Assume that you are in a space station conducting fluid mechanics experiments in zero gravity. You perfectly coat a sphere and a long cylinder with a thin layer of the same fluid and thickness. If the sphere and cylinder have the same radius, will the fluid layers on the two objects have the same pressure

The balance sheet, income statement, and cash flow statement each offer unique details with information that is all interconnected. Together the three statements give a comprehensive portrayal of the company's operating activities.

Answer:

339.3 N

Explanation:

First, we start by converting the units.

1 rev/s = 2π rad/s, so

0.6 rev/s = 2π * 0.6 rad/s

0.6 rev/s = 1.2π rad/s

0.6 rev/s = 3.77 rad/s

Now we apply the equation of motion,

W(f) = w(o) + αt

3.77 = 0 + α * 2

3.77 = 2α

α = 3.77/2

α = 1.885 rad/s²

Torque = I * α

Torque = F * r

This means that

I * α = F * r, where I = 1/2mr²

Substituting for I, we have

1/2mr²α = F * r, making F the subject of formula, we have

F = 1/2mrα, then we substitute for the values

F = 1/2 * 240 * 1.5 * 1.885

F = 678.6 / 2

F = 339.3 N

We are given:

Mass of Tarzan before swinging = 80 kg

Mass of Tarzan when swinging = 80 + 15 = 95 kg

Velocity of Tarzan = 7 m/s

The height of the rock Tarzan's monkey is sitting on = 3 m

__________________________________________________________

Momentum of Tarzan before swinging:

We know that:

Momentum = Mass*Velocity

Momentum = 80 * 7

Momentum = 560 kg m/s

__________________________________________________________

Speed of Tarzan after grabbing the bananas:

The momentum of Tarzan will remain the same but his mass will increase

So, Since Momentum = New Mass* velocity

560 = 95 * v                           [where v is the velocity of Tarzan]

v = 5.9 m/s

__________________________________________________________

Here, KE = Kinetic Energy and PE = Potential Energy

Initial and Final KE:

We know that KE = 1/2*(mv²)

Initial KE:

Initial KE = 1/2*(mv²)          [where v is the velocity after picking the bananas]

Initial KE = 1/2*(95*5.9²)

Initial KE = 1653.5 Joules

Final KE:

Final KE = 1/2*(mv²)            

[where v is the velocity at the maximum point of the swing]

Since Tarzan will be at rest at the maximum point of the swing, v = 0 m/s

Final KE = 1/2*(95*0²)

Final KE = 0 Joules

Initial and Final PE:

We know that:

PE = mgh                

[where g is the acceleration due to gravity and h is the height]

Initial PE:

Since the height of Tarzan from the ground was 0 m at the beginning of the swing, h = 0

Initial PE = 95*10*0

Initial PE = 0 Joules

Final PE:

Let the maximum height of Tarzan be h m

Final PE = 95*10*h

Final PE = 950(h)

__________________________________________________________

Here, KE = Kinetic Energy and PE = Potential Energy

From the law of conservation of momentum, we know that:

Initial KE + Initial PE = Final KE + Final PE

Replacing the variables:

1653.5 + 0 = 0 + 950h

1653.5 = 950h

h = 1653.5/950         [dividing both sides by 950]

h = 1.74 m

Therefore, the maximum height reached by Tarzan is 1.74 m

but since his monkey is sitting 3 m high, he will NOT be able to reach his monkey

Answer:

b. The clock in orbit runs slow. The clock in Colorado runs slow.

Explanation:

b. The clock in orbit runs slow. The clock in Colorado runs slow. This is because of the fact that as the gravity weakens, time moves faster, hence, the answer is b.

Answer: The clock in Colorado runs slow

Explanation: I got it correct on the HW. It should be a separate answer from B though.

Answer:

the boy would go missing

Answer: Slender man converts the boy to christianity

Answer:

 v₀ = [tex]\sqrt{2gH}[/tex]

to determine this speed experimentally, the student must measure the height of the body as a function of time and with equation (1) he can find the speed for each point of interest

Explanation:

In this internal exercise the student must use the conservation of mechanical energy,

Starting point. Highest point of the trajectory

         Em₀ = U = m g H

Point of interest. Point at height Y

         [tex]Em_{f}[/tex] = K + U = ½ m v² + m g Y

energy is conserved

          Em₀ = Em_{f}

          m g H = ½ m v² + m g Y

          v² = 2 g (H -Y)             (1)

in this case they indicate that Y is the equilibrium position whereby Y = 0 and the velocity is v = v₀

          v₀ = [tex]\sqrt{2gH}[/tex]

Therefore, to determine this speed experimentally, the student must measure the height of the body as a function of time and with equation (1) he can find the speed for each point of interest

Answer:

v = 0.5 m/s

f = 0.42 Hz

ω = 2.6 rad/sec

Explanation:

        [tex]v =\frac{\Delta s}{\Delta t} = \frac{1.19m}{2.4s} = 0.5 m/s (1)[/tex]

       [tex]\omega = \frac{\Delta\theta}{\Delta t} = \frac{2*\pi}{2.4s} = 2.6 rad/sec (3)[/tex]

Answer:

The value is [tex]F_f = 46.935 \ N[/tex]

Explanation:

From the question we are told that

    The  magnitude of the horizontal force is [tex]F = 92.7 \ N[/tex]

     The mass of the crate is  [tex]m = 40.5 \ kg[/tex]

     The acceleration of the crate is  [tex]a = 1.13 \ m/s[/tex]

Generally the net force acting on the crate is mathematically represented as

       [tex]F_{net} = F - F_f = ma[/tex]

Here [tex]F_f[/tex] is force of kinetic friction (in N) acting on the crate

      So  

            [tex]92.7 - F_f = 40.5 * 1.13[/tex]

=>         [tex]F_f = 46.935 \ N[/tex]

Answer:

с. The net work done on the cart is equal to the change in kinetic energy of the cart.

Explanation:

In the context, a motion sensor detects the motion of the cart where a cart is used to move using a force sensor that is attached to the cart of certain mass. As the cart moves with a speed at a particular time, the computer records both the readings on the force sensor as well as the motion sensor. From these readings the is can be concluded that the work done on the cart is same as the change in the kinetic energy in the cart.

Answer:

Like charges repel each other; unlike charges attract. Thus, two negative charges repel one another, while a positive charge attracts a negative charge. The attraction or repulsion acts along the line between the two charges. The size of the force varies inversely as the square of the distance between the two charges.

Answer:

positive and negative ??

Explanation:

I dont really understand the question if im being honest

Answer:

Velocity ratio of single pulley = 2

Explanation:

Given:

Tension T

Distance = T + T = 2T

Find:

Velocity ratio of single pulley

Computation:

Velocity ratio of single pulley = Total distance / Distance effort

Velocity ratio of single pulley = 2T / T

Velocity ratio of single pulley = 2

Answer:

Explanation:

The question is incomplete. Here is the complete question:

You are pushing a 13.3 kg lawn mower across the lawn with a force of 200 N. What is the value of the coefficient of friction between the mower and the grass if the mower moves with a constant velocity? The force is applied downward at an angle of 65° with the horizontal.

According to Newton's second law of motion:

[tex]\sum F_x= ma_x\\F_{app} - F_f = ma_x\\[/tex]

[tex]F_f = \mu R\\[/tex]

[tex]F_{app} - \mu Rcos \theta = ma_x[/tex]

Fapp is the applied force = 200N

Ff is the frictional force

[tex]\mu[/tex] is the coefficient of friction between the mower and the grass

R is the reaction

m is the mass of the object

ax is the acceleration

Given

R = mg = 13.3*9.8

R = 130.34N

m = 13.3kg

ax  = 0m/s² (constant velocity)

Fapp = 200N

[tex]\theta = 65^0[/tex]

Substitute the given parameters into the formula and get the coefficient of friction as shown;

Recall that: [tex]F_f = \mu R\\[/tex]

[tex]\mu = \frac{F_f}{R}\\\mu = \frac{F_{x}cos65}{F_y+W} \\\mu =\frac{ 200cos65}{200sin65+13.3(9.8)}\\\mu = \frac{84.52}{181.26+130.34}\\\mu = \frac{84.52}{311.6}\\\mu = 0.27[/tex]

Hence the coefficient of friction between the mower and the grass is 0.27

Answer:

Its stored in there

Explanation:

And air has little mass

Answer:

806.6 N

Explanation:

Given that :

Mass (m) = 74 kg

Acceleration due to gravity (g) = 9.8 m/s²

Acceleration during interval t1 = 1.10 m/s²

Using the relation :

Normal reaction = Mass (g + acceleration at interval t1)

Normal reaction = 74(9.8 + 1.10)

Normal reaction = 74(10.9)

Normal reaction = 806.6 N

Answer: 3) There are many possible elements, and they are all in the same vertical column as bromine.

Explanation:

Answer:

choice 3

Explanation:

Answer:

B. 17m/s

Explanation:

This question contains a graph that illustrates the relationship between the speed of a car over time. The graph shows that one can make an inference of the amount of time it takes for the car to cover a particular speed and vice versa.

In this case, after 3 seconds, the speed of the car will be 17 m/s. This inference was got by tracing the position of 3s in the x-axis to the value on the y-axis. Doing this, the best inference for the speed of the car after 3 seconds is 17m/s.

Answer:

Displacement -6

Distance 24

Explanation:

Answer:

Explanation:

What is the displacement of the elephant between

0s

and

16s

displacement =9

distance traveled by the elephant between =9

Answer:

5.76 cm³

Explanation:

Using the equation for volume expansivity,

V = V₀ + V₀γΔθ) where V₀ = volume of cube = volume of mercury = 400 cm³, γ = cubic expansivity of mercury = 18 × 10⁻⁵ /K and Δθ temperature change = θ₂ - θ₁ where θ₁ = 0 °C and θ₂ = 80°C. So, Δθ = 80°C - 0°C = 80°C = 80 K

Now, the volume change, ΔV = V - V₀ = V₀γΔθ.

So, substituting the values of the variables into the equation, we have

ΔV = V₀γΔθ

= 400 cm³ × 18 × 10⁻⁵ /K × 80 K

= 5.76 cm³

So the mercury will overflow by 5.76 cm³.