DEVELOPMENT OF A CORRELATION MODEL FOR TORSIONAL SHEAR MODULUS PROPERTIES BETWEEN STRUCTURAL SIZE SPECIMENS BASED ON EN 384:2016 AND SMALL CLEAR SPECIMENS (MS544: PART 2)

In timber design, the shear modulus of beams is crucial for ensuring torsional stability and minimizing vibrational issues. Traditionally, the ratio of modulus of elasticity (E) to shear modulus (G) is assumed to be 16:1. However, bending tests often combine flexural and shear stresses, making it di...

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Published in:JURNAL TEKNOLOGI-SCIENCES & ENGINEERING
Main Authors: Puaad, Muhammad Bazli Faliq Mohd; Ahmad, Zakiah; Bhkari, Norshariza Mohamad; Ibrahim, Mohd Johan Mohamed; Noh, Narita; Mohammad, Shahrul Nizam; Ismail, Herda Balqis
Format: Article
Language:English
Published: PENERBIT UTM PRESS 2024
Subjects:
Online Access:https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001342155400005
author Puaad
Muhammad Bazli Faliq Mohd; Ahmad
Zakiah; Bhkari
Norshariza Mohamad; Ibrahim
Mohd Johan Mohamed; Noh
Narita; Mohammad
Shahrul Nizam; Ismail
Herda Balqis
spellingShingle Puaad
Muhammad Bazli Faliq Mohd; Ahmad
Zakiah; Bhkari
Norshariza Mohamad; Ibrahim
Mohd Johan Mohamed; Noh
Narita; Mohammad
Shahrul Nizam; Ismail
Herda Balqis
DEVELOPMENT OF A CORRELATION MODEL FOR TORSIONAL SHEAR MODULUS PROPERTIES BETWEEN STRUCTURAL SIZE SPECIMENS BASED ON EN 384:2016 AND SMALL CLEAR SPECIMENS (MS544: PART 2)
Engineering
author_facet Puaad
Muhammad Bazli Faliq Mohd; Ahmad
Zakiah; Bhkari
Norshariza Mohamad; Ibrahim
Mohd Johan Mohamed; Noh
Narita; Mohammad
Shahrul Nizam; Ismail
Herda Balqis
author_sort Puaad
spelling Puaad, Muhammad Bazli Faliq Mohd; Ahmad, Zakiah; Bhkari, Norshariza Mohamad; Ibrahim, Mohd Johan Mohamed; Noh, Narita; Mohammad, Shahrul Nizam; Ismail, Herda Balqis
DEVELOPMENT OF A CORRELATION MODEL FOR TORSIONAL SHEAR MODULUS PROPERTIES BETWEEN STRUCTURAL SIZE SPECIMENS BASED ON EN 384:2016 AND SMALL CLEAR SPECIMENS (MS544: PART 2)
JURNAL TEKNOLOGI-SCIENCES & ENGINEERING
English
Article
In timber design, the shear modulus of beams is crucial for ensuring torsional stability and minimizing vibrational issues. Traditionally, the ratio of modulus of elasticity (E) to shear modulus (G) is assumed to be 16:1. However, bending tests often combine flexural and shear stresses, making it difficult to assess pure shear properties. The British Standard BS EN 408:2012 now recommends the torsion test as the preferred method for determining the shear modulus of structural-size timber and timber composites. This method has received limited attention in Malaysia. This study investigates the torsional shear modulus of Malaysian tropical timber species across different strength groups (SG), including Balau (SG1), Kempas (SG2), Kelat (SG3), Kapur (SG4), Resak (SG4), Keruing (SG5), Mengkulang (SG5), Light Red Meranti (SG6), and Geronggang (SG7). Torsion tests were conducted in line with BS EN 408, and the results were compared with modulus of elasticity values from MS554: Part 2. The findings showed that the E to G ratio for these species ranged from 17:1 to 29:1, with an average of 21:1-exceeding the conventional 16:1 ratio. This indicates that torsional shear modulus must be experimentally tested rather than inferred from the traditional ratio.
PENERBIT UTM PRESS
0127-9696
2180-3722
2024
86
6
10.11113/jurnalteknologi.v86.20819
Engineering
gold
WOS:001342155400005
https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001342155400005
title DEVELOPMENT OF A CORRELATION MODEL FOR TORSIONAL SHEAR MODULUS PROPERTIES BETWEEN STRUCTURAL SIZE SPECIMENS BASED ON EN 384:2016 AND SMALL CLEAR SPECIMENS (MS544: PART 2)
title_short DEVELOPMENT OF A CORRELATION MODEL FOR TORSIONAL SHEAR MODULUS PROPERTIES BETWEEN STRUCTURAL SIZE SPECIMENS BASED ON EN 384:2016 AND SMALL CLEAR SPECIMENS (MS544: PART 2)
title_full DEVELOPMENT OF A CORRELATION MODEL FOR TORSIONAL SHEAR MODULUS PROPERTIES BETWEEN STRUCTURAL SIZE SPECIMENS BASED ON EN 384:2016 AND SMALL CLEAR SPECIMENS (MS544: PART 2)
title_fullStr DEVELOPMENT OF A CORRELATION MODEL FOR TORSIONAL SHEAR MODULUS PROPERTIES BETWEEN STRUCTURAL SIZE SPECIMENS BASED ON EN 384:2016 AND SMALL CLEAR SPECIMENS (MS544: PART 2)
title_full_unstemmed DEVELOPMENT OF A CORRELATION MODEL FOR TORSIONAL SHEAR MODULUS PROPERTIES BETWEEN STRUCTURAL SIZE SPECIMENS BASED ON EN 384:2016 AND SMALL CLEAR SPECIMENS (MS544: PART 2)
title_sort DEVELOPMENT OF A CORRELATION MODEL FOR TORSIONAL SHEAR MODULUS PROPERTIES BETWEEN STRUCTURAL SIZE SPECIMENS BASED ON EN 384:2016 AND SMALL CLEAR SPECIMENS (MS544: PART 2)
container_title JURNAL TEKNOLOGI-SCIENCES & ENGINEERING
language English
format Article
description In timber design, the shear modulus of beams is crucial for ensuring torsional stability and minimizing vibrational issues. Traditionally, the ratio of modulus of elasticity (E) to shear modulus (G) is assumed to be 16:1. However, bending tests often combine flexural and shear stresses, making it difficult to assess pure shear properties. The British Standard BS EN 408:2012 now recommends the torsion test as the preferred method for determining the shear modulus of structural-size timber and timber composites. This method has received limited attention in Malaysia. This study investigates the torsional shear modulus of Malaysian tropical timber species across different strength groups (SG), including Balau (SG1), Kempas (SG2), Kelat (SG3), Kapur (SG4), Resak (SG4), Keruing (SG5), Mengkulang (SG5), Light Red Meranti (SG6), and Geronggang (SG7). Torsion tests were conducted in line with BS EN 408, and the results were compared with modulus of elasticity values from MS554: Part 2. The findings showed that the E to G ratio for these species ranged from 17:1 to 29:1, with an average of 21:1-exceeding the conventional 16:1 ratio. This indicates that torsional shear modulus must be experimentally tested rather than inferred from the traditional ratio.
publisher PENERBIT UTM PRESS
issn 0127-9696
2180-3722
publishDate 2024
container_volume 86
container_issue 6
doi_str_mv 10.11113/jurnalteknologi.v86.20819
topic Engineering
topic_facet Engineering
accesstype gold
id WOS:001342155400005
url https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001342155400005
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collection Web of Science (WoS)
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