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Tapia Camú, Cristóbal

Cristóbal Tapia Camú

Dr.-Ing.

Head of Unit
Materials Testing Institute
Timber Structures

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+49 711 685 62931
Email

Pfaffenwaldring 4b
70569 Stuttgart

Publications

C. Tapia Camú, H. J. Wagner, S. Treml, A. Menges, and S. Aicher, “Point-Support Reinforcement for a Highly Efficient Timber Hollow Core Slab System,” in World Conference on Timber Engineering (WCTE 2023), in World Conference on Timber Engineering (WCTE 2023). Oslo, Norway, 2023, pp. 2978–2986. doi: 10.52202/069179-0388.
- BibTeX
BibTeX
@conference{tapia2023pointsupport, address = {Oslo, Norway}, author = {Tapia Camú, Cristóbal and Wagner, Hans Jakob and Treml, Simon and Menges, Achim and Aicher, Simon}, booktitle = {World Conference on Timber Engineering (WCTE 2023)}, doi = {10.52202/069179-0388}, pages = {2978-2986}, title = {Point-Support Reinforcement for a Highly Efficient Timber Hollow Core Slab System}, year = 2023 }
T. Camú. Cristóbal, F. Amtsberg, A. Münzer, S. Aicher, and A. Menges, “Rotational Stiffness of Newly Developed LVL-based Column-Head Reinforcement for Point-Supported Slab-Column Building Systems,” in World Conference on Timber Engineering (WCTE 2023), in World Conference on Timber Engineering (WCTE 2023). Oslo, Norway, 2023, pp. 688–697. doi: 10.52202/069179-0094.
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@conference{cristobal2023rotational, address = {Oslo, Norway}, author = {Cristóbal, Tapia Camú. and Amtsberg, Felix and Münzer, Aaron and Aicher, Simon and Menges, Achim}, booktitle = {World Conference on Timber Engineering (WCTE 2023)}, doi = {10.52202/069179-0094}, pages = {688-697}, title = {Rotational Stiffness of Newly Developed LVL-based Column-Head Reinforcement for Point-Supported Slab-Column Building Systems}, year = 2023 }
C. Tapia and S. Aicher, “A new concept for column-to-column connections for multi-storey timber buildings — Numerical and experimental investigations,” Engineering Structures, vol. 295, p. 116770, 2023, doi: https://doi.org/10.1016/j.engstruct.2023.116770.
- BibTeX
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BibTeX
@article{Tapia_2023, abstract = {A new jointing concept for the vertical load transfer between glued laminated timber (GLT) columns in multi-storey timber buildings has been developed. The basic components of the connection are two stepped, pyramid-shaped inserts made from block-glued laminated veneer lumber (LVL), which are bonded oppositely into corresponding cavities of the jointed GLTs. The load transfer between the mating columns relies on an intermediate LVL pin, fitting into pyramid-type cavities. Beech LVL was chosen for both, insert and pin, due to its 2.2 times higher characteristic compressive strength as compared to the employed high-strength softwood GLT (GL32h). The form fit of the stepped components which are bonded together relies on high precision robotic milling and a gap-filling two-component polyurethane adhesive. Manufacturing and mechanical performance of the scalable connection was investigated with full-sized specimens, achieving up to 90% of the characteristic GLT compressive capacity of 1040kN for a cross-section of 180mm×180mm. A parametric model based on the finite element method (FEM) showed a good agreement with empiric strain distributions and provided a stress-spread angle of 35° for the concentrated vertical load for an analytical design approach. The location and magnitude of tensile stresses perpendicular to the grain causing splitting failure was identified by FEM. Reinforcement by self-tapping screws proved a significant load-capacity enhancement. The mean experimental axial compressive load capacity exceeded the analytical prediction by 19%. First investigations on the rotational stiffness delivered a value of 240kNm/rad. The column utilization due to additional directly supported floor slabs was assessed exclusively by FEM. The calculation results predict a significant reduction of the tensile stresses perpendicular to the grain to be verified experimentally.}, author = {Tapia, Cristóbal and Aicher, Simon}, doi = {https://doi.org/10.1016/j.engstruct.2023.116770}, issn = {0141-0296}, journal = {Engineering Structures}, pages = 116770, title = {A new concept for column-to-column connections for multi-storey timber buildings — Numerical and experimental investigations}, url = {https://www.sciencedirect.com/science/article/pii/S0141029623011859}, volume = 295, year = 2023 }
Link
https://www.sciencedirect.com/science/article/pii/S0141029623011859
C. Tapia and S. Aicher, “Survival Analysis of Tensile Strength Variation and Simulated Length-Size Effect along Oak Boards,” Journal of engineering mechanics, vol. 148, no. 1, Art. no. 1, 2022, doi: 10.1061/(ASCE)EM.1943-7889.0002006.
- BibTeX
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@article{tapiacamu2022survival, affiliation = {Tapia, C (Corresponding Author), Univ Stuttgart, Mat Testing Inst, Pfaffenwaldring 4b, D-70569 Stuttgart, Germany. Tapia, Cristobal; Aicher, Simon, Univ Stuttgart, Mat Testing Inst, Pfaffenwaldring 4b, D-70569 Stuttgart, Germany.}, author = {Tapia, Cristóbal and Aicher, Simon}, doi = {10.1061/(ASCE)EM.1943-7889.0002006}, issn = {{0733-9399} and {1943-7889}}, journal = {Journal of engineering mechanics}, language = {eng}, number = 1, pages = 04021130, publisher = {American Society of Civil Engineers}, research-areas = {Engineering}, title = {Survival Analysis of Tensile Strength Variation and Simulated Length-Size Effect along Oak Boards}, unique-id = {WOS:000719533400017}, volume = 148, year = 2022 }
C. Tapia Camú, “Variation of mechanical properties in oak boards and its effect on glued laminated timber : Application to a stochastic finite element glulam strength model,” Cuvillier Verlag, Göttingen, 2022. doi: 10.18419/OPUS-12111.
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@phdthesis{https://doi.org/10.18419/opus-12111, abstract = {The renewable material wood and hereof derived structural engineered wood products (EWPs) is widely acknowledged as being the major pillar of sustainable building construction. Due to the strongly increasing demand and technical assets the wood resource hardwoods, previously less used as compared to softwoods, is gaining a high momentum for EWPs. Here, the species white oak (Quercus robur, petraea) representing beside beech (Fagus sylvatica) the largest hardwood stocks in Europe is investigated. This work addresses the need of improved understanding and modeling of the variability of stiffness and strength along and between boards and the resulting impact on the size-effect of glued laminated timber (GLT) made of oak. A set of 53 oak boards (Quercus robur) was used to study the variation of mechanical properties along the board's main axis. For each board, detailed information regarding size and position of knots was obtained, which was then used to digitally reproduce the geometry of the knots. The modulus of elasticity (MOE) parallel to the fiber was measured in tension along each board in 15 consecutive segments of 100 mm in length. The boards were tested in tension until failure and the remnants were then tested in secondary tension tests, when possible. Thus, multiple values for tensile strength were obtained per board. Based on the MOE results, a first order autoregressive [AR(1)] model for the simulation of local MOE profiles within board was developed. The model considers the non-stationarity of the MOE profiles by means of a two step method. Firstly, a Gaussian AR process is conducted and then mapped to the normalized MOE distribution. In a second step, the result in scaled to fit a specified global MOE value. The tensile strength data was analyzed by means of survival analysis, where different parametric and regression type statistical models were fitted. The tensile strength models were coupled to the localized MOE AR(1) model by means of a cross-correlation coefficient, thus obtaining a modified vector autoregressive (VAR) model for the local MOE and tensile strength along board. Numerical simulations with the fitted tensile strength models predicted a relatively high size effect, i.e. length effect, characterized by a size-effect exponent of around 0.23 at the 5%-quantile level. A stochastic finite element model for the analysis of GLT beams was developed. The model considers the local variation of mechanical properties within each lamination, simulated by the derived VAR model, as well as the stochastic distribution of finger-joints connecting adjacent boards. A simple energy-based failure mechanism is considered for the evolution of tensile damage in wood and finger-joint elements. The model was calibrated with experiments of oak GLT beams of three different cross-sections tested at the MPA, University of Stuttgart, and then applied to simulate a second database of oak GLT beams tested at FCBA, France. The results obtained with the model are in good agreement with the experiments. In particular, the size effect of beam depth is correctly represented. The influence of the used material models for wood and finger-joints was analyzed parametrically. It is shown that the lower tail of the local tensile strength distribution, which can be estimated rather accurately by survival analysis dominates the GLT bending strength. This is fortunate, as the lower tails can be estimated by means of survival analysis in a rather accurate manner, while the upper tails require further assumptions. The author hopes that the presented work contributes to stimulate the discussion on modelling of structural timber elements made of hardwoods.}, address = {Göttingen}, author = {Tapia Camú, Cristóbal}, copyright = {info:eu-repo/semantics/openAccess}, doi = {10.18419/OPUS-12111}, isbn = {978-3-7369-6588-1}, language = {en}, publisher = {Cuvillier Verlag}, school = {University of Stuttgart}, title = {Variation of mechanical properties in oak boards and its effect on glued laminated timber : Application to a stochastic finite element glulam strength model}, year = 2022 }
C. Tapia and S. Aicher, “Size effect of glulam made of oak wood under consideration of the finite weakest link theory,” in International Network on Timber Engineering Research --- Meeting 55, in International Network on Timber Engineering Research --- Meeting 55. Bad Aibling, Germany: Timber Scientific Publishing, 2022, pp. 245--262.
- BibTeX
BibTeX
@inproceedings{Tapia_2022b, address = {Bad Aibling, Germany}, author = {Tapia, Cristóbal and Aicher, Simon}, booktitle = {International Network on Timber Engineering Research --- Meeting 55}, pages = {245--262}, publisher = {Timber Scientific Publishing}, title = {Size effect of glulam made of oak wood under consideration of the finite weakest link theory}, year = 2022 }
C. Tapia, M. Claus, and S. Aicher, “A finger-joint based edge connection for the weak direction of CLT plates,” Construction and Building Materials, vol. 340, p. 127645, 2022, doi: 10.1016/j.conbuildmat.2022.127645.
- BibTeX
- Link
BibTeX
@article{Tapia_2022, abstract = {A new connection concept for joining cross-laminated timber (CLT) plates in their secondary direction is presented. The connection consists of two laminated veneer lumber (LVL) gusset plates with finger-joint-like profiles milled on one side which are glued onto the outermost layers of the CLT. It is demonstrated that the joint represents a stiff moment resistant connection, enabling the activation of the normally underutilized biaxiality of CLT plates and expanding the design freedom of architects and engineers. The concept was analyzed by means of analytical and finite element (FE) models for two geometry alternatives, differing in either a 2D or 3D tapered finger profile. The 3D tapered finger profile produced a stress reduction of around 5% in the region of stress concentration and a more even shear stress distribution on the bonded surface. Thereafter, four specimens were manufactured – two of each geometry alternative – and then tested in four- and three-point bending setups in order to assess the behavior at pure bending as well as at combined moment and shear loading, respectively. At pure bending, the studied connection delivered bending capacities of 100% of the characteristic value of the unjointed CLT material. For the case of moment and shear loading, the global capacity was determined by a bending failure in the CLT region subjected to maximum moment, while the joints remained unbroken. Measured deformations and strains during the tests validated the FE model, which can be used to further develop the connection concept, which allows for a full activation of the biaxial behavior of large-span CLT floors.}, author = {Tapia, Cristóbal and Claus, Marian and Aicher, Simon}, doi = {10.1016/j.conbuildmat.2022.127645}, issn = {0950-0618}, journal = {Construction and Building Materials}, pages = 127645, title = {A finger-joint based edge connection for the weak direction of CLT plates}, url = {https://www.sciencedirect.com/science/article/pii/S0950061822013204}, volume = 340, year = 2022 }
Link
https://www.sciencedirect.com/science/article/pii/S0950061822013204
C. Tapia, L. Stimpfle, and S. Aicher, “A scalable column-CLT-slab connection for open-plan high-rise timber buildings,” in Proceedings of WCTE 2021 - World Conference on Timber Engineering, in Proceedings of WCTE 2021 - World Conference on Timber Engineering. Santiago, Chile, 2021.
- BibTeX
BibTeX
@inproceedings{tapia_2021, abstract = {It is reported on first results regrading a novel column-to-slab connection suited for multi-storey timberbuildings. The emphasis is on the development of a new constructive solution for a scalable, bespoken connection type,which enables to overcome today’s rigid rectangular floor grid restrictions, thus enabling open-plan and flexible spacearchitecture. The paper firstly reveals some of the recent developments of column-to-slab solutions in engineered timberconstruction. Then the constructive detailing, the finite element based modelling and some test results of a bondedconnection, manufactured exclusively out of wood, are presented. The novel solution is based on specific orthogonallylayered and stepped inserts, based on laminated veneer lumber (LVL) from beech wood, which are bonded into preciselyfitting cavities in the CLT. The connection was developed within the frame of the Science Cluster of Excellence IntCDC(Integrated Computational Design and Construction for Architecture), allocated at the University of Stuttgart. }, address = {Santiago, Chile}, author = {Tapia, Cristóbal and Stimpfle, Lisa and Aicher, Simon}, booktitle = {Proceedings of WCTE 2021 - World Conference on Timber Engineering}, eventtitle = {World Conference on Timber Engineering}, title = {A scalable column-CLT-slab connection for open-plan high-rise timber buildings}, year = 2021 }
C. Tapia and S. Aicher, “Simulation of the Localized Modulus of Elasticity of Hardwood Boards by Means of an Autoregressive Model,” Journal of materials in civil engineering, vol. 33, no. 6, Art. no. 6, 2021, doi: 10.1061/(ASCE)MT.1943-5533.0003696.
- BibTeX
BibTeX
@article{tapiacamu2021simulation, affiliation = {Tapia, C (Corresponding Author), Univ Stuttgart, Mat Testing Inst, Pfaffenwaldring 4b, D-70569 Stuttgart, Germany. Tapia, Cristobal; Aicher, Simon, Univ Stuttgart, Mat Testing Inst, Pfaffenwaldring 4b, D-70569 Stuttgart, Germany.}, author = {Tapia, Cristóbal and Aicher, Simon}, doi = {10.1061/(ASCE)MT.1943-5533.0003696}, issn = {{0899-1561} and {1943-5533}}, journal = {Journal of materials in civil engineering}, language = {eng}, number = 6, pages = 04021132, publisher = {American Society of Civil Engineers}, research-areas = {Construction & Building Technology; Engineering; Materials Science}, title = {Simulation of the Localized Modulus of Elasticity of Hardwood Boards by Means of an Autoregressive Model}, unique-id = {ISI:000648591400019}, volume = 33, year = 2021 }
M. Claus, C. Tapia, and S. Aicher, “Bond line characteristics of new edge connections of cross-laminated timber in the weak direction based on milled profiled connection plates from laminated veneer lumber made of beech,” Otto Graf Journal, vol. 20, pp. 39--60, 2021.
- BibTeX
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@article{Claus_2021, author = {Claus, Marian and Tapia, Cristóbal and Aicher, Simon}, editor = {Garrecht, H. and Reinhardt, H. W. and Mielich, O.}, journal = {Otto Graf Journal}, location = {Stuttgart, Germany}, pages = {39--60}, publisher = {Otto-Graf-Institute (FMPA), University of Stuttgart}, title = {Bond line characteristics of new edge connections of cross-laminated timber in the weak direction based on milled profiled connection plates from laminated veneer lumber made of beech}, volume = 20, year = 2021 }
C. Tapia, L. Stimpfle, and S. Aicher, “A new column-to-slab connection for multi-storey timber buildings,” Otto Graf Journal, vol. 19, pp. 297--317, 2020.
- BibTeX
BibTeX
@article{Tapia_2020, abstract = {It is reported on first results regrading a novel column-to-slab connection suited for multi-storey timber buildings. The emphasis is on the development of a new constructive solution for a scalable, bespoken connection type, which enables to overcome today's rigid rectangular floor grid restrictions, thus enabling open-plan and flexible space architecture. The paper firstly reveals some of the recent developments of column-to-slab solutions in engineered timber construction. Then the constructive detailing, the finite element based modelling and some test results of a bonded connection, manufactured exclusively out of wood, are presented. The novel solution is based on specific orthogonally layered and stepped inserts, based on laminated veneer lumber (LVL) from beech wood, which are bonded into precisely fitting cavities in the CLT. The connection enables a multidirectional load transfer, being a prime requisite to enable biaxial plate action of the CLT elements, which span today almost exclusively uniaxially in their strong direction. The detailing and foremost the manufacture of the developed connection relies essentially on high precision CNC milling, which plays a key role in advanced timber connection solutions. This is especially true for the case of bonded connections which require very small tolerances. The novel connection was developed within the frame of the Science Cluster of Excellence IntCDC (Integrated Computational Design and Construction for Architecture), allocated at the University of Stuttgart.}, author = {Tapia, Cristobal and Stimpfle, Lisa and Aicher, Simon}, editor = {Garrecht, H. and Reinhardt, H. W. and Mielich, O.}, issn = {0938-409X}, journal = {Otto Graf Journal}, location = {Stuttgart, Germany}, pages = {297--317}, publisher = {Otto-Graf-Institute (FMPA), University of Stuttgart}, title = {A new column-to-slab connection for multi-storey timber buildings}, volume = 19, year = 2020 }
C. Tapia and S. Aicher, “Evaluation of design concepts for holes in glulam --- Comparison with test results,” Otto-Graf-Journal, vol. 18, pp. 329--344, 2019.
- BibTeX
BibTeX
@article{Tapia2019b, author = {Tapia, C. and Aicher, S.}, journal = {Otto-Graf-Journal}, pages = {329--344}, title = {Evaluation of design concepts for holes in glulam --- Comparison with test results}, volume = 18, year = 2019 }
C. Tapia and S. Aicher, “Variation and serial correlation of modulus of elasticity between and within European oak boards (Quercus robur and Q. petraea),” Holzforschung, vol. 74, no. 1, Art. no. 1, 2019, doi: 10.1515/hf-2019-0038.
- BibTeX
- Link
BibTeX
@article{Tapia_2019, author = {Tapia, Cristóbal and Aicher, Simon}, doi = {10.1515/hf-2019-0038}, journal = {Holzforschung}, number = 1, pages = {33--46}, publisher = {Walter de Gruyter {GmbH}}, title = {Variation and serial correlation of modulus of elasticity between and within European oak boards (Quercus robur and Q. petraea)}, url = {https://doi.org/10.1515%2Fhf-2019-0038}, volume = 74, year = 2019 }
Link
https://doi.org/10.1515%2Fhf-2019-0038
S. Aicher and C. Tapia, “Novel internally LVL-reinforced glued laminated timber beams with large holes,” Construction and Building Materials, vol. 169, pp. 662--677, 2018, doi: https://doi.org/10.1016/j.conbuildmat.2018.02.178.
- BibTeX
- Link
BibTeX
@article{Aicher2018, author = {Aicher, Simon and Tapia, Cristóbal}, doi = {https://doi.org/10.1016/j.conbuildmat.2018.02.178}, issn = {0950-0618}, journal = {Construction and Building Materials}, keyword = {Novel timber composite, Glued laminated timber (GLT), Laminated veneer lumber (LVL), Internal LVL reinforcement, Large rectangular holes, Stress redistribution, Damage tolerance}, pages = {662--677}, title = {Novel internally LVL-reinforced glued laminated timber beams with large holes}, url = {http://www.sciencedirect.com/science/article/pii/S0950061818304276}, volume = 169, year = 2018 }
Link
http://www.sciencedirect.com/science/article/pii/S0950061818304276
C. Tapia and S. Aicher, “Modelling the variation of mechanical properties along oak boards,” in International Network on Timber Engineering Research --- Meeting 51, in International Network on Timber Engineering Research --- Meeting 51. Tallin, Estland, 2018.
- BibTeX
BibTeX
@inproceedings{Tapia2018b, address = {Tallin, Estland}, author = {Tapia, Cristóbal and Aicher, Simon}, booktitle = {International Network on Timber Engineering Research --- Meeting 51}, title = {Modelling the variation of mechanical properties along oak boards}, year = 2018 }
C. Tapia and S. Aicher, “A Novel LVL-Based Internal Reinforcement for Holes in Glulam Beams,” in CD-ROM Proceedings of the World Conference on Timber Engineering (WCTE 2018), in CD-ROM Proceedings of the World Conference on Timber Engineering (WCTE 2018). Seoul, Republic of Korea: WCTE, 2018.
- BibTeX
BibTeX
@inproceedings{Tapia2018a, address = {Seoul, Republic of Korea}, author = {Tapia, Cristóbal and Aicher, Simon}, booktitle = {CD-ROM Proceedings of the World Conference on Timber Engineering (WCTE 2018)}, publisher = {WCTE}, title = {A Novel LVL-Based Internal Reinforcement for Holes in Glulam Beams}, year = 2018 }
C. Tapia and S. Aicher, “Improved Design Equations for the Resultant Tensile Forces in Glulam Beams with Holes,” in International Network on Timber Engineering Research --- Meeting 50, in International Network on Timber Engineering Research --- Meeting 50. Kyoto, Japan, 2017.
- BibTeX
BibTeX
@inproceedings{Tapia2017a, address = {Kyoto, Japan}, author = {Tapia, Cristóbal and Aicher, Simon}, booktitle = {International Network on Timber Engineering Research --- Meeting 50}, title = {Improved Design Equations for the Resultant Tensile Forces in Glulam Beams with Holes}, year = 2017 }
C. Tapia and S. Aicher, “Holes in glulam -- Orientation and design of internal reinforcements,” in CD-ROM Proceedings of the World Conference on Timber Engineering (WCTE 2016), J. Eberhardsteiner, W. Winter, A. Fadai, and M. Pöll, Eds., in CD-ROM Proceedings of the World Conference on Timber Engineering (WCTE 2016). Vienna, Austria: Vienna University of Technology, Austria, 2016.
- BibTeX
BibTeX
@inproceedings{Tapia2016, abstract = {The usage of holes in glulam and LVL beams is a common practice in timber constructions and requires in many cases the application of reinforcement. At present, Eurocode 5 does not contain design rules for holes, nor for their reinforcement, which are, however, regulated in the German National Annex to EC5. Although it has been proven that internal rod-like reinforcements improve the shear force capacity of a beam with holes, several problems still remain, particularly the inability to successfully reduce peak stresses at the periphery of the hole, especially shear stresses. Inclined internal steel rod reinforcements were studied and compared with vertically oriented rods, which is currently the only regulated application. The analysis revealed a reduction of both perpendicular to grain tensile stresses and shear stresses, which for the case of vertical rods are not reduced at all. A first attempt at the design of such inclined reinforcements was made by deriving an equation based on the results from FEM simulations. The design approach was then applied to an example case. Experimental verification of the theoretical observations is still necessary and ongoing, though a very promising approach for an improved internal reinforcement and its respective design can already be observed.}, address = {Vienna, Austria}, author = {Tapia, Crstóbal and Aicher, Simon}, booktitle = {CD-ROM Proceedings of the World Conference on Timber Engineering (WCTE 2016)}, editor = {Eberhardsteiner, J. and Winter, W. and Fadai, A. and Pöll, M.}, groups = {WCTE_2016}, isbn = {978-3-903039-00-1}, publisher = {Vienna University of Technology, Austria}, title = {Holes in glulam -- Orientation and design of internal reinforcements}, year = 2016 }
C. Tapia and S. Aicher, “Rechnerische Untersuchungen zu Mindestabständen von Durchbrüchen in Brettschichtholz,” in Doktorandenkolloquium ,,Holzbau Forschung und Praxis’’, in Doktorandenkolloquium ,,Holzbau Forschung und Praxis’’. Pfaffenwaldring 7, 70569 Stuttgart: Universität Stuttgart, 2016, pp. 31--39.
- BibTeX
BibTeX
@conference{Tapia2016a, address = {Pfaffenwaldring 7, 70569 Stuttgart}, author = {Tapia, Cristóbal and Aicher, Simon}, booktitle = {Doktorandenkolloquium ,,Holzbau Forschung und Praxis''}, organization = {Universität Stuttgart}, pages = {31--39}, title = {Rechnerische Untersuchungen zu Mindestabständen von Durchbrüchen in Brettschichtholz}, year = 2016 }

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