a man in a gym is holding an 8.0 kg weight at arm's length, a distance of 0.55 m from his shoulder joint What is the torque about his shoulder joint due to the weight if his arm is horizontal

Answer:8

Explanation:

Answer:

A force of 1.788 newtons is exerted on one side of the sheet of paper by the atmosphere.

Explanation:

From definition of pressure, we get that force exerted by the atmosphere ([tex]F[/tex]), measured in newtons, on one side of the sheet of paper is given by the expression:

[tex]F = P_{atm}\cdot w\cdot l[/tex] (Eq. 1)

Where:

[tex]P_{atm}[/tex] - Atmospheric pressure, measured in pascals.

[tex]w[/tex] - Width of the sheet of paper, measured in meters.

[tex]l[/tex] - Length of the sheet of paper, measured in meters.

If we know that [tex]P_{atm} = 101325\,Pa[/tex], [tex]w = 0.353\,m[/tex] and [tex]l = 0.05\,m[/tex], then the force exerted on one side of the sheet of paper is:

[tex]F = (101325\,Pa)\cdot (0.353\,m)\cdot (0.05\,m)[/tex]

[tex]F = 1.788\,N[/tex]

A force of 1.788 newtons is exerted on one side of the sheet of paper by the atmosphere.

Answer:

kinetic

Explanation:

Answer:

kinetic energy.

Explanation:

Answer:

The speed of the particle is proportional to:

c. t²

Explanation:

Given;

initial velocity of the particle, u = 0

let the net force on the object = F

Work done on the particle is given by;

W = F x d

W ∝ t

[tex]Fd \ \alpha \ t\\\\\frac{mv}{t}d \ \ \alpha \ t\\\\mvd \ \ \alpha \ t^2\\\\v \ \ \alpha \ t^2[/tex]

Therefore, the speed of the particle is proportional to t²

The speed of the particle is proportional to t.

It should be noted that work is a change in kinetic energy. Therefore, power will be calculated as:

Power = Work / Time = force × velocity

Power is proportional to t. Since force is a constant, then the velocity will be proportional to t. Therefore, the speed of the particle is proportional to t.

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correct answer is mass media is correct answer OK

Answer:

0.344 m/s^2

Explanation:

The first step is to calculate V

V= distance /time

= 2/1.45

= 1.379 m/s

Therefore the acceleration of the block can be calculated as follows

a= V - U/2d

= 1.379 - 0/2×2

= 1.379/4

= 0.344 m/s^2

Answer:

When the ball is on the frictionless side of the track , the angular speed is 89.7 rad/s.

Explanation:

Consider the ball is a solid sphere of radius 3.8 cm and mass 0.14 kg .

Given ,  mass, m=0.14 kg

Ball is released from rest at a height of, h= 0.83 m

Solid sphere of radius, R = 3.8 cm

                                       =0.038 m

From the conservation of energy

                          ΔK  = ΔU  

                [tex]\frac{1}{2}mv^2 +\frac{1}{2} I\omega^2=mgh[/tex]

Here , [tex]I=\frac{2}{5} MR^2 , v= R \omega[/tex]

  [tex]\frac{1}{2}mv^2\frac{1}{2}(\frac{2}{5}MR^2)(\frac{v}{R^2} )=mgh[/tex]

  [tex]\frac{1}{2} [v^2+\frac{2}{5}v^2]= gh[/tex]

[tex]\frac{7}{10} v^2=gh[/tex]

[tex]0.7v^2=gh[/tex]

 v=[tex]\sqrt{[gh/(0.7)][/tex]

=[tex]\sqrt{ [(9.8 m/s^2)(0.83 m) / (0.7) ][/tex]

= 3.408 m/s

Hence, angular speed when it is on the frictionless side of the track,

[tex]\omega=\frac{v}{R}[/tex]

   = (3.408 m/s)/(0.038 m)

[tex]\omega[/tex]   =  89.7 rad/s

Hence , the angular speed is 89.7 rad/s

Answer:

μ = 0.2041

Explanation:

Given

[tex]a = -2m/s^2[/tex]

Required

Determine the coefficient of friction (μ)

The acceleration is negative because it is decreasing.

Solving further, we have that:

[tex]F_f =[/tex] μmg

Where

μ = Coefficient of kinetic friction

[tex]F_f = ma[/tex]

So, we have:

ma = μmg

Divide both sides by m

a = μg

Substitute values for a and g

2 = μ * 9.8

Solve for μ

μ = 2/9.8

μ = 0.2041

Answer:

Net force = 419.5N

Explanation:

Given the following data;

Mass = 50kg

Radius = 15m

Time = 2.1 secs

Turns = 1/4 = 0.25

In order to find the net force, we would first of all solve for the speed and acceleration of the halfback.

To find speed;

Speed can be defined as distance covered per unit time. Speed is a scalar quantity and as such it has magnitude but no direction.

Mathematically, speed is given by the equation;

[tex]Speed = \frac{distance}{time}[/tex]

But the distance traveled is given by the circumference of a circle = [tex] 2\pi r[/tex]

Since he covered 1/4th of a turn;

[tex] Distance = 0.25 * 2 \pi *r[/tex]

Substituting into the equation;

[tex] Speed, v = \frac {(0.25*2*3.142 * 15)}{2.1}[/tex]

[tex] Speed, v = \frac {23.565}{2.1}[/tex]

Speed, v = 11.22m/s

To find acceleration;

[tex] Acceleration, a = \frac {v^{2}}{r}[/tex]

Where, v = 11.22m/s and r = 15m

Substituting into the equation, we have;

[tex] Acceleration, a = \frac {11.22^{2}}{15}[/tex]

[tex] Acceleration, a = \frac {125.8884}{15}[/tex]

Acceleration, a = 8.39m/s²

To find the net force;

Force is given by the multiplication of mass and acceleration.

Mathematically, Force is;

[tex] F = ma[/tex]

Where;

Substituting into the equation, we have;

[tex] F = 50 * 8.39[/tex]

F = 419.5N

Therefore, the net force acting upon the halfback is 419.5 Newton.

Answer:

Kinetic Energy

Explanation:

I can't really explain it, but that's the correct answer.

Answer:

Explanation:

The acceleration of an object given it's mass and the force acting on it can be found by using the formula

[tex]a = \frac{f}{m} \\ [/tex]

where

f is the force

m is the mass

From the question we have

[tex]a = \frac{12}{4} \\ [/tex]

We have the final answer as

Hope this helps you

Answer:

1.2 seconds

Explanation:

Formula for total time of flight in projectile is; T = 2u/g

Now, for the time to reach maximum height, it is gotten from Newton's first equation of motion;

v = u + gt

t is time taken to reach maximum height.

But in this case, g will be negative since motion is against gravity. Final velocity will be 0 m/s at max height.

Thus;

0 = u - gt

u = gt

t = u/g

Putting t for u/g in the equation of total time of flight, we have;

T = 2t

We are given t = 1.2

Thus, T = 2 × 1.2 = 2.4

Since total time of flight is 2.4 s and time to get to maximum height is 1.2 s, then it means time to fall from maximum height back to the students hand is; 2.4 - 1.2 = 1.2 s

Answer:

Energy lost = 55.28Joules

Explanation:

Using the law of momentum:

m1u1+m2u2 = m1v1+m2v2

m1 and m2 are the masses of the objects

u1 and u2 are the initial velocities.

v1 and v2 are final velocities

Given

m1 = 5kg

m2 = 4kg

u1 = 12m/s

u2 = 2m/s

v1 = 10m/s

v2 = ?

Substitute

5(12)+4(2)=4(10)+5v2

60+8 = 40+5v2

68-40 = 5v2

28 = 5v2

v2 = 28/5

v2 = 5.6m/sec

Hence the speed of the 5kg block is 5.6m/s

Energy lost = Kinetic energy after collision - kinetic energy before collision

KE after collision = 1/2m1v1²+1/2m2v2²

KE after collision = 1/2(5)10²+1/2(4)(5.6)²

= 250+62.72

= 312.72Joules

KE before collision = 1/2m1u1²+1/2m2u2²

KE before collision = 1/2(5)12²+1/2(4)(2)²

= 360+8

= 368Joules

Energy lost = 368-312.72

Energy lost = 55.28Joules

Answer:

Larger in magnitude

Explanation:

As the vectors get closer reducing the 90 degree angle, based on the "parallelogram rule" for vector addition, the magnitude of the resultant vector gets larger than when they are forming a 90 degree angle.

Answer:

Simple enough that it seems like a trick question: gravity.

Answer:

Vf = Vi + at

t = Vf - Vi = 0.0m/s - 1.75 m/s

    --------- = ------------------------- = 8.8s

         a              -0.20 m/s(squared)

Explanation:

This is what I got I am pretty sure it's correct but correct me if I'm wrong : )

Answer:

a and c

Explanation:

Answer:

9.77 m/s

Explanation:

Since the cylinder is rolling, it will have both translational and rotational kinetic energy.

From conservation of energy, its initial mechanical energy equals its final mechanical energy.

So, K' + U' = K + U where K and U are the initial kinetic and potential energies respectively and K' and U' are the final kinetic and potential energies respectively.

So, Since the cylinder starts from rest, its initial kinetic energy K = 0, its initial potential energy = mgh where m = mass of cylinder, g = acceleration due to gravity = 9.8 m/s² and h = height of incline = 7.30 mm = 7.3 × 10⁻³ m . Its final kinetic energy K' = 1/2Iω² + 1/2mv² where I = moment of inertia of cylinder = 1/2mr² where r = radius of cylinder and v = translational velocity of cylinder. Its final potential energy U' = 0. Substituting these into the equation, we have  

K' + U' = K + U

1/2Iω² + 1/2mv² + 0 = 0 + mgh

1/2(1/2mr²)ω² + 1/2mv² = mgh

1/4mr²ω² + 1/2mv² = mgh          

1/4m(rω)² + 1/2mv² = mgh    v = rω

1/4mv² + 1/2mv² = mgh

3/4mv² = mgh

v² = 4gh/3

v = √(4gh/3)

v = √(4 × 9.8 m/s² × 7.3 × 10⁻³ m/3)

v = (√286.16/3) m/s

v = (√95.39) m/s

v = 9.77 m/s

Answer:

The friction force exerted by the surface is 490 newtons.

Explanation:

From Physics, we remember that static friction force ([tex]f_{s}[/tex]), measured in newtons, for a particle on a horizontal surface is represented by the following inequation:

[tex]f_{s} \leq \mu_{s}\cdot m \cdot g[/tex] (Eq. 1)

Where:

[tex]\mu_{s}[/tex] - Static coefficient of friction, dimensionless.

[tex]m[/tex] - Mass of the crate, measured in kilograms.

[tex]g[/tex] - Gravitational acceleration, measured in meters per square second.

If [tex]f_{s} = \mu_{s}\cdot m \cdot g[/tex], then crate will experiment an imminent motion. The maximum static friction force is:  ([tex]\mu_{s} = 0.6[/tex], [tex]m = 100\,kg[/tex], [tex]g = 9.807\,\frac{m}{s^{2}}[/tex])

[tex]f_{s} = (0.6)\cdot (100\,kg)\cdot \left(9.807\,\frac{m}{s^{2}} \right)[/tex]

[tex]f_{s} = 588.42\,N[/tex]

From Newton's Laws we get that current force of friction as reaction to the pulling force done by the worker on the crate is:

[tex]\Sigma F = F-f = 0[/tex]

[tex]f = F[/tex] (Eq. 2)

Where:

[tex]F[/tex] - Horizontal force done by the worker, measured in newtons.

[tex]f[/tex] - Static friction force, measured in newtons.

If [tex]F = 490\,N[/tex], then the static friction force exerted by the surface is:

[tex]f = 490\,N[/tex]

Given that [tex]f < f_{s}[/tex], the crate does not change its state of motion. The friction force exerted by the surface is 490 newtons.  

Answer:

The tension in the rope is 588 N

Explanation:

I have attached a free body diagram of the problem.

First we calculate the force applied downwards by the person's weight:

[tex]F_{weight} =m*a = 80 kg * 9.8 \frac{m}{s^{2}} = 784 N[/tex]

If the scale reads a 25% of the person' weight:

[tex]F_{Scale} = F_{weight}*0.25=784N*0.25=196N[/tex]

which is the same value (but opposite) to the effective weight of the persons ([tex]F_{Person}=-F_{Scale}[/tex])

The other 75% of the total weight is the force of the rope pulling the person upwards.

[tex]F_{Pull}= F_{weight}*0.75=784N*0.75=588N[/tex]

To verify, we can use 1st Newton's law

∑F = 0

[tex]F_{Rope}-F_{Pull}+F_{Person}-F_{Scale}=0 \\588N-588N+196N-196N=0[/tex]

Answer:

1. force applied southward = -4 j

force applied eastward = 5 i

total force applied = 5i - 4j

magnitude of total force applied = √(5)²+(-4)²

magnitude of total force applied = √25 + 16 = √41

magnitude of total force applied = 6.4N

But the beach ball also weighs 4 N,

which means that a force of 4N is required to overcome the inertia of the ball

Net force applied on the ball = total force applied - force applied by inertia

Net force applied on the ball = 6.4 - 4

Net force applied on the ball = 2.4 N

Mass of the ball:

Mass of the ball = weight of the ball / gravitational constant

Mass of the ball = 4 / 9.8 = 0.4 kg

Acceleration of Ball:

from newton's second law of motion:

F = ma

replacing the variables

2.4 = 0.4 * a          (where a is the acceleration of the ball)

a = 2.4/0.4

a = 6 m/s²

2. Mass of astronaut = 70 kg

Weight of Earth:

Weight = Mass * acceleration due to gravity

Weight = 70 * 9.8

Weight = 686 N

Weight on Moon:

Weight = Mass * acceleration due to gravity

Weight = 70 * 1.6                             (we are given that g = 1.6 on moon)

Weight = 112 N

Weight on Venus:

Weight = Mass * acceleration due to gravity

Weight = 70 * 18.7                         (we are given that g = 18.7 on Venus)

Weight = 1309 N

Answer:

1.6m

Explanation:

Using the spring equation, which is as follows:

F = Kx

Where; F = force applied on the spring (N)

K = spring constant (3kg/s²)

x = extension of spring (m)

However, Force applied by object = mass × acceleration (9.8m/s²)

F = 0.49kg × 9.8m/s²

F = 4.802N

Since, F = 4.802N

F = Kx

4.802 = 3 × x

4.802 = 3x

x = 4.802/3

x = 1.6006

x = 1.6m

The spring is stretched i.e. the extension of the spring, by 1.6m

Answer:

Rₓ = 1562.5 Ω

Explanation:

The formula for the wheat stone bridge in balanced condition is given as follows:

R₁/R₂ = R₃/Rₓ

where,

Rₓ = Unknown Resistance = ?

R₃ = 2500 Ω

R₂/R₁ = 0.625

R₁/R₂ = 1/0.625 = 1.6

Therefore,

1.6 = 2500 Ω/Rₓ

Rₓ = 2500 Ω/1.6

Rₓ = 1562.5 Ω

Answer:

[tex]\alpha =240.79\ rad/s^2[/tex]

Explanation:

Given that,

Initial angular velocity, [tex]\omega_i=0[/tex]

Final angular velocity, [tex]\omega_f=16740\ rev/min = 1753\ rad/s[/tex]

We need to find the angular acceleration of the drill. It is given by the formula as follows :

[tex]\alpha =\dfrac{\omega_f-\omega_i}{t}\\\\\alpha =\dfrac{1753-0}{7.28}\\\\\alpha =240.79\ rad/s^2[/tex]

So, the angular acceleration of the drill is [tex]240.79\ rad/s^2[/tex].

Answer:

Kindly check explanation

Explanation:

Change in momentum:

m(v - u)

M = mass = 1500kg

v = final velocity = 0 m/s

u = initial velocity = 8m/s

Momentum = 1500(8 - 0)

Momentum = 1500 * 8

Momentum = 12000 kgm/s

B.) impulse that acts on the car

Impulse = Force * time

Impulse = change in momentum with time

Impulse = m(v - u)

Hence, impulse = 12000Ns

C.) Average force action on the car during collision

Impulse = Force * time

12000 = force * 0.6

12000/ 0.6 = force

Force = 20000 N

D.) Workdone by haystack in stopping the car :

Workdone = Force * Distance

Distance = speed * time

Distance = 8 * 0.6

Distance = 4.8m

Hence,

Workdone = 20,000 * 4.8 = 96000 J

Answer:

t = 9.25 s

Explanation:

Given that,

Initial angular velocity, [tex]\omega_o=0[/tex] (at rest)

Final angular velocity, [tex]\omega_o=0.25\ rad/s[/tex]

Angular acceleration, [tex]\alpha =0.027\ rad/s^2[/tex]

We need to find the time it take the wheel to come up to operating speed. We know that the angular acceleration in terms of angular speed is given by :

[tex]\alpha =\dfrac{\omega_f-\omega_o}{t}\\\\t=\dfrac{\omega_f-\omega_o}{\alpha }\\\\t=\dfrac{0.25-0}{0.027}\\\\t=9.25\ s[/tex]

So, it will reach up to the operating speed in 9.25 s.

Explanation:

Speed - The rate at which something moves

Velocity - The speed of something in a specific direction

Velocity is kind of a specific type of speed.

Answer:

The answer is below

Explanation:

a) Using the formula:

[tex]\omega^2=\omega_o^2+2\alpha \theta\\\\\omega=final\ velocity=15\ rev/s,w_o=initial\ velocity=4.4\ rev/s, \\\theta=distance=60\ rev\\\\Substituting:\\\\15^2=4.4^2+2(60)\alpha\\\\2(60)\alpha=15^2-4.4^2\\\\2(60)\alpha=205.64\\\\\alpha=1.71\ rev/s^2[/tex]

b) The disk is initially at rest. Using the formula:

[tex]\theta=\omega_ot+\frac{1}{2}\alpha t^2 \\\\but\ \omega_o=0(rest), \theta=60\ rev,\alpha=1.71\ rev/s^2\\\\Subsituting:\\\\60=0+\frac{1}{2}(1.71) t^2\\\\t=8.4\ s[/tex]

c)

[tex]\omega=\omega_o+\alpha t \\\\but\ \omega_o=0(rest), \omega=4.4 \ rev/s\ rev,\alpha=1.71\ rev/s^2\\\\Subsituting:\\\\4.4=1.71t\\\\t=2.6\ s[/tex]

d)

[tex]\omega^2=\omega_o^2+2\alpha \theta\\\\\omega=final\ velocity=4.4\ rev/s,w_o=initial\ velocity=0\ rev/s, \\\alpha=1.71\ rev/s^2\\\\Substituting:\\\\4.4^2=0+2(1.71)\theta\\\\19.36=3.42\theta\\\\\theta=5.66\ rev[/tex]