Please answer the following questions, (a) Determine the velocity that the object releases from the inclined ramp at B. (b) Determine the vertical velocity component at C. (c) If the object enters the pipeline at C with the above velocity when s=0, and the object's velocity increases at a rate of v = 0.1s m/sec² (s is in meters), determine the velocity of the object that exits the pipeline at D. (d) Using the appropriate friction coefficients given above, determine the distance that the object
Please answer the following questions, (a) Determine the velocity that the object releases from the inclined ramp at B. (b) Determine the vertical velocity component at C. (c) If the object enters the pipeline at C with the above velocity when s=0, and the object's velocity increases at a rate of v = 0.1s m/sec² (s is in meters), determine the velocity of the object that exits the pipeline at D. (d) Using the appropriate friction coefficients given above, determine the distance that the object
Elements Of Electromagnetics
7th Edition
ISBN:9780190698614
Author:Sadiku, Matthew N. O.
Publisher:Sadiku, Matthew N. O.
ChapterMA: Math Assessment
Section: Chapter Questions
Problem 1.1MA
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![A 5 kg object is pressed against the spring which has an undeformed length of 0.5 m (spring
stiffness is 500 N/m) by 0.35 m and released at an instant shown in the figure below. After the
object is released, it vertically falls through a circular pipeline located at 4.4 m below the baseline
of the smooth ramp. After travelling through the pipeline, the object moves on a straight-line path
on a rough surface that has friction coefficients of s=0.25 and µ=0.10.
Undeformed
spring length of 0.5 m
0.6 m
Owwww
0.35 m
0.8 m
4.4 m
3 m
3 m
Please answer the following questions,
(a) Determine the velocity that the object releases from the inclined ramp at B.
(b) Determine the vertical velocity component at C.
(c) If the object enters the pipeline at C with the above velocity when s=0, and the object's velocity
increases at a rate of v = 0.1s m/sec? (s is in meters), determine the velocity of the object that
exits the pipeline at D.
(d) Using the appropriate friction coefficients given above, determine the distance that the object
stops measured from D.](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2Feb0db590-5d37-48a1-bf5a-623f4987797d%2Fadd6c697-ed90-4f0f-8751-7e5d335cf733%2Fydknyu_processed.png&w=3840&q=75)
Transcribed Image Text:A 5 kg object is pressed against the spring which has an undeformed length of 0.5 m (spring
stiffness is 500 N/m) by 0.35 m and released at an instant shown in the figure below. After the
object is released, it vertically falls through a circular pipeline located at 4.4 m below the baseline
of the smooth ramp. After travelling through the pipeline, the object moves on a straight-line path
on a rough surface that has friction coefficients of s=0.25 and µ=0.10.
Undeformed
spring length of 0.5 m
0.6 m
Owwww
0.35 m
0.8 m
4.4 m
3 m
3 m
Please answer the following questions,
(a) Determine the velocity that the object releases from the inclined ramp at B.
(b) Determine the vertical velocity component at C.
(c) If the object enters the pipeline at C with the above velocity when s=0, and the object's velocity
increases at a rate of v = 0.1s m/sec? (s is in meters), determine the velocity of the object that
exits the pipeline at D.
(d) Using the appropriate friction coefficients given above, determine the distance that the object
stops measured from D.
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