Chapter 3 Voltage.

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Presentation transcript:

Chapter 3 Voltage

Objectives After completing this chapter, you will be able to: Identify the six most common voltage sources Describe six different methods of producing electricity Define a cell and a battery Describe the difference between primary and secondary cells

Objectives (cont’d.) Describe how cells and batteries are rated Identify ways to connect cells or batteries to increase current or voltage output or both Define voltage rise and voltage drop Identify the two types of grounds associated with electrical circuits

Voltage Sources Six common voltage sources: Friction Friction, magnetism, chemicals, light, heat, and pressure Friction Oldest known method of producing electricity Example: Van de Graaf generator

Voltage Sources (cont’d.) Magnetism Most common method used today Example: generator Chemical cell Second most common method used today Contains positive and negative electrodes separated by an electrolytic solution

Voltage Sources (cont’d.) Figure 3-6. A photovoltaic cell can convert sunlight directly into electricity.

Voltage Sources (cont’d.) Figure 3-8. Thermocouples convert heat energy directly into electrical energy.

Cells and Batteries Battery Primary cells Secondary cells Combination of two or more cells Primary cells Cannot be recharged Example: dry cells Secondary cells Can be recharged Example: lead-acid batteries

Connecting Cells and Batteries Series-aiding configuration Output current is the same IT = I1 = I2 = I3 Output voltage increases ET = E1 + E2 + E3

Connecting Cells and Batteries (cont’d.) Figure 3-18. Cells or batteries can be connected in series to increase voltage.

Connecting Cells and Batteries (cont’d.) Parallel configuration Output current increases IT = I1 + I2 + I3 Voltage output remains the same ET = E1 = E2 = E3

Figure 3-19. Cells or batteries can be connected in parallel to increase current flow.

Connecting Cells and Batteries (cont’d.) Figure 3-20. Cells and batteries can be connected in series-parallel to increase current and voltage outputs.

Connecting Cells and Batteries (cont’d.) Figure 3-21. The voltage increases when cells are connected in series.

Connecting Cells and Batteries (cont’d.) Figure 3-22. Connecting the series-connected cells in parallel increases the output current. The net result is a series-parallel configuration.

Voltage Rises and Voltage Drops Figure 3-23. A potential applied to a circuit is called a voltage rise.

Voltage Rises and Voltage Drops (cont’d.) Figure 3-24. The energy used by the circuit in passing current through the load (resistance) is called a voltage drop. A voltage drop occurs when current flows in the circuit.

Ground as a Voltage Reference Level Term used to identify zero potential Earth grounding Keeps appliances and equipment at same potential Electrical grounding Provides common reference point

Summary Current is produced when an electron is forced from its orbit Voltage provides energy to dislodge electrons from their orbit A voltage source provides a means of converting some other form of energy into electrical energy

Summary (cont’d.) Cells and batteries can be connected in series, in parallel, or in series-parallel to increase voltage, current, or both Key concepts in this chapter: Primary cells, secondary cells, ampere-hours, voltage rise, voltage drop, Ground