Air enters the compressor of an air-standard Brayton cycle with a volumetric flow rate of 60 m3/s at 0.8 bar, 280 K. The compressor pressure ratio is 20, and the maximum cycle temperature is 2100 K. For the compressor, the isentropic efficiency is 92% and for the turbine the isentropic efficiency is 95%. Determine


(a) the net power developed, in MW

(b) the rate of heat addition in the combustor, in MW

(c) the thermal efficiency of the cycle

Answer: Metal has a oxide layer when in air. Before an experiment cleaning it with sand paper will remove the leyer of oxide and ensure truer results.  Cleaning with tissue paper will not result in removing the layer of oxide.

Shows how active H2 can be.

Explanation:

Following are the responses to the given question:

For question 1:

For question 2:

For question 3:

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Answer

The answer and procedures of the exercise are attached in the following archives.

Step-by-step explanation:

You will find the procedures, formulas or necessary explanations in the archive attached below. If you have any question ask and I will aclare your doubts kindly.  

The Essay class design involves computing a student's essay score from Grammar, Spelling, Correct Length, and Content categories, and is an extension of the GradedActivity class.

The student's question involves designing an Essay class that is derived from the GradedActivity class. The Essay class needs to evaluate a student's essay score based on specific criteria: Grammar (30 points), Spelling (20 points), Correct Length (20 points), and Content (30 points).

To demonstrate the class, one can create a simple program that initializes an instance of the Essay class, assigns scores to each of these aspects, calculates the total score, and then determines the grade based on these scores. In implementing this class, it would be necessary to have methods within the class that allow for setting each of the component scores separately, a method to calculate the final score, and one to output the resulting grade.

Answer:C  0.12 V

Explanation:

Given

Concentration of [tex]Fe^{2+} M_1=0.40 M[/tex]

Concentration of [tex]Ni^{2+} M_2=0.002 M[/tex]

Standard Potential for Ni and Fe are [tex]V_2=-0.25 V[/tex]  and [tex]V_1=-0.44 V[/tex]

[tex]\Delta V=V_2-V_1-\frac{0.0592}{2}\log (\frac{M_1}{M_2})[/tex]

[tex]\Delta V=-0.25-(-0.44)-\frac{0.0592}{2}\log (\frac{0.4}{0.002})[/tex]

[tex]\Delta V=0.12\ V[/tex]

Answer

The answer and procedures of the exercise are attached in the following archives.

Step-by-step explanation:

You will find the procedures, formulas or necessary explanations in the archive attached below. If you have any question ask and I will aclare your doubts kindly.  

a) The average power density in the interface area defined by the weld nugget is [tex]\( 9025 \, \text{kW} \).[/tex]

b) The percentage of energy generated that went into the formation of the weld nugget is [tex]\( 17.51\% \).[/tex]

To solve the problem, we need to go through several steps, including calculating the electrical power, the energy required to form the weld nugget, and the ratio of these energies.

Given Data:

- Current,  I = 9500 A

- Time,  t = 0.17 sec

- Resistance,  R = 100  micro-ohms [tex]\( = 100 \times 10^{-6} \)[/tex] ohms

- Weld nugget diameter,  d = 0.190  in

- Weld nugget thickness, [tex]\( t_{nugget} = 0.060 \)[/tex] in

- Sheet thickness, [tex]\( t_{sheet} = 0.040 \)[/tex] in (this is given but not needed for the calculation)

- Unit melting energy of steel, [tex]\( u_m = 150 \) Btu/in\(^3\)[/tex]

Step 1: Calculate the average power density in the interface area

Electrical Power Generated:

[tex]\[ P = I^2 R \][/tex]

[tex]\[ P = (9500)^2 \times (100 \times 10^{-6}) \][/tex]

[tex]\[ P = 9500^2 \times 0.0001 \][/tex]

[tex]\[ P = 9025 \, \text{kW} \][/tex]

Energy Supplied:

[tex]\[ E_{source} = P \times t \][/tex]

[tex]\[ E_{source} = 9025 \times 0.17 \][/tex]

[tex]\[ E_{source} = 1534.25 \, \text{J} \][/tex]

Step 2: Calculate the energy required to form the weld nugget

Volume of the Weld Nugget:

[tex]\[ V_{nugget} = \pi \left(\frac{d}{2}\right)^2 t_{nugget} \][/tex]

[tex]\[ V_{nugget} = \pi \left(\frac{0.190}{2}\right)^2 \times 0.060 \][/tex]

[tex]\[ V_{nugget} = \pi \times 0.095^2 \times 0.060 \][/tex]

[tex]\[ V_{nugget} = \pi \times 0.009025 \times 0.060 \][/tex]

[tex]\[ V_{nugget} = 0.001698 \, \text{in}^3 \][/tex]

Energy Required to Form the Weld Nugget:

[tex]\[ E_{weld} = u_m \times V_{nugget} \][/tex]

[tex]\[ E_{weld} = 150 \, \text{Btu/in}^3 \times 0.001698 \, \text{in}^3 \][/tex]

[tex]\[ E_{weld} = 0.2547 \, \text{Btu} \][/tex]

Converting Btu to Joules (1 Btu = 1055.06 J):

[tex]\[ E_{weld} = 0.2547 \times 1055.06 \][/tex]

[tex]\[ E_{weld} = 268.66 \, \text{J} \][/tex]

Step 3: Find the percentage of energy that went into the formation of the weld nugget

Ratio [tex]\( \frac{E_{weld}}{E_{source}} \):[/tex]

[tex]\[ \text{Ratio} = \frac{E_{weld}}{E_{source}} \][/tex]

[tex]\[ \text{Ratio} = \frac{268.66}{1534.25} \][/tex]

[tex]\[ \text{Ratio} = 0.1751 \][/tex]

So, the percentage of energy that went into the formation of the weld nugget is:

[tex]\[ \text{Percentage} = 0.1751 \times 100 \][/tex]

[tex]\[ \text{Percentage} = 17.51\% \][/tex]

Answer:orientation of piles

Explanation:

The stiffness and strength of a properly constructed composite buildup depend upon the orientation of piles to the load direction.

Structural composite materials are designed and manufactured to withstand certain specific stress loads. The ability to withstand these stress loads depends, to a large extent, on how the fibers are arranged. The fiber orientation of the parts must be the same as that of the original form.          

Answers:

31.7 inches

Explanation:

Given:

Diameter = 3ft

Let D = Diameter

So, D = 3ft. (Convert to inches)

D = 3 * 12in = 36 inches

Coss-sectional area of the steel = 0.2in²

Gauge Pressure (P) = 4psi

Stress in Steel (σ)= 11.4ksi

Force in steel = ½ (Pressure * Projected Area)

Area (A) = 2 * Force/Pressure

Also, Area (A) = Spacing (S) * Wood Pipe Diameter

Area = Area

2*Force/Pressure = Spacing * Diameter

Substitute values I to the above expression

2 * Force / 4psi = S * 36 inches

Also

Force in steel (F) = Stress in steel (σ) × Cross-sectional area of the steel

So, F = 11.4ksi * 0.2in²

F = 11.4 * 10³psi * 0.2in²

F = 2.28 * 10³ psi.in²

So, 2 * Force / 4psi = S * 36 becomes

2 * 2.28 * 10³/4 = S * 36

S = 2 * 2.28 * 10³ / (4 * 36)

S = 4560/144

S = 31.66667 inches

S = 31.7 inches (approximated)

Answer:

A. -0.003

B. 0.02

Explanation:

Step 1: identify the given parameters

Giving the following parameters

Wing area (S)= 1.5 m²

Wing chord (C) = 0.45 m

Velocity (V) = 100 m/s

moment about center of gravity(Mcg) = -12.4 N-m

at another angle of attack, L = 3675 N and Mcg = 20.67 N-m

Step 2: calculate the value of the moment coefficient about the aerodynamic center (Cmcg)

[tex]q_{∞} =\frac{1}{2}\rho*v^{2}[/tex]

[tex]q_{∞} =\frac{1}{2}1.225*100^{2}[/tex]= 6125 N/m²

[tex]C_{mcg,w} =\frac{M_{cg,w} }{q_{∞}*S*C }[/tex]

[tex]C_{mcg,w} =\frac{-12.4}{6125*1.5*0.45 }[/tex] = -0.003  

[tex]C_{mcg,w}= C_{ac,w}= -0.003[/tex] at zero lift

Step 3: calculate coefficient of lift

Cl = L/q*s

Cl = 3675/6125*1.5 = 0.4

Step 4: calculate the location of the aerodynamic center

New moment coefficient about the aerodynamic center (Cmcg):

[tex]C_{mcg} =\frac{20.67}{6125*1.5*0.45}[/tex] = 0.005

[tex]C_{mcg,w} = C_{ac} ,w + C_{l}(h-h_{ac})[/tex]

[tex]h-h_{ac}= \frac{C_{mcg,w} -C_{ac,w}}{C_{l} }[/tex]

[tex]h-h_{ac}= \frac{0.005-(-0.003)}{0.4}[/tex]=0.02

the location of the aerodynamic center = 0.02

To determine the rate of heat transfer from a stack, natural convection and radiation must be considered when there's no wind, and forced convection must be considered when there are 20 km/h winds. Specific calculation details depend on heat transfer coefficients and empirical correlations.

To calculate the rate of heat transfer from an incinerator stack, we need to consider the mode of heat transfer. Without wind, the transfer will primarily be through natural convection and radiation. With wind, forced convection becomes significant.

(a) For no wind, we can use equations for natural convection and radiation to determine the heat loss. For convection, Newton's law of cooling \\( ext{Q} = hA\\Delta\\text{T}\\) can be applied where \\('h'\\) is the heat transfer coefficient, \\('A'\\) is the surface area, and \\('\\Delta\\text{T}'\\) is the temperature difference. For radiation, we can use the Stefan-Boltzmann law, considering the emissivity of the stack's material and the temperatures of the surface and the environment.

(b) For 20 km/h winds, the forced convection equation will be used. The heat transfer coefficient \\('h'\\) will be greater due to the wind, increasing the rate of heat transfer. The formula still follows \\( ext{Q} = hA\\Delta\\text{T}\\), but \\('h'\\) will change based on empirical correlations for flow past a cylinder.

Note that specifics of the calculation aren't provided as they require detailed coefficients and calculations beyond the scope of this question.

Take a look at the pictures that should help you out.

Answer:

a) initial mass = 34.85 gm, final mass = 3.48gm

b)

Explanation:

At the initial state, the:

Pressure, p1 = 1000kPa,

Temperature, T1 = 1000K,

Volume, V1 = 10 m³

The mass of air in the tank can be evaluated using;

m1 = (p1 x V1) /(R x T1)

m1 = (1000 x 10)/(287 x 1000)

Therefore, m1 = 34.85g

At the final state,

Pressure, p2 = 100kPa,

Temperature, T2 = 1000K,

Volume, V2 = 10 m³

The mass of air in the tank is given by;

m2 = (p2 x V2) / R x T2

m2 = (100 x 10)/ 287 x 1000

Therefore m2 = 3.48 gm

Answer:

Exfoliation.

Explanation:

Exfoliation is a form of chemical weathering that occurs when sheets of rocks peel from a massive rock's surface. It is also the unloading and sheeting of stress in a rock that expands the magma chamber.

The phasor technique for combining sinusoidal functions into a single expression cannot be used when the frequencies within the same expression differ. The expressions 45 sin(2500t – 50°) + 20 cos(1500t +20°) and -100 sin(10,000t +90°) + 40 sin(10,100t – 80°) + 80 cos(10,000t) both contain differing frequencies, and therefore cannot be combined using the phasor technique.

In the phasor technique, for the method to be applicable, all sinusoidal functions being combined should have the same frequency. Looking at the expressions given, the phasor technique cannot be applied to these:

The reasoning for these exceptions is due to discrepancies in the frequencies of the sinusoidal functions within the same expression; in these two cases, the frequencies 2500t and 1500t, as well as 10,000t and 10,100t, do not match, making the phasor technique inapplicable.

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Answer:

A

Explanation:

A key space is a set of all arrangements of a key, when given a fixed key size.

It is the total number of possible values of keys in a cryptographic algorithm or other security measures such as a password.

A key which is a byte long (or 8 bits) would consist of 256 possible keys.

Answer:

7.65 mm

Explanation:

Stress, [tex]\sigma=\frac {F}{A}[/tex] where F is the force and A is the area

Also, [tex]\sigma=E\times \frac {\triangle L}{L}[/tex]

Where E is Young’s modulus, L is the length and [tex]\triangle L[/tex] is the elongation

Therefore,

[tex]\frac {F}{A}= E\times \frac {\triangle L}{L}[/tex]

Making A the subject of the formula then

[tex]A=\frac {FL}{E\triangle L}=\frac {6660\times 380}{110\times 10^{9}\times 0.5}=4.60145\times 10^{-5} m^{2}[/tex]

Since [tex]A=\frac {\pi d^{2}}{4}[/tex] then  

[tex]d=\sqrt {\frac {4A}{\pi}}=\sqrt {\frac {4\times 4.60145\times 10^{-5}}{\pi}}= 0.00765425m= 7.654249728 mm\approx 7.65 mm[/tex]

Answer:

407 minutes

Explanation:

Step 1: Calculate the volume of the brick

[tex]V = 0.203 X 0.102 X 0.057[/tex]

V = 0.0012 m³

Step 2: Calculate the surface area of the brick

A= 2[(0.203 X 0.102) +(0.203 X 0.057) +(0.102 X0.057)] = 0.08 m²

Step 3: calculate the characteristic length

[tex]L_{C} =\frac{V}{A}[/tex]

[tex]L_{C} = \frac{0.0012}{0.08}[/tex] = 0.015 m

Step 4: calculate the biot number

[tex]B_{i} = \frac{hL_{c} }{k}[/tex]

[tex]B_{i} = \frac{5X0.015 }{0.9}[/tex] = 0.083

⇒Since [tex]B_{i}[/tex] ∠ 0.1, the lumped system analysis is applicable. Then cooling time is determined from

[tex]b = \frac{hA}{\rho c_{p}V } = \frac{h}{\rho c_{p}L_{c} }[/tex]

[tex]b = \frac{h}{\rho c_{p}L_{c} }[/tex]

[tex]b = \frac{5}{1920 X 790 X 0.015}[/tex]

b = 0.0002197 s⁻¹

[tex]\frac{T(t) -T_{o}}{T_{i} - T_{o}} =e^{-bt}[/tex]

[tex]\frac{5}{1100 - 30} =e^{-0.0002197t}[/tex]

Take natural log of both sides

-5.3659 = -0.0002197t

t = 24,424 seconds = 407 minutes

The required time "7 hours".

Dimension of brick[tex]= 203\times 102\times 57 \ mm\\\\[/tex]

kiln Temperature [tex]\ T_t = 1100^{\circ}\ C \\\\[/tex]

Air temperature of Ambient [tex]\ T_{\infty} = 30^{\circ}\ C\\\\[/tex]

Heat transmission coefficient by convection:

[tex]\to h=5\ \frac{W}{m^2}\ K\\\\[/tex]

Properties of Bricks:  

[tex]\to \rho = 1920\ \frac{kg}{m^3}\\\\ \to C_p = 790\ \frac{J}{kg-K}\\\\ \to k=0.9 \frac{W}{m-K}\\\\[/tex]

Calculating the temperature difference:

[tex]\to T_t -T_{\infty} = 5^{\circ}\ C\\\\[/tex]

Where t represents the amount of time needed to cool the brick for a temperature of

[tex]\to T_t = 35^{\circ}\ C\\\\[/tex]

We are familiar with the lumped system analysis for energy balance.

[tex]\to \ln(\frac{T_t-T_{\infty}}{T_i-T_{\infty}}) = \frac{hA_s}{\rho V C_p} t \\\\\\[/tex]

Calculating the brick surface area:

[tex]\to A_s = 2(ab + bc +ca)[/tex]

         [tex]= 2(0.203\times 0.102 +0.102 \times 0.057 +0.057\times 0.203)\\ \\= 2(0.020706 +0.005814 +0.011571)\\\\ = 2 \times 0.038091 \\\\ =0.076182 \ m^2\\\\[/tex]

Calculating the volume:

[tex]\to V = abc[/tex]

       [tex]= 0.057 \times 0.203 \times 0.102 \\\\ = 0.00118\ m^3\\\\[/tex]

We know that:

[tex]\to \ln(\frac{T_t-T_{\infty}}{T_i-T_{\infty}}) = - \frac{hA_s}{\rho V C_p} t \\\\\to \ln(\frac{5}{1100-30}) = \frac{5\times 0.076}{1920 \times 790 \times 0.00118 } t \\\\\to -5.3659=-2.128 \times 10^{-4}\ t\\\\\to t =\frac{-5.3659}{-2.128 \times 10^{-4}}\\\\\to t= 2.521423 \times 10^{4}\ s\\\\\to t=25214.23 \ s\\\\\to t=7.0039527778 \ h\\\\[/tex]

Therefore, the final answer is "7 hours".

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Answer:

Explanation:

Given

scale i.e. [tex]L_r=1:15[/tex]

Using Reynolds number similarity

[tex](Re)_m=(Re)_p[/tex]

[tex](\frac{Vl}{\nu })_m=(\frac{Vl}{\nu })_p[/tex]

Properties of air

[tex]\nu _{air}=1.57\times 10^{-4} ft/s[/tex]

Properties of sea water

[tex]\nu _{sea}=1.26\times 10^{-5} ft/s[/tex]

[tex]\left ( \frac{V_ml_M}{\nu _m}\right )=\left ( \frac{V_pl_p}{\nu _p}\right )[/tex]

[tex]V_p=V_m\left ( \frac{l_m}{l_p}\right )\left ( \frac{\nu _p}{\nu _m}\right )[/tex]

[tex]V_p=180\times \frac{1}{15}\times \frac{1.26\times 10^{-5}}{1.57\times 10^{-4}}[/tex]

[tex]V_p=0.963\ ft/s[/tex]

Answer:

Volume of tank = 6.4792 × 10 ³ m³

Final temperature = 371°C

Final Pressure = 21.3 kilo pascal

Change in temperature = 1373.54 kilo joule per kilogram.

Explanation:

Saturated liquid water = 1.4 kilogram

T1 = 200°C

At T1, = 25% of liquid  = V1 = water

At T1 =  75% = air

T2 = ? , V2 = ? ΔT = ?

Referencing the question,

to be able to calculate the volume of the tank, we need to know the volume of water in the tank.

Therefore, Volume of water = 1.4 kilogram × 0.001157 m³/kg

= 1.6198 × 10³ m ³

Now going back to calculate the volume of the tank,

We have, Volume of tank = 4 × Volume of water

= 4 × 1.6198 × 10³ m ³

6.4792 × 10 ³ m ³

Now, to calculate the pressure and the temperature, we need to calculate the specific volume of the mix,

So we have, α vapor =  volume of tank ÷ saturated liquid vapor

we have, 6.4792 × 10 ³ m ³ ÷ 1.4

0.004628 m³ / kilogram

T2 now therefor is 371°C and P2 = 21.3 kilo pascal

Change in temperate of water = T2 - T1

= 2224 - 850.46

1373.54 kilojoule/kilogram

Answer:

[tex]\tau_{max}  = 142.6[/tex] MPa

T = 1536.8 N m

Explanation:

Given data:

Torque = 3.5 k N m = 3.5*10^3 N.m

Diameter D = 5 cm = 0.05 m

a) from torsional equation we have

[tex]\frac[T}{J_{solid}} = \frac{\tau_{max}}{D/2}[/tex]

[tex]\frac{T}{\pi/32 D^4} = \frac{\tau_{max}}{D/2}[/tex]

solving for [tex]\tau_{max}[/tex]

[tex]\tau_{max} = \frac{16 T}{\pi D^3} =\frac{16 \times 3.5*10^3}{\pi 0.05^3}[/tex]

[tex]\tau_{max}  = 142.6[/tex] MPa

B)

[tex]\tau = 37 MPa = 37 \times  10^6[/tex] Pa

[tex]D_i = 4.5 cm = 0.045[/tex] m

[tex]D_o = 6.5 cm = 0.065[/tex] m

[tex]\frac{T}{J_{hollow}} = \frac{\tau_{max}}{D_o /2}[/tex]

[tex]\frac{T}{(\pi/32) (0.065^4 - 0.045^4)} =\frac{37*10^6}{0.065/2}[/tex]

T = 1536.8 N m

Answer:

Option D

This delay

Explanation:

The contract between Ruth and the contractor is assumed to be oral and since the contractor is supposed to complete a stage of the project when date for completion is over. Ruth can sue the contractor for the delay of the project. The contractor may consequently pay an interest for the delay of the project to Ruth.

The Rankine passive earth pressure on a 12-ft high retaining wall with backfill of granular soil having an internal angle of friction of 30° and a unit weight of 125 pcf is calculated to be 500 psf.

The question relates to calculating the Rankine passive earth pressure on a retaining wall that is 12-ft high with backfill of granular soil. The internal angle of friction (φ) provided is 30°, and the unit weight (γ) of soil is 125 pcf (pounds per cubic foot). First, to calculate the passive earth pressure (Ψp), we use the Rankine theory formula: Ψp = γh [1 - sin(φ)]/[1 + sin(φ)], where h is the height of the wall. Substituting the given values, Ψp = 125 * 12 * [1 - sin(30°)]/[1 + sin(30°)]. Since sin(30°) = 0.5, the calculation simplifies to: Ψp = 125 * 12 * [1 - 0.5]/[1 + 0.5], which further simplifies to Ψp = 125 * 12 * 0.5/1.5. Therefore, the Rankine passive earth pressure on the wall amounts to Ψp = 500 psf (pounds per square foot).

Explanation:

It may be instructive to look at the opposite of the sentence here. Perhaps the smarter creature would be more unhappy when frustrated, recognizing how it gains from happiness relative to the creature with less experience and less knowledge of a situation that does not define it at the moment.  

Perhaps the argument is really about the fact that wisdom helps one to hypothetically live in multiple states and a lack of wisdom prevents or fails this possibility.

Answer:

Replace the toner cartridge

Explanation:

solution

when laser printer  print black color liner vertical line print it is  very frustrating  that condition  nearly empty toner cartridge

but first we clean the corona wire for that color line

and Reinstall the toner cartridges after Shake the toner cartridge side to side

if problem not solve than Clean the drum unit

and finally if not solve change the toner cartridge

so as that our problem will be resolve

The value of P needed to cause motion is 142.5 N, and it's a sliding motion.

Multiply the coefficient of static friction (0.3) by the normal force (475 N) to find the maximum static friction force.

Static friction equals

= [tex]0.3 * 475 N[/tex]

= 142.5 N.

To initiate motion, the applied force (P) must overcome static friction. Thus,

P=142.5 N.

If P was less than s, the chest wouldn't move. Since P equals fs, the motion is sliding. Thus, the value of P needed to cause motion is 142.5 N, and it's a sliding motion.

Answer:

874 psi

Explanation:

Given a sample mean (x') = 900,

and a standard error (SE) = 10

At 99% confidence, Z(critical) = 2.58

That gives 99% confidence interval as,

x' ± Z(critical) x SE = 900 ± 2.58 x 10

The value of the lower limit is,

900 - 25.8 = 874.2

≈ 874 psi

Answer:

The answer is C): Stereospecific and concerted.

Explanation:

An E2 mechanism is a single step elimination reaction that is both stereospecific and concerted: it is stereospecific because it can convert the components of the reaction into stereoisomeric products; it is concerted because all bonds are broken and formed during the single step.

Answer:

13 %

Explanation:

rd= 9%

T = 40%

WACC = 9.96%

wd = 40%

wc = 60%

WACC= (wd)(rd)(1 – T) + (wc)(rs)

0.0996 = (0.4)(0.09)(1 – 0.4) + (0.6)rs

0.0996 = 0.0216 + 0.6rs

0.078= 0.6rs

rs= 13%

Answer:

50,625kg of wood

Explanation:

Power input = power output ÷ efficiency

Power output = 7500 horsepower = 7500×750W = 5625000W, efficiency = 6% = 0.06

Power input = 5625000/0.06 = 93750000W

Energy input = power input × time

time = 3hour = 3×3600 = 10800sec

Energy input = 93750000 × 10800 = 1.0125×10^12J

Mass = Energy ÷ Energy density = (1.0125×10^12J) ÷ (20×10^6J/kg) = 50,625kg of wood

Approximately 182.25 kilograms of wood must be burned during the 3-hour trip.

First, let's convert the horsepower rating of the locomotive to watts:

1 horsepower = 750 W

So, 7500 horsepower = 7500 × 750 W = 5,625,000 W

Now, let's calculate the energy output of the locomotive during the 3-hour trip:

Energy output = Power × Time

Energy output = 5,625,000 W × 3 hours = 16,875,000 Wh

Now, we need to convert watt-hours to joules since wood's energy density is given in joules:

1 Wh = 3600 J (since 1 watt = 1 joule/second and there are 3600 seconds in an hour)

So, 16,875,000 Wh × 3600 J/Wh = 60,750,000,000 J

Now, we'll adjust for the efficiency of the locomotive:

Efficiency = 6% = 0.06

Actual energy output = Energy output × Efficiency

Actual energy output = 60,750,000,000 J × 0.06 = 3,645,000,000 J

Now, let's calculate the mass of wood needed using its energy density:

Energy density of wood = 20.0 MJ/kg = 20,000,000 J/kg

Mass of wood = Actual energy output / Energy density of wood

Mass of wood = 3,645,000,000 J ÷ 20,000,000 J/kg = 182.25 kg

So, approximately 182.25 kilograms of wood must be burned during the 3-hour trip.

Answer:

Vc = 94 V

Explanation:

In a series circuit, powered by a sinusoidal source, the current is the same across all circuit elements, and can be calculated based on the impedance concept, that takes into account that the voltage and the current in a given circuit element have a phase angle, which means that voltage and current don´t reach to a maximum at the same time.

We define the impedance as the complex sum of the resistive part of the circuit (in which current and voltage be in phase) and the reactive part (in which current and voltage are 90º out of phase), as follows:

Z = R + j (XL - XC)

In order to obtain the magnitude of Z, we can do the following:

Z =√R²+ (Xl-Xc)²

The value of the current can be obtained just dividing the applied voltage between the magnitude of the impedance.

For our circuit, we can get the magnitude of Z as follows:

Z= √(39+68)²+(60+50)² = 154 Ω

⇒ I = V/Z = 240 V / 154 Ω = 1.56 A

In order to get the magnitude of the voltage drop across any circuit element, we just need to apply the generalized version of Ohm´s Law.

For a capacitor, the voltage drop can be calculated as follows:

Vc = I* Xc

⇒ Vc = 1.56 A * 60Ω = 94 V