1. Hydroelectricity & OTEC

2. Watermills appeared as early as 100 BC. Watermills appeared as early as 100 BC. By 1200 water was used to operate hammers in ironworks By 1200 water was used to operate hammers in ironworks By 1500 it was the primary source of industrial power By 1500 it was the primary source of industrial power Today hydropower is used primarily to generate electricity Today hydropower is used primarily to generate electricity

3. First Hydroelectric Generator Located at Cragside, a country house in Northumberland, England. Located at Cragside, a country house in Northumberland, England. country house Northumberland England country house Northumberland England In 1870, water from one of the estate's lakes was used to drive a Siemens dynamo in what was probably the world's first hydroelectric power station. In 1870, water from one of the estate's lakes was used to drive a Siemens dynamo in what was probably the world's first hydroelectric power station.1870Siemens dynamo power station1870Siemens dynamo power station

4. Is hydroelectricity a form of solar power? A. Yes B. No

5. Water cycle as a great big heat engine

6. Heat Engine Q hot – Q cold = W Q hot – Q cold = W Efficiency: e = W/Q hot Efficiency: e = W/Q hot

7. What is the heat source in the water cycle? A. The Sun B. Geothermal C. Ocean depths D. The Moon

8. What is the cold reservoir in the water cycle? A. The Sun B. Geothermal C. Ocean depths D. The Moon

9. Hydroelectric Dams Converts gravitational potential energy of mass of water into electricity Converts gravitational potential energy of mass of water into electricity Height between surface of reservoir and river below is the head Height between surface of reservoir and river below is the head

10. Hydroelectric Dams Potential Energy  Kinetic Energy Potential Energy  Kinetic Energy mgh = ½mv 2 mgh = ½mv 2 “h” is the head of the dam “h” is the head of the dam Modern hydroelectric plants convert about 90% of PE into electricity Modern hydroelectric plants convert about 90% of PE into electricity

11. How Dams Produce Electricity

12. High Head Dams Head is up to 1000ft. Head is up to 1000ft. A lot of energy per liter of water that flows through. A lot of energy per liter of water that flows through. Can get by with smaller flows. Can get by with smaller flows.

13. Low Head Dams Head as low as 10 ft. Head as low as 10 ft. Not much energy per liter of water. Not much energy per liter of water. Need a higher flow rate to get as much electricity Need a higher flow rate to get as much electricity

14. Contra Dam Ticino, Switzerland

15. Example Hoover Dam is rated at 2,451 MW. Hoover Dam is rated at 2,451 MW. 1 W = 1J/s 1 W = 1J/s Head of Hoover Dam = 221 m Head of Hoover Dam = 221 m Mass of 1 liter of water is 1 kg. Mass of 1 liter of water is 1 kg. If the dam is 90% efficient at generating electricity, how much water flows through the dam each second? If the dam is 90% efficient at generating electricity, how much water flows through the dam each second?

16. Volume flow rate of Hoover Dam 2.723 x 10 9 l/s 2.723 x 10 9 l/s 2.451 x 10 9 l/s 2.451 x 10 9 l/s 1.257 x 10 6 l/s 1.257 x 10 6 l/s 1.132 x 10 6 l/s 1.132 x 10 6 l/s

17. Example 2,451 MW/0.90 = 2,723.3 MW 2,451 MW/0.90 = 2,723.3 MW 2,451 MW of electricity needs 2723 MW from water 2,451 MW of electricity needs 2723 MW from water 2.723 x 10 9 J/s = m(9.8m/s 2 )(221m) 2.723 x 10 9 J/s = m(9.8m/s 2 )(221m) m is in kg/s m is in kg/s m = 2.723 x 10 9 J/s/2165.8 m 2 /s 2 m = 2.723 x 10 9 J/s/2165.8 m 2 /s 2 m = 1.257 x 10 6 kg/s  1.257 x 10 6 l/s m = 1.257 x 10 6 kg/s  1.257 x 10 6 l/s

18. US Hydroelectric Production

19. Existing hydroelectric plants (yellow) and potential high head/low power energy sites (orange)

21. Principal Dams in the US

23. Top Ten Countries for Hydroelectricity CountryAnnual Hydroelectric Production (TWh) Installed Capacity Capacity Factor Percent of all electricity China652.05196.790.3722.25 Canada369.599.9740.5961.12 Brasil363.869.0800.5685.56 United States250.679.5110.425.74 Russia167.045.0000.4217.64 Norway140.427.5280.4998.25 India115.633.6000.4315.8 Venezuela86.867.17 Japan69.227.2290.377.21 Sweden65.516.2090.4644.34

24. Top Ten Largest Hydroelectric Plants DamCountryCompletedPower (GW) Three Gorges DamChina2008/1118.3/22.5 ItaipuBrazil/Paraguay1984/91/0314.0 Guri (Simon Bolivar)Venezuela198610.2 TucuruiBrazil19848.37 Grand CouleeUnited States1942/806.81 Sayano ShushenskayaRussia1985/896.4 krasnoyarskayaRussia19726.0 Robert-BourassaCanada19815.62 Churchill FallsCanada19715.43 Longtan DamChina20094.9/6.3

25. Which country generates the most hydroelectricity? A. United States B. Venezuela C. Canada D. China

26. Three Gorges Dam (World’s Largest)

27. Ten largest Dams Under Construction ProjectCountryCapacity (GW)Completion Xiluodu DamChina12.62015 Siang Upper HE Project India11.02024 TaSang DamBurma7.12022 Xiangjiaba DamChina 6.4 2015 Nuozhadu DamChina5.92017 Jinping 2 HP Station China4.82014 Laxiwa DamChina4.22010 Xiaowan DamChina4.22012 Jinping 2 HP Station China3.62014 Pubugou DamChina3.32010

28. Whacky Idea (2007) Red Sea Dam The idea is to dam the Red Sea at its southern end where the Bab-al-Mandab Strait is only 18 miles (29 km) wide. Natural evaporation would rapidly lower the level of the enclosed Red Sea. Water allowed back into the sea would drive turbines to generate electricity. It is claimed that up to 50 gigawatts would be generated, dwarfing all other power schemes. The idea is to dam the Red Sea at its southern end where the Bab-al-Mandab Strait is only 18 miles (29 km) wide. Natural evaporation would rapidly lower the level of the enclosed Red Sea. Water allowed back into the sea would drive turbines to generate electricity. It is claimed that up to 50 gigawatts would be generated, dwarfing all other power schemes.Red Sea Bab-al-Mandab StraitRed Sea Bab-al-Mandab Strait

29. Hydroelectric Power Advantages Fuel is not burned so there is minimal pollution. Fuel is not burned so there is minimal pollution. Major role in reducing greenhouse gases Major role in reducing greenhouse gases Water provided free. Water provided free. Relatively low operations and maintenance costs. Relatively low operations and maintenance costs. Reliable and proven technology. Reliable and proven technology. Renewable – reservoir water renewed by rainfall. Renewable – reservoir water renewed by rainfall.

30. Reservoirs can be used for other purposes such as irrigation, recreation, flood control Reservoirs can be used for other purposes such as irrigation, recreation, flood control

31. Hydroelectric Power Disadvantages Lifetime of 50 to 200 years, due to silting. Lifetime of 50 to 200 years, due to silting. Large environmental changes upstream and downstream. Large environmental changes upstream and downstream. Fish, wildlife, and peopleFish, wildlife, and people Loss of free flowing water. Loss of free flowing water. Loss of land flooded by reservoir. Loss of land flooded by reservoir. Often upstream from population centers. Often upstream from population centers. High investment costs High investment costs Hydrology dependent (precipitation) Hydrology dependent (precipitation)

32. High investment costs High investment costs Hydrology dependent (precipitation) Hydrology dependent (precipitation) Inundation of land and wildlife habitat Inundation of land and wildlife habitat Loss or modification of fish habitat Loss or modification of fish habitat Fish entrainment or passage restriction Fish entrainment or passage restriction Changes in reservoir and stream water quality Changes in reservoir and stream water quality Displacement of local populations Displacement of local populations

33. Dam Failures From 1918-58 there were 33 dam failures in the US resulting in 1680 deaths. From 1918-58 there were 33 dam failures in the US resulting in 1680 deaths. Between 1959 and 65 there were 9 large failures worldwide. Between 1959 and 65 there were 9 large failures worldwide. It is unusual, but a significant hazard. It is unusual, but a significant hazard. Terrorists? Terrorists?

34. Water pouring out of the reservoir of the Teton Dam in Idaho following its catastrophic failure on June 5, 1976.Teton DamIdaho Teton Dam Failure

35. Ocean Thermal Electric Conversion Uses temperature difference between the surface and deep water to drive a heat engine. Uses temperature difference between the surface and deep water to drive a heat engine.

36. Heat Engine Q hot – Q cold = W Q hot – Q cold = W Efficiency: e = W/Q hot Efficiency: e = W/Q hot

37. Ocean Thermal Electric Conversion Uses temperature difference between the surface and deep water to drive a heat engine. Uses temperature difference between the surface and deep water to drive a heat engine. Very low efficiency, but no fuel cost. Very low efficiency, but no fuel cost. Most efficient where temperature difference between surface and deep water is greatest  Tropics Most efficient where temperature difference between surface and deep water is greatest  Tropics T surface = 25ºC T deep = 5ºC T surface = 25ºC T deep = 5ºC

38. The theoretical maximum efficiency of a heat is A. W/Q H B. Q C /Q H C. 1 – T C /T H D. 1 + Q H /Q C

39. Ocean Thermal Electric Conversion Maximum efficiency e C = 1 – T C /T H Maximum efficiency e C = 1 – T C /T H T surface = 25ºC T deep = 5ºC T surface = 25ºC T deep = 5ºC What is the maximum efficiency of OTEC? What is the maximum efficiency of OTEC?

40. Maximum efficiency of OTEC A. 5% B. 2.3% C. 1% D. 0.17% E. 0.067%

41. Ocean Thermal Electric Conversion Maximum efficiency e C = 1 – T C /T H Maximum efficiency e C = 1 – T C /T H T surface = 25ºC T deep = 5ºC T surface = 25ºC T deep = 5ºC e c = 1 - (278 K/298 K) = 0.067 or 6.7% e c = 1 - (278 K/298 K) = 0.067 or 6.7% Real efficiency more like 2-3% Real efficiency more like 2-3%

43. Ocean Thermal Electric Conversion Closed cycle uses refrigerant such as ammonia as working fluid Closed cycle uses refrigerant such as ammonia as working fluid Open cycle pumps warm water into low pressure vessel. Water boils and drives a low pressure turbine Open cycle pumps warm water into low pressure vessel. Water boils and drives a low pressure turbine

44. Closed-Cycle OTEC

45. Open-Cycle OTEC

46. Ocean Thermal Electric Conversion Requires a large water flow. Requires a large water flow. A 100 MW plant would require approximately 25,000,000 liters per second of both warm and cold water. A 100 MW plant would require approximately 25,000,000 liters per second of both warm and cold water. Should have T > 17C which means locations with warm surface waters. Should have T > 17C which means locations with warm surface waters. Predictable power output since T is very stable over the course of a day. Predictable power output since T is very stable over the course of a day.

48. Not much current development. Not much current development. 1930’s : concept plant built near Cuba generated 22kW of power, but used more than it generated. 1930’s : concept plant built near Cuba generated 22kW of power, but used more than it generated. 1970’s : small test plant built in Hawaii. 1970’s : small test plant built in Hawaii. No government support since the 1980’s. No government support since the 1980’s.

49. Other Ideas Large underwater turbines anchored to the sea floor. Large underwater turbines anchored to the sea floor. Ex: Gulf stream has a steady flow that is 1000 time larger than the Mississippi River with a maximum velocity of 4 mph. Ex: Gulf stream has a steady flow that is 1000 time larger than the Mississippi River with a maximum velocity of 4 mph.