Determine the heat transfer coefficient at the stagnation point and the average value of the heat transfer coefficient for a single 5-cm-OD, 60-cm-long tube in cross-flow. The temperature of the tube surface is 260°C , the velocity of the fluid flowing perpendicular to the tube axis is 6 m/s, and the temperature of the fluid is 38°C . Consider the following fluids: (a) air, (b) hydrogen, and (c) water.

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Answer 1

Textbook Question

Chapter 6, Problem 6.1P

Determine the heat transfer coefficient at the stagnation point and the average value of the heat transfer coefficient for a single 5-cm-OD, 60-cm-long tube in cross-flow. The temperature of the tube surface is 260°C , the velocity of the fluid flowing perpendicular to the tube axis is 6 m/s, and the temperature of the fluid is 38°C . Consider the following fluids: (a) air, (b) hydrogen, and (c) water.

(a)

Expert Solution

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with air as working fluid.

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=68.9 W/m2K.

Average heat-transfer co-efficient h¯=41.9 W/m2K.

Explanation of Solution

Given Information:

Outer diameter of the tube (D) = 5 cm = 0.05 m

Length of the tube (L) = 60 cm = 0.6 m

Temperature of the tube surface (T_s) = 260⁰C

Velocity of the fluid flowing perpendicular to the tube axis is (V) = 6 m/s

Temperature of the fluid is (T_f) = 38⁰C

Explanation:

For cylindrical surfaces having cross flow, local heat-transfer co-efficient at any angular portion θ, is given by,

Nu(θ)=1.14 [Re]0.5[Pr]0.4 [1−(θ90)3]

Heat transfer co-efficient at stagnation point (θ=0) , is given by ,

Nu(θ)=1.14 [Re]0.5[Pr]0.4

Reynolds number (Re)=VDϑ

Nusselt number (Nu)=hDk

hDk=1.14 [VDν]0.5[Pr]0.4

Heat transfer -coefficient at stagnation point is given by,

h=kD×1.14 [VDν]0.5[Pr]0.4 —— Equation(1)

For cross flow over cylindrical surfaces, average Nusselt number is given by:

Nu¯=C [Re]m[Pr]n [PrPrs]0.25

h¯Dk=C [VDν]m[Pr]n [PrPrs]0.25

Average convective heat-transfer co-efficient is given by,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25———-Equation (2)

From Appendix-2, Table -28, Properties of dry air at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 0.71

Thermal conductivity (k) = 0.0264 W/mK

Kinematic viscosity (ν)=17.4×10−6 m2/s

At surface temperature Prandtl number, Prs=0.71

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=0.02640.05×1.14 [6×0.0517.4×10−6]0.5[0.71]0.4

h=68.9 W/m2K

From Equation(2), average heat transfer co-efficient is,

Re=6×0.0517.4×10−6=17241.37

For Re =17241.37, C = 0.26, m = 0.6

For Pr <10, n = 0.37

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

h¯=0.0264 0.05×0.26×[6×0.0517.4×10−6]0.6[0.71]0.37 [0.710.71]0.25

h¯=41.9 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=68.9 W/m2K.

Average heat-transfer co-efficient h¯=41.9 W/m2K.

(b)

Expert Solution

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with hydrogen as working fluid.

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=184.36 W/m2K

Average heat-transfer co-efficient h¯=96.14 W/m2K

Explanation of Solution

From Appendix – 2, table-32, Properties of hydrogen at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 0.704

Thermal conductivity (k) = 0.187 W/mK

Kinematic viscosity (ν)=116.6×10−6 m2/s

At surface temperature Prandtl number, Prs=0.671

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=kD×1.14 [VDν]0.5[Pr]0.4

h=0.1870.05×1.14 [6×0.05116.6×10−6]0.5[0.671]0.4 =184.36 W/m2K

From Equation(2), average heat transfer co-efficient is,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

Re=6×0.05116.6×10−6=2573

From table 6.1, For Re =2573, C = 0.26, m = 0.6

For Pr < 10, n = 0.37

h¯=0.1870.05×(0.26) [2573]0.6[0.704]0.37 [0.7040.671]0.25

h¯=96.14 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=184.36 W/m2K

Average heat-transfer co-efficient h¯=96.14 W/m2K

(c)

Expert Solution

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with water as working fluid.

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=17231.51 W/m2K

Average heat-transfer co-efficient h¯=22432 W/m2K

Explanation of Solution

From Appendix – 2, table-13, Properties of water at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 4.5

Thermal conductivity (k) = 0.629 W/mK

Kinematic viscosity (ν)=0.685×10−6 m2/s

At surface temperature Prandtl number, Prs=0.86

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=kD×1.14 [VDν]0.5[Pr]0.4

h=0.6290.05×1.14 [6×0.050.685×10−6]0.5[4.5]0.4 =17231.51 W/m2K

From Equation(2), average heat transfer co-efficient is,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

Re=6×0.050.685×10−6=437956.2

From table 6.1, For Re = 437956.2, C = 0.076, m = 0.7

For Pr < 10, n = 0.37

h¯=0.6290.05×(0.076) [437956.2]0.7[4.5]0.37 [4.50.86]0.25

h¯=22432 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=17231.51 W/m2K

Average heat-transfer co-efficient h¯=22432 W/m2K

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Students have asked these similar questions

Engine oil flows at a rate of 0.05 kg/s through a section of a 2.5 cm diameter tube. The oil enters the section at a temperature of 50 C. The tube wall is kept at 20 C, and it can be assumed that the flow through the section is fully developed. The section of the tube is 5 m long. (a) What is the exit temperature of the oil? (b) What is the heat transfer rate from the oil to the tube wall?

Heat Transfer Questiion is image

Engine oil flows through a 50 mm diameter tube at an average temperature of147°C. The flow velocity is 80 cm/s. Calculate the average heat transfer coefficient if the tube wall is maintained at a temperature of 200°C and it is 2 m long. Hint: Area can be assumed to be equal to the vertical projectiion of the tube , i.e. LD. Ans.: h = 377.36 W/m2.K . Draw an illustration. Note: use the formula on the picture

Answer 2

Textbook Question

Chapter 6, Problem 6.1P

Determine the heat transfer coefficient at the stagnation point and the average value of the heat transfer coefficient for a single 5-cm-OD, 60-cm-long tube in cross-flow. The temperature of the tube surface is 260°C , the velocity of the fluid flowing perpendicular to the tube axis is 6 m/s, and the temperature of the fluid is 38°C . Consider the following fluids: (a) air, (b) hydrogen, and (c) water.

(a)

Expert Solution

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with air as working fluid.

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=68.9 W/m2K.

Average heat-transfer co-efficient h¯=41.9 W/m2K.

Explanation of Solution

Given Information:

Outer diameter of the tube (D) = 5 cm = 0.05 m

Length of the tube (L) = 60 cm = 0.6 m

Temperature of the tube surface (T_s) = 260⁰C

Velocity of the fluid flowing perpendicular to the tube axis is (V) = 6 m/s

Temperature of the fluid is (T_f) = 38⁰C

Explanation:

For cylindrical surfaces having cross flow, local heat-transfer co-efficient at any angular portion θ, is given by,

Nu(θ)=1.14 [Re]0.5[Pr]0.4 [1−(θ90)3]

Heat transfer co-efficient at stagnation point (θ=0) , is given by ,

Nu(θ)=1.14 [Re]0.5[Pr]0.4

Reynolds number (Re)=VDϑ

Nusselt number (Nu)=hDk

hDk=1.14 [VDν]0.5[Pr]0.4

Heat transfer -coefficient at stagnation point is given by,

h=kD×1.14 [VDν]0.5[Pr]0.4 —— Equation(1)

For cross flow over cylindrical surfaces, average Nusselt number is given by:

Nu¯=C [Re]m[Pr]n [PrPrs]0.25

h¯Dk=C [VDν]m[Pr]n [PrPrs]0.25

Average convective heat-transfer co-efficient is given by,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25———-Equation (2)

From Appendix-2, Table -28, Properties of dry air at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 0.71

Thermal conductivity (k) = 0.0264 W/mK

Kinematic viscosity (ν)=17.4×10−6 m2/s

At surface temperature Prandtl number, Prs=0.71

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=0.02640.05×1.14 [6×0.0517.4×10−6]0.5[0.71]0.4

h=68.9 W/m2K

From Equation(2), average heat transfer co-efficient is,

Re=6×0.0517.4×10−6=17241.37

For Re =17241.37, C = 0.26, m = 0.6

For Pr <10, n = 0.37

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

h¯=0.0264 0.05×0.26×[6×0.0517.4×10−6]0.6[0.71]0.37 [0.710.71]0.25

h¯=41.9 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=68.9 W/m2K.

Average heat-transfer co-efficient h¯=41.9 W/m2K.

(b)

Expert Solution

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with hydrogen as working fluid.

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=184.36 W/m2K

Average heat-transfer co-efficient h¯=96.14 W/m2K

Explanation of Solution

From Appendix – 2, table-32, Properties of hydrogen at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 0.704

Thermal conductivity (k) = 0.187 W/mK

Kinematic viscosity (ν)=116.6×10−6 m2/s

At surface temperature Prandtl number, Prs=0.671

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=kD×1.14 [VDν]0.5[Pr]0.4

h=0.1870.05×1.14 [6×0.05116.6×10−6]0.5[0.671]0.4 =184.36 W/m2K

From Equation(2), average heat transfer co-efficient is,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

Re=6×0.05116.6×10−6=2573

From table 6.1, For Re =2573, C = 0.26, m = 0.6

For Pr < 10, n = 0.37

h¯=0.1870.05×(0.26) [2573]0.6[0.704]0.37 [0.7040.671]0.25

h¯=96.14 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=184.36 W/m2K

Average heat-transfer co-efficient h¯=96.14 W/m2K

(c)

Expert Solution

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with water as working fluid.

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=17231.51 W/m2K

Average heat-transfer co-efficient h¯=22432 W/m2K

Explanation of Solution

From Appendix – 2, table-13, Properties of water at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 4.5

Thermal conductivity (k) = 0.629 W/mK

Kinematic viscosity (ν)=0.685×10−6 m2/s

At surface temperature Prandtl number, Prs=0.86

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=kD×1.14 [VDν]0.5[Pr]0.4

h=0.6290.05×1.14 [6×0.050.685×10−6]0.5[4.5]0.4 =17231.51 W/m2K

From Equation(2), average heat transfer co-efficient is,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

Re=6×0.050.685×10−6=437956.2

From table 6.1, For Re = 437956.2, C = 0.076, m = 0.7

For Pr < 10, n = 0.37

h¯=0.6290.05×(0.076) [437956.2]0.7[4.5]0.37 [4.50.86]0.25

h¯=22432 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=17231.51 W/m2K

Average heat-transfer co-efficient h¯=22432 W/m2K

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Answer 3

Textbook Question

Chapter 6, Problem 6.1P

Determine the heat transfer coefficient at the stagnation point and the average value of the heat transfer coefficient for a single 5-cm-OD, 60-cm-long tube in cross-flow. The temperature of the tube surface is 260°C , the velocity of the fluid flowing perpendicular to the tube axis is 6 m/s, and the temperature of the fluid is 38°C . Consider the following fluids: (a) air, (b) hydrogen, and (c) water.

(a)

Expert Solution

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with air as working fluid.

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=68.9 W/m2K.

Average heat-transfer co-efficient h¯=41.9 W/m2K.

Explanation of Solution

Given Information:

Outer diameter of the tube (D) = 5 cm = 0.05 m

Length of the tube (L) = 60 cm = 0.6 m

Temperature of the tube surface (T_s) = 260⁰C

Velocity of the fluid flowing perpendicular to the tube axis is (V) = 6 m/s

Temperature of the fluid is (T_f) = 38⁰C

Explanation:

For cylindrical surfaces having cross flow, local heat-transfer co-efficient at any angular portion θ, is given by,

Nu(θ)=1.14 [Re]0.5[Pr]0.4 [1−(θ90)3]

Heat transfer co-efficient at stagnation point (θ=0) , is given by ,

Nu(θ)=1.14 [Re]0.5[Pr]0.4

Reynolds number (Re)=VDϑ

Nusselt number (Nu)=hDk

hDk=1.14 [VDν]0.5[Pr]0.4

Heat transfer -coefficient at stagnation point is given by,

h=kD×1.14 [VDν]0.5[Pr]0.4 —— Equation(1)

For cross flow over cylindrical surfaces, average Nusselt number is given by:

Nu¯=C [Re]m[Pr]n [PrPrs]0.25

h¯Dk=C [VDν]m[Pr]n [PrPrs]0.25

Average convective heat-transfer co-efficient is given by,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25———-Equation (2)

From Appendix-2, Table -28, Properties of dry air at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 0.71

Thermal conductivity (k) = 0.0264 W/mK

Kinematic viscosity (ν)=17.4×10−6 m2/s

At surface temperature Prandtl number, Prs=0.71

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=0.02640.05×1.14 [6×0.0517.4×10−6]0.5[0.71]0.4

h=68.9 W/m2K

From Equation(2), average heat transfer co-efficient is,

Re=6×0.0517.4×10−6=17241.37

For Re =17241.37, C = 0.26, m = 0.6

For Pr <10, n = 0.37

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

h¯=0.0264 0.05×0.26×[6×0.0517.4×10−6]0.6[0.71]0.37 [0.710.71]0.25

h¯=41.9 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=68.9 W/m2K.

Average heat-transfer co-efficient h¯=41.9 W/m2K.

(b)

Expert Solution

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with hydrogen as working fluid.

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=184.36 W/m2K

Average heat-transfer co-efficient h¯=96.14 W/m2K

Explanation of Solution

From Appendix – 2, table-32, Properties of hydrogen at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 0.704

Thermal conductivity (k) = 0.187 W/mK

Kinematic viscosity (ν)=116.6×10−6 m2/s

At surface temperature Prandtl number, Prs=0.671

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=kD×1.14 [VDν]0.5[Pr]0.4

h=0.1870.05×1.14 [6×0.05116.6×10−6]0.5[0.671]0.4 =184.36 W/m2K

From Equation(2), average heat transfer co-efficient is,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

Re=6×0.05116.6×10−6=2573

From table 6.1, For Re =2573, C = 0.26, m = 0.6

For Pr < 10, n = 0.37

h¯=0.1870.05×(0.26) [2573]0.6[0.704]0.37 [0.7040.671]0.25

h¯=96.14 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=184.36 W/m2K

Average heat-transfer co-efficient h¯=96.14 W/m2K

(c)

Expert Solution

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with water as working fluid.

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=17231.51 W/m2K

Average heat-transfer co-efficient h¯=22432 W/m2K

Explanation of Solution

From Appendix – 2, table-13, Properties of water at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 4.5

Thermal conductivity (k) = 0.629 W/mK

Kinematic viscosity (ν)=0.685×10−6 m2/s

At surface temperature Prandtl number, Prs=0.86

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=kD×1.14 [VDν]0.5[Pr]0.4

h=0.6290.05×1.14 [6×0.050.685×10−6]0.5[4.5]0.4 =17231.51 W/m2K

From Equation(2), average heat transfer co-efficient is,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

Re=6×0.050.685×10−6=437956.2

From table 6.1, For Re = 437956.2, C = 0.076, m = 0.7

For Pr < 10, n = 0.37

h¯=0.6290.05×(0.076) [437956.2]0.7[4.5]0.37 [4.50.86]0.25

h¯=22432 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=17231.51 W/m2K

Average heat-transfer co-efficient h¯=22432 W/m2K

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Answer 4

Textbook Question

Chapter 6, Problem 6.1P

Determine the heat transfer coefficient at the stagnation point and the average value of the heat transfer coefficient for a single 5-cm-OD, 60-cm-long tube in cross-flow. The temperature of the tube surface is 260°C , the velocity of the fluid flowing perpendicular to the tube axis is 6 m/s, and the temperature of the fluid is 38°C . Consider the following fluids: (a) air, (b) hydrogen, and (c) water.

(a)

Expert Solution

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with air as working fluid.

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=68.9 W/m2K.

Average heat-transfer co-efficient h¯=41.9 W/m2K.

Explanation of Solution

Given Information:

Outer diameter of the tube (D) = 5 cm = 0.05 m

Length of the tube (L) = 60 cm = 0.6 m

Temperature of the tube surface (T_s) = 260⁰C

Velocity of the fluid flowing perpendicular to the tube axis is (V) = 6 m/s

Temperature of the fluid is (T_f) = 38⁰C

Explanation:

For cylindrical surfaces having cross flow, local heat-transfer co-efficient at any angular portion θ, is given by,

Nu(θ)=1.14 [Re]0.5[Pr]0.4 [1−(θ90)3]

Heat transfer co-efficient at stagnation point (θ=0) , is given by ,

Nu(θ)=1.14 [Re]0.5[Pr]0.4

Reynolds number (Re)=VDϑ

Nusselt number (Nu)=hDk

hDk=1.14 [VDν]0.5[Pr]0.4

Heat transfer -coefficient at stagnation point is given by,

h=kD×1.14 [VDν]0.5[Pr]0.4 —— Equation(1)

For cross flow over cylindrical surfaces, average Nusselt number is given by:

Nu¯=C [Re]m[Pr]n [PrPrs]0.25

h¯Dk=C [VDν]m[Pr]n [PrPrs]0.25

Average convective heat-transfer co-efficient is given by,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25———-Equation (2)

From Appendix-2, Table -28, Properties of dry air at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 0.71

Thermal conductivity (k) = 0.0264 W/mK

Kinematic viscosity (ν)=17.4×10−6 m2/s

At surface temperature Prandtl number, Prs=0.71

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=0.02640.05×1.14 [6×0.0517.4×10−6]0.5[0.71]0.4

h=68.9 W/m2K

From Equation(2), average heat transfer co-efficient is,

Re=6×0.0517.4×10−6=17241.37

For Re =17241.37, C = 0.26, m = 0.6

For Pr <10, n = 0.37

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

h¯=0.0264 0.05×0.26×[6×0.0517.4×10−6]0.6[0.71]0.37 [0.710.71]0.25

h¯=41.9 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=68.9 W/m2K.

Average heat-transfer co-efficient h¯=41.9 W/m2K.

(b)

Expert Solution

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with hydrogen as working fluid.

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=184.36 W/m2K

Average heat-transfer co-efficient h¯=96.14 W/m2K

Explanation of Solution

From Appendix – 2, table-32, Properties of hydrogen at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 0.704

Thermal conductivity (k) = 0.187 W/mK

Kinematic viscosity (ν)=116.6×10−6 m2/s

At surface temperature Prandtl number, Prs=0.671

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=kD×1.14 [VDν]0.5[Pr]0.4

h=0.1870.05×1.14 [6×0.05116.6×10−6]0.5[0.671]0.4 =184.36 W/m2K

From Equation(2), average heat transfer co-efficient is,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

Re=6×0.05116.6×10−6=2573

From table 6.1, For Re =2573, C = 0.26, m = 0.6

For Pr < 10, n = 0.37

h¯=0.1870.05×(0.26) [2573]0.6[0.704]0.37 [0.7040.671]0.25

h¯=96.14 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=184.36 W/m2K

Average heat-transfer co-efficient h¯=96.14 W/m2K

(c)

Expert Solution

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with water as working fluid.

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=17231.51 W/m2K

Average heat-transfer co-efficient h¯=22432 W/m2K

Explanation of Solution

From Appendix – 2, table-13, Properties of water at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 4.5

Thermal conductivity (k) = 0.629 W/mK

Kinematic viscosity (ν)=0.685×10−6 m2/s

At surface temperature Prandtl number, Prs=0.86

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=kD×1.14 [VDν]0.5[Pr]0.4

h=0.6290.05×1.14 [6×0.050.685×10−6]0.5[4.5]0.4 =17231.51 W/m2K

From Equation(2), average heat transfer co-efficient is,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

Re=6×0.050.685×10−6=437956.2

From table 6.1, For Re = 437956.2, C = 0.076, m = 0.7

For Pr < 10, n = 0.37

h¯=0.6290.05×(0.076) [437956.2]0.7[4.5]0.37 [4.50.86]0.25

h¯=22432 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=17231.51 W/m2K

Average heat-transfer co-efficient h¯=22432 W/m2K

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Answer 5

Textbook Question

Answer 6

Textbook Question

Answer 7

(a)

Expert Solution

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with air as working fluid.

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=68.9 W/m2K.

Average heat-transfer co-efficient h¯=41.9 W/m2K.

Explanation of Solution

Given Information:

Outer diameter of the tube (D) = 5 cm = 0.05 m

Length of the tube (L) = 60 cm = 0.6 m

Temperature of the tube surface (T_s) = 260⁰C

Velocity of the fluid flowing perpendicular to the tube axis is (V) = 6 m/s

Temperature of the fluid is (T_f) = 38⁰C

Explanation:

For cylindrical surfaces having cross flow, local heat-transfer co-efficient at any angular portion θ, is given by,

Nu(θ)=1.14 [Re]0.5[Pr]0.4 [1−(θ90)3]

Heat transfer co-efficient at stagnation point (θ=0) , is given by ,

Nu(θ)=1.14 [Re]0.5[Pr]0.4

Reynolds number (Re)=VDϑ

Nusselt number (Nu)=hDk

hDk=1.14 [VDν]0.5[Pr]0.4

Heat transfer -coefficient at stagnation point is given by,

h=kD×1.14 [VDν]0.5[Pr]0.4 —— Equation(1)

For cross flow over cylindrical surfaces, average Nusselt number is given by:

Nu¯=C [Re]m[Pr]n [PrPrs]0.25

h¯Dk=C [VDν]m[Pr]n [PrPrs]0.25

Average convective heat-transfer co-efficient is given by,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25———-Equation (2)

From Appendix-2, Table -28, Properties of dry air at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 0.71

Thermal conductivity (k) = 0.0264 W/mK

Kinematic viscosity (ν)=17.4×10−6 m2/s

At surface temperature Prandtl number, Prs=0.71

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=0.02640.05×1.14 [6×0.0517.4×10−6]0.5[0.71]0.4

h=68.9 W/m2K

From Equation(2), average heat transfer co-efficient is,

Re=6×0.0517.4×10−6=17241.37

For Re =17241.37, C = 0.26, m = 0.6

For Pr <10, n = 0.37

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

h¯=0.0264 0.05×0.26×[6×0.0517.4×10−6]0.6[0.71]0.37 [0.710.71]0.25

h¯=41.9 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=68.9 W/m2K.

Average heat-transfer co-efficient h¯=41.9 W/m2K.

(b)

Expert Solution

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with hydrogen as working fluid.

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=184.36 W/m2K

Average heat-transfer co-efficient h¯=96.14 W/m2K

Explanation of Solution

From Appendix – 2, table-32, Properties of hydrogen at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 0.704

Thermal conductivity (k) = 0.187 W/mK

Kinematic viscosity (ν)=116.6×10−6 m2/s

At surface temperature Prandtl number, Prs=0.671

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=kD×1.14 [VDν]0.5[Pr]0.4

h=0.1870.05×1.14 [6×0.05116.6×10−6]0.5[0.671]0.4 =184.36 W/m2K

From Equation(2), average heat transfer co-efficient is,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

Re=6×0.05116.6×10−6=2573

From table 6.1, For Re =2573, C = 0.26, m = 0.6

For Pr < 10, n = 0.37

h¯=0.1870.05×(0.26) [2573]0.6[0.704]0.37 [0.7040.671]0.25

h¯=96.14 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=184.36 W/m2K

Average heat-transfer co-efficient h¯=96.14 W/m2K

(c)

Expert Solution

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with water as working fluid.

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=17231.51 W/m2K

Average heat-transfer co-efficient h¯=22432 W/m2K

Explanation of Solution

From Appendix – 2, table-13, Properties of water at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 4.5

Thermal conductivity (k) = 0.629 W/mK

Kinematic viscosity (ν)=0.685×10−6 m2/s

At surface temperature Prandtl number, Prs=0.86

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=kD×1.14 [VDν]0.5[Pr]0.4

h=0.6290.05×1.14 [6×0.050.685×10−6]0.5[4.5]0.4 =17231.51 W/m2K

From Equation(2), average heat transfer co-efficient is,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

Re=6×0.050.685×10−6=437956.2

From table 6.1, For Re = 437956.2, C = 0.076, m = 0.7

For Pr < 10, n = 0.37

h¯=0.6290.05×(0.076) [437956.2]0.7[4.5]0.37 [4.50.86]0.25

h¯=22432 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=17231.51 W/m2K

Average heat-transfer co-efficient h¯=22432 W/m2K

Answer 8

(a)

Expert Solution

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with air as working fluid.

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=68.9 W/m2K.

Average heat-transfer co-efficient h¯=41.9 W/m2K.

Explanation of Solution

Given Information:

Outer diameter of the tube (D) = 5 cm = 0.05 m

Length of the tube (L) = 60 cm = 0.6 m

Temperature of the tube surface (T_s) = 260⁰C

Velocity of the fluid flowing perpendicular to the tube axis is (V) = 6 m/s

Temperature of the fluid is (T_f) = 38⁰C

Explanation:

For cylindrical surfaces having cross flow, local heat-transfer co-efficient at any angular portion θ, is given by,

Nu(θ)=1.14 [Re]0.5[Pr]0.4 [1−(θ90)3]

Heat transfer co-efficient at stagnation point (θ=0) , is given by ,

Nu(θ)=1.14 [Re]0.5[Pr]0.4

Reynolds number (Re)=VDϑ

Nusselt number (Nu)=hDk

hDk=1.14 [VDν]0.5[Pr]0.4

Heat transfer -coefficient at stagnation point is given by,

h=kD×1.14 [VDν]0.5[Pr]0.4 —— Equation(1)

For cross flow over cylindrical surfaces, average Nusselt number is given by:

Nu¯=C [Re]m[Pr]n [PrPrs]0.25

h¯Dk=C [VDν]m[Pr]n [PrPrs]0.25

Average convective heat-transfer co-efficient is given by,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25———-Equation (2)

From Appendix-2, Table -28, Properties of dry air at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 0.71

Thermal conductivity (k) = 0.0264 W/mK

Kinematic viscosity (ν)=17.4×10−6 m2/s

At surface temperature Prandtl number, Prs=0.71

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=0.02640.05×1.14 [6×0.0517.4×10−6]0.5[0.71]0.4

h=68.9 W/m2K

From Equation(2), average heat transfer co-efficient is,

Re=6×0.0517.4×10−6=17241.37

For Re =17241.37, C = 0.26, m = 0.6

For Pr <10, n = 0.37

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

h¯=0.0264 0.05×0.26×[6×0.0517.4×10−6]0.6[0.71]0.37 [0.710.71]0.25

h¯=41.9 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=68.9 W/m2K.

Average heat-transfer co-efficient h¯=41.9 W/m2K.

Answer 9

(a)

Expert Solution

Answer 10

(a)

Expert Solution

Answer 11

Expert Solution

Answer 12

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with air as working fluid.

Answer 13

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=68.9 W/m2K.

Average heat-transfer co-efficient h¯=41.9 W/m2K.

Answer 14

Explanation of Solution

Given Information:

Outer diameter of the tube (D) = 5 cm = 0.05 m

Length of the tube (L) = 60 cm = 0.6 m

Temperature of the tube surface (T_s) = 260⁰C

Velocity of the fluid flowing perpendicular to the tube axis is (V) = 6 m/s

Temperature of the fluid is (T_f) = 38⁰C

Explanation:

For cylindrical surfaces having cross flow, local heat-transfer co-efficient at any angular portion θ, is given by,

Nu(θ)=1.14 [Re]0.5[Pr]0.4 [1−(θ90)3]

Heat transfer co-efficient at stagnation point (θ=0) , is given by ,

Nu(θ)=1.14 [Re]0.5[Pr]0.4

Reynolds number (Re)=VDϑ

Nusselt number (Nu)=hDk

hDk=1.14 [VDν]0.5[Pr]0.4

Heat transfer -coefficient at stagnation point is given by,

h=kD×1.14 [VDν]0.5[Pr]0.4 —— Equation(1)

For cross flow over cylindrical surfaces, average Nusselt number is given by:

Nu¯=C [Re]m[Pr]n [PrPrs]0.25

h¯Dk=C [VDν]m[Pr]n [PrPrs]0.25

Average convective heat-transfer co-efficient is given by,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25———-Equation (2)

From Appendix-2, Table -28, Properties of dry air at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 0.71

Thermal conductivity (k) = 0.0264 W/mK

Kinematic viscosity (ν)=17.4×10−6 m2/s

At surface temperature Prandtl number, Prs=0.71

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=0.02640.05×1.14 [6×0.0517.4×10−6]0.5[0.71]0.4

h=68.9 W/m2K

From Equation(2), average heat transfer co-efficient is,

Re=6×0.0517.4×10−6=17241.37

For Re =17241.37, C = 0.26, m = 0.6

For Pr <10, n = 0.37

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

h¯=0.0264 0.05×0.26×[6×0.0517.4×10−6]0.6[0.71]0.37 [0.710.71]0.25

h¯=41.9 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=68.9 W/m2K.

Average heat-transfer co-efficient h¯=41.9 W/m2K.

Answer 15

(b)

Expert Solution

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with hydrogen as working fluid.

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=184.36 W/m2K

Average heat-transfer co-efficient h¯=96.14 W/m2K

Explanation of Solution

From Appendix – 2, table-32, Properties of hydrogen at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 0.704

Thermal conductivity (k) = 0.187 W/mK

Kinematic viscosity (ν)=116.6×10−6 m2/s

At surface temperature Prandtl number, Prs=0.671

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=kD×1.14 [VDν]0.5[Pr]0.4

h=0.1870.05×1.14 [6×0.05116.6×10−6]0.5[0.671]0.4 =184.36 W/m2K

From Equation(2), average heat transfer co-efficient is,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

Re=6×0.05116.6×10−6=2573

From table 6.1, For Re =2573, C = 0.26, m = 0.6

For Pr < 10, n = 0.37

h¯=0.1870.05×(0.26) [2573]0.6[0.704]0.37 [0.7040.671]0.25

h¯=96.14 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=184.36 W/m2K

Average heat-transfer co-efficient h¯=96.14 W/m2K

Answer 16

(b)

Expert Solution

Answer 17

(b)

Expert Solution

Answer 18

Expert Solution

Answer 19

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with hydrogen as working fluid.

Answer 20

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=184.36 W/m2K

Average heat-transfer co-efficient h¯=96.14 W/m2K

Answer 21

Explanation of Solution

From Appendix – 2, table-32, Properties of hydrogen at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 0.704

Thermal conductivity (k) = 0.187 W/mK

Kinematic viscosity (ν)=116.6×10−6 m2/s

At surface temperature Prandtl number, Prs=0.671

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=kD×1.14 [VDν]0.5[Pr]0.4

h=0.1870.05×1.14 [6×0.05116.6×10−6]0.5[0.671]0.4 =184.36 W/m2K

From Equation(2), average heat transfer co-efficient is,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

Re=6×0.05116.6×10−6=2573

From table 6.1, For Re =2573, C = 0.26, m = 0.6

For Pr < 10, n = 0.37

h¯=0.1870.05×(0.26) [2573]0.6[0.704]0.37 [0.7040.671]0.25

h¯=96.14 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=184.36 W/m2K

Average heat-transfer co-efficient h¯=96.14 W/m2K

Answer 22

(c)

Expert Solution

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with water as working fluid.

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=17231.51 W/m2K

Average heat-transfer co-efficient h¯=22432 W/m2K

Explanation of Solution

From Appendix – 2, table-13, Properties of water at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 4.5

Thermal conductivity (k) = 0.629 W/mK

Kinematic viscosity (ν)=0.685×10−6 m2/s

At surface temperature Prandtl number, Prs=0.86

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=kD×1.14 [VDν]0.5[Pr]0.4

h=0.6290.05×1.14 [6×0.050.685×10−6]0.5[4.5]0.4 =17231.51 W/m2K

From Equation(2), average heat transfer co-efficient is,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

Re=6×0.050.685×10−6=437956.2

From table 6.1, For Re = 437956.2, C = 0.076, m = 0.7

For Pr < 10, n = 0.37

h¯=0.6290.05×(0.076) [437956.2]0.7[4.5]0.37 [4.50.86]0.25

h¯=22432 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=17231.51 W/m2K

Average heat-transfer co-efficient h¯=22432 W/m2K

Answer 23

(c)

Expert Solution

Answer 24

(c)

Expert Solution

Answer 25

Expert Solution

Answer 26

To determine

Heat transfer co-efficient at stagnation point and average heat transfer co-efficient with water as working fluid.

Answer 27

Answer to Problem 6.1P

Heat transfer co-efficient at stagnation point h=17231.51 W/m2K

Average heat-transfer co-efficient h¯=22432 W/m2K

Answer 28

Explanation of Solution

From Appendix – 2, table-13, Properties of water at bulk temperature of 38⁰C are,

Prandtl number (Pr) = 4.5

Thermal conductivity (k) = 0.629 W/mK

Kinematic viscosity (ν)=0.685×10−6 m2/s

At surface temperature Prandtl number, Prs=0.86

Form Equation(1), Heat transfer co-efficient at stagnation point :

h=kD×1.14 [VDν]0.5[Pr]0.4

h=0.6290.05×1.14 [6×0.050.685×10−6]0.5[4.5]0.4 =17231.51 W/m2K

From Equation(2), average heat transfer co-efficient is,

h¯=kD×C [VDν]m[Pr]n [PrPrs]0.25

Re=6×0.050.685×10−6=437956.2

From table 6.1, For Re = 437956.2, C = 0.076, m = 0.7

For Pr < 10, n = 0.37

h¯=0.6290.05×(0.076) [437956.2]0.7[4.5]0.37 [4.50.86]0.25

h¯=22432 W/m2K

Conclusion:

Heat transfer co-efficient at stagnation point h=17231.51 W/m2K

Average heat-transfer co-efficient h¯=22432 W/m2K

Answer 29

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