Q2. (a) A force of P = 200 N is applied to block A and causes block A to accelerate to the right on a rough surface as shown in Figure Q2(a). Knowing that the mass for block A is (6 + a) kg, where a denotes the last digit of your student ID and the mass for block B is 6 kg. Appendix A shows the examples of identifying the value using student ID. The coefficient of kinetic friction between block A and the surface is 0.15. Pulleys are massless and smooth. (i) With suitable diagram(s), determine the accelerations of block A and B. (ii) (iii) B Determine the tension in the cable attached to block 4. Explain with calculations on the possible way(s) to reduce the acceleration of block B. 6 kg A (6+a) kg 30°
Q2. (a) A force of P = 200 N is applied to block A and causes block A to accelerate to the right on a rough surface as shown in Figure Q2(a). Knowing that the mass for block A is (6 + a) kg, where a denotes the last digit of your student ID and the mass for block B is 6 kg. Appendix A shows the examples of identifying the value using student ID. The coefficient of kinetic friction between block A and the surface is 0.15. Pulleys are massless and smooth. (i) With suitable diagram(s), determine the accelerations of block A and B. (ii) (iii) B Determine the tension in the cable attached to block 4. Explain with calculations on the possible way(s) to reduce the acceleration of block B. 6 kg A (6+a) kg 30°
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
Related questions
Question
Let a = 1
![A force of P = 200N is applied to block A and causes block A to accelerate to
the right on a rough surface as shown in Figure Q2(a). Knowing that the mass
for block A is (6 + a) kg, where a denotes the last digit of your student ID and
the mass for block B is 6 kg. Appendix A shows the examples of identifying the
value using student ID. The coefficient of kinetic friction between block A and
the surface is 0.15. Pulleys are massless and smooth.
Q2.
(a)
(i)
With suitable diagram(s), determine the accelerations of block A and B.
(ii)
Determine the tension in the cable attached to block A.
(iii) Explain with calculations on the possible way(s) to reduce the
acceleration of block B.
A
30°
(6 + a) kg
6 kg
B
Figure Q2(a)
(b)
"Newton's second law states that the product of mass and acceleration is equal
to force". Do you agree with the statement? Explain with reasoning.](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2Fda1a9fbd-d8a6-43ae-a0a2-f4aac46b33e0%2F1aa802e1-0817-4af7-a35a-cf3e513605c3%2F5v74yri_processed.png&w=3840&q=75)
Transcribed Image Text:A force of P = 200N is applied to block A and causes block A to accelerate to
the right on a rough surface as shown in Figure Q2(a). Knowing that the mass
for block A is (6 + a) kg, where a denotes the last digit of your student ID and
the mass for block B is 6 kg. Appendix A shows the examples of identifying the
value using student ID. The coefficient of kinetic friction between block A and
the surface is 0.15. Pulleys are massless and smooth.
Q2.
(a)
(i)
With suitable diagram(s), determine the accelerations of block A and B.
(ii)
Determine the tension in the cable attached to block A.
(iii) Explain with calculations on the possible way(s) to reduce the
acceleration of block B.
A
30°
(6 + a) kg
6 kg
B
Figure Q2(a)
(b)
"Newton's second law states that the product of mass and acceleration is equal
to force". Do you agree with the statement? Explain with reasoning.
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