations of the present research programme come from our research in composite structures. There are 9 papers in which we propose the foundations of the geometrically and materially linear and non-linear theories of layered structures, where tangent slip as well as normal uplift are considered and presented in Steel & Compos. Struct. 2004, Comput. & Struct. 2004, 2011, 2013, J. Struct. Eng. 2007, Struct. Eng. & Mech. 2006, 2010, and Eng. Struct. 2010. The theories have extensively been applied in stability analyses of composite columns at room temperature and in fire. Some studies were focused also on stability of partially delaminated spatial beams. The results of these analyses were presented in 9 journal papers. One of the papers, namely "The influence of boundary conditions and axial deformability on buckling behaviour of two-layer composite columns with interlayer slip" (Schnabl & Planinc, Eng. Struct. 2010) was commented by the anonymous reviewer as "The reviewer would like to remark that this paper is the best he has reviewed since long time, and of great importance for researchers working in the field of composite structural members with interlayer slip". • The fire analysis has become highly popular recently. During the last 10 years or so we have proposed various numerical formulations for estimating behaviour of concrete, steel and timber structures in fire. We have developed some sophisticated numerical tools for thermal and mechanical analyses, and performed parametric analyses to assess and understand the response of particular structures in fire. Transport of moisture, vapour and air in concrete (or timber) during fire is modelled as a coupled non-stationary process. The temperature and pressure fields were taken as applied loads in the subsequent mechanical calculations. The mechanical model assumes the geometrically and materially non-linear beam where the criterion of the local critical state and the subsequent strain localization are described in the paper "On strain softening in finite element analysis of RC planar frames subjected to fire" (Markovič, Saje, Planinc & Bratina, Eng. Struct. 2012). • One of our highest achievements is the invention of the ultrasonic apparatus in conjunction with the artificial neuron networks for predicting the concrete strength and the onset of concrete hardening, presented in seven papers in top journals. We only mention one of them, "Prediction of concrete strength using ultrasonic pulse velocity and artificial neural networks" (Trtnik, Kavčič & Turk, Ultrasonics 2009).
Significance for the country
• Many commercial computer programmes for the structural analysis are available and one may get an impression that the development of further new software in engineering mechanics is not needed. Life does not prove that. A part of the problem seems to be an insufficient theoretical knowledge that engineers presently posess, which is probably due to inappropriate university curricula in Slovenia. The limited possibilities of solving practical problems, if using commercial programmes, appear when non-linear analyses of structures subject to non-standard loads (like collision of two structures, the response to an earthquake or wind, structural behaviour in fire, effects of fluids on structures) must be performed, or searching for the reasons for collapse and identifying non-linear parameters of a structure, is carried out. These examples require accurate and reliable numerical formulations adapted to the speciality of the problem, and the use of the non-commercial programmes gets sense. This is exactly the case here, where slip and localization issues in fire analyses must be well accounted for. One particularly important type of structure that is vulnerable to fire is the highway tunnel structure, where the prediction of its mechanical safety to fire must be highly accurate and strictly conservative. • Concrete plays a very important role in construction engineering of Slovenia. Here the technology of placing large concrete volumes (like in concrete water dams or bridge column foundations) or of prefabricated concrete elements must be designed such to increase the quality of the product and the decrease of its price. Such a technology requires the knowledge of the behaviour of concrete during early hardening stage. The ultrasonic methods of measuring being a part of the programme definitely help to meet these goals. • In terms of the relative forest cover, Slovenia is one of the first countries in the European Union. It is almost unbelievable that the use of timber in construction is relatively limited. In the view of sustainable development which has to be one of the Slovenian priorities, the use of timber as a structural material is important. The results of this research will increase the added value to the timber as building material. At the time being, the timber obtained from Slovenian forests is exported into other countries where it is properly graded and labelled and imported back to Slovenia as a graded and labelled structural timber, yet at a considerably higher price. Slovenian industry should be capable to perform grading and labelling by itself. We strongly believe that the present activities of the research group regarding the timber strength grading will have an important economical effect in future.
Most important scientific results Annual report 2009, 2010, 2011, 2012, 2013, final report, complete report on dLib.si
Most important socioeconomically and culturally relevant results Annual report 2009, 2010, 2011, 2012, 2013, final report, complete report on dLib.si
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