A has a mass of 7 kg, object B has a mass of 5 lbm, and object C has a mass of 0.5 slug. (a) Which object has the largest mass? Which object has the smallest mass? (b) Find the weights of objects A, B and C (in both N and lbf) on the surface of Mars.

Answer:

Wind

Hydro electric

Explanation:

Energy are of two types

1.Renewable energy

 These have unlimited source of energy.

Ex: Solar energy,wind energy,geothermal energy,hydro power ,biomass etc

2.Non renewable energy

These have limited source of energy.

Ex:  Petroleum,Coal

Wind is the fastest renewable source of energy.This energy is produce by using the natural velocity of air.

Hydro electric power plant is the mostly used renewable source of energy to produce electricity.

Answer with Explanation:

The growth of renewable sources of energy depend on various factor's and their grown is also a regional dependent process. Many different countries use different renewable sources of energy and the growth of the renewable sources of energy depend on the location of the place. As an example in India the solar energy is the most widely growing source of energy due to the location of the place. while as in European union Bio energy is the source of renewable energy that has shown the most growth.

Water is the renewable source which is  used to produce the most electricity in the world accounting for 16.3% of the total global electricity production.

Answer:

V=33.66 m/s

[tex]Re=448.8\times 10^6[/tex]

Re>4000, The flow is turbulent flow.

Explanation:

Given that

Pressure difference  = 50 mm of Hg

We know that density of Hg=136000[tex]Kg/m^3[/tex]

ΔP= 13.6 x 1000 x 0.05 Pa

ΔP=680 Pa

Diameter of tunnel = 200 mm

Property of air at 25°C

ρ=1.2[tex]Kg/m^3[/tex]

Dynamic viscosity

[tex]\mu =1.8\times 10^{-8}\ Pa.s[/tex]

Velocity of fluid given as

[tex]V=\sqrt{\dfrac{2\Delta P}{\rho_{air}}}[/tex]

[tex]V=\sqrt{\dfrac{2\times 680}{1.2}}[/tex]

V=33.66 m/s

Reynolds number

[tex]Re=\dfrac{\rho _{air}Vd}{\mu }[/tex]

[tex]Re=\dfrac{1.2\times 33.66\times 0.2}{1.8\times 10^{-8}}[/tex]

[tex]Re=448.8\times 10^6[/tex]

Re>4000,So the flow is turbulent flow.

Answer:

The term Accuracy means that how close our result to the original result.

Suppose we do any experiment in laboratory and we calculate mass = 7 kg but answer is mass = 15 kg then our answer is not accurate.

And the term Precision means how likely we get result like this.

Suppose we do any experiment in laboratory and we calculate mass five times and each time we get mass = 7 kg then our answer is precised but not accurate.

Answer:

9.7g / cm^3

Explanation:

To calculate a conbined density we must find the ratio  between the sum of the masses and the sum of the volumes remembering that the equation to find the density is α=m/v, taking into account the above the following equation is inferred.

αc=copper density

αs=silver density

Vs=volume of silver

Vc=volume of copper

α= density of alloy

[tex]\alpha =\frac{({\alpha c}{Vc} +{\alpha s }{Vs} )}{Vs+Vc} \\\alpha =\frac{(8.9)(10) +(10.5)(10) }{10+10} \\\\\alpha =9.7g / cm^3[/tex]

the density of the alloy is 9.7g / cm^3

Answer:

1) Velocity at t =6 =32m/s

2) Position of particle at t = 6 secs = 67 meters

3) Distance covered in 6 seconds equals 72 meters.

Explanation:

By definition of acceleration we have

[tex]a=\frac{dv}{dt}\\\\dv=a(t)dt\\\\\int dv=\int a(t)dt\\\\v(t)=\int (2t-1)dt\\\\v(t)=t^{2}-t+c_{1}[/tex]

Now at t = 0 v = 2 m/s thus the value of constant is obtained as

[tex]2=0-0+c_{1}\\\\\therefore c_{1}=2[/tex]

thus velocity as a function of time is given by

[tex]v(t)=t^{2}-t+2[/tex]

Similarly position can be found by

[tex]x(t)=\int v(t)dt\\\\x(t)=\int (t^{2}-t+2)dt\\\\x(t)=\frac{t^{3}}{3}-\frac{t^{2}}{2}+2t+c_{2}[/tex]

The value of constant can be obtained by noting that at time t = 0 x = 1.

Thus we get

[tex]1=0+0+0+c_{2}\\\\\therefore c_{2}=1[/tex]

thus position as a function of time is given by

[tex]x(t)=\frac{t^{3}}{3}-\frac{t^{2}}{2}+2t+1[/tex]

Thus at  t = 6 seconds we have

[tex]v(6)=6^{2}-6+2=32m/s[/tex]

[tex]x(6)=\frac{6^{3}}{3}-\frac{6^{2}}{2}+2\times 6 +1=67m[/tex]

The path length can be obtained by evaluating the integral

[tex]s=\int_{0}^{6}\sqrt{1+(t^{2}-t+2)^{2}}\cdot dt\\\\s=72meters[/tex]

Explanation:

Step1

Volume flow rate is the rate of change of volume of fluid that is flowing in the duct of pipe per unit time. It is measure in m³/s or l/s. Volume flow rate is very important parameter in fluid analysis.

Step2

For the given duct, the volume flow rate is the product of average velocity to the cross section area of duct.

Expression for volume flow rate is given as follows:

Q=AV

Here, Q is the flow rate, A is area of the duct and V is the average velocity of flowing fluid.

Answer:

Net discharge per hour will be 3.5325 [tex]m^3/hr[/tex]

Explanation:

We have given internal diameter d = 25 mm

Time = 1 hour = 3600 sec

So radius [tex]r=\frac{d}{2}=\frac{25}{2}=12.5mm=12.5\times 10^{-3}m[/tex]

We know that area is given by

[tex]A=\pi r^2=3.14\times (12.5\times 10^{-3})^2=490.625\times 10^{-6}m^2[/tex]

We know that discharge is given by [tex]Q=AV[/tex], here A is area and V is velocity

So [tex]Q=AV=490.625\times 10^{-6}\times 2=981.25\times 10^{-6}m^3/sec[/tex]

So net discharge in 1 hour = [tex]981.25\times 10^{-6}m^3/sec\times 3600=3.5325m^3/hour[/tex]

Answer:

Shearing strain will be 0.1039 radian

Explanation:

We have given change in length [tex]\Delta L=0.12inch[/tex]

Length of the pad L = 1.15 inch

We have to find the shearing strain

Shearing strain is given by

[tex]\alpha =tan^{-1}\frac{\Delta L}{L}=tan^{-1}\frac{0.12}{1.15}=5.9571^{\circ}[/tex]

Shearing strain is always in radian so we have to change angle in radian

So [tex]5.9571\times \frac{\pi }{180}=0.1039radian[/tex]

Answer:

4.29%

Explanation:

Given:

Density of water, ρ = 1000 kg/m³

elevation change of Δz = 800 m

work per unit mass delivered, Wp = 8,200 J/kg

Now,

The percent irreversibility = [tex](1-n_p)\times100[/tex]

where,

[tex]n_p\frac{W_{actual}}{W_{theoretical}}[/tex]

also,

[tex]W_{actual}=\frac{g\Delta z}{1000}[/tex]

Where, g is the acceleration due to the gravity

on substituting the values, we get

[tex]W_{actual}=\frac{9.81\times800}{1000}[/tex]

or

[tex]W_{actual}=7.848\ KJ/kg[/tex]

or

[tex]W_{actual}=7848\ J/kg[/tex]

Therefore,

The percent irreversibility = [tex](1-n_p)\times100[/tex]

on substituting the values, we get

The percent irreversibility = [tex](1-\frac{7848}{8,200})\times100[/tex]

or

The percent irreversibility = 4.29%

Answer:

Part 1) Speed at s = 420 meters =12.26 m/s

Part 2) Time required to cover the distance = 26 seconds

Explanation:

This problem can be solved using third equation of kinematics as follows

[tex]v^2=u^2+2as[/tex]

where

'v' is the final velocity

'u' is the initial velocity

'a' is the acceleration of the car

's' is the distance covered between change in velocities

Now during the time at which the car moves it cover's a distance of 420 m-100 m=320 meters

Thus applying values in the above equation we get

[tex]v^2=12^{2}+2\times 0.01\times 320\\\\v^2=150.4\\\\\therefore v=12.26m/s[/tex]

The time to reach this velocity  can be found using first equation of kinematics as

[tex]v=u+at\\\\\therefore t=\frac{v-u}{a}\\\\t=\frac{12.26-12}{0.01}=26seconds[/tex]

Answer:Yes,266.66 MPa

Explanation:

Given

Yield stress of material =140 MPa

Cross-section of [tex]300\times 100 mm^2[/tex]

Force(F)=8 MN

Therefore stress due to this Force([tex]\sigma [/tex])

[tex]\sigma =\frac{F}{A}=\frac{8\times 10^6}{300\times 100\times 10^{-6}}[/tex]

[tex]\sigma =266.66 \times 10^{6} Pa[/tex]

[tex]\sigma =266.66 MPa[/tex]

Since induced stress  is greater than Yield stress therefore Plastic deformation occurs

Answer:

Mass of earth will be [tex]M=5.96\times 10^{24}kg[/tex]

Explanation:

We have given acceleration due to gravity [tex]g=9.81m/sec^2[/tex]

Radius of earth = 6370 km =[tex]6370\times 10^3m[/tex]

Gravitational constant [tex]G=6.67\times 10^{-11}Nm^2/kg^2[/tex]

We know that acceleration due to gravity is given by

[tex]g=\frac{GM}{R^2}[/tex], here G is gravitational constant, M is mass of earth and R is radius of earth

So [tex]9.81=\frac{6.67\times 10^{-11}\times M}{(6370\times 10^3)^2}[/tex]

[tex]M=5.96\times 10^{24}kg[/tex]

So mass of earth will be [tex]M=5.96\times 10^{24}kg[/tex]

Answer:

[tex]\eta = 91.7[/tex]%

Explanation:

Determine the initial velocity

[tex]v_1 = \frac{\dot v}{A_1}[/tex]

    [tex] = \frac{0.1}{\pi}{4} 0.08^2[/tex]

     = 19.89 m/s

final velocity

[tex]v_2 =\frac{\dot v}{A_2}[/tex]

      [tex]= \frac{0.1}{\frac{\pi}{4} 0.12^2}[/tex]

      =8.84 m/s

total mechanical energy is given as

[tex]E_{mech} = \dot m (P_2v_2 -P_1v_1) + \dot m \frac{v_2^2 - v_1^2}{2}[/tex]

[tex]\dot v = \dot m v[/tex]                       [tex]( v =v_1 =v_2)[/tex]

[tex]E_{mech} = \dot mv (P_2 -P_1) + \dot m \frac{v_2^2 - v_1^2}{2}[/tex]

                [tex] = mv\Delta P + \dot m  \frac{v_2^2 -v_1^2}{2}[/tex]

                 [tex]= \dot v \Delta P  + \dot v \rho \frac{v_2^2 -v_1^2}{2}[/tex]

              [tex]   = 0.1\times 500 + 0.1\times 860\frac{8.84^2 -19.89^2}{2}\times \frac{1}{1000}[/tex]

[tex]E_{mech} = 36.34 W[/tex]

Shaft power

[tex]W = \eta_[motar} W_{elec}[/tex]

    [tex]=0.9\times 44 =39.6[/tex]

mechanical efficiency

[tex]\eta{pump} =\frac{ E_{mech}}{W}[/tex]

[tex]=\frac{36.34}{39.6} = 0.917  = 91.7[/tex]%

Answer:

The direction of any heat transfer between the systems will be from system B to System A.

Explanation:

The direction of any heat transfer between the systems will be from system B to System A.

Even if the system A has a higher thermal Energy it will be from B to A because the system B has a higher temperature than A. The energy will be transferred from B to A until the temperature of the two systems equals and the temperature is in equilibrium.

This comes from the fundamental law of thermodynamics.

Answer:

The collision force is 81987.577 lbf

Explanation:

Apply Newton’s second law of motion for required collision force exerted on the goose.

Given:  

Mass of goose is 12 lb.

Time of collision is [tex]10^{-3}[/tex] s.

Taking off speed is 150 miles/h.

Calculation:  

Step1

Convert take off speed in ft/s as follows:

[tex]v=(150mi/h)(\frac{\frac{5280}{3600}ft/s}{1mi/h})[/tex]

v = 220 ft/s

Step2  

Collision force is calculated as follows:

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

[tex]F=\frac{(\frac{12}{32.2})220}{10^{-3}}[/tex]

F = 81987.577 lbf.

Thus, the collision force is 81987.577 lbf.  

Answer:

Please, see the attachment.

Explanation:

First, we have to create two input boxes that allows the user to write the current year in one of them and his/her birth year in the another one. Also, we have to create a label that will show the result of the desired variable. We can write a message "Your age is:" and it will be attached to the result.

For the algorithm, let's call the variables as follows:

CY = Current Year

BY = Birth Year

X = Age of user

When the user inserts the current year and his/her birth year, the program will do the following operation:

X = CY - BY; this operation will give us the age of the user

After this the user will see something like "Your age is:" X.

Answer:

The gravitational force between the masses is [tex]1.0\times 10^{-8}Newtons[/tex]

Explanation:

For 2 masses 'm' and 'M' separated by a distance 'd' the gravitational force between them is given by Newton as

[tex]F=G\cdot \frac{mM}{d^{2}}[/tex]

where

'G' is universal gravitational constant whose value is [tex]6.67\times 10^{-11}m^3kg^{-1}s^{-2}[/tex]

Applying the values in the above relation we get

[tex]F=6.67\times 10^{-11}\times \frac{8\times 12}{(800\times 10^{-3})^{2}}=1.0\times 10^{-8}Newtons[/tex]

Weight of 8 kg mass =[tex]8\times 9.81=78.45Newtons[/tex]

Weight of 12 kg mass =[tex]12\times 9.81=117.72Newtons[/tex]

thus we see that gravitational force between the masses is completely negligible as compared to the weight of the masses.

Answer:

wr = 6.32 rad/s

Explanation:

m = 750 kg

k = 30 kN/m

This system has no dampening, therefore the resonance frequency will simply be the natural frequency of the system.

[tex]wr = w0 = \sqrt{\frac{k}{m}}[/tex]

[tex]wr = \sqrt{\frac{30000}{750}} = 6.32 rad/s[/tex]

In this case the force applied doesn't matter. because we are calculating the resonance frequency.

Answer:

The force between the charges when the separation decreases to 0.7 meters equals 126.955 Newtons

Explanation:

We know that for two point charges of magnitude [tex]q_{1},q_{2}[/tex] the magnitude of force between them is given by

[tex]F=\frac{k_{e}q_{1}\cdot q_{2}}{r^{2}}[/tex]

where

[tex]k_{e}[/tex] is constant

[tex]r[/tex] is the separation between the charges

Initially when the charges are separated by 2.4 meters the force can be calculated as

[tex]F_{1}=\frac{k_{e}\cdot q_{1}q_{2}}{2.4^{2}}\\\\10.8=\frac{k_{e}\cdot q_{1}q_{2}}{2.4^{2}}\\\\\therefore k_{e}\cdot q_{1}q_{2}=10.8\times 2.4^{2}=62.208[/tex]

Now when the separation is reduced to 0.7 meters the force is similarly calculated as

[tex]F_{2}=\frac{k_{e}\cdot q_{1}q_{2}}{0.7^{2}}[/tex]

Applying value of the constant we get

[tex]F_{1}=\frac{62.208}{0.7^{2}}[/tex]

Thus [tex]F_{2}=126.955Newtons[/tex]

Answer:

No, is not a violation of the first law of thermodynamics.

Explanation:

The first law of thermodynamics states that energy is neither created nor destroyed in an isolated system (a system without mass or energy transfer with ambient).

In a heat pump work is used to transfer heat from a cold body to a hot body (see figure). In a free system heat would go from the heat source to the cold one, that is why you need work. Work and heat are energy in transit.

W + Qin = Qout

In your case

2 kW + Qin =  7 kW

Qin =5 kW

It would be a violation to the first law of thermodynamics if Qout is less than  2 kW.

Answer:

6243.6 lbs

Explanation:

We have given weight = 2838 kg

We have to convert this weight into lbs

Both kg and lbs are unit of measuring the weight of the body so they are changeable

We know that 1 lbs = 2.20 kg

So for converting kg into lbs we have to multiply with 2.20

So 2838 kg = 2838×2.2 = 6243.6 pound

So weight of 2838 kg will be equivalent to 6243.6 lbs

Answer:

1) Acceleration of player is 7.8125 [tex]m/s^{2}[/tex].

2) Constant speed of player is 12.5 m/s.

Explanation:

Let the acceleration of the player by 'a' and let he complete the initial 10 meters in [tex]t_1[/tex] time

The initial 10 meters are case of uniformly accelerated motion and hence we can relate the above quantities using second equation of kinematics as

[tex]s=ut+\frac{1}{2}at^{2}\\\\[/tex]

now since the player starts from rest hence u = 0 thus the equation can be written as

[tex]10=\frac{1}{2}at_1^2\\\\at_{1}^{2}=20...........(i)[/tex]

The speed the player reaches after [tex]t_{1}[/tex] time is obtained using first equation of kinematics as

[tex]v=u+at\\v=at_{1}[/tex]

Since the total distance traveled by the player is 40 meters hence the total time of trip is 4 seconds hence we infer that he covers 30 meters of distance at a constant speed in time of [tex]4-t_{1}[/tex] seconds

Hence we can write

[tex](4-t_{1})\cdot at_{1}=30.......(ii)\\\\[/tex]

Solving equation i and ii we get

from equation 'i' we obtain [tex]a=\frac{10}{t_{1}^{2}}[/tex]

Using this in equation 'ii' we get

[tex](4-t_{1})\cdot \frac{20}{t_{1}^{2}}\cdot t_{1}=30\\\\30t_{1}=80-20t_{1}\\\\\therefore t_{1}=\frac{80}{50}=1.6seconds\\\\\therefore a=\frac{20}{1.6^2}=7.8125m/s^{2}[/tex]

Thus constant speed equals [tex]v=7.8125\times 1.6=12.5m/s[/tex]

Answer:

Emissions produce by combustion of fossil fuel:

1.Sulfur di oxide

2.Carbon mono oxide

3.Nitrogen oxide

4.Particular matter

5.Lead

6.Hydrocarbon

7.Photo chemical smog

Effects of emissions produce by combustion of fossil fuel:

1.Sulfur and nitrogen oxide leads to acid rain which corrodes the monuments.

2.Carbon mono oxide affects the central nervous system.

3.Particular matter produce asthma diseases.

4.Lead damage red blood cells.

5.Free silica produce cough and chest pain.

Answer:

Explanation:

Engineering Stress is defined as Load applied to the original cross-sectional area which we have taken in the start.

True stress is defined as the load divided by area of cross-section of specimen at that instant.

Engineering stress  and true stress can be expressed by relation

[tex]\sigma _T=\sigma _E\left ( 1+\epsilon _E\right )[/tex]

Where

[tex]\sigma _T=True\ stress[/tex]

[tex]\sigma _E=Engineering\ stress[/tex]

[tex]\epsilon _E=Engineering\ Strain[/tex]

Answer:

a) zero b) zero

Explanation:

Newton's first law tells us that a body remains at rest or in uniform rectilinear motion, if a net force is not applied on it, that is, if there are no applied forces or If the sum of forces acting is zero. In this case there is a body that moves with uniform rectilinear motion which implies that there is no net force.

Answer:

9 cm

Explanation:

The liquid on the bend will be affected by two accelerations: gravity and centripetal force.

Gravity will be of 9.81 m/s^2 pointing down at all points.

The centripetal acceleration will be of

ac = v^2/r

Pointing to the center of the bend (perpendicular to gravity).

The velocity will depend on the radius

v = (1 m^2/s) / r

Replacing:

ac = (1/r)^2 / r

ac = (1 m^4/s^2) / r^3

If we set up a cylindrical reference system with origin at the center of the bend, the total acceleration will be

a = (-1/r^3 * i - 9.81 * j)

The surface of the liquid will be an equipotential surface, this means all points on the surface have the same potential energy.

The potential energy of the gravity field is:

pg = g * h

The potential energy of the centripetal force is:

pc = ac * r

Then the potential field is:

p = -1/r^2 * - 9.81*h

Points on the surface at r = 1 m and r = 3 m have the same potential.

-1/1^2 * - 9.81*h1 = -1/3^2 * - 9.81*h2

-1 - 9.81*h1 = -1/9 - 9.81*h2

-1 + 1/9 = 9.81 * (h1 - h2)

h1 - h2 = (-8/9) / 9.81

h2 - h1 = 0.09 m

The outer part will be 9 cm higher than the inner part.

Answer:

Water needs to be added into the pool at the rate of 1064.814 Liters/min.

Explanation:

The concentration in mg/L of the chlorine in the pool that is induced by dumping the whole container of chlorine into the pool equals

[tex]\frac{500\times 10^{3}}{200\times 10^{3}}=2.5mg/l[/tex]

Since this is in excess to the required concentration of 0.20 mg/L

Let the amount of pure water we need to add be equal to 'V' liters now since pure water does not have any chlorine thus

By the conservation of mass principle we have

[tex]0\times V+2.5\times 200\times 10^{3}=0.20\times (V+200\times 10^{3})[/tex]

Solving for V we get

[tex]V=\frac{2.5\times 200\times 10^{3}-0.20\times 200\times 10^{3}}{0.20}=2300000Liters[/tex]

Thus 2300000 Liters of water needs to be further added in 36 hours

Thus the rate of flow in L/min equals

[tex]Q=\frac{2300000}{36\times 60}=1064.814Liters/min[/tex]

Answer:

Silica is the principal component in glass.

Explanation:

Step1

Glass is the amorphous solid and transparent. Glass products have many of the shapes and design that are available in market.

Step2

Natural quartz is the primary source of glass in sand. Silica is the principal component in approximately all glass. Lime stone, soda ash and aluminum oxide are added in the galas for desired properties depending upon application. So, silica is the principal component in glass.

Answer:

The availability of system will be 0.9

Explanation:

We have given mean time of failure = 900 hours

Mean time [to repair = 100 hour

We have to find availability of system

Availability of system is given by  [tex]\frac{mean\time\ of\ failure}{mean\ time\ of\ failure+mean\ time\ to\ repair}[/tex]

So availability of system [tex]=\frac{900}{900+100}=\frac{900}{1000}=0.9[/tex]

So the availability of system will be 0.9

Answer:

308 acre-ft of water

Explanation:

Given:

Area of the watershed = 22 square miles

Depth of Rainfall = 0.75 in =[tex]\frac{\textup{0.75}}{\textup{12}}[/tex]=0.0625 ft

Percentage rainfall falling in reservoir as runoff = 35%

Now,

1 square mile = 640 acre

Thus,

22 square miles = 22 × 640 = 14,080 acres

Thus,

The total volume of rainfall = Area of watershed × Depth of the rainfall

or

The total volume of rainfall = 14,080 acres × 0.0625 ft = 880 acre-ft

also,

only 35% of the total rainfall is contributing as runoff

thus,

Runoff = 0.35 × 880 acre-ft = 308 acre-ft of water