An ideal Otto cycle with Argon as the working fluid has a compression ratio of 7....

An ideal Otto cycle with Argon as the working fluid has a compression ratio of 7....

An ideal Otto cycle with Argon as the working fluid has a compression ratio of 7. The minimum and maximum temperatures in the cycle are 290 and 1350 K. accounting for the constant specific heats at room temperature, determine (a) the amount of heat transferred to Argon during the heat addition process, (b) the thermal efficiency of Otto cycle, and (c) the thermal efficiency of a Carnot cycle operating between the same temperature limits.

1) An air-standard Otto cycle has a compression ratio of 9. At the beginning of the...

1) An air-standard Otto cycle has a compression ratio of 9. At the beginning of the compression process, the temperature is 20°C, and the pressure is 100 kPa. The heat added is 500 kJ/kg. Determine the cycle efficiency, work output, and the heat rejected 2) An air-standard Otto cycle operates with a minimum temperature of 300 K and a maximum temperature of 1700 K. The compression ratio of the cycle is 7. At the beginning of the compression process, the...

10) An air-standard Otto cycle has a compression ratio of 9. At the beginning of the...

10) An air-standard Otto cycle has a compression ratio of 9. At the beginning of the compression process, the temperature is 20°C, and the pressure is 100 kPa. The heat added is 500 kJ/kg. Determine the cycle efficiency, work output, and the heat rejected. 11)An air-standard Otto cycle operates with a minimum temperature of 300 K and a maximum temperature of 1700 K. The compression ratio of the cycle is 7. At the beginning of the compression process, the pressure...

An ideal Otto engine has a compression ratio of 10 and uses air as the working...

An ideal Otto engine has a compression ratio of 10 and uses air as the working fluid. The state of air at the beginning of the compression process is 100 kPa and 27 0C. The maximum temperature in the cycle is 2100K. (R=0.287 for air) (using variable specific heat) Draw the P-v diagram of the Otto cycle Determine the specific internal energies at the beginning and the end of the compression, Determine the specific internal energies before and after the...

The compression ratio in an air-standard Otto cycle is 8. At the beginning of the compression...

The compression ratio in an air-standard Otto cycle is 8. At the beginning of the compression stroke the pressure is 14.7 lbf/in2 and the temperature is 600F. The heat transfer to the air during the combustion process per cycle is 800 Btu/lbm. Determine: (a) The pressure and temperature at the end of each process of the cycle. (b) The thermal efficiency (use k = 1.4, Cv = 0.171 Btu/lbm 0F).

The compression ratio in an air-standard Otto cycle is 8. At the beginning of the compression...

The compression ratio in an air-standard Otto cycle is 8. At the beginning of the compression stroke the pressure is 14.7 lbf/in2 and the temperature is 600F. The heat transfer to the air during the combustion process per cycle is 800 Btu/lbm. Determine: (a) The pressure and temperature at the end of each process of the cycle. (b) The thermal efficiency (use k = 1.4, Cv = 0.171 Btu/lbm 0F).

At the beginning of the compression process of an air-standard Otto cycle, p1 = 1 bar...

At the beginning of the compression process of an air-standard Otto cycle, p1 = 1 bar and T1 = 300 K. The compression ratio is 6 and the heat addition per unit mass of air is 1500 kJ/kg. Determine: (a) the maximum temperature of the cycle, in K. (b) the net work, in kJ/kg. (c) the percent thermal efficiency of the cycle. (d) the mean effective pressure, in kPa.

An ideal Otto cycle engine, an ideal Diesel cycle engine, and a Stirling engine all have...

An ideal Otto cycle engine, an ideal Diesel cycle engine, and a Stirling engine all have a maximum volume of 1 liter. The volume at the end of combustion for the Otto and Diesel engines is 0.1 liter. The minimum volume for the Stirling engine is 0.1 liter. All three engines operate with air initially at 100 kPa, and have a minimum temperature of 300 K and a maximum temperature of 1200 K. Determine how much work is done for...

An ideal Diesel cycle has a cut off ratio of 2. The temperature of the air...

An ideal Diesel cycle has a cut off ratio of 2. The temperature of the air at the beginning and at the end of the compression process are 300 K and 900 K respectively. By utilizing constant specific heats, taking the specific heat ratio, k = 1.4, Cp = 1.005 kJ/kg K and Cv = 0.718 kJ/kg K. Determine the followings: (i) The compression ratio. [5 marks] (ii) The maximum cycle temperature. [5 marks] (iii) The amount of heat transferred...

A diesel cycle has a compression ratio of 18 and an intake cutoff ratio of 3....

A diesel cycle has a compression ratio of 18 and an intake cutoff ratio of 3. At the beginning of the compression process, the working fluid is at 100 Kpa and 20 degrees C. assuming variation of the specific heats find the temperature and pressure of the air in each state, the heats of input and output per unit mass and thermal efficiency.