Which of the following gives the nearest value for the maximum spring force, in Netwons?

a. 1800 N

b. 900 N

c. 121 N

d. 4.123 N

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Draw Free Body Diagram of the Block at Initial Condition Q1: Calculate the frictional force from the Free Body Diagram Q2: Find the acceleration at descend of block using Newton's Second Law Q3: Find the velocity of the block at initial contact with the spring using Uniform Accelerated Motion Q4: Find the time it takes for the initial contact using Impulse-Momentum Q4: Find the time it takes for the initial contact using Uniform Accelerated Motion Start Q5: Calculate for the maximum deflection of the spring using Work-Energy Method Q8: Calculate the velocity after leaving the spring using Work-Energy Method Q7: Calculate for the maximum inclined distance from the spring after it leaves the spring using Work-Energy Method Q6: Calculate the maximum spring force using Hooke's Law (F= kx) Q10: Calculate the time it takes to reach the maximum distance after it leaves the spring using Impulse-Momentun Q7: Calculate for the maximum inclined distance from the spring after it leaves the spring using Uniform Accelerated Motion Q10: Calculate the time it takes to reach the maximum distance after it leaves the spring using Uniform Accelerated Motion Draw the Free Body Diagram of the Block after leaving the spring Q9: Find the acceleration after leaving the spring of block using Newton's Second Law

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An 8-kg block slides 150mm from rest down the 25-degree plane. The spring has a value of k = 1800N/m. The coefficient of friction is 0.20. 8 kg 7777777 150 mm 25°