To calculate the specific enthalpy and temperature at the throat, the specific volume, area, and diameter at the throat, and the actual dryness factor, specific volume, area, velocity, and specific actual enthalpy at the exit.
To calculate the specific enthalpy and temperature at the throat, we can use the specific heat capacity and the given pressure and velocity values. From the given data, the specific heat capacity of the steam at the throat is 2.56 kJ/kg.K, and the pressure and velocity are 820 kPa and 500 m/s, respectively. We can apply the specific heat formula to find the specific enthalpy at the throat.
To determine the specific volume, area, and diameter at the throat, we can use the given specific volume of dry saturated steam at the exit pressure and the fact that the isentropic dryness factor is 98.95% of the actual dryness factor. By applying the isentropic dryness factor to the given specific volume, we can calculate the actual specific volume at the exit pressure. The specific volume is then used to calculate the cross-sectional area at the throat, which can be converted to diameter.
Finally, to find the actual dryness factor, specific volume, area, velocity, and specific actual enthalpy at the exit, we need to use the given data of the specific volume of dry saturated steam at the exit pressure. The actual dryness factor can be obtained by dividing the actual specific volume at the exit by the specific volume of dry saturated steam at the exit pressure. With the actual dryness factor, we can calculate the specific volume, area, velocity, and specific actual enthalpy at the exit.
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The manufacturer of a component that will be subjected to fatigue from -0 MPa to 50 MPa, specifies that it must be changed when it has been detected that the crack has advanced up to 40% of its critical value. The manufacturing process of the component leaves cracks on the surface of 0.1mm. The material has the following properties: KIC = 70MPam1/2 and crack growth is characterized by n=3.1 and C= 10E-11. Assume f=1.12.
How many life cycles did the component have left after it had been removed as directed by the manufacturer?
Indicate your answer without decimals.
Fatigue is the weakening of a material caused by cyclic loading, resulting in the formation and propagation of cracks.
Fatigue fracture failure is a type of failure that is caused by cyclic loading, which is the progressive growth of an initial crack until it reaches a critical size and a fracture occurs. In this question, we are given the following information.
The manufacturing process of the component leaves cracks on the surface of 0.1mm.The material has the following properties: [tex]KIC = 70 MPam1/2[/tex], and crack growth is characterized by n = 3.1 and C = 10E-11. Assume f = 1.12.Calculations:In this question.
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An insulated, rigid tank whose volume is 0.5 m³ is connected by a valve to a large vesset holding steam at 40 bar, 400°C. The tank is initially evacuated. The valve is opened only as long as required to fill the tank with steam to a pressure of 30 bar Determine the final temperature of the steams in the tank, in °C, and the final mass of the steam in the tank, in kg
The final temperature of steam in the tank is 375/V1°C, and the final mass of steam in the tank is 1041.26 V1 kg.
The given problem is related to the thermodynamics of a closed system. Here, we are given an insulated, rigid tank whose volume is 0.5 m³, and it is connected to a large vessel holding steam at 40 bar and 400°C. The tank is initially evacuated. The valve is opened only as long as required to fill the tank with steam to a pressure of 30 bar. Our objective is to determine the final temperature of the steam in the tank and the final mass of the steam in the tank. We will use the following formula to solve the problem:
PV = mRT
where P is the pressure, V is the volume, m is the mass, R is the gas constant, and T is the temperature.
The gas constant R = 0.287 kJ/kg K for dry air. Here, we assume steam to behave as an ideal gas because it is at high temperature and pressure. Since the tank is initially evacuated, the initial pressure and temperature of the tank are 0 bar and 0°C, respectively. The final pressure of the steam in the tank is 30 bar. Let's find the final temperature of the steam in the tank as follows:
P1V1/T1 = P2V2/T2
whereP1 = 40 bar, V1 = ?, T1 = 400°CP2 = 30 bar, V2 = 0.5 m³, T2 = ?
Rearranging the above formula, we get:
T2 = P2V2T1/P1V1T2 = 30 × 0.5 × 400/(40 × V1)
T2 = 375/V1
The final temperature of steam in the tank is 375/V1°C.
Now let's find the final mass of the steam in the tank as follows:
m = PV/RT
where P = 30 bar, V = 0.5 m³, T = 375/V1R = 0.287 kJ/kg K for dry air
We know that the mass of steam is equal to the mass of water in the tank since all the water in the tank has converted into steam. The density of water at 30 bar is 30.56 kg/m³. Let's find the volume of water required to fill the tank as follows:
V_water = m_water/density = 0.5/30.56 = 0.0164 m³
where m_water is the mass of water required to fill the tank. Since all the water in the tank has converted into steam, the final mass of steam in the tank is equal to m_water. Let's find the final mass of steam in the tank as follows:
m = PV/RT = 30 × 10^5 × 0.5/(0.287 × 375/V1) = 1041.26 V1 kg
The final mass of steam in the tank is 1041.26 V1 kg.
Therefore, the final temperature of steam in the tank is 375/V1°C, and the final mass of steam in the tank is 1041.26 V1 kg.
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QUESTION 1 Which of the followings is true? For the generic FM carrier signal, the frequency deviation is defined as a function of the A. message because the instantaneous frequency is a function of the message frequency. B. message because it resembles the same principle of PM. C. message frequency. D. message. QUESTION 2 Which of the followings is true? The concept of "power efficiency may be useful for A. linear modulation. B. non-linear modulation. C. multiplexing. D. convoluted multiplexing. QUESTION 3 Which of the followings is true? A. Adding a pair of complex conjugates gives double the real part. B. Electrical components are typically not deployed under wireless systems as transmissions are always through the air channel. C. Adding a pair of complex conjugates gives the real part. D. Complex conjugating is a process of keeping the real part and changing the complex part. QUESTION 4 Which of the followings is true? A. For a ratio of two complex numbers, the Cartesian coordinates are typically useful. B. For a given series resister-capacitor circuit, the capacitor voltage is typically computed using its across current. C. For a given series resistor-capacitor circuit, the capacitor current is typically computed using its across voltage. D. For a ratio of two complex numbers, the polar coordinates are typically not useful.
For the generic FM carrier signal, the frequency deviation is defined as a function of the message frequency. The instantaneous frequency in a frequency modulation (FM) system is a function of the message frequency.
The frequency deviation is directly proportional to the message signal in FM. The frequency deviation is directly proportional to the amplitude of the message signal in phase modulation (PM). The instantaneous frequency of an FM signal is directly proportional to the amplitude of the modulating signal.
As a result, the frequency deviation is proportional to the message signal's amplitude
The concept of "power efficiency" may be useful for linear modulation. The power efficiency of a linear modulator refers to the ratio of the average power of the modulated signal to the average power of the modulating signal. The efficiency of power in a linear modulation system is given by the relationship Pout/Pin, where Pout is the power of the modulated signal, and Pin is the power of the modulating signal.
Adding a pair of complex conjugates gives the real part. Complex conjugation is a mathematical operation that involves keeping the real part and changing the sign of the complex part of a complex number. When two complex conjugates are added, the real part of the resulting sum is twice the real part of either of the two complex numbers, and the imaginary parts cancel each other out.
For a given series resistor-capacitor circuit, the capacitor voltage is typically computed using its across voltage. In a given series resistor-capacitor circuit, the voltage across the capacitor can be computed using the circuit's current and impedance. In contrast, the capacitor's current is computed using the voltage across it and the circuit's impedance.
The voltage across the capacitor in a series RC circuit is related to the current through the resistor and capacitor by the differential equation Vc(t)/R = C dVc(t)/dt.
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A quantity of gas at 2.8 bar and 195 °C occupies a volume of 0.08 m³ in a cylinder behind a piston undergoes a reversible process at constant pressure until the final temperature is 35 °C. Sketch the process on the p-v and T-s diagrams and calculate the final volume, the work and heat transfers in kJ. The specific heat capacity at constant pressure, Cp is 1.005 kJ/kg K and the specific gas constant, R is 0.290 kJ/kg K.
Initial pressure, P1 = 2.8 bar = 2.8 x 10⁵ PaInitial temperature, T1 = 195 °C = 195 + 273 = 468 KInitial volume, V1 = 0.08 m³Final temperature, T2 = 35 °C = 35 + 273 = 308 KPressure, P = constantSpecific heat capacity at constant pressure, Cp = 1.005 kJ/kg KSpecific gas constant, R = 0.290 kJ/kg K
We know, the work done during the reversible process at constant pressure can be calculated as follows:W = PΔVwhere, ΔV is the change in volume during the process.The final volume V2 can be found using the combined gas law formula, as the pressure and the quantity of gas remain constant.(P1V1)/T1 = (P2V2)/T2(P2V2) = (P1V1T2)/T1P2 = P1T2/T1V2 = (P1V1T2)/(P2T1)V2 = (2.8 x 10⁵ × 0.08 × 308) / (2.8 x 10⁵ × 468)V2 = 0.0387 m³The work done during the reversible process is:W = PΔV = 2.8 x 10⁵ (0.0387 - 0.08)W = -10188 J = -10.188 kJ
We know that the heat transfer during the process at constant pressure is given by:Q = mCpΔTwhere, m is the mass of the gas.Calculate the mass of the gas:PV = mRTm = (PV) / RTm = (2.8 x 10⁵ x 0.08) / (0.290 x 468)m = 0.00561 kgQ = 0.00561 × 1.005 × (308 - 468)Q = -0.788 kJ = -788 J the p-v and T-s diagrams.
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After building a SAP computer in Vivado, how can you manually execute instructions to the computer?
For example:
LDA $ 40H
MVA B
LDA $ 41H
ANA B (A and B)
HLT
After building a SAP computer in Vivado, the manually executing instructions to the computer can be done with the three steps mentioned as:
Step 1: Open Xilinx SDKOnce the block diagram is created and synthesized in Vivado, the SDK needs to be opened to generate the software code and to program the board.
Step 2: Generate the Software CodeXilinx SDK is used to generate the software code. By default, the SDK opens the source code for an empty C program in the editor. It is recommended that a basic program for the SAP-1 is written first. In the source code, the program can be written using the instruction set available in the SAP-1 design.
Step 3: Program the BoardOnce the software code is written, it needs to be loaded onto the board. Select "Program FPGA" from the "Xilinx" menu. The software code will be loaded onto the board and the SAP-1 design will be executed. The results will be displayed on the board's output devices.
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A huge redevelopment project on heritage museum was undertaken by a construction company Z. Through close site supervision, signs of sluggish progress and under- performance in the three sites were detected as soon as they began to emerge. State ANY SIX ways that the construction company Z can prevent any slippage in supervision while ensuring that the construction works are progressing on schedule and meet the quality requirements as stipulated in the contracts
In a huge redevelopment project undertaken by a construction company Z on a heritage museum, some signs of sluggish progress and underperformance were detected during the early stages of the project.
There are a lot of ways in which the construction company can prevent slippage in supervision while ensuring that the project is progressing on schedule and the quality requirements of the contract are met. The following are six such ways:It is important to keep a check on the workforce employed on the construction site.
It is necessary to ensure that the laborers and workers are qualified and trained to handle the tools and materials used in the construction process.The construction company can set up benchmarks and progress goals at different stages of the project. These goals can be set according to the project timeline. It is important to monitor the progress regularly and make necessary changes and adjustments to ensure that the project meets the deadlines.
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Question1: [Mark 6] (CLO2, CLO3) A 100 kVA, 3000 V, 50 Hz star connected synchronous generator has effective armature resistance of 0.2 ohm. The field current of 40 A produces short circuit current of 200 A and an open circuit emf of 1040 V (line value). Calculate the full load voltage regulation at 0.8 pf lagging and 0.8 pf leading. Draw phasor diagrams.
The synchronous impedance, Zs, can be calculated as (1040V/200A) = 5.2 ohms. The synchronous reactance, Xs, is √(Zs² - R²) = √(5.2² - 0.2²) = 5.199 ohms.
How to solve to find the 0.8 pf lagging:For 0.8 pf lagging:
The voltage regulation is Vr(lag) =
[(√(Ea² - V²)/V)x(0.8) + (Xs/V)x(0.6)]*100 = [(√(1040² - (3000/√3)²)/(3000/√3))x(0.8) + (5.199/(3000/√3))x(0.6)]*100
≈ 6.91%.
For 0.8 pf leading:
The voltage regulation is Vr(lead) =
[(√(Ea² - V²)/V)x(0.8) - (Xs/V)x(0.6)]*100
≈ -3.52%.
Phasor Diagrams: In both cases, Ea, V, I, and Zs are represented by phasors. For 0.8 pf lagging, the current phasor lags behind the voltage, and for 0.8 pf leading, it leads the voltage.
The voltage regulation is the difference in magnitude between Ea and V.
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A steel rotor disc of uniform thickness 50mm has an outer rim diameter 800mm and a central hole of diameter 150mm. There are 200 blades each of weight 2N at an effective radius of 420mm pitched evenly around the periphery. Determine the rotational speed at which yielding first occurs according to the maximum shear stress criterion. Yield stress= 750 MPa, v = 0.304, p = 7700 kg/m³.
The rotational speed at which yielding first occurs according to the maximum shear stress criterion is approximately 5.24 rad/s.
To determine the rotational speed at which yielding first occurs according to the maximum shear stress criterion, we can use the following steps:
1. Calculate the total weight of the blades:
Total weight = Number of blades × Weight per blade
= 200 × 2 N
= 400 N
2. Calculate the torque exerted by the blades:
Torque = Total weight × Effective radius
= 400 N × 0.42 m
= 168 Nm
3. Calculate the polar moment of inertia of the rotor disc:
Polar moment of inertia (J) = (π/32) × (D⁴ - d⁴)
= (π/32) × ((0.8 m)⁴ - (0.15 m)⁴)
= 0.02355 m⁴
4. Determine the maximum shear stress:
Maximum shear stress (τ_max) = Yield stress / (2 × Safety factor)
= 750 MPa / (2 × 1) (Assuming a safety factor of 1)
= 375 MPa
5. Use the maximum shear stress criterion equation to find the rotational speed:
τ_max = (T × r) / J
where T is the torque, r is the radius, and J is the polar moment of inertia.
Rearrange the equation to solve for rotational speed (N):
N = (τ_max × J) / T
= (375 × 10⁶ Pa) × (0.02355 m⁴) / (168 Nm)
Convert Pa to N/m² and simplify:
N = 5.24 rad/s
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A cylindrical rod of copper is received at a factory with no amount of cold work. This copper, originally 10 mm in diameter, is to be cold worked by drawing. The circular cross section will be maintained during deformation. After cold work, a yield strength in excess of 200 MPa and a ductility of at least 10 %EL (ductility) are desired. Furthermore, the final diameter must be 8 mm. Explain how this may be accomplished. Provide detailed procedures and calculations.
The percentage reduction in cross-sectional area due to cold work is: 35.88%. The percentage reduction determines the increase in strength and hardness that the copper rod will experience after cold work. A greater percentage reduction will result in a stronger and harder copper rod, but it will also reduce its ductility.
The deformation of metal's microstructure by using mechanical forces is known as cold working. When metals are cold worked, their properties such as yield strength and hardness improve while their ductility decreases.
The given cylindrical rod of copper is to be cold worked by drawing. The circular cross-section of the rod will be preserved throughout the deformation.
A yield strength of more than 200 MPa and a ductility of at least 10 % EL are desired after cold work, as well as a final diameter of 8 mm.The drawing method is used to cold work the rod. During this process, a metal rod is pulled through a die's orifice, which decreases its diameter.
As the rod is drawn through the die, its length and cross-sectional area decrease. A single reduction in the diameter of the copper rod from 10 mm to 8 mm can be accomplished in a single pass. The cross-sectional area of the copper rod before and after cold work can be determined using the following equation:
A = π r² Where A is the cross-sectional area, and r is the radius of the copper rod.
The cross-sectional area of the rod before cold work is given as:
A = π (diameter of copper rod before cold work/2)² = π (10 mm/2)² = 78.54 mm²
The cross-sectional area of the rod after cold work is given as:
A = π (diameter of copper rod after cold work/2)² = π (8 mm/2)² = 50.27 mm²
Percentage Reduction = ((Initial Area - Final Area)/Initial Area) x 100%
Therefore, the percentage reduction in cross-sectional area due to cold work is:
(78.54 - 50.27)/78.54 x 100 = 35.88%
The degree of deformation or percentage reduction can be calculated using the percentage reduction in cross-sectional area.
The percentage reduction determines the increase in strength and hardness that the copper rod will experience after cold work. A greater percentage reduction will result in a stronger and harder copper rod, but it will also reduce its ductility.
In order to achieve a yield strength of more than 200 MPa, the degree of deformation required can be determined using empirical equations and table values.
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1. The adiabatic turbine of a gas turbine engine operates at steady state. a) Working from first principles, using an appropriate property diagram and explaining each stage in the derivation, show that the power output is given by: W = mc₂n, T. (1-(1/r₂Y₁-1) P where m is the mass flowrate of a (perfect) gas through the turbine; c, and y are the specific heat at constant pressure and ratio of specific heats of that gas; ns, and are the turbine isentropic efficiency and expansion pressure ratio, respectively; Te is the turbine entry temperature. Gas velocity may be assumed to be low throughout. Assume universal gas constant R = 8.3145 J.K-1.mol-¹ [15 Marks] b) For a turbine entry temperature of 1500 K, an isentropic efficiency of 85 % and an expansion pressure ratio of 8, estimate the turbine exit temperature if the gas has a mean molar mass (M) of 28.6 kg/kmol and a mean specific heat at constant pressure of 1.23 kJ/kgK. [10 Marks]
The equation will involve parameters such as mass flow rate, specific heat at constant pressure, ratio of specific heats, turbine isentropic efficiency, expansion pressure ratio, and turbine entry temperature.
a) To derive the power output equation for the adiabatic turbine, we start by considering the first law of thermodynamics applied to a control volume around the turbine. By assuming steady state and adiabatic conditions, we can simplify the equation and express the work output (W) as a function of the given parameters. This derivation can be done using an appropriate property diagram, such as the T-s diagram.
Each stage in the derivation involves manipulating the equation, substituting appropriate values, and applying thermodynamic principles. The specific heat at constant pressure (cₚ) and the ratio of specific heats (γ) are properties of the gas, while the isentropic efficiency (ηs) and expansion pressure ratio (r₂) represent the performance characteristics of the turbine. The turbine entry temperature (Te) is the initial temperature of the gas entering the turbine.
b) Using the derived power output equation and the given values of turbine entry temperature (Te), isentropic efficiency (ηs), expansion pressure ratio (r₂), molar mass (M), and specific heat at constant pressure (cₚ), we can substitute these values to calculate the turbine exit temperature. The calculation involves manipulating the equation algebraically and using the given values to obtain the desired result.
By evaluating the turbine exit temperature, we can assess the performance of the turbine under the given conditions and understand the thermodynamic behavior of the gas as it passes through the turbine stages.
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NOTE: This is a multi-part question. Once an answer is submitted, you will be unable to return to this part. Five kilograms of air at 427°C and 600 kPa are contained in a piston-cylinder device. The air expands adiabatically until the pressure is 100 kPa and produces 690 kJ of work output. Assume air has constant specific heats evaluated at 300 K. Determine the entropy change of the air in kJ/kg.K. Use the table containing the ideal gas specific heats of various common gases. (You must provide an answer before moving on to the next part.) The entropy change of the air is kJ/kg.K.
Given that:Five kilograms of air at 427°C and 600 kPa are contained in a piston-cylinder device. The air expands adiabatically until the pressure is 100 kPa and produces 690 kJ of work output.
Assume air has constant specific heats evaluated at 300 K. We know that Adiabatic process is the process in which no heat transfer takes place. Here, ΔQ = 0.W = ΔUAdiabatic work is given by the equation.
This ΔU is change in internal energy. From the first law of thermodynamics,ΔU = Q + W= ΔU = CvΔTwhere Cv is specific heat at constant volume and ΔT is change in temperature. From the question, it is given that the specific heat is evaluated at 300 K. Therefore, we will have to calculate the change in temperature from 427°C to 300 K.
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To begin our first assignment, you will need a piece of graph paper. Start by drawing your initials in block letters in a space about six points by six points. Even thought we won't use the mills in our lab that will help restrict us to our size. 6"x 6" Next we will assume that all coordinates are in positive X and Y coordinates. plot the points that are the end of each line. Next we will begin plotting a tool path. We do want to make this toolpath as efficient as possible but the path is up to you. On your graph paper write the X and Y coordinates for each point that your program will use. Open Notepad and begin by creating a program number on the first line. The first line of our program will be N10. We skip at least numbers on between lines to allow for editing. if we need to add a line between N110 and N120 we can insert a line N115 and avoid having to edit the whole program. N10 will give the specifics of the program, G20 and 21 indicate standard or metric coordinates. G90 indicates an absolute coordinate system, G91 is incremental coordinates, meaning the coordinates are based off of an absolute zero or referenced off of the last point. GOO is a rapid positioning command, when we make contact with the work piece, feed rates must be set. XO,YO. N20 will indicate linear interpolation, meaning the tool piece will move from each point in a straight line. We will enter our first point and a feed rate. for this exercise, its F25, 25 inches per minute. Each line of code from this point will be points between movement. When it is input into our toolpath generator it should look like you have drawn your initials without picking you pencil up. We will add the Z axis a little later.
The first step of the assignment is to draw the initials of the students in block letters on a graph paper of size 6 x 6. Assume that all coordinates are in positive X and Y coordinates.
The end of each line is plotted with points. The tool path is plotted next. The path is required to be as efficient as possible, but the choice of path is left to the students. The X and Y coordinates for each point are written on the graph paper. Next, a Notepad is opened to create the program.
The first line of the program will be N10. In between the lines, a few numbers are skipped to allow for editing. The next line will give the specifics of the program. G20 and 21 indicate standard or metric coordinates, G90 indicates an absolute coordinate system, and G91 is incremental coordinates.
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Yaw system in the wind turbine are using for facing the wind
turbine towards the wind flow. Categorize the Yaw systems in terms
of their body parts and operation.
Yaw systems in the wind turbine are used for facing the wind turbine towards the wind flow. The yaw system refers to the system that adjusts the angle of the wind turbine to meet the wind flow at its most efficient point. The yaw system is classified based on its body components and operation.
Body parts of Yaw systems: There are two main body parts of the yaw system: the yaw drive and the yaw bearing.
1. Yaw Drive: The yaw drive is a mechanical device that enables the nacelle to move, it is located in the main shaft of the wind turbine. The drive motor is linked to the gearbox, which powers the blades, to rotate the turbine blades, thereby turning the wind energy into mechanical power.
2. Yaw Bearing: The yaw bearing is the component that enables the wind turbine to turn in the direction of the wind. It allows the rotor blades to rotate freely around the nacelle. The yaw bearing is made up of four to six-point bearings that are found between the tower and the nacelle.
Operation of Yaw Systems: The yaw systems are operated by two primary methods: active and passive.
1. Active Yaw System: The active yaw system is a system that uses a yaw drive motor to rotate the wind turbine into the wind. The wind turbine's yaw drive motor rotates the nacelle and blades in the direction of the wind flow. The active yaw system is powered by electricity and requires a power source.
2. Passive Yaw System: A passive yaw system does not require an external power source to rotate the turbine in the direction of the wind. Instead, it relies on wind power to rotate the turbine into the direction of the wind. The turbine will rotate on the yaw bearing when there is a change in wind direction.
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Q10. Select and sketch an appropriate symbol listed in Figure Q10 for ench geometric chracteristic listed below. OV Example: Perpendicularity a) Straightness b) Flatness c) Roundness d) Parallelism e) Symmetry f) Concentricity 수 오우 ㅎㅎ V Figure Q10 10 (6 Marks)
Figure Q10 lists various symbols used in the geometric tolerance in engineering. The symbols used in engineering indicate the geometrical shape of the object. It is a symbolic representation of an object's shape that is uniform.
Geometric tolerances are essential for ensuring that manufactured components are precise and will work together smoothly. Perpendicularity is shown by a square in Figure Q10. Straightness is represented by a line in Figure Q10.Flatness is indicated by two parallel lines in Figure Q10. Roundness is shown by a circle in Figure Q10. Parallelism is represented by two parallel lines with arrows pointing out in opposite directions in Figure Q10.Symmetry is indicated by a horizontal line that runs through the centre of the shape in Figure Q10. Concentricity is shown by two circles in Figure Q10, with one inside the other. In conclusion, geometric tolerances are essential in engineering and manufacturing. They guarantee that the manufactured components are precise and will function correctly.
The symbols used in engineering represent the geometrical shape of the object and are used to describe it. These symbols make it easier for manufacturers and engineers to understand and communicate the requirements of an object's shape.
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5. Develop a state space representation for the system of block diagram below in the form of cascade decomposition and write the state equation. Then find the steady- state error for a unit-ramp input. Ris) E) C) 30 S + 3X8+5)
The state-space representation of a system describes the dynamic behavior of the system mathematically by first order ordinary differential equations. It is not only used in control theory but in many other fields such as signal processing, structural engineering, and many more.
Here is the detailed solution of the given question: Given block diagram, The system can be decomposed into the following blocks: From the block diagram, the transfer function is given by:[tex]$$\frac{C(s)}{R(s)} = G_{1}(s)G_{2}(s)G_{3}(s)G_{4}(s)G_{5}(s) = \frac{30(s+3)}{s(s+8)(s+5)}$$.[/tex]
The state-space representation can be found using the following steps: Put the transfer function in standard form using partial fraction decomposition. [tex]$$\frac{C(s)}{R(s)} = \frac{2}{s} + \frac{5}{s+5} - \frac{7}{s+8} + \frac{10}{s+8} + \frac{20}{s+5} - \frac{100}{s}$$.[/tex]
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A triangular duct, 7 cm on a side, with 4 kg/s of water at 42°C, has a constant surface temperature of 90°C. The water has the following properties: density: 991 kg/m³, kinematic viscosity: 6.37E-7 m²/s, k=0.634 W/m K, Pr = 4.16. The surface roughness of the duct is 0.2 mm. What is the heat transfer coefficient of the water? h= Number W/m²K
The heat transfer coefficient of the water is 14.83 W/m²K.
The heat transfer coefficient of the water is required. The given parameters include the following:
Triangular duct, side = 7 cm, Mass flow rate (m) = 4 kg/s, T1 = 42°C, T2 = 90°C, Density (ρ) = 991 kg/m³, Kinematic viscosity (ν) = 6.37E-7 m²/s, Thermal conductivity (k) = 0.634 W/mK, Prandtl number (Pr) = 4.16, Surface roughness of duct = 0.2 mm.
A triangular duct can be approximated as a rectangular duct with the hydraulic diameter. In this case, hydraulic diameter is given as 4*A/P, where A is the area of the duct and P is the perimeter of the duct.
Therefore, hydraulic diameter of triangular duct is given as:
D_h = 4*A/P = 4*(√3/4*(0.07)^2)/(3*0.07) = 0.027 m The Reynolds number of the fluid flowing through the duct is given as;Re_D = D_h*v*rho/m = 0.027*4/(6.37*10^-7*991) = 11418
Therefore, the flow is turbulent.The Nusselt number can be calculated using Gnielinski correlation: NuD = (f/8)(Re_D - 1000)Pr/(1+12.7((f/8)^0.5)((Pr^(2/3)-1)))(1+(D_h/4.44)((Re_DPrD_h/f)^0.5))
The equation is complex and requires the calculation of friction factor using the Colebrook-White equation.
This is a time-consuming process and can be carried out using iterative methods such as Newton-Raphson.
The heat transfer coefficient is given as;h = k*Nu_D/D_h = 0.634*NuD/0.027 = 14.83 W/m²K.
Reynolds Number, Re_D = 11418 Hydraulic diameter, D_h = 0.027 m Nusselt Number, Nu_D = 140.14 Heat transfer coefficient, h = 14.83 W/m²K.
Therefore, the heat transfer coefficient of the water is 14.83 W/m²K.
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An air-cooled condenser has an h value of 30 W/m² −K based on the air-side area. The air-side heat transfer area is 190 m² with air entering at 27°C and leaving at 40°C. If the condensing temperature is constant at 49°C, what is the air mass flow rate in kg/s ? Let Cₚ₍ₐᵢᵣ₎ = 1.006 kJ/kg−K.(20pts) Draw and label the temperature-flow diagram. Round off your answer to three (3) decimal places.
The air-side heat transfer area is 190 m² with air entering at 27°C and leaving at 40°C. The condensing temperature is constant at 49°C. We need to find the air mass flow rate in kg/s. Also,[tex]Cₚ₍ₐᵢᵣ₎ = 1.006 kJ/kg−K.[/tex]The heat flow from the condenser is given by[tex]Q = m . Cp .[/tex]
Heat flow from the condenser is given by [tex]Q = m . Cp . ∆T[/tex]
Now, heat is transferred from the refrigerant to air.The formula for heat transfer is given by,
[tex]Q = U . A . ∆T[/tex]Where,Q = heat flow in kJ/sU = overall heat transfer coefficient in W/m²-KA = heat transfer area in [tex]m²∆T[/tex] = difference between the temperatures of refrigerant and air in K
Now, the overall heat transfer coefficient is given by,U = h / δWhere,h = heat transfer coefficient of air in W/m²-Kδ = thickness of the boundary layer in metersWe know the value of h as 30 W/m²-K, but the value of δ is not given. Therefore, we need to assume a value of δ as 0.0005 m.Then, the overall heat transfer coefficient is given by
[tex]U = 30 / 0.0005 = 60000 W/m²-K[/tex]
Now, heat flow from the refrigerant is given by
[tex]Q = U . A . ∆TQ = 60000 x 190 x 9Q = 102600000 W = 102600 kWAlso,Q = m . Cp . ∆T102600 = m . 1.006 . 9m = 11402.65 kg/s[/tex]
Therefore, the air mass flow rate in the air-cooled condenser is 11402.65 kg/s.
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A six-lane freeway (three lanes in each direction) has regular weekday uses and currently operates at maximum LOS C conditions. The lanes are 3.3 m wide, the right-side shoulder is 1.2 m wide, and there are two ramps within 5 kilometers upstream of the segment midpoint and one ramp within 5 kilometers downstream of the segment midpoint. The highway is on rolling terrain with 10% large trucks and buses (no recreational vehicles), and the peak-hour factor is 0.90. Determine the hourly volume for these conditions.
Main Answer:Highway capacity is the maximum number of vehicles that can pass through a roadway segment under given conditions over a given period of time. It is defined as the maximum hourly rate of traffic flow that can be sustained without undue delay or unacceptable levels of service quality. LOS C is an acceptable level of service during peak hours. The road is a six-lane freeway with three lanes in each direction. The lanes are 3.3 m wide, and the right-side shoulder is 1.2 m wide. The highway is on rolling terrain with a peak-hour factor of 0.90 and 10% large trucks and buses (no recreational vehicles).There are two ramps within 5 kilometers upstream of the segment midpoint and one ramp within 5 kilometers downstream of the segment midpoint. Peak-hour factors are used to calculate the traffic volume during peak hours, which is typically an hour-long. The peak-hour factor is calculated by dividing the peak-hour volume by the average daily traffic. According to HCM, peak-hour factors range from 0.5 to 0.9 for most urban and suburban roadways. Therefore, the peak-hour factor of 0.90 is appropriate in this situation.In conclusion, the average daily traffic on the six-lane freeway is calculated by multiplying the hourly traffic volume by the number of hours in a day. Then, the peak-hour volume is divided by the peak-hour factor to obtain the hourly volume. The resulting hourly volume is 2,297 vehicles per hour (vph). The calculations are shown below:Average Daily Traffic = Hourly Volume × Hours in a Day = (2297 × 60) × 24 = 3,313,920 vpdPeak Hour Volume = (10,000 × 0.9) = 9000 vphHourly Volume = Peak Hour Volume / Peak Hour Factor = 9000 / 0.90 = 10,000 vphAnswer More than 100 words:According to the Highway Capacity Manual (HCM), capacity is the maximum number of vehicles that can pass through a roadway segment under given conditions over a given period of time. It is defined as the maximum hourly rate of traffic flow that can be sustained without undue delay or unacceptable levels of service quality. Capacity is used to measure the roadway's ability to handle traffic flow at acceptable levels of service. The LOS is used to rate traffic flow conditions. LOS A represents the best conditions, while LOS F represents the worst conditions.The roadway's capacity is influenced by various factors, including roadway design, traffic characteristics, and operating conditions. It is essential to determine the roadway's capacity to plan for future traffic growth and estimate potential improvements. Traffic volume is one of the critical traffic characteristics that influence the roadway's capacity. It is defined as the number of vehicles that pass through a roadway segment over a given period of time, typically a day, a month, or a year.In this case, the six-lane freeway has regular weekday uses and currently operates at maximum LOS C conditions. The lanes are 3.3 m wide, the right-side shoulder is 1.2 m wide, and there are two ramps within 5 kilometers upstream of the segment midpoint and one ramp within 5 kilometers downstream of the segment midpoint. The highway is on rolling terrain with 10% large trucks and buses (no recreational vehicles), and the peak-hour factor is 0.90. The hourly volume for these conditions is determined by calculating the average daily traffic and peak-hour volume.According to HCM, peak-hour factors range from 0.5 to 0.9 for most urban and suburban roadways. Therefore, the peak-hour factor of 0.90 is appropriate in this situation. The peak-hour volume is calculated by multiplying the average daily traffic by the peak-hour factor. Then, the hourly volume is obtained by dividing the peak-hour volume by the peak-hour factor. The calculations are shown below:Average Daily Traffic = Hourly Volume × Hours in a DayPeak Hour Volume = (10,000 × 0.9) = 9000 vphHourly Volume = Peak Hour Volume / Peak Hour Factor = 9000 / 0.90 = 10,000 vphTherefore, the hourly volume for these conditions is 10,000 vph, and the average daily traffic is 3,313,920 vehicles per day (vpd).
(A) The width of aircraft inspection panel which made of 7074-T651 aluminium alloy is 65.4 mm. Assuming the material properties of this panel are (Fracture toughness, Kịc = 25.8 MN m-3/2 and Yield stress, Gy = 505 MPa. During an inspection, an edge through-crack, a, of length 6.4 mm is found. If a cyclic stress of 90 MPa is applied on this plate. Determine the number of cycles to failure (N/) using Paris' Law. Taking A = 1.5x10-12 m/(MNm-3/2)" per cycle and m= 2.8, (Take Y = 1.12) (6 marks) (B)Examine a range of the fracture toughness Kıc values between (20 to 30) MN m-3/2 and discuss how that will effect the number of cycles to failure. (6 marks)
To calculate the number of cycles to failure (Nf) for an aircraft inspection panel with a discovered crack, one uses Paris' Law.
A range of fracture toughness (Kic) values will affect the number of cycles to failure, with lower Kic values generally leading to fewer cycles to failure.
Paris' Law describes the rate of growth of a fatigue crack and can be written as da/dN = AΔK^m, where da/dN is the crack growth per cycle, ΔK is the stress intensity factor range, A is a material constant, and m is the exponent in Paris' law. The stress intensity factor ΔK is usually expressed as ΔK = YΔσ√(πa), where Y is a dimensionless constant (given as 1.12), Δσ is the stress range, and a is the crack length. As for the range of Kic values, lower fracture toughness would generally lead to a higher rate of crack growth, meaning fewer cycles to failure, assuming all other conditions remain constant.
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QUESTION 6 12 points Save Answer A compressor used to deliver 2. 10 kg/min of high pressure air requires 8.204 kW to operate. At the compressor inlet, the air is at 100 kPa and 26.85°C. The air exits the compressor at 607 kPa and 256.85°C. Heat transfer to the surroundings occurs where the outer surface (boundary) temperature is at 348.5°C. Determine the rate of entropy production (kW/K) within the compressor if the air is modeled as an ideal gas with variable specific heats. Note: Give your answer to six decimal places.
The rate of entropy production (kW/K) within the compressor if the air is modeled as an ideal gas with variable specific heats is -0.570737 kW/K.
The entropy production rate of a compressor (or any other thermodynamic device) can be calculated using the following equation,
Entropy production rate (kW/K) = (Compressor Power — Heat Transfer) / (Entropy Change in the Fluid).
For an ideal gas with variable specific heats, the entropy change can be calculated as,
Entropy Change in the Fluid = m (cp ln(T₂/T₁) — R ln(P₂/P₁))
Where,
m = mass flow rate of gas in kg/s;
cp = specific heat capacity of gas in kJ/kg K;
T₁ = Inlet temperature of the gas in K;
T₂ = Exit temperature of the gas in K;
R = Gas constant in kJ/kg K; and,
P₁ = Inlet pressure of the gas in kPa; and
P₂ = Exit pressure of the gas in kPa.
Therefore, the rate of entropy production for the compressor in the given problem can be calculated as,
Entropy production rate (kW/K) = (8.204 kW - Heat Transfer) / [10 kg/min (cp ln(256.85/26.85) - R ln(607/100))]
Where,
cp = 1.013 kJ/kg K,
R = 0.287 kJ/kg K.
Therefore,
Entropy production rate (kW/K) = (8.204 kW - Heat Transfer) / 469.79
Heat Transfer = m (cp (T₂ - T₁)) where,
m = 10 kg/min and
T2 = 348.5°C = 621.65 K.
Heat Transfer = 10 kg/min (1.013 kJ/kg K) (621.65 K - 256.85 K).
Heat Transfer = 285.354 kW
Entropy production rate (kW/K) = (8.204 kW - 285.354 kW) / 469.79 = -0.570737 kW/K (six decimal places).
Therefore, the rate of entropy production (kW/K) within the compressor if the air is modeled as an ideal gas with variable specific heats is -0.570737 kW/K.
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Moist air initially at 101 kPa, 40°C db, 20% relative humidity undergoes a sensible cooling process until the dry bulb temperature is 20°C. For a moist air mass flow rate of 2.2 kg/s, what is the rate of heat removal for this process? Express your answer in kW. In your written solution, draw the process in the psychrometric chart, and show the initial and final state and the values obtained from the chart.
Therefore, the rate of heat removal for this process is 55.52 kW.
Given Data: Mass Flow Rate of Moist Air, m = 2.2 kg/s
Initial Conditions of Moist Air:
Pressure, P1 = 101 kPa
Dry Bulb Temperature, Tdb1 = 40°C
Relative Humidity, ϕ1 = 20%
Final Conditions of Moist Air:
Dry Bulb Temperature, Tdb2 = 20°C
The process can be shown on the psychrometric chart, as shown below:
The required process can be shown on the psychrometric chart as follows:
State 1 represents initial conditions of moist air.
State 2 represents final conditions of moist air.
The dry air process line connects these two states.
Latent heat is not added or removed during this process, so the line connecting these two states is a straight line.
The required rate of heat removal for the process can be calculated as follows:
Initial Specific Enthalpy of Moist Air:h1 = 76.84 kJ/kg
Final Specific Enthalpy of Moist Air:h2 = 51.62 kJ/kg
Rate of Heat Removal, Q = m × (h1 - h2)Q = 2.2 × (76.84 - 51.62)Q = 55.52 kW
Therefore, the rate of heat removal for this process is 55.52 kW.
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Two synchronous generators need to be connected in parallel to supply a load of 10 MW. The first generator supplies three times the amount of the second generator. If the load is supplied at 50 Hz and both generators have a power drooping slope of 1.25 MW per Hz. a. (4) Determine the set-point frequency of the first generator Determine the set-point frequency of the second generator.
In this problem, the load of 10 MW is to be supplied at a of 50 Hz. Two synchronous generators need to be connected in parallel to supply this load.
Let's assume the rating of the second generator as G2. Then the rating of the first generator, G1 = 3G2.From the problem statement, we know that the power drooping slope is 1.25 MW/Hz. The frequency decreases by 1 Hz when the load increases by 1.25 MW. At the set-point frequency, the generators will share the load equally.
Let's assume that the frequency of G1 is f1 and the frequency of G2 is f2. Therefore, the set-point frequency of the first generator (G1) is 53.33 Hz and that of the second generator (G2) is 51.11 Hz.
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Refrigerant 134a enters a horizontal pipe operating at steady state at 40°C, 3.2 bar and a velocity of 40 m/s. At ° the exit, the temperature is 50°C and the pressure is 240 kPa. The pipe diameter is 0.04 m. Determine (a) the mass flow rate of the refrigerant, in kg/s, (b) the velocity at the exit, in m/s, and (c) the rate of heat transfer between the pipe and its surroundings, in kW. Also find the entropy generation rate (kW/K) if Tb = 30C
Refrigerant 134a enters a horizontal pipe operating at steady state at 40°C, 3.2 bar, and a velocity of 40 m/s. The answers are following:The mass flow rate is 5.099 kg/s. Velocity at the exit is 0.071 m/s. The rate of heat transfer is 51.35 kW. Entropy generation rate is 0.166kW/K.
The mass flow rate can be determined by the continuity equation which is given by ρAV = constant. ρ1 = P1 / RT1ρ1 = 3.2 × 105 / (0.001005 × 313) = 101.4 kg/m3A1 = πD12 / 4 = π × 0.042 / 4 = 1.256 × 10-3 m2V1 = 40 m/s. At the exit of the pipe,ρ2 = P2 / RT2ρ2 = 240 × 103 / (0.001005 × 323) = 748.5 kg/m3A2 = πD22 / 4 = π × 0.042 / 4 = 1.256 × 10-3 m2V2 = ?, first determine the velocity at the exit. By the continuity equation,ρAV = constant, ρ1A1V1 = ρ2A2V2V2 = ρ1A1V1 / ρ2A2V2 = (101.4 × 1.256 × 10-3 × 40) / (748.5 × 1.256 × 10-3) = 0.071 m/s. Therefore, the velocity at the exit is 0.071 m/s. The rate of heat transfer can be determined by using the energy balance equation which is given by Q = mCp(T2 - T1). Cp for refrigerant 134a at an average temperature of 45°C is 1.005 kJ/kg K. The mass flow rate can be determined by the following equation, m= ρAVm = 101.4 × 1.256 × 10-3 × 40 = 5.099 kg/s. Therefore, the rate of heat transfer is Q = mCp(T2 - T1)Q = 5.099 × 1.005 × (50 - 40) = 51.35 kW. The entropy generation rate (kW/K) if Tb = 30C is given by, δs_gen = Q/T. δs_gen = 51.35 / (273 + 30) = 0.166 kW/K.
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Five miners must be lifted from a mineshaft (vertical hole) 100m deep using an elevator. The work required to do this is found to be 341.2kJ. If the gravitational acceleration is 9.75m/s^2, determine the average mass per person in kg.
a. 65kg
b. 70kg
c. 75kg
d. 80kg
(b).Given information: Depth of mine shaft = 100 m Work done = 341.2 kJ Gravitational acceleration = 9.75 m/s²Number of persons to be lifted = 5Formula used: Work done = force × distanceIn this question, we are supposed to determine the average mass per person in kg.
The formula to calculate the average mass per person is:Average mass per person = Total mass / Number of personsLet's begin with the solution:From the given information,The work done to lift 5 persons from the mine shaft is 341.2 kJThe gravitational acceleration is 9.75 m/s²The distance covered to lift the persons is 100 mTherefore,Work done = force × distance
Using this formula, we getForce = Work done / distance= 341.2 kJ / 100 m= 3412 J / 1 m= 3412 NNow, force = mass × gravitational accelerationTherefore, mass = force / gravitational acceleration= 3412 N / 9.75 m/s²= 350.56 kgAverage mass per person = Total mass / Number of persons= 350.56 kg / 5= 70.11 kg ≈ 70 kgTherefore, the average mass per person in kg is 70 kg. Hence, the correct option is (b).
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Which of the following is NOT part of the scope of CAD/CAM a. manufacturing control b. business functions c. design d. manufacturing planning
Computer-aided design/computer-aided manufacturing (CAD/CAM) refers to the use of computer systems to create, modify, evaluate, and produce various goods and products. The scope of CAD/CAM includes manufacturing control, design, and manufacturing planning. It is not a part of the scope of business functions.
Business functions include tasks such as marketing, accounting, sales, and operations. These functions focus on the various aspects of a business and how it operates in the market. They are essential to the success of any organization.
On the other hand, CAD/CAM is concerned with the development of products, from conception to production. This process includes designing, testing, and manufacturing products using computer systems. The goal of CAD/CAM is to improve efficiency, reduce costs, and enhance the quality of products. In summary, the answer to the question is b. business functions. CAD/CAM is not a part of the scope of business functions.
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Example 20kw, 250V, 1000rpm shunt de motor how armature and field. resistances of 0,22 and 2402. When the HOA rated current at motor takes raded conditions. a) The rated input power, rated output power, and efficiency. Generated vo Hagl <) Induced torque. d) Total resistance arent to current. of 1,2 times Ox. 1200rpm. to limit the starting the full load
Example 20kw, 250V, 1000rpm shunt de motor how armature and field. resistances of 0,22 and 2402. When the HOA rated current at motor takes raded conditions. a) The rated input power, rated output power, and efficiency. Generated vo Hagl <) Induced torque. d) Total resistance arent to current. of 1,2 times Ox. 1200rpm. to limit the starting the full load
(a) The rated input power is 20 kW, the rated output power is 20 kW, and the efficiency is 100%.
(b) The generated voltage is 250 V.
(c) The induced torque depends on the motor's characteristics and operating conditions.
(d) The total resistance is not specified in the given information.
(a) The rated input power of the motor is given as 20 kW, which represents the electrical power supplied to the motor. Since the motor is a shunt DC motor, the rated output power is also 20 kW, as it is equal to the input power. Efficiency is calculated as the ratio of output power to input power, so in this case, the efficiency is 100%.
(b) The generated voltage of the motor is given as 250 V. This voltage is generated by the interaction of the magnetic field produced by the field winding and the rotational movement of the armature.
(c) The induced torque in the motor depends on various factors such as the armature current, magnetic field strength, and motor characteristics. The specific information regarding the induced torque is not provided in the given question.
(d) The total resistance mentioned in the question is not specified. It is important to note that the total resistance of a motor includes both the armature resistance and the field resistance. Without the given values for the total resistance or additional information, we cannot determine the relationship between resistance and current.
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A power station supplies 60 kW to a load over 2,500 ft of 000 2-conductor copper feeder the resistance of which is 0.078 ohm per 1,000 ft. The bud-bar voltage is maintained constant at 600 volts. Determine the maximum power which can be transmitted.
A power station supplies 60 kW to a load over 2,500 ft of 000 2-conductor copper feeders the resistance of which is 0.078 ohm per 1,000 ft. The bud-bar voltage is maintained constant at 600 volts. 5.85 MW, the maximum power which can be transmitted.
[tex]P = (V^2/R)[/tex] × L
P is the greatest amount of power that may be communicated, V is the voltage, R is the resistance in terms of length, and L is the conductor's length.
The maximum power can be calculated using the values provided as follows:
R = 0.078 ohm/1,000 ft × 2,500 ft = 0.195 ohm
L = 2,500 ft
V = 600 volts
[tex]P = (V^2/R)[/tex] × L = [tex]L = (600^2[/tex]/0.195) × 2,500
= 5,853,658.54 watts
= 5.85 MW.
Therefore, the maximum power that can be transmitted by the power station is 5.85 MW.
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Question 3: Design Problem (2 Points) 1. In which of the application below would you allow for overshoot? State why (2) and why not. (tick the ones that doesn't allow overshoot) • Water Level . Elevator . Cruise Control • Air Conditioning Water flow rate into a vessel
Among the given applications (Water Level, Elevator, Cruise Control, Air Conditioning, and Water flow rate into a vessel), the application that allows for overshoot is Cruise Control.
Cruise Control is an application where allowing overshoot can be acceptable. Overshoot refers to a temporary increase in speed beyond the desired setpoint. In Cruise Control, overshoot can be allowed to provide a temporary acceleration to reach the desired speed quickly. Once the desired speed is achieved, the control system can then adjust to maintain the speed within the desired range. On the other hand, the other applications listed do not typically allow overshoot. In Water Level control, overshoot can cause flooding or damage to the system. Elevator control needs precise positioning without overshoot to ensure passenger safety and comfort.
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Each cell of an automobile 12 volt battery can produce about volts. A) 4.2 B) 4 C) 1.2 D) 2.1
The correct answer is D) 2.1 volts. Each cell of an automobile 12-volt battery typically produces around 2.1 volts.
Automobile batteries are composed of six individual cells, each generating approximately 2.1 volts. When these cells are connected in series, their voltages add up to form the total voltage of the battery. Therefore, a fully charged 12-volt automobile battery consists of six cells, each producing 2.1 volts, resulting in a total voltage of 12.6 volts (2.1 volts x 6 cells).
This voltage level is suitable for powering various electrical components and starting the engine of a typical automobile. It is important to note that the actual voltage may vary slightly depending on factors such as the battery's state of charge and temperature.
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Connect a resistor of value 20 Ω
between terminals a-b and calculate i10
a) Using mesh method
b) Using node method
a) Using mesh method:
Mesh analysis is one of the circuit analysis methods used in electrical engineering to simplify complicated networks of loops when using the Kirchhoff's circuit laws
b) Using node method
Node analysis is another method of circuit analysis. It is used to determine the voltage and current of a circuit.
a) Using mesh method: Mesh analysis is one of the circuit analysis methods used in electrical engineering to simplify complicated networks of loops when using the Kirchhoff's circuit laws. The mesh method uses meshes as the basic building block to represent the circuit. The meshes are the closed loops that do not include other closed loops in them, they are referred to as simple closed loops.
Connect a resistor of value 20 Ω between terminals a-b and calculate i10
a) Using mesh method
1. Assign a current in every loop in the circuit, i1, i2 and i3 as shown.
2. Solve the equation for each mesh using Ohm’s law and KVL.
The equation of each loop is shown below.
Mesh 1:
6i1 + 20(i1-i2) - 5(i1-i3) = 0
Mesh 2:
5(i2-i1) - 30i2 + 10i3 = 0
Mesh 3:
-10(i3-i1) + 40(i3-i2) + 20i3 = 103.
Solve the equation simultaneously to obtain the current
i2i2 = 0.488A
4. The current flowing through the resistor of value 20 Ω is the same as the current flowing through mesh 1
i = i1 - i2
= 0.562A
b) Using node method
Node analysis is another method of circuit analysis. It is used to determine the voltage and current of a circuit.
Node voltage is the voltage of the node with respect to a reference node. Node voltage is determined using Kirchhoff's Current Law (KCL). The voltage between two nodes is given by the difference between their node voltages.
Connect a resistor of value 20 Ω between terminals a-b and calculate i10
b) Using node method
1. Apply KCL at node A, and assuming the voltage at node A is zero, the equation is as follows:
i10 = (VA - 0) /20Ω + (VA - VB)/5Ω
2. Apply KCL at node B, the equation is as follows:
(VB - VA)/5Ω + (VB - 10V)/30Ω + (VB - 0)/40Ω = 0
3. Substitute VA from Equation 1 into Equation 2, and solve for VB:
VB = 4.033V
4. Substitute VB into Equation 1 to solve for i10:
i10 = 0.202A.
Therefore, the current flowing through the resistor is 0.202A or 202mA.
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