O-ICE-S XJA5//allExtra Problems chapter 2Problem 1:In an Otto cycle, the air at the beginning of the isentropic compression is at 1 bar and the ratio ofcompression is 8. If the heat added during the constant volume process is 1010 kl/kg, the maximumtemperature in the cycle is 1819°C, the specific heat ratio is k-1.4 and the gas constant is 287J/kg.K for air,a. Determine The specific heat at constant volume Cv in kJ/kg.kb. Determine The temperature at the end of the isentropic compression in the cyclec. Determine The temperature at the beginning of the isentropic compression in the cyeled. Determine The air standard efficiencye. Determine The work done per kg of airf Determine The heat rejected per kg of air

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Problem 1: In an Otto cycle, the air at the beginning of the isentropic compression compression is 8. If the heat added during the constant volume process is temperature in the cycle is 1819°C, the specific heat ratio is k=1.4 ar J/kg.K for air, a. Determine The specific heat at constant volume Cv in kJ/kgk b. Determine The temperature at the end of the isentropic compres Determine The temperature at the beginning of the isentropic co C.

Problem 1: In an Otto cycle, the air at the beginning of the isentropic compression compression is 8. If the heat added during the constant volume process is temperature in the cycle is 1819°C, the specific heat ratio is k=1.4 ar J/kg.K for air, a. Determine The specific heat at constant volume Cv in kJ/kgk b. Determine The temperature at the end of the isentropic compres Determine The temperature at the beginning of the isentropic co C.

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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