The total emissive power of the emitter with area d A and temperature T is given b?

E = ¬¨¬®≈í¬© ‚âà√¨‚àö√¢ T 4 d A

E = 2 ‚âà√¨‚àö√¢ T 4 d A

E = 3 ‚âà√¨‚àö√¢ T 4 d A

E = ‚âà√¨‚àö√¢ T 4 d A

E = ¬¨¬®≈í¬© ‚âà√¨‚àö√¢ T 4 d A

If I n denotes the normal intensity and I ‚âà√≠¬¨¬± represents the intensity at angle ‚âà√≠¬¨¬±, then$

I ‚âà√≠¬¨¬± = 2 I n cos ‚âà√≠¬¨¬±

I ‚âà√≠¬¨¬± = 3 I n cos ‚âà√≠¬¨¬±

I ‚âà√≠¬¨¬± = 4 I n cos ‚âà√≠¬¨¬±

I ‚âà√≠¬¨¬± = I n cos ‚âà√≠¬¨¬±

16 + Mcqs in Intensity Radiations in Heat Transfer Page 1 McqOptions

1.	The energy radiated out decreases with increases in α and becomes zero at an angle of
A.	45
B.	30
C.	0
D.	90
Answer» E.

Discussion

2.	A black body of 0.2 m2 area has an effective temperature of 800 K. Calculate the intensity of normal radiations
A.	1234.65 W/m2 sr
B.	7396.28 W/m2 sr
C.	3476.74 W/m2 sr
D.	8739.43 W/m2 sr
Answer» C. 3476.74 W/m2 sr

Discussion

3.	The total emissive power of the emitter with area d A and temperature T is given by
A.	E = 2 σ T 4 d A
B.	E = 3 σ T 4 d A
C.	E = σ T 4 d A
D.	E = ½ σ T 4 d A
Answer» D. E = ½ σ T 4 d A

Discussion

4.	Consider a deep-space probe constructed as 1 m diameter polished aluminum sphere. Estimate the equilibrium temperature that the probe reaches if the solar energy received is 300 W/m2. For solar radiation, absorptivity of aluminum is 0.3 and the average emissivity appropriate for aluminum at low temperature is 0.04
A.	415.67 K
B.	315.67 K
C.	215.67 K
D.	115.67 K
Answer» C. 215.67 K

Discussion

5.	A small surface emits diffusively, and measurements indicate that the total intensity associated with emission in the normal direction I n = 6500 W/square m sr. The emitted radiation is intercepted by three surfaces. Mark calculations for intensity associated with emission
A.	3500 W/m2 sr
B.	4500 W/m2 sr
C.	5500 W/m2 sr
D.	6500 W/m2 sr
Answer» E.

Discussion

6.	The intensity of normal radiation I n is how much times the emissive power?
A.	1/π
B.	2/ π
C.	3/ π
D.	4/ π
Answer» B. 2/ π

Discussion

7.	If I n denotes the normal intensity and I α represents the intensity at angle α, then
A.	I α = 2 I n cos α
B.	I α = 3 I n cos α
C.	I α = 4 I n cos α
D.	I α = I n cos α
Answer» E.

Discussion

8.	A_BLACK_BODY_OF_0.2_M²_AREA_HAS_AN_EFFECTIVE_TEMPERATURE_OF_800_K._CALCULATE_THE_INTENSITY_OF_NORMAL_RADIATIONS?$
A.	1234.65 W/m<sup>2</sup> sr
B.	7396.28 W/m<sup>2</sup> sr
C.	3476.74 W/m<sup>2</sup> sr
D.	8739.43 W/m<sup>2</sup> sr
Answer» C. 3476.74 W/m<sup>2</sup> sr

Discussion

9.	The_energy_radiated_out_decreases_with_increases_in_‚âà√≠¬¨¬±_and_becomes_zero_at_an_angle_of$#
A.	45
B.	30
C.	0
D.	90
Answer» E.

Discussion

10.	The total emissive power of the emitter with area d A and temperature T is given b?
A.	E = 2 ‚âà√¨‚àö√¢ T<sup> 4</sup> d A
B.	E = 3 ‚âà√¨‚àö√¢ T<sup> 4</sup> d A
C.	E = ‚âà√¨‚àö√¢ T<sup> 4</sup> d A
D.	E = ¬¨¬®≈í¬© ‚âà√¨‚àö√¢ T<sup> 4</sup> d A
Answer» D. E = ¬¨¬®≈í¬© ‚âà√¨‚àö√¢ T<sup> 4</sup> d A

Discussion

11.	Consider a deep-space probe constructed as 1 m diameter polished aluminum sphere. Estimate the equilibrium temperature that the probe reaches if the solar energy received is 300 W/m². For solar radiation, absorptivity of aluminum is 0.3 and the average emissivity appropriate for aluminum at low temperature is 0.04
A.	415.67 K
B.	315.67 K
C.	215.67 K
D.	115.67 K
Answer» C. 215.67 K

Discussion

12.	The intensity of normal radiation I _nis how much times the emissive power?
A.	1/‚âà√¨‚àö√ë
B.	2/ ‚âà√¨‚àö√ë
C.	3/ ‚âà√¨‚àö√ë
D.	4/ ‚âà√¨‚àö√ë
Answer» B. 2/ ‚âà√¨‚àö√ë

Discussion

13.	If I _ndenotes the normal intensity and I _{‚âà√≠¬¨¬±} represents the intensity at angle ‚âà√≠¬¨¬±, then$
A.	I <sub>‚âà√≠¬¨¬± </sub>= 2 I <sub>n</sub> cos ‚âà√≠¬¨¬±
B.	I <sub>‚âà√≠¬¨¬± </sub>= 3 I <sub>n</sub> cos ‚âà√≠¬¨¬±
C.	I <sub>‚âà√≠¬¨¬± </sub>= 4 I <sub>n</sub> cos ‚âà√≠¬¨¬±
D.	I <sub>‚âà√≠¬¨¬± </sub>= I <sub>n</sub> cos ‚âà√≠¬¨¬±
Answer» E.

Discussion

14.	When the incident surface is a sphere, the projection of surface normal to the line of propagation is the silhouette disk of the sphere which is a circle of the diameter of
A.	Parabola
B.	Sphere
C.	Triangle
D.	Hyperbola
Answer» C. Triangle

Discussion

15.	The plane angle is defined by a region by the rays of a circle, and is measured as
A.	3 L/ r
B.	2 L/ r
C.	L/ r
D.	4 L / r
Answer» D. 4 L / r

Discussion

16.	The solid angle is defined by a region by the rays of a sphere, and is measured as
A.	A<sub>n</sub>/r <sup>2</sup>
B.	A<sub>n</sub>/r
C.	A<sub>n</sub>/r <sup>3</sup>
D.	A<sub>n</sub>/r <sup>4</sup>
Answer» B. A<sub>n</sub>/r

Discussion

Explore topic-wise MCQs in Heat Transfer.

The energy radiated out decreases with increases in α and becomes zero at an angle of

A black body of 0.2 m2 area has an effective temperature of 800 K. Calculate the intensity of normal radiations

The total emissive power of the emitter with area d A and temperature T is given by

A small surface emits diffusively, and measurements indicate that the total intensity associated with emission in the normal direction I n = 6500 W/square m sr. The emitted radiation is intercepted by three surfaces. Mark calculations for intensity associated with emission

The intensity of normal radiation I n is how much times the emissive power?

If I n denotes the normal intensity and I α represents the intensity at angle α, then

A_BLACK_BODY_OF_0.2_M2_AREA_HAS_AN_EFFECTIVE_TEMPERATURE_OF_800_K._CALCULATE_THE_INTENSITY_OF_NORMAL_RADIATIONS?$

The_energy_radiated_out_decreases_with_increases_in_‚âà√≠¬¨¬±_and_becomes_zero_at_an_angle_of$#

The total emissive power of the emitter with area d A and temperature T is given b?

The intensity of normal radiation I n is how much times the emissive power?

If I n denotes the normal intensity and I ‚âà√≠¬¨¬± represents the intensity at angle ‚âà√≠¬¨¬±, then$

When the incident surface is a sphere, the projection of surface normal to the line of propagation is the silhouette disk of the sphere which is a circle of the diameter of

The plane angle is defined by a region by the rays of a circle, and is measured as

The solid angle is defined by a region by the rays of a sphere, and is measured as

A_BLACK_BODY_OF_0.2_M²_AREA_HAS_AN_EFFECTIVE_TEMPERATURE_OF_800_K._CALCULATE_THE_INTENSITY_OF_NORMAL_RADIATIONS?$

The intensity of normal radiation I _nis how much times the emissive power?

If I _ndenotes the normal intensity and I _{‚âà√≠¬¨¬±} represents the intensity at angle ‚âà√≠¬¨¬±, then$