Structures and Stiffness
Transcription
Structures and Stiffness
Structures and Stiffness B. Furman K. Youssefi 20SEP2007 K. Youssefi and B. Furman Engineering 10, SJSU 1 Outline • • • • • • • Newton’s 3rd Law Hooke’s Law Stiffness Area moment of Inertia Orientation of cross section and stiffness Comparison of cross sections Materials and stiffness K. Youssefi and B. Furman Engineering 10, SJSU 2 Newton’s 3rd Law • Lex III: Actioni contrariam semper et æqualem esse reactionem: sive corporum duorum actiones in se mutuo semper esse æquales et in partes contrarias dirigi. • To every action there is always opposed an equal reaction: or the mutual actions of two bodies upon each other are always equal, and directed to contrary parts. K. Youssefi and B. Furman Engineering 10, SJSU 3 Newton’s 3rd Law - example T, tension Free body diagram T, tension M •Isolate the body of interest •Put back the forces that are acting M M*g K. Youssefi and B. Furman Engineering 10, SJSU 4 Hooke’s Law • Robert Hooke (1635-1702) – Materials resist loads (push or pull back) in response to applied loads • This ‘resistance’ is accomplished by deformation of the material (changing its shape) – Tension (stretching) – Compression (shortening) – Stretching or shortening of chemical bonds in atoms • The science of Elasticity concerns forces and deformations in materials K. Youssefi and B. Furman Engineering 10, SJSU 5 Hooke’s Law, cont. • Hooke found that deflection was proportional to load Load, N Slope of Load-Deflection curve: load k= deflection slope, k Deflection, mm The “Stiffness” K. Youssefi and B. Furman Engineering 10, SJSU 6 Stiffness • Stiffness in tension and compression – Forces F applied, length L, cross-sectional area, A, and material property, E (Young’s modulus) A F F L k= F δ K. Youssefi and B. Furman F = FL AE FL δ= AE AE k= L Engineering 10, SJSU 7 Stiffness, cont. • Stiffness in bending F Ri A Ro B • How does the material resist the applied load? – Think about what happens to the material as the beam bends • Inner “fibers” (A) are in compression (radius of curvature, Ri) • Outer “fibers” (B) are in tension (radius of curvature, Ro) K. Youssefi and B. Furman Engineering 10, SJSU 8 Review Question 1 • Stiffness is defined as: A. B. C. D. E. Force/Area Deflection/Force Force/Deflection Force x Deflection Mass/area K. Youssefi and B. Furman Engineering 10, SJSU 9 Concept of Area Moment of Inertia The Area Moment of Inertia is an important parameter in determine the state of stress in a part (component, structure), the resistance to buckling, and the amount of deflection in a beam. The area moment of inertia allows you to tell how stiff a structure is. The Area Moment of Inertia, I, is a term used to describe the capacity of a cross-section (profile) to resist bending. It is always considered with respect to a reference axis, in the X or Y direction. It is a mathematical property of a section concerned with an area and how that area is distributed about the reference axis. The reference axis is usually a centroidal axis. Mathematically, the area moment of inertia appears in the denominator of the deflection equation, therefore; The higher the area moment of inertia, the less a structure deflects (higher stiffness) K. Youssefi and B. Furman Engineering 10, SJSU 10 Mathematical Equation for Area Moment of Inertia Ixx = ∑ (Ai) (yi)2 = A1(y1)2 + A2(y2)2 + …..An(yn)2 A (total area) = A1 + A2 + ……..An A2 A1 y1 y2 X K. Youssefi and B. Furman Area, A X Engineering 10, SJSU 11 Moment of Inertia – Comparison 1 Load Maximum distance of 4 inch to the centroid 2 Load 2 x 8 beam I2 I1 Maximum distance of 1 inch to the centroid 2 x 8 beam I2 > I1 , orientation 2 deflects less K. Youssefi and B. Furman Engineering 10, SJSU 12 Moment of Inertia Equations for Selected Profiles d Round solid section do Round hollow section di π (d)4 I= 64 π [(do)4 – (di)4] I= 64 Rectangular solid section Rectangular hollow section b I= 1 bh3 12 h h b I= B I= 1 hb3 12 H b 1 1 BH3 bh3 12 12 h K. Youssefi and B. Furman Engineering 10, SJSU 13 Example – Optimization for Weight & Stiffness Consider a solid rectangular section 2.0 inch wide by 1.0 high. 1.0 I = (1/12)bh3 = (1/12)(2)(1)3 = .1667 , Area = 2 2.0 Now, consider a hollow rectangular section 2.25 inch wide by 1.25 high by .125 thick. b B = 2.25, H = 1.25 h b = 2.0, h = 1.0 H B I = (1/12)bh3 = (1/12)(2.25)(1.25)3 – (1/12)(2)(1)3= .3662 -.1667 = .1995 Area = 2.25x1.25 – 2x1 = .8125 (.1995 - .1667)/(.1167) = .20 = 20% less deflection Compare the weight of the two parts (same material and length), compare areas. Material and length is the same for both profiles. (2 - .8125)/(2) = .6 = 60% lighter So, for a slightly larger outside dimension section, 2.25x1.25 instead of 2 x 1, you can design a beam that is 20% stiffer and 60 % lighter K. Youssefi and B. Furman Engineering 10, SJSU 14 Review Question 2 • Which cross section has the larger I? A. Rectangular Horizontal B. Rectangular Vertical K. Youssefi and B. Furman Engineering 10, SJSU 15 Stiffness Comparisons for Different sections Square K. Youssefi and B. Furman Box Rectangular Horizontal Engineering 10, SJSU Rectangular Vertical 16 Material and Stiffness E = Elasticity Modulus, a measure of material deformation under a load. Deflection of a Cantilever Beam Support L = length F = force Y = deflection = FL3 / 3EI Fixed end The higher the value of E, the less a structure deflects (higher stiffness) K. Youssefi and B. Furman Engineering 10, SJSU 17 Modulus of Elasticity (E) of Materials Steel is 3 times stiffer than Aluminum and 100 times stiffer than Plastics. K. Youssefi and B. Furman Engineering 10, SJSU 18 Density of Materials Plastic is 7 times lighter than steel and 3 times lighter than aluminum. K. Youssefi and B. Furman Engineering 10, SJSU 19 Wind Turbine Structure The support structure should be optimized for weight and stiffness. Support Structure K. Youssefi and B. Furman Engineering 10, SJSU 20 Review Question 3 • Which material has the higher stiffness? A. B. C. D. E. Steel Aluminum Alumina ceramic Nylon Unobtanium K. Youssefi and B. Furman Engineering 10, SJSU 21 Examples of Achieving Structural Stiffness ‘Boss’ ‘Gusset’ ‘Ribbing’ K. Youssefi and B. Furman Engineering 10, SJSU 22 Examples of Achieving Structural Stiffness, cont. http://en.wikipedia.org/wiki/Image:FT_Rail.jpg K. Youssefi and B. Furman Engineering 10, SJSU 23 Examples of Achieving Structural Stiffness, cont. Welded ‘box’ construction K. Youssefi and B. Furman Engineering 10, SJSU 24 Examples of Achieving Structural Stiffness, cont. K. Youssefi and B. Furman Engineering 10, SJSU 25 Examples of Achieving Structural Stiffness, cont. ‘Flange’ K. Youssefi and B. Furman Engineering 10, SJSU 26 Examples of Achieving Structural Stiffness, cont. K. Youssefi and B. Furman Engineering 10, SJSU 27