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L 17 - Thermodynamics [2]. Science that studies the relationships between heat and work it applies to all living and non-living things it predicts the direction of natural processes why ice melts (rather than getting colder!) why gases expand to fill entire volumes. L 1. Metal bar at T 1.
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L 17 - Thermodynamics [2] • Science that studies the relationships between heat and work • it applies to all living and non-living things • it predicts the direction of natural processes • why ice melts (rather than getting colder!) • why gases expand to fill entire volumes
L1 Metal bar at T1 Metal bar at T2 > T1 L2 Thermal Expansion • Expansion occurs in all dimensions • Expansion must be taken into account when designing roads and bridges in climates that vary significantly from winter to summer – all materials expand, steel, concrete, asphalt . . .
Areas and volumes expand too! cold hot cold hot
Does the whole get bigger or smaller when heated? cold hot Both the inner and outer diameters increase when the ring is heated
Bi-Metal strips • thermal expansion of metals is put to good use in a bi-metallic strip. • this is two strips of different metals bonded together metal A metalB
Heating a Bi-metal strip • when heat is applied to the bi-metallic strip, both metals expand, but by different amounts! • result: this can be used as a switch – in your coffee maker!
Bi-Metal strip thermal switch when a preset temperature is reached, the bi-metallic strip opens up
350.0 °F Thermocouples- measure Temp. • The temperature sensor you stick into your turkey is a thermocouple • it is composed of 2 wires composed of different metals welded together - when it gets hot it makes electrical current flow
Thermocouples protect you! • a thermocouple is used in gas heaters and dryers to protect against explosions • a thermocouple is placed in the pilot light • as long as the pilot light is on, the thermocouple is hot and current flows • a circuit senses the current and allows the main gas valve to open • if the pilot light is out, the circuit prevents the main gas valve from opening
Internal energy, Temperature and Heat • in a gas the molecules have energy because they are moving. • the sum of all the energies of all the molecules is the system’s internal energy • the temperature of the system is a measure of how much internal energy it has, Temperature Internal Energy
System B at temp TB System A at temp TA Heat what is it ? ? ? • Heat is the energy that flows from one system to another because of their temperature difference. • Heat stops flowing when the two systems come to the same temperature. • Heat was considered to be an actual fluid (caloric), but it is NOT a fluid- it is energy!
Heat Flow and the laws of thermodynamics • System A has a certain amount of internal energy and so does system B • If energy is transferred and the internal energy of B decreases by some amount then internal energy of A must increase by the same amount. [the first law] • If the temperature of A is less than the temperature of B then heat flows from B to A (hot to cold). [the second law]
1st and 2nd Laws of Thermodynamics • the 1st law says that energy is conserved whatever energy system A gains must be accounted for by the energy that B lost. (assuming that the systems are isolated so that they do not interact with any other systems) • The 2nd law specifies the direction of heat flow hot to cold (ice melts!)
Reverse heat flow- why ice melts Notice that the 1st law does not say that ice must melt. The first law does not prohibit that the ice from getting colder and the water warmer! The 2nd law specifies the direction of heat flow in natural (spontaneous)processes.
A refrigerator is a device that moves heat from something cold (inside) to something hot (the room). But what about refrigerators? needs to be plugged in to work! [energy in]
Refrigerators and the 2nd Law • Does this violate the 2nd law? NO, because it is not a spontaneous process • Refrigerators require energy input (work) (electricity) to operate. • Heat does not flow spontaneously from cold to hot, but it can be made to flow backwards if there is an input of WORK. • It uses electrical energy to pump heat from cold to hot.
Heat flow • HEAT the energy that flows from one system to another because of temperature differences. • But how does it flow? Three ways: • convection • conduction • radiation
Convection • heat is carried from place to place by the bulk movement of either liquids or gases • does not apply to solids • when water is boiled, hot liquid rises and mixes with cooler liquid, thus the heat is transferred • Hot air rises: • want heat into lower level of house (winter) • cooled air into upper levels (summer)
Conduction iron is a particularly poor conductor of heat • heat is transferred directly through a material, with no bulk movement of stuff • only energy moves
heat conduction HOT COLD Heat Flow
Thermal Conductivity • The effectiveness of a material in conducting heat is characterized by a parameter called the thermal conductivity • there are good thermal conductors (metals) and poor ones (insulators)