In a reversible heat engine, TH=1200 K, TL=300 K , QL=25kJ. Calculate Wnet,out and QH. A...

A refrigeration cycle receives energy QL from a low temperature body at TL = 250 K...

A refrigeration cycle receives energy QL from a low temperature body at TL = 250 K and rejects energy QH to a high temperature body at TH = 300 K. For each of the following cases determine whether the cycle operates reversibly, irreversible, or is impossible. (a) QL = 1000 kJ, Wcycle = 400 kJ. (b) QL =1500kJ,QH =1800kJ. (c) QH = 1500 kJ, Wcycle = 200 kJ. (d) COP=4.

The following heat engine operates between heat reservoirs at 750 K and 300 K, respectively, and...

The following heat engine operates between heat reservoirs at 750 K and 300 K, respectively, and produces power of 95,000 kW. (a) If the engine operates all reversible, calculate the η, QH, and QC. (b) In practice, due to the irreversibility, the efficiency η = 0.35. If QH, TH and TC remain the same, calculate the produced work, lost work Wlost, and total entropy generation (ΔS).

A heat engine that operates at steady state between two reservoirs at TH = 750◦C and...

A heat engine that operates at steady state between two reservoirs at TH = 750◦C and TL = 15◦C, has a heat intake of 0.1 MW and rejects 50 kW of heat to the low- temperature environment. Determine the actual power produced, the thermal efficiency, the entropy generation rate. In addition, calculate the maximum possible output power and efficiency. Assume the reservoirs are isolated systems.

2) A heat engine operates between two fixed temperature reservoirs, TH = 127 0C, TC =...

2) A heat engine operates between two fixed temperature reservoirs, TH = 127 0C, TC = 7 0C. In each cycle 5 J are extracted from the hot reservoir and 4 J are deposited into the cold reservoir. [ 0 0C = 273 K] (a) How much work is performed by the engine per cycle ? (4) (b) What is the efficiency of the engine ? (4) (c) What is the entropy change of the hot reservoir during one cycle...

An ideal heat pump is used to heat a room that is at 300 K. The...

An ideal heat pump is used to heat a room that is at 300 K. The outdoor temperature is 263 K. Recall that for a heat pump, ???????? = ?? ??−?? . a. If the ? = 300 J, calculate the heat pumped into the room. (2 pts) ?? =______________ J b. Calculate the heat extracted from the outside air. (1 pts) ?? = _____________J c. Calculate the entropy change in the outside air. (2 pts) Δ???? = ____________ J/K...

A heat engine is assumed to operate on a Carnot cycle. It receives 600kJ heat from...

A heat engine is assumed to operate on a Carnot cycle. It receives 600kJ heat from a high temperature reservoir at 600oC and rejects heat to a low temperature reservoir at 20oC. a. Calculate the thermal efficiency of the cycle. b. What is QL? c. What is the net work produced by this cycle? d. Does this process violate Kelvin-Plank statement? Explain. e. An inventor claimed that he built a heat engine operating between the same reservoirs that give a...

Air is cooled from 300 K to 273 K as it flows steadily through a duct....

Air is cooled from 300 K to 273 K as it flows steadily through a duct. Frictional dissipation may be neglected. Cooling is achieved by removing heat via a heat pump. The work requirement is 1.15 times that of a reversible heat pump operating between 263 and 310 K. For each mole of air flowing through the duct, calculate: Air can be assumed an ideal gas with a constant heat capacity cP of 3.50R. The temperature of the surroundings is...

An inventor proposes a four-stroke cycle running on helium. The engine has a compression ratio of...

An inventor proposes a four-stroke cycle running on helium. The engine has a compression ratio of 8 and maximum operating temperature of 1,500 K. The atmospheric conditions are temperature of 300 K and pressure of 100 kPa. The processes can be approximated as below: 1- 2 isentropic compression 2- 3 constant volume heat addition 3- 4 isentropic expansion 4- 1 constant pressure heat removal a. Plot P-v and T-s diagrams for this cycle. b. Determine state conditions at the end...

Reconsider the top-secret military power supply for artic environments that you worked in a previous homework....

Reconsider the top-secret military power supply for artic environments that you worked in a previous homework. Previously, you modeled it as a Carnot cycle; now you will use the more realistic Rankine cycle. The boiler operates at 1000 kPa with a maximum temperature of 30°C. The condenser is isobaric and operates at -5°C. a. Calculate the vapor quality leaving the turbine and the specific enthalpy exiting the turbine (in kJ/kg) b. Determine the specific-work produced by the Rankine cycle turbine...

A finned heat exchanger tube is made of aluminum alloy (k=186W/m· K) and contains 125 annular...

A finned heat exchanger tube is made of aluminum alloy (k=186W/m· K) and contains 125 annular fins per meter of tube length. The bare tube between fins has an OD of 50 mm. The fins are 4mm thick and extend 15mm beyond the external surface of the tube. The outer surface of the tube will be at 200◦C and the tube will be exposed to a fluid at 20◦C with a heat-transfer coefficient of 40W/m2 · K. Calculate: (a) The...