Concept explainers
- (a) Water flows through a shower head steadily at a rate of 10 L/min. An electric resistance heater placed in the water pipe heats the water from 16 to 43°C. Taking the density of water to be 1 kg/L, determine the electric power input to the heater in kW and the rate of entropy generation during this process in kW/K.
FIGURE P7–209
- (b) In an effort to conserve energy, it is proposed to pass the drained warm water at a temperature of 39°C through a heat exchanger to preheat the incoming cold water. If the heat exchanger has an effectiveness of 0.50 (that is, it recovers only half of the energy that can possibly be transferred from the drained water to incoming cold water), determine the electric power input required in this case and the reduction in the rate of entropy generation in the resistance heating section.
a)
The electric power input to the heater and the rate of entropy generation during the process.
Answer to Problem 209RP
The electric power input to the heater is
The rate of entropy generation during the process is
Explanation of Solution
Write the expression for the energy balance of steady flow system.
Here, rate of net energy transfer in to the control volume is
Write the expression to calculate the mass flow rate
Here, density of water at room temperature is
Write the expression for the entropy balance equation of the system for steady flow process.
Here, rate of net entropy in is
Conclusion:
There is only one exit and one inlet, write the equation for the mass balance of steady flow system as,
Here, mass flow rate of water at inlet is
The rate of change in internal energy of system inside the system is zero at steady state,
Substitute 0 for
Here, electric power input to the heater is
From Table A-3 “Properties of common liquids, solids and foods”, the value for the density
Substitute
Substitute
Thus, the electric power input to the heater is
Substitute
Since, water is incompressible substance,
Here, rate of entropy generation at stage 1 is
Substitute
Thus, the rate of entropy generation during the process is
b)
The electric power input required and the reduction in the rate of entropy generation in the resistance heating section.
Answer to Problem 209RP
The electric power input required is
The reduction in the rate of entropy generation in the resistance heating section is
Explanation of Solution
Write the expression to calculate the energy saved
Here, effectiveness of heat exchanger is
Write the expression to calculate the required electric power
Here, electric power input to the heater is
Write the expression to calculate the temperature at which the cold water leaves heat exchanger.
Here, the energy saved is
Write the expression to calulate the entropy generation at stage 2.
Here, rate of entropy generation at stage 2 is
Write the expression to calculate the reduction in the rate of entropy generation within the heating section
Here, reduction in the rate of entropy generation is
Conclusion:
Substitute 0.5 for
Substitute
Substitute
Substitute
Substitute
Thus, the reduction in the rate of entropy generation in the resistance heating section is
Want to see more full solutions like this?
Chapter 7 Solutions
THERMODYNAMICS(SI UNITS,INTL.ED)EBOOK>I
- A compressor draws in 0.5 kgm/s of air with 7 m/s speed, 100 kPa pressure, and 0.95 m3/kgm. The air leaves at 5 m/s, 700 kPa and 0.19 m3/kgm. The internal energy of the air leaving is 90 kJ/kgm greater than that of the air entering. The coolant absorbs heat from the air at the rate of 58 kW. Determine the work in kW.arrow_forwardA centrifugal air compressor receives a gas at a rate of 6 m3 /min and compresses it from 90 kPa to 630 kPa. The initial and final specific volumes are 0.82 m3 /kg and 0.21 m3 /kg, respectively, and the diameters of the duct are 10 cm at the inlet and 5 cm at the exit. Determine (a) the flow work at the boundaries, (b) the mass flow rate, and (c) the change in velocity.(Ans: a) 132.3 kJ/kg, b) 0.122 kg/s, c) 0.311 m/s)arrow_forwardAir flows steadily at the rate of 1 kg/s through an air compressor at 10 m/s, 100 kPa and 1 m3/kg and leaving at 6 m/s, 800 kPa and 0.2 m3/kg. The internal energy of the air leaving is 100 kJ/kg greater than the air entering. Cooling water in the compressor jacket absorbs heat from air at the rate of 100 kW. Find the rate of work done in kW.arrow_forward
- A device submitted to the Pa- tent Office is shown schemati- cally in the figure to the right. Its inventor claims that it can generate 10 kW of electrical power continuously, using only 0.03 kg/s of low-pressure (2 bar) saturated steam, which exits as a mixture of liquid and gas also at 2 bar. A stream of cooling water (0.3 kg/s, liquid at 1 bar) is used in the device; the patent application lists its entrance and exit temperatures as 20 °C and 40 °C, respectively. The de- vice does not have any other heat or material exchanges with the environ- ment. You are asked to give your fully justified opinion as to whether steady-state operation of this device is (or is not) thermodynamically per- missible. If it is not possible to obtain the electrical power stated, what is the maximum power than can be generated? 0.03 kg/s sat. steam, P = 2 bar 0.3 kg/s liq. water, 0 = 20 °C Device liq. + vap. P = 2 bar 8= 40 °Carrow_forwardA nozzle is to be designed to expand steam at the rate of 0.10 kg/s from 500 kPa, 210 C to 100 kPa. Neglect inlet velocity of steam. For nozzle efficiency of 0.9, determine the exit area of the nozzle.arrow_forwardWater flows through a horizontal coil heated from the outside by high temperature flue gases. As it passes through the coil, the water changes state from liquid at 200 kPa and 80 deg C to vapor at 100kPa and 125 deg C. Its entering velocity is 3m/s and exit velocity is 200 m/s. Determine the heat transferred through the coil per unit mass, Enthalpies of inlet and outlet streams are 334.9 kJ/kg and 2726.5 kJ/kgarrow_forward
- The compressors of a production facility maintain the compressed-air lines at a (gauge) pressure of 700 kPa at sea level where the atmospheric pressure is 101 kPa. The average temperature of air is 20°C at the compressor inlet and 24°C in the compressed-air lines. The facility operates 4200 hours a year, and the average price of electricity is $0.078/kWh. Taking the compressor efficiency to be 0.8, the motor efficiency to be 0.92, and the discharge coefficient to be 0.65, determine the energy and money saved per year by sealing a leak equivalent to a 3-mm-diameter hole on the compressed-air line.arrow_forwardAir enters the evaporator section of a window air conditioner at 100 kPa and 27C with a volume flow rate of 6 m3/min. The refrigerant-134a at 120 kPa with a quality of 0.3 enters the evaporator at a rate of 2 kg/min and leaves as saturated vapor at the same pressure. Determine the exit temperature of the air and the rate of entropy generation for this process, assuming (a) the outer surfaces of the air conditioner are insulated and (b) heat is transferred to the evaporator of the air conditioner from the surrounding medium at 32C at a rate of 30 kJ/min.arrow_forwardA turbine is operating steadily and connected to a generator to convert mechanical work to electrical work where the generator has an efficiency of 90%. Steam with 35 m/s enters the turbine at 4.5 MPa and 400 oC where the inlet diameter is 15 cm. The pressure is dropped to 40 kPa at the turbine exit and 10% of the total mass is in the liquid phase. If heat is lost to the surroundings at a rate of 35 kW, determine the electrical work produced by the generator. Neglect the kinetic and potential energy changes through the turbine.arrow_forward
- Air enters a compressor at atmospheric conditions of 20 C and 80 kPa and exits at 800 kPa and 200 C through a 10 cm diameter pipe at 20 m/s. Calculate the rate of heat transfer if the power input is 400 kW.arrow_forwardSteam enters a turbine at 1380 kPa with internal energy of 2705 kJ/kg and specific volume of 0.1655 m3/kg. Exhaust is at 7 kPa with internal energy 2150 kJ/kg and specific volume of 18.36 m3/kg. The heat loss from the turbine is 25 kJ/kg. Determine the work per kg and (b) the steam flow rate in kg/hr if the turbine produces 75 kW.arrow_forwardA turbine operates with superheated steam entering at 900°F and 1,100 psia with a mass flow rate of 70 lbm/s. The exhaust pressure is 5 psia and the turbine efficiency is 0.80. Determine the power output of the turbine in kW.arrow_forward
- Elements Of ElectromagneticsMechanical EngineeringISBN:9780190698614Author:Sadiku, Matthew N. O.Publisher:Oxford University PressMechanics of Materials (10th Edition)Mechanical EngineeringISBN:9780134319650Author:Russell C. HibbelerPublisher:PEARSONThermodynamics: An Engineering ApproachMechanical EngineeringISBN:9781259822674Author:Yunus A. Cengel Dr., Michael A. BolesPublisher:McGraw-Hill Education
- Control Systems EngineeringMechanical EngineeringISBN:9781118170519Author:Norman S. NisePublisher:WILEYMechanics of Materials (MindTap Course List)Mechanical EngineeringISBN:9781337093347Author:Barry J. Goodno, James M. GerePublisher:Cengage LearningEngineering Mechanics: StaticsMechanical EngineeringISBN:9781118807330Author:James L. Meriam, L. G. Kraige, J. N. BoltonPublisher:WILEY