HEAT+MASS TRANSFER-PHYSICAL ACCESS CODE
6th Edition
ISBN: 9781265896676
Author: CENGEL
Publisher: MCG CUSTOM
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A telemetry system is used to quantify kinematic values of a ski jumper immediately before the jumper leaves the ramp. According to the system r=560 ft , r˙=−105 ft/s , r¨=−10 ft/s2 , θ=25° , θ˙=0.07 rad/s , θ¨=0.06 rad/s2 Determine the velocity of the skier immediately before leaving the jump.
The velocity of the skier immediately before leaving the jump along with its direction is ? I have 112.08 ft/s but can't seem to get the direction correct. Determine the acceleration of the skier at this instant.
At this instant, the acceleration of the skier along with its direction is ? acceleration is 22.8 ft/s^2 but need help with direction. Need help with velocity direction and acceleration direction please.
For Problems 18-22 (Table 7-27), design a V-belt drive.
Specify the belt size, the sheave sizes, the number of belts, the
actual output speed, and the center distance.
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- only 41arrow_forwardNormal and tangential components-relate to x-y coordinates A race car enters the circular portion of a track that has a radius of 65 m. When the car enters the curve at point P, it is traveling with a speed of 120 km/h that is increasing at 5 m/s^2 . Three seconds later, determine the x and y components of velocity and acceleration of the car. I need help with finding the y component of the total acceleration. I had put -32 but its incorrect. but i keep getting figures around that numberarrow_forwardThe bracket BCD is hinged at C and attached to a control cable at B. Let F₁ = 275 N and F2 = 275 N. F1 B a=0.18 m C A 0.4 m -0.4 m- 0.24 m Determine the reaction at C. The reaction at C N Z F2 Darrow_forward
- Consider the angle bar shown in the given figure A W 240 mm B 80 mm Draw the free-body diagram needed to determine the reactions at A and B when a = 150 mm. This problem could also be approached as a 3-force body using method of Section 4.2B.arrow_forwardA telemetry system is used to quantify kinematic values of a ski jumper immediately before the jumper leaves the ramp. According to the system r=560 ft , r˙=−105 ft/s , r¨=−10 ft/s2 , θ=25° , θ˙=0.07 rad/s , θ¨=0.06 rad/s2 Determine the velocity of the skier immediately before leaving the jump. The velocity of the skier immediately before leaving the jump along with its direction is ? I have 112.08 ft/s but can't seem to get the direction correct. Determine the acceleration of the skier at this instant. At this instant, the acceleration of the skier along with its direction is ? acceleration is 22.8 ft/s^2 but need help with direction. Need help with velocity direction and acceleration direction please.arrow_forwardFor the stop bracket shown, locate the x coordinate of the center of gravity. Consider a = = 16.50 mm. 34 mm 62 mm 51 mm 10 mm 100 mm 88 mm 55 mm 45 mm The x coordinate of the center of gravity is mm.arrow_forward
- In the given figure, the bent rod ABEF is supported by bearings at C and D and by wire AH. The portion AB of the rod is 250 mm long, and the load W is 580 N. Assume that the bearing at D does not exert any axial thrust. H B A с 30° 250 mm D Z 50 mm 300 mm F 250 mm 50 mm W Draw the free-body diagram needed to determine the tension in wire AH and the reactions at C and D.arrow_forwardA 10-ft boom is acted upon by the 810-lb force as shown in the figure. D 6 ft 6 ft E B 7 ft C 6 ft x 4 ft W Draw the free-body diagram needed to determine the tension in each cable and the reaction at the ball-and-socket joint at A.arrow_forwardLocate the center of gravity of the sheet-metal form shown. Given: r = 26.40 mm . 50 mm 40 mm X 150 mm The center of gravity (✗) of the sheet-metal form is The center of gravity (Y) of the sheet-metal form is The center of gravity ( Z ) of the sheet-metal form is mm. mm. (Round the final answer to three decimal places.) mm.arrow_forward
- Determine the reactions at the beam supports for the given loading if W = 300 lb/ft . W 6 ft A 9 ft. 6 ft- The reaction at Bis lb. The reaction at A is lb. Barrow_forwardIn the given figure, the bent rod ABEF is supported by bearings at C and D and by wire AH. The portion AB of the rod is 250 mm long, and the load W is 580 N. Assume that the bearing at D does not exert any axial thrust. 30° 250 mm 300 mm 50 mm H B C D 50 mm W 250 mm Determine the reactions at C and D. (Include a minus sign if necessary.) The reaction at Cis N) j + N)k The reaction at Dis N) j + ( N)karrow_forwardConsider the angle bar shown in the given figure A B W 240 mm- 80 mm Determine the reactions at A and B when a = 150 mm and W = 320 N. The reaction at A is N ZI The reaction at Bis N.arrow_forward
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