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A Bell Coleman refrigerator working on dense air system as compared to open air system, for the same range of temperature, results in __________ power per tonne of refrigeration.

Question: A Bell Coleman refrigerator working on dense air system as compared to open air system, for the same range of temperature, results in __________ power per tonne of refrigeration.
[A].

same

[B].

lower

[C].

higher

Answer: Option B

Explanation:

No answer description available for this question.

A Bell Coleman refrigerator working on dense air system as compared to open air system, for the same range of temperature, results in __________ power per tonne of refrigeration. Read More »

Heat Transfer, Mechanical Engineering, Refrigeration and Air Conditioning

A Bell Coleman refrigerator working on dense air system as compared to open air system, for the same range of temperature, results in higher coefficient of performance.

Question: A Bell Coleman refrigerator working on dense air system as compared to open air system, for the same range of temperature, results in higher coefficient of performance.
[A].

Agree

[B].

Disagree

Answer: Option A

Explanation:

No answer description available for this question.

A Bell Coleman refrigerator working on dense air system as compared to open air system, for the same range of temperature, results in higher coefficient of performance. Read More »

Heat Transfer, Mechanical Engineering, Refrigeration and Air Conditioning

In air-conditioning of aeroplanes, using air as a refrigerant, the cycle used is

Question: In air-conditioning of aeroplanes, using air as a refrigerant, the cycle used is
[A].

reversed Carnot cycle

[B].

reversed Joule cycle

[C].

reversed Brayton cycle

[D].

reversed Otto cycle

Answer: Option C

Explanation:

No answer description available for this question.

In air-conditioning of aeroplanes, using air as a refrigerant, the cycle used is Read More »

Heat Transfer, Mechanical Engineering, Refrigeration and Air Conditioning

If the evaporator temperature is kept constant, the coefficient of performance of a refrigeration cycle __________ with the increase in condenser temperature.

Question: If the evaporator temperature is kept constant, the coefficient of performance of a refrigeration cycle __________ with the increase in condenser temperature.
[A].

increases

[B].

decreases

Answer: Option B

Explanation:

No answer description available for this question.

If the evaporator temperature is kept constant, the coefficient of performance of a refrigeration cycle __________ with the increase in condenser temperature. Read More »

Heat Transfer, Mechanical Engineering, Refrigeration and Air Conditioning

If the condenser temperature is kept constant, the coefficient of performance of a refrigeration cycle increases with the increase in evaporator temperature.

Question: If the condenser temperature is kept constant, the coefficient of performance of a refrigeration cycle increases with the increase in evaporator temperature.
[A].

Yes

[B].

No

Answer: Option A

Explanation:

No answer description available for this question.

If the condenser temperature is kept constant, the coefficient of performance of a refrigeration cycle increases with the increase in evaporator temperature. Read More »

Heat Transfer, Mechanical Engineering, Refrigeration and Air Conditioning

In a refrigerating machine, heat rejected is __________ heat absorbed.

Question: In a refrigerating machine, heat rejected is __________ heat absorbed.
[A].

equal to

[B].

less than

[C].

greater than

Answer: Option C

Explanation:

No answer description available for this question.

In a refrigerating machine, heat rejected is __________ heat absorbed. Read More »

Heat Transfer, Mechanical Engineering, Refrigeration and Air Conditioning

The C.O.P. of a refrigerator working on a reversed Carnot cycle is (where T1 = Lowest absolute temperature, and T2 = Highest absolute temperature)

Question: The C.O.P. of a refrigerator working on a reversed Carnot cycle is (where T1 = Lowest absolute temperature, and T2 = Highest absolute temperature)
[A].

[B].

[C].

[D].

Answer: Option A

Explanation:

No answer description available for this question.

The C.O.P. of a refrigerator working on a reversed Carnot cycle is (where T1 = Lowest absolute temperature, and T2 = Highest absolute temperature) Read More »

Heat Transfer, Mechanical Engineering, Refrigeration and Air Conditioning