Knowing that for the extruded beam shown theallowable

Knowing that the couple shown acts in a vertical plane, determine the stress at (a) point A, (b) point B.

Knowing that the couple shown acts in a vertical plane, determine the stress at (a) point A, (b) point B.

Using an allowable stress of 16 ksi, determine the largest couple that can be applied to each pipe.

A nylon spacing bar has the cross section shown. Knowing that the allowable stress for the grade of nylon used is 24 MPa, determine the largest couple Mz that can be applied to the bar.

A beam of the cross section shown is extruded from an aluminum alloy for which sY 5 250 MPa and sU 5 450 MPa. Using a factor of safety of 3.00, determine the largest couple that can be applied to the beam when it is bent about the z axis.

Solve Prob. 4.5, assuming that the beam is bent about the y axis.

Two W4 3 13 rolled sections are welded together as shown. Knowing that for the steel alloy used, sY 5 36 ksi and sU 5 58 ksi and using a factor of safety of 3.0, determine the largest couple that can be applied when the assembly is bent about the z axis.

Two W4 3 13 rolled sections are welded together as shown. Knowing that for the steel alloy used, sY 5 36 ksi and sU 5 58 ksi and using a factor of safety of 3.0, determine the largest couple that can be applied when the assembly is bent about the z axis.

Two vertical forces are applied to a beam of the cross section shown. Determine the maximum tensile and compressive stresses in portion BC of the beam.

Two vertical forces are applied to a beam of the cross section shown. Determine the maximum tensile and compressive stresses in portion BC of the beam.

Two vertical forces are applied to a beam of the cross section shown. Determine the maximum tensile and compressive stresses in portion BC of the beam.

Knowing that a beam of the cross section shown is bent about a horizontal axis and that the bending moment is 6 kN ? m, determine the total force acting on the top flange.

Knowing that a beam of the cross section shown is bent about a horizontal axis and that the bending moment is 6 kN ? m, determine the total force acting on the shaded portion of the web.

Knowing that a beam of the cross section shown is bent about a horizontal axis and that the bending moment is 50 kip ? in., determine the total force acting (a) on the top flange (b) on the shaded portion of the web.

The beam shown is made of a nylon for which the allowable stress is 24 MPa in tension and 30 MPa in compression. Determine the largest couple M that can be applied to the beam.

Solve Prob. 4.15, assuming that d 5 40 mm.

Knowing that for the extruded beam shown the allowable stress is 12 ksi in tension and 16 ksi in compression, determine the largest couple M that can be applied.

Knowing that for the casting shown the allowable stress is 5 ksi in tension and 18 ksi in compression, determine the largest couple M that can be applied.

Knowing that for the extruded beam shown the allowable stress is 120 MPa in tension and 150 MPa in compression, determine the largest couple M that can be applied.

Knowing that for the extruded beam shown the allowable stress is 120 MPa in tension and 150 MPa in compression, determine the largest couple M that can be applied.

A steel band saw blade, that was originally straight, passes over 8-in.-diameter pulleys when mounted on a band saw. Determine the maximum stress in the blade, knowing that it is 0.018 in. thick and 0.625 in. wide. Use E 5 29 3 106 psi.

Straight rods of 0.30-in. diameter and 200-ft length are sometimes used to clear underground conduits of obstructions or to thread wires through a new conduit. The rods are made of high-strength steel and, for storage and transportation, are wrapped on spools of 5-ft diameter. Assuming that the yield strength is not exceeded, determine (a) the maximum stress in a rod, when the rod, which is initially straight, is wrapped on a spool, (b) the corresponding bending moment in the rod. Use E 5 29 3 106 psi.

A 900-mm strip of steel is bent into a full circle by two couples applied as shown. Determine (a) the maximum thickness t of the strip if the allowable stress of the steel is 420 MPa, (b) the corresponding moment M of the couples. Use E 5 200 GPa.

A 60-N ? m couple is applied to the steel bar shown. (a) Assuming that the couple is applied about the z axis as shown, determine the maximum stress and the radius of curvature of the bar. (b) Solve part a, assuming that the couple is applied about the y axis. Use E 5 200 GPa.

A couple of magnitude M is applied to a square bar of side a. For each of the orientations shown, determine the maximum stress and the curvature of the bar

A portion of a square bar is removed by milling, so that its cross Problems 241 section is as shown. The bar is then bent about its horizontal axis by a couple M. Considering the case where h 5 0.9h0, express the maximum stress in the bar in the form sm 5 ks0 where s0 is the maximum stress that would have occurred if the original square bar had been bent by the same couple M, and determine the value of k.

In Prob. 4.26, determine (a) the value of h for which the maximum stress sm is as small as possible, (b) the corresponding value of k.

A couple M will be applied to a beam of rectangular cross section that is to be sawed from a log of circular cross section. Determine the ratio dyb for which (a) the maximum stress sm will be as small as possible, (b) the radius of curvature of the beam will be maximum

For the aluminum bar and loading of Sample Prob. 4.1, determine (a) the radius of curvature r9 of a transverse cross section, (b) the angle between the sides of the bar that were originally vertical. Use E 5 10.6 3 106 psi and n 5 0.33.

For the bar and loading of Example 4.01, determine (a) the radius of curvature r, (b) the radius of curvature r9 of a transverse cross section, (c) the angle between the sides of the bar that were originally vertical. Use E 5 29 3 106 psi and n 5 0.29.

A W200 3 31.3 rolled-steel beam is subjected to a couple M of moment 45 kN ? m. Knowing that E 5 200 GPa and n 5 0.29, determine (a) the radius of curvature r, (b) the radius of curvature r9 of a transverse cross section.

It was assumed in Sec. 4.3 that the normal stresses sy in a member in pure bending are negligible. For an initially straight elastic member of rectangular cross section, (a) derive an approximate expression for sy as a function of y, (b) show that (sy)max 5 2(cy2r)(sx)max and, thus, that sy can be neglected in all practical situations. (Hint: Consider the free-body diagram of the portion of beam located below the surface of ordinate y and assume that the distribution of the stress sx is still linear.)

bar having the cross section shown has been formed by securely bonding brass and aluminum stock. Using the data given below, determine the largest permissible bending moment when the composite bar is bent about a horizontal axis.

bar having the cross section shown has been formed by securely bonding brass and aluminum stock. Using the data given below, determine the largest permissible bending moment when the composite bar is bent about a horizontal axis.

For the composite bar indicated, determine the largest permissible bending moment when the bar is bent about a vertical axis.Bar of Prob. 4.33.

For the composite bar indicated, determine the largest permissible bending moment when the bar is bent about a vertical axis.Bar of Prob. 4.34.

Wooden beams and steel plates are securely bolted together to form the composite member shown. Using the data given below, determine the largest permissible bending moment when the member is bent about a horizontal axis.

Wooden beams and steel plates are securely bolted together to form the composite member shown. Using the data given below, determine the largest permissible bending moment when the member is bent about a horizontal axis.

A steel bar and an aluminum bar are bonded together Problems 251 to form the composite beam shown. The modulus of elasticity for aluminum is 70 GPa and for steel is 200 GPa. Knowing that the beam is bent about a horizontal axis by a couple of moment M 5 1500 N ? m, determine the maximum stress in (a) the aluminum, (b) the steel.

A steel bar and an aluminum bar are bonded together Problems 251 to form the composite beam shown. The modulus of elasticity for aluminum is 70 GPa and for steel is 200 GPa. Knowing that the beam is bent about a horizontal axis by a couple of moment M 5 1500 N ? m, determine the maximum stress in (a) the aluminum, (b) the steel.

The 6 3 12-in. timber beam has been strengthened by bolting to it the steel reinforcement shown. The modulus of elasticity for wood is 1.8 3 106 psi and for steel is 29 3 106 psi. Knowing that the beam is bent about a horizontal axis by a couple of moment M 5 450 kip ? in., determine the maximum stress in (a) the wood, (b) the steel.

The 6 3 12-in. timber beam has been strengthened by bolting to it the steel reinforcement shown. The modulus of elasticity for wood is 1.8 3 106 psi and for steel is 29 3 106 psi. Knowing that the beam is bent about a horizontal axis by a couple of moment M 5 450 kip ? in., determine the maximum stress in (a) the wood, (b) the steel.

For the composite beam indicated, determine the radius of curvature caused by the couple of moment 1500 N ? m.Beam of Prob. 4.39.

For the composite beam indicated, determine the radius of curvature caused by the couple of moment 1500 N ? m.Beam of Prob. 4.40.

For the composite beam indicated, determine the radius of curvature caused by the couple of moment 450 kip ? in.Beam of Prob. 4.41

For the composite beam indicated, determine the radius of curvature caused by the couple of moment 450 kip ? in.Beam of Prob. 4.42

The reinforced concrete beam shown is subjected to a positive bending moment of 175 kN ? m. Knowing that the modulus of elasticity is 25 GPa for the concrete and 200 GPa for the steel, determine (a) the stress in the steel, (b) the maximum stress in the concrete.

Solve Prob. 4.47, assuming that the 300-mm width is increased to 350 mm.

A concrete slab is reinforced by 16-mm-diameter steel rods placed on 180-mm centers as shown. The modulus of elasticity is 20 GPa for the concrete and 200 GPa for the steel. Using an allowable stress of 9 MPa for the concrete and 120 MPa for the steel, determine the largest bending moment in a portion of slab 1 m wide.

Solve Prob. 4.49, assuming that the spacing of the 16-mm-diameter rods is increased to 225 mm on centers.

A concrete beam is reinforced by three steel rods placed as shown. The modulus of elasticity is 3 3 106 psi for the concrete and 29 3 106 psi for the steel. Using an allowable stress of 1350 psi for the concrete and 20 ksi for the steel, determine the largest allowable positive bending moment in the beam.

Knowing that the bending moment in the reinforced concrete beam is 1100 kip ? ft and that the modulus of elasticity is 3.625 3 106 psi for the concrete and 29 3 106 psi for the steel, determine (a) the stress in the steel, (b) the maximum stress in the concrete.

The design of a reinforced concrete beam is said to be balanced if the maximum stresses in the steel and concrete are equal, respectively, to the allowable stresses ss and sc. Show that to achieve a balanced design the distance x from the top of the beam to the neutral axis must be x 5 d 1 1 ssEc scEs where Ec and Es are the moduli of elasticity of concrete and steel, respectively, and d is the distance from the top of the beam to the reinforcing steel.

For the concrete beam shown, the modulus of elasticity is 3.5 3 106 psi for the concrete and 29 3 106 psi for the steel. Knowing that b 5 8 in. and d 5 22 in., and using an allowable stress of 1800 psi for the concrete and 20 ksi for the steel, determine (a) the required area As of the steel reinforcement if the beam is to be balanced, (b) the largest allowable bending moment. (See Prob. 4.53 for definition of a balanced beam.)

Five metal strips, each 40 mm wide, are bonded Problems 253 together to form the composite beam shown. The modulus of elasticity is 210 GPa for the steel, 105 GPa for the brass, and 70 GPa for the aluminum. Knowing that the beam is bent about a horizontal axis by a couple of moment 1800 N ? m, determine (a) the maximum stress in each of the three metals, (b) the radius of curvature of the composite beam.

Five metal strips, each 40 mm wide, are bonded Problems 253 together to form the composite beam shown. The modulus of elasticity is 210 GPa for the steel, 105 GPa for the brass, and 70 GPa for the aluminum. Knowing that the beam is bent about a horizontal axis by a couple of moment 1800 N ? m, determine (a) the maximum stress in each of the three metals, (b) the radius of curvature of the composite beam.

The composite beam shown is formed by bonding together a brass rod and an aluminum rod of semicircular cross sections. The modulus of elasticity is 15 3 106 psi for the brass and 10 3 106 psi for the aluminum. Knowing that the composite beam is bent about a horizontal axis by couples of moment 8 kip ? in., determine the maximum stress (a) in the brass, (b) in the aluminum.

A steel pipe and an aluminum pipe are securely bonded together to form the composite beam shown. The modulus of elasticity is 200 GPa for the steel and 70 GPa for the aluminum. Knowing that the composite beam is bent by a couple of moment 500 N ? m, determine the maximum stress (a) in the aluminum, (b) in the steel.

The rectangular beam shown is made of a plastic for which the value of the modulus of elasticity in tension is one-half of its value in compression. For a bending moment M 5 600 N ? m, determine the maximum (a) tensile stress, (b) compressive stress.

A rectangular beam is made of material for which the modulus of elasticity is Et in tension and Ec in compression. Show that the curvature of the beam in pure bending is 1 r 5 M Er I where Er 5 4EtEc 11Et 1 1Ec 22

Semicircular grooves of radius r must be milled as shown in the sides of a steel member. Using an allowable stress of 60 MPa, determine the largest bending moment that can be applied to the member when (a) r 5 9 mm, (b) r 5 18 mm.

Semicircular grooves of radius r must be milled as shown in the sides of a steel member. Knowing that M 5 450 N ? m, determine the maximum stress in the member when the radius r of the semicircular grooves is (a) r 5 9 mm, (b) r 5 18 mm.

Knowing that the allowable stress for the beam shown is 90 MPa, determine the allowable bending moment M when the radius r of the fillets is (a) 8 mm, (b) 12 mm.

Knowing that M 5 250 N ? m, determine the maximum stress in the beam shown when the radius r of the fillets is (a) 4 mm, (b) 8 mm.

The allowable stress used in the design of a steel bar is 12 ksi. Determine the largest couple M that can be applied to the bar (a) if the bar is designed with grooves having semicircular portions of radius r 5 34 in., as shown in Fig. a, (b) if the bar is redesigned by removing the material above and below the dashed lines as shown in Fig. b.

A couple of moment M 5 20 kip ? in. is to be applied to the end of a steel bar. Determine the maximum stress in the bar (a) if the bar is designed with grooves having semicircular portions of radius r 5 12 in., as shown in Fig. a, (b) if the bar is redesigned by removing the material above and below the dashed lines as shown in Fig. b.

The prismatic bar shown is made of a steel that is assumed to be elastoplastic with sY 5 300 MPa and is subjected to a couple M parallel to the x axis. Determine the moment M of the couple for which (a) yield first occurs, (b) the elastic core of the bar is 4 mm thick

Solve Prob. 4.67, assuming that the couple M is parallel to the z axis.

The prismatic bar shown, made of a steel that is assumed to be elastoplastic with E 5 29 3 106 psi and sY 5 36 ksi, is subjected to a couple of 1350 lb ? in. parallel to the z axis. Determine (a) the thickness of the elastic core, (b) the radius of curvature of the bar.

Solve Prob. 4.69, assuming that the 1350-lb ? in. couple is parallel to the y axis.

A bar of rectangular cross section shown is made of a steel that is assumed to be elastoplastic with E 5 200 GPa and sY 5 300 MPa. Determine the bending moment M for which (a) yield first occurs, (b) the plastic zones at the top and bottom of the bar are 12 mm thick.

Bar AB is made of a steel that is assumed to be elastoplastic with E 5 200 GPa and sY 5 240 MPa. Determine the bending moment M for which the radius of curvature of the bar will be (a) 18 m, (b) 9 m.

A beam of the cross section shown is made of a steel Problems 267 that is assumed to be elastoplastic with E 5 200 GPa and sY 5 240 MPa. For bending about the z axis, determine the bending moment at which (a) yield first occurs, (b) the plastic zones at the top and bottom of the bar are 30 mm thick.

A beam of the cross section shown is made of a steel Problems 267 that is assumed to be elastoplastic with E 5 200 GPa and sY 5 240 MPa. For bending about the z axis, determine the bending moment at which (a) yield first occurs, (b) the plastic zones at the top and bottom of the bar are 30 mm thick.

A beam of the cross section shown is made of a steel that is assumed to be elastoplastic with E 5 29 3 106 psi and sY 5 42 ksi. For bending about the z axis, determine the bending moment at which (a) yield first occurs, (b) the plastic zones at the top and bottom of the bar are 3 in. thick.

A beam of the cross section shown is made of a steel that is assumed to be elastoplastic with E 5 29 3 106 psi and sY 5 42 ksi. For bending about the z axis, determine the bending moment at which (a) yield first occurs, (b) the plastic zones at the top and bottom of the bar are 3 in. thick.

For the beam indicated, determine (a) the plastic moment Mp, (b) the shape factor of the cross section.Beam of Prob. 4.73.

For the beam indicated, determine (a) the plastic moment Mp, (b) the shape factor of the cross section.Beam of Prob. 4.74.

For the beam indicated, determine (a) the plastic moment Mp, (b) the shape factor of the cross section.Beam of Prob. 4.75.

For the beam indicated, determine (a) the plastic moment Mp, (b) the shape factor of the cross section.Beam of Prob. 4.76.

Determine the plastic moment Mp of a steel beam of the cross section shown, assuming the steel to be elastoplastic with a yield strength of 240 MPa.

Determine the plastic moment Mp of a steel beam of the cross section shown, assuming the steel to be elastoplastic with a yield strength of 240 MPa.

Determine the plastic moment Mp of a steel beam of the cross section shown, assuming the steel to be elastoplastic with a yield strength of 240 MPa.

Determine the plastic moment Mp of a steel beam of the cross section shown, assuming the steel to be elastoplastic with a yield strength of 240 MPa.

Determine the plastic moment Mp of the cross section shown, assuming the steel to be elastoplastic with a yield strength of 36 ksi.

Determine the plastic moment Mp of the cross section shown, assuming the steel to be elastoplastic with a yield strength of 36 ksi.

For the beam indicated, a couple of moment equal to the full plastic moment Mp is applied and then removed. Using a yield strength of 240 MPa, determine the residual stress at y 5 45 mm.Beam of Prob. 4.73.

For the beam indicated, a couple of moment equal to the full plastic moment Mp is applied and then removed. Using a yield strength of 240 MPa, determine the residual stress at y 5 45 mm.Beam of Prob. 4.74

A bending couple is applied to the bar indicated, causing plastic zones 3 in. thick to develop at the top and bottom of the bar. After the couple has been removed, determine (a) the residual stress at y 5 4.5 in., (b) the points where the residual stress is zero, (c) the radius of curvature corresponding to the permanent deformation of the bar.Beam of Prob. 4.75.

A bending couple is applied to the bar indicated, causing plastic zones 3 in. thick to develop at the top and bottom of the bar. After the couple has been removed, determine (a) the residual stress at y 5 4.5 in., (b) the points where the residual stress is zero, (c) the radius of curvature corresponding to the permanent deformation of the bar.Beam of Prob. 4.76.

A bending couple is applied to the beam of Prob. 4.73, causing plastic zones 30 mm thick to develop at the top and bottom of the beam. After the couple has been removed, determine (a) the residual stress at y 5 45 mm, (b) the points where the residual stress is zero, (c) the radius of curvature corresponding to the permanent deformation of the beam.

A beam of the cross section shown is made of a steel that is assumed to be elastoplastic with E 5 29 3 106 psi and sY 5 42 ksi. A bending couple is applied to the beam about the z axis, causing plastic zones 2 in. thick to develop at the top and bottom of the beam. After the couple has been removed, determine (a) the residual stress at y 5 2 in., (b) the points where the residual stress is zero, (c) the radius of curvature corresponding to the permanent deformation of the beam.

A rectangular bar that is straight and unstressed is bent into an arc of circle of radius r by two couples of moment M. After the couples are removed, it is observed that the radius of curvature of the bar is rR. Denoting by rY the radius of curvature of the bar at the onset of yield, show that the radii of curvature satisfy the following relation:

A solid bar of rectangular cross section is made of a material that Problems 269 is assumed to be elastoplastic. Denoting by MY and rY, respectively, the bending moment and radius of curvature at the onset of yield, determine (a) the radius of curvature when a couple of moment M 5 1.25 MY is applied to the bar, (b) the radius of curvature after the couple is removed. Check the results obtained by using the relation derived in Prob. 4.93.

The prismatic bar AB is made of a steel that is assumed to be elastoplastic and for which E 5 200 GPa. Knowing that the radius of curvature of the bar is 2.4 m when a couple of moment M 5 350 N ? m is applied as shown, determine (a) the yield strength of the steel, (b) the thickness of the elastic core of the bar.

The prismatic bar AB is made of an aluminum alloy for which the tensile stress-strain diagram is as shown. Assuming that the s-P diagram is the same in compression as in tension, determine (a) the radius of curvature of the bar when the maximum stress is 250 MPa, (b) the corresponding value of the bending moment. (Hint: For part b, plot s versus y and use an approximate method of integration.)

The prismatic bar AB is made of a bronze alloy for which the tensile stress-strain diagram is as shown. Assuming that the s-P diagram is the same in compression as in tension, determine (a) the maximum stress in the bar when the radius of curvature of the bar is 100 in., (b) the corresponding value of the bending moment. (See hint given in Prob. 4.96.)

A prismatic bar of rectangular cross section is made of an alloy for which the stress-strain diagram can be represented by the relation P 5 ksn for s . 0 and P 5 2|ksn| for s , 0. If a couple M is applied to the bar, show that the maximum stress is

A short wooden post supports a 6-kip axial load as shown. Determine the stress at point A when (a) b 5 0, (b) b 5 1.5 in., (c) b 5 3 in.

As many as three axial loads each of magnitude P 5 10 kips can be applied to the end of a W8 3 21 rolled-steel shape. Determine the stress at point A, (a) for the loading shown, (b) if loads are applied at points 1 and 2 only.

Knowing that the magnitude of the horizontal force P is 8 kN, determine the stress at (a) point A, (b) point B.

The vertical portion of the press shown consists of a rectangular tube of wall thickness t 5 10 mm. Knowing that the press has been tightened on wooden planks being glued together until P 5 20 kN, determine the stress at (a) point A, (b) point B.

Solve Prob. 4.102, assuming that t 5 8 mm.

Determine the stress at points A and B, (a) for the loading shown, (b) if the 60-kN loads are applied at points 1 and 2 only.

Knowing that the allowable stress in section ABD is 10 ksi, deter- mine the largest force P that can be applied to the bracket shown.

Portions of a 12 3 12 -in. square bar have been bent to form the two machine components shown. Knowing that the allowable stress is 15 ksi, determine the maximum load that can be applied to each component.

The four forces shown are applied to a rigid plate supported by a solid steel post of radius a. Knowing that P 5 100 kN and a 5 40 mm, determine the maximum stress in the post when (a) the force at D is removed, (b) the forces at C and D are removed.

A milling operation was used to remove a portion of a solid bar of square cross section. Knowing that a 5 30 mm, d 5 20 mm, and sall 5 60 MPa, determine the magnitude P of the largest forces that can be safely applied at the centers of the ends of the bar.

A milling operation was used to remove a portion of a solid bar of square cross section. Forces of magnitude P 5 18 kN are applied at the centers of the ends of the bar. Knowing that a 5 30 mm and sall 5 135 MPa, determine the smallest allowable depth d of the milled portion of the bar.

A short column is made by nailing two 1 3 4-in. planks to a 2 3 4-in. timber. Determine the largest compressive stress created in the column by a 12-kip load applied as shown at the center of the top section of the timber if (a) the column is as described, (b) plank 1 is removed, (c) both planks are removed.

An offset h must be introduced into a solid circular rod of diameter d. Knowing that the maximum stress after the offset is introduced must not exceed 5 times the stress in the rod when it is straight, determine the largest offset that can be used.

An offset h must be introduced into a metal tube of 0.75-in. outer diameter and 0.08-in. wall thickness. Knowing that the maximum stress after the offset is introduced must not exceed 4 times the stress in the tube when it is straight, determine the largest offset that can be used.

A steel rod is welded to a steel plate to form the machine element shown. Knowing that the allowable stress is 135 MPa, determine (a) the largest force P that can be applied to the element, (b) the corresponding location of the neutral axis. Given: The centroid of the cross section is at C and Iz 5 4195 mm4.

A vertical rod is attached at point A to the cast iron hanger shown. Knowing that the allowable stresses in the hanger are sall 5 15 ksi and sall 5 212 ksi, determine the largest downward force and the largest upward force that can be exerted by the rod.

Solve Prob. 4.114, assuming that the vertical rod is attached at point B instead of point A.

Three steel plates, each of 25 3 150-mm cross section, are welded together to form a short H-shaped column. Later, for architectural reasons, a 25-mm strip is removed from each side of one of the flanges. Knowing that the load remains centric with respect to the original cross section and that the allowable stress is 100 MPa, determine the largest force P (a) that could be applied to the original column, (b) that can be applied to the modified column.

A vertical force P of magnitude 20 kips is applied at point C located on the axis of symmetry of the cross section of a short column. Knowing that y 5 5 in., determine (a) the stress at point A, (b) the stress at point B, (c) the location of the neutral axis

A vertical force P is applied at point C located on the axis of symmetry of the cross section of a short column. Determine the range of values of y for which tensile stresses do not occur in the column.

Knowing that the clamp shown has been tightened until P 5 400 N, determine (a) the stress at point A, (b) the stress at point B, (c) the location of the neutral axis of section a-a.

The four bars shown have the same cross-sectional area. For the given loadings, show that (a) the maximum compressive stresses are in the ratio 4:5:7:9, (b) the maximum tensile stresses are in the ratio 2:3:5:3. (Note: the cross section of the triangular bar is an equilateral triangle.)

The C-shaped steel bar is used as a dynamometer to determine the magnitude P of the forces shown. Knowing that the cross section of the bar is a square of side 40 mm and that the strain on the inner edge was measured and found to be 450 m, determine the magnitude P of the forces. Use E 5 200 GPa.

An eccentric force P is applied as shown to a steel bar of 25 3 90-mm cross section. The strains at A and B have been measured and found to be PA 5 1350 m PB 5 270 m Knowing that E 5 200 GPa, determine (a) the distance d, (b) the magnitude of the force P.

Solve Prob. 4.122, assuming that the measured strains are PA 5 1600 m PB 5 1420 m

A short length of a W8 3 31 rolled-steel shape supports a rigid plate on which two loads P and Q are applied as shown. The strains at two points A and B on the centerline of the outer faces of the flanges have been measured and found to be PA 5 2550 3 1026 in./in. PB 5 2680 3 1026 in./in. Knowing that E 5 29 3 106 psi, determine the magnitude of each load.

Solve Prob. 4.124, assuming that the measured strains are PA 5 135 3 1026 in./in. and PB 5 2450 3 1026 in./in.

The eccentric axial force P acts at point D, which must be located 25 mm below the top surface of the steel bar shown. For P 5 60 kN, determine (a) the depth d of the bar for which the tensile stress at point A is maximum, (b) the corresponding stress at point A.

The couple M is applied to a beam of the cross section shown in a plane forming an angle b with the vertical. Determine the stress at (a) point A, (b) point B, (c) point D.

The couple M is applied to a beam of the cross section shown in a plane forming an angle b with the vertical. Determine the stress at (a) point A, (b) point B, (c) point D.

The couple M is applied to a beam of the cross section shown in a plane forming an angle b with the vertical. Determine the stress at (a) point A, (b) point B, (c) point D.

The couple M is applied to a beam of the cross section shown in a plane forming an angle b with the vertical. Determine the stress at (a) point A, (b) point B, (c) point D.

The couple M is applied to a beam of the cross section shown in a plane forming an angle b with the vertical. Determine the stress at (a) point A, (b) point B, (c) point D.

The couple M is applied to a beam of the cross section shown in a plane forming an angle b with the vertical. Determine the stress at (a) point A, (b) point B, (c) point D.

The couple M is applied to a beam of the cross section shown in a plane forming an angle b with the vertical. Determine the stress at (a) point A, (b) point B, (c) point D.

The couple M is applied to a beam of the cross section shown in a plane forming an angle b with the vertical. Determine the stress at (a) point A, (b) point B, (c) point D.

The couple M acts in a vertical plane and is applied to a beam oriented as shown. Determine (a) the angle that the neutral axis forms with the horizontal, (b) the maximum tensile stress in the beam.

The couple M acts in a vertical plane and is applied to a beam oriented as shown. Determine (a) the angle that the neutral axis forms with the horizontal, (b) the maximum tensile stress in the beam.

The couple M acts in a vertical plane and is applied to a beam oriented as shown. Determine (a) the angle that the neutral axis forms with the horizontal, (b) the maximum tensile stress in the beam.

The couple M acts in a vertical plane and is applied to a beam oriented as shown. Determine (a) the angle that the neutral axis forms with the horizontal, (b) the maximum tensile stress in the beam.

The couple M acts in a vertical plane and is applied to a beam oriented as shown. Determine (a) the angle that the neutral axis forms with the horizontal, (b) the maximum tensile stress in the beam.

The couple M acts in a vertical plane and is applied to a beam oriented as shown. Determine (a) the angle that the neutral axis forms with the horizontal, (b) the maximum tensile stress in the beam.

The couple M acts in a vertical plane and is ap plied to a beam oriented as shown. Determine the stress at point A.

The couple M acts in a vertical plane and is ap- Problems 291 plied to a beam oriented as shown. Determine the stress at point A.

The couple M acts in a vertical plane and is ap- Problems 291 plied to a beam oriented as shown. Determine the stress at point A.

The tube shown has a uniform wall thickness of 12 mm. For the loading given, determine (a) the stress at points A and B, (b) the point where the neutral axis intersects line ABD.

Solve Prob. 4.144, assuming that the 28-kN force at point E is removed.

A rigid circular plate of 125-mm radius is attached to a solid 150 3 200-mm rectangular post, with the center of the plate directly above the center of the post. If a 4-kN force P is applied at E with u 5 308, determine (a) the stress at point A, (b) the stress at point B, (c) the point where the neutral axis intersects line ABD.

In Prob. 4.146, determine (a) the value of u for which the stress at D reaches its largest value, (b) the corresponding values of the stress at A, B, C, and D.

Knowing that P 5 90 kips, determine the largest distance a for which the maximum compressive stress does not exceed 18 ksi.

Knowing that a 5 1.25 in., determine the largest value of P that can be applied without exceeding either of the following allowable stresses: sten 5 10 ksi scomp 5 18 ksi

The Z section shown is subjected to a couple M0 acting in a vertical plane. Determine the largest permissible value of the moment M0 of the couple if the maximum stress is not to exceed 80 MPa. Given: Imax 5 2.28 3 1026 m4, Imin 5 0.23 3 1026 m4, principal axes 25.78 c and 64.38 a.

Solve Prob. 4.150, assuming that the couple M0 acts in a horizontal plane.

A beam having the cross section shown is subjected to a couple M0 that acts in a vertical plane. Determine the largest permissible value of the moment M0 of the couple if the maximum stress in the beam is not to exceed 12 ksi. Given: Iy 5 Iz 5 11.3 in4, A 5 4.75 in2, kmin 5 0.983 in. (Hint: By reason of symmetry, the principal axes form an angle of 458 with the coordinate axes. Use the relations Imin 5 Ak2 min and Imin 1 Imax 5 Iy 1 Iz.)

Solve Prob. 4.152, assuming that the couple M0 acts in a horizontal plane.

An extruded aluminum member having the cross section shown is subjected to a couple acting in a vertical plane. Determine the largest permissible value of the moment M0 of the couple if the maximum stress is not to exceed 12 ksi. Given: Imax 5 0.957 in4, Imin 5 0.427 in4, principal axes 29.48 a and 60.68 c.

A couple M0 acting in a vertical plane is applied to a W12 3 16 rolled-steel beam, whose web forms an angle u with the vertical. Denoting by s0 the maximum stress in the beam when u 5 0, determine the angle of inclination u of the beam for which the maximum stress is 2s0.

Show that, if a solid rectangular beam is bent by a couple applied Problems 293 in a plane containing one diagonal of a rectangular cross section, the neutral axis will lie along the other diagonal.

A beam of unsymmetric cross section is subjected to a couple M0 acting in the horizontal plane xz. Show that the stress at point A, of coordinates y and z, is sA 5 zIz 2 yIyz IyIz 2 I2 yz My where Iy, Iz, and Iyz denote the moments and product of inertia of the cross section with repect to the coordinate axes, and My the moment of the couple.

A beam of unsymmetric cross section is subjected to a couple M0 acting in the vertical plane xy. Show that the stress at point A, of coordinates y and z, is sA 5 2 yIy 2 zIyz IyIz 2 I2 yz Mz where Iy, Iz, and Iyz denote the moments and product of inertia of the cross section with respect to the coordinate axes, and Mz the moment of the couple.

(a) Show that, if a vertical force P is applied at point A of the section shown, the equation of the neutral axis BD is axA r2z b x 1 azA r2x b z 5 21 where rz and rx denote the radius of gyration of the cross section with respect to the z axis and the x axis, respectively. (b) Further show that, if a vertical force Q is applied at any point located on line BD, the stress at point A will be zero.

(a) Show that the stress at corner A of the prismatic member shown in Fig. P4.160a will be zero if the vertical force P is applied at a point located on the line x by6 1 z hy6 5 1 (b) Further show that, if no tensile stress is to occur in the member, the force P must be applied at a point located within the area bounded by the line found in part a and three similar lines corresponding to the condition of zero stress at B, C, and D, respectively. This area, shown in Fig. P4.160b, is known as the kern of the cross section.

For the machine component and loading shown, determine the stress at point A when (a) h 5 2 in., (b) h 5 2.6 in.

For the machine component and loading shown, determine the stress at points A and B when h 5 2.5 in.

The curved portion of the bar shown has an inner radius of 20 mm. Knowing that the allowable stress in the bar is 150 MPa, determine the largest permissible distance a from the line of action of the 3-kN force to the vertical plane containing the center of curvature of the bar

The curved portion of the bar shown has an inner radius of 20 mm. Knowing that the line of action of the 3-kN force is located at a distance a 5 60 mm from the vertical plane containing the center of curvature of the bar, determine the largest compressive stress in the bar.

The curved bar shown has a cross section of 40 3 60 mm and an inner radius r1 5 15 mm. For the loading shown determine the largest tensile and compressive stresses.

For the curved bar and loading shown, determine the percent error introduced in the computation of the maximum stress by assuming that the bar is straight. Consider the case when (a) r1 5 20 mm, (b) r1 5 200 mm, (c) r1 5 2 m.

The curved bar shown has a cross section of 30 3 30 mm. Knowing that a 5 60 mm, determine the stress at (a) point A, (b) point B.

The curved bar shown has a cross section of 30 3 30 mm. Knowing that the allowable compressive stress is 175 MPa, determine the largest allowable distance a.

Steel links having the cross section shown are available with different central angles b. Knowing that the allowable stress is 12 ksi, determine the largest force P that can be applied to a link for which b 5 908.

Solve Prob. 4.169, assuming that b 5 608.

A machine component has a T-shaped cross section that is orientated as shown. Knowing that M 5 2.5 kN ? m, determine the stress at (a) point A, (b) point B.

Assuming that the couple shown is replaced by a vertical 10-kN force attached at point D and acting downward, determine the stress at (a) point A, (b) point B.

Three plates are welded together to form the curved beam shown. For the given loading, determine the distance e between the neutral axis and the centroid of the cross section.

Three plates are welded together to form the curved beam shown. For M 5 8 kip ? in., determine the stress at (a) point A, (b) point B, (c) the centroid of the cross section.

The split ring shown has an inner radius r1 5 20 mm and a circular cross section of diameter d 5 32 mm. For the loading shown, determine the stress at (a) point A, (b) point B.

The split ring shown has an inner radius r1 5 16 mm and a circular cross section of diameter d 5 32 mm. For the loading shown, determine the stress at (a) point A, (b) point B

The curved bar shown has a circular cross section of 32-mm diameter. Problems 303 Determine the largest couple M that can be applied to the bar about a horizontal axis if the maximum stress is not to exceed 60 MPa.

The bar shown has a circular cross section of 0.6 in.-diameter. Knowing that a 5 1.2 in., determine the stress at (a) point A, (b) point B.

The bar shown has a circular cross section of 0.6-in. diameter. Knowing that the allowable stress is 8 ksi, determine the largest permissible distance a from the line of action of the 50-lb forces to the plane containing the center of curvature of the bar.

Knowing that P 5 10 kN, determine the stress at (a) point A, (b) point B.

Knowing that M 5 5 kip ? in., determine the stress at (a) point A, (b) point B.

Knowing that M 5 5 kip ? in., determine the stress at (a) point A, (b) point B.

For the curved beam and loading shown, determine the stress at (a) point A, (b) point B.

For the crane hook shown, determine the largest tensile stress in section a-a.

Knowing that the machine component shown has a trapezoidal cross section with a 5 3.5 in. and b 5 2.5 in., determine the stress at (a) point A, (b) point B.

Knowing that the machine component shown has a trapezoidal cross section with a 5 2.5 in. and b 5 3.5 in., determine the stress at (a) point A, (b) point B.

Show that if the cross section of a curved beam consists of two or more rectangles, the radius R of the neutral surface can be expressed as

Using Eq. (4.66), derive the expression for R given in Fig. 4.73 for A circular cross section.

A trapezoidal cross section.

A triangular cross section.

For a curved bar of rectangular cross section subjected to a bending couple M, show that the radial stress at the neutral surface is sr 5 M Ae a1 2 r1 R 2 ln R r1 b and compute the value of sr for the curved bar of Examples 4.10 and 4.11. (Hint: consider the free-body diagram of the portion of the beam located above the neutral surface.)

Two vertical forces are applied to a beam of the cross section shown. Determine the maximum tensile and compressive stresses in portion BC of the beam

Straight rods of 6-mm diameter and 30-m length are stored by coiling the rods inside a drum of 1.25-m inside diameter. Assuming that the yield strength is not exceeded, determine (a) the maximum stress in a coiled rod, (b) the corresponding bending moment in the rod. Use E 5 200 GPa.

Knowing that for the beam shown the allowable stress is 12 ksi in tension and 16 ksi in compression, determine the largest couple M that can be applied

In order to increase corrosion resistance, a 2-mm-thick cladding of aluminum has been added to a steel bar as shown. The modulus of elasticity is 200 GPa for steel and 70 GPa for aluminum. For a bending moment of 300 N ? m, determine (a) the maximum stress in the steel, (b) the maximum stress in the aluminum, (c) the radius of curvature of the bar.

A single vertical force P is applied to a short steel post as shown. Gages located at A, B, and C indicate the following strains: PA 5 2500 m PB 5 21000 m PC 5 2200 m Knowing that E 5 29 3 106 psi, determine (a) the magnitude of P, (b) the line of action of P, (c) the corresponding strain at the hidden edge of the post, where x 5 22.5 in. and z 5 21.5 in.

For the split ring shown, determine the stress at (a) point A, (b) point B.

A couple M of moment 8 kN ? m acting in a vertical plane is applied to a W200 3 19.3 rolled-steel beam as shown. Determine (a) the angle that the neutral axis forms with the horizontal plane, (b) the maximum stress in the beam.

Determine the maximum stress in each of the two machine elements shown.

The shape shown was formed by bending a thin steel plate. Assuming that the thickness t is small compared to the length a of a side of the shape, determine the stress (a) at A, (b) at B, (c) at C.

Three 120 3 10-mm steel plates have been welded together to form the beam shown. Assuming that the steel is elastoplastic with E 5 200 GPa and sY 5 300 MPa, determine (a) the bending moment for which the plastic zones at the top and bottom of the beam are 40 mm thick, (b) the corresponding radius of curvature of the beam.

A short column is made by nailing four 1 3 4-in. planks to a 4 3 4-in. timber. Determine the largest compressive stress created in the column by a 16-kip load applied as shown in the center of the top section of the timber if (a) the column is as described, (b) plank 1 is removed, (c) planks 1 and 2 are removed, (d) planks 1, 2, and 3 are removed, (e) all planks are removed.

Two thin strips of the same material and same cross section are bent by couples of the same magnitude and glued together. After the two surfaces of contact have been securely bonded, the couples are removed. Denoting by s1 the maximum stress and by r1 the radius of curvature of each strip while the couples were applied, determine (a) the final stresses at points A, B, C, and D, (b) the final radius of curvature.