FUND OF ENG THERMODYN(LLF)+WILEYPLUS
9th Edition
ISBN: 9781119391777
Author: MORAN
Publisher: WILEY
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Multiple choice Questions
Any reversible path may be substituted by a reversible zigzag path between the same end processes such that the heat transfer during this zigzag path is equal to the heat transfer during original path. What are theprocesses involved in the zigzag path?
a.reversible polytropic and isobaric processb.reversible polytropic and isothermal processc. reversible adiabatic and isothermal processesd. none of the above
The cycle involved in the operation of an internal combustion engine is called the Otto cycle.
Air can be considered to be the working substance and can be assumed to be a perfect gas. The cycle consists of the following steps:
I) Reversible adiabatic compression from A to B.
2) Reversible constant-volume pressure increase from B to C due to the combustion of a small amount of fuel.
3) Reversible adiabatic expansion from C to D.
4) Reversible and constant-volume pressure decrease back to state A.
Determine the change in entropy (of the system and of the surroundings) for each step of the cycle and determine an expression for the efficiency of the cycle, assuming that the heat is supplied in Step 2. Evaluate the efficiency for a compression ratio 10:1. Assume that in state A, V=4.00 dm', p= 1.00 atm, T= 300 K, that VA = 10 Vb, pc/pb = 5, and that Cp.m = (7/2)R
Note that R = 8.314 J K-1 mol-1 and dm = 10-1 m.
THERMODYNAMICS
Indicate whether the following statements are true or false. Explain.
Although the exhaust gas temperature of a simple gas turbine is typically well above the ambient temperature, the exhaust gas is normally discarded to the surroundings for operational simplicity.
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- 2 inlets and 1 outlet in a feed water heater operating in steady regime exists. Liquid water from inlet 1 with 7 bar pressure, 42°C temperature and 70 kg/s mass flow enters. From the inlet 2, a liquid-steam mixture of 98% quality and 7 bar pressure is entered into the system. enters. Saturated liquid comes out from the outlet at 7 bar pressure. heat transfer with the environment, kinetic and potential energy effects are neglected. Mass flow rate from inlet 2 kg/s Specify in terms of .arrow_forwardFor each of the following processes, indicate whether each of the quantities q, w, AH, AU, and AT are positive, negative, or zero. The reversible adiabatic compression of an ideal gas when Pert> Patm. A) The reversible isothermal compression of an ideal gas when 0 Patm: Need detailed and correct answer wrong answer means many downyotesarrow_forwardX Your answer is incorrect. Steam enters a well-insulated turbine operating at steady state at 4 MPa with a specific enthalpy of 3015.4 kJ/kg and a velocity of 10 m/s. The steam expands to the turbine exit where the pressure is 0.07 MPa, specific enthalpy is 2431.7 kJ/kg, and the velocity is 90 m/s. The mass flow rate is 11.95 kg/s. Neglecting potential energy effects, determine the power developed by the turbine, in kW. 3004.4 kWarrow_forward
- 1. The first law of thermodynamics discussesa. Thermal equilibriumb. Energy conservationc. Direction of heat flowd. Entropy is zero at absolute zero temperature 2. A tank contains 1 kg mass gas whose density is 700 kg/m3. The pressure is increased from 1 bar to 3 bar. The approximate specific boundary work of the system isa. Cannot be find since some data is missingb. 285 kJ/kgc. 0 kJ/kgd. 0.285 kJ/kg 3. The nozzle is a device in whicha. Area decreases b. Area increasesc. Velocity decreases d. Velocity increases 4. Choose the correct statement/s with respect to entropy change during a processa. Entropy increases with increase in pressure at constant temperatureb. Entropy increases with increase in temperature at constant pressurec. Entropy can be kept constant by systematically increase both pressure and temperatured. Entropy can not be changed 5. The isentropic process is also called asa. Adiabatic processb. Irreversible adiabatic processc. Reversible adiabatic processd. Reversible…arrow_forwardWhich of the following is the correct statement? a. Irreversible engines have maximum efficiency b. The increase in entropy is obtained from a given quantity of heat at a low temperature c. The entropy represents a maximum amount of work obtainable per degree drop in temperature d. All the reversible engines have the same efficiency e. All the reversible and irreversible engines have the same efficiency f. The change in entropy may be regarded as a measure of the rate of the availability of heat for transformation into work g. All engines are designed as reversible to obtain maximum efficiencyarrow_forwardDetermine the specific exergy of saturated water vapor at 137 °C, where To = 313K, Po = 101.3kPa. Assume the velocity and elevation is zero with reference to the environment. You must use following tables to solve this problem. (answer to 2 decimal) Saturated water temperature table Sat Liq. Temp., Sat Liq. Sat Liq. Sat Liq. vf uf hf sf °C m3/kg kJ/kg kJ/kg kJ/kg.K 30 0.001004 125.73 125.74 0.4368 35 0.001006 146.63 146.64 0.5051 40 0.001008 167.53 167.53 0.5724 45 0.00101 188.43 188.44 0.6386 Saturated water temperature table Temp., Sat. Vap. Sat. Vap. Sat. Vap. Sat. Vap. hg kJ/kg vg ug sg °C m3/kg kJ/kg kJ/kg.K 125 0.7508 2534.5 2713.5 7.0745 126 0.7358 2535.5 2714.8 7.0649 127 0.7208 2536.5 2716.1 7.0553 128 0.7058 2537.5 2717.4 7.0457 129 0.6908 2538.5 2718.7 7.0361 130 0.6758 2539.5 2720.0 7.0265 131 0.6608 2540.5 2721.4 7.0169 132 0.6458 2541.4 2722.7 7.0073 133 0.6308 2542.4 2724.0 6.9977 134 0.6158 2543.4 2725.3 6.9881 6.9785 135 0.6008 2544.4 2726.6 136 0.5858 2545.4 2727.9…arrow_forward
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- Answer true (T) or false (F) as appropriate1. Entropy is a measure of irreversibilities in processes.2. The entropy of the universe must always decrease.3. The thermal efficiency of a Carnot engine is the maximum possible.4. The gas turbine operates on the Rankine cycle.5. The steam turbine operates on the Brayton cycle.arrow_forwardMultiple choice Questions Question No. 2: When a system is taken from state A to state B through a reversible path 1 and again the system is taken to its initial state A from B through different reversible path 2, then what will be the effect on entropy? a.entropy increasesb.entropy decreasesc. entropy remains constantd. none of the abovearrow_forwardAn internal combustion engine is a commonly-analyzed thermodynamic system. In a few sentences, describe the flows of energy and matter across the boundaries of a typical engine.arrow_forward
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