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Do Now: What are the 4 steps of the Water Cycle? What is the difference between transcription and evaporation?

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Presentation on theme: "Do Now: What are the 4 steps of the Water Cycle? What is the difference between transcription and evaporation?"— Presentation transcript:

1 Do Now: What are the 4 steps of the Water Cycle? What is the difference between transcription and evaporation?

2 The Water Cycle 1. Evaporation & Transpiration 2. Condensation 3. Precipitation 4. Infiltration, Storage & Runoff

3 The Parts of a Hydroelectric Plant

4 Essential Questions How is moving water an energy source? How can flowing water do work? What is hydropower’s potential?

5 The Water Cycle The Water Cycle ensures that water flows from mountain peaks, down rivers and streams back into the ocean. That continuous flow of water carries with it a large amount of kinetic energy. …kinetic energy that can be transformed into electrical energy, with the aid of hydroelectric power plants, to power our homes and businesses!

6 Hydroelectric Power Plants Water enters hydroelectric plants from a river or reservoir; each plant has essentially 8 different elements: 1.Reservoir 2.Penstock 3.Turbine Blades & Shaft 4.Generator 5.Step-up Transformer 6.Transmission Lines 7.Tailrace 8.Dam & Spillway

7 Reservoir The reservoir for a hydroelectric plant is a man-made lake/pond where water stored so that it backs up behind a dam; the height of such a mass of water is a way of storing gravitational potential energy.

8 Penstock Penstock is the pipe that channels water from the reservoir to the blades of the turbine. As the water moves through the penstock, its potential energy is transformed into kinetic energy.

9 Turbine Blades & Shaft The turbine blades transform the kinetic energy of the water into mechanical energy which the shaft transmits on to the generator.

10 Generator The generator transforms the mechanical energy transmitted from the turbine blades into electricity, into electrical energy.

11 Step-up Transformer The step-up transformer increases the voltage of the electrical current generated so that it can be transmitted long distances more efficiently.

12 Dam & Spillway A Dam is a barrier that blocks the regular flow of a river or stream, causing the water to back up behind it. Spillways are holes in the dam that can be opened to allow water to flow past the dam to prevent water from overflowing the dam.

13 Types of Hydroelectric Plants There are 3 main types of hydroelectric plants: 1.Traditional2.Pumped Storage3.Run-of-River

14 Hydro Turbines: Power & Efficiency

15 The Potential Energy of Reservoirs Dams force water to back up behind them into reservoirs which store the gravitational potential energy of water. head, h The amount of energy stored is proportional to the head – the height of water in the reservoir above the turbine. The stored energy can be used to generate power.

16 Volumetric Flow Rate Volume Flow Rate Through a Pipe Q = AV Q, volumetric flow rate A, cross-sectional area V, average fluid velocity In this case, the pipe we’re talking about is the penstock that channels water from the reservoir to the turbines where power is transmitted to the generators. Example: Water flows at a rate of 1 m/s through a round pipe with a diameter of 3 cm. What is the volumetric flow rate [L/s]?

17 How much power does a hydro turbine produce? Power =  ghQ , efficiencyg, acceleration of gravity , densityh, head Q, volume flow rate Example: A hydroelectric plant employs a turbine with an overall efficiency of 85% in conditions where the flow rate is 30000 liters per second and the surface of the reservoir is 20m above the turbine. How much power is produced [kW]?

18 Power, Head & Flow Rate This image shows a cross-section of surface run-off at three separate locations: (A) a small, fast-flowing, steep mountain stream; (B) a deep, quick flowing river in a narrow channel; and (C) a very wide, but shallow, slow- moving river. As we follow the run-off from A to C, the vertical drop of the water flow decreases (h goes down), but the volumetric flow rate increases (Q goes up). This means that, in theory, it would be possible to achieve the same power when installing a hydroelectric power plant at any of the three locations shown. Large h Small Q Average h Average Q Small h Large Q

19 Types of Turbines Impulse ◦ Pelton Wheel - large h, small Q Reaction ◦ Kaplan - small h, large Q ◦ Francis - large h, large Q Pelton WheelKaplanFrancis

20 Choosing Turbines Which type of turbine would you choose if you were designing a hydroelectric power plant for a site similar to the conditions at location C? Why?

21 What’s Coming Up? Impacts on Environment/Society Homework Due Tomorrow Homework 3 Water Flow

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