Two gases—helium or nitrogen—are compressed isentropically from 100 kPa and 25°C to 1 MPa in a...

10 kg of H2O is reversibly compressed from 600 kPa and 600 oC to 1 MPa...

10 kg of H2O is reversibly compressed from 600 kPa and 600 oC to 1 MPa in an insulated piston- cylinder assembly. Calculate (a) entropy change (kJ/K) of the system and (b) the final temperature.

A rigid closed tank is full of oxygen at 120 kPa and 25 C. The mass...

A rigid closed tank is full of oxygen at 120 kPa and 25 C. The mass of oxygen in the tank is 1.8 kg. A stirring device introduces 150 kJ of work and there is heat loss to the surroundings in the amount of 45 kJ. Find the final temperature in Celsius and pressure in kPa. Assume specific heats constant at room temperature (300 K).

0.5 kilograms of air are compressed from 100 kPa and 300 K in a polytropic process,...

0.5 kilograms of air are compressed from 100 kPa and 300 K in a polytropic process, n = 1.3, to a state where V2 = 0.5 V1. The air is further compressed at constant pressure until the final volume is 0.2 V1 . Draw a sketch of the processes on a p-V diagram. Determine the work for each process.

please show all steps. 2.5 kg of nitrogen gas with an initial temperature of 300 K...

please show all steps. 2.5 kg of nitrogen gas with an initial temperature of 300 K and pressure of 100 kPa is compressed to a higher pressure. The internal energy change during this process is 70 kJ/kg. Determine the final temperature of the nitrogen. Please perform at least two iterations with average specific heats.

A tank of 0.1 m3 volume initially containing nitrogen at 25 C and 1 bar will...

A tank of 0.1 m3 volume initially containing nitrogen at 25 C and 1 bar will be filled with compressed nitrogen at a rate of 20 mol/s. The nitrogen coming from the compressor and into the tank is at an absolute pressure of 110 bar and a temperature of 80 C. The filling process occurs sufficiently rapidly that there is negligible heat transfer between the gas and the tank walls, and a valve is closed to stop the filling process...

1-kg of R-134a initially at 600 kPa and 25 °C undergoes a process during which the...

1-kg of R-134a initially at 600 kPa and 25 °C undergoes a process during which the entropy is kept constant until the pressure drops to 100 kPa. Determine the final temperature of the R-134a and the final specific internal energy.

Consider the following processes (treat all gases as ideal). I. The pressure of 1 mole of...

Consider the following processes (treat all gases as ideal). I. The pressure of 1 mole of oxygen gas is allowed to double at constant temperature. II. Carbon dioxide is allowed to expand at constant temperature to 10 times its original volume. III. The temperature of 1 mol of helium is increased 25 degrees C at constant pressure. IV. Nitrogen gas is compressed at constant temperature to half its original volume. V. A glass of water loses 100 J of energy...

An isentropic compressor that takes in air from the atmosphere at 100 kPa and 300 K...

An isentropic compressor that takes in air from the atmosphere at 100 kPa and 300 K compresses it to 1 MPa. The compressor feeds into a rigid tank that is initially filled with 5 kg of air at a pressure of 500 kPa and a temperature of 500 K. Once the mass in the tank reaches 8 kg, the compressor will stop to prevent the tank from rupturing, which will occur if the pressure exceeds 1000 kPa. a) Determine the...

1 mole of a non-ideal gas is compressed isothermally at 100°C from 1 bar to 50...

1 mole of a non-ideal gas is compressed isothermally at 100°C from 1 bar to 50 bar. What are the heat and work needed for this (reversible) compression if the gas conforms to the principle of corresponding states? The critical properties of the non-ideal gas are Tc = 406 K and Pc = 11.3 MPa.

Two moles of helium are initially at a temperature of 30.0 ∘C and occupy a volume...

Two moles of helium are initially at a temperature of 30.0 ∘C and occupy a volume of 3.50×10−2 m3 . The helium first expands at constant pressure until its volume has doubled. Then it expands adiabatically until the temperature returns to its initial value. Assume that the helium can be treated as an ideal gas. A.) What is the total heat supplied to the helium in the process? In J B.) What is the total change in internal energy of...