I solved this question step wise step. Please like my answer. I represent all I centre's by red pen.
4-8 Locate all instant centers for the mechanism shown in Fig. P4-8. 19.IR 66.7 57.2 28.6...
Note: to graphically locate the instant centers, you will have to use the exact diagrams provided. One way to do this is to copy the diagram on to a blank PowerPoint slide, print it out and start finding the instant centers. Be sure to leave enough room if the instant centers are far from the mechanism links. When finding instant centers, highlight them (the point and the label) with a different color. (You could write the labels in color, circle...
only question 4 Name: Student ID A mechanism of a method and analytical method to analysis the reciprocat center icalethng saw is shown in figure below. Use instant motion of the blade. Crank wheel 50 Blade 3.2130 65 Figure 1. A mechanism of a reciprocating saw 1. Draw a kinematic diagram of the mechanism that produces the reciprocating 2. Graphically determine the location of all instant centers for the mechanism (10 3. Use the instant center method to graphically determine...
4-34 Refer to Fig. P4-34. Determine the forces acting on each member of the frame due to the 4-kN load shown. Neglect the weights of all members srwoda bsol 10 m 0.5 m 0.5m 4 kN 0.7 m FIGURE P4-34
8-4. Find all the end moments by slope-deflection for the rigid frame shown in Fig. 8-22. Draw the moment diagram, and sketch the deformed structure I04 5 ft 5 ft El constant 10 ft Figure 8-22
A link is offset, as shown in Fig. 4-19 below, to provide clearance for adjacent parts. Determine the maximum shear stress and specify its location (or locations). Answer = 1970 psi; points A and B Please show all work. The answer is provided too. Thank You! 18. A link is offset, as shown in Fig. 4-19 below. to provide clearance for adjacent parts. Determine the maxi mum shear stress and specify its location (or locations). Ans. 1970 psi; points A...
2. In the mechanism shown in Fig.2, the driving link is link A"A and the angle measured from the positive x-axis to this link is θ2 θ+ Φ. AA0.9 in A*B* = 1.7 in AB- 2.6 in h0.8 in 8-6" B* 120° Figure 2: (a) What is the mobility of the mechanism (b) Using the loop equation, derive an expression for the length AB and angle θ4 between link 4 and the horizontal asa function of the input angle θ2.
11:34 Practice Problem on Dijkstra's.. 12 8 4 LI P4. Consider the network shown in Problem P3. Using Dijkstra's algorithm, work using a table similar to Table 5.1 D,do the following: a. Compute the shortest path from t to all network nodes.
2.3-3 For the signal g(t) shown in Fig. P2.3-3, sketch (a) g(t - 4); (b) 8 (3): (c) g(21-4): (d) (2-1). Hint Recall that replacing t with 1-T delays the signal by T. Thus, g (2 - 4) is 8(21) with replaced by : - 2. Similarly, 8 (2-1) is g(-1) with / replaced by:- 2. Figure P.2.3-3
4. (15pts) In the structure shown in Fig. 1, an 8-mm-diameter pin is used at A, and 12-mm-diameter pins used at B and D. Knowing that the ultimate shearing stress is 100 MPa at all connections and that the ultimate normal stress is 250 MPa in each of the two links jointing B and D, determine the allowable load P if an overall factor of safety of 3.0 is desired. Top view -200 mm-fe180 mm-12 mm B с Smm 20...
i want just (F) 2. (40 points) In the engine mechanism shown in fig. 2, the crank AB has a constant clockwise angular velocity of 2000 rpm.And the connecting rod is a uniform, slender rod whose center of mass is in its geometric center G. For the crank position shown determine l 8 in 3in Figure 2: Problem 2 (a) (2.5 points) The velocity of B (b) (5 points) The angular velocity of the connecting rod BD, and the velocity...