i’m pretty sure it’s , the alkali metals
Answer:
The velocity = 5.82[m/s], Tension = 1.78 [N]
Explanation:
We can solve this problem using the principle of energy conservation and Newton's second law.
Here we can find an attached image of the pendulum with a free body diagram, where we can see the forces acting over the pendulum.
The initial data are:
The pendulum is released when the string is at 90° with respect to the vertical axis. Therefore the initial velocity is zero = 0, and the initial kinetic energy will be zero also.
The expression that defines the kinetic energy and the work is the following equation.
We take the reference point where the pendulum is matching the vertical axis. At this point the potential energy is zero and all the potential energy has been transformed into kinetic energy.
Now analyzing once again the expression deducted, we have:
In the free body diagram, we can see the forces and the equation to find the tension T. Especial attention must be seen to notice that the acceleration to find the tension in the equation should be the normal acceleration.
The normal acceleration is defined by:
Clearing the tension T, this value is 1.78 [N]
Answer:
The current in primary coil is 2.08 A.
Explanation:
Given that,
Power = 500 W
Voltage = 16 kV
Number of turns = 80000
We need to calculate the number of current
Using formula of voltage
Put the value into the formula
We need to calculate the current in secondary coil
Using formula of current
We need to calculate the current in primary coil
Put the value into the formula
Hence, The current in primary coil is 2.08 A.
Since the initial velocity is 30 and the final is 0. 15 is the vave so you can use that with 1/2mv^2 to find the force