Draw a particle model of heat transfer in a double walled thermos. thank you

a thermos bottle has the following features to control transfer of heat energy in and out:...

a thermos bottle has the following features to control transfer of heat energy in and out: a) a tight cover, b) a shiny metallic outside coating, and c) an air layer between the inside and outside surfaces. what function does each of these features serve in controlling heat energy transfer? Which of the heat transfer processes is most reduced by each design feature of the thermos

A thin-walled double pipe counter flow heat exchanger is to be used to cool oil (cp...

A thin-walled double pipe counter flow heat exchanger is to be used to cool oil (cp = 2200 j/kg*K) from 150 ℃ to 30 ℃ at a rate of 2.1 kg/s by water (cp= 4180 J/kg*K) that enters at 20 ℃ at a rate of 1.2 kg/s. The diameter of the tube is 2.5 cm, and its length is 10 m. Using Excel (a) Determine the overall heat transfer coefficient of this heat exchanger. (b) Investigate the effects of oil...

Write down the total heat transfer resistance for a double-pipe heat exchanger. Show how to convert...

Write down the total heat transfer resistance for a double-pipe heat exchanger. Show how to convert from the total resistance to an overall heat-transfer co-efficient and explain how flow regime may affect overall heat transfer rate.

Cold water leading to a shower enters a well-insulated, thin-walled, double-pipe, counterflow heat exchanger at 10C...

Cold water leading to a shower enters a well-insulated, thin-walled, double-pipe, counterflow heat exchanger at 10C at a rate of 1.15kg/s and is heated to 70C by hot water that enters at 85C at a rate of 1.6kg/s. Use data from the tables to Determine the rate of entropy generation in the heat exchanger. Answer in kW/K.

In a Dual cycle the heat transfer during the constant volume process is double that during...

In a Dual cycle the heat transfer during the constant volume process is double that during the constant pressure process. The compression ratio is 14 and the air initial conditions are 1 bar and 27oC. If the maximum pressure in the cycle is 60 bar, calculate: Maximum temperature Heat added at constant volume and constant pressure per kg of air Cycle thermal efficiency Net work per kg of air Exergy destroyed associated with the cycle. Assume the source temperature to...

Draw the sound spectrum of a typical chordophone. Thank you.

Draw the sound spectrum of a typical chordophone. Thank you.

This is a heat transfer course, please explain and show work neatly, and please do not...

This is a heat transfer course, please explain and show work neatly, and please do not copy from any other solutions because they are incorrect. Thank you so much in advance Consider atmospheric air at a velocity of V = 20 m/s and a temperature of T= 20C, in cross flow over 10 mm square tube at 45 degrees, maintained at 50C. Sketch Assumptions Calculate the air properties (show the interpolation steps) Re = ? Nu = ? (reference the...

Describe one unique application of the concepts you learned on steady-state heat transfer

Describe one unique application of the concepts you learned on steady-state heat transfer

Problem 2. (20 pts) You would like to know the heat transfer coefficient from a cooling...

Problem 2. (20 pts) You would like to know the heat transfer coefficient from a cooling fin operating under forced convection, but with a length of 1 cm the real fin is just too small to make any measurements. You make a 10x scale model and test it at the real operating temperatures and 1/10th the ambient airflow velocity. If your scale model has an h of 5.14 W/m2/K, what is the value of h for the real fin? In...

In the first lesson we talk about the heat transfer that takes place in the human...

In the first lesson we talk about the heat transfer that takes place in the human body, but the same types of transfer occur for any object. For the following question, use the dimensions and characteristics of your own home. It’s reasonable to assume that walls are thick enough to block direct heat loss to radiation (without prior conduction through the walls). Windows are relatively thin in comparison and conduct more heat than walls (i.e. a double-pane glazed window has...