Modeling Thermal Systems - California State …nhuttho/me584/Chapter 6 Thermal Systems.pdfThermal...
Transcript of Modeling Thermal Systems - California State …nhuttho/me584/Chapter 6 Thermal Systems.pdfThermal...
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Modeling Thermal Systems
Dr. Nhut Ho
ME584
Chp6 1
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Agenda
• Basic Effects
• Circuit Analysis of Static Thermal Systems
• Circuit Analysis of Dynamic Thermal Systems
• Active Learning: Pair-share Exercises
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Basic Effects
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Thermal Systems
• Thermal Systems: – Energy is stored and transferred as heat– Exhibit static and dynamic behavior (resistance, capacitance,
time constants. Thermal inductance does not exist.)– Nonlinear, variable-coefficient, distributed-parameter models
• Units: – Temperature T [0C, K, 0F, R]– Heat flow rate Q [J/s, BTU/hr]
• Thermal effects– Conduction– Convection– Radiation– Heat Storage Capacity
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Chp6 5
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Thermal Conduction
• Conduction: Ability of materials to conduct heat
• Fourier’s law of heat conduction
Minus sign indicates …
Temperature drops in direction of heat flow
Chp6 6
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Kt: Metal V. Liquid/GasChp6 7
Kt=Kt(T) => Nonlinear heat conduction equation
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Conduction in Various Shapes
Chp6 9
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Thermal Convection
• Convection: Heat transfer between a surface and a fluid exposed to surface via free or forced convection
• Newton’s law of cooling:
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Thermal Resistance and Convection Coefficient
• Resistance
• Typical Values for Convection Coefficient, h’s
Chp6 11
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Thermal RadiationRadiation: heat transfer (when energy is high) without presence of surrounding medium
Chp6 12
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Thermal Capacitance
• Capacitance: ability to store heat
• Specific heat of various substances
Chp6 13
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Circuit Analysis of Static Thermal Systems
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Example 1: Lowest Cost for Thermal Conductivity
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Example 1: Lowest Cost for Thermal Conductivity
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Example 1: Lowest Cost for Thermal Conductivity
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Example 2: Pair-Share: Heat Loss Through Window
• Calculate the amount of heat loss (in Watts) through an uncovered window in a home. The temperature difference between the air inside and outside of the house is 200C, with moderate convection on each side of the glass. The size of the glass is 0.75m by 1.2 m, and the thickness is 3 mm.
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Example 2: Heat Loss Through WindowChp6 19
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Example 2: Heat Loss Through WindowChp6 20
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Example 3: Radiator Hose
• The radiator hose on an automobile is made of something similar to BunaTM rubber. The internal diameter of the hose is 50 mm, its length is 200mm, and its thickness is 6 mm. The water on the inside is maintained at 1000C, and the outside air temperature is 500C. Calculate how much heat is conducted through the hose.
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Example 3: Radiator Hose
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Eq. 6.10 (pg. 178)
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Example 4: Pair-Share: Iron Pipe
A ¾ inch pipe (ID = .824 inch, OD = 1.050 inches) is used to transmit hot water. The internal water temperature is 1200F, and the ambient air temperature is 750F. Consider a pipe that is 5 feet in length.– Calculate how much heat is transferred from the
water to air.– If a spongy rubber tape that is 0.1 inch thick is placed
on the outside of the pipe, calculate how much heat is transferred.
– What is the reduction in heat loss with the use of the rubber insulation?
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Example 4: Pair-Share: Iron PipeChp6 24
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Example 4: Pair-Share: Iron PipeChp6 25
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Example 4: Pair-Share: Iron PipeChp6 26
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Circuit Analysis of Dynamic Thermal Systems
Chp6 27
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Model ClassificationChap6 28
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Model Classification TreeChap 6 29
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Dynamic Thermal Systems
• Dynamic response: time rate of change of temperature during process due to large heat capacity or small time duration
• Diffusion equation, 2nd order partial differential equation (PDE) in space and time, is used to model this process (beyond scope of class)
• Take lumped-parameter model approach under certain conditions
Chp6 30
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Lumped Parameter Model (LPM)
• LPM assumes that all properties of thermal resistance and capacitance are lumped at selected points in space and produces a set of ordinary differential equations (ODEs) in time
• Approximating PDEs in space with ODEs in time at certain locations in the system requires breaking system into lumps
• Choice of single-lumped or multiple-lumped capacitance model depends on convection and conduction resistances
• Example: Model the temperature in a house • Use a single temperature => a single ODE
• Take a representative temperature for each room => an ODE for each room, leading to several equations
• Either model is still more manageable than if lumping were not performed
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Biot Number
Number of lumps required for accuracy depends on ratio of conduction and convection resistances, i.e., dimensionless Biot number Nb
Chp6 32
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Small Biot Number (Nb < 0.1)
• Rcond << Rconv → same temperature in solid
• Dominant temperature difference is between surface and free-stream fluid
• Model with single lumped capacitance, heat capacity of solid and convection heat transfer
• Ignore thermal conduction resistance in solid
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Large Biot Number (Nb > 0.1)
• Rcond >> Rconv → different temperatures in solid, and between solid and free-fluid stream
• Model with several lumps of capacitance and determine temperatures at several points inside solid as a function of time
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Example 5: Single-Lumped Capacitance Model (SLCM): Quenching
• SLC model applies when heat capacity is significant (Nb is small)
• Example: Quenching is a process in which a heated object is placed into a liquid bath. The rapid cooling that occurs can improve certain properties such as hardness. Consider a copper sphere 1 in. in diameter with k = 212 BTU/hr-ft-0F at 5700F and immersed in a fluid such that h = 0.5 BTU/hr-ft2
(See Figure below).
– Show that its temperature can be considered uniform, and develop a model of the sphere’s temperature as a function of the temperature T0 of the surrounding fluid.
– Show that the RC circuit (see below) is analogous to the thermal model of the sphere’s quenching process.
Chp6 35
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Example 5: Single-Lumped Capacitance Model (SLCM): Quenching
• As = 4π(1/24)2=2.18x10-2 ft2, Volume = (4/3)π(1/24)3=3.03x10-4 ft3
• Lc=V/As = 0.0139, Nb = hLc/k = 3.28x10-5 << 1
• Biot criterion: treat sphere as a single-lumped system with a single uniform T
Chp6 36
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Multiple-Lumped Capacitance Model (MLCM)
• Models one-dimensional heat conduction with an equivalent thermal circuit with lumped capacitance and resistance
– Capacitance at nodes connected by resistance elements, analogous to mechanical system’s discrete masses connected by massless springs
– Accuracy depends on number of lumps: large Bio number requires division into several nodes
– Thermal properties are assumed homogeneous
Chp6 37
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Multiple-Lumped Capacitance Model (MLCM)
• Models one-dimension heat transfer in a flat plate with mass M and thickness L (<< length and width) by dividing into n elements
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Constant Surface Temperature Sources• When convection coefficients are high, convection resistance
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Constant Surface Temperature Sources
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Convection Surface Temperature Sources
• When convection coefficients are not high, convection resistance will be large and there will be convection resistance between surface temperature and free-stream temperature, and significant temperature difference between them
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Convection Surface Temperature SourcesChp6 43
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Example 6: Thermal Plant Boiler Chp6 44
Shown in the figure is a boiler used in a thermal energy plant. Write the modeling equations for the system, and derive a differential equation for the temperature inside the boiler as a function of the ambient temperature and the heat input. State the expressions for the time constant and the steady-state temperature
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Example 6: Thermal Plant Boiler Chp6 45
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Example 7: PS: Pool Water Heater • Shown below is a swimming pool operating in cool weather. The pool has
a heater that provides a heat input of qh watts. The water depth varies from 1.2m to 3m, and the pool is 5m wide by 10 m long. A pump runs continuously to keep the water thoroughly mixed.– Calculate the Biot number, and justify the assumption that the pool can be
treated as a single-lumped capacitance model– Assuming that the significant heat transfer is the convection at the water
surface and that no heat transfers out the sides and bottoms, write the modeling equations for the system using a single-lumped parameter capacitor model, and derive a differential equation for the temperature of the water as a function of the ambient temperature and the heat input.
– Calculate the value of the time constant of the system. If a period of one time constant would be enough time to “take the chill off,” would you recommend leaving the heater on all the time or turning it off overnight?
– State the expression for the steady-state temperature of the water. If the ambient temperature were 200C and the desired water temperature were 250C, what size heater would be required (in watts)?
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Example 7: PS: Swimming Pool Heater Chp6 47
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Example 7: PS: Swimming Pool Heater Chp6 48
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Example 7: PS: Swimming Pool Heater Chp6 49
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Example 8: Propane Tank• A tank 75% (by volume) full of liquid propane is taken from a warehouse and
placed in the direct sunlight on a hot summer day. We are concerned about the internal temperature (and therefore the internal pressure) of the tank as it sits in the sun. We want to know how long it takes to heat up and what is its final steady-state temperature.
– Model the tank as a sphere 1 foot in diameter. The walls of the tank are steel of 0.100 of an inch thick. The temperature inside the warehouse is 900F, and the outside air temperature is 1000F. (The tank is in Texas!) The solar insolation for this particular day is 900 watts/m2 = 285 (Btu/hr)/ft2. You should consider the sun as a constant heat flow source of energy over the exposed surface are of the sphere. The density of liquid propane is 20.8 lbm/ft3. The density of steel is 490 lbm/ft3. The specific heat of liquid propane is 0.58 Btu/(lbm 0F). The specific heat of steel is 0.11 Btu/(lbm 0F). The wind velocity is such that you should use a convection coefficient for high free convection or low forced convection.
– Model this system, and derive a differential equation for the internal temperature of the propane as a function of the solar heat input and the ambient temperature (with a given initial temperature). Calculate the time constant for the system, and state how long it will take for the tank to be at its steady-state temperature. What will the steady-state temperature be for given conditions?
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Example 8: Propane Tank
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Example 8: Propane Tank
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Example 8: Propane TankChp6 53
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Example 9: Pair-Share: Fish Tank
• A fish tank is fabricated using 4mm Plexiglas walls. The water on the inside of the tank is maintained at a constant temperature of 260C. The ambient room temperature is 220C. We are interested in modeling the heat transfer through the walls of the tank if there is a sudden change in room temperature. The inside of the tank has water that is circulated with a pump and therefore should have a convection coefficient on the lower end of forced convection with water. The outside of the tank has air that should have a convection coefficient on the upper end of free convection with air. – Calculate the Biot number for the inside and outside surfaces. Based
upon these numbers, can lumped parameter modeling be used to model the temperature distribution in the Plexiglas? Can you assume that the convection heat transfer is so good in the water, that the water temperature on the inside surfaces is constant?
– Based upon the Biot number, how many lumps should be considered in the lumped parameter analysis?
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Example 9: Pair-Share: Fish TankChp6 55
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Homework 6: Chapter 6
• 6.2
• 6.7
• 6.11
• 6.13
• 6.16
• 6.23
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References
• Woods, R. L., and Lawrence, K., Modeling and Simulation of Dynamic Systems, Prentice Hall, 1997.
• Close, C. M., Frederick, D. H., Newell, J. C., Modeling and Analysis of Dynamic Systems, Third Edition, Wiley, 2002
• Palm, W. J., Modeling, Analysis, and Control of Dynamic Systems
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