Presentation is loading. Please wait.

Presentation is loading. Please wait.

Radiation C ontents: Basic Concept Example Whiteboards.

Published byDomenic Snow Modified over 9 years ago

Similar presentations

Presentation on theme: "Radiation C ontents: Basic Concept Example Whiteboards."— Presentation transcript:

1 Radiation C ontents: Basic Concept Example Whiteboards

2 Radiation TOC Hot objects radiate photons (black body radiation) Heating up a poker Demo - Show red hot paperclip Demo – Start silver/black demo Bonfire/barn fire/stoves The sun Frost Preheat the oven/drying tennis balls

3 Radiation ΔQ / t = Heat flow rate in J/s or Watts e = emissivity (0 < e < 1) (Temp?) σ = 5.67x10 -8 Wm -2 K -4 (Stefan Boltzmann constant) A = Area (m 2 ) T = High temperature (K)

4 Net heat transfer (emitted) - (absorbed) T 1 = object T 2 = surroundings e = e?

5 Q/t = (0.75)(1.72 m 2 )(5.67E-8 Wm -2 K -4 )((273.15+33 K) 4 -(273.15+18 K) 4 ) = 116.97 W 120 W Example: A person has a surface area of 1.72 m 2 and a skin temperature of 33 o C. They are standing in a room whose walls are at 18 o C, and their skin has an emissivity of 0.75. What is the net rate of radiative heat flow out of their body?

6 Demo – check temperatures on radiation demo Silver lined blankets/bags reflect radiation back to you

7 Radiation 1-3

8 Q/t = (0.92)(0.0096 m 2 )(5.67E-8 Wm -2 K -4 )((273.15 + 20.50) 4 -(273.15+20.00 K) 4 ) = 0.025296… W 0.025 W, 25 mW A power converter is a cube 4.0 cm on a side, and is made of black plastic with an emissivity of 0.92. It maintains a temperature of 20.50 o C in a room whose walls are at 20.00 o C. What is its net rate of radiative heat transfer?

9 34 = e(4  (0.03 m) 2 )(5.67E-8 Wm -2 K -4 )((273.15 + 250.0) 4 -(273.15+19.0 K) 4 ) 0.78 A 3.0 cm radius (sperical) light bulb radiates 34 Watts of energy. If it has a surface temperature of 250.0 o C in a room whose walls are at 19.0 o C, what is its emissivity?

10 1000 = (0.95)(6.00 m 2 )(5.67E-8 Wm -2 K -4 )(T 4 -(273.15+18.00 K) 4 ), T = 318.417 T = 45 o C 318 K, 45 o C If you put a 1000. Watt hair dryer into a 1.00 m cube box with an emissivity of 0.95, it would heat up the box’s surface until energy flowed out (assume radiatively) as fast as it flowed in. What would be the surface temperature of the box in Celsius if the room it was in had walls at 18.0 o C?

Download ppt "Radiation C ontents: Basic Concept Example Whiteboards."

Similar presentations

Day Topic: Finish Convection, Begin Radiation

Day Topic: Finish Convection, Begin Radiation
As close to chemistry as we can get

As close to chemistry as we can get
Wind Power: For wind power A = frontal area (πr 2 ) m 2 ρ = density of air (≈1.3 kg/m 3 ) v = wind speed Ex – What max power can you get from a wind turbine.

Wind Power: For wind power A = frontal area (πr 2 ) m 2 ρ = density of air (≈1.3 kg/m 3 ) v = wind speed Ex – What max power can you get from a wind turbine.
Physics 101: Lecture 28, Pg 1 Physics 101: Lecture 28 The Transfer of Heat l Today’s lecture will cover Textbook Chapter 13 è The Transfer of Heat »Convection.

Physics 101: Lecture 28, Pg 1 Physics 101: Lecture 28 The Transfer of Heat l Today’s lecture will cover Textbook Chapter 13 è The Transfer of Heat »Convection.
Physics 101: Chapter 13 The Transfer of Heat

Physics 101: Chapter 13 The Transfer of Heat
PHYSICS 231 INTRODUCTORY PHYSICS I

PHYSICS 231 INTRODUCTORY PHYSICS I
Matter and Energy.

Matter and Energy.
MECHANISM OF HEAT TRANSFER Mode of Heat transfer Conduction Convection

MECHANISM OF HEAT TRANSFER Mode of Heat transfer Conduction Convection
Heat Engines C ontents: Basic Concept Carnot cycle Energy flow Solving problems Whiteboards Heat Pumps Whiteboard.

Heat Engines C ontents: Basic Concept Carnot cycle Energy flow Solving problems Whiteboards Heat Pumps Whiteboard.
Physics 101: Lecture 26 Conduction, Convection, Radiation

Physics 101: Lecture 26 Conduction, Convection, Radiation
Heat Physics 102 Professor Lee Carkner Lecture 3 “If you can’t stand the heat, get out of the kitchen.” -Harry S. Truman.

Heat Physics 102 Professor Lee Carkner Lecture 3 “If you can’t stand the heat, get out of the kitchen.” -Harry S. Truman.
Solar Radiation Emission and Absorption

Solar Radiation Emission and Absorption
Heat Physics 102 Professor Lee Carkner Lecture 2.

Heat Physics 102 Professor Lee Carkner Lecture 2.
Announcements 9/14/11 Prayer Remember, HW solutions are being posted in hallway around corner from where you turn in the homework, right next to the CSR.

Announcements 9/14/11 Prayer Remember, HW solutions are being posted in hallway around corner from where you turn in the homework, right next to the CSR.
Announcements 1/21/11 Prayer Lab 2 starts tomorrow Homework solutions are being posted in hallway around corner from where you turn in the homework, right.

Announcements 1/21/11 Prayer Lab 2 starts tomorrow Homework solutions are being posted in hallway around corner from where you turn in the homework, right.
Heat Physics 102 Professor Lee Carkner Lecture 3 “If you can’t stand the heat, get out of the kitchen.” -Harry S. Truman.

Heat Physics 102 Professor Lee Carkner Lecture 3 “If you can’t stand the heat, get out of the kitchen.” -Harry S. Truman.
Thermal Equilibration between 2 things : “Review” 1.No possible phase changes. Q H + Q C = 0. Solve for T f 2.Possible phase changes. Divide the process.

Thermal Equilibration between 2 things : “Review” 1.No possible phase changes. Q H + Q C = 0. Solve for T f 2.Possible phase changes. Divide the process.
Solar Radiation Emission and Absorption

Solar Radiation Emission and Absorption
P-V Diagrams and processes Contents:

P-V Diagrams and processes Contents:
Blackbody Radiation & Atomic Spectra. “Light” – From gamma-rays to radio waves The vast majority of information we have about astronomical objects comes.

Blackbody Radiation & Atomic Spectra. “Light” – From gamma-rays to radio waves The vast majority of information we have about astronomical objects comes.

Similar presentations

Ads by Google