(a) Analyse the temperature distribution of all interior nodes in the copper cable wire by using an explicit finite-difference method of the heat equation, ∂t
∂u
​ =1.1819 ∂x 2
∂ 2
u
​ . The cable has a length (x) of 18 cm, and the length interval (h=Δx) is given by 6 cm, which consists of four (4) nodes starting from 0 cm to 18 cm. The boundary condition for the left end of the cable, u(0,t) is 400 ∘
C; meanwhile, the right end of the cable, u(18,t) is 20 ∘
C. The initial temperature of the cable is u(x,0)=20 ∘
C for 6≤x≤18. The time interval (k=Δt) is 10 s, and the temperature distribution in the cable is examined from t=0 s to t=30 s. (12 marks)

(i) Maslow's hierarchy of needs is a theory of human needs that helps to understand the various factors that influence the motivation of individuals.

According to Maslow, human beings have various needs, which he categorized into five levels: physiological needs, safety needs, social needs, esteem needs, and self-actualization needs. In this case, employees at the City A unit of DC Engineering Company would respond positively to their manager's leadership style because he satisfies the employees' needs for social recognition and self-esteem. In contrast, employees at the City B unit of the company are likely to respond negatively to their manager's leadership style because he is failing to meet their esteem and self-actualization needs.

(ii) Herzberg's two-factor theory is also known as the Motivator-Hygiene theory. Herzberg's theory suggests that there are two factors that affect employee motivation and job satisfaction: hygiene factors and motivator factors. Hygiene factors include working conditions, salary, job security, and company policies. Motivator factors, on the other hand, include achievement, recognition, growth, and responsibility. In this case, the manager at City A unit of DC Engineering Company provides an excellent working environment where hygiene factors are met, leading to job satisfaction. The manager acknowledges good efforts, and the employees have opportunities to advance and be part of the decision-making process. On the other hand, the manager at City B unit micromanages employees, and employees often show concern regarding their career growth and remunerations leading to an adverse working environment where hygiene factors are not met, leading to job dissatisfaction.

(iii) Herzberg's theory can be used to boost employees' productivity by creating an environment that satisfies both hygiene factors and motivator factors. Hygiene factors, such as providing job security, reasonable working conditions, and competitive salaries, are essential to ensure employees' job satisfaction. Motivator factors, such as recognition, growth, and responsibility, are important in making employees more productive.

(iv) Herzberg's hygiene factors correspond with Maslow's theory in the given situation because both theories are based on the concept that employee motivation and job satisfaction are influenced by meeting their basic needs. Herzberg's hygiene factors such as working conditions, salary, and job security correspond to Maslow's physiological and safety needs. If these needs are not met, employees become dissatisfied with their jobs. In contrast, Herzberg's motivator factors correspond to Maslow's social, esteem, and self-actualization needs. If these needs are met, employees become motivated and productive.

(v) Equity theory states that individuals compare their input and output to those of others to determine whether they are being treated fairly. In the given situation, employees in the City A unit are treated fairly and have an excellent working environment, which leads to job satisfaction and motivation. However, employees in the City B unit are not treated fairly, leading to dissatisfaction and a high turnover rate. Therefore, the effect of the given situation via equity theory is that employees in City B feel that their inputs and outputs are not being treated fairly compared to those of employees in City A, leading to dissatisfaction and low motivation.

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The axial thrust on the shaft is 286.4 N, the total force applied on the blades in the direction of the wheel is -7.874 N, the power developed by the turbine is 541.23 kW, the blading efficiency is 84.5%, and the average blade velocity is 673.08 m/s.

Velocity of steam at nozzle outlet, V1 = 660 m/s

Angle of outlet of steam from the nozzle, α1 = 17°

Blades outlet angle of first moving row of turbine, β2 = 18°

Blades outlet angle of second moving row of turbine, β2 = 36°

Blades outlet angle of the row of fixed blades, βf = 22°

Mean radius of the blade wheel, r = 155 mm = 0.155 m

Rotational speed of the blade wheel, N = 4000 rpm

Steam flow rate, m = 80 kg/min

Reduction in steam velocity over all the blades, i.e., (V1 − V2)/V1 = 10% = 0.1

Scale used, 1 mm = 5 m/s (for drawing velocity diagrams)

The length of the blade in the first and second rows of the turbine blades can be determined using the velocity diagram.

Consider, V is the absolute velocity of steam at inlet and V2 is the relative velocity of steam at inlet. Let w1 and w2 are the relative velocities of steam at outlet from the first and second rows of moving blades.

Hence, using the law of cosines, we get

V2² = w1² + V1² – 2w1V1 cos (α1 – β1)

For the first row of blades, β1 = 18°V2² = w1² + 660² – 2 × 660w1 cos (17° – 18°)

w1 = 680.62 m/s

The length of the velocity diagram is proportional to w1, i.e., 680.62/5 = 136.124 mm

Similarly, for the second row of moving blades, β1 = 36°V2² = w2² + 660² – 2 × 660w2 cos (17° – 36°)

w2 = 690.99 m/s

The length of the velocity diagram is proportional to w2, i.e., 690.99/5 = 138.198 mm

Let w1′ and w2′ be the relative velocities of steam at outlet from the first and second rows of blades, respectively.Using the law of cosines, we get

V2² = w1′² + V1² – 2w1′V1 cos (α1 – βf)

For the row of fixed blades, β1 = 22°

V2² = w1′² + 660² – 2 × 660w1′ cos (17° – 22°)

w1′ = 695.32 m/s

The length of the velocity diagram is proportional to w1′, i.e., 695.32/5 = 139.064 mm

The axial thrust on the shaft is given by difference between axial forces acting on the first and second moving row of blades.

Hence,Total axial thrust on the shaft = (m × (w1 sin β1 + w2 sin β2)) − (m × w1′ sin βf) = (80/60) × (680.62 sin 18° + 690.99 sin 36°) – (80/60) × 695.32 sin 22° = 286.4 N

The tangential force acting on each blade can be given by,f = (m (w1 − w1′)) / N

Length of the blade wheel = 2πr = 2 × 3.14 × 0.155 = 0.973 m

Total tangential force on the blade = f × length of blade wheel = ((80/60) × (680.62 − 695.32)) / 4000 × 0.973 = −7.874 N (negative sign implies the direction of force is opposite to the direction of wheel rotation)

Power developed by the turbine can be given by,P = m(w1V1 − w2V2) / 1000 = 80 × (680.62 × 660 − 690.99 × 656.05) / 1000 = 541.23 kW

The blade efficiency can be given by,ηb = (actual work done / work done if steam is entirely used in nozzle) = ((w1V1 − w2V2) / (w1V1 − V2)) = 84.5%

The average blade velocity can be determined by,πDN = 2πNr

Average blade velocity = Vavg = (2w1 + V1)/3 = (2 × 680.62 + 660)/3 = 673.08 m/s

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(5) Strength conditions of tight tension joints under preload F' onlyIn engineering, preload is defined as the process of applying a load or force before applying the actual load or force on a structure. Preloading is mostly used in the joining of mechanical structures and assemblies by nuts, bolts, and other similar components.

The tight tension joints that are preloaded by preload F' are the ideal and efficient type of joints used in engineering applications.  For tight tension joints, the following conditions must be met:1. The preloaded tension must exceed the external force applied to the joint.

2. The material used must be of the right quality and free from defects that could cause it to fail under preloaded tension.

3. The geometry of the joint must be correct, with the right clearances and tolerances for the bolt and nut.

4. The joint must be free from contaminants such as oil, grease, and other foreign particles that could cause the preload to reduce.

5. The preload force must be applied uniformly across the bolt's length, without any sudden or excessive fluctuations.

(6) Friction, wear and lubricationFriction, wear, and lubrication are the primary factors that affect the performance of mechanical components in engineering applications. Friction is the resistance that two surfaces experience when they come into contact with each other. Wear is the process of gradual erosion of the surfaces of components due to friction and other external factors.

Lubrication is the process of applying a lubricant such as oil, grease, or another fluid between the contacting surfaces to reduce friction and wear. The type of lubrication used depends on the degree of motion, surface conditions, and other factors that could affect the joint's performance.According to the lubrication states, the types of friction are classified as follows:

1. Dry friction - This type of friction occurs when the contacting surfaces are dry and without any lubrication. The friction force is usually high, and the surfaces experience significant wear.

2. Boundary friction - This type of friction occurs when a thin layer of lubricant is applied between the contacting surfaces. The friction force is lower than dry friction, and the wear is reduced.

3. Fluid friction - This type of friction occurs when a continuous layer of fluid separates the contacting surfaces. The friction force is the lowest, and the wear is almost negligible.

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The amount of salt in the tank at any time t is y(t) = 2000 - 50 e^(-t/40), the limit of the salt in the tank is 2000 pounds.

(a) The amount of salt y(t) in the tank at any time t:Initially, the tank contains 200 gallons of water with 40 pounds of salt. As brine is entering at a rate of 5 gallons per minute, then the amount of salt in this brine is 10 pounds per gallon. Let x(t) denote the number of gallons of brine that has entered the tank. Then, at any time t, the amount of salt in the tank is y(t).Thus, the differential equation of the amount of salt in the tank over time can be derived as:dy/dt = (10 lb/gal)(5 gal/min) - y/200 (5 gal/min)dy/dt = 50 - y/40

Rearranging the differential equation: dy/dt + y/40 = 50. The integrating factor is: e^(∫1/40dt) = e^(t/40)Multiplying both sides by the integrating factor: e^(t/40) dy/dt + (1/40) e^(t/40) y = (50/1) e^(t/40)Simplifying the left-hand side: (e^(t/40) y)' = (50/1) e^(t/40)Integrating both sides: e^(t/40) y = (50/1) ∫e^(t/40)dt + C, where C is the constant of integration.Rewriting the equation: y = 2000 - 50 e^(-t/40)

(b) The limit of the salt in the tank:The limit of y(t) as t approaches infinity can be found by taking the limit as t approaches infinity of the expression 2000 - 50 e^(-t/40).As e^(-t/40) approaches 0 as t approaches infinity, the limit of y(t) is 2000.

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The pressure inside the tank is approximately 909.12 kPa using the van der Waals equation.

To determine the pressure inside the tank using the van der Waals equation, we need to consider the van der Waals constants for argon:

a = 1.3553 N²/m⁴

b = 0.0320 m³/kg

The van der Waals equation is given by:

P = (R * T) / (V - b) - (a * n²) / (V²)

where:

P is the pressure

R is the gas constant (8.314 J/(mol·K))

T is the temperature

V is the volume

n is the number of moles of the gas

First, we need to determine the number of moles of argon gas in the tank. We can use the ideal gas law:

PV = nRT

Rearranging the equation, we have:

n = PV / RT

Given:

V = 0.02 m³

m (mass) = 1.6 kg

M (molar mass of argon) = 39.95 g/mol

T = 120 K

Converting the mass of argon to moles:

n = (m / M) = (1.6 kg / 0.03995 kg/mol) = 40.10 mol

Now we can substitute the values into the van der Waals equation:

P = (R * T) / (V - b) - (a * n²) / (V²)

P = (8.314 J/(mol·K) * 120 K) / (0.02 m³ - 0.0320 m³/kg * 1.6 kg) - (1.3553 N²/m⁴ * (40.10 mol)²) / (0.02 m³)²

Calculating the pressure:

P ≈ 909.12 kPa

Therefore, the pressure inside the tank is approximately 909.12 kPa.

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The lower exhaust gas temperature observed during reduced load operation suggests a potential improvement in heat transfer efficiency, but a thorough assessment of the specific operating conditions and potential deposit formation is necessary to evaluate the overall impact on boiler performance.

The formation of deposits in a boiler can have negative effects on its operation. Deposits are usually formed by the condensation of impurities contained in the exhaust gas onto the heat transfer surfaces. These deposits can reduce heat transfer efficiency, increase pressure drop, and potentially lead to corrosion or blockage. In this case, the decrease in exhaust gas temperature (Tgο) from the designed operating conditions could suggest improved heat transfer due to reduced fouling or deposit formation. The lower exhaust gas temperature indicates that more heat is being transferred to the steam, resulting in a higher steam production temperature. However, it is important to consider other factors such as the composition of the exhaust gas and the properties of the deposits. Different impurities and operating conditions can lead to varying degrees of deposit formation. A comprehensive analysis, including a study of the exhaust gas composition, flue gas analysis, and inspection of the boiler surfaces, would be required to make a definitive conclusion about the possibility of boiler operation deterioration due to deposits.

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A square loop with sides a and wire radius b: LA = 2μo a/π=[In (a/b) - 0.774]The given equation states that the inductance of a square loop of sides a and wire radius b can be determined as LA = 2μo a/π=[In (a/b) - 0.774].

Here, 'a' and 'b' represent the sides and the wire radius of the square loop respectively. LA represents the inductance of the square loop.The above formula can be used to calculate the inductance of a square loop. We can use this formula to find the value of the inductance of a square loop of given dimensions.Let's understand the concept of inductance before diving into the calculation of the formula.What is Inductance?Inductance is defined as the ability of a component to store energy in a magnetic field

.Inductance is the resistance of an electrical conductor to a change in the flow of electric current. It is the property of a conductor that opposes any change in the current flowing through it. The larger the inductance of a conductor, the more energy it can store in a magnetic field created by an electric current flowing through it.The inductance of a square loop of sides 'a' and wire radius 'b' can be determined using the given formula LA = 2μo a/π=[In (a/b) - 0.774].

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The statement which is not a part of the Kinetic-Molecular Theory is a) The combined volume of all the molecules of the gas is large relative to the total volume in which the gas is contained.

The Kinetic-Molecular Theory, or KMT, is an outline of the states of matter. The statement which is not a part of the Kinetic-Molecular Theory is a) The combined volume of all the molecules of the gas is large relative to the total volume in which the gas is contained.

KMT is built on a series of postulates. KMT includes four important postulates. They are the following:

Matter is composed of small particles referred to as atoms, ions, or molecules, which are in a constant state of motion.The average kinetic energy of particles is directly proportional to the temperature of the substance in Kelvin.

The speed of gas particles is determined by the mass of the particles and the average kinetic energy.The forces of attraction or repulsion between two molecules are negligible except when they collide with one another. Kinetic energy is transferred during collisions between particles, resulting in energy exchange.

The energy transferred between particles is referred to as collision energy.Therefore,

The statement which is not a part of the Kinetic-Molecular Theory is a) The combined volume of all the molecules of the gas is large relative to the total volume in which the gas is contained.

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To determine the distance out of the drilled hole the casing will be when it is resting on the bottom of the hole.

Let's begin by identifying the given values before making use of the casing movement calculation. Provided values are:Hole diameter: 12 1/8 inchDistance drilled: 2,652 feetCasing diameter: 9 3/4 inchNumber of barrels of a spacer fluid pumped down the casing: 62Length of each joint of casing: 30 feet Calculation of the casing movementThe first thing to do is to determine the total length of the casing to be run from the surface to the bottom of the drilled hole. The casing will be run in sections of 30 feet length, so the total length of the casing to be run is the quotient of the distance drilled and the length of each joint of casing.

So:Total length of casing = Distance drilled / Length of each joint of casing = 2,652 feet / 30 feet = 88.4 ≈ 89 joints of casingNext, to calculate the length of the space between the casing and the hole, we subtract the diameter of the casing from the diameter of the hole and divide by 2. Then multiply by the number of joints of casing run to the bottom of the hole, and multiply again by 12 to convert feet to inches.So: Length of space between casing and hole = [(12 1/8 inch - 9 3/4 inch) / 2] × 89 × 12= (2 3/8 inch / 2) × 89 × 12= 2.375 × 89 × 12= 2,652 ≈ 2634 inch

Finally, to calculate the distance out of the drilled hole the casing will be when it is resting on the bottom of the hole, we subtract the length of the space between the casing and the hole from the distance drilled. So: Distance out of the drilled hole = Distance drilled - Length of space between casing and hole= 2,652 feet - (2634 inch / 12)= 2,652 feet - 219.5 feet= 2,432.5 feetTherefore, the distance out of the drilled hole the casing will be when it is resting on the bottom of the hole is approximately 2,432.5 feet, which is option C.

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The pressure inside the tank is approximately 28.63 kPa by using van der Waal's equation.

The van der Waals equation for a real gas is given by:

(P + a(n/V)²)(V - nb) = nRT

Where:

P is the pressure

V is the volume

n is the number of moles of gas

R is the ideal gas constant

T is the temperature

a and b are the van der Waals constants specific to the gas

First, we need to determine the number of moles (n) of argon gas. We can use the ideal gas equation to do this:

PV = nRT

Rearranging the equation, we have:

n = PV / RT

Given:

V = 0.02 m³

T = 110 K

m (mass of argon) = 1.6 kg

molar mass of argon = 39.95 g/mol

First, we convert the mass of argon to moles:

n = (1.6 kg / 39.95 g/mol)

Now, we can substitute the values into the van der Waals equation to calculate the pressure (P):

(P + a(n/V)²)(V - nb) = nRT

To solve for P, we rearrange the equation:

P = (nRT / (V - nb)) - (a(n/V)²)

Substituting the values, we get:

P = [(1.6 kg / 39.95 g/mol) * (8.314 J/(molK)) * (110 K)] / (0.02 m³ - 0.0266 m³/mol * (1.6 kg / 39.95 g/mol)) - (1.355 Jm³/(mol²))

Calculating this expression gives us:

P ≈ 28627.89 Pa

Converting Pa to kPa:

P ≈ 28.63 kPa

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The electric field in the channel is 12,000 V/m.

a) Pinch off occurs when the VGS = Vp. for silicon JFETs, Vp = |2 |V for n-channel JFETs. The channel width can be determined with the equation W = Φ/Vp, where Φ is the donor concentration in the channel. W = 1x10¹⁶ cm³/V·s/12 V = 8.3×10¹⁴ cm.

b) To maintain pinch-off with VGS = -9 V, the drain voltage (VD) must be greater than or equal to -12 V.

c) For a given channel width, the minimum VD necessary for pinch-off to occur, is Vp or 12 V.

d) The electric field in the channel can be calculated with the equation E = VD/L, where L is the length of the channel. E = 12V/1mm = 12,000 V/m.

Therefore, the electric field in the channel is 12,000 V/m.

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The production cost per 1000 kg steam in a steam plant when the evaporation rate is 7.2 kg steam per kg coal is $18.03. This is obtained as follows;

Step-by-step explanation:

The steam produced from the combustion of coal in a steam plant can be evaluated by first finding the amount of steam generated per kg of coal burned. This is called the evaporation rate.The evaporation rate is given as 7.2 kg steam per kg coal.The cost of coal is given as $8.00 per ton.The steam plant has an average steam production of 14,500 kg per hr.Annual operational cost exclusive of coal is $15,000.The initial cost of plant is $150,000.The life of the steam plant is 20 years.

The interest on borrowed capital is 4% while the interest on the sinking fund is 3%.To find the cost of steam production per 1000 kg, the following calculations are made;

Total amount of steam produced in one year = 14,500 * 24 * 365 = 126,540,000 kg

Annual coal consumption = 126,540,000 / 7.2 = 17,541,666.67 kg

Total cost of coal in one year = (17,541,666.67 / 1000) * $8.00 = $140,333.33

Total cost of operation per year = $140,333.33 + $15,000 = $155,333.33

Annual equivalent charge = AEC = 1 + i/n - 1/(1+i/n)^n*t

Where i = interest n = number of years for which the sum is invest

dt = total life of the investment AEC = 1 + 0.04/1 - 1/(1+0.04/1)^(1*20) = 1.7487

Annual equivalent disbursement = AED = S / a

Where S = initial cost of plant + sum of annual cost (AEC) for n y

earsa = annuity factor obtained from the tables

.AED = $150,000 / 3.8879 = $38,595.69

Annual sinking fund = AS = AED * i / (1 - 1/(1+i/n)^n*t)AS = $38,595.69 * 0.03 / (1 - 1/(1+0.03/1)^(1*20)) = $1,596.51

Total annual cost of the steam plant

= $155,333.33 + $1,596.51

= $156,929.84

Cost of steam production per 1000 kg = 1000 / (126,540,000 / 14,500) * $156,929.84 = $18.03Therefore, the cost of steam production per 1000 kg is $18.03.

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A new constraint should be added as 500 MW = (Base Power)*(01-03)/X13 when a transmission line limit of 500 MW is imposed on line 1-3.

A transmission line limit is the maximum amount of power that can be transmitted through a transmission line. The transmission line's capacity is determined by the line's physical attributes, such as length, voltage, and current carrying capacity.

Transmission lines are the backbone of the electrical grid, allowing electricity to be transported over long distances from power plants to where it is required. The transmission line limits must be properly managed to prevent overloading and blackouts.

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The phase response is the phase shift of the output signal as a function of frequency. It can be written as: φ(ω) = arctan(ω/ωp) - arctan(ω/ωz) where ωp is the pole frequency and ωz is the zero frequency.

QUESTION 1: The correct answer is option D) 16kHz.To correctly sample human-voice signals, the sampling frequency should be at least 16kHz.

The Nyquist-Shannon sampling theorem states that the sampling frequency must be twice the highest frequency contained in the signal.

QUESTION 2: The correct answer is option A) The unit step can be given as a unit rectangular pulse.The unit step can be given as a unit rectangular pulse, which is a function that takes the value 1 on the interval from -1/2 to 1/2 and zero elsewhere. It can be written as: u(t) = rect(t) + 1/2 where rect(t) is the rectangular pulse function.

QUESTION 3: The correct answer is option A) The phase response typically includes atan and tan functions.The phase response typically includes atan and tan functions.

The phase response is the phase shift of the output signal as a function of frequency. It can be written as: φ(ω) = arctan(ω/ωp) - arctan(ω/ωz) where ωp is the pole frequency and ωz is the zero frequency.

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Wheel and Gear Friction Wheel and Gear both are used to transmit power. Friction wheel is a simple device that is commonly used in low power applications. It is also known as a belt drive and can be found in home appliances such as washing machines, mixers, etc.

Friction wheels work by using the friction between the wheel and the belt to transmit power. On the other hand, gear drives are more commonly used in high power applications. Gears can be found in cars, trains, wind turbines, and many other machines. They transmit power by meshing together and transferring torque. Two important differences between Friction Wheel and Gear are: Friction wheels are easy to maintain while gears require more maintenance. Friction wheels are less expensive than gears.

Merits of Gear Drives:High efficiency: Gear drives have high efficiency as compared to other drives like belt drives.No slippage: Gear drives have no slippage, making them suitable for high power transmission and critical applications.Long life: Gear drives have a longer life than belt drives as they are made of metal. Hence they are more reliable and can be used for a longer duration of time. Smooth operation: Gear drives provide smooth operation as they don't slip and produce less noise.

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A. The suitable length of bolt is 240 mm (rounded up to nearest 5 mm).

B.  Stiffness of AISI 1050 steel plate (k1) = 1313.8 N/mm

Stiffness of 1st 2024-T3 aluminium plate (k2) = 287.5 N/mm

Stiffness of 2nd 2024-T3 aluminium plate (k3) = 664.1 N/mm

(a) Suitable length of bolt: For calculating the suitable length of bolt, the thickness of the 2024-T3 aluminium plates, thickness of AISI 1050 steel plate, thickness of nut and threaded length of bolt must be considered.

Based on the given dimensions:

Thickness of AISI 1050 steel plate (t1) = 40 mmThickness of 1st 2024-T3 aluminium plate (t2)

= 20 mm Thickness of 2nd 2024-T3 aluminium plate (t3)

= 30 mm Threaded length of bolt (l)

= l1 + l2Threaded length of bolt (l)

= 2 × (t1 + t2 + t3) + 6 mm (extra for nut)l

= 2(40 + 20 + 30) + 6

= 232 mm

The suitable length of bolt is 240 mm (rounded up to nearest 5 mm).

(b) Bolt stiffness: Bolt stiffness (kb) can be calculated by the following formula: kb=π × d × d × Eb /4 × l

where,d = bolt diameter

Eb = modulus of elasticity of the bolt material

l = length of the bolt

The diameter of the bolt

(d) is 14 mm. Modulus of elasticity of the bolt material (Eb) is given as 200 kN/mm².

Substituting the given values in the formula:

kb= 3.14 × 14 × 14 × 200 / 4 × 240 = 1908.08 N/mm(e)

Stiffness of members:

The stiffness (k) of a member can be calculated by the following formula :k = π × E × I / L³

where,E = modulus of elasticity of the material of the member

I = moment of inertia of the cross-sectional area of the member

L = length of the member

For AISI 1050 steel plate:

E = 200 kN/mm²t = 40 mm

Width of plate = b = 1 m

Moment of inertia of the plate can be calculated using the formula:

I = (b × t³) / 12I

= (1000 × 40³) / 12

= 6.67 × 10^7 mm^4

Stiffness of the AISI 1050 steel plate can be calculated as:

k1 = 3.14 × 200 × 6.67 × 10^7 / (1000 × 1000 × 1000 × 1000)

= 1313.8 N/mm

For 1st 2024-T3 aluminium plate:

E = 73.1 kN/mm²

t = 20 mm

Width of plate = b = 1 m

Moment of inertia of the plate can be calculated using the formula:

I = (b × t³) / 12I = (1000 × 20³) / 12

= 1.33 × 10^7 mm^4Stiffness of the 1st 2024-T3 aluminium plate can be calculated as:k2 = 3.14 × 73.1 × 1.33 × 10^7 / (1000 × 1000 × 1000 × 1000) = 287.5 N/mm

For 2nd 2024-T3 aluminium plate:

E = 73.1 kN/mm²

t = 30 mm

Width of plate = b = 1 m

Moment of inertia of the plate can be calculated using the formula:

I = (b × t³) / 12I = (1000 × 30³) / 12

= 2.25 × 10^7 mm^4

Stiffness of the 2nd 2024-T3 aluminium plate can be calculated as:

k3 = 3.14 × 73.1 × 2.25 × 10^7 / (1000 × 1000 × 1000 × 1000)

= 664.1 N/mm

Therefore, Stiffness of AISI 1050 steel plate (k1) = 1313.8 N/mm

Stiffness of 1st 2024-T3 aluminium plate (k2) = 287.5 N/mm

Stiffness of 2nd 2024-T3 aluminium plate (k3) = 664.1 N/mm

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the temperature after compression is 2682 K. In an ideal Otto engine with an air compression ratio of 9 starts with an air pressure of 90kpa and a temperature of 25 C,

the temperature after compression can be determined using the ideal gas law. The ideal gas law is given as;PV=nRTWhere P is the pressure, V is the volume, n is the number of moles of the gas, R is the gas constant, and T is the temperature.In the problem above, we are interested in finding the final temperature (T2) after compression given initial conditions of pressure (P1)

temperature (T1) which are; P1 = 90 kPa and T1 = 25 °C = 298 K respectively. The air compression ratio is given as; r = 9. Therefore, the volume at the end of compression (V2) will be 1/9th of the initial volume (V1) that is;V2 = V1 / 9.From the ideal gas law, we have;P1V1 / T1 = P2V2 / T2Where;P2 = P1rV2 = V1/9Substituting the values gives;P1V1 / T1 = P1rV1 / 9T2 = T1r9T2 = 298 K x 9T2 = 2682 KT

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To determine the particle's deceleration when it is located at point A, we need to differentiate the velocity function with respect to time. Given that the velocity function is v = (130 s) mm/s, where s is in millimeters:

v = 130s

To find the deceleration, we differentiate the velocity function with respect to time (s):

a = dv/dt = d(130s)/dt

Since the particle is traveling along a straight line within a liquid, we can assume that its velocity is a function of time only.

Differentiating the velocity function, we get:

a = 130 ds/dt

To find the deceleration at point A, where SA = 90 mm, we substitute the position value into the equation:

a = 130 d(90)/dt

Since the position is not given as a function of time, we assume that it is constant at SA = 90 mm.

Therefore, the deceleration at point A is:

a = 130 * 0 = 0 mm/s²

The deceleration at point A is 0 mm/s².

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To answer your questions, let's consider the context of fluid mechanics and boundary layers:

Assumptions in the solution: In fluid mechanics, various assumptions are often made to simplify the analysis and mathematical modeling of fluid flow. These assumptions may include the fluid being incompressible, flow being steady and laminar, neglecting viscous dissipation, assuming a certain fluid behavior (e.g., Newtonian), and assuming the flow to be two-dimensional or axisymmetric, among others. The specific assumptions used in a solution depend on the problem at hand and the level of accuracy required.

Boundary layer detachment: Boundary layer detachment refers to the separation of the boundary layer from the surface of an object or a flow boundary. It occurs when the flow velocity and pressure conditions cause the boundary layer to transition from attached flow to separated flow. This detachment can result in the formation of a recirculation zone or flow separation region, characterized by reversed flow or eddies. Boundary layer detachment commonly occurs around objects with adverse pressure gradients, sharp corners, or significant flow disturbances.

Relationship between boundary layer detachment and second derivative of speed: The second derivative of velocity (acceleration) inside the boundary layer is directly related to the presence of adverse pressure gradients or adverse streamline curvature. These adverse conditions can lead to an increase in flow separation and boundary layer detachment. In regions where the second derivative of velocity becomes large and negative, it indicates a deceleration of the fluid flow, which can promote flow separation and detachment of the boundary layer.

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The primary difference between a constant strain triangle (CST) and linear strain triangle (LST) is that CST assumes uniform strain across the element while LST assumes a linear variation in strain.

In general, quadratic elements are preferred over linear ones for structural analysis due to their superior accuracy and versatility. Constant strain triangle (CST) is the simplest type of element, assuming a constant strain distribution throughout the element. This leads to less accurate results in complex problems. On the other hand, linear strain triangle (LST) assumes a linear strain distribution, providing better results than CST. Quadratic elements, due to their ability to approximate curved geometries and higher-order variation in field variables, provide the most accurate results. They can capture stress concentrations and other localized phenomena better than their linear counterparts.

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Rubber is effective in providing good mountings for delicate instruments due to its unique properties, such as high elasticity, flexibility, and damping capabilities. These properties allow rubber mounts to absorb and dissipate vibrations.

(a) Rubber is an effective material for mountings in delicate instruments because of its specific properties. Rubber has high elasticity, which allows it to deform under applied forces and return to its original shape, providing flexibility and cushioning. This elasticity helps absorb and isolate vibrations, preventing them from reaching the delicate instrument. Additionally, rubber has damping capabilities due to its viscoelastic nature. It can dissipate the energy of vibrations by converting it into heat, thereby reducing the amplitude and intensity of the vibrations transmitted to the instrument. (b) When the plate begins vibrating and the frequency increases.

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1. Theoretical mass of air required is 9.484375 units

2. Actual air/fuel ratio is 0.0948

3. Mass of excess air is 18.4052

1. Theoretical mass of air required = Mass of carbon/12 + Mass of hydrogen/4 + Mass of sulphur/32 - Mass of oxygen/32

Theoretical mass of air required = (87/12) + (9/4) + (1/32) - (1.5/32)

Theoretical mass of air required = 7.25 + 2.25 + 0.03125 - 0.046875

Theoretical mass of air required = 9.484375 units

2 Actual air/fuel ratio = Theoretical mass of air required / Total fuel mass

Actual air/fuel ratio = 9.484375 / 100

Actual air/fuel ratio ≈ 0.0948

3 Mass of excess air = Actual air/fuel ratio - Stoichiometric air/fuel ratio (assuming stoichiometric ratio of 18.5)

Mass of excess air = 18.5 - 0.0948

Mass of excess air ≈ 18.4052

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Given data:Pressure of steam entering turbine (P1) = 10 MPaTemperature of steam entering turbine (T1) = 500 degree CPressure of steam at the condenser (P2) = 10 kPaPower generated (W) = 210 MWNow, let's draw the T-s diagram with respect to saturation lines below:

1. The quality of steam at the turbine exit:From the T-s diagram, we can see that at the turbine exit, the state point lies somewhere between the two saturation lines.Using the steam tables, we can find the saturation temperature and pressure at the exit state:Pressure at the exit (P3) = 10 kPaSaturated temperature corresponding to P3 = 46.9 degree CEnthalpy of saturated liquid corresponding to P3 (h_f) = 191.81 kJ/kgEnthalpy of saturated vapor corresponding to P3 (h_g) = 2676.5 kJ/kgThe quality of steam (x) at the exit state is given by:x = (h - h_f)/(h_g - h_f)Where, h is the specific enthalpy at the exit state.

h = 191.81 + x(2676.5 - 191.81)h = 191.81 + 2421.69x= (h - h_f)/(h_g - h_f)x = (191.81 + 2421.69 - 191.81)/(2676.5 - 191.81)x = 0.91The quality of steam at the turbine exit is 0.91.2. Thermal efficiency of the cycle:For an ideal Rankine cycle, thermal efficiency is given by:eta_th = 1 - (T2/T1)Where, T2 and T1 are the temperatures of the steam at the condenser and the turbine inlet respectively.

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1. Continuous x-rays occur when a high energy electron strikes a metal atom in the target, causing the innermost electrons of the atom to be removed from their orbits. This process leaves an electronic vacancy in the inner shell, which can be filled by an electron from an outer shell. When an outer shell electron fills the inner shell vacancy, it releases energy in the form of an x-ray. However, because each electron shell has a different binding energy, the energy of the released x-ray varies.

2. The swl (short wavelength limit) moves to the left as the tube voltage increases because the x-ray energy and wavelength are inversely proportional. When the tube voltage increases, the energy of the emitted x-rays also increases, and the wavelength decreases. the swl shifts to the left on the graph as the tube voltage increases.

3. The x-ray intensity increases as the tube voltage increases because higher tube voltage results in more electron acceleration, which generates more x-rays. When the tube voltage is increased, more electrons are accelerated across the anode, resulting in more x-rays produced and higher x-ray intensity.

4. The x-ray emitted is not symmetric because of the characteristic x-rays and bremsstrahlung x-rays. Characteristic x-rays occur when an electron drops down to fill an inner shell vacancy, releasing energy in the form of an x-ray. The energy of characteristic x-rays is fixed because the energy difference between the two shells is fixed. Bremsstrahlung x-rays, on the other hand, are emitted when an electron is deflected by the positive charge of the nucleus.

The energy of bremsstrahlung x-rays can vary depending on the extent of electron deflection, resulting in a continuous spectrum of x-ray energies. This combination of characteristic and bremsstrahlung x-rays results in a non-symmetric distribution of x-ray energy.

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It is a method of compressing stress air, adding fuel to the compressed air, igniting the fuel-air mixture, and then expanding the air-fuel mixture to generate power.

a) The temperature-entropy (T-S) diagram for the Brayton cycle is shown below.   In a gas turbine engine, the Brayton cycle is a thermodynamic cycle.

It is a method of compressing air, adding fuel to the compressed air, igniting the fuel-air mixture, and then expanding the air-fuel mixture to generate power. The following are the stages of the cycle: 1. Isentropic compression 2. Isobaric heat addition 3. Isentropic expansion 4. Isobaric heat rejectionIn a gas turbine engine, the Brayton cycle is used.

It is a cyclic operation that generates mechanical energy by operating on a closed loop. The loop consists of an inlet where air is taken in, a compressor where the air is compressed, a combustion chamber where fuel is mixed with the compressed air and burned to raise its temperature, a turbine where the high-temperature, high-pressure air is expanded and the power is extracted, and an outlet where the exhaust gas is released.

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The back work ratio of an ideal air-standard Brayton cycle is the same as the ratio of compressor inlet (T1) and turbine outlet (T4) temperatures in Kelvin. Use a cold-air standard analysis.

Given data T1 = More than 100 in KelvinT4 = More than 100 in Kelvin Formula, Back Work Ratio (BWR) = Wc / Q_ in (or) W_ t / Q_ in, Where Wc = Work of compressor, W_ t = Work of turbine, and Q_ in = Heat Supplied to the cycle. Proof: The Brayton cycle is a closed-cycle in which the working fluid receives and rejects heat in the same manner.

Rankine cycle, but the working fluid is not water but air. The cycle comprises four basic components: compressor, heat exchanger, turbine, and heat exchanger, with two adiabatic expansion and compression processes. The first process is compression by the compressor.

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When writing a practical report, you will need to have an introduction where you introduce your experimental topics and it should be divided into 3 paragraphs.

The following is an outline of how the introduction should be structured:

This paragraph should give a brief definition of your topics. Here, you should explain what your experimental topics are and why they are important. It is important to be clear and concise in this paragraph.  This paragraph should provide a brief history of motor failure analyses and link it to today's applications and methods used in this day and age.

Here, you should explain how motor failure analyses have evolved over time and how they are used today. You should also discuss the methods used in this day and age and how they are different from the methods used in the past. This paragraph should introduce your work and state what is required from you on this assignment. You should name the paragraph the AIM.

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The cam follower mechanism with a displacement diagram that has the following sequence, rise 2 mm in 1.2 seconds, dwell for 0.3 seconds, fall 1 r in 0.9 seconds, dwell again for 0.6 seconds and then continue falling for 1 E in 0.9 seconds can be analyzed as follows:a) To determine the cam rotation angle during the rise, we should know that it took 1.2 seconds to rise 2 mm.

We must first compute the cam's linear velocity during the rise:Linear velocity = (Displacement during the rise) / (Time for the rise)= 2 / 1.2 = 1.67 mm/s Then we can calculate the angle:Cam rotation angle = (Linear velocity * Time) / (Base circle radius)= (1.67 * 1.2) / 10 = 0.2 radian= (0.2 * 180) / π = 11.47 degrees Therefore, the cam rotation angle during the rise is 11.47 degrees. Therefore, option a) is incorrect.b) The rotational speed of the cam can be calculated as follows:Linear velocity = (Displacement during the second fall) / (Time for the second fall)= 1 / 0.9 = 1.11 mm/s

Therefore, the rotational speed of the cam is 71.95 rpm. Therefore, option b) is incorrect.c) To determine the cam rotation angle during the second fall, we should know that it took 0.9 seconds to fall 1 E. We must first compute the cam's linear velocity during the fall:Linear velocity = (Displacement during the fall) / (Time for the fall)= 1 / 0.9 = 1.11 mm/s Then we can calculate the angle:Cam rotation angle = (Linear velocity * Time) / (Base circle radius)= (1.11 * 0.9) / 10 = 0.0999 radians= (0.0999 * 180) / π = 5.73 degrees

Therefore, the cam rotation angle during the second fall is 5.73 degrees. Therefore, option c) is incorrect.Therefore, the answer is option e) None of the above.

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The inlet area of the diffuser is 11.57 in^2.

To determine the inlet area of the diffuser, we can use the mass flow rate and the velocity of the steam at the inlet. The mass flow rate is given as 5 lbm/s, and the velocity is given as 80.0 ft/s.

The mass flow rate, denoted by m_dot, is equal to the product of density (ρ) and velocity (V) times the cross-sectional area (A) of the flow. Mathematically, this can be expressed as:

m_dot = ρ * V * A

Rearranging the equation, we can solve for the cross-sectional area:

A = m_dot / (ρ * V)

Given the values for mass flow rate, velocity, and the properties of steam at the inlet (pressure and temperature), we can calculate the density of the steam using steam tables or thermodynamic properties of the fluid. Once we have the density, we can substitute the values into the equation to find the inlet area of the diffuser.

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The distance between the parallel axes of gears or the crossed axes of helical gears and worm gears is known as the "Center distance" (C).

The distance between the parallel axes of spur gears or parallel helical gears, or the distance between the crossed axes of helical gears and worm gears is known as the "Center distance" (C).

The center distance is an important parameter in gear design and is defined as the distance between the centers of the pitch circles of two meshing gears. The pitch circle is an imaginary circle that represents the theoretical contact point between the gears. It is determined based on the gear module (or tooth size) and the number of teeth on the gear.

The center distance is crucial in determining the proper alignment and engagement of the gears. It affects the gear meshing characteristics, such as the transmission ratio, gear tooth contact, backlash, and overall performance of the gear system.

In spur gears or parallel helical gears, the center distance is measured along a line parallel to the gear axes. It determines the spacing between the gears and affects the gear ratio. Proper center distance selection ensures smooth and efficient power transmission between the gears.

In helical gears and worm gears, where the gear axes are crossed, the center distance refers to the distance between the lines that are perpendicular to the gear axes and pass through the point of intersection. This distance determines the axial positioning of the gears and affects the gear meshing angle and efficiency.

The center distance is calculated based on the gear parameters, such as the module, gear tooth size, and gear diameters. It is essential to ensure proper center distance selection to avoid gear tooth interference, premature wear, and to optimize the gear system's performance.

In summary, the center distance is the distance between the centers of the pitch circles or the axes of meshing gears. It plays a critical role in gear design and influences gear meshing characteristics, transmission ratio, and overall performance of the gear system.

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