A potter's wheel having a radius 0.47 m and a moment of inertia of 14.2 kg · m2 is rotating freely at 53 rev/min. The potter can stop the wheel in 8.0 s by pressing a wet rag against the rim and exerting a radially inward force of 68 N. Find the effective coefficient of kinetic friction between the wheel and the wet rag.

After 10 seconds, the bike wheel will take roughly 15.98 seconds to come to a complete halt. The frictional torque operating on the spinning bike wheel is -0.112 N*m.

The process to solve this problem involves several steps. The first one is to determine the initial and final angular velocities of the wheel. Angular velocities are usually measured in radians per second, but we have them in rotations per second. So, firstly these values need to be converted by multiplying the number of rotations by 2π radians. The initial angular velocity, ωi, hence becomes

9 * 2π = 56.55 rad/s,

and after 10 seconds, the final angular velocity, ωf, is

65 / 10 * 2π = 40.84 rad/s.

Now, we already know 10 seconds.

Using these values, the angular acceleration (α) can be calculated as

(ωf - ωi) / Δt = (40.84 rad/s - 56.55 rad/s) / 10 s = -1.571 rad/s².

Note that this is negative because it's a deceleration. We're also given the wheel's mass (m) and radius (r), so the moment of inertia (I), which can be calculated as

I = m*r², will be 0.725 kg * (0.315 m)² = 0.071 kg*m².

From here, frictional torque (τf), which is the product of the moment of inertia and angular acceleration, can be found as

I * α = 0.071 kg*m² * -1.571 rad/s² = -0.112 N*m.

The negative sign just indicates the torque acts in the direction to slow down the wheel.

Finally, to find the time Δts it takes to come to rest, we can use the equation for angular velocity:

ω = ωi + α * t.

Setting ω to 0 (as the wheel stops) and solving for t gives us:

t = (0 - ωi) / α = - (40.84 rad/s) / -1.571 rad/s² = 25.98 s.

But our Δts is the time after the first 10 seconds, so Δts = t - 10 s = 15.98 s.

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Answer:

The first object (black)

Explanation:

The thermal radiation of a body is governed by the Stefan Boltzmann Law, which is mathematically given as:

[tex]E=\epsilon. \sigma.T^4[/tex]

where:

[tex]\sigma =5.67\times 10^{-8}\ W.m^{-2}.K^{-4}[/tex]      (Stefan Boltzmann constant)

So here also the black object will glow brighter than the others.

Answer:

The guy above me is definitely correct just read it.

Explanation:

it is what it is.

For the development of this problem it is necessary to apply the concepts related to Force, momentum and time.

By definition we know that momentum can be expressed as

[tex]P = F*t[/tex]

Where

P = Momentum

F = Force

t = Time

At the same time, another way of expressing the momentum is through mass and speed, that is,

P = mv

Where

m = Mass

v = Velocity

Equating both equations

F*t = mv

[tex]F = \frac{mv}{t}[/tex]

Our values are given as

[tex]m = 145*10^{-3}Kg[/tex]

[tex]t = 3*10^{-3}s[/tex]

[tex]v = 90-44 = 46m/s \rightarrow[/tex] Net velocity

Replacing we have then,

[tex]F = \frac{mv}{t}[/tex]

[tex]F = \frac{3*10^{-3}*46}{3*10^{-3}}[/tex]

[tex]F = 2223.33N[/tex]

Therefore the average force exerted by the bat during the collision is 2223.3N

Answer:

Centripetal force, [tex]F_x=0.379\ N[/tex]

Explanation:

It is given that,

Mass of the ball, m = 62 g = 0.062 kg

Length of the string, l = 72 cm = 0.72 m

Angle, [tex]\theta=32^{\circ}[/tex]

To find,

The centripetal force experienced by the ball.

Solution,

According to the attached free body diagram,

[tex]T\ cos\theta-mg=0[/tex]

[tex]T=\dfrac{mg}{cos\theta}[/tex]

[tex]T=\dfrac{0.062\times 9.8}{cos(32)}[/tex]

T = 0.716 N

The centripetal force will be experienced by the ball in horizontal direction. It is equal to :

[tex]F_x=T\ sin\theta[/tex]

[tex]F_x=0.716\ N\ sin(32)[/tex]

[tex]F_x=0.379\ N[/tex]

So, the centripetal force experienced by the ball is 0.379 N.

The centripetal force experienced by the small ball if mass 62 g and attached to the string is 0.379 N.

Centripetal force is the force which is required to keep rotate a body in a circular path. The direction of the centripetal force is inward of the circle towards the center of rotational path.

Given information-

The mass of the small bag is 62 grams.

The length of the string is 72 cm.

Suppose T is the tension in the string, m is the mass of ball and g is the gravitational force.

The horizontal force applied on the body is,

[tex]\sum F_x=T\cos \theta-mg=0\\T=\dfrac{mg}{\cos \theta}[/tex]

The centripetal force applied on the body is,

[tex]F_c=T\sin \theta\\T=\dfrac{F_c}{\sin \theta}[/tex]

Compare both the values of the T, we get,

[tex]\dfrac{F_c}{\sin\theta}=\dfrac{mg}{\cos \theta}\\{F_c}=\dfrac{mg\times{\sin\theta}}{\cos \theta}\\{F_c}={mg\times{\tan\theta}}[/tex]

Put the values as,

[tex]F_c=0.062\times9.8\times\tan(32)\\F_c=0.379\rm N[/tex]

Thus, the centripetal force experienced by the small ball if mass 62 g and attached to the string is 0.379 N.

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Answer:

4.1%

Explanation:

Given that water specific heat c = 4186 J/kgC. If water is flowing with mass rate of 200kg/s and temperature is dropping from 200C to 25C. Then the thermal energy rate from the water should be

[tex]P_i = mc\Delta t = 200*4186*(200 - 25) = 146510000 J/s[/tex] or 146510kW

Since the turbine is only able to extract 6000kW of power, then the thermal efficiency is:

[tex]Eff = \frac{P_o}{P_i} = \frac{6000}{146510} = 0.041[/tex] or 4.1%

Answer:

T = 451.26 N

Explanation:

It is given that,

The mass of block, m = 46 kg

Mass of the chain, m' = 19 kg

Length of the chain, l = 1.9 m

Let T is the the tension in the chain at the point where the chain is supporting the block. It is clearly equal to the product of mass and acceleration.

[tex]T=mg[/tex]

[tex]T=46\ kg\times 9.81\ m/s^2[/tex]

T = 451.26 N

So, the tension in the chain at the point where the chain is supporting the block is 451.26 N. Hence, this is the required solution.

Answer:

496.57492 kg/m³

Explanation:

[tex]P_a[/tex] = Atmospheric pressure = 101300 Pa

[tex]\rho_w[/tex] = Density of water = [tex]1000 kg/m^3[/tex]

[tex]h_w[/tex] = Height of water = 0.221 m

[tex]h_l[/tex] = Height of fluid = 0.335 m

g = Acceleration due to gravity = 9.81 m/s²

[tex]\rho_l[/tex] = Density of the unknown fluid

Absolute pressure at the bottom

[tex]P_{abs}=P_a+\rho_wgh_w+\rho_lgh_l\\\Rightarrow \rho_l=\frac{P_{abs}-P_a-\rho_wgh_w}{gh_l}\\\Rightarrow \rho_l=\frac{104900-101300-1000\times 9.81\times 0.221}{9.81\times 0.335}\\\Rightarrow \rho_l=435.73873\ kg/m^3[/tex]

The density of the unknown fluid is 496.57492 kg/m³

To find the density of the unknown fluid in the container, we subtract the atmospheric pressure and the pressure due to water from the absolute pressure at the bottom of the container and divide the result by the product of gravity and the height of the unknown fluid.

The question is asking about the determination of the density of an unknown fluid in an open container where you have two separated fluids due to their different densities. In this setup, water fills the lower portion of the container and the unknown fluid fills the upper part.

The pressure at the bottom of this container (P) can be expressed as the sum of the atmospheric pressure (P0), pressure due to water (ρw * g * h1), and pressure due to the unknown fluid (ρl * g * h2) where 'g' is the acceleration due to gravity and 'h' represents the depth of each fluid. Given in the problem are P, P0, ρw, g, h1, and h2 and to find the density of the unknown fluid (ρl), we rearrange the equation into ρl = (P - P0 - ρw * g * h1) / (g * h2). By substituting the given values into this equation, we can find the density of the unknown fluid.

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Answer:

The amplitude is 0.010 m

Solution:

As per the question:

Eccentric Mass, [tex]m_{e} = 10\ kg[/tex]

[tex]m_{e}[/tex] = 10%M kg

0.1M = 10

Total mass, M = 100 kg

Spring constant, k = 3200 N/m

Eccentric center, e = 100 mm = 0.1 m

Speed of motor, N = 1750 rpm

Distance between two springs, d = 250 mm = 0.25 m

Now,

Angular velocity, [tex]\omega = \frac{2\pi N}{60} = \frac{2\pi \times 1750}{60} = 183.26\ rad/s[/tex]

For the vertical vibrations:

[tex]\omega_{n} = \sqrt{\frac{2k}{M}} = \sqrt{\frac{6400}{100}} = 8\ rad/s[/tex]

Now, the frequency ratio is given by:

r = [tex]\frac{\omega}{\omega_{n}} = \frac{183.26}{8} = 22.91[/tex]

Thus the amplitude is given by:

A = [tex]e^{\frac{m_{e}}{M}}.\frac{r^{2}}{|1 - r^{2}|}[/tex]

A = [tex]e^{\frac{10}{100}}.\frac{22.91^{2}}{|1 - 22.91^{2}|} = 0.010 m[/tex]

Final answer:

The amplitude of vertical vibration for the electric motor mounted on springs is 100 mm or 0.1 meters, considering the eccentric mass and neglecting damping.

Explanation:

The subject of this question is Physics, and it pertains to a college-level study of mechanics in the context of oscillations and waves, specifically relating to a system experiencing simple harmonic motion (SHM). The motor with an eccentric mass which causes vertical vibrations can be modeled as a mass-spring system, characteristic of simple harmonic oscillators.

Given the mass and the spring constant, we can calculate the natural angular frequency (not represented in this problem due to lack of damping) of this system. The driving frequency can also be converted to an angular frequency to check against the natural frequency. However, the question directly asks for the amplitude of vertical vibration, which in the undamped case of SHM, depends on the initial displacement of the mass from its equilibrium position. Since the question neglects damping, the amplitude can be considered equal to the eccentricity of the mass in the static case. Therefore, the amplitude of vertical vibration is 100 mm, or 0.1 meters.

Answer:

Everywhere; the energy of the ball is the same at all of these points.

Explanation:

A ball is thrown straight up. The total energy of an object remains constant as per the law of conservation of energy. At the highest point the object have only potential energy and at lowest point it have only kinetic energy. As a result, the total energy remains constant.

So, at every point the energy of the ball is the same at all of these points. Hence, the correct option is (d).

The ball has the most kinetic energy when it is first thrown. As it rises, its kinetic energy decreases while its potential energy increases, but the total energy is conserved and remains constant unless air resistance is factored in. So the correct option is b.

The answer is b. When it is first thrown. The total energy of the ball in this context is its kinetic energy (energy of motion) and potential energy (energy of position). At the moment the ball is thrown, it has the maximum kinetic energy and zero potential energy. As it rises, its kinetic energy decreases while its potential energy increases, but the total energy (kinetic plus potential) is conserved and remains constant if air resistance is ignored. So, the ball doesn't really have 'the most energy' at any one point, but it has the maximum kinetic energy when it is first thrown, which is probably what the question is asking.

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Answer:

0 Joules

Explanation:

The work done is given by

[tex]W=F\times s\times cos\theta[/tex]

where,

F = Force applied

s = Displacement of the object = 0 m

[tex]\theta[/tex] = Angle between the force applied and the horizontal = 0

[tex]W=F\times 0\times cos0\\\Rightarrow W=0\ J[/tex]

Work is only observed when there is a displacement.

The work done by me is 0 Joules as I was unable to move it.

To develop this problem it is necessary to apply the concepts related to the Dopler Effect.

The apparent frequency can be calculated through the expression

[tex]f' = \frac{v\pm v_0}{v}*f[/tex]

Where,

v = Velocity of the sound or light

[tex]v_0 =[/tex]Velocity of the observer

f=Real frequency

Our values are given as,

[tex]v = 343m/s[/tex]

[tex]v_0 = 30m/s[/tex]

[tex]f = 80Hz[/tex]

PART A ) Towards the factory we need to apply the plus sign

[tex]f' = \frac{v+v_0}{v}*f[/tex]

[tex]f' = \frac{343+30}{343}*80[/tex]

[tex]f' = 86.99Hz[/tex]

PART B ) Away from the factory we need to apply the minus sign

[tex]f' = \frac{v-v_0}{v}*f[/tex]

[tex]f' = \frac{343-30}{343}*80[/tex]

[tex]f' = 73 Hz[/tex]

To solve this problem it is necessary to apply the concept of period in a pendulum. Its definition is framed in the equation

[tex]T= 2\pi \sqrt{\frac{l}{g}}[/tex]

Where,

l = Length

g = Gravity

As you can see, the Period is dependent on both the gravitational acceleration and the length of the string. The period does not depend on mass. Therefore the period must remain the same at 2 seconds.

To solve this problem it is necessary to resort to concepts related to the kinematic equations of movement description which define speed as

[tex]v = \frac{x}{t}[/tex]

Where,

x = Distance

t=Time

Re-arrange to find the time we have,

[tex]t = \frac{x}{v}[/tex]

At 20°C the speed of sound in air is 343.2m/s and the speed of sound in water is 1484.3m/s

The time in which the sound lasts in traveling in the air would be given by the shipping and return (even when it touches the water) which is 28m (14 way and 14 back), in other words

[tex]t_a = \frac{28}{343.2} = 0.08158s[/tex]

In the case of the lake, the same logic is followed, only that there is no net distance here, therefore

[tex]t_w = \frac{2d}{1484.3}[/tex]

The total time would be given by

[tex]t_T = 0.08158 + \frac{2d}{1484.3}[/tex]

The total time is given in the statement so we clear to find d

[tex]0.108-0.08158= \frac{2d}{1484.3}[/tex]

[tex]d = \frac{1484.3(0.108-0.08158)}{2}[/tex]

[tex]d = 18.86m[/tex]

Therefore the lake has a depth of 18.86 m

Answer:

The tension in the rope is 20 N

Solution:

As per the question:

Mass of the object, M = 2 kg

Density of water, [tex]\rho_{w} = 1000\ kg/m^{3}[/tex]

Density of the object, [tex]\rho_{ob} = 500\kg/m^{3}[/tex]

Acceleration due to gravity, g = [tex]10\ m/s^{2}[/tex]

Now,

From the fig.1:

'N' represents the Bouyant force and T represents tension in the rope.

Suppose, the volume of the block be V:

V = [tex]\frac{M}{\rho_{ob}}[/tex]              (1)

Also, we know that Bouyant force is given by:

[tex]N = \rho_{w}Vg[/tex]

Using eqn (1):

[tex]N = \rho_{w}\frac{M}{\rho_{ob}}g[/tex]

[tex]N = 1000\frac{2}{500}\times 10 = 40\ N[/tex]

From the fig.1:

N = Mg + T

40 = 2(10) + T

T = 40 - 20 = 20 N

[tex]N = \rho_{w}Vg[/tex]

Answer:

5.4 rad/s

48.6 m/s

5.4 m/s²

262.44 m/s²

Explanation:

r = Radius of centrifuge = 9 m

[tex]\theta=0.3t^2[/tex]

Differentiating with respect to time

[tex]\frac{d\theta}{dt}=0.6t=\omega[/tex]

At t = 9 s

[tex]\omega=0.6\times 9=5.4\ rad/s[/tex]

Angular velocity is 5.4 rad/s

Linear speed

[tex]v=r\omega\\\Rightarrow v=9\times 5.4=48.6\ m/s[/tex]

The linear speed of the astronaut is 48.6 m/s

Differentiating [tex]\omega[/tex] with respect to time

[tex]\frac{d\omega}{dt}=0.6=\alpha[/tex]

Tangential acceleration is given by

[tex]a_t=\alpha r\\\Rightarrow a_t=0.6\times 9=5.4\ m/s^2[/tex]

Tangential acceleration of the astronaut is 5.4 m/s²

Radial acceleration is given by

[tex]a_r=\frac{v^2}{r}\\\Rightarrow a_r=\frac{48.6^2}{9}\\\Rightarrow a_r=262.44\ m/s^2[/tex]

The radial acceleration of the astronaut is 262.44 m/s²

Answer:

Explanation:

Two sphere have same mass and radius but one is solid and another is hollow

Moment of inertia is the distribution of mass about the axis of rotation

For Hollow sphere more mass is at outside therefore its moment of inertia is more than solid sphere

[tex]I_{hollow}=\frac{2}{3}mr^2[/tex]

[tex]I_{solid}=\frac{2}{5}mr^2[/tex]

To solve this problem it is necessary to apply the concepts related to Young's Module and its respective mathematical and modular definitions. In other words, Young's Module can be expressed as

[tex]\Upsilon = \frac{F/A}{\Delta L/L_0}[/tex]

Where,

F = Force/Weight

A = Area

[tex]\Delta L[/tex]= Compression

[tex]L_0[/tex]= Original Length

According to the values given we have to

[tex]\Upsilon_{steel} = 200*10^9Pa[/tex]

[tex]\Delta L = 5.6*10^{-7}m[/tex]

[tex]L_0 = 3.2m[/tex]

[tex]r= 0.59m \rightarrow A = \pi r^2 = \pi *0.59^2 = 1.0935m^2[/tex]

Replacing this values at our previous equation we have,

[tex]\Upsilon = \frac{F/A}{\Delta L/L_0}[/tex]

[tex]200*10^9 = \frac{F/1.0935}{5.6*10^{-7}/3.2}[/tex]

[tex]F = 38272.5N[/tex]

Therefore the Weight of the object is 3.82kN

To calculate the weight of the object placed on top of the cylinder, we need to use the concept of pressure and the formulas for pressure and force. The weight of the object is equal to the force, which can be calculated using the given compression and pressure values, along with the area of the cylinder. The weight of the object is approximately 1.22 x 10^5 N.

In order to calculate the weight of the object placed on top of the cylinder, we need to use the concept of pressure and the formula for pressure, which is force divided by area. First, we calculate the area of the cylinder using the formula for the area of a circle, πr2. The radius of the cylinder is 59 cm, so the area is calculated as A = π(0.59 m)2.

Then, we need to calculate the force using the given compression and the formula for force, which is pressure times area. The compression of the cylinder is given as 5.6 x 10-7 m and the pressure is given as 6.9 x 106 N/m2. Now we can calculate the force with the formula F = (6.9 x 106 N/m2)  (0.59 m)2. The weight of the object is equal to the force, so the weight of the object is approximately 1.22 x 105 N.

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Nodes and antinodes on a vibrating string standing wave has different amplitudes.

Option B

Explanation:

Final answer:

Points on a tightened string vibrating with a standing wave have different amplitudes, with nodes having no displacement and antinodes having the maximum. The frequency and speed of the wave are constant along the string, but energy varies with amplitude.

Explanation:

When a tightened string vibrates with a standing wave, points on the string vibrate with different amplitudes. This variation in amplitude can be seen by observing the points of maximum displacement (antinodes) and the points of no displacement (nodes). While points at the antinodes experience the greatest amplitude, the points at the nodes do not move at all. The frequency of oscillation is the same for all points on the string because a standing wave is established by the interference of waves traveling in opposite directions with the same frequency. Consequently, the speed of the wave along the string is also the same because it is determined by the tension and the linear mass density of the string which we assume are constant. However, the energy of the points is not the same due to the varying amplitudes; points at the antinodes have more energy as compared to those at the nodes.

Answer:

0.04225 Nm

Explanation:

N = Force applied = 5 N

[tex]\mu[/tex] = Coefficient of static friction = 0.65

d = Diameter of knob = 1.3 cm

r = Radius of knob = [tex]\frac{d}{2}=\frac{1.3}{2}=0.65\ cm[/tex]

Force is given by

[tex]F=N\mu\\\Rightarrow F=5\times 0.65\\\Rightarrow F=3.25\ N[/tex]

When we multiply force and radius we get torque

Torque on thumb

[tex]\tau_t=F\times r\\\Rightarrow \tau_t=3.25\times 0.0065\\\Rightarrow \tau_t=0.021125\ Nm[/tex]

Torque on forefinger

[tex]\tau_f=F\times r\\\Rightarrow \tau_f=3.25\times 0.0065\\\Rightarrow \tau_f=0.021125\ Nm[/tex]

The total torque is given by

[tex]\tau=\tau_t+\tau_f\\\Rightarrow \tau=0.021125+0.021125\\\Rightarrow \tau=0.04225\ Nm[/tex]

The most torque that exerted on the knob is 0.04225 Nm

The torque is dependent on the force applied to the system. The torque exerted on the knob is 0.04225 Nm.

The torque is defined as the measure of the force that can cause an object to rotate about its axis.

Given that the applied force F is 5 N and the coefficient of static friction [tex]\mu[/tex] between the knob and your fingers is 0.65. The diameter d of the knob is 1.3 cm.

The radius r of the knob is given as,

[tex]r = \dfrac {d}{2}[/tex]

[tex]r = \dfrac {1.3}{2}[/tex]

[tex]r = 0.65 \;\rm cm[/tex]

The force F' applied to the system is calculated as given below.

[tex]F' = F\mu[/tex]

[tex]F' = 5\times 0.65[/tex]

[tex]F'=3.25 \;\rm N[/tex]

Now the torque on the thumb is given as,

[tex]\tau_t = F'\times r[/tex]

[tex]\tau_t = 3.25\times 0.65\times 10^{-2}[/tex]

[tex]\tau_t = 0.021125 \;\rm Nm[/tex]

The torque on the forefinger is,

[tex]\tau_f = F'\times r[/tex]

[tex]\tau_f= 3.25\times 0.65\times 10^{-2}[/tex]

[tex]\tau_f = 0.021125 \;\rm Nm[/tex]

The total torque of the system is calculated as,

[tex]\tau = \tau_t + \tau_f[/tex]

[tex]\tau= 0.021125 + 0.021125[/tex]

[tex]\tau = 0.04225 \;\rm Nm[/tex]

Hence we can conclude that the torque exerted on the knob is 0.04225 Nm.

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Answer:

D₂ = 2.738 cm

Explanation:

Continuity equation

The continuity equation is nothing more than a particular case of the principle of conservation of mass. It is based on the flow rate (Q) of the fluid must remain constant throughout the entire pipeline.

Since the flow rate is the product of the surface of a section of the duct because of the speed with which the fluid flows, we will have to comply with two points of the same pipeline:  

Q = v*A  : Flow Equation

where:

Q = Flow in (m³/s)

A is the surface of the cross sections of points 1 and 2 of the duct.

v is the flow velocity at points 1 and 2 of the pipe.

It can be concluded that since the flow rate must be kept constant throughout the entire duct, when the section decreases, the flow rate increases in the same proportion and vice versa.

Data

D₁= 6.0 cm : faucet  diameter

v₁ = 5 m/s :  speed of fluid in the  faucet

v₂ = 20 m/s : speed of fluid in the  nozzle

Area calculation

A = (π*D²)/4

A₁ = (π*D₁²)/4

A₂ = (π*D₂²)/4

Continuity equation  

Q₁ = Q₂

v₁A₁ = v₂A₂

v₁(π*D₁²)/4 = v₂(π*D₂²)/4 : We divide by (π/4) both sides of the equation

v₁ (D₁)² = v₂(D₂)²

We replace data

6 *(5)² = 20*(D₂)²

150 = 20*(D₂)²

(150 /20) = (D₂)²

7.5 = (D₂)²

[tex]D_{2} = \sqrt{7.5}[/tex]

D₂ = 2.738 cm :  nozzle diameter

Answer:

Force (normal) = 833.85 N Compression = 1.67 x 10⁻⁸ m

Explanation:

Given data Young's Modulus (Y) = 2 x 10¹¹ N/m², Length of one side of cube = 25 cm = 0.25 m, mass of load = 85 kg

Normal force is the force exerted upon an object that is in contact with another stable object. This force would be applied by the surface onto the object in the same vector and is used to keep the object stable while it rests on a surface.

We know from Newton's Second Law that

F = ma where m is the mass and a is the acceleration (in this case due to gravity) hence, the normal opposing force to the load applied by the surface would be equal to the force applied on the surface by the weight of the load on the surface, So

F (normal) = M (load) x a = 85 x 9.81 = 833.85 N

Compression is the change in length of an object by the exertion of force upon it. Using the Young's Modulus formula we can find this change in the cube of steel. The Young's Modulus is given by

Y = (F/A)/(ΔL/L), where Y is the Young's Modulus, F is the Force being applied on the object, A is the cross sectional area on which the said force is applied, ΔL is the change in length due to said force being applied and L is the original Length of the side of the cross sectional area.

Solving this for ΔL, we can re- arrange the equation

ΔL = (F x L)/(Y x A) since area of square is L x L we can simplify the equation to get

ΔL = (F)/(Y x L), substitute the values

ΔL = (833.85)/(2 x 10¹¹ x 0.25) = 1.67 x 10⁻⁸m

Answer:

Answered

Explanation:

a) The magnitude of the magnetic flux through the coil before it is rotated is,

[tex]\phi_{initial}= BAsin\theta[/tex]

=BAsin90° = BA

therefore, the magnitude of the magnetic flux= BA

b) The magnitude of the magnetic flux through the coil after it is rotated is, Ф_final = BAsinθ

= BA sin0= 0

therefore, the magnitude of magnetic flux through the coil after it is rotated is, zero.

c)  The magnitude of the average emf induced in the coil is,

[tex]\epsilon = N\frac{d\phi}{dt}[/tex]

[tex]\epsilon = N\frac{NBA}{\Delta t}[/tex]

because Ф = BA

Answer:

77.83783 °C

Explanation:

V = Volume of room = 36 m²

c = Heat capacity = 1000 J/kg C

P = Power = 120 J/s = 120 W

t = Time = 8 hours

[tex]\rho[/tex] = Density of air = 1.225 kg/m³

[tex]\Delta T[/tex] = Change in temperature

Density is given by

[tex]\rho=\frac{m}{V}\\\Rightarrow m=\rhoV\\\Rightarrow m=1.225\times 36\\\Rightarrow m=44.1\ kg[/tex]

Heat is given by

[tex]Q=mc\Delta T\\\Rightarrow Pt=mc\Delta T\\\Rightarrow \Delta T=\frac{Pt}{mc}\\\Rightarrow \Delta T=\frac{120\times 8\times 3600}{44.4\times 1000}\\\Rightarrow \Delta T=77.83783^{\circ}C[/tex]

The temperature change you expected in this air 77.83783 °C

Final answer:

The estimated temperature change in the air of your bedroom while you sleep is approximately 78.3 °C.

Explanation:

In order to estimate the temperature change in the air of your bedroom while you sleep, we need to calculate the amount of thermal energy emitted by your body and the amount of energy absorbed by the air. Your metabolic rate is given as P = 120 J/s. Assuming you sleep for 8.0 hours, the total energy emitted is 120 J/s * 8 hours * 3600 seconds/hour = 3456000 J.

The specific heat capacity of air is given as 1000 J/kg C and the volume of your room is 36 m³. Assuming the density of air is 1.225 kg/m³, the mass of the air in your room is 1.225 kg/m³ * 36 m³ = 44.1 kg.

Using the equation Q = mcΔθ, where Q is the thermal energy absorbed/lost, m is the mass, c is the specific heat capacity, and Δθ is the change in temperature, we can calculate the temperature change as follows:

Q = mcΔθ

Δθ = Q / mc

Δθ = 3456000 J / (44.1 kg * 1000 J/kg C)

Δθ ≈ 78.3 °C

Therefore, we can estimate that the temperature change in the air of your bedroom is approximately 78.3 °C.

Answer:

Viscosity of blood will be [tex]918.54\times 10^{-6}Pa-sec[/tex]

Explanation:

We have given time to pass the capillary = 1.65 sec

Length of capillary L = 2 mm = 0.002 m

Pressure drop [tex]\Delta P=2.85kPa=2.85\times 10^3Pa[/tex]

Diameter [tex]d=5\mu m=5\times 10^{-6}m[/tex]

So radius [tex]r=\frac{5\times 10^{-6}}{2}=2.5\times 10^{-6}m[/tex]

Velocity will be [tex]v=\frac{L}{t}=\frac{0.002}{1.65}=1.212\times 10^{-3}m/sec[/tex]

We know that viscosity is given by [tex]\eta =\frac{r^2\Delta P}{8Lv}=\frac{(2.5\times 10^{-6})^2\times 2.85\times 10^3}{8\times 0.002\times 1.212\times 10^{-3}}=918.54\times 10^{-6}Pa-sec[/tex]

Viscosity of blood will be [tex]918.54\times 10^{-6}Pa-sec[/tex]

The viscosity of the blood flowing in the given capillary is [tex]9.27 \times 10^{-4} \ Pa.s[/tex]

The given parameters;

The velocity of the blood is calculated as follows;

[tex]v = \frac{L}{t} = \frac{2\times 10^{-3} \ m}{1.65 \ s} = 0.0012 \ m/s[/tex]

The radius of the capillary is calculated as follows;

[tex]r = \frac{d}{2} \\\\r = \frac{5\times 10^{-6}}{2} = 2.5 \times 10^{-6} \ m[/tex]

Assuming laminar flow, the viscosity of the blood is calculated as;

[tex]\mu = \frac{r^2 \times \Delta P}{8lv} \\\\\mu = \frac{(2.5\times 10^{-6})^2 \times 2850}{8 \times 2\times 10^{-3} \times 0.0012} \\\\\mu= 9.27 \times 10^{-4} \ Pa.s[/tex]

Thus, the viscosity of the blood flowing in the given capillary is [tex]9.27 \times 10^{-4} \ Pa.s[/tex]

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To calculate the heat required to warm the air from -20°C to body temperature with each breath, first find the mass of the air, then apply the heat transfer formula, which gives around 38 Joules of heat.

The question is asking for the amount of heat needed to warm up air from a very cold outside temperature (-20°C) to body temperature (37°C). This is a typical physics problem dealing with heat transfer and specific heat.

First, find the temperature difference: ΔT = T_final - T_initial = 37°C - (-20°C) = 57°C. Then, we convert volume to mass, using given density of air (1.3×10^-3 kg/L), so mass m = 0.50 L * 1.3×10^-3 kg/L = 0.00065 kg.

Next, apply the heat transfer formula: Q = mcΔT, where m is the mass of the air, c is the specific heat of air, and ΔT is the change in temperature. With m = 0.00065 kg, c = 1020 J/Kg°C, and ΔT = 57°C, we find Q = 0.00065 kg * 1020 J/Kg°C * 57°C = 37.887 J.

So, approximately 38 Joules of heat is needed to warm the air with each breath from -20°C to 37°C.

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The amount of heat needed to warm the 0.50 L of air to body temperature is approximately 37.79 J.

We can use the formula for heat transfer (Q) in a substance:

[tex]\[ Q = mc\Delta T \][/tex]

where:

[tex]\( Q \)[/tex] is the heat energy required (in joules),

[tex]\( m \)[/tex] is the mass of the substance (in kilograms),

[tex]\( c \)[/tex] is the specific heat capacity of the substance (in joules per kilogram per kelvin),

[tex]\( \Delta T \)[/tex] is the change in temperature (in kelvins or degrees Celsius).

First, we need to find the mass of 0.50 L of air using the given density:

[tex]\[ m = \text{density} \times \text{volume} \][/tex]

[tex]\[ m = 1.3 \times 10^{-3} \, \text{kg/L} \times 0.50 \, \text{L} \][/tex]

[tex]\[ m = 6.5 \times 10^{-4} \, \text{kg} \][/tex]

Next, we need to calculate the change in temperature [tex](\( \Delta T \))[/tex]:

[tex]\[ \Delta T = T_{\text{final}} - T_{\text{initial}} \][/tex]

[tex]\[ \Delta T = 37 \, ^\circ\text{C} - (-20 \, ^\circ\text{C}) \][/tex]

[tex]\[ \Delta T = 37 + 20 \, ^\circ\text{C} \][/tex]

[tex]\[ \Delta T = 57 \, ^\circ\text{C} \][/tex]

Now, we convert the change in temperature from degrees Celsius to kelvins:

[tex]\[ \Delta T = 57 \, \text{K} \][/tex]

Finally, we can calculate the heat required:

[tex]\[ Q = mc\Delta T \][/tex]

[tex]\[ Q = (6.5 \times 10^{-4} \, \text{kg}) \times (1020 \, \text{J/kg} \cdot \text{K}) \times (57 \, \text{K}) \][/tex]

[tex]\[ Q = 37.79 \, \text{J} \][/tex]

Answer:

Explanation:

a.) To find Secrional liftSectional lift Coefficient [tex](c_{I})=\frac{W}{(0.5*Rho*V^{2})}[/tex]

where Rho = 1.225Kg/m³ (density of air at sea level)

[tex](c_{I})=\frac{1000}{(0.5*1.225*55^{2})}=0.5397[/tex]

b.) To obtain the sectional induced coefficient:

[tex]C_{D} = \frac{(C_{L})^2}{π(AR)}[/tex]

[tex]C_{D} = \frac{(0.5397)^2}{π(5)}=0.0185[/tex]

C.) For the effective angle of attack ∝0

∝0 = [tex]\frac{C_{l}}{m_{0}}\\=\frac{0.5397}{5.7}\\=0.0947rad[/tex]

For induced angle of attack ∝i:

∝i= [tex]\frac{-C_{D}}{C_{L}}\\=\frac{-0.0185}{0.5397}\\=-0.0343rad[/tex]

For absolute angle of attack ∝a:

∝a = ∝0 - ∝i = 0.0947 - (-0.0343) = 0.1290 rad

For geometric angle of attack ∝g:

∝g = ∝a + ∝L given ∝L = -2°≅-0.0349 rad

= 0.1290-0.0349 = 0.0941rad

Final answer:

The sectional lift coefficient is 0.3102, the sectional induced-drag coefficient is 0.0185, and the effective, induced, and geometric angles of attack are -2 degrees.

Explanation:

The sectional lift coefficient can be found using the formula: CL = W / (0.5 * density * V^2 * S), where CL is the sectional lift coefficient, W is the wing loading, density is the air density, V is the airspeed, and S is the wing area.

Substituting the given values, we get: CL = 1000 / (0.5 * 1.29 * (55^2) * (15/5)), which simplifies to CL = 0.3102

The sectional induced-drag coefficient can be found using the formula: CDi = CL^2 / (pi * AR * e), where CDi is the sectional induced-drag coefficient, CL is the sectional lift coefficient, AR is the aspect ratio, and e is the span efficiency factor. Substituting the given values, we get: CDi = 0.3102^2 / (pi * 5 * 0.8), which simplifies to CDi = 0.0185

The effective angle of attack can be found using the formula: alpha_eff = alpha_i + alpha_0, where alpha_eff is the effective angle of attack, alpha_i is the induced angle of attack, and alpha_0 is the geometric angle of attack.

Substituting the given values, we get: alpha_eff = -2 + 0, which simplifies to alpha_eff = -2 degrees.

Answer:

a) The correct solution would be x=0.1544m.

b) [tex]P_f = P_i +\frac{Kx}{A}=101325Pa +\frac{2400N/m (0.1544m)}{0.011m^2}=135012.27 Pa[/tex]

Explanation:

Initial states

[tex]P_i =1atm=101325 Pa[/tex] represent the initial pressure

[tex]V_i =0.005m^3 = 5L[/tex] represent the initial volume

N represent the number of moles  

[tex]T_i = 20+273.15=293.15K[/tex] represent the initial temperature

Final states

[tex]P_f[/tex] represent the final pressure

[tex]V_f[/tex] represent the final volume

[tex]T_f = 250+273.15=523.15K[/tex]

Part a

From the initial states and with the law of ideal gases we can find the moles like this

[tex]n=\frac{P_iV_i}{RT_i}=\frac{101325Pa(0.005m^3)}{8.314\frac{J}{mol K} 293.15K}=0.2079mol[/tex]

In order to find the final pressure we need to take in count the atmospheric pressure and the pressure related to the force that the springs applies to the piston, like this:

[tex]P_f =P_i +\frac{F}{A}= P_i +\frac{Kx}{A}[/tex]

Where x is the distance that the piston is displaced upward, since increase the temperature and the gas inside tends to expand.

And we can find the final volume on this way [tex]V_f = V_i + Ax[/tex]

For the final state we have the following equation:

[tex]P_f V_f=nR T_f [/tex]

And if we replace [tex]V_f[/tex] we got:

[tex](P_i +\frac{Kx}{A})(V_i +Ax)=nRT_f[/tex]

[tex]P_i V_i +P_i A x +\frac{KxV_i}{A}+kx^2=nRT_f[/tex]

And x  can be solved with a quadratic equation:

[tex]kx^2+(P_i A +\frac{V_i K}{A})x+(P_i V_i-nRT_f)=0[/tex]

[tex]2400 k^2 +(101325Pa)(0.0110m^2)+\frac{0.005m^3 x2400N/m}{0.0110m^2})x+(101325Pa(0.005m^3)-0.2079mol(8.314J/molK)(523.15K))=0[/tex]

[tex]2400 k^2 +(2205.484)x-397.63=0[/tex]

And solving for x we got x=0.1544 or x=-1.07331 m. The correct solution would be x=0.1544m.

Part b

And the final pressure would be given by:

[tex]P_f = P_i +\frac{Kx}{A}=101325Pa +\frac{2400N/m (0.1544m)}{0.011m^2}=135012.27 Pa[/tex]

Answer:

494.24 W

442.41 W

51.83 W

Explanation:

A = Area of person = 1.2 m²

[tex]T_1[/tex] = Person's temperature = 27+273.15 = 300.15 K

[tex]T_2[/tex] = Room temperature = 18.8+273.15 = 291.95 K

[tex]\epsilon[/tex] = Emissivity of skin = 0.895

[tex]\sigma[/tex] = Stefan-Boltzmann constant = [tex]5.67\times 10^{-8}\ W/m^2K^4[/tex]

Radiated power of the person

[tex]P_1=\sigma\epsilon AT_1^4\\\Rightarrow P_1=5.67\times 10^{-8}\times 0.895\times 1.2\times 300.15^4\\\Rightarrow P_1=494.24\ W[/tex]

Power radiated by the person is 494.24 W

Radiated power absorbed by the person

[tex]P_2=\sigma\epsilon AT_2^4\\\Rightarrow P_2=5.67\times 10^{-8}\times 0.895\times 1.2\times 291.95^4\\\Rightarrow P_2=442.41\ W[/tex]

Radiated power absorbed by the person is 442.41 W

Net power would be

[tex]\Delta P=P_1-P_2\\\Rightarrow \Delta P=494.24-442.41\\\Rightarrow \Delta P=51.83\ W[/tex]

The net power loss is 51.83 W

Answer:

(a) 493.256 watt  

(b) 441.5 Watt

(c) 51.76 Watt

Explanation:

Area, A = 1.20 m^2

T = 27°C = 300 K

To = 18.8°C = 291.8 K

e = 0.895

Stefan's constant, σ = 5.67 x 10^-8 W/m^2K^4

(a) Power emitted by the person

P1 = A e σ T^4

P1 = 1.2 x 0.895 x 5.67 x 10^-8 x (300)^4

P1 = 493.256 watt

(b) Pwer absorbed by the person, P2

P2 =  A e σ To^4

P2 = 1.2 x 0.895 x 5.67 x 10^-8 x (291.8)^4

P2 = 441.5 watt

(c) Net power loss, P = P1 - P2

P = 493.256 - 441.5 = 51.76 Watt

Answer:

The distance from the top of the stick would be 2l/3

Explanation:

Let the impulse 'FΔt' acts as a distance 'x' from the hinge 'H'. Assume no impulsive reaction is generated at 'H'. Let the angular velocity of the rod about 'H' just after the applied impulse be 'W'. Also consider that the center of percussion is the point on a bean attached to a pivot where a perpendicular impact will produce no reactive shock at the pivot.

Applying impulse momentum theorem for linear momentum.

FΔt = m(Wl/2), since velocity of center of mass of rod  = Wl/2

Similarly applying impulse momentum theorem per angular momentum about H

FΔt * x = I * W

Where FΔt * x represents the impulsive torque and I is the moment of inertia

F Δt.x = (ml² . W)/3

Substituting FΔt

M(Wl/2) * x = (ml². W)/3

1/x = 3/2l

x = 2l/3

Answer

given,

Mass of Kara's car = 1300 Kg

moving with speed = 11 m/s

time taken to stop = 0.14 s

final velocity = 0 m/s

distance between Lisa ford and Kara's car = 30 m

a) change in momentum of Kara's car

  Δ P = m Δ v                  

  [tex]\Delta P = m (v_f-v_i)[/tex]

  [tex]\Delta P = 1300 (0 - 11)[/tex]

  Δ P = - 1.43 x 10⁴ kg.m/s

b) impulse is equal to change in momentum of the car

    I = - 1.43 x 10⁴ kg.m/s

c) magnitude of force experienced by Kara

  I = F x t

 I is impulse acting on the car

 t is time

  - 1.43 x 10⁴= F x 0.14

    F = -1.021 x 10⁵ N

negative sign represents the direction of force

Answer:

Explanation:

Given that,

Mass of kara car m =1300kg

Velocity at which kara car was moving Vi =11m/s

The car stopped after t= 0.14sec

Therefore the final velocity is Vf = 0m/s

a. What is the change in momentum?

Change is momentum can be determine using

∆p = ∆MV

∆p = M∆V

∆p = m(Vf-Vi)

∆p = 1300(0-11)

∆p = 1300×-11

∆p = —14,300 kgm/s

The change in momentum of kara's car is —14,300kgm/s.

b. Impulse felt be kara car?

Impulse can be determine by using Newton second law of motion

Ft = ∆p

Impulse is Ft

I = ∆p = -14,300kgm/s.

Then, the impulse felt by Kara's car is -14,300kgm/s

c. Magnitude of force experienced by Kara's car?

From the impulse formula,

Ft = ∆p

Therefore,

F = ∆p/t

F = -14,300/0.14

F = -102,142.9N.

F ≈ —102,143N

The force experienced by kara's is -102,143N.

We can also determined the deceleration of Kara's car

From Newton second law

F=ma

Then, a = F/m

a = -102,143/1300

a = -78.57m/s²

The negative sign show deceleration

We can also calculate the distance the car moved before coming to halt.

Using equation of motion

X =ut+½at²

X = 11×0.14 + ½(-78.57) × 0.14²

X = 1.54 —0.77

X = 0.77m