| 1. |
- Crocetti, Roberto, et al.
(författare)
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An Innovative Prefabricated Timber-Concrete Composite System
- 2014
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Ingår i: Materials and Joints in Timber Structures. - Dordrecht : Springer Netherlands. - 2211-0844 .- 2211-0852. - 9789400778108 ; 9, s. 507-516
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Konferensbidrag (refereegranskat)abstract
- A novel type of timber-concrete composite floor, consisting of longitudinal glulam beams with a fibre reinforced concrete (FRC) slab on the top is proposed. In order to check some relevant mechanical properties of such a floor, full-scale laboratory tests along with numerical analyses were carried out. The shear connector system used in the investigation consisted of self-tapping screws driven at an angle of 45 degrees to the grain direction of the glulam beams. The manufacture of the structure occurred according to the following steps: (a) the screws were inserted on the top of the glulam beams; (b) the beams were rotated 180 degrees about the longitudinal axis and placed in a concrete formwork; (c) the FRC was cast into the formwork; (d) after curing of the FRC, the composite floor was again rotated 180 degrees about the longitudinal axis into its right position, i.e. with the FRC slab on the top side. Long term tests and quasi-static bending tests were performed. It was found that the proposed connection system showed a very high degree of composite action both during the long-term testing and at load levels close to the failure load. Furthermore, the assembly of the prefabricated timber-concrete composite system revealed to be very fast and easy.
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| 2. |
- Abrahamsen, Rune, et al.
(författare)
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Dynamic Response of Tall Timber Buildings Under Service Load : The DynaTTB Research Program
- 2020
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Ingår i: EURODYN 2020, XI international conferece on structural dynamics. - : National Technical University of Athens. - 9786188507210 ; , s. 4900-4910
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Konferensbidrag (refereegranskat)abstract
- Wind-induced dynamic excitation is becoming a governing design action determin-ing size and shape of modern Tall Timber Buildings (TTBs). The wind actions generate dynamic loading, causing discomfort or annoyance for occupants due to the perceived horizontal sway – i.e. vibration serviceability failure. Although some TTBs have been instrumented and meas-ured to estimate their key dynamic properties (natural frequencies and damping), no systematic evaluation of dynamic performance pertinent to wind loading has been performed for the new and evolving construction technology used in TTBs. The DynaTTB project, funded by the Forest Value research program, mixes on site measurements on existing buildings excited by heavy shakers, for identification of the structural system, with laboratory identification of building elements mechanical features coupled with numerical modelling of timber structures. The goal is to identify and quantify the causes of vibration energy dissipation in modern TTBs and pro-vide key elements to FE modelers.The first building, from a list of 8, was modelled and tested at full scale in December 2019. Some results are presented in this paper. Four other buildings will be modelled and tested in spring 2020.
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| 3. |
- Abrahamsen, Rune, et al.
(författare)
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Dynamic response of tall timber buildings under service load : results from the dynattb research program
- 2023
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Ingår i: World Conference on Timber Engineering 2023 (WCTE 2023). - : Curran Associates, Inc.. - 9781713873297 ; , s. 2907-2914
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Konferensbidrag (refereegranskat)abstract
- Wind-induced dynamic excitation is a governing design action determining size and shape of modern Tall Timber Buildings (TTBs). The wind actions generate dynamic loading, causing discomfort or annoyance for occupants due to the perceived horizontal sway, i.e. vibration serviceability problem. Although some TTBs have been instrumented and measured to estimate their key dynamic properties (eigenfrequencies, mode shapes and damping), no systematic evaluation of dynamic performance pertinent to wind loading had been performed for the new and evolving construction technologies used in TTBs. The DynaTTB project, funded by the ForestValue research program, mixed on site measurements on existing buildings excited by mass inertia shakers (forced vibration) and/or the wind loads (ambient vibration), for identification of the structural system, with laboratory identification of building elements mechanical features, coupled with numerical modelling of timber structures. The goal is to identify and quantify the causes of vibration energy dissipation in modern TTBs and provide key elements to finite element models. This paper presents an overview of the results of the project and the proposed Guidelines for design of TTBs in relation to their dynamic properties.
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| 4. |
- Al-Emrani, Mohammad, 1967, et al.
(författare)
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Strengthening Glulam Beams with Steel and Composite Plates
- 2009
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Ingår i: Proceedings of the 7th International Conference on Composite Science and Technology, Sharjah, UAE.
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Konferensbidrag (refereegranskat)abstract
- The stiffness requirements in the design of timber beams in serviceability limit state is a factor that often makes it necessary to increase the beam dimensions beyond what is required for strength. This causes increased material use and thus higher production costs. This study is an effort to investigate the viability of using Steel and CFRP (carbon fibre reinforced polymers) as reinforcement in new glulam beams. By gluing CFRP to the tension side of the beam it is possible to move the fracture from tensile rupture to the compression side of the beam which is beneficiary due to the more ductile behaviour of wood in compression. In the experimental part of the investigation, nine glulam beams strengthened with bonded steel and CFRP-laminates were tested to failure. The effect of various geometrical properties for the laminates was investigated, as well as strengthening with different amounts of laminates on the tension and compression side.
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| 5. |
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| 6. |
- Bergenudd, Jens, et al.
(författare)
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Dynamic analysis of a pedestrian timber truss bridge at three construction stages
- 2024
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Ingår i: Structures. - : Elsevier BV. - 2352-0124. ; 59
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Tidskriftsartikel (refereegranskat)abstract
- This article investigates the dynamic behaviour of a single span pedestrian timber truss bridge by in situ testing and numerical modelling. The in situ dynamic tests were performed at three different construction stages: (1) on only the truss structure, (2) on the finished bridge without the asphalt layer and (3) on the finished bridge with the asphalt layer. The objective is to better understand how the different parts of the bridge contribute to the overall dynamic properties. The experimental results show that the damping ratios increased significantly for the first lateral mode (from 1.0 to 3.8%) and the first torsional mode (from 1.2 to 3.5%) between stage 2 and stage 3 due to the asphalt layer. The damping ratio is around 1.6% for the first bending mode for the finished bridge. The experimental and numerical results indicate that the stiffness of the asphalt layer is important to consider at stage 3 (10 degrees C) for the first lateral and torsional mode, but not for the first bending mode. Finally, it was concluded that longitudinal springs must be applied at the pot bearings in order to get agreement with the experimental results at all the three stages.
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| 7. |
- Bergenudd, Jens
(författare)
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Dynamic properties of two pedestrian timber bridges : Experimental and numerical analysis at several stages of construction
- 2023
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Licentiatavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Pedestrian bridges can beneficially be made from timber in order for our society to reach a sustainable future. This positive development is partly made possible due to advances in engineered wood products (e.g. glued laminated timber) and the possibilities for pre-fabrication of structural parts. Timber bridges, especially long and slender, can however be susceptible to uncomfortable vibrations which could be solved by more accurate dynamic analysis in the design phase. Common issues reported by previous research are the difficulties in accurate predictions of the natural frequencies without calibration against experimental results. The purpose with the present research work is therefore to perform dynamic analysis of two pedestrian timber bridges at different construction stages in order to better understand the influence of different structural parts in the numerical models. The results show that the estimated and applied values for the densities of the timber (Norway spruce and Scots pine) are slightly higher than in the norm. Both bridges required calibration of longitudinal stiffness at the supports for the numerical results to agree with the experiments. The railings could be omitted from the numerical models for both bridges, which is in contrast with common engineering practise where they are often considered as an additional mass. The stiffness of the asphalt was required at low temperatures (10 °C and 0 °C). However, the asphalt could be modelled as an additional mass at a high temperature (40 °C) where special care also could be given to the effects of the composite cross-section geometry (timber deck and asphalt). The level of detail for the modelling of the truss joints, the connection truss/crossbeam and the connection deck/crossbeams proved to be an important issue for the Stela bridge. The damping ratios (ζ) increased with an asphalt layer on the bridge and are slightly higher than the values recommended by the norms. This may be relevant to consider in the design phase. However, it may be difficult to derive general conclusions for other pedestrian timber bridges since this thesis only concerns case studies of two bridges. More studies of other types of bridges are therefore necessary in order to confirm or disprove the present results
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| 8. |
- Bergenudd, Jens, et al.
(författare)
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Dynamic testing and numerical modelling of a pedestrian timber bridge at different construction stages
- 2023
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Ingår i: Engineering structures. - : Elsevier BV. - 0141-0296 .- 1873-7323. ; 279
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Tidskriftsartikel (refereegranskat)abstract
- This article studies the dynamic properties of a single span pedestrian timber bridge by in-situ testing and numerical modelling. The in-situ dynamic tests are performed at four different construction stages: (1) on only the timber structure, (2) on the timber structure with the railings, (3) on the timber structure with railings and an asphalt layer during warm conditions and (4) same as stage 3 but during cold conditions. Finite element models for the four construction stages are thereafter implemented and calibrated against the experimental results. The purpose of the study is to better understand how the different parts of the bridge contribute to the overall dynamic properties. The finite element analysis at stage 1 shows that longitudinal springs must be introduced at the supports of the bridge to get accurate results. The experimental results at stage 2 show that the railings contributes to 10% of both the stiffness and mass of the bridge. A shell model of the railings is implemented and calibrated in order to fit with the experimental results. The resonance frequencies decrease with 10–20% at stage 3 compared to stage 2. At stage 3 it is sufficient to introduce the asphalt as an additional mass in the finite element model. For that, a shell layer with surface elements is the best approach. The resonance frequencies increase with 15–30% between warm (stage 3) and cold conditions (stage 4). The stiffness of the asphalt therefore needs to be considered at stage 4. The continuity of the asphalt layer could also increase the overall stiffness of the bridge. The damping ratios increase at all construction stages. They are around 2% at warm conditions and around 2.5% at cold conditions for the finished bridge.
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| 9. |
- Bergenudd, Jens, et al.
(författare)
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Study of the dynamic response of a timber pedestrian bridge during different construction stages
- 2022
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Ingår i: Conference Proceedings 4th ICTB (2022) ,ICTB 2021 PLUS 4th International Conference on Timber Bridges. - Biel/Bienne, Switzerland. ; , s. 167-178
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Konferensbidrag (övrigt vetenskapligt/konstnärligt)abstract
- The objective of this article is to study the dynamic behaviour of a timber pedestrian bridge by performing in-situ tests at four different construction stages: 1) on only the timber structure 2) on the timber structure with the railings 3) on the timber structure with railings and an asphalt layer during warm conditions and 4) same as stage 3 but during cold conditions. The study included numerical calculations with a 2D finite element model. Two modal parameter extraction methods were implemented during the post-processing. The modes of vibration were analysed with the modal assurance criterion (MAC) to ensure their validity. The results show that the presence of the railings during stage 2 increases the resonance frequencies with 0-2 % compared to stage 1, despite an approximately 5 % increase of the total mass of the bridge. The vertical resonance frequencies decreased 12-22 % when the asphalt was installed at stage 3 compared to stage 2, due to an approximately 70 % increase of the total mass and the asphalt’s low stiffness due to a high temperature. The resonance frequencies increased 14-27 % during cold conditions at stage 4 compared to stage 3. This was mainly due to an increased stiffness of the asphalt layer due to a low temperature. Adding railings therefore resulted in a higher overall stiffness of the bridge, whereas asphalt essentially only added mass to the bridge at warm conditions but increased the stiffness at cold compared to warm conditions. The damping ratios increased for each construction stage and were approximately 2-3 % for the finished bridge. The two modal parameter extraction methods produced similar results which ensures that reliable results are obtained. The auto-MAC indicated well-separated modes and the cross-MAC ensured comparison of the same modes. The finite element model showed that some stiffness was lacking for the first bending mode. This stiffness could be due to shear deformation of the plastic pads at the bridge supports.
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