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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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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