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4 years ago

Write a short summary of the power of dreams

Engineering

1 answer:

slava [35]4 years ago

6 0

Answer:

The Power of a Dream

You don’t just think a dream. You feel it in your bones and in your heart.

Via Your Road Map for Success:

“I believe that each of us has a dream placed in the heart. I’m not talking about wanting to win the lottery. That kind of idea comes from a desire to escape our present circumstances, not to pursue a heartfelt dream. I’m talking about a vision deep inside that speaks to the very soul. It’s the thing we were born to do. It draws on our talents and gifts. It appeals to our highest ideals. It sparks our feelings of destiny. It is inseparably linked to our purpose in life. The dream starts us on the success journey.”

A Dream Gives Us Direction

Our dreams act as a compass and help us choose a path, among our many options. Dreams shape our choices that shape our way forward.

A Dream Helps Us Prioritize

Dreams help us weight our choices and make trade-offs based on what we truly value, and what really matters to us.

Via Your Road Map for Success:

“A dream gives us hope for the future, and it also brings us power in the present. It makes it possible for us to prioritize everything we do. A person who has a dream knows what he is willing to give up in order to go up. He is able to measure everything he does according to whether or not it contributes to the dream, concentrating his attention on the things that bring him closer to it and giving less attention to everything that doesn’t.”

A Dream Adds Value to Our Work

The same job takes on new meaning when we add emotion and add vision and bring our dreams to life.

Via Your Road Map for Success:

“A dream puts everything we do into perspective. Even the tasks that aren’t exciting or immediately rewarding take on added value when we know they ultimately contribute to the fulfillment of a dream. each activity becomes an important piece in that bigger picture.

It reminds me of the story of a reporter who talked to three construction workers pouring concrete at a building site, ‘What are you doing?’ he asked the first worker, ‘I’m earning a paycheck he grumbled.’

The reporter asked the same question of a second laborer, who looked over his shoulder and said, ‘What’s it look like I’m doing? I’m pouring concrete.’

Then he noticed a third man who was smiling and whistling as he worked. ‘What are you doing/’ he asked the third worker.

He stopped what he was doing and said excitedly, ‘I’m building a shelter for the homeless.‘ He wiped his hands clean on a rag and then pointed, ‘Look, over there is where the kitchen will be. And that over there is the women’s dormitory. This here …’

A Dream Predicts Our Future

We create our future by chasing our dreams, and it’s what we become in the pursuit of our dreams, that makes the journey worth it.

Dare to Act on Your Dreams

Don’t let your dreams sit on the shelf. Live them. Breathe them. Be that change you always wanted.

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3 years ago

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A Rankine steam power plant is considered. Saturated water vapor enters a turbine at 8 MPa and exits at condenser at 10 kPa. The

Ray Of Light [21]

Answer:

0.31

126.23 kg/s

Explanation:

Given:-

- Fluid: Water

- Turbine: P3 = 8MPa , P4 = 10 KPa , nt = 85%

- Pump: Isentropic

- Net cycle-work output, Wnet = 100 MW

Find:-

- The thermal efficiency of the cycle

- The mass flow rate of steam

Solution:-

- The best way to deal with questions related to power cycles is to determine the process and write down the requisite properties of the fluid at each state.

First process: Isentropic compression by pump

P1 = P4 = 10 KPa ( condenser and pump inlet is usually equal )

h1 = h-P1 = 191.81 KJ/kg ( saturated liquid assumption )

s1 = s-P1 = 0.6492 KJ/kg.K

v1 = v-P1 = 0.001010 m^3 / kg

P2 = P3 = 8 MPa( Boiler pressure - Turbine inlet )

s2 = s1 = 0.6492 KJ/kg.K .... ( compressed liquid )

- To determine the ( h2 ) at state point 2 : Pump exit. We need to determine the wok-done by pump on the water ( Wp ). So from work-done principle we have:

$w_p = v_1*( P_2 - P_1 )\\\\w_p = 0.001010*( 8000 - 10 )\\\\w_p = 8.0699 \frac{KJ}{kg}$

- From the following relation we can determine ( h2 ) as follows:

h2 = h1 + wp

h2 = 191.81 + 8.0699

h2 = 199.88 KJ/kg

Second Process: Boiler supplies heat to the fluid and vaporize

- We have already evaluated the inlet fluid properties to the boiler ( pump exit property ).

- To determine the exit property of the fluid when the fluid is vaporized to steam in boiler ( super-heated phase ).

P3 = 8 MPa

T3 = ? ( assume fluid exist in the saturated vapor phase )

h3 = hg-P3 = 2758.7 KJ/kg

s3 = sg-P3 = 5.7450 KJ/kg.K

- The amount of heat supplied by the boiler per kg of fluid to the water stream. ( qs ) is determined using the state points 2 and 3 as follows:

$q_s = h_3 - h_2\\\\q_s = 2758.7 -199.88\\\\q_s = 2558.82 \frac{KJ}{kg}$

Third Process: The expansion ( actual case ). Turbine isentropic efficiency ( nt ).

- The saturated vapor steam is expanded by the turbine to the condenser pressure. The turbine inlet pressure conditions are similar to the boiler conditions.

- Under the isentropic conditions the steam exits the turbine at the following conditions:

P4 = 10 KPa

s4 = s3 = 5.7450 KJ/kg.K ... ( liquid - vapor mixture phase )

- Compute the quality of the mixture at condenser inlet by the following relation:

$x = \frac{s_4 - s_f}{s_f_g} \\\\x = \frac{5.745- 0.6492}{7.4996} \\\\x = 0.67947$

- Determine the isentropic ( h4s ) at this state as follows:

$h_4_s = h_f + x*h_f_g\\\\h_4_s = 191.81 + 0.67947*2392.1\\\\h_4_s = 1817.170187 \frac{KJ}{kg}$

- Since, we know that the turbine is not 100% isentropic. We will use the working efficiency and determine the actual ( h4 ) at the condenser inlet state:

$h4 = h_3 - n_t*(h_3 - h_4_s ) \\\\h4 = 2758.7 - 0.85*(2758.7 - 181.170187 ) \\\\h4 = 1958.39965 \frac{KJ}{kg} \\$

- We can now compute the work-produced ( wt ) due to the expansion of steam in turbine.

$w_t = h_3 - h_4\\\\w_t = 2758.7-1958.39965\\\\w_t = 800.30034 \frac{KJ}{kg}$

- The net power out-put from the plant is derived from the net work produced by the compression and expansion process in pump and turbine, respectively.

$W_n_e_t = flow(m) * ( w_t - w_p )\\\\flow ( m ) = \frac{W_n_e_t}{w_t - w_p} \\\\flow ( m ) = \frac{100000}{800.30034-8.0699} \\\\flow ( m ) = 126.23 \frac{kg}{s}$

Answer: The mass flow rate of the steam would be 126.23 kg/s

- The thermal efficiency of the cycle ( nth ) is defined as the ratio of net work produced by the cycle ( Wnet ) and the heat supplied by the boiler to the water ( Qs ):

$n_t_h = \frac{W_n_e_t}{flow(m)*q_s} \\\\n_t_h = \frac{100000}{126.23*2558.82} \\\\n_t_h = 0.31$