The Influence of Panel Lay-Up on the Characteristic Bending and Rolling Shear Strength of CLT

O’Ceallaigh, C.; Sikora, Karol S.; Harte, Annette M.

doi:10.3390/buildings8090114

Cited by 32 publications

(15 citation statements)

References 12 publications

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“…The influence of shear deformations on the cross-layer has also been examined with three-point bending tests in Mastek et al [8] and in Minghao Li [9]. Recently, experimental tests and numerical models have also been presented in Franzoni et al [10], in which the influence of large and small gaps between lateral boards (lamellas) on mechanical behavior of CLT panels subjected to vertical loads with respect to its mid-plane has been highlighted, while experimental measurements of rolling shear properties on soft and hardwood species were carried out by Zhou et al [11] and O' Ceallaigh et al [5]. An extensive experimental campaign (consisting of 342 tests), aimed to evaluate the rolling shear properties of six timber species, with three different sawing patterns and three different aspect ratios of specimens, has been conducted by Ehahart and Brandner [12].…”

Section: Rolling Shear Phenomenonmentioning

confidence: 99%

“…As far as the rolling strength is concerned, experimental tests carried out on large scale CLT panels made with three or five layers established a reduced range of characteristic value, from 1.0-2.0 MPa for European spruces, independently from the timber strength class. This topic is beyond the scope of the present paper because the effect of the rolling shear on the deformative flexural behavior of CLT panels is mainly investigated here, whereby additional information can be found in the reference literature works [5,12,14,16].…”

Section: Rolling Shear Phenomenonmentioning

confidence: 99%

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The Rolling Shear Influence on the Out-of-Plane Behavior of CLT Panels: A Comparative Analysis

Sandoli

Calderoni

2020

Buildings

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This paper deals with the influence of the rolling shear deformation on the flexural behavior of CLT (Cross-Laminated Timber) panels. The morphological configuration of the panels, which consist of orthogonal overlapped layers of boards, led to a particular shear behavior when subjected to out-of-plane loadings: the low value of the shear modulus in orthogonal to grain direction (i.e., rolling shear modulus) gives rise to significant shear deformations in the transverse layers of boards, whose grains direction is perpendicular with respect to the tangential stresses direction. This produces increases of deflections and vibrations under service loads, creating discomfort for the users. Different analytical methods accounting for this phenomenon have been already developed and presented in literature. Comparative analyses among the results provided by some of these methods have been carried out in the present paper and the influence of the rolling shear deformations, with reference to different span-to-depth (L/H) ratios investigated. Moreover, the analytical results have also been compared with those obtained by more accurate 2D finite element models. The results show that, at the service limit states, the influence of the rolling shear can be significant when the aspect ratios became less than L/H = 30, and the phenomenon must be accurately considered in both deflection and stress analysis of CLT floors. Contrariwise, in the case of higher aspect ratios (slender panels), the deflections and stresses can be evaluated neglecting the rolling shear influence, assuming the layers of boards as fully-connected.

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Section: Rolling Shear Phenomenonmentioning

confidence: 99%

Section: Rolling Shear Phenomenonmentioning

confidence: 99%

The Rolling Shear Influence on the Out-of-Plane Behavior of CLT Panels: A Comparative Analysis

Sandoli

Calderoni

2020

Buildings

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“…Results based on 28 FEG specimens. 2 Results based on 3 FEG specimen and/or 3 SEG specimen. 3 Results based on 9 FEG specimen and/or 9 SEG specimen.…”

Section: Single-layer Testsmentioning

confidence: 99%

“…Several studies have investigated parameters that affect the rolling shear strength of CLT panels. O'Ceallaigh et al (2018) [2] tested the bending and shear strength of 3-and 5-layer CLT with different panel thicknesses. The study found that both, bending and rolling shear strength decreases with increasing panel thickness.…”

Section: Introductionmentioning

confidence: 99%

Comparison of Theoretical and Laboratory Out-of-Plane Shear Stiffness Values of Cross Laminated Timber Panels

2018

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The lay-up of cross laminated timber (CLT) leads to significant differences in properties over its cross-section. Particularly the out-of-plane shear behavior of CLT is affected by the changes in shear moduli over the cross-section. Results from laboratory shear tests are used to evaluate the shear stiffness of 3- and 5-layer CLT panels in their major and minor strength direction. The results are compared to calculated shear stiffness values on evaluated single-layer properties as well as commonly used property ratios using the Timoshenko beam theory and the shear analogy method. Differences between the two calculation approaches are pointed out. The shear stiffness is highly sensitive to the ratio of the shear modulus parallel to the grain to the shear modulus perpendicular to the grain. The stiffness values determined from two test measurements are compared with the calculated results. The level of agreement is dependent on the number of layers in CLT and the property axis of the CLT panels.

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“…The emergence of mass timber in the form of cross-laminated timber (CLT) over the past 20 years, however, has necessitated a closer look at strength properties in a plane perpendicular to the grain axis. In particular, for CLT cross laminations, so-called rolling shear [ 3 , 4 , 5 ] is among the dominant failure modes for certain CLT layups. Hence, the motivation for the work described in this paper is to better understand strength and fracture in the plane perpendicular to the grain axis of the wood.…”

Section: Introductionmentioning

confidence: 99%

Growth Ring Orientation Effects in Transverse Softwood Fracture

Dastjerdi

Landis

2021

Materials

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In this study, the fracture mechanics of eastern spruce were characterized in relation to end-grain orientation. Compact tension-type specimens with small pre-formed cracks were prepared such that grain angle varied relative to the load axis. Specimens were loaded under crack mouth opening displacement (CMOD) control as to maintain stable crack growth. Specimen fracture was characterized using both R-curve and bulk fracture energy approaches. The results showed that under a RT grain orientation, as well as grain deviations up to about 40∘, cracks will follow a path of least resistance in an earlywood region. As the grain angle exceeds 40∘, the crack will initially move macroscopically in the direction of maximum strain energy release rate, which extends in the direction of the pre-crack, but locally meanders through earlywood and latewood regions before settling once again in an earlywood region. At 45∘, however, the macroscopic crack takes a turn and follows a straight radial path. The results further show that RT fracture is macroscopically stable, while TR fracture is unstable. None of the end-grain fracture orientations showed rising R-curve behavior, suggesting that there is not a traditional fracture process zone in this orientation.

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The Influence of Panel Lay-Up on the Characteristic Bending and Rolling Shear Strength of CLT

Cited by 32 publications

References 12 publications

The Rolling Shear Influence on the Out-of-Plane Behavior of CLT Panels: A Comparative Analysis

The Rolling Shear Influence on the Out-of-Plane Behavior of CLT Panels: A Comparative Analysis

Comparison of Theoretical and Laboratory Out-of-Plane Shear Stiffness Values of Cross Laminated Timber Panels

Growth Ring Orientation Effects in Transverse Softwood Fracture

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