a = 1/1.4 = .714 m/s^2 upward acceleration
Total force on bundle = m(.714) = tension on string - m g
so tension = m (.714 + 9.8) = 66.2 N
Im not sure if i solved this right, but here is my work:
6.3(9.8)=61.74 N
Total force on bundle = m(.714) = tension on string - m g
so tension = m (.714 + 9.8) = 66.2 N
you need to use this equation:
Xf=Xi+Vi*t+(1/2)a*t^2
Xi=0,Vi=0,t=1.4,Xf=1,a=?
1=0+0(1.4)+(1/2)a(1.4^2)
1(2)= a(1.96)
2/1.96= a
1.0204 = a
Then you follow the rest of the equation
T = m(g+a)
We know that the net force acting on the bundle is equal to the tension in the chord minus the weight of the bundle. The weight of the bundle can be calculated using the formula:
Weight = mass × acceleration due to gravity
Weight = 6.3 kg × 9.8 m/s^2
Weight = 61.74 N
So, the net force on the bundle is 61.74 N. Since the elevator is accelerating upwards, there must be an additional upward force acting on the bundle to account for this acceleration.
Therefore, the tension in the chord can be found by adding the weight to the net force:
Tension = Weight + net force
Tension = 61.74 N + 61.74 N
Tension = 123.48 N
So, the tension in the chord as the elevator accelerates is approximately 123.48 N.
I hope this helps! Remember, tension is a real "puller" in tricky situations like this.
Let's break down the problem step by step:
Step 1: Calculate the weight of the bundle.
The weight of an object is given by the equation: weight = mass × acceleration due to gravity.
Given the mass of the bundle is 6.3 kg and the acceleration due to gravity is 9.8 m/s², we can calculate the weight:
Weight = 6.3 kg × 9.8 m/s² = 61.74 N
Step 2: Determine the net force acting on the bundle.
Since the elevator is accelerating upwards, there is an additional force acting on the bundle. This force is the net force, which can be calculated using Newton's second law: net force = mass × acceleration.
The mass of the bundle is 6.3 kg, and we know from the problem statement that it moves 1 m during the first 1.4 s. We can find the acceleration using the equation: acceleration = (final velocity - initial velocity) / time.
Since the elevator starts from rest, the initial velocity is 0 m/s.
Acceleration = (1 m - 0 m) / 1.4 s = 0.714 m/s²
Net force = 6.3 kg × 0.714 m/s² = 4.4982 N
Step 3: Determine the tension in the chord.
The tension in the chord is equal to the net force acting on the bundle.
Therefore, the tension in the chord is 4.4982 N.
Therefore, the tension in the chord as the elevator accelerates is approximately 4.4982 N.