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Chapter 10: part 2 Ohms Law Superconductivity Parallel and Series Circuits Delivery of Power in a Circuit Pricing Energy Fuel Cells
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Energy in the News
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Ohm’s Law V = I * R V= voltage, units of volts I= current, units of amperes (coulombs per second) R =resistance, units of ohms
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Physical Meaning Resistance: resistance to flow of electrons (pipe: wire) Voltage: electrical potential ( like pressure head for a pump driving flow= potential energy per unit charge) 1 volt = 1 Joule per coulomb Current: quantity of electrons flowing
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Toaster What is the current?
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Resistive Heating Power = Voltage * Current P= V*I Plug in ohms law, V= I* R P = I 2 * R Electric stoves, toasters and hair dryers: What do they have in common? Expected wattage?
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Electrical Energy: Work or Heat
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Superconductivity Major problem with energy transfer: transmission losses ~10% High temperature superconductors; greatly reduce losses High temperature superconductors-will conduct at temperatures Achievable with liquid nitrogen (still pretty cold!!) Ceramics: latest superconductors. Normally insulators. Structure of ceramics: like high pressure silicates (Walker) High pressure pressure at LDEO.
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Simple Circuits Parallel: everything connected by the same circle of Wire Series: a set of interconnected circular circuits
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Meissner Effect Superconducting materials exclude magnetic fields Therefore, a magnet near a superconductor will Stay in the air Result: magnetic levitation (MAGLEV) Bullet trains in Japan and Germany use MAGLEV
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Series and Parallel Circuits Parallel circuits: Resistances add Series circuits: Currents add Household circuits: Which type? Fire danger? How to reduce fire hazard?
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Batteries: Series and Parallel Which arrangement produces More voltage? More current? More resistance? More power?
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Typical Household Circuit What should be included to ensure safety?
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Prices of Energy Typical prices of energy per kilowatt hour? Locally (on Long Island)? Nationally? Rates for wind power?
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Payback Time on Energy Efficiency Energy efficiency is an investment Example; compact fluorescent bulbs Cost; $10 each (10 times as much), last 10 times as long Use 1/4 the energy of incandescent bulbs. Payback time=time to pay back the extra cost for energy Saving equipment with savings on energy cost.
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Quote from Prizewinning Engineer What will the lights of the future be?
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L.E.D.s Light Emitting Diodes Lumens per Watt Lumens: measure Of light intensity How do incandescents Mercury, halogens Low pressure sodium Fluorescents measure Up?
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L.E.D.s How They Work Semi-conductor N-type layer- Supplies electrons P-type layer: supplies positive Charges or holes In the active layer Photons of light Emitted. Solar cells: also use Semi-conductors N and P type layers
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Lighting Whales with LEDs Can’t use visible light? Why? Light is in near infra-red Visible to videotape but not to whales LEDS allow selection of wavelength Of light. LEDS work well at high pressures 1 atmosphere per 10 meters of water
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Common Uses of LEDs Upper left; SGT Pepper costumes Upper Right; Traffic light Lower Right; Taillights, turn signals Lower left: signs
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Fuel Cells Fuel cell: combines a fuel ( Often natural gas or hydrogen) With oxygen. Uses the chemical Energy to produce electricity. Present cost: $3000 to $4000 per Kilowatt: too expensive
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Greenhouse Gas Emissions Why are zero emissions Vehicles (electric cars) Not necessarily the best Choice?
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Cost for Fuel Cells :Medium Term Life cycle costs: cents Per mile Yellow: Fuel Purple: Electricity Dark blue: Maintenance Brown: Fuel Storage Red:Battery Light blue: Fuel Cell Green:Basic Vehicle Cost
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Long Term: Costs for Fuel Cells Life cycle costs: cents Per mile Yellow: fuel Purple: electricity Dark blue: Maintenance Brown: Fuel Storage Red:Battery Light blue: Fuel Cell Green:Basic Vehicle Cost
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Types of Fuel Cells PEM: Proton exchange membrane Fuel cell cars: can be refueled in minutes (unlike ZEVs) Range similar if natural gas or methanol powered, Very Quiet!! Use 2/5 of energy of typical cars with internal combustion engines Drawbacks: platinum catalyst in short supply
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Fuel Cell: Central Park, New York
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Fuel Cell Powered Bus
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Fuel Cells: The Future Daimler/Chrysler and General Motors: Fuel cell powered car By 2004. Honda: Fuel cell powered car by 2003. Roughly 2.5 to 3 times as efficient as typical gasoline powered cars. Wind farms on 6% of land in Great Plains: enough to produce hydrogen For all USA cars and light trucks if all fuel cell powered!! Photovoltaic cells (solar cells) on 1% of US land needed to provide hydrogen for US Fuel cell fleet.
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