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Draw a 7 inch by 3.5 inch rectangular block and illustrate a 30 pound force vector at 15 degrees above the X-axis and a 20 pound force vector at 30 degrees below the X-axis. Add one force vector onto the other to compute the Resultant. Measure the magnitude and direction of the Resultant. Save the drawing as Adding Vectors.dwg

Draw a 7 inch by 3.5 inch rectangular block and illustrate a 32 pound force vector at 45 degrees above the X-axis, a 25 pound force vector at 10 degrees above the X-axis and a 17.5 pound force vector at 40 degrees below the X-axis. Add one force vector onto the other to compute the Resultant. Measure the magnitude and direction of the Resultant. Save the drawing as Adding Vectors 2.dwg

Draw a 7 inch by 3.5 inch rectangular block and illustrate a 22.75 pound force vector at 15.95 degrees above the X-axis, a 23.25 pound force vector at 12.4 degrees below the X-axis and a 7.5 pound force vector at 180 degrees around the X-axis. Add one force vector onto the other to compute the Resultant. Measure the magnitude and direction of the Resultant. Save the drawing as Adding Vectors 3.dwg

Draw a 7 inch by 3.5 inch by 1.5 inch solid block and illustrate a 22.25 pound force vector at 45 degrees above the X-axis and a 30 pound force vector at 12.5 degrees below the X-axis. Add one more vector of 21 pounds force at 45 degrees above the XY-plane. Measure the magnitude and direction of the Resultant. Save the drawing as Adding 3D Vectors.dwg

Draw a 7 inch by 3.5 inch rectangular block and illustrate a 28.75 pound force vector at 33.99 degrees above the X-axis, a 23.25 pound force vector at 19.90 degrees below the X-axis and a 12.00 pound force vector at 180 degrees around the X-axis. Add one force vector onto the other to compute the Resultant. Measure the magnitude and direction of the Resultant. Save the drawing as Adding Vectors 5.dwg

Draw a 7 inch by 3.5 inch rectangular block and illustrate a 30.88 pound force vector at 40.49 degrees above the X-axis, a 22.87 pound force vector at 39.48 degrees below the X-axis and a 19.20 pound force vector at 150 degrees around the X-axis. Add one force vector onto the other to compute the Resultant. Measure the magnitude and direction of the Resultant. Save the drawing as Adding Vectors 6.dwg

Draw a 7 inch by 3.5 inch by 1.5 inch solid block and illustrate a 31.50 pound force vector at 53.90 degrees above the X-axis and a 21.50 pound force vector at 27.50 degrees below the X-axis. Add one more vector of 27.55 pounds force at 52.50 degrees above the XY-plane. Measure the magnitude and direction of the Resultant. Save the drawing as Adding 3D Vectors 2.dwg

Draw a solid can containing a solid cylinder representing the amount of sand within. Illustrate a 2.0-pound force vector at 90 degrees above the XY plane and a 2.0-pound force vector at 90 degrees below the XY plane. Save the drawing as Equilibrium Problem 1.dwg

Draw a solid can containing a solid cylinder representing the amount of sand within. Illustrate a 2.0-pound force vector at 90 degrees below the XY plane and two counteracting force vectors at 30 degrees above the XY plane. Determine the size of the two force vectors at 30 degrees above the XY plane. Save the drawing as Equilibrium Problem 2.dwg

Draw a solid can containing a solid cylinder representing the amount of sand within. Illustrate a 2.0-pound force vector at 90 degrees below the XY plane and two counteracting force vectors at 20 degrees above the XY plane. Determine the size of the two force vectors at 20 degrees above the XY plane. Save the drawing as Equilibrium Problem 3.dwg

Draw a solid board that is 0.5 inch by 3.5 inch by 24.0 inch. Illustrate a 2.0-pound force vector at 90 degrees below the XY plane that is 8.0 inches from the rotation point. Illustrate a 2.0-pound force vector at 90 degrees below the XY plane that is 12.0 inches from the rotation point on the opposite side of the first force vector. Determine the size of the second force vector by using the formula M = Fs. Save the drawing as Equilibrium Problem 4.dwg