1 kg of Oxygen has initial volume of 2 x 10° cm³ is heated at Isobaric process from 298 K to200°C. Calculate (i) ratio of specific heats (i) heat transfer in 'kl' (ii) work transfer in 'kJ'(V)change in internal energy in 'kl' (V) volume after heating (vi) pressure before heating in"bar'.Gas(kJlkg K)(kJ/kg K)Air1.0050.718OxygenNitrogenHydrogen0.9200.6601.0460.75414.4010.40Carbon monoxide1.0460.754

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1 kg of Oxygen has initial volume of 2 x 10 cm³ is heated at Isobaric process from 298 K to 200°C. Calculate (i) ratio of specific heats (ii) heat transfer in 'kI" (ii) work transfer in 'kJ'(iv) change in internal energy in 'k' (v) volume after heating (vi) pressure before heating in 'bar'. Gas (kJlkg K) (kJlkg K) Air 1.005 0.718 Oxygen Nitrogen Hydrogen 0.920 0.660 1.046 0.754 14.40 10.40 Carbon monoxide 1.046 0.754

1 kg of Oxygen has initial volume of 2 x 10 cm³ is heated at Isobaric process from 298 K to 200°C. Calculate (i) ratio of specific heats (ii) heat transfer in 'kI" (ii) work transfer in 'kJ'(iv) change in internal energy in 'k' (v) volume after heating (vi) pressure before heating in 'bar'. Gas (kJlkg K) (kJlkg K) Air 1.005 0.718 Oxygen Nitrogen Hydrogen 0.920 0.660 1.046 0.754 14.40 10.40 Carbon monoxide 1.046 0.754

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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1 kg of Oxygen has initial volume of 2 x 10° cm³ is heated at Isobaric process from 298 K to 200°C. Calculate (i) ratio of specific heats (ii) heat transfer in 'kJ' (ii) work transfer in 'kJ'(iv) change in internal energy in 'kl' (v) volume after heating (vi) pressure before heating in "bar'. Gas (kJ/kg K) (kJ/kg K) Air 1.005 0.718 Oxygen Nitrogen Hydrogen Carbon monoxide 0.920 0.660 1.046 0.754 14.40 10.40 1.046 0.754
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