Question: A circular nylon pipe supports a downward

> For what values of c does the curve y = cx3 + ex have inflection points?

> If a ball is thrown vertically upward with a velocity of 80 ft/s, then its height after t seconds is s = 80t - 16t2. (a) What is the maximum height reached by the ball? (b) What is the velocity of the ball when it is 96 ft above the ground on its way up?

> If P(a, a2) is any point on the parabola y = x2, except for the origin, let Q be the point where the normal line at P intersects the parabola again (see the figure). (a) Show that the y-coordinate of Q is smallest when a = 1/ 2 . (b) Show that the line s

> Sketch the set of all points (x, y) such that |x + y | ≤ ex.

> Find the highest and lowest points on the curve x2 + xy + y2 = 12.

> Calculate the given quantity if a = i + j - 2k b = 3i - 2j + k c = j - 5k (a). 2a + 3b (b). |b | (c). a ∙ b (d). a × b (e). |b × c | (f). a ∙ (b × c) (g). c × c (h). a × (b × c) (i). compa b (j). proja b (k). The angle between a and b (correct to th

> Differentiate the function. f (x) = ln (1/x)

> (a). Find an equation of the sphere that passes through the point (6, -2, 3) and has center (-1, 2, 1). (b). Find the curve in which this sphere intersects the yz-plane. (c). Find the center and radius of the sphere x2 + y2 + z2 - 8x + 2y + 6z + 1 = 0

> An ellipsoid is created by rotating the ellipse 4x2 + y2 – 16 about the x-axis. Find an equation of the ellipsoid.

> (a). Find an equation of the plane that passes through the points A (2, 1, 1), B (-1, -1, 10), and C (1, 3, -4). (b). Find symmetric equations for the line through B that is perpendicular to the plane in part (a). (c). A second plane passes through (2, 0

> Find an equation of the plane through the line of intersection of the planes x - z = 1 and y + 2z = 3 and perpendicular to the plane x + y - 2z = 1.

> The height (in meters) of a projectile shot vertically upward from a point 2 m above ground level with an initial velocity of 24.5 m/s is h = 2 + 24.5t - 4.9t2 after t seconds. (a) Find the velocity after 2 s and after 4 s. (b) When does the projectile r

> Determine whether the lines given by the symmetric equations are parallel, skew, or intersecting. x - х — 1 у - 2 г-3 y z - 3 2 3 4 у — 3 y -1 х+1 z + 5

> Find the distance from the origin to the line x = 1 + t, y = 2 - t, z = 21 + 2t.

> Find the point in which the line with parametric equations x = 2 - t, y = 1 + 3t, z = 4t intersects the plane 2x - y + z = 2.

> Find an equation of the plane. The plane through (1, 2, -2) that contains the line x = 2t, y = 3 - t, z = 1 + 3t

> Find an equation of the plane. The plane through (3, -1, 1), (4, 0, 2), and (6, 3, 1)

> Reduce the equation to one of the standard forms, classify the surface, and sketch it. x2 - y2 - z2 - 4x - 2z + 3 = 0

> A boat is pulled onto shore using two ropes, as shown in the diagram. If a force of 255 N is needed, find the magnitude of the force in each rope. 20° 255 N 30°

> Find the acute angle between two diagonals of a cube.

> Show that if a, b, and c are in V3, then (a × b) ∙ [(b × c) × (c × a) g = [a ∙ (b × c)]2

> Suppose that u ∙ (v × w) = 2. Find (a). (u × v) ∙ w (b). u ∙ (w × v) (c). v ∙ (u × w) (d). (u × v) ∙ v

> (a). Sketch the graph of y = ex as a curve in R2. (b). Sketch the graph of y = ex as a surface in R3. (c). Describe and sketch the surface z = ey.

> Differentiate the function. y = 1 / ln x

> (a). What does the equation y = x2 represent as a curve in R2? (b). What does it represent as a surface in R3? (c). What does the equation z = y2 represent?

> Show that the curve of intersection of the surfaces x2 + 2y2 - z2 + 3x = 1 and 2x2 + 4y2 - 2z2 - 5y = 0 lies in a plane.

> Show that if the point (a, b, c) lies on the hyperbolic paraboloid z = y2 - x2, then the lines with parametric equations x = a + t, y = b + t, z = c + 2 (b 0- a) t and x = a + t, y = b - t, z = c – 2 (b + a) t both lie entirely on this paraboloid. (This

> A cooling tower for a nuclear reactor is to be constructed in the shape of a hyperboloid of one sheet (see the photo on page 839). The diameter at the base is 280 m and the minimum diameter, 500 m above the base, is 200 m. Find an equation for the tower.

> Sketch the graph of a function that satisfies the given conditions. f (0) = 0, f &acirc;&#128;&#152;(-2) = f &acirc;&#128;&#152;(1) = f &acirc;&#128;&#152;(9) = 0, lim f(x) = 0, lim f(x) = -∞, f'(x) < 0 on (-o0, -2), (1, 6), and (9, 0), f'(x) > 0 on

> Segments AB and BCD of beam ABCD are pin connected at x = 4 m. The beam is supported by a sliding support at A and roller supports at C and D (see figure). A triangularly distributed load with peak intensity of 80 N/m acts on BC. A concentrated moment is

> Segments AB and BC of beam ABC are pin connected a small distance to the right of joint B (see figure). Axial loads act at A and at the mid-span of AB. A concentrated moment is applied at joint B. (a) Find reactions at supports A, B, and C. (b) Find inte

> Find support reactions at A and B and then calculate the axial force N, shear force V, and bending moment M at mid-span of AB. Let L = 4 m, q0 = 160 N/m , P = 200 N, and Mo = 380 Nm?. Mo B L/2

> Find support reactions at A and B and then calculate the axial force N, shear force V, and bending moment M at mid-span of AB. Let L = 14 ft, qo 512 lb/ft, P = 50 lb, and M0 = 300 lb-ft. Mo 4 B 3 C L L/2 A

> Two separate cables AC and BC support a sign structure of weight W = 1575 lb attached to a building. The sign is also supported by a pin support at O and a lateral restraint in the z-direction at D. (a) Find the tension in each cable. Neglect the mass of

> A round bar ABC of length 2L (see figure) rotates about an axis through the midpoint C with constant angular speed &Iuml;&#137; (radians per second). The material of the bar has weight density g. (a) Derive a formula for the tensile stress x s in the bar

> Two gondolas on a ski lift are locked in the position show in the figure while repairs are being made elsewhere. The distance between support towers is L 5100 ft. The length of each cable segment under gondolas weighing WB = 450 lb and WC =650 lb are DAB

> A crane boom of mass 450 kg with its center of mass at C is stabilized by two cables AQ and BQ (Ae = 304 mm2 for each cable) as shown in the figure. A load P = 20 kN is supported at point D. The crane boom lies in the y-z plane. (a) Find the tension forc

> An L-shaped reinforced concrete slab 12&Acirc;&nbsp;ft&Acirc;&nbsp;&Atilde;&#151;&Acirc;&nbsp;12&Acirc;&nbsp;ft, with a 6 ft &Atilde;&#151; 6 ft cut-out and thickness t = 9.0 in, is lifted by three cables attached at O, B, and D, as shown in the figure.

> Solve the preceding problem if the mass of the tailgate is MT = 27 kg and that of the crate is MC = 68 kg. Use dimensions H = 305 mm, L&Acirc;&nbsp;=&Acirc;&nbsp;406&Acirc;&nbsp;mm, dC&Acirc;&nbsp;=&Acirc;&nbsp;460 mm, and dT = 350 mm. The cable cross-se

> A cable and pulley system at D is used to bring a 230-kg pole (ACB) to a vertical position, as shown in the figure part a. The cable has tensile force T and is attached at C. The length L of the pole is 6.0&Acirc;&nbsp;m, the outer diameter is d = 140 mm

> A pickup truck tailgate supports a crate where WC = 150 lb, as shown in the figure. The tailgate weighs WT = 60 lb and is supported by two cables (only one is shown in the figure). Each cable has an effective cross-sectional area AE = 0.017 in2. (a) Find

> A long retaining wall is braced by wood shores set at an angle of 308 and supported by concrete thrust blocks, as shown in the first part of the figure. The shores are evenly spaced at 3 m apart. For analysis purposes, the wall and shores are idealized a

> Two steel wires support a moveable overhead camera weighing W = 28 lb (see figure part a) used for close-up viewing of field action at sporting events. At some instant, wire 1 is at an angle a = 228 to the horizontal and wire 2 is at angle b = 408. Wires

> A car weighing 130 kN when fully loaded is pulled slowly up a steep inclined track by a steel cable (see figure). The cable has an effective cross-sectional area of 490 mm2, and the angle a of the incline is 308. (a) Calculate the tensile stress st in th

> The cross section of a concrete corner column that is loaded uniformly in compression is shown in the figure. A circular pipe chase cut-out of 10 in. in diameter runs the height of the column (see figure). (a) Determine the average compression stress c s

> A circular aluminum tube with a length of L = 420 mm is loaded in compression by forces P (see figure). The hollow segment of length L/3 has outside and inside diameters of 60 mm and 35 mm, respectively. The solid segment of length 2L/3 has a diameter of

> A bicycle rider wants to compare the effectiveness of cantilever hand brakes (see figure part a) versus V brakes (figure part b). (a) Calculate the braking force RB at the wheel rims for each of the bicycle brake systems shown. Assume that all forces act

> A force P of 70 N is applied by a rider to the front hand brake of a bicycle (P is the resultant of an evenly distributed pressure). As the hand brake pivots at A, a tension T develops in the 460-mm long brake cable (Ae = 1 .075 mm2), which elongates by

> A circular tube AB is fixed at one end and free at the other end. The tube is subjected to axial force at joint B. If the outer diameter of the tube is 3&Acirc;&nbsp;in. and the thickness is &Acirc;&frac34; in., calculate the maximum normal stress in the

> A square steel tube of a length L = 20 ft and width b2 = 10.0 in. is hoisted by a crane (see figure). The tube hangs from a pin of diameter d that is held by the cables at points A and B. The cross section is a hollow square with an inner dimension b1 =

> The data shown in the accompanying table are from a tensile test of high-strength steel. The test specimen has a diameter of 0.505 in. and a gage length of 2.00 in. At fracture, the elongation between the gage marks is 0.12&Acirc;&nbsp;in. and the minimu

> A specimen of a methacrylate plastic is tested in tension at room temperature (see figure), producing the stress-strain data listed in the accompanying table. Plot the stress-strain curve and determine the proportional limit, modulus of elasticity (which

> A symmetrical framework consisting of three pin-connected bars is loaded by a force P (see figure). The angle between the inclined bars and the horizontal is 52 a 58. The axial strain in the middle bar is measured as 0.036. Determine the tensile stress i

> The strength-to-weight ratio of a structural material is defined as its load-carrying capacity divided by its weight. For materials in tension, use a characteristic tensile stress obtained from a stress strain curve as a measure of strength. For instance

> Three different materials, designated A, B, and C, are tested in tension using test specimens having diameters of 0.505 in. and gage lengths of 2.0 in. (see figure). At failure, the distances between the gage marks are found to be 2.13, 2.48, and 2.78 in

> A steel riser pipe hangs from a drill rig located offshore in deep water. (a) What is the greatest length (meters) it can have without breaking if the pipe is suspended in the air and the ultimate strength (or breaking strength) is 550 MPa? (b) If the sa

> A wire of length L = 4 ft and diameter d&Acirc;&nbsp;=&Acirc;&nbsp;0.125 in. is stretched by tensile forces P = 600 lb. The wire is made of a copper alloy having a stress strain relationship that may be described mathematically by in which &Icirc;&micro;

> A continuous cable (diameter 6 mm) with tension force T is attached to a horizontal frame member at B and C to support a sign structure. The cable passes over a small frictionless pulley at D. The wire is made of a copper alloy, and the stress-strain rel

> An aluminum bar has length L = 6 ft and diameter d = 1.375 in. The stress-strain curve for the aluminum is shown in Fig.&Acirc;&nbsp;1-34. The initial straight line part of the curve has a slope (modulus of elasticity) of 10.61 063 psi. The bar is loaded

> A circular bar of magnesium alloy is 750 mm long. The stress-strain diagram for the material is shown in the figure. The bar is loaded in tension to an elongation of 6.0 mm, and then the load is removed. (a) What is the permanent set of the bar? (b) If t

> A suspender on a suspension bridge consists of a cable that passes over the main cable (see figure) and supports the bridge deck, which is far below. The suspender is held in position by a metal tie that is prevented from sliding downward by clamps aroun

> A bar made of structural steel having the stress-strain diagram shown in the figure has a length of 48 in. The yield stress of the steel is 42 ksi, and the slope of the initial linear part of the stress-strain curve (modulus of elasticity) is 30 &Atilde;

> A bar of length 2.0 m is made of a structural steel having the stress-strain diagram shown in the figure. The yield stress of the steel is 250 MPa, and the slope of the initial linear part of the stress-strain curve (modulus of elasticity) is 200 GPa. Th

> Three round, copper alloy bars having the same length L but different shapes are shown in the figure. The first bar has a diameter d over its entire length, the second has a diameter d over one-fifth of its length, and the third has a diameter d over one

> A hollow, brass circular pipe ABC (see figure) supports a load P1 = 26.5 kips acting at the top. A second load P2 = 22.0 kips is uniformly distributed around the cap plate at B. The diameters and thicknesses of the upper and lower parts of the pipe are d

> A tensile test is performed on a brass specimen 10 mm in diameter using a gage length of 50 mm (see figure). When the tensile load P reaches a value of 20 kN, the distance between the gage marks has increased by 0.122 mm. (a) What is the modulus of elast

> A bar of monel metal with a length L&Acirc;&nbsp;= 9&Acirc;&nbsp;in. and a diameter d = 0.225 in. is loaded axially by a tensile force P (see figure). If the bar elongates by 0.0195 in., what is the decrease in diameter d? What is the magnitude of the lo

> A circular aluminum tube of length L&Acirc;&nbsp;=&Acirc;&nbsp;600&Acirc;&nbsp;mm is loaded in compression by forces P (see figure). The outside and inside diameters are d2 = 75 mm and d1 = 63 mm, respectively. A strain gage is placed on the outside of t

> A polyethylene bar having rectangular cross section with a width 7.35 in. and depth 7 in. is placed inside a hollow steel square section with side dimension of 8 in. The polyethylene bar is then compressed by an axial force&Acirc;&nbsp;P. At what value o

> A square plastic bar (length Lp, side dimension sp = 193 mm) is inserted inside a hollow, square, cast iron tube (length Lc = 400 mm, side sc = 200 mm, and thickness tc = 3 mm). (a) What is the required initial length Lp of the plastic bar so that, when

> A polyethylene bar with a diameter d1 = 4.0 in. is placed inside a steel tube with an inner diameter d2 = 4.01 in. (see figure). The polyethylene bar is then compressed by an axial force P. At what value of the force P will the space between the polyethy

> Continuous cable ADB runs over a small frictionless pulley at D to support beam OABC that is part of an entrance canopy for a building (see figure). Assume that the canopy segment has a weight W = 1700 lb. (a) Find the required cross-sectional area of ca

> A round bar of 10 mm diameter is made of aluminum alloy 7075-T6 (see figure). When the bar is stretched by axial forces P, its diameter decreases by 0.016 mm. Find the magnitude of the load P. Obtain the material properties from Appendix I. |d= 10 m

> A high-strength steel bar used in a large crane has a diameter d = 2.00 in. (see figure). The steel has a modulus of elasticity E = 29 &Atilde;&#151; 106 psi and Poisson&acirc;&#128;&#153;s ratio is n = 0.29. Because of clearance requirements, the diamet

> A bicycle chain consists of a series of small links, where each are 12 mm long between the centers of the pins (see figure). You might wish to examine a bicycle chain and observe its construction. Note particularly the pins, which have a diameter of 2.5

> A basketball player hangs on the rim after a dunk. He applies equal forces P1 = P2 = 110 lb at both A and B (see joint coordinates in the figure). Forces P1&Acirc;&nbsp;and P2 act parallel to the y-z plane. (a) Find the reactions at the support bracket (

> A cargo ship is tied down to marine bollards at a number of points along its length while its cargo is unloaded by a container handling crane. Each bollard is fastened to the wharf using anchor bolts. Three cables having known tension force magnitudes F1

> The top portion of a pole saw used to trim small branches from trees is shown in the figure part&Acirc;&nbsp;a. The cutting blade BCD (see figure parts a and c) applies a force P at point D. Ignore the effect of the weak return spring attached to the cut

> A single steel strut AB with a diameter ds = 8mm supports the vehicle engine hood of a mass 20 kg that pivots about hinges at C and D (see figure parts a and b). The strut is bent into a loop at its end and then attached to a bolt at A with a diameter db

> A spray nozzle for a garden hose requires a force F = 5 lb to open the spring-loaded spray chamber AB. The nozzle hand grip pivots about a pin through a flange at O. Each of the two flanges has a thickness t = 1/16 in., and the pin has a diameter dp = 1/

> A removable sign post on a hurricane evacuation route (see figure part a) consists of an upper pole with a slotted base plate bolted to a short post anchored in the ground. The lower post is capped with a separate conventional base plate having four hole

> A shock mount constructed as shown in the figure is used to support a delicate instrument. The mount consists of an outer steel tube with inside diameter b, a central steel bar of diameter d that supports the load P, and a hollow rubber cylinder (height&

> Cable DB supports canopy beam OABC as shown in the figure. Find the required cross-sectional area of cable BD if the allowable normal stress is 125&Acirc;&nbsp;MPa. Determine the required diameter of the pins at O, B, and D if the allowable stress in she

> The clamp shown in the figure supports a load hanging from the lower flange of a steel beam. The clamp consists of two arms (A and B) joined by a pin at C. The pin has a diameter d = 12 mm. Because arm B straddles arm A, the pin is in double shear. Line

> A hitch-mounted bicycle rack is designed to carry up to four 30-lb bikes mounted on and strapped to two arms GH (see bike loads in the figure part a). The rack is attached to the vehicle at A and is assumed to be like a cantilever beam ABCDGH (figure par

> A flexible connection consisting of rubber pads (thickness t = 9 mm) bonded to steel plates is shown in the figure. The pads are 160 mm long and 80 mm wide. (a) Find the average shear strain aver g in the rubber if the force P = 16 kN and the shear modul

> A steel riser pipe hangs from a drill rig located offshore in deep water (see figure). Separate segments are joined using bolted flange plages (see figure part b and photo). Assume that there are six bolts at each pipe segment connection. Assume that the

> A punch for making a slotted hole in ID cards is shown in the figure&Acirc;&nbsp;part a. Assume that the hole produced by the punch can be described as a rectangle (12mm &Atilde;&#151; 3 mm) with two half circles (r = 1 5 mm) on the left and the right si

> A joint between two glass plates A and B is filled with a flexible epoxy that bonds securely to the glass. The height of the joint is h = 0.5 in, its length is L = 30 in, and its thickness is t = 0.5 in. Shear force of V = 25 kips is applied to the joint

> A steel punch consists of two shafts: upper shaft and lower shaft. Assume that the upper shaft has a diameter d1 =24 mm and the bottom shaft has a diameter d2 = 16 mm. The punch is used to insert a hole in a 4 mm plate, as shown in the figure. If a force

> A joint between two concrete slabs A and B is filled with a flexible epoxy that bonds securely to the concrete (see figure). The height of the joint is h = 4.0in, its length is L = 40 in., and its thickness is t = 0.5 in. Under the action of shear forces

> An elastomeric bearing pad consisting of two steel plates bonded to a chloroprene elastomer (an artificial rubber) is subjected to a shear force V during a static loading test (see figure). The pad has dimensions a = 125 mm and b = 240 mm, and the elasto

> A special-purpose eye bolt with a shank diameter d = 0.50 in. passes through a hole in a steel plate of thickness tp = 0.75 in. (see figure) and is secured by a nut with thickness t = 0.25 in. The hexagonal nut bears directly against the steel plate. The

> A plane truss has joint loads P, P2, and P3 at joints D, C, and B, respectively (see figure) where load variable P = 5200 lb. All members have two end plates that are pin- connected to gusset plates. Each end plate has a thickness tp = 0.625 in, and all

> A steel plate of dimensions 2.5 &Atilde;&#151; 1.5 &Atilde;&#151; 0.08 m and weighing 23.1 kN is hoisted by steel cables with lengths L1 = 3.2m and L2 = 3.9m that are each attached to the plate by a clevis and pin (see figure). The pins through the clevi

> The inclined ladder AB supports a house painter (85 kg) at C and the weight (q = 4 0N/m) of the ladder itself. Each ladder rail (tr = 4 mm) is supported by a shoe (ts = 5 mm) that is attached to the ladder rail by a bolt of diameter dp = 8mm. Typica

> The upper deck of a football stadium is supported by braces, each of which transfers a load P = 160 kips to the base of a column (see figure part a). A cap plate at the bottom of the brace distributes the load P to four flange plates (tf = 1 in.) through

> Truss members supporting a roof are connected to a 26-mm-thick gusset plate by a 22-mm diameter pin, as shown in the figure and photo. The two end plates on the truss members are each 14 mm thick. (a) If the load P = 80 kN, what is the largest bearing st

> The piston in an engine is attached to a connecting rod AB, which in turn is connected to a crank arm BC (see figure). The piston slides without friction in a cylinder and is subjected to a force P (assumed to be constant) while moving to the right in th

> A sign of weight W is supported at its base by four bolts anchored in a concrete footing. Wind pressure p acts normal to the surface of the sign; the resultant of the uniform wind pressure is force F at the center of pressure (C.P.). The wind force is as