Vapor lock occurs when the gasoline is cooled and forms a gel, preventing fuel flow and

engine operation. TRUE or FALSE

Answer:

a) I₂ = 2 mA   (The current has decreased)

b) L₂ = 2.4 cm

Explanation:

Consider the old wire as wire 1 and the new wire as wire 2. The data that we have from the question is:

Current through wire 1 = I₁ = 12.5 mA

Diameter of wire 1 = d₁ = 5 mm

Length of wire 1 = L₁ = 15 cm

Cross-Sectional Area of wire 1 = A₁ = πd₁²/4 = π(5 mm)²/4 = 19.63 mm²

Diameter of wire 2 = d₂ = 2 mm

Cross-Sectional Area of wire 2 = A₂ = πd₂²/4 = π(2 mm)²/4 = 3.14 mm²

a)

Length of wire 2 = L₂ = 15 cm

Since, the battery is same. Therefore, the voltage will be same for both wires.

V₁ = V₂

using Ohm's Law (V = IR)

I₁R₁ = I₂R₂

Since resistance of wire is given by formula:  R = ρL/A

Therefore,

I₁ρ₁L₁/A₁ = I₂ρ₂L₂/A₂

where,

ρ = resistivity, and it depends upon material of wire and the material of both wires is same and the length of wires is also same.

Hence,    ρ₁ = ρ₂

and      L₁ = L₂

and the equation becomes:

I₁/A₁ = I₂/A₂

I₂ = I₁A₂/A₁

I₂ = (12.5 mA)(3.14 mm²)/(19.63 mm²)

I₂ = 2 mA

Thus, the current has decreased.

b)

In order to have same current the resistance of both wires must be same:

R₁ = R₂

ρ₁L₁/A₁ = ρ₂L₂/A₂

Since,   ρ₁ = ρ₂

Therefore,

L₁/A₁ = L₂/A₂

L₂ = L₁A₂/A₁

L₂ = (15 cm)(3.14 mm²)/(19.63 mm²)

L₂ = 2.4 cm

Answer:

Explanation:

a) Present worth of the system:

First step :

Calculation of bank installment:

We are given:

·nitial costs = $32,000

Borrow amount = ½ of purchase price

Payment of borrow amount = EOY 2 to EOY 4 (3 Equal installments)

Bank loan interest = 8.5% = 8.5/100 = 0.085

Assume the installment amount is F. They will be paid at end of year 2 to end of year 4. Their present value must be equal to borrow amount.

Present value of cost to be incurred in future can be calculated by below formula:

F P (1 + i)

F= Future cost

i = Rate of interest

n = time (in years)

Therefore,

F F $32,000 2 F (1 +0.085)2 (1 +0.085) 3 (1 +0.085) + +

.: 2.35394F = 16,000 or F = 16,000 2.35394 - $6,797.11

Step 2: Present worth of the system:

Given Data:

Initial costs = $32,000

Expected life = 7 years

Salvage value = $5,000

O&M Costs = $2,000 per year

MARR = 12.5%

= 12.5/100

= 0.125

Present value of uniform recurring payments is given by below formula:

P=A (1 + i) - 1 i(1+i)n 72

Where,

P = Present Value

A = Recurring payments per annum

i = rate of interest

n = time (in years)

Hence present value of O&M costs,

P1 = -2,000 x (1 + 0.125) 7-1 0.125 x (1 + 0.125) 7 -$8,984.60

Present worth of the system calculated in below table:

Description

F ($)

MARR (i)

per year

n (years)

P ($)

Initial investment (1/2 of purchase price)

-16,000.00

0.125

0

-16,000.00

Bank installment EOY2

-6,797.11

0.125

2

-5,370.56

Bank installment EOY3

-6,797.11

0.125

3

-4,773.83

Bank installment EOY4

-6,797.11

0.125

4

-4,243.40

Salvage value

5,000.00

0.125

7

2,192.31

O&M Costs

-8,984.60

0.125

0

-8,984.60

The current worth of the new system

-37,180.07

Part b) Decision rule of judgment:

Assuming current value of costs is lower than current value of benefit, an alternative is known to be economic to use based on current worth analysis.

Part c) Decision for the water filtration system:

Given Data:

· Annual savings from filtration system (A) = $13,000 per year

· Expected life (n) = 7 years

· MARR = 12.5%

= 12.5/100

= 0.125

Present value of benefits = 13,000 X (1 + 0.125)7 - 1 0.125 x (1 + 0.125) 7 $58,399.91

Since current value of costs is less than current value of benefit, this is an worthwhile system and has to be be purchased.

Answer:

Explanation:

Find the temperature at exit of compressor

[tex]T_2=300 \times 8^{\frac{1.667-1}{1.667} }\\=689.3k[/tex]

Find the work done by the compressor

[tex]\frac{W}{m} =c_p(T_2-T_1)\\\\=5.19(689.3-300)\\=2020.4kJ/kg[/tex]

Find the actual workdone by the compressor

[tex]\frac{W}{m} =n_c(\frac{W}{m} )\\\\=1 \times 2020.4kJ/kg[/tex]

Find the temperature at exit of the turbine

[tex]T_4=\frac{1800}{8^{\frac{1.667-1}{1.667} }} \\\\=787.3k[/tex]

Find the actual workdone by the turbine

[tex]1 \times 5.19 (1800-783.3)\\=5276.6kJ/kg[/tex]

Find the temperature of the regeneration

[tex]\epsilon = \frac{T_5-T_2}{T_4-T_2} \\\\0.75=\frac{T_5-689.3}{783.3-689.3} \\\\T_5=759.8k[/tex]

Find the heat supplied

[tex]Q_i_n=c_p(T_3-T_5)\\\\=5.19(1800-759.8)\\\\=5388.2kJ/kg[/tex]

Find the thermal efficiency

[tex]n_t_h=\frac{W_t-W_c}{Q_i_n} \\\\=\frac{5276.6-2020.4}{5388.2} \\\\n_t_h=60.4[/tex]

60.4%

Find the mass flow rate

[tex]m=\frac{W_net}{P} \\\\\frac{60 \times 10^3}{5276.6-2020.4} \\\\=18.42[/tex]

Find the actual workdone by the compressor

[tex]\frac{W_c}{m} =\frac{(\frac{W}{m} )}{n_c} \\\\=\frac{2020.4}{0.8} \\\\=2525.5kg[/tex]

Find the actual workdone by the turbine

[tex]\frac{W_t}{m} =n_t(\frac{W}{m} )\\\\=0.8 \times5.19(1800-783.3)\\\\=4221.2kJ/kg[/tex]

Find the temperature of the compressor exit

[tex]\frac{W_t}{m} =c_p(T_2_a-T_1)\\2525.5=5.18(T_2_a-300)\\T_2_a=787.5k[/tex]

Find the temperature at the turbine exit

[tex]4221.2=5.18(1800-T_4_a)\\\\T_4_a=985k[/tex]

Find the temperature of regeneration

[tex]\epsilon =\frac{T_5-T_2}{T_4-T_2}\\\\0.75=\frac{T_5-787.5}{985-787.5}\\\\T_5=935.5k[/tex]

Answer:

a) 60.4%;  18.42 kg/s

b) 37.8% ;    35.4 kg/s

Explanation:

a) at an isentropic efficiency of 100%.

Let's first find the exit temperature of the compressor T2, using the formula:

[tex](r_p) ^k^-^1^/^k = \frac{T_2}{T_1}[/tex]

Solving for T2, we have:

[tex] T_2 = 300 * (8)^1^.^6^6^7^-^1^/^1^.^6^6^7 = 689.3 K [/tex]

Let's now find the work dine by the compressor.

[tex] \frac{W_c}{m} = c_p(T_2 - T_1) [/tex]

[tex] \frac{W_c}{m} = 5.19(689.3 - 300) = 2020.4 KJ/kg[/tex]

The actual work done by the compressor =

[tex] W_c = 1 * 2020.4 = 2020.4 KJ/kg [/tex]

Let's find the temperature at the exit of the turbine, T4

[tex](r_p) ^k^-^1^/^k = \frac{T_3}{T_4}[/tex]

Solving for T4, we have:

[tex]T_4 = \frac{1800}{(8)^1^.^6^6^7^-^1^/^1^.^6^6^7} = 783.3 K[/tex]

Let's find the work done by the turbine.

[tex]\frac{W_t}{m} = c_p(T_3 - T_4)[/tex]

[tex]\frac{W_t}{m} = 5.19(1800 - 783.3) = 5276.6 KJ/kg[/tex]

The actual work done by the turbine:

= 1 * 5276.6 = 5276.6 KJ/kg

Let's find the regeneration temperature, using the formula:

[tex] e = \frac{T_r - T_2}{T_4 - T_2}[/tex]

Substituting figures, we have:

[tex] 0.75 = \frac{T_r - 689.3}{783.3 - 689.3} [/tex]

[tex] T_r = [0.75(783.3 - 689.3)] + 689.3 = 759.8 [/tex]

Let's calculate the heat supplied.

[tex]Q = c_p(T_3 - T_r)[/tex]

[tex] Q = 5.19(1800 - 759.8) [/tex]

Q = 5388.2 kJ/kg

For thermal efficiency, we have:

[tex] n = \frac{W_t - W_c}{Q} [/tex]

Substituting figures, we have:

[tex] n = \frac{5276.6 - 2020.4}{5388.2} = 0.604 [/tex]

0.604 * 100 = 60.4%

For mass flow rate:

Let's use the formula:

[tex] m = \frac{W_n_e_t}{P} [/tex]

Wnet = 60MW = 60*1000

[tex] m = \frac{60*10^3}{5276.6 - 2020.4} = 18.42 [/tex]

b) at an isentropic efficiency of 80%.

Let's now find the work done by the compressor.

[tex] \frac{W_c}{m} = c_p(T_2 - T_1) [/tex]

[tex] \frac{W_c}{m} = 5.19(689.3 - 300) = 2020.4 KJ/kg[/tex]

The actual work done by the compressor =

[tex] W_c = \frac{2020.4}{0.8}= 2525.5 KJ/kg [/tex]

Let's find the work done by the turbine.

[tex] \frac{W_t}{m} = c_p(T_3 - T_4) [/tex]

[tex] \frac{W_t}{m} = 5.19(1800 - 787.5) = 5276.6 KJ/kg[/tex]

The actual work done by the turbine:

= 0.8 * 5276.6 = 4221.2 KJ/kg

Let's find the exit temperature of the compressor T2, using the formula:

[tex]\frac{W_c}{m} = c_p(T_2 - T_1) [/tex]

[tex] 2525.5 = 5.19(T_2 - 300) [/tex]

Solving for T2, we have:

[tex] T_2 = \frac{2525.5 + 300}{5.19} = 787.5 [/tex]

Let's find the temperature at the exit of the turbine, T4

[tex] \frac{W_t}{m} = c_p(T_3 - T_4) [/tex]

[tex] 4221.2 = 5.19(1800 - T_4) [/tex]

Solving for T4 we have:

[tex] T_4 = 958 K[/tex]

Let's find the regeneration temperature, using the formula:

[tex] e = \frac{T_r - T_2}{T_4 - T_2}[/tex]

Substituting figures, we have:

[tex] 0.75 = \frac{T_r - 787.5}{985 - 787.5} [/tex]

[tex] T_r = [0.75(958 - 787.5)] + 787.5 = 935.5 K [/tex]

Let's calculate the heat supplied.

[tex]Q = c_p(T_3 - T_r)[/tex]

[tex] Q = 5.19(1800 - 935.5) [/tex]

Q =  4486.2 kJ/kg

For thermal efficiency, we have:

[tex] n = \frac{W_t - W_c}{Q} [/tex]

Substituting figures, we have:

[tex] n = \frac{4221.2 - 2525.2}{4486.2} = 0.378 [/tex]

0.378 * 100 = 37.8%

For mass flow rate:

Let's use the formula:

[tex] m = \frac{W_n_e_t}{P} [/tex]

Wnet = 60MW = 60*1000

[tex] m = \frac{60*10^3}{4221.2 - 2525.2} = 35.4 kg/s [/tex]

Answer:

Explanation:

The image that is supposed to be attached to the question is displayed in the diagram below.

Applying Nodal Analysis at node 1;

[tex]\dfrac{V_o -50}{12.5*10^{-3}} + \dfrac{V_o}{50*10^3}+\dfrac{V_o-7500 \ in}{10*10^3}=0[/tex]

where;

[tex]in = \dfrac{V_o}{50*10^3}[/tex]   (from the circuit)

= [tex]\dfrac{V_o-50}{12.5}+\dfrac{V_o}{50} + V_o -\dfrac{7500 *V_o }{\frac{50*10^3}{10}}=0[/tex]

= [tex]V_o [ \dfrac{1}{12.5}+\dfrac{1}{50}+\dfrac{1}{10}-\dfrac{75}{500}] = \dfrac{50}{12.5}[/tex]

= [tex]V_o[ \dfrac{500*500+12.5*5000+12.5*5000*5-75*12.5*500}{12.5*50*10*500}]= \dfrac{50}{12.5}[/tex]

= [tex]V_o = 80 \ volts[/tex]

[tex]in = \frac{80}{50*10^3}= 1.6 mA \\ \\ 7500*in = 120 volts \\ \\ I = \frac{120-80}{10(10^3} =4*10^{-3} Amps \\ \\ \\ \\ P_{generated} = 75000*in*I \\ \\ P_{generated} = 120*4*10^{-3} \\ \\ P_{generated} = 480 \ MW[/tex]

Answer: Firebrick is referred to as "common brick" because it is the most commonly used  type of brick --- False

Explanation:

 Firebrick is not the most commonly used,   it is  a  refractory ceramic brick used in lining of  furnaces and  kilns, which is built basically  to withstand or resist high temperature.The most commonly used type of brick, is the Building Brick called "common brick"   because it is versatile and used for  applications where appearance is not an  important factor.

The image attached that is supposed to be attached to the question is shown in the first file below.

Answer:

t = 2.19 seconds

Explanation:

The free body diagram showing the center of mass A and B is attached in the second diagram below.

NOTE : that from the second diagram; Mass A and B do not have any acceleration

Taking the moment about wheel A:

[tex]\sum M_A = I_A \alpha _A[/tex]

[tex]-f(r_A) = I_A \alpha _A ----- (1)[/tex]

The equilibrium forces in the y-direction is 0

i.e

[tex]F_y = 0[/tex]

So;

[tex]N +T sin 30^0 -W_A = 0 ----- (2)[/tex]

The equilibrium forces in the x-direction is as follows:

[tex]\sum F_x = 0[/tex]

[tex]Tcos 30^0 + f= 0 -----(3)[/tex]

The kinetic friction f can be expressed as :

[tex]f = \mu _k N[/tex]

From above equation (2) and equation (3);

[tex]N + [\dfrac{-f}{cos 30^0}]sin 30^0 -150 =0[/tex]

[tex]N - \mu _k N \ tan 30^0 -150 =0[/tex]

[tex]N = \dfrac{150}{1-0.3 \ tan 30^0}[/tex]

N = 181.423 lb

Similarly; from equation(1)

[tex]\alpha_A = - \dfrac{f(r_A)}{I_A}[/tex]

[tex]\alpha _A = \dfrac{-\mu_k N(r_A)}{I_A}[/tex]

[tex]\alpha _A = \dfrac{-0.3*181.423*1.25}{\frac{150}{32.2}*I^2}[/tex]

[tex]\alpha _A =-14.6045 \ rad/s^2[/tex]

However; from the kinematics ; as moments are constant ; so is the angular acceleration is constant )

Thus;

[tex]\omega _A - \omega_o^A = \alpha_A t[/tex]

[tex]\omega _A = \omega_o^A + \alpha_A t[/tex]

[tex]\omega _A = 100 -14.6045 \ t ---- (4)[/tex]

Let's take a look at wheel B now;

Taking the moment about wheel B from the equation of motion:

[tex]\sum M_B = I_B \alpha _B[/tex]

[tex]f(r_B) = I_B \alpha _B[/tex]

[tex]\mu_k N (r_B) = I_B \alpha_B[/tex]

[tex]\mu_k N (r_B) = \dfrac{W_B}{g}* k^2_B \alpha_B[/tex]

[tex]\alpha_B = \dfrac{0.3*181.423*1}{\frac{100}{32.2}*0.75^2}[/tex]

[tex]\alpha = 31.1563 \ rad/s^2[/tex]

Again; from the kinematics; as the moments are constant which lead to the angular accleration;

[tex]\omega _B = \omega _o^B + \alpha _B \ t[/tex]

[tex]\omega _B =0 + 31.156 \ t-----(5)[/tex]

From equation 4 and 5 which attain the same angular velocity; we have;

[tex]\omega^A = \omega^B[/tex]

100 - 14.6045 t = 31.1563 t

100 = 31.1563 t + 14.6045 t

100 = 45.761 t

t = 100/45.761

t = 2.19 seconds

Answer:

atomic percentage = 143 %

Explanation:

Let  x be the number of tin atoms and there are 4 atoms / cell in the FCC structure , then 4 -x  be the number of copper atoms . Therefore, the value of x can be determined by using the density equation as shown below:

[tex]\mathbf{density (\rho) = \dfrac{(no \ of \ atoms/cell)(atomic \ mass )}{(lattice \ parameter )^3(6.022*10^{23} atoms/ mol)} }[/tex]

where;

the lattice parameter is given as : 4.7589 × 10⁻⁸ cm

The atomic mass of tin is 118.69 g/mol

The atomic mass of copper is 63.54 g/mol

The density is 8.772 g/cm³

[tex]\mathbf{8.772 g/cm^3 = \dfrac{(x)(118.69 \ g/mol) +(4-x)(63.54 \ g/mol)}{(4.7589*10^{-8} cm )^3(6.022*10^{23} atoms/ mol)} }[/tex]

569.32 = 118.69x + 254.16-63.54x

569.32 - 254.16 = 118.69x - 63.54 x

315.16 = 55.15x

x = 315.16/55.15

x = 5.72 atoms/cell

As there are four atoms per cell in FCC structure for the metal, thus, the atomic percentage of the tin is  calculated as follows :

atomic % = [tex]\frac{no \ of \ atoms \ per \ cell \ in \ tin }{no \ of \ atoms \ per \ cell \ in \ the \ metal}*100[/tex]

atomic % = [tex]\frac{5.72 \ atoms / cell}{4 \ atoms/ cell} *100[/tex]

atomic % = 143 %

Answer:

Using 1's complement

a)

Therefore the difference is -10001

b)

Therefore the difference is 00001

c)

Therefore the difference is 01001

d)  

Therefore the difference is 10100

e)

Therefore the difference is 00111

Explanation:

Using 1's complement

a) The 1's complement of the subtrahend 11010 = 00101.

Therefore 01001-11010 = 01001 + 00101 = 01110

Since no overflow, we take the 1's complement of the result and it is negative.

Therefore the difference is -10001

b) The 1's complement of the subtrahend 11001 = 00110.

Therefore 11010-11001 = 11010 + 00110 =1 00000

Since there is an overflow, we add the overflow to the result

Therefore the difference is 00001

c) The 1's complement of the subtrahend 01101 = 10010

Therefore 10110-01101 = 10110 + 10010 =  1 01000

Since there is an overflow, we add the overflow to the result

Therefore the difference is 01001

d)  The 1's complement of the subtrahend 00111 = 11000

Therefore 11011-00111= 11011 + 11000 =  1 10011

Since there is an overflow, we add the overflow to the result

Therefore the difference is 10100

e) The 1's complement of the subtrahend 10101 = 01010

Therefore 11100-10101= 11100 + 01010 = 1 00110

Since there is an overflow, we add the overflow to the result

Therefore the difference is 00111

Using 2's complement

a) The 2's complement of the subtrahend 11010 = 00110.

Therefore 01001-11010 = 01001 + 00110 = 01111

Since no overflow, we take the 2's complement of the result and it is negative.

Therefore the difference is -10001

b) The 2's complement of the subtrahend 11001 = 00111.

Therefore 11010-11001 = 11010 + 00111 =1 00001

Since there is an overflow, we drop the overflow

Therefore the difference is 00001

c) The 1's complement of the subtrahend 01101 = 10011

Therefore 10110-01101 = 10110 + 10011 =  1 01001

Since there is an overflow, we drop the overflow

Therefore the difference is 01001

d)  The 1's complement of the subtrahend 00111 = 11001

Therefore 11011-00111= 11011 + 11001 =  1 10100

Since there is an overflow, we drop the overflow

Therefore the difference is 10100

e) The 1's complement of the subtrahend 10101 = 01011

Therefore 11100-10101= 11100 + 01011 = 1 00111

Since there is an overflow, we drop the overflow

Therefore the difference is 00111

Answer:

The shear stress will be 80 MPa

Explanation:

Here we have;

τ = (T·r)/J

For rectangular tube, we have;

Average shear stress given as follows;

Where;

[tex]\tau_{ave} = \frac{T}{2tA_{m}}[/tex]

[tex]A_m[/tex] = 100 mm × 200 mm = 20000 mm² = 0.02 m²

t = Thickness of the shaft in question = 2 mm = 0.002 m

T = Applied torque

Therefore, 50 MPa = T/(2×0.002×0.02)

T = 50 MPa × 0.00008 m³ = 4000 N·m

Where the dimension is 50 mm × 250 mm, which is 0.05 m × 0.25 m

Therefore, [tex]A_m[/tex] = 0.05 m × 0.25 m = 0.0125 m².

Therefore, from the following average shear stress formula, we have;

[tex]\tau_{ave} = \frac{T}{2tA_{m}}[/tex]

Plugging in then values, gives;

[tex]\tau_{ave} = \frac{4000}{2\times 0.002 \times 0.0125} = 80,000,000 Pa[/tex]

The shear stress will be 80,000,000 Pa or 80 MPa.

Answer:

$151094

Explanation:

Solution

Recall that:

Acme Chemical in 2002 purchased a large pump worth of = 112,000

The estimation for the pump to the industrial pump index is =100

The index in 2002= 212

The current index is = 286

k = is the  reference year for which cost or price is known.

n =  the year for which cost or price is to be estimated (n>k).

Cn = the estimated cost or price of item in year n.

Ck =  the cost or price of item in reference year k.

Cn = Ck * (In / Ik )

Now,

We find the estimated cost of the new pump which is stated as follows:

Cn = (112,000 * 286) /212

=32032000/212

=$151094

Therefore, the estimated cost of the new pump is $151094

Answer:

  B) leads the voltage

Explanation:

One way to think about it is that the current causes charge to be accumulated on the capacitor, changing its voltage. The current must be non-zero before the voltage can change. Hence current leads voltage.

Answer:

A counter which counts from 0 to 255 with seven segment display

Timer Mode Control (TMOD)

Explanation:

Answer:

4.2ms

Explanation:

Calibrated time= 0.3+0.2+0.5+1.4= 2.4

Measured time= 6.6ms

Accuracy is closeness of measurement to an observed or true value

Accuracy= 6.6-2.4= 4.2ms

Answer & Explanation:

Circular Flow model denotes how goods & services, factor incomes & prices move within sectors of economy.

A closed economy has two sectors - households & firms, having following features of circular flow between them:

In case of open economy - with rest of world & foreign country, exports & imports also come in circular flow.

Answer:

0.09

Explanation:

Packet switching involves breaking a message into packets and sending them independently. Since the user only needs to transmit 10 percent of the time, the probability that a given (specific) user is transmitting = 10% = 0.1

The  probability that a user is not transmitting = 100% - 10% = 90% = 0.9

Therefore, the probability that a given (specific) user is transmitting, and the remaining users are not transmitting = 0.1 * 0.9 = 0.09

Answer:

(a) Qh(dot)=600 kW, Qc(dot)=400 kW  is an irreversible process.

(b) Qh(dot)=600 kW, Qc(dot)=0 kW  is an impossible process.

(c) Qh(dot)=600 kW, Qc(dot)=200 kW  is a reversible process.

Explanation:

T(hot) = 1200k, T(cold) = 400

efficiency n = (Th - Tc ) / Tc

n = (1200 - 400) / 1200 = 0.667 (this will be the comparison base)

(a)

Qh = 600 kW, Qc = 400 kW

n = (Qh - Qc) / Qh ⇒ (600 - 400) / 600

n = 0.33

0.33 is less than efficiency value from temperature 0.67

∴ it is irreversible process

(b)

Qh = 600 kW, Qc = 0

n = (Qh - Qc) / Qh ⇒ (600 - 0) / 600 = 1

efficiency in any power cycle can never be equal to one.

∴ it is an impossible process.

(c)

Qh = 600 kW, Qc = 200 kW

n = (Qh - Qc) / Qh = (600 - 200) / 600

n = 0.67 (it is equal to efficiency value from temperature)

∴ it is a reversible process

Answer:

The solution is presented in explanation

Explanation:

This problem can be solved in following steps:

1) In the first round the peasant will take the goat to the other side.

2) Now, the peasant will come back alone.

3) The peasant will now take the wolf with him to other side.

4) The peasant will return with the goat to riverbank.

5) Now, he will take cabbage to the other side of the river, where the wolf is already present.

6) Peasant will leave cabbage and wolf on other side and come back to riverbank alone. Since, wolf does not eat cabbage.

7) Now, finally the peasant will take goat to the other side of river.

In this way, all three of them shall be transported to the other side of the river without eating each other.

Answer:

option A. Inferring

Explanation:

inferring/ inference as reading strategy simply is the process by which one uses what he/she knows to make a guess about what you don't know or reading between the lines. Readers in making  inferences uses  clues found inside text along with their own  views or experiences to help them figure out what is not directly said,thereby causing a  personal and memorable text. for one to draw an inference from the passage via reading, Identify if its an Inference Question.inferring involves Trusting the Passage or what you are seeing,  then you start Hunting for Clues thereafter you Narrow Down the Choices. and then come to a conclusion or Practice.

I inferred you meant emerging technologies we see today.

Explanation:

1. 3D Printing

A three dimensional printing allows a digital model to be printed (constructed) into a physical object.

A box, an industrial design and many more could be printed within minutes.

2. AI voice recognition devices

Another trend in the tech world is the rise in artificial intelligence been used in voice recognition devices that not only recognize one's voice but also take commands from the user.

This technology allows one to listen to the internet, such as listening to music online.

The tech world is ever changing with new technology beyond one's consumption on the increase daily.

Answer: a. 0.4667

b. 0.4667 and C 0.0667

Explanation:

Given Data:

N = population size (10)

n = random selection (2)

r = number of observations = 7

Therefore

f(y) = ( r/y ) ( N - r / n - y ) / ( N /n )

When y = 1

f(1) = ( 7/1 ) ( 10 - 7 / 2 -1 ) / ( 10/2 )

= 7 / 15

= 0.4667

When y = 2

f(2) = ( 7/2 ) ( 10 - 7 / 2 -2 ) / ( 10/2 )

= 7 / 15

= 0.4667

When y = 0

f(0) = ( 7/0 ) ( 10 - 7 / 2 -0) / ( 10/2 )

= 1 / 15

= 0.0667

Answer:

D) AND gate.

Explanation:

Given that:

A certain printer requires that all of the following conditions be satisfied before it will send a HIGH to la microprocessor acknowledging that it is ready to print

These conditions are:

1. The printer's electronic circuits must be energized.

2. Paper must be loaded and ready to advance.

3. The printer must be "on line" with the microprocessor.

Now; if these conditions are met  the logic gate produces a HIGH output indicating readiness to print.

The objective here is to determine the basic logic gate used in this circuit.

Now;

For NOR gate;

NOR gate gives HIGH only when all the inputs are low. but the question states it that "a HIGH is generated and applied to a 3-input logic gate". This already falsify NOR gate to be the right answer.

For NOT gate.

NOT gate operates with only one input and one output device but here; we are dealing with 3-input logic gate.

Similarly, OR gate gives output as a high if any one of the input signals is high but we need "a HIGH that is generated and applied to a 3-input logic gate".

Finally, AND gate output is HIGH only when all the input signal is HIGH and vice versa, i.e AND gate output is LOW only when all the input signal is LOW. So AND gate satisfies the given criteria that; all the three conditions must be true for the final signal to be HIGH.

Answer:

The required diameter of the fuse wire should be 0.0383 cm  to limit the current to 0.53 A with current density of 459 A/cm² .

Explanation:

We are given current density of 459 A/cm²  and we want to limit the current to 0.53 A in a fuse wire. We are asked to find the corresponding diameter of the fuse wire.

Recall that current density is given by

j = I/A

where I is the current flowing through the wire and A is the area of the wire

A = πr²

but r = d/2  so

A = π(d/2)²

A = πd²/4

so the equation of current density becomes

j = I/πd²/4

j = 4I/πd²

Re-arrange the equation for d

d² = 4I/jπ  

d = √4I/jπ

d = √(4*0.53)/(459π)

d = 0.0383 cm

Therefore, the required diameter of the fuse wire should be 0.0383 cm  to limit the current to 0.53 A with current density of 459 A/cm² .

Answer:

diameter is 1 cm

Explanation:

diameter is 1 cm

Answer:

1.96 kg/s.

Explanation:

So, we are given the following data or parameters or information which we are going to use in solving this question effectively and these data are;

=> Superheated water vapor at a pressure = 20 MPa,

=> temperature = 500°C,

=> " flow rate of 10 kg/s is to be brought to a saturated vapor state at 10 MPa in an open feedwater heater."

=> "mixing this stream with a stream of liquid water at 20°C and 10 MPa."

K1 = 3241.18, k2 = 93.28 and 2725.47.

Therefore, m1 + m2= m3.

10(3241.18) + m2 (93.28) = (10 + m3) 2725.47.

=> 1.96 kg/s.

Answer:

See explaination

Explanation:

please kindly see attachment for the step by step solution of the given problem

Answer:

V = 36.4 m³ = 4.86 gallons

W = 80193.88 lbf = 356720 N = 356.72 KN

Explanation:

We have the following data given in the question:

At = Total area of roof =  1967 ft²

h = Annual Rainfall = 14 inches = 1.17 ft

V = Volume of tank in m³  and gallons = ?

W = Weight of water in N and lbf = ?

So, for volume we know that the area of roof that receives rainfall is 56% of total area and 14 inches of annual rainfall means  that there is a standing height of 14 inches of rain water for a given area, for 1 year.

Area to receive rain = A = 0.56*1967 ft² = 1101.52 ft²

Now,

Volume = V = A * h = 1101.52 ft²)(1.17 ft)

V = 1285.11 ft³

Converting to m³:

V = (1285.11 ft³)(1 m³/35.3147 ft³)

V = 36.4 m³

Converting to gallons:

V = (1285.11 ft³)(1 m³/264.172 gal)

V = 4.86 gal

Now, for the weight of water, we use formula:

W = ρVg

where,

W = weight of water = ?

ρ = Density of water = 1000 kg/m³

V = Volume of tank = 36.4 m³

g = 9.8 m/s²

Therefore,

W = (1000 kg/m³)(36.4 m³)(9.8 m/s²)

W = 356720 N = 356.72 KN

Converting to lbf:

W = (356720 N)(1 lbf/4.44822 N)

W = 80193.88 lbf

Answer:

A one -two pages menu was written with questions directed to the CSP which is stated below in the explanation section

Explanation:

Solution

If CSP has no team or limited staff, you will need to ask the following questions to understand how the CSP is set up:

To access evidence in the cloud :

Answer:

1. 0.494

2. = 352.299 million years

3. It is between 0 years to 352.299 million years

4. greater than the 352.299 million years.

Explanation:

Given

Uranium 235 ———— lead 207( zircon sample)

t= 0 100%. 0%

t= t. 71%. 29%

1)- half lives elapsed = n

(1/2)n = 0.71

By taking log and solving n = 0.494

No of half lives = 0.494

2) Calculating the age of the larva

- age of lava flow = half life of uranium 235 x n

= 713 x 0.494

= 352.299 million years

3)- The rock layers was created above this lava flow is of later occurrence so the age will be lower than that of the age of the lava flow so the age of rock over the lava flow will lower than the 352.299 million years it will be in between 0 years to 352.299 million years.

4)- The rock layers created underneath this lava flow is of earlier occurrence so its age is more than that of the age of the lava flow so the age of rock will more than the lava flow is greater than the 352.299 million years.

B. The astronomers think the earth was created as all of the other rock materials in our solar system, including the oldest meteorites. The oldest meteorites ever found on Earth contain nearly equal amounts of both Uranium-238 and Lead-206.

The number of half-lives of the uranium-235to lead-207 decay pair have elapsed in the zircon crystals is; 0.494

We are given;

The atoms of Uranium-235 and lead-207 which made up the zircon sample.

At t = 0; Uranium-235 is 100% while lead-207 is 0%

At t = t;  Uranium-235 is 71% while lead-207 is 29%

1) Let the half lives that elapsed be n. Thus;

(¹/₂)ⁿ = 0.71

n*log0.5 = log 0.71

n = (log 0.71)/(log 0.5)

n = 0.494

Thus;

Number of half lives = 0.494

2) Formula to get the absolute age of the larva is;

Absolute age age of lava flow = half life of uranium-235 * n

The half life of uranium-235 is 713 million years. Thus;

Absolute age age of lava flow  = 713 * 0.494

Absolute age of lava flow = 352.22 million years

3) The rock layers above the lava flow were created after the lava flow and so the age will be lower than that of the age of the lava flow. Thus, it's age will be between 0 years and 352.299 million years.

4) A: The rock layers beneath the lava flow were in existence earlier than the lava flow and as such, the age of rock layers beneath the lava flow will be greater than 352.22 million years.

B; The astronomers think the earth was created as all of the other rock materials in our solar system.

Read more about Half life at; https://brainly.com/question/26148784

Answer: Because of the role the base region play in the transistor.

Explanation:

The base region of BJT transistor - an opposite polarity charge carrier from emitter region to collector region, plays a vital role in triggering for a sufficient emiter - to - collector current.

The current received by the base region of BJT determines the effect of the continue flow of current into the collector region which will eventually determine the output current.

Answer:

The meole fraction of acetone in the outlet liquid is [tex]x_1 = 0.0072[/tex]

Explanation:

1.

The schematic diagram to represent this process is shown in the diagram attached below:

2.

the mole fraction of acetone in the outlet liquid is determined as follows:

solute from Basis Gas flow rate [tex]G_s = 10(1-0.012) =9.88 kmol/hr[/tex]

Let the entering mole be :[tex]y_1 = 1.2[/tex] % = 0.012

[tex]y_1 =(\dfrac{y_1}{1-y_1})[/tex]

[tex]y_1 =(\dfrac{0.012}{1-0.012})[/tex]

[tex]y_1 =0.012[/tex]

Let the outlet gas concentration be [tex]y_2[/tex] = 0.1% = 0.001

[tex]y_2 = 0.001[/tex]

Thus; the mole fraction of acetone in the outlet liquid is:

[tex]G_s y_1 + L_s x_2 = y_2 L_y + L_s x_1[/tex]

[tex]9.88(0.012-0.001)=15*x_1[/tex]

[tex]9.88(0.011) = 15x_1[/tex]

[tex]x_1 = \dfrac{0.10868}{15}[/tex]

[tex]x_1 = 0.0072[/tex]

The mole fraction of acetone in the outlet liquid is [tex]x_1 = 0.0072[/tex]

Answer:

The answer is "26.55 V"

Explanation:

Given values:

[tex]d_i= 0.96m\\d_o= 1m\\\epsilon = 0.05\\T_0= 280k\\T_i= 95k\\[/tex]

For Answer  (a) please find the attachment.

Answer (b):

[tex]q_{i-0}= \frac{\sigma (T_{0}^4)-(T_{i}^4)}{\frac{1-\epsilon i }{\epsilon_{i} A_{i}}+ \frac{1 }{\ f_{i o} A_{i}} +\frac{1-\epsilon_{0}}{\epsilon_{0} A_{0}}}[/tex]

[tex]f_{i0}= 1 \ it \ is \ fully \ inside \ the \ large \ sphero \\[/tex]

[tex]q_{i-0}= \frac{\sigma A_i (T_{0}^4)-(T_{i}^4)}{\frac{1 }{\epsilon_{i}} - 1+ 1 +\frac{1-\epsilon_{0}}{\epsilon_{0}} \times \frac{A_i}{A_0}}\\\\q_{i-0}= \frac{\sigma A_i (T_{0}^4)-(T_{i}^4)}{\frac{1 }{\epsilon_{i}} +\frac{1-\epsilon_{0}}{\epsilon_{0}} \times (\frac{d_i}{d_0})^2}\\\\q_{i-0}= \frac{\sigma (\pi d^2_i) (T_{0}^4)-(T_{i}^4)}{\frac{1 }{\epsilon_{i}} +\frac{1-\epsilon_{0}}{\epsilon_{0}} \times (\frac{r_i}{r_0})^2}\\\\[/tex]

[tex]q_{i-0}= \frac{5.67 \times 10^{-8} \times 3.14 \times 9.62 \times 9.62 \times (280^4-94^4)}{\frac{1 }{0.05} +\frac{1-0.05}{0.05} \times (\frac{0.96}{1})^2}\\\\\ After \ solve the \ equation \ the \ answer \ is:\\\\q_{i-0} = 26.55 \ V[/tex]