discuss 7 habits of highly effective people and how important are ethics in today's society​

Answer:

6282 kJ

Explanation:

Given that:

The mass (m) = 15 kg

The specific latent heat of ice fusion [tex]h_{fg}_{ice}[/tex] = 335 kJ/kg

The specific heat capacity of water = 4.19 kJ/kg.c

The initial temperature of the ice [tex]T_i[/tex]= 0° C

The final temperature of the water [tex]T_f[/tex] = 20° C

To find the needed amount of heat to convert 0° C ice to 20° C of water.

To do that, we need to find the latent heat required for the phase change from 0° C ice to 0° C water, then the heat required to convert  0° C water to 20° C water.

Heat required = [tex]m \times h_{fg}_{ice}+ m \times c_{water} \times \Delta T[/tex]

Heat required = (15 × 335) + (15 × 4.19) × (20 - 0)

Heat required = 5025 + 62.85 × 20

Heat required = 5025 + 1257

Heat required = 6282 kJ

Answer:

a. The inlet temperature is approximately 305.232 K

b. The inlet pressure is approximately 452.0108 kPa

c. The area ratio between the inlet and exit is approximately 2.2509

Explanation:

a. From the energy equation related to the question, we have;

[tex]C_p \cdot (T_i - T_e) = \dfrac{1}{2} \cdot \left (v_e^2 - v_1^2 \right)[/tex]

Where;

[tex]C_p[/tex] = The specific heat capacity for helium = 5.913 kJ/(kg·K)

[tex]T_i[/tex] = The inlet temperature

[tex]T_e[/tex] = The exit temperature = 300 K

[tex]v_i[/tex] = The inlet velocity = 25 m/s

[tex]v_e[/tex] = The exit velocity = 250 m/s

Therefore, we have;

[tex]T_i= \dfrac{ \dfrac{1}{2} \cdot \left (v_e^2 - v_1^2 \right)}{C_p} + T_e = \dfrac{ \dfrac{1}{2} \times \left (250^2 - 25^2 \right)}{5.913 \times 1000} + 300 \approx 305.232[/tex]

The inlet temperature = [tex]T_i[/tex] ≈ 305.232 K

b. From the following equation for the critical pressure, for helium, we have;

[tex]\dfrac{P_c}{P_i} = \left (\dfrac{2}{n + 1} \right ) ^{\dfrac{n}{n - 1} } = 0.487[/tex]

Where;

[tex]P_c[/tex] = The critical pressure = 2.26 atm for helim

[tex]P_i[/tex] = The inlet pressure

n = The polytropic constant

We have;

[tex]\dfrac{2.26 \ atm}{P_i} = 0.487[/tex]

[tex]\therefore P_i = \dfrac{2.26 \ atm}{0.487} \approx 4.641 \ atm[/tex]

The inlet pressure, [tex]P_i[/tex] ≈ 4.641 atm ≈ 452.0108 kPa

c. The inlet to exit pressure ratio is given as follows;

[tex]P_e = \dfrac{A_i \times T_e \times v_i}{A_e \times T_i \times v_e} \times P_i[/tex]

Therefore, we have;

[tex]\dfrac{A_i}{A_e} = \dfrac{P_e \times T_i \times v_e}{ T_e \times v_i \times P_i} = \dfrac{100 \times 305.232 \times 250}{ 300 \times 25 \times 452.0108} = 2.2509[/tex]

The area ratio between the inlet and exit, [tex]A_i/A_e[/tex] ≈ 2.2509.

Answer:

10 m

Explanation:

The Soil Cohesion is the force that holds together molecules or like particles within a soil.

The unit weight of a soil mass is the ratio of the total weight of soil to the total volume of soil.

The stability number (Sn) is given by the formula:

[tex]S_n=\frac{C_m}{\gamma *H}[/tex]

Given that:

Cohesion = C = 15 kN/m², Factor of safety = FOS = 1.5, unit weight = γ = 20 kN/m³, H = maximum height, Sn = 0.05. Hence:

[tex]C_m=\frac{C}{FOS}\\\\S_n=\frac{C}{\gamma *FOS *H}\\\\H= \frac{C}{\gamma *FOS *S_n}\\\\Substituting:\\\\H=\frac{15}{20*1.5*0.05} \\\\H=10\ m[/tex]

This question is incomplete, the complete question is;

Determine the design moment strength (ϕMn) for a W21x73 steel beam with a simple span of 18 ft when lateral bracing for the compression flange is provided at the ends only (i.e., Lb = 18 ft). Report the result in kip-ft.

Use Fy=50 ksi and assume Cb=1.0 (if needed).

Answer: the design moment strength for the W21x73 steel beam is 566.25 f-ft

Explanation:

Given that;

section  W 21 x 73 steel beam;

now from the steel table table for this section;

Zx = Sx = 151 in³

also given that; fy = 50 ksi and Cb = 1.0

QMn = 0.9 × Fy × Zx

so we substitute

QMn = 0.9 × 50 × 151

QMn = 6795 k-inch

we know that;

12inch equals 1 foot

so

QMn = 6795 k-inch / 12

QMn = 566.25 f-ft

Therefore the design moment strength for the W21x73 steel beam is 566.25 f-ft

Answer:

need more information about the question

Answer:

The Process of printing

Explanation:

hope this helps :)

Answer:

a

Explanation:

Answer:

A. Ability to correct system maintenance issues

Explanation:

As a systems engineer, you will be responsible for a range of tasks, including management of IT systems, working with software developers to design and document new system architecture, and testing and implementing processes to improve the efficacy of existing systems.

Answer:

The appropriate response will be "125.55 kg/hr".

Explanation:

The given values are:

Rate of heat exchanger,

m = 1000 kg/h

Inlet temperature,

T = 30°C

Specific heat,

[tex]c_p[/tex] = 4 kJ/(kg°C)

Now,

The heat taken by juice from steam will be:

⇒ [tex]Q=mc_p(\Delta T)[/tex]

On substituting the values, we get

⇒     [tex]=1000\times 4(100-30)[/tex]

⇒     [tex]=280000 \ kJ/hr[/tex]

The heat given by the steam to juice will be:

⇒ [tex]Q=m\times L[/tex]

On substituting the values, we get

⇒     [tex]=m\times 125.55[/tex]

On equating both the heat values, we get

⇒ [tex]280000=m\times 2230.2[/tex]

⇒         [tex]m=\frac{280000}{2230.2}[/tex]

⇒         [tex]m=125.55 kg/hr[/tex]

In order to avoid slipping in the shop, your footwear should have proper tread. The correct option is D.

Slipping is an action of falling or sliding down due to a lack of friction between the surfaces. This occurs when both surfaces coming into contact are smooth or frictionless.

During rainy seasons, due to rain everywhere the chances of slipping increase, the slippers slip on mud or water. Vehicles also slip down on roads.

To avoid slipping, wear proper shoes. The shoes that have a good grip are less to slip. The tires are given with tread, which increases the grip on the road. Tread-on shoes or slippers are also good. Wear tread full shoes. It can avoid slipping and accidents.

Thus, the correct option is D. Have proper tread.

To learn more about slipping, refer to the link:

https://brainly.com/question/6327886

#SPJ2

Answer:

No.

Explanation:

[tex]P_r[/tex] = Power rating = 1 W

R = Resistance = [tex]350\ \Omega[/tex]

V = Voltage = [tex]24\ \text{V}[/tex]

Power is given by

[tex]P=\dfrac{V^2}{R}\\\Rightarrow P=\dfrac{24^2}{350}\\\Rightarrow P=1.65\ \text{W}[/tex]

[tex]1.65\ \text{W}>1\ \text{W}[/tex]

So

[tex]P>P_r[/tex]

Hence, the resistor is not operating within its power rating.

Answer:

A gas stream and other points are discussed below in details.

Explanation:

The method flow chart is displayed above.

B)Mole fraction of H2 in stream C=25%=0.25

Mole fraction of N2 in steams C=1-Mole fraction of H2=1-0.25=0.75

Average molecular weight of stream C=Mole fraction of H2*Molecular weight of H2+ Mole fraction of N2*Molecular weight of N2=0.25*2 kg/kmol+0.75*28 kg/kmol=21.5 kg/kmol

C) Mass flow rate of product C=100 kg/h

Molar flow rate of product C=Mass flow rate /Molecular weight=100 kg/h/21.5 kg/kmol=4.6512 kmol/h

D) Apply overall mole balance

Mole in=Mole out

Mole in=Mole of A+Mole of B=A+B

Let mole of A=A kmol/h

Mole of B=B kmol/h

Mole out=Mole of C stream=4.6512 kmol/h

A+B=4.6512 eq.1

Apply hydrogen mole balance

Mole of H2 in=Mole of H2 in A stream+ Mole of H2 in B stream=0.15 A+0.4 B

Mole of H2 out=Mole of H2 in C stream=0.25*4.6512=1.1628 kmol/h

1.1628 =0.15 A+0.4 B eq.2

Multiply eq.1 by 0.15

0.69768=0.15 A+0.15 B eq.3

Subtract eq.3 from eq.2

0.25 B=0.46512

B=1.86048 kmol/h

Substitute in eq1.

A=4.6512-1.86048=2.79042 kmol/h

Molar flow rate of A=2.79042 kmol/h

A molar flow rate of B=1.86048 kmol/h

Explanation:

1. Ensure all circuits are de-energized before beginning work (29 CFR 1926.416(a)(3)).

2. Controls to be deactivated during the course of work on energized or de-energized

equipment or circuits must be tagged (29 CFR 1926.417(a)).

3. Employees must be instructed to recognize and avoid unsafe conditions associated with

their work (29 CFR 1926.21(b)(2)).