16:31

Example 3.6 Heat Loss Through Composite Wall | Thermal Resistance Method | Heat Transfer Problem Sol

20:50

Solved: Composite Wall Conduction | Cengel Heat Transfer Problem | 1-D Steady Heat Flow

09:14

Tricky Round Table Puzzle Explained | Seating Arrangement for Aptitude Exams

20:51

Who Gets the Interview When? Scheduling Puzzle | HAT, NTS, GAT, GRE, SSC, UPSC, MDCAT, ETEA

14:26

Basketball Lesson Scheduling Puzzle | Logical Reasoning Question Solved Step by Step

13:38

Seating & Ordering Puzzle Solved | Must Practice for Competitive Exams

10:15

Police Line-Up Puzzle | Logical Reasoning Question with Solution | Competitive Exams

10:30

Regenerative Brayton Cycle Solved | Problem 9-105 | Heat Addition & Rejection | Cengel Thermo 9th Ed

11:40

Age Puzzle | Logical Reasoning Question No.4 Solved Step by Step | Must Watch for Competitive Exams

09:19

Ordering and Grouping Lecture 3 important for all competitive exam

06:50

Brayton Cycle Problem 9-93 | 500 kW Heat Input | Thermal Efficiency & Power Output

05:18

Brayton Cycle Problem 9-88 Solved | Net Work & Thermal Efficiency | Cengel Thermodynamics 9th Ed

12:59

Analytical Reasoning 2 Puzzle | Must Solve for Competitive Exams | HAT, NTS, GAT, GRE, SSC,UPSC,ETEA

20:32

Lecture 1 Analytical Reasoning Puzzle for Competitive Exams | HAT, NTS, GAT, GRE, UPSC, MDCAT, ETEA

08:58

Brayton Cycle Problem 9-86 Solved | Mass Flow Rate for 32 MW Output | Cengel Thermodynamics 9th Ed

10:38

Brayton Cycle Problem Solved | Cengel Thermodynamics 9th | Power Output, Mass Flow Rate, Efficiency

08:20

Solved: Diesel Cycle Problem | to Find Compression Ratio 16, Cutoff Ratio 2 | Cengel 9th Edition

11:34

Otto Cycle Problem 9.38 Solved | Find Thermal Efficiency, Net Work, MEP | Cengel Thermodynamics 9th

04:24

Problem 3.15 A refrigerant is dry saturated at 2 bar and is compressed reversibly in a cylinder

06:59

Problem 3.14 Using the refrigerant properties given in Table Calculate n, Work input and Heat (Q)

05:47

Problem 3.12 from book applied thermodynamics for engineer and technologists Td Eastop and McConkey

05:07

Problem 3.9 if the initial volume occupied was 0.03m3 .calculate the work input

03:10

Problem 3.8 Calculate the final temperature and the work input

02:44

Problem 3.7 Calculate the work input and the heat supplied.

05:23

Problem 3.6 calculate the change of internal energy per unit mass of steam.

02:08

Problem 3.5 Calculate the heat supplied.

03:54

Problem 3.11 Calculate the work done on the air and the heat supplied during the compression

05:23

Problem 3.4 Calculate the final temperature and the work input.

04:35

Problem 3.3 Calculate the work input and the heat supplied during the expansion

10:07

Problem 5.9 Calculate the maximum cycle temperature when the cycle efficiency is 60%.

04:35

Problem 3.2 Calculate the mass of steam in the vessel, the final pressure of the steam

03:00

Problem 3.1 The container is heated until temperature is 200°C. Calculate pressure of air finally.

05:36

Example 3.8 A gas turbine receives gases from the combustion chamber at 7 bar and 650C.

08:46

Example 3.7 Calculate the heat flow to or from the cylinder walls:

06:21

Example 3.5 Calculate final temperature, the final volume and work done on mass of air in cylinder.

05:42

Example 3.4 Calculate the work done

04:18

Example 3.3 Calculate the work done and the heat flow during the process.

10:46

Example 3.2 Calculate the mass of steam in the vessel, the final pressure of the steam

09:18

example 3.1 Calculate the work done and the heat flow during the process

05:16

Problem 2.12 quantity of a certain perfect gas is compressed from an initial state of 0.085m3.

04:37

Problem 2.11 Calculate temperature of the air at outlet and the increase of internal energy per kg

03:51

Problem 2.10 Calculate Cp, Cv γ and the molar mass of the gas.

04:43

Problem 2.9 At what temperature must the plug melt to limit the pressure in the vessel to 240 bar?

05:46

Problem 2.8 alculate the internal energy and enthalpy of 1 kg of air new volume occupied

02:48

Problem 2.7 calculate the specific gas constant, R, and the specific heat capacities at Cp, and Cv.

04:27

Problem 2.3 Steam at 7 bar and 250 C enters a pipeline and flows along it at constant pressure

11:03

2.4 Analysis of Steam Cooling in a Rigid Vessel Determination of Dryness Fraction and Heat Rejection

03:28

Problem 2.2 Calculate the mass of steam in the vessel and the enthalpy of this mass

09:55

Example 2.11 A perfect gas has a molar mass of 26 kg/kmol and a value of γ = 1.26 find heat rejected

02:16

Example 2.10 A certain perfect gas has specific heat capacities as follows:

03:46

Example 2.9 Calculate: (i) the molar mass of the gas: (ii) the final temperature.

04:59

Example 2.8 calculate the new pressure when the vessel has returned to its initial temperature

05:12

Example 2.4 team at 150 bar has a specific enthalpy of 3309 kJ/kg. Calculate the temperature

04:39

Example 2.3 Steam at 110 bar has a specific volume of 0.0196 m3/kg, calculate the temperature

04:24

Example 2.2 Calculate dryness fraction, specific volume and internal energy of steam at 7 bar

03:18

Example 2.1 Calculate specific volume, specific enthalpy, and specific internal energy of wet steam

04:00

Problem 11.31 determine the power required to tow this submarine in air and water

04:53

Example 11.27 determine the bending moment at the bottom of its pole

06:37

Problem 1.14 A nozzle is a device for increasing the velocity of a steadily flowing fluid.

08:52

Problem 1.13 A turbine operating under steady-flow conditions receives steam at the following state