LECTURE NO. 20 (Handout) TIMBER Objectives: To explain the engineering properties and usages of timber
INTRODUCTION The "wood" used for building, carpentry or various other engineering purposes is termed as "timber". Wood is used extensively for buildings, bridges, utility poles, piles, floor, trusses, roofs Wood is used in the following forms: Natural form, and Engineered wood products (laminates, plywood, strand board, etc) Low cost, availability, ease of use, and renewable Wood is natural, renewable product from trees. There are more than 600 species of trees in the U.S alone
INTRODUCTION Trees are classified into two types based on growth Exogenous: Growth from center out by adding concentric layer of wood Endogenous: Growth with intertwined fibers, such as bamboo Predominant physical features of tree stem Bark Cambium Wood (sap wood and heartwood) Pith Sapwood functions as storehouse for starches and as a pipeline to transport sap Heartwood are cells that are chemically and physically altered by mineral deposit. It provides structural strength for the tree Annual rings or tree rings are the concentric layers in the stem of exogenous trees Each annual ring is composed of earlywood and latewood. Earlywood grows during spring time and has large cell openings (cavities). Latewood grows during summer and consists of dense, dark, and thick cells wall, which produce a stronger wood than earlywood
ANISOTROPIC NATURE OF WOOD Wood is an anisotropic material because it has different properties in various directions Three-axis orientation in wood are Longitudinal or parallel to the grain Radical or across the growth rings (perpendicular to the grain) Tangential or tangent to the growth rings An isotropic nature affects physical and mechanical properties of wood such as shrinkage, stiffness, and strength The wood cells have a rectangular cross section. The center of the tubes is hollow. The tube structure resists stresses parallel to its length, but it will deform when loaded on its side Tubes are 100/1 (length to diameter)
CHEMICAL COMPOSITION OF WOOD Cellulose: 50% by weight Lignin: 23-33% in softwoods, 16-26% in hardwoods It is the glue for the cells. It controls the shear strength. Hemicellulose: 15-20% of softwood and 20-30% of hardwood. Polymeric units made from sugar molecules. Xylone in hardwoods, mannose in softwood. Extractives: 5-30% of the wood substance Include poly-phenolics, coloring material, oils and fats, resins, waxes, gums, starches. Soluble in water, alcohol, acetone, and benzene Ash-forming materials: 0.1to 3.0% of the wood material Include calcium, potassium, phosphate, and silica
WATER IN WOOD Types of water in wood: Fiber Saturation Point (FSP): Bound water: held within the cell wall by absorption forces Free water exists as either condensed water or water vapor Fiber Saturation Point (FSP): The level at which the cell walls are completely saturated, but no free water exists in the cell cavities FSP varies among tree species, typically range in 21-32% Physical and mechanical properties are dependent on the FSP Shrinkage: If the moisture content is higher than the FSP, the wood is dimensionally stable Shrinkage may result with the moisture content less than the FSP Occurs when moisture is lost from cell walls Swelling occurs when moisture is gained in the cell walls Shrinkage in the radial direction is generally one-half the change in the tangential direction Shrinkage in the longitudinal direction is usually minimal, ranging from 0.1 to 0.2% for a change in the moisture content from FSP to oven dry
WOOD PRODUCTION PROCESSES Wood is produced through following processes: Harvesting Sawing into desired shapes and sizes Seasoning Surfacing Preservation
WOOD PRODUCTION PROCESSES: Harvesting of wood Logs of wood are harvested during the fall or winter due to fire hazards and also cutting the trees at the end of their non-tree plant lives in the forest
WOOD PRODUCTION PROCESSES: Sawing of wood into desired shapes and sizes Harvested logs are transported to sawmill where they are cut into following useful dimensional shapes: Lumber 50 - 125 mm (2 - 5 inch) thick, sawing and surfacing on all four sides remove 5-10 mm from the dimensions Sizes include 24, 26, 28, 210, 212, 44 referring to rough cut dimensions in inches, actual sizes are less Lengths range from 8 to 24 ft Uses include studs, sill, and top plates, joists, beams, rafters, trusses, and decking Heavy timber Rough sawn dimensions of 46, 66, 88 reduced by 10 mm per side due to surfacing. Uses include heavy-frame construction, landscaping, railroad ties, and marine construction Round stock Poles and posts used for building, marine pilings, and utility poles
WOOD PRODUCTION PROCESSES: Seasoning of wood Seasoning is the process of removing moisture from a harvested wood Green wood contains 30 to 200% moisture by oven-dried weight, this is lowered to 7% for dry areas or up to 14% in damp areas, leaving a saw mill, wood is at 15% moisture Air drying (inexpensive and slow) Stack boards with air space between them to allow drying After 3 to 4 months, it reaches the local humidity level Often requires further dying to reach acceptable levels Kiln drying (scientific and expensive) Boards dried at 70-120 F for 4-10 days Rapid drying may result in cracks and deformed lumber, and post-process wood is thirsty, so it must be covered and cared for properly
WOOD PRODUCTION PROCESSES: Surfacing of wood Planning (surfacing) to produce a smooth surface Post-drying surfacing yields higher quality lumber because it removes small defects developed during the drying In case of pre-surfacing, the dimensions are slightly increases to compensate for shrinkage during seasoning
WOOD PRODUCTION PROCESSES: Wood preservation The wood needs to be preserved against the degradation caused by various organisms such as: fungi, bacteria, insects, and marine organisms. The quality of preservation depends on the following: The type of preservative The degree of penetration by preservative The amount of the chemical retained in the wood Types of preservatives Paints Petroleum-based solutions These are very effective but environmentally sensitive. Used where a high degree of environmental exposure exists and human contact is not a concern such as utility poles, railroad ties, retaining walls Waterborne preservatives (salts) Ammoniacal copper arsenate Chromated copper arsenate Ammoniocal copper zinc arsenate Advantages: Cleanliness and ability to be painted Disadvantages: Their removal by leaching when exposed to moist conditions over long periods of time. Environmentally sensitive. Used for wood structure such as residual decks and fences
WOOD PRODUCTION PROCESSES: Wood preservation---contd. Preservative application techniques Superficial treatment Techniques include coatings applied by painting, spraying, or immersion Fluid penetration process Occurs by capillary action and is a function of surface tension, angle of contact, time, temperature, and pressure Pressure-treated wood has greater resistance to degradation than surface-treated wood because the preservative is forced into the entire structure of the wood
ENGINEERED WOOD PRODUCTS Following engineered wood products are manufactured by bonding wood strands, veneers, lumber, or fibers. Glued - laminated timber (glulam) Structural composite lumber (same dimensions as sawn wood dimensional lumber) Structural strand panels (plywood, orientated strand board, and composite panels) Wood I-Joists Quality and serviceability depend on: Gluing properties and wood preparation Type of adhesive Quality control in the gluing process Adhesives used for gluing: Natural (casein, vegetable protein, and blood protein glues) Synthetic (phenol, urea, resorcinol, polyvinyl, and epoxy resins)
ENGINEERED WOOD PRODUCTS Glued-laminated timbers Douglas-fir and southern pine are the most common Advantages: Ease of manufacturing large members Can design large members whose cross-sections vary along their length Can use low grade wood for less stressed areas Minimal seasoning defects Factors that affect strength: Cross-grain Knots Effect of end joining
ENGINEERED WOOD PRODUCTS Plywood Thin sheets of wood (plies) that are glued in layers Production of Plywood: Logs are saturated. Six hours before processing are moved into boiling water. Bark is removed and logs are cut into eight-foot sections A continuous sheet of veneer is peeled from the log Veneer is seasoned and dried Assemble, glue, and press veneer Classification based on: Type of wood used Number of plies Grade of plies Type of adhesive Properties of Plies: Adjacent sheets have grain that runs perpendicular to each other The middle plies in even - plied panels have the same grain orientation Plies are 1.6 mm to 7.9 mm thick Plywood panels are 3.2 to 29 mm thick
ENGINEERED WOOD PRODUCTS Particle Board and Strand Board Manufactured by gluing together "scraps" produces Particle board is made from sawdust-sized particles Strand board is made from flat chips These products are replacing plywood in many applications because it is cheaper
PHYSICAL PROPERTIES OF WOOD: Moisture content (MC) MC is the weight of water as a percentage of the oven-dry weight of the wood Oven-dried is attained in an oven at 100ºC to 150ºC until the wood attains a constant weight Physical properties, such as weight, shrinkage and strength depend on the moisture content of wood
PHYSICAL PROPERTIES OF WOOD: Specific gravity (G) Specific gravity of wood is determined in the oven-dry condition, as: G is a good indicator of mechanical properties G depends on cell size, cell-wall thickness, and the number and type of cells. G for cell material is 1.5
PHYSICAL PROPERTIES OF WOOD: Density or unit weight () Following equation is recommended to calculate density of wood at any moisture content: Where: G is the specific gravity in oven-dry condition and MC is the moisture content in percent. The dry density of wood can range from 160 kg/m3 (10 lb/ft3) to 1000 kg/m3 (65 lb/ft3) depending on tree species The range of the majority is 320 - 720 kg/m3 (20 to 45 lb/ft3
PHYSICAL PROPERTIES OF WOOD: Thermal conductivity, Thermal diffusivity and Electrical resistivity It is the rate of heat flow Thermal conductivity for wood is a fraction of most metals and 3 to 4 times greater than most common insulating material It depends on grain orientation, moisture content, specific gravity, extractive content, and irregularities Heat flow parallel to grain is 2.0 to 2.8 times greater than in the radial direction As the moisture content increases from 0 to 40%, the thermal conductivity increases by about 30% It has linear correlation with specific gravity meaning heavier wood conduct heat faster Thermal Diffusivity: It is a measure of the rate at which a material absorbs heat from its surroundings For wood, it is much smaller than that of other common building materials Thermal diffusivity value of wood averages 0.006 mm/s (0.00025 inch/s) Electrical Resistivity: Air-dry wood is a good electrical insulator Resistivity decreases by a factor of three for each percentage increase in moisture content Wood has the resistivity of water when it reaches the fiber saturation point (FSP)
Coefficient of Thermal Expansion: PHYSICAL PROPERTIES OF WOOD: Specific heat and Coefficient of thermal expansion Specific Heat: It is the ratio of the quantity of heat required to raise the temperature of a material 1 degree to that required for raising the temperature of an equal mass of water by 1 degree For wood, it is dependent on moisture and temperature Species and density have little or no effect on specific heat Coefficient of Thermal Expansion: It is a measure of dimensional changes caused by a temperature variance Longitudinal (parallel to grain) coefficient values range from 0.009 to 0.0014 mm/m/°C (0.0000017 to 0.0000025 inch/inch/°F) Coefficients are 5 to 10 times greater across the grain Moist wood that is heated, expands due to thermal expansion and shrinks due to moisture loss (below FSP) which usually results in a net shrinkage
MECHANICAL PROPERTIES OF WOOD: Strength Vary widely depending on the tree species and direction of the grain relative to the direction of the force Compressive and tensile strengths in the direction parallel to grain are found to be several times more than that in the direction perpendicular to grain Columns, posts, and members of a truss subjected to axial loads are the examples of loads parallel to grain. A vertical member supported to a horizontal member is an example of load perpendicular to grain The compressive strength in the direction parallel to the grain is around more than 10 times the strength perpendicular to the grain The tensile strength in the direction parallel to the grain is about more than 30 times the strength perpendicular to the grain The tensile strength parallel to the grain is larger than the compressive strength in the same direction
MECHANICAL PROPERTIES OF WOOD: Modulus of elasticity, Creep, and Damping capacity Wood starts off having a linear stress-strain curve, then a small non-linear curve occurs before it fails Important factors are: Tree species, Variation in moisture content, and Specific gravity Wood is an isotropic material (different stress-strain relations exist for different directions) Creep: Wood continuously deforms and creeps under sustained loads Damping Capacity: Reduction in amplitude of vibration over time due to internal friction within material and resistance to support system Higher moisture content means a proportional increase in damping up to FSP Wood structures dampen vibrations more quickly than metal structures Damping capacity of wood parallel to grain is 10 times that of structural metals
MECHANICAL PROPERTIES OF WOOD
SOME COMMON DEFECTS IN WOOD