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Getting the electricity from the plant to the light switch

Getting the electricity from the plant to the light switch. Power transmission. Power plants are not located near population centers Need to get the power from the plant to the users Edison created the first power system in New York City in 1882.

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Getting the electricity from the plant to the light switch

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  1. Getting the electricity from the plant to the light switch

  2. Power transmission • Power plants are not located near population centers • Need to get the power from the plant to the users • Edison created the first power system in New York City in 1882. • Used direct current. Could only deliver electricity to customers closer than 1.5 miles away from the power station. • Westinghouse proposed using AC current, which could be more easily and cheaply transmitted. Resulted in the “War of Currents” • Edison waged a PR campaign, claiming AC current was far more dangerous as at frequencies near 60HZ, it had a greater potential to cause cardiac fibrillations. • He and his workers publically electrocuted animals to make their point. • Edison opposed capital punishment, but in an effort to make his point about AC current, he secretly funded the development of the first electric chair.

  3. Power transmission • Energy is lost in transmission lines • Materials that allow electrons to flow through them (current) are called conductors. • Every conductor has some resistance to the flow of current. • Energy is lost as the current flows through the transmission lines • Relationship between voltage, current and the resistance to current flow is given by V = IR

  4. Power transmission • The losses in the line are proportional to the resistance and the current squared or RI2 and the power in the line is proportional to VI (voltage times current) • The solution to these losses is to transmit the power at much higher voltages than the users need, and step the voltage down along the way. That way the current in the line is low, so the power losses are low. • So the voltage is increased before the electricity leaves the power station and then decreased as needed. • This is accomplished with a device called a transformer

  5. Transformers • No not these guys…..

  6. Transformers • A device that transfers energy from one electrical circuit to another using the concept of induction • A changing current in the first circuit (the primary) creates a changing magnetic field. This changing magnetic field induces a changing voltage in the second circuit (the secondary). This effect is called mutual induction.

  7. Transformers • The number of coils in the windings determine if the voltage is increased (stepped up) or decreased (stepped down) • If the number of coils in the secondary is larger than the primary, voltage is stepped up, if it is less it is stepped down.

  8. Power transmission • At the power station, the generator produces 13-25kV. • A step up transformer boosts this to 115 to 765 kV. • Substations reduce the voltages for local distribution. • Transformers on power poles reduce it further to the 240 V generally fed into our homes.

  9. Power Transmission

  10. Health Risks from Power Lines • Power lines are live, if you touch them (and are in contact with the ground) you provide the current a path to ground. AC currents can induce heart fibrillations and cause death. • NO strong link to overhead power lines and increased cancer due to the lines themselves.

  11. Power Grid • A network of power transmission systems • Usually more than one path between points on a network

  12. Power Grid • The US and Canadian power companies are integrated into a single power grid • Allows backups in case of emergencies, utilities can trade electrical energy and it is economical • Circuit breakers (devices which cut off the flow of electricity through the circuit protect against sudden surges in power • The can isolate the problem and help the grid reroute the power flow • If the problem is not isolated, the problem can spread throughout major portions of the grid, causing power interruptions we call blackouts.

  13. US Power Grid • Three grids cover the contiguous 48 states and parts of Canada and Mexico and are known as the Western Interconnection, the Eastern Interconnection, and the Electric Reliability Council of Texas (ERCOT) Interconnection. Collectively they make up what is called the national power grid • Each grid may be broken up into smaller power sharing arrangements, described below. • ECAR - East Central Area Reliability Coordination Agreement • ERCOT - Electric Reliability Council of Texas • FRCC - Florida Reliability Coordinating Council • MAAC - Mid-Atlantic Area Council • MAIN - Mid-America Interconnected Network • MAPP - Mid-Continent Area Power Pool • NPCC - Northeast Power Coordinating Council • SERC - Southeastern Electric Reliability Council • SPP - Southwest Power Pool • WSCC - Western Systems Coordinating Council

  14. Power interruptions • Dropouts -momentary (milliseconds to seconds) loss of power typically caused by a temporary fault on a power line. • Brownouts -a drop in voltage in an electrical power supply, so named because it typically causes lights to dim. Can occur if the demand for electricity on the grid is greater than what it can produce • Blackouts - total loss of power to an area • Note that it doesn’t take a bad storm to cause problems with power line. If demand increases and the power on the line increases, the lines heat up and stretch, causing them to sag. If they come in contact with a tree, then the line can short out.

  15. 2003 Blackout • Affected much of the Notheastern US and parts of Canada August 14, 2003. • Timeline: (Thank you Wilkipedia) • # 12:15 p.m. Incorrect telemetry data renders inoperative the state estimator, a power flow monitoring tool operated by the Ohio-based Midwest Independent Transmission System Operator (MISO). An operator corrects the telemetry problem but forgets to restart the monitoring tool. • # 1:31 p.m. The Eastlake, Ohio generating plant shuts down. The plant is owned by FirstEnergy, an Akron, Ohio-based company that had experienced extensive recent maintenance problems. • # 2:02 p.m. The first of several 345 kV overhead transmission lines in northeast Ohio fails due to contact with a tree in Walton Hills, Ohio. • # 2:14 p.m. An alarm system fails at FirstEnergy's control room and is not repaired. • # 2:27 p.m. A second 345 kV line fails due to contact with a tree.

  16. Timeline • # 3:05 p.m. A 345 kV transmission line known as the Chamberlain-Harding line fails in Parma, south of Cleveland, due to a tree. • # 3:17 p.m. Voltage dips temporarily on the Ohio portion of the grid. Controllers take no action. • # 3:32 p.m. Power shifted by the first failure onto another 345 kV power line, the Hanna-Juniper interconnection, causes it to sag into a tree, bringing it offline as well. While MISO and FirstEnergy controllers concentrate on understanding the failures, they fail to inform system controllers in nearby states. • # 3:39 p.m. A FirstEnergy 138 kV line fails. • # 3:41 p.m. A circuit breaker connecting FirstEnergy's grid with that of American Electric Power is tripped as a 345 kV power line (Star-South Canton interconnection) and fifteen 138 kV lines fail in rapid succession in northern Ohio. Later analysis suggests that this could have been the last possible chance to save the grid if controllers had cut off power to Cleveland at this time. • # 3:46 p.m. A sixth 345 kV line, the Tidd-Canton Central line, trips offline. • # 4:06 p.m. A sustained power surge on some Ohio lines begins an uncontrollable cascade after another 345 kV line (Sammis-Star interconnection) fails. • # 4:09:02 p.m. Voltage sags deeply as Ohio draws 2 GW of power from Michigan, creating simultaneous undervoltage and overcurrent conditions as power attempts to flow in such a way as to rebalance the system's voltage. • # 4:10:34 p.m. Many transmission lines trip out, first in Michigan and then in Ohio, blocking the eastward flow of power around the south shore of Lake Erie. Suddenly bereft of demand, generating stations go offline, creating a huge power deficit. In seconds, power surges in from the east, overloading east-coast power plants whose generators go offline as a protective measure, and the blackout is on. • # 4:10:37 p.m. The eastern and western Michigan power grids disconnect from each other. Two 345 kV lines in Michigan trip. A line that runs from Grand Ledge to Ann Arbor known as the Oneida-Majestic interconnection trips. A short time later, a line running from Bay City south to Flint in Consumers Energy's system known as the Hampton-Thetford line also trips.

  17. Timeline • # 4:10:38 p.m. Cleveland separates from the Pennsylvania grid. • # 4:10:39 p.m. 3.7 GW power flows from the east along the north shore of Lake Erie, through Ontario to southern Michigan and northern Ohio, a flow more than ten times greater than the condition 30 seconds earlier, causing a voltage drop across the system. • # 4:10:40 p.m. Flow flips to 2 GW eastward from Michigan through Ontario (a net reversal of 5.7 GW of power), then reverses back westward again within a half second. • # 4:10:43 p.m. International connections between the United States and Canada begin failing. • # 4:10:45 p.m. Northwestern Ontario separates from the east when the Wawa-Marathon 230 kV line north of Lake Superior disconnects. The first Ontario power plants go offline in response to the unstable voltage and current demand on the system. • # 4:10:46 p.m. New York separates from the New England grid. • # 4:10:50 p.m. Ontario separates from the western New York grid. • # 4:11:57 p.m. The Keith-Waterman, Bunce Creek-Scott 230 kV lines and the St. Clair-Lambton #1 and #2 345 kV lines between Michigan and Ontario fail. • # 4:12:03 p.m. Windsor, Ontario and surrounding areas drop off the grid. • # 4:13 p.m. End of cascading failure. 256 power plants are off-line, 85% of which went offline after the grid separations occurred, most due to the action of automatic protective controls.

  18. 2003 Northeastern Blackout • 50 million people in the dark • Cost economy 1 billion dollars

  19. Getting the electricity from the plant to the light switch • Not a place for wireless technology-or is it?

  20. Wireless is not out of the question • Wireless transmission of electricity was actually pioneered by Nikola Tesla in late 19th century • Wireless power transmission is known as the Tesla effect • Based on inductive power transfer

  21. Tesla’s ideas

  22. Tesla envisioned a world wide electricity network • Tesla envisioned a world wide electricity network

  23. Inductive power transfer • An electric toothbrush recharges through three simple steps. • First, a current from the wall outlet is directed into the charger and into the base coil via an electric wire. • When the current flows through the base coil, the coil generates a magnetic field which in turn induces a current to flow to the coil in the toothbrush handle. • This charges the toothbrush battery.

  24. Inductive power transfer • But the objects have to be in contact, what about over a distance? • Problem is the magnetic field decreases over distance, so the magnetic field generated in the base has to be large, but this reduces efficiency • Using ideas of magnetic resonance, the distance can be greatly increased. • Over large distances and high powers, lasers, radio and microwaves can be used. • Many technology demonstrations of this have already occurred

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