Derive expressions for the coefficient of performance of a Carnot refrigerator and of a Carnot heat...

A refrigerator has a coefficient of performance of K=2.1. Each cycle, it absorbs 3.45×104 J of...

A refrigerator has a coefficient of performance of K=2.1. Each cycle, it absorbs 3.45×104 J of heat from the cold reservoir. The refrigerator is driven by a Carnot engine that has an efficiency of e=0.5. 1.During each cycle, how much heat flows into the Carnot engine? Express your answer in joules to three significant figures.

What is the maximal coefficient of performance of a refrigerator which cools down 10 kg of...

What is the maximal coefficient of performance of a refrigerator which cools down 10 kg of water (and then ice) to -6?C. Upper heat source of this refrigerator is surroundings at constant temperature 21?C. Initially water is in equilibrium with surroundings. What is maximal coefficient of performance of heat pump operating in the same configuration. Specific heat of water, specific heat of ice, and latent heat of fusion are equal to 4.19KJ/kg/K, 2.1KJ/kg/K and 335 KJ/kg, respectively.

A refrigerator with a coefficient of performance of 1.70 absorbs 3.60×104 J of heat from the...

A refrigerator with a coefficient of performance of 1.70 absorbs 3.60×104 J of heat from the low-temperature reservoir during each cycle. How much mechanical work is required to operate the refrigerator for a cycle? How much heat does the refrigerator discard to the high-temperature reservoir during each cycle?

A device uses a Stirling cycle on 378 moles of a monatomic ideal gas between two...

A device uses a Stirling cycle on 378 moles of a monatomic ideal gas between two reservoirs with temperatures of 389 K and 659 K as a refrigerator or a heat pump. The volume of the system shifts between 0.94 m3 and 2.44 m3. 1) How much energy does this device remove from the cold reservoir? 2)How much energy does this device transfer into the hot reservoir? 3)How much work is done by the device on the gas? 4)What is...

A Carnot refrigerator transfers heat from its inside (5.63 oC) to the room air outside (22.0...

A Carnot refrigerator transfers heat from its inside (5.63 oC) to the room air outside (22.0 oC). (a) Find the coefficient of performance of the refrigerator. (b) Determine the magnitude of the minimum work needed to cool 5.84 kg of water from 22.0 to 5.63 oC when it is placed in the refrigerator.

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...

Part A What is the coefficient of performance of an ideal heat pump that extracts heat...

Part A What is the coefficient of performance of an ideal heat pump that extracts heat from 3.0 ∘C air outside and deposits heat inside a house at 18 ∘C ? Part B If this heat pump operates on 1200 W of electrical power, what is the maximum heat it can deliver into the house each hour?

Chapter 16 Part 2: Question 16.3 An ideal Carnot engine takes 2000 J of heat from...

Chapter 16 Part 2: Question 16.3 An ideal Carnot engine takes 2000 J of heat from a reservoir at 500 K, does some work, and discards some heat to a reservoir at 350 K. Let’s see what happens if the Carnot engine described is run backward as a refrigerator.What is its performance coefficient? SOLUTION SET UP AND SOLVE We know that a refrigerator will act like an engine but with the signs for QH, QC, and Wreversed because the cycle...

1. (a) Draw a schematic of theoretical wet-vapor (e.g. liquid refrigerant and vapor mixture) Carnot Refrigeration...

1. (a) Draw a schematic of theoretical wet-vapor (e.g. liquid refrigerant and vapor mixture) Carnot Refrigeration cycle going through four key components (or devices) through an open system with its respective energy source and sink. (b) Following the class note’s format, label and explain each process (e.g. isobaric evaporation) and its association with work (e.g., W =0) and heat (e.g., Qin). (If there is no work or heat, must indicate so.) (c) Plot the cycles on P-v and T-s diagrams...

A shell and-tube heat exchanger is required for the following service: Hot stream Cold Stream Aromatic...

A shell and-tube heat exchanger is required for the following service: Hot stream Cold Stream Aromatic Stream Cooling Water inlet Temperature (oC) 85 20 outlet Temperature (oC) 40 35 Mass Flowrate x heat Capacity (kW/oC) 85.2 Hot Stream cold stream (Cooling water) Heat Capacity (J/kg K) 2840 4193 Density (kg/m3) 750 999 Viscosity (cP) 0.34 1.016 Thermal conductivity (W/m.K) 0.19 0.594 Fouling Factor (m2.oC/W 0.00018 0.000176 ? The cooling water is allocated to the tube-side of the exchanger. ? It...