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Engineering construction.
- 1. Engineering construction Prof. Syed Ali Hussnain 1
- 2. Elastic Properties Of Wood • There is no sharply defined elastic limit in wood. • However, the stress-strain diagram in any direction is fairly straight over a considerable range before it gradually curves off. • It is a ductile material. • The relative stress-strain curves for direct tension, direct compression and bending stress intensities parallel to the grain in the figure which is given at the next page. • Modulus of elasticity of the grain is practically the same in direct tension, direct compression and bending. 2
- 3. Elastic Properties Of Wood 3 0 1 2 3 4 5 6 7 8 0 5 10 15 20 25 Y Graph of Stress Strain
- 4. Elastic Properties Of Wood o COMPRESSIVE STRENGTH • When subjected to compressive force acting parallel to the axis of growth, wood is found to be one of the strongest structural material. • However, compressive strength perpendicular to fibers of wood is much lower than that parallel to fibers of wood. • When wood is subjected to compression parallel to grain, it may fail through collapsing of the cell walls or through bending of cells and fibers. 4
- 5. Elastic Properties Of Wood o TENSILE STRENGTH • When a properly shaped wooden stick is subjected to tensile forces acting parallel to the grain it is found to have greater strength that can be developed under any other kind of stresses. • The tensile strength parallel to the grain is two to four times the compressive strength, the latter governs the strength of beams. • The tensile strength parallel to the grain is influenced to some extent by nature of the wood elements and their arrangement, but principally by the straightness of the grain and the thickness of the walls of the longitudinal elements. 5
- 6. Elastic Properties Of Wood o BENDING STRENGTH • Wood well withstands static bending, owing to which it is widely employed for elements of buildings, e.g. beams, slabs, trusses, etc. • The initial failure of long beams of uniform width is indicated by a wrinkling of the overstressed compression fibers. • Very dry specimens sometimes fail very suddenly in tension before any wrinkling of the compression fibers is noticeable. 6
- 7. Decay of Timber • Timber does not deteriorate by natural, physical and chemical changes or by pure ageing. • It is, however, affected by destructive elements, such as weathering, chemical attack, fungi, insects or rodents. 7
- 8. Defects In Timber • Defects can occur in timber at various stages, principally during the growing period and during the conversion and seasoning process. • Defects affect the quality, reduce the quantity of useful wood, reduce the strength, spoil the appearance and favour its decay. 8
- 9. Defects In Timber • Following are the some of the important defects commonly found in wood due to abnormal growth or rupture of tissues due to natural forces. o CHEEKS • cheeks is the longitudinal crack which is usually normal to the annual rings. • These adversely affect the durability of timber because they readily admit moisture and air. o SHAKES • Shakes are longitudinal separations in the wood between the annual rings. • These lengthwise separations reduce the allowable shear strength without much effect on compressive and tensile values. 9
- 10. Defects In Timber • The separations make the wood undesirable when appearance is important. o KNOTS • Knots are bases of twigs or branches buried by cambial activity of the mother branch. 10
- 11. Defects In Timber o HEART SHAKE • Heart shake occurs due to shrinkage of heart wood, when tree is over matured. • Cracks start from center And run towards sap wood. • These are the wider at the Centre and diminish outwards. o STAR SHAKE • Star shakes are radial splits or cracks wide at Circumference and diminishing Towards the centre of the tree. 11