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372612
Energy for the Home
Descrição
AS Level Physics (P1: Energy for the Home) Mapa Mental sobre Energy for the Home, criado por Oliver Wood em 19-11-2013.
Sem etiquetas
p1: energy for the home
physics
physics
p1: energy for the home
as level
Mapa Mental por
Oliver Wood
, atualizado more than 1 year ago
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Criado por
Oliver Wood
aproximadamente 11 anos atrás
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Resumo de Recurso
Energy for the Home
Energy
Energy flow
Hot body to cold body
Energy decreases as energy flows out
Measuring temperature
Specific Heat Capacty
Amount of energy needed to raise 1kg by 1°C
J/kg °C
Energy transfer by Specific Heat Capacity:
Energy transferred = mass x spec. heat capacity x temp. change
Specific Latent Heat
Energy needed to melt/boil 1kg of a material
Measured in (J/kg)
When changing states, energy is transferred but temp. remains constant
Energy is used to break intermolecular bonds instead
Energy transfer = mass x specific latent heat
E.g. Water SLH = 340,000
Insulation
Double glazing
Reduces heat lost by convection
two glass panels filled with vaccum OR gas
E.g. argon
Loft insulation
Reduces heat lost by conduction and convection
Hot air in home rises
Stops energy transfer between ceiling to loft AND ceiling to roof
Cavity Wall
Reduces conduction and convection
Air in foam insulates
Air is trapped by foam
Insulation blocks
Shiny foil on either side
Reflects sun's energy back during summer
Home's energy is reflected inward during winter
Conduction, Convection, Radiation
Conduction
Kinetic energy between particles
Convection
Gas expands when heated
Makes it less dense so rises
Density in kg/m3 OR g/m3
Density = Mass/Volume
Radiation
Needs no medium
Travels through vacuum
Energy Efficiency
efficiency = useful energy output (x100%) / total energy input
Shown by Sankey diagrams
Source energy is lost to 'sink'
Different insulation types vary in cost and efficiency
Payback time = Cost of Insulation / Annual Saving
All things waste some energy
Efficient buildings lose little energy to surroundings
Designers and architects consider this
Waves
Wave Terms;
Amplitude = maximum displacement from rest position
Crest = Highest point
Trough = Lowest point
Wavelength = Distance between two successive points
Wave speed = Frequency x Wavelength
Measurements
Frequency: Hertz (Hz)
Wavelength: Metres (m)
Speed: Metres/second (m/s)
Types & Properties
Radio
Microwave
Infra-red
Visible
Ultra-violet
X-ray
Gamma
Changing Waves
Refraction
Occurs as wave enters a denser medium
Wave speed changes
(Frequency stays same but wavelength changes)
Diffraction
Wave spreads out after passing through gap
90° when wavelength = gap size
Noticeable in telescopes and microscopes
Cooking and Communicating
Infrared doesn't penetrate food well
Microwaves penetrate 1cm
Reflected by special glass
EM Spectrum
Energy transfer depends on
Wavelength
Frequency
High frequency (short wavelength) transfers more energy
Microwave lengths
Between 1mm and 30cm
Mobile phones = longer wavelengths
Transfer less energy
Microwave communication
Used over long distances
Transmitter + receiver need line of sight
E.g. top of high buildings
Satellites are used
Signal recieved from Earth
Amplified
Retransmitted to Earth
Signal strength
Little diffraction
Strong weather and large water bodies scatter signals
Curvature of earth
Limits line of sight
Transmitters must be high up/near
Interference with equipment
Bannings
Hospitals
Planes
Light and Lasers
Morse Code
Series of dots and dashes
A digital signal
Signals
Can be sent by Electromagnetic Spectrum or electricity:
Almost instantaneous
Criticising each method
Speed?
Can it be seen?
Can wires be cut?
How far must it travel?
Laser Light
Single frequency
(White light has many at once)
In phase (Syncronised)
White light is mixed)
CDs
Surface is pitted
Pits = digital signal
Laser shone on surface
DIfferent reflections provide signal
Critical Angles
More dense --> Less dense
°Refraction > °Incidence
When °Incidence makes °refraction = 90°
That °incidence is 'critical angle'
When °Incidence is GREATER than critical angle
Total internal reflection occurs (TIR)
Use in communicatinons
Fibre optics
Telephone
Computer
Data travels at speed of light (200,000km/s in glass)
Endoscopy
Light sent down optical fibres
Reflects off patient's insides
Light is picked up by endoscope
Data Transmission
Infrared signals for electronics
LED pulses a digital IR signal
Start command
Instruction command
device code
Stop command
Analogue/Digital switch
2009 - 2015
Greater program choice
Interaction
Subtitles
Digital Signal advantages
No damaging interference from other waves
Multiplexing
Multiple waves combined and sent together
Wireless Signals
Less atmospheric refraction at high frequencies
Digital Audio Broacasting (DAB)
Greater range
Eliminates interference
Radio reflection
Reflected by the Ionosphere
Signal can pass around Earth
Microwaves pass through Ionosphere
Comms. satellites
Geostationary orbit
Problems
Radiowaves diffract
Satellites require focused signals
Beams split (diverge)
Stable Earth
Earthquakes
Ozone Depletion
Found in Stratosphere 10km - 30km up
Filters UV
Chlouroflourocarbons (CFCs)
Depletion highest at the poles
Monitored using IR satellites
Anexos de mídia
saNKEY.gif (image/gif)
Wave_Diagram (image/jpg)
Wave_properties.PNG (image/PNG)
criticalangle (image/png)
multiplexing (image/jpg)
P_and_S_waves.gif (image/gif)
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