Week 2 - EEM107 - Voltage and Circuit Concepts PDF

Summary

This document is a set of lecture notes on voltage, current, and circuits. The notes include definitions, explanations, equations and examples.

Full Transcript

Chapter 3 Voltage
Objectives

 After completing this chapter, you will be able to:
 Identify the six most common voltage sources
 Describe six 6 different methods of producing electricity
 Define a cell and a battery
 Describe the difference between primary and secondary cells
 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, magnetism, chemicals, light, heat, and pressure
 Friction
 Oldest known method of producing electricity
 Example: Van de Graaf generator
 Van de Graaf generator

https://youtu.be/3Ptu07enIsY https://www.youtube.com/watch?v=y20lKZB5BR0
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
 Electromagnetic Generators

https://www.youtube.com/watch?v=WhATjUHgzxQ
 Voltage Sources (cont’d.)

Figure 3-6. A photovoltaic cell can convert sunlight directly into electricity.
 A photovoltaic (Solar) Cells

https://www.youtube.com/watch?app=desktop&v=UJ8XW9AgUrw
SciToons channel, Brown University, USA
 Voltage Sources (cont’d.)

Figure 3-8. Thermocouples convert heat energy directly into electrical energy
(commonly used to measure directly temperature in ovens, stove…etc.)

Note: This shows that the conversion of energy from Thermal energy (Heat) to
Electrical Energy. However, is not widely use to generate electric power!
Cells and Batteries

 Battery
 Combination of two or more cells
 Primary cells
 Cannot be recharged
 Example: dry cells
 Secondary cells
 Can be recharged
 Example: lead-acid, Lithium-ion 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.

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

 Ground
 Term used to identify zero potential
 Earth grounding In the home, all electrical circuits and
appliances are earth grounded. Consequently,
 Keeps appliances and equipment at same potential no difference of potential exists between any
two appliances to avoid electrocution/electric
 Electrical grounding shocks

 Provides common reference point
Electrical grounding is used in automobiles. Here
the chassis of the automobile is used as a ground. This
can be verified by seeing where the battery cables are
attached to the automobile. Generally, the negative terminal is
bolted directly to the frame of the automobile. This point or
any other point on the frame of the automobile is considered to
be ground. Ground serves as part of the complete circuit
 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
 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
Chapter 4 Resistance
Objectives

 After completing this chapter, you will be able to:
 Define resistance and explain its effect in a circuit
 Determine the tolerance range of a resistor
 Identify carbon composition, wirewound, and film resistors
 Identify potentiometers and rheostats
 Describe how a variable resistor operates
 Decode a resistor’s value using the color code or
alphanumeric code
 Identify the three types of resistor circuits
 Calculate total resistance in series, parallel, and series-
parallel circuits
Resistance

 Conductance (R)
 Ability of a material to stop/hinder
electrons flow.
 Unit of Resistance in Ohm, [Ω]

Figure 4-1. Resistance of several conductors
of the same length and cross-section area A.
Conductance

 Conductance (G)
 Ability of a material to pass electrons: inverse (1/x) of Resistance
 Unit of conductance is Mho (mirror of the word Ohm)
 Measured in Siemens (S)
 Resistors
 Resistors
 Elements of electrical and electronic circuits
 Possess a specific value of resistance to current flow
 Have values of their resistance in in Ohm, [Ω]
 They can be: Either fixed (changeable) or Variable (non-changeable)
 Resistor’s tolerance (variance due manufacturing variability)
 Their values can vary and still be acceptable within a range called tolerance range
 10% tolerance is satisfactory, generally.
 Resistors (cont’d.)

Figure 4-6. Carbon composition resistors were the
most widely used resistors in electronic circuits.

The wirewound resistor is constructed of a nickel-
chromium alloy (nichrome) wire wound on a ceramic
form (Figure 4-7). Leads are attached and the entire
resistor is sealed with a coating. Wirewound resistors
are used in high-current circuits where precision is
necessary. The resistance range varies from a fraction
of an ohm to several thousand ohms.
Figure 4-7. Wirewound resistors are
available in many different styles.
 Resistors (cont’d.)

Figure 4-8. The film resistor offers the size of the carbon
resistor with the accuracy of the wirewound resistor.
Film resistors have become popular (Figure 4-8)
because they offer the small size of the composition
resistor with the accuracy of the wirewound resistor.
A thin film of carbon is deposited on a cylindrical
ceramic core and sealed in an epoxy or glass coating
to form a carbon film resistor
Figure 4-10. Variable resistors allow the resistance to
increase or decrease at random.
 Resistors (cont’d.)

 Potentiometer (or pot)
 A variable resistor used to control voltage (small currents)
 Used in audio volume and tone controls, lighting dimmer switches, and
motor speed control in robotics.
 Rheostat
 A variable resistor used to control current (large currents)
 Used to control motor speed, heat, and voltage in electronic circuits.
Figure 4-12. The Electronic Industries Association (EIA) 4-band color code.
Resistor Value Identification using
Electronic Industries Association
(EIA) 4 and 5-band color code

3RD DIGIT

Figure 4-13. Meaning of the colored bands on a carbon composition resistor.
R=[1ST Digit] [2ND Digit2]10^[[3RD Digit] ± TOLERANCE%
Resistor Value Identification using
Electronic Industries Association
(EIA) 4 and 5-band color code

The brown band (first band) represents the 1st digit (=1)
The green band (second band) represents the 2nd digit (=5)
The red band (third band) represents 3rd digit (=2)
The silver band (fourth band) indicates a resistance tolerance of 10%.

Therefore, this is a R=15.102 = 1500ohm with a ±10% tolerance, which means
can take any value between R=1500-10%x1500 and R=1500+10%x1500
Resistor Value Identification using
Electronic Industries Association
(EIA) 4 and 5-band color code

(i.e. exponent)

The fifth band on a resistor indicates the resistor’s reliability.
Reliability of the resistor tells how many of the resistors (per
thousand) will fail after 100 hours of operation (Quality indicator)
Electronic Industries Association
(EIA) 5-band color code
Resistor Value Identification:
Alfa-Numerically

Figure 4-16. Resistors may also be identified by a letter-
and-number system.
RN60D5112F has the following meaning:
RN60 Resistor style ( composition, wirewound, film)
D Characteristic (effects of temperature)
5112 Resistance value (2 exponent, i.e., # of zeros)
F Tolerance (1%)
Therefore, this resistor of R=[511.102 ±1%x 511.102]Ω
Figure 4-18. Three types of resistive circuits:
(A) serial circuit, (B) parallel circuit, (C) serial-parallel circuit.
Connecting Resistors in
Series
 Series circuit
 Provides one path for current to flow
 Total resistance formula:
RT = R1 + R2 + R3 … + Rn
Connecting Resistors in
Parallel
 Parallel circuit
 Provides two or more paths for current to flow
 Total resistance formula:
1/RT = 1/R1 + 1/R2 + 1/R3 … + 1/Rn

 Total resistance is always less than smallest resistor
Connecting Resistors in
Series and Parallel

 Series-parallel circuit
 Combination of a series and a parallel circuit
 To calculate total resistance, use the series and parallel formulas
 Summary

 Resistance is opposition to flow of current
 Several factors, such as size and type of wire, affect electrical resistance
 Resistors are either fixed or variable
 Three major categories of resistors:
 molded carbon composition, wirewound, or film
 Variable resistors allow resistance to vary/change
 Resistor values may be identified by colored bands or by an alphanumeric
system
 Three types of resistive circuits: series, parallel, series-parallel