What is the uncertainty in position of an electron of an atom if there is t 2.0 x 10' msec uncertainty in its velocity? Use the reduced Planck's constant and electron mass 9.19 x 103 kg.

Answer:

N = 38546.82 rpm

Explanation:

[tex]D_{1}[/tex] = 150 mm

[tex]A_{1}= \frac{\pi }{4}\times 150^{2}[/tex]

              = 17671.45 [tex]mm^{2}[/tex]

[tex]D_{2}[/tex] = 250 mm

[tex]A_{2}= \frac{\pi }{4}\times 250^{2}[/tex]

              = 49087.78 [tex]mm^{2}[/tex]

The centrifugal force acting on the flywheel is fiven by

F = M ( [tex]R_{2}[/tex] - [tex]R_{1}[/tex] ) x [tex]w^{2}[/tex] ------------(1)

Here F = ( -UTS x [tex]A_{1}[/tex] + UCS x [tex]A_{2}[/tex] )

Since density, [tex]\rho = \frac{M}{V}[/tex]

                        [tex]\rho = \frac{M}{A\times t}[/tex]

                        [tex]M = \rho \times A\times t[/tex][tex]M = 7100 \times \frac{\pi }{4}\left ( D_{2}^{2}-D_{1}^{2} \right )\times t[/tex]

                        [tex]M = 7100 \times \frac{\pi }{4}\left ( 250^{2}-150^{2} \right )\times 37[/tex]

                        [tex]M = 8252963901[/tex]

∴ [tex]R_{2}[/tex] - [tex]R_{1}[/tex] = 50 mm

∴ F = [tex]763\times \frac{\pi }{4}\times 250^{2}-217\times \frac{\pi }{4}\times 150^{2}[/tex]

  F = 33618968.38 N --------(2)

Now comparing (1) and (2)

[tex]33618968.38 = 8252963901\times 50\times \omega ^{2}[/tex]

∴ ω = 4036.61

We know

[tex]\omega = \frac{2\pi N}{60}[/tex]

[tex]4036.61 = \frac{2\pi N}{60}[/tex]

∴ N = 38546.82 rpm

Answer:

Four- high rolling mill                              Two-high rolling mill

1.Small roll radius.That is why required  1.High roll radius.That is  required low power.           .                    why required high power.

2.  Low roll separating force.                   2.High roll separating

                                                                        force

Answer:

(a)[tex]s_2-s_1[/tex]= -0.098 KJ/kg-K

(b)P= 29.8 KW

(c) [tex]S_{gen}[/tex]= -0.098 KW/K  

Explanation:

[tex]V_1=1m^3/kg,V_2=0.71m^3/kg,[/tex] mass flow rate= 1 kg/s.

T=25°C

Air treating as ideal gas

(a)

We know that entropy change for ideal gas between two states

 [tex]s_2-s_1=mC_v\ln \frac{T_2}{T_1}+mR\ln \frac{V_2}{V_1}[/tex]

Given that this is isothermal process so

 [tex]s_2-s_1=mR\ln \frac{V_2}{V_1}[/tex]

[tex]s_2-s_1=1\times 0.287\ln \frac{0.71}{1}[/tex]

[tex]s_2-s_1[/tex]= -0.098 KJ/kg-K

(b)

Power required

[tex]P=\dot{m}T\Delta S[/tex]

[tex]P=1\times (273+25)(s_2-s_1)[/tex]

[tex]P=1\times (273+25)(-0.098)[/tex]

P= -29.8 KW        (Negative sign means it is compression process.)

(c)

Rate of entropy generation [tex]S_{gen}[/tex]

[tex]S_{gen}=\dot{m}T\Delta S[/tex]  

[tex]S_{gen}[/tex]=1(-0.098)

 [tex]S_{gen}[/tex]= -0.098 KW/K  

Given:

max displacement, A = 3.2 m

f= 50 Hz

at t = 0, displacement, d = 150 cm = 1.5 m

Solution:

Displacement in the general form is represented by:

d = Asin(ωt ± α)

d = 3.2sin(2πft ± α)

d = 3.2sin(100πt ± α)                    

where,

A = 3.2 m,            

ω = 2πf = 100π

Now,

at t = 0,

1.5 = 3.2sin(100π(0) ± α )

1.5 = 3.2sinα

sin α = [tex]\frac{1.5}{3.2}[/tex] = 0.4687

α = [tex]sin^{-1}(0.46875)[/tex] = 27.95° = 0.488 radian

Now, we can express displacement in the form of 'Asin(wt + α)' as:

d = 3.2sin(100πt ± 0.488 )

Answer:

it is f all of the above

Explanation:

let me know if im right

im not positive if im right but i should be right

Answer: A)  Gradually decrease

Explanation:

  The convection value of heat transfer rate are gradually decreasing with the flow of the heat. Flow in a circular pipe, flow direction does not change in the velocity path. The average of the coefficient of heat transfer and the number of pipes are needed and the effects are get neglected so that is why the flow are fully developed.

Answer:

Power consume by compressor=113,726.87 KW

Explanation:

Given:[tex]P_{1}=100KPa ,V_{1}=200 m/s,T_{1}=283 K, A_{1} =2m^2[/tex]

 [tex]P_{2}=2000KPa ,T_{2}=513 K,A_{2}=0.5m^2[/tex]

Actually compressor is an open system, so here we will use first law of thermodynamics for open system .

We know that first law of thermodynamics for steady flow

[tex]h_{1}+\frac{V_{1} ^{2} }{2}+Q=h_{2}+\frac{V_{2} ^{2} }{2}+W[/tex]

We know that[tex]C_{p}=1.005\frac{Kj}{KgK}[/tex]and we take the air as ideal gas.

System is in steady state then mass flow rate in =mass flow rate out

Mass flow rate= [tex]density\times area\times velocity[/tex]

So mass flow rate =[tex]\rho _{1}V_{1}A_{1}[/tex]     ,[tex]\rho =\frac{P}{RT}[/tex]

                                   =1.23×200×2 Kg/s

                                  =541.17 Kg/s

[tex]\rho _{1}V_{1}A_{1}=\rho _{2}V_{2}A_{2}[/tex]

[tex]\rho _{2}=13.58\frac{Kg}{{m}^3}[/tex]  ,[tex]\rho =\frac{P}{RT}[/tex]

[tex]V_{2}[/tex]=80.07 m/s

Enthalpy of ideal gas h=[tex]C_{p}\times T[/tex]

So[tex] h_{1}=1.005\times283=284.41\frac{Kj}{Kg}[/tex]

             [tex]h_{2}=1.005\times513=515.56\frac{Kj}{Kg}[/tex]

Now by putting the values

[tex]284.41+\frac{220 ^{2} }{2000}+Q=515.56+\frac{80.07 ^{2} }{2000}+W[/tex]

Here Q=0 because heat transfer is zero here.

W= -210.15 KJ/kg

So power consume by compressor=541.17×210.15

                                                          =113,726.87 KW

In vibration analysis, damping cannot always be disregarded. This is especially the case when the system is excited near the resonance frequency.

Answer:900 KJ/kg

Explanation:

Given data

mass flow rate of fluid through tube is=1 kg/s

Initial enthalpy of fluid through tube=100 KJ/kg

Final enthalpy of fluid through tube=500KJ/kg

mass flow rate of fluid through shell is=4 kg/s

Initial enthalpy of fluid through shell=1000 KJ/kg

Final enthalpy of fluid through shell=[tex]h_2[/tex]

since heat lost by Shell fluid is equal to heat gain by Tube fluid  

heat lost by Shell fluid=[tex]4\times c\left ( 1000-h_2\right )[/tex]

Heat gain by tube Fluid=[tex]1\times c\left ( 500-100\right )[/tex]

Equating both heats

[tex]4\times c[/tex][tex]\left ( 1000-h_2\right )[/tex]=[tex]1\times c\left ( 500-100\right )[/tex]

[tex]h_2[/tex]=900 KJ/kg

Answer:

explained

Explanation:

Gear is a  mechanical components designed for transfer of torque or power from one shaft to the other. Gear designing is a costly affair. The configuration and geometry of gears are such that its designing is tedious task. A lot of precision is required to design a gear. This is why factor of safety of gears are always kept higher.

The higher factor of safety accounts for durability of gears. Gears once made can used for about 200 hundred years. The wear and tear are less and the failure of gears is avoided. And hence whole machine failure can be avoided.  

Answer:

Load carried by shaft=9.92 ft-lb

Explanation:

Given:    Power P=4.4  HP

                    P=3281.08 W

Power:  Rate of change of work with respect to time is called power.

We know that P=[tex]Torque\times speed[/tex]

     [tex]\omega=\frac{2\pi N}{60}[/tex] rad/sec

So that P=[tex]\dfrac{2\pi NT}{60}[/tex]

So   3281.08=[tex]\dfrac{2\pi \times 2329\times T}{60}[/tex]

      T=13.45 N-m         (1 N-m=0.737 ft-lb)

 So T=9.92 ft-lb.

Load carried by shaft=9.92 ft-lb

Answer:

The given statement "A negative normal strain can be considered to increase or decrease volume depending on coordinate system used" is

b) False

Explanation:

Normal strain refers to the strain due to normal stress which is when the applied stress is perpendicular to the surface.

Negative normal strain results in compression or contraction further leading to a decrease in volume while a positive normal strain results in elongation thus giving rise to an increase in volume.

Answer:

275 Kelvin

Explanation:

Coefficient of Performance=11

[tex]T_H=\text {Absolute Temperature of high temperature reservoir=300 K}[/tex]

[tex]T_L=\text {Absolute Temperature of low temperature reservoir}[/tex]

[tex]\text {Coefficient of performance for carnot cooler}\\=\frac {T_L}{T_H-T_L}\\\Rightarrow 11=\frac{T_L}{300-T_L}\\\Rightarrow 11(300-T_L)=T_L\\\Rightarrow 3300-11T_L=T_L\\\Rightarrow 3300=T_L+11T_L\\\Rightarrow 3300=12T_L\\\Rightarrow T_L=\frac {3300}{12}\\\Rightarrow T_L=275\ K\\\Therefore \text{Temperature at which the refrigerator absorbs heat=275 Kelvin}[/tex]

Answer:

the rate of heat loss is 2.037152 W

Explanation:

Given data

stainless steel K = 16 W [tex]m^{-1}K^{-1}[/tex]

diameter (d1) = 10 cm

so radius (r1)  = 10 /2 = 5 cm = 5 × [tex]10^{-2}[/tex]

radius (r2)  = 0.2 + 5 = 5.2 cm = 5.2 × [tex]10^{-2}[/tex]

temperature = 25°C

surface heat transfer coefficient = 6 6 W [tex]m^{-2}K^{-1}[/tex]

outside air temperature = 15°C

To find out

the rate of heat loss

Solution

we know current is pass in series from temperature = 25°C to  15°C

first pass through through resistance R1  i.e.

R1  = ( r2 -  r1 ) / 4[tex]\pi[/tex]  × r1 × r2 × K

R1  = ( 5.2 - 5 ) [tex]10^{-2}[/tex]  / 4[tex]\pi[/tex]  × 5 × 5.2 × 16 × [tex]10^{-4}[/tex]

R1  = 3.825 ×  [tex]10^{-3}[/tex]

same like we calculate for resistance R2 we know   i.e.

R2 = 1 / ( h × area )

here area = 4 [tex]\pi[/tex] r2²

area = 4 [tex]\pi[/tex] (5.2 × [tex]10^{-2}[/tex])²  =  0.033979

so R2 = 1 / ( h × area ) = 1 / ( 6 × 0.033979  )

R2 = 4.90499

now we calculate the heat flex rate by the initial and final temp and R1 and R2

i.e.

heat loss = T1 -T2 / R1 + R2

heat loss = 25 -15 / 3.825 ×  [tex]10^{-3}[/tex] + 4.90499

heat loss =  2.037152 W

Answer:

The correct option is : b. Brass

Explanation:

The cutting tool materials are materials that are used to make cutting tools. The cutting tools serve a very important roles in the machinery such as milling cutters. The materials used for making the cutting tools must be tougher and harder than the material that is being cut, at all temperatures.

Some of the cutting tool materials are tool steels (carbon tool steel and high speed steel), cemented carbides and super hard materials such as diamond.

Therefore, brass is not used for making cutting tool.

Answer and explanation :

Fluid distribution is a new technique to produce and to transmit power from one place to other its play a major role in power distribution it is a process of using fluid (any type of fluid as oil or water ) under pressure to generate to control or to transmit  

fluid power system is divided into two types

Answer:

(d) all of the above

Explanation:

before cutting the screw threads the operator should lubricate all of the machine parts given in the option that is lead screw and gearbox , the ways and the cross slide and the carriage and half-nuts. we should use lubrication because it reduces the overall system friction and if friction is reduced then heat generated due to friction is also decreases which is beneficial

so option (D) will be correct because we need lubricate in all the given parts  

Answer:b) Point defects

Explanation: The point defect is the tiny defect that occurs in the lattice. It usually occurs when there is the atoms or ions missing in the lattice structure that creates a irregularity in the structure.The name point defect itself describes that the occurring defect is having a size of point thus is the smallest defect. Therefore option(b) is the correct option.

Answer:

B. 3 m

Explanation: For plastic injection moulded the thickness is generally between 2 mm to 3 mm

the wall is not too thick because during cooling process there should be defects so thickness of wall is no too high and there is also a problem if we use thicker wall that we need more material for moulding process so the thickness should be in between 2 to 3 mm which is in option B so option B will be the correct option

Answer:

ICP -OES stand for inductively coupled plasma optical emission spectroscopy

Explanation:

It is techniques that known as trace level technique which help to identify and quantify the element present in sample by using spectra emission.

The analysis process include desolvates, ionization and excitation of the sample. The sample is identify by analyzing the emission line from it and quantify by analyzing the intensity of same emission lines.

Answer:

ICP stands for Insane Clown Posse. It is a rap group. The group's members are Violent J and Shaggy 2 Do*e

Explanation:

Answer:

a) 0.51 s

b) 1.275m

Explanation:

using equation of linear motion

v=u+gt...........................(1)

[tex]v^{2} -u^{2}=2gh[/tex]...........(2)

[tex]s=ut+\frac{1}{2} gt^2[/tex].......(3)

a) as the ball is thrown upward -ve 'g' will be acting on the body

as the body reaches to the maximum height the final velocity(v) becomes

zero so from equation (1)

0=5-9.8t

[tex]t=\frac{5}{9.8}[/tex]

t=0.51s

b) Now for maximum height calculation using equation (2)

[tex]v^{2} -u^{2}=2gh[/tex]

v=0

[tex]h=\frac{-u^2}{2g}[/tex]

[tex]h=\frac{-5^2}{2\times-9.8}[/tex]

h=1.275m

Answer:

Thermosetting polymers are polymers that becomes soft and pliable when heated is false

Answer:

Removal of dust and fluff from spinning mill is important as it has adverse and detrimental effects on the health of the workers in these industries. Tiny and microscopic particles of various substances present in the surrounding air is transferred from one place to another and these causes various respiratory diseases and pose health hazards for the workers and make work environment unhealthy and hazardous thus affecting the over all efficiency and productivity.

Cotton dust , the major pollutant, when breathed in affetcs the lungs badly and workers experience symptoms such as respiratory problems, coughing, tightness in chest, etc.  Thus to ensure proper health of the workers spinning mills have been provided with powerful air conditioning to ensure purity of air, to maintain proper moisture levels and to ensure dust and fluff removal.

The dust and fluff laiden air is humidified, purified and then recirculated. Optimization of number of air changes/hour to clean air stream and prevent any health risk of the workers.

Answer:

[tex]h_2-h_1=6\times 10^{-3}\frac{KJ}{Kg}[/tex]

Explanation:

Now from first law for open system

[tex]h_1+\dfrac{V_1^2}{2}+Q=h_2+\dfrac{V_2^2}{2}+w[/tex]

Here given  Q=0 ,w=0

So [tex]h_1+\dfrac{V_1^2}{2}=h_2+\dfrac{V_2^2}{2}[/tex]

[tex]V_1=4 m/s,V_2=2 m/s[/tex]

[tex]h_1+\dfrac{4^2}{2000}=h_2+\dfrac{2^2}{2000}[/tex]

[tex]h_2-h_1=6\times 10^{-3}[/tex]

So increase in specific enthalpy

[tex]h_2-h_1=6\times 10^{-3}\frac{KJ}{Kg}[/tex]

Answer:2.88

Explanation:

Answer:

F₁ = 1500 N

F₂ = 750 N

[tex]F_{e}[/tex] = 500 N

Explanation:

Given :

Power transmission, P = 7.5 kW

                                      = 7.5 x 1000 W

                                      = 7500 W

Belt velocity, V = 10 m/s

F₁ = 2 F₂

Now we know from power transmission equation

P = ( F₁ - F₂ ) x V

7500 = ( F₁ - F₂ ) x 10

750 =  F₁ - F₂

750 = 2 F₂ - F₂      ( ∵F₁ = 2 F₂ )

∴F₂  = 750 N

Now F₁ = 2 F₂

        F₁ = 2 x F₂

        F₁ = 2 x 750

        F₁ = 1500 N   ,   this is the maximum force.

Therefore we know,

[tex]F_{max}[/tex] = 3 x [tex]F_{e}[/tex]

where [tex]F_{e}[/tex] is centrifugal force

 [tex]F_{e}[/tex] = [tex]F_{max}[/tex] / 3

                          = 1500 / 3

                         = 500 N

Answer: False

Explanation: Horizontal axis wind turbines are usually used for generation of the electric power on the off-shore. The generation of horizontal-axis wind turbine works well when it is installed away from the shore because it supports large sized wind turbines so that they can generate high amount of electricity.They are usually not preferred for the on-shore wind farms because they can have small sized wind turbines only.Therefore the statement given is false.

Answer:

1 ton refrigeration =3.517 kJ/s = 3.517 kW

Explanation:

Refrigeration capacity is defined at the  measure of the effective cooling capacity of a refrigerator which is  expressed in Btu per hour or in tons.

1 ton capacity is a unit of air conditioning and refrigeration which  measure the capacity of air conditioning and refrigeration unit.

One ton  is equal to removal of 3025kcal heat per hour

1 ton refrigeration = 200 Btu/min = 3.517 kJ/s = 3.517 kW = 4.713 HP

Answer:

1. Mass = 2070 kg

2.Total length of strip = 2556 m

3. Total length of dislocation = 7.67 X[tex]10^{14}[/tex] m

Explanation:

Given:

Aluminium coil thickness, t = 0.3 mm

                                              = 0.3 X [tex]10^{-3}[/tex] m

Width of the coil,w = 1 m

Drum diameter, d = 15 cm

                              = 0.15 m

Coil outer diameter, d = 1 m

Dislocation density = [tex]10^{15}[/tex] [tex]m^{2}[/tex]

1). Area of the coil, A = [tex]\frac{\pi }{4}\times[/tex] ( [tex]d_{coil} ^{2}[/tex]-[tex]d_{drum} ^{2}[/tex])

                           A = [tex]\frac{\pi }{4}\times (1^{2}-0.15^{2})[/tex]

                           A = 0.767 [tex]m^{2}[/tex]

Volume of the coil,V = A X w

                                  = 0.767 X 1

                                  = 0.767 [tex]m^{3}[/tex]

We know density of aluminum at STP = 2.7 X [tex]10^{3}[/tex]

Therefore, mass of the aluminum coil is,

Mass,m = Density of aluminium X Volume

             = 2.7 X [tex]10^{3}[/tex] X 0.767

             = 2070 kg

Mass = 2070 kg

2). Total length of trip of coil is given by

          L = Volume of coil / area of strip

             = [tex]\frac{0.767}{1\times 0.3\times 10^{-3}}[/tex]

              = 2556 m

Total length of strip = 2556 m

3). Total length of dislocation of the coiled strip = volume X dislocation density

                                                                             = 0.767 X [tex]10^{15}[/tex]

                                                                              = 7.67 X [tex]10^{14}[/tex]

Total length of dislocation = 7.67 X[tex]10^{14}[/tex] m

To hoist a load 6 meters in 1.5 seconds, the cable must be drawn in by the motor at a constant speed of 4 meters per second.

The question asks to determine the constant speed at which a cable must be drawn in by a motor to hoist a load to a certain height within a given time frame. This can be solved by understanding the basic concepts of distance, speed, and time.

To find the constant speed, we use the formula:
Speed = Distance / Time. In this case, the distance is 6 meters (the height the load needs to be hoisted) and the time is 1.5 seconds.

Plugging the numbers into the formula gives:
Speed = 6m / 1.5s = 4 m/s.

Therefore, the cable must be drawn in by the motor at a constant speed of 4 meters per second to hoist the load 6 meters in 1.5 seconds.