3. Automotive Technology 2 period 3-4 (Kingsville Independent School District)

Due: 10/04/2025

Tue, 23 Sep 2025 12:26:57 PDT

Chapter 45

Lighting Systems

Learning Objectives

After reading this chapter, you will be able to:

45-01 Describe the purpose of the lighting system.
45-02 Describe the types of lights.
45-03 Describe light bulb configurations.
45-04 Describe park, tail, marker, and license lights.
45-05 Describe driving, fog, and cornering lights.
45-06 Describe brake and backup lights.
45-07 Describe turn signal and hazard lights.
45-08 Describe headlights and head light systems.
45-09 Describe lighting system testing and precautions.
45-10 Perform peripheral lighting service.
45-11 Perform headlight service.

ASE Education Foundation Tasks

The following ASE Education Foundation Automobile Accreditation Tasks are covered in this chapter:

VIE1 Inspect interior and exterior lamps and sockets including headlights and auxiliary lights (fog lights/driving lights); replace as needed.
VIE2 Aim headlights.
VIE3 Identify system voltage and safety precautions associated with high-intensity discharge headlights.

Readings and Preparation

Review all instructional materials, including the chapter in Fundamentals of Automotive Maintenance and Light Repair, Second Edition, and all related presentation support materials.

Support Materials

Lecture PowerPoint presentation, including all Skill Drills

Pre-Lecture

You Are the Automotive Technician
- A progressive case study that encourages critical thinking skills.
- Direct students to read the “You Are the Automotive Technician” scenario found at the beginning of each chapter.
- Group Activity: Direct students to review the discussion questions at the end of the scenario and prepare a response to each question. Facilitate a class discussion centered on the questions.
- Homework Assignment: Ask students to turn in their comments on the questions.
Teaching Tip: Explain to students how this material applies to the workplace. Provide an example of a situation to make it relevant and meaningful. How does it fit into the broader picture? Is it building on something they already know? Will it help them master a skill? Students need to understand that what we are teaching is of importance on the job. This can be done by describing interesting lighting system problems you have experienced. You can also have students complete the online pre-test for this chapter in the CDX online system. This will help them understand what they do and do not know about lighting systems.

Lecture

45-01 Describe the purpose of the lighting system.

Lighting systems improve the driver’s visibility at night and make a vehicle visible to others on the road.
The headlight switch activates taillights, park lights, and headlights, which allows the driver to see the road ahead.
A beam selector switch allows the driver to change the beams from high to low, or vice versa.
Brake lights operate when the brake pedal is depressed.
Red or amber turn signals alert other drivers of a change in direction.

45-02 Describe the types of lights.

Different types of lamps used in modern vehicles include standard incandescent lamps, halogen lamps, vacuum tube fluorescent (VTF) lighting, HID xenon gas systems, LEDs, and more.
Incandescent lamps consist of one or more tungsten filaments.
Halogen lamps are another type of incandescent lamp.
Light-emitting diodes (LEDs) turn on instantly and are particularly useful in brake lights.
Vacuum tube fluorescent (VTF) lighting is used for instrumentation displays on instrument panel clusters.
High-intensity discharge (HID) headlamps produce light with an electric arc; they typically produce between 2800 and 3500 lumens of light.

45-03 Describe light bulb configurations.

All lamps or lightbulbs have letters and numbers on them that typically indicate the part number, operating voltage, and power consumed.
Lamps and lightbulbs come in a variety of configurations to fit the various applications within a vehicle.
One distinguishing feature is the number of filaments within a bulb. Single-filament bulbs are commonly used in courtesy lights, dash lights, and warning lights, whereas dual-filament bulbs have two filaments of different wattage.
Another feature that differs among lights is the type of base on the lamp or the type of socket it fits into.

45-04 Describe park, tail, marker, and license lights.

Park, tail, and marker lights are all low-intensity or low-wattage bulbs used to mark the outline or width of the vehicle (RC).
Park lamps are placed at the front of the vehicle and are used at night when the vehicle is parked on the side of the road.
Park lamps are yellow or white in color.
Tail lamps are red and are located at the rear of the vehicle.
Government regulations control the height of the lamps and their brightness.
Marker lights are used to mark the sides of some vehicles.
Red marker lamps face toward the rear, and yellow marker lamps face toward the front of the vehicle.
License plate lamps produce a white light and are designed to illuminate the lettering on the license plate at night.

45-05 Describe driving, fog, and cornering lights.

Driving lights provide high-intensity light over a long distance.
Vehicle regulations specify the positioning and lens configuration of driving lights.
Driving lights come in different sizes, shapes, lens patterns, and bulb wattage.
Fog lights are used with other vehicle lighting in poor weather such as thick fog, driving rain, or blowing snow.
Most older fog lights have yellow-colored reflectors; however, more recently, white fog lights have become more widely used.
Cornering lights are white lights usually installed into the bumper or fender and are designed to provide side lighting when the vehicle is turning corners.
Cornering lights turn on only when the headlights and turn signal switches are both on and turn off automatically when the turn signal cancels.

45-06 Describe brake and backup lights.

Brake lights or stop lights are red lights mounted to the rear of the vehicle and are incorporated in the taillight cluster.
Many vehicles, by law, now have a higher additional third brake light mounted on top of the trunk lid or near the rear window, called the center high mount stop light (CHMSL), or “chimsul”.
The brake lights are activated whenever the driver operates the foot brake or when a control module automatically applies the brakes.
The backup lights, also called reverse lights, are white lights mounted at the rear of a vehicle; they assist the driver with vision behind the vehicle at night.

45-07 Describe turn signal and hazard lights.

Turn signal lights are located on the extreme corners of the vehicle and are usually amber in the front and can be either red or amber in the rear.
A column-mounted switch, operated by the driver, directs a pulsing current to the turn signal lights on one side of the vehicle or the other.
Turn signal lights warn other road users of the driver’s intended change of direction.
The circuit for hazard warning lights connects into the turn signal lights and pulses all exterior turn signal lights and both indicator lights on the instrument panel.

45-08 Describe headlights and head light systems.

Headlights are built into the front of a vehicle.
They illuminate the road ahead of the vehicle when driving at night or in conditions of reduced visibility.
In headlights, most vehicles require both a high beam and a low beam.
High beam and a low beam, created by separate filaments, must be positioned correctly in relation to the highly polished reflector.
The high-beam filament is precisely positioned; it projects the maximum amount of light forward and parallel to the road.
The low-beam filament is often placed above and slightly to one side of the high-beam filament; this produces a beam of light that is projected slightly downward and toward the curb.
A beam selector switch, typically located on the steering column, selects between low beam and high beam.
A sealed-beam headlight has a highly polished aluminized glass reflector that is fused to the optically designed lens; it is a completely sealed unit that has the filaments accurately positioned in relation to the reflector.
A semi-sealed beam headlight uses a replaceable bulb with a prefocus collar that locates the bulb in the headlight housing and controls the correct positioning of the filaments to the reflector and lens.
An alternative to a reflector-type lighting system is a projection-type headlight system, which has a smaller front lens but produces a high-intensity forward beam; it uses a lens system, rather than the traditional reflector system, to project the light forward.
Daytime running lights (DRLs) are an additional safety feature designed to improve the vehicle’s visibility to other drivers; they use existing lights that turn on when the vehicle is running and turn off when the engine stops.

45-09 Describe lighting system testing and precautions.

The layouts of electrical circuits and their components are shown as diagrams.
Being able to read a wiring diagram is probably the most important skill when diagnosing an electrical fault.
Several safety precautions should be taken when working on HID systems.
There is a risk of electrocution, burns, or shock from the high voltages generated by the HID system.
Wear safety glasses, high-voltage safety gloves, and safety boots when working on HID systems.
Persons with active electronic implants, such as heart pacemakers, should not work on HID headlamps.
Dispose of the bulbs in HID headlamps in an environmentally friendly way.

45-10 Perform peripheral lighting service.

When checking lighting and peripheral systems, be sure to work in a systematic manner to avoid missing a faulty bulb or other component.
A vehicle may have warning lights that activate only if that circuit is in use.
Inspecting the lighting system’s operation periodically will help identify any lightbulb issues.
Look carefully at the bulb you are replacing to make sure you do not try to force the bulb in the wrong way, and make sure you don’t replace a dual-filament bulb with a single-filament bulb or vice versa.

45-11 Perform headlight service.

Always make sure you replace a bulb with one of exactly the same type.
When replacing a halogen bulb, avoid touching it with your fingers.
If you inadvertently touch the bulb, clean it with alcohol and a lint-free cloth; do not use gasoline or paraffin to clean the bulb.
The principle of aiming headlights is the same in the majority of cases, but the legal rules can differ from region to region.
If the headlights are too dim, one reason could be high resistance in the light circuit, which can be checked by measuring the voltage drop on both the power side of the bulb and the ground side.
If the voltage drop is less than 0.5 volt on each side, suspect the lightbulb is wearing out.
A light intensity meter can be used to measure the amount of light energy produced by a lamp.

Post-Lecture

This section contains various student-centered end-of-chapter activities designed as enhancements to the instructor’s presentation. As time permits, these activities may be presented in class. They are also designed to be used as homework activities.

Direct students to read and individually answer the question sets located in the Wrap-Up section at the end of each chapter. Allow approximately 10–20 minutes for this part of the activity.
Facilitate a class review and discussion of the answers, allowing students to correct responses as may be needed. Use the answers noted in the Answer Key to assist in building this review.
You may wish to ask students to complete this activity on their own and turn in their answers on a separate piece of paper.

Review Questions

This question set is designed to assist students in understanding the chapter content by asking knowledge-based comprehension questions.

__________ headlamps produce light with an electric arc rather than a glowing filament.
1. Vacuum tube fluorescent
2. High-intensity discharge
3. Incandescent and halogen
4. Light-emitting diode

All of the following turn on with the taillights, EXCEPT:
1. backup lights.
2. license plate lights.
3. park lights.
4. side markers.

Which of the following is NOT a part of the reverse light circuit?
1. Brake light switch
2. Reverse light switch
3. Ignition switch
4. Vehicle battery

Red or amber turn signals alert other drivers of a change in direction and are mounted so they can always be seen from the __________ of the automobile.
1. front
2. rear
3. sides
4. All of these

Many vehicles use halogen light bulbs. What must you avoid when handling halogen bulbs?
1. Touching the glass
2. Touching the metal
3. Touching the halogen gas
4. Touching the terminal

Which lights are wired in parallel with the taillights and operate whenever the taillights are switched on?
1. Headlights
2. Turn signal lights
3. Backup lights
4. License plate lights

All of the following statements with respect to the function of headlights are true, EXCEPT:
1. They illuminate the road ahead.
2. They help drivers at the time of reduced visibility.
3. They provide two beams, high and low, to serve different purposes.
4. They are connected in series with each other.

When aiming headlights:
1. make sure the wheels are pointed 20 degrees to the right.
2. make sure the vehicle ride height is correct.
3. adjust the tire pressure after aligning the headlights.
4. place 100 pounds of weight in the trunk.

Which of the following lamps produce more lumens with a bluish tinge for the given wattage when compared with all other lamps?
1. Incandescent lamps
2. Halogen lamps
3. High-intensity discharge lamps
4. VTF lamps

Which type of light bulb has a base on each end of a cylindrical bulb?
1. Bayonet style
2. Festoon style
3. Wedge style
4. Dual-filament style

ASE Technician A/Technician B Style Questions

This question set is designed to assist students in gaining a further understanding of and familiarity with ASE Technician A/Technician B questions.

Technician A says light-emitting diodes (LEDs) have better visibility in inclement weather, operate at cooler temperatures, consume less energy, are much smaller, and can last up to 100 times longer than traditional bulbs. Technician B says LEDs can reduce the braking light response time by two-tenths of a second. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Two technicians are discussing brake light bulbs. Technician A says that a two-filament bulb uses the second filament as a back-up if the first filament burns out. Technician B says that two-filament bulbs have different wattage filaments. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Technician A says that all modern vehicles by law must be equipped with a center high mount stop lamp (CHMSL). Technician B says the CHMSL is usually mounted on top of the trunk lid or in the rear window of a vehicle. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Technician A says hazard warning lights use a flasher unit that can be a separate unit or the same as that used for the turn signals. Technician B says daytime running lights are used to warn other road users that a hazardous condition exists or that the vehicle is standing or parked in a dangerous position on the side of the road. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Technician A says high-intensity discharge (HID) headlamps produce light with an electric arc rather than a glowing filament. Technician B says HID lamps are commonly called xenon headlamps. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Technician A says park, tail, and marker lights are all high-intensity or high-wattage bulbs. Technician B says license plate illumination lamps are connected in series with the taillights. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Technician A says cornering lights are typically used in poor weather such as thick fog, driving rain, or blowing snow. Technician B says fog lights are red lights usually installed into the bumper or fender and are designed to provide side lighting when the vehicle is turning. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Technician A says that some brake lights get power from the brake switch through the turn signal switch. Technician B says many turn signals use amber lights. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Technician A says that incandescent bulbs resist vibration well. Technician B says that HID headlamps require a ballast to raise the voltage for the light. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Technician A says that a light intensity meter is used to measure the brightness of headlights. Technician B says that if a bulb is dim, you should perform a voltage drop test on the power and ground side of the bulb. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Assignments

Review all materials from this chapter and be prepared for a chapter quiz to be administered (date to be determined by instructor).
Direct students to read the next chapter in Fundamentals of Automotive Maintenance and Light Repair, Second Edition as listed on your syllabus to prepare for the next class session.

Due: 09/27/2025

Mon, 22 Sep 2025 06:45:12 PDT

Chapter 43

Battery Systems

Learning Objectives

After reading this chapter, you will be able to:

43-01 Describe basic battery construction and operation.
43-02 Describe basic types of batteries.
43-03 Describe battery configurations, terminals, and cables.
43-04 Describe battery ratings and the charge–discharge cycle.
43-05 Describe conditions that shorten/lengthen the life of a battery.
43-06 Describe the purpose and types of battery maintenance.
43-07 Inspect, clean, fill, and replace the battery and cables.
43-08 Perform battery charging and jump-starting.
43-09 Perform battery state of charge and specific gravity tests.
43-10 Perform battery capacity tests.
43-11 Maintain and restore electronic memories.
43-12 Measure parasitic draw.

ASE Education Foundation Tasks

The following ASE Education Foundation Automobile Accreditation Tasks are covered in this chapter:

VIA8 Measure key-off battery drain (parasitic draw).
VIB1 Perform battery state-of-charge test; determine necessary action.
VIB2 Confirm proper battery capacity for vehicle application; perform battery capacity and load test; determine necessary action.
VIB3 Maintain or restore electronic memory functions.
VIB4 Inspect and clean battery; fill battery cells; check battery cables, connectors, clamps, and hold-downs.
VIB5 Perform slow/fast battery charge according to manufacturer’s recommendations.
VIB6 Jump-start vehicle using jumper cables and a booster battery or an auxiliary power supply.
VIB8 Identify electrical/electronic modules, security systems, radios, and other accessories that require reinitialization or code entry after reconnecting vehicle battery.
VIB9 Identify hybrid vehicle auxiliary (12v) battery service, repair, and test procedures.

Readings and Preparation

Review all instructional materials, including the chapter in Fundamentals of Automotive Maintenance and Light Repair, Second Edition, and all related presentation support materials.

Support Materials

Lecture PowerPoint presentation, including all Skill Drills

Pre-Lecture

You Are the Automotive Technician
- A progressive case study that encourages critical thinking skills.
- Direct students to read the “You Are the Automotive Technician” scenario found at the beginning of each chapter.
- Group Activity: Direct students to review the discussion questions at the end of the scenario and prepare a response to each question. Facilitate a class discussion centered on the questions.
- Homework Assignment: Ask students to turn in their comments on the questions.
Teaching Tip: Explain to students how this material applies to the workplace. Provide an example of a situation to make it relevant and meaningful. How does it fit into the broader picture? Is it building on something they already know? Will it help them master a skill? Students need to understand that what we are teaching is of importance on the job. This can be done by describing interesting battery problems you have experienced. You can also have students complete the online pre-test for this chapter in the CDX online system. This will help them understand what they do and do not know about battery systems.

Lecture

43-01 Describe basic battery construction and operation.

A battery transforms electrical to chemical energy and vice versa.
A battery consists of two dissimilar metals: an insulator material separating the metals and an electrolyte, which is an electrically conductive solution.
The traditional automotive battery type is the lead-acid battery.
The standard 12-volt car battery consists of six 2.1-volt cells connected in series, each containing two sets of electrodes or plates immersed in an electrolyte solution of diluted sulfuric acid (H₂SO₄) and water.
The positive plates are assembled alternate to negative plates and parallel to other positive plates, and the negative plates are assembled alternate to positive plates and parallel to other negative plates.

43-02 Describe basic types of batteries.

Deep-cycle batteries are made with heavier lead plates that tolerate deep discharging better than starting batteries.
Deep-cycle batteries are heavier and bulkier than starting batteries and have a lower output per pound.
Low-maintenance batteries require little, if any, topping off of the water in the electrolyte but still have removable caps.
Absorbed glass mat batteries (suited for off-road and racing vehicles) have a gel electrolyte that is absorbed in a mat of fine glass fibers.
Sealed or maintenance-free batteries typically have no removable cell covers; some of them have a visual indicator called a single-cell hydrometer float that provides information on the status of the charge and condition of one of the battery cells.
Cell phones and tablet computers have rechargeable cell batteries that may be nickel-cadmium (Ni-Cd), nickel-metal hydride (Ni-MH), or lithium ion (Li-ion)
A nickel-metal hydride battery can have two to three times the energy of nickel-cadmium batteries.
A lithium-ion battery has one of the highest energy density ratios, meaning that it can store more energy than other comparable batteries, and it has a low self-discharge rate.
In hybrid or electric vehicle applications, many small individual cells are connected in series to each other and in parallel to other series arrangements, forming a battery pack.
Advantages of lithium-ion batteries include high energy density, low self-discharge, low maintenance, no periodic discharge requirement, no memory, and low internal resistance.
Disadvantages of lithium-ion batteries include need for circuit protection, sensitivity to high temperatures, increased cost of manufacturing, and potential for damage if completely discharged.

43-03 Describe battery configurations, terminals, and cables.

Physical attributes of the automotive battery include the size of the battery case, the location of the battery terminals, and the size or type of battery terminal.
Battery cables and terminals are designed to carry high discharge currents and are usually made of solid lead or zinc-plated brass.
Types of battery terminals are cone design, side terminal, and flat terminal; the most common is cone design.

43-04 Describe battery ratings and the charge–discharge cycle.

The three most common methods used to rate automotive battery capacity are cold cranking amps (CCAs), cranking amps (CAs), and reserve capacity (RC).
CCA measures the load in amps that a battery can deliver for 30 seconds while maintaining a voltage of 1.2 volts per cell or higher at 0°F (-17.8°C).
CA measures the same thing, but at a higher temperature of 32°F (0°C).
RC is the time in minutes that a new, fully-charged battery at 80°F (26.7°C) will supply a constant load of 25 amps without its voltage dropping below 10.5 volts for a 12-volt battery.
The RC rating approximates the amount of time a vehicle can be driven before the battery dies if the charging system fails completely.
As the battery creates current flow to operate electrical devices, it is being discharged.
As it discharges, the sulfuric acid in the electrolyte joins with lead dioxide to form lead sulfate, and the oxygen from the plate joins the hydrogen from the electrolyte to form water.
When being charged, electrical pressure (voltage) is higher than that of the battery’s total cell voltage, which pushes electricity back into the battery, reversing the chemical process.

43-05 Describe conditions that shorten/lengthen the life of a battery.

Conditions that shorten a battery’s life include being fully discharged or having deep discharge cycles, remaining overcharged or undercharged, experiencing high discharge rates for extended periods, experiencing excessive vibration, being exposed to extremes of temperature, having dirt or moisture on the case, and developing corrosion.
Batteries should be kept clean, dry, and fully charged.

43-06 Describe the purpose and types of battery maintenance.

Regular maintenance of batteries includes inspection, cleaning, testing, and charging when discharged.

43-07 Inspect, clean, fill, and replace the battery and cables.

Maintenance tasks such as inspecting, cleaning, and filling batteries should be performed every six months to one year on top-post batteries and every 1–2 years on side-post batteries.

43-08 Perform battery charging and jump-starting.

Slow charging is less stressful on a battery than fast charging.
To determine the ideal charging rate: CCAs divided by 70.
To determine the max charging rate: CCAs divided by 40.
Never exceed 15.5 volts when charging a 12-volt flooded cell battery, 14.8 volts when charging a 12-volt AGM battery, and 14.3 volts when charging a 12-volt gel cell battery.
Jump-starting a vehicle is the process of using one vehicle to start another vehicle; the vehicle with a charged battery provides electrical energy to start the vehicle that has a discharged battery.
Some vehicles should NOT be jump started.

43-09 Perform battery state of charge and specific gravity tests.

There are two tests for determining the battery’s state of charge: the specific gravity test and the open circuit voltage test.
The specific gravity test measures the electrolyte’s specific gravity; it indicates the acid content, and so the state of charge.
The open circuit voltage test uses a DMM to accurately measure the voltage of a battery and is a very quick and reasonably accurate indicator of battery state of charge.

43-10 Perform battery capacity tests.

The conductance tester can determine a battery’s CCA capacity by measuring its conductance.
The conductance tester sends low-frequency signals into the battery, which allows it to determine the battery’s ability to conduct current.
The load test is used to test a battery’s capacity and internal condition.
The load test subjects the battery to a high rate of discharge, and the voltage is then measured at the end of a set time to see how well the battery creates that current flow.

43-11 Maintain and restore electronic memories.

Many electronic modules in vehicles require a small amount of power to maintain their keep alive memory (KAM).
When the battery is disconnected, memory is usually lost.
Loss of memory may prevent the vehicle from being restarted or the radio from being used.
In some cases, it may be possible to use a memory saver to maintain the vehicle’s memory while the battery is disconnected.
Many technicians use an external 12-volt DC power supply connected to the data link connector with a suitable cable.

43-12 Measure parasitic draw.

All modern vehicles have a small amount of current draw when the ignition is turned off, which is called parasitic draw.
The total parasitic draw should be a relatively small amount of current because excessive parasitic draw will discharge the battery over a short amount of time.
The most common way of measuring parasitic draw is by using an ammeter capable of measuring milliamps.
The ammeter is inserted in series between one of the battery posts and the battery terminal.
The Chesney parasitic load test uses an ohmmeter to indicate the size of the parasitic draw.

Post-Lecture

Direct students to read and individually answer the question sets located in the Wrap-Up section at the end of each chapter. Allow approximately 10–20 minutes for this part of the activity.
Facilitate a class review and discussion of the answers, allowing students to correct responses as may be needed. Use the answers noted in the Answer Key to assist in building this review.
You may wish to ask students to complete this activity on their own and turn in their answers on a separate piece of paper.

Review Questions

This question set is designed to assist students in understanding the chapter content by asking knowledge-based comprehension questions.

The electrolyte in an automotive lead acid battery is:
1. dilute sulfuric acid.
2. hydrochloric acid.
3. sulfur dioxide.
4. nitric acid.

Absorbed glass mat batteries have the electrolyte absorbed within a mat of fine glass fibers, and are a type of:
1. low-maintenance battery.
2. unsealed battery.
3. maintenance-free battery.
4. single-cell hydrometer battery.

The most common battery cable terminal is a __________ that provides a large surface contact area with the ability to tighten the terminal onto the battery post using a nut and bolt.
1. side terminal design
2. cone design
3. flat terminal design
4. back terminal design

CCA measures the load in amps that a battery can deliver for __________ while maintaining a voltage of __________ volts per cell.
1. 60 seconds; 2.1
2. 30 seconds; 2.1
3. 60 seconds; 1.2
4. 30 seconds; 1.2

Clean the battery with a mixture of __________, but make sure not to get any of that mixture down inside of the battery, as it will tend to neutralize the electrolyte, damaging the battery.
1. baking soda and water
2. soap and water
3. salt and water
4. alcohol and water

What is the correct sequence for disconnecting battery terminals?
1. Disconnect the negative terminal and then the positive terminal
2. Disconnect whichever terminal is the easiest first
3. Disconnect whichever terminal is hardest first
4. Disconnect the positive terminal and then the negative terminal

When a vehicle has been shut off, it can have a:
1. thermal runaway.
2. parasitic draw.
3. paralysis draw.
4. heat runaway.

When performing an open circuit voltage test to determine the battery state of charge, what should a fully charged battery read?
1. 0 volts
2. 2 volts
3. 6 volts
4. 5 volts

When performing a battery load test, what should the load be set to?
1. 150 amps
2. 300 amps
3. Two times the cold cranking amps (CCA)
4. Half the cold cranking amps (CCA)

When using a DMM to measure parasitic draw, connect the meter leads:
1. between one of the battery posts and terminal on the battery cable.
2. from one battery post to the other.
3. from the positive battery post to a good engine ground.
4. across the high current contacts on the starter solenoid.

ASE Technician A/Technician B Style Questions

This question set is designed to assist students in gaining a further understanding of and familiarity with ASE Technician A/Technician B questions.

Technician A says that a battery stores electrical energy in chemical form. Technician B says that the chemical reactions change the composition of the chemicals, which then are stored until the electrical energy is needed. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Technician A says that when disconnecting the battery, the negative terminal should be disconnected first. Technician B says that when disconnecting the battery terminals, always remove the positive terminal completely first. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Two technicians are discussing the specific gravity test. Technician A says that if the electrolyte level is too low, then you will have to add distilled water, and the battery will have to be fully charged to mix the water and acid. Technician B says that the battery should be topped up with a mixture of acid and water. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A or B

Two technicians are discussing battery load testing. Technician A says that if the battery fails the load test, it is bad and should be replaced. Technician B says if it fails the load test, it should be fully charged and the test repeated. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Two technicians are discussing measuring parasitic draw. Technician A says that the parasitic draw is measured with an ammeter. Technician B says that the parasitic draw is measured with a voltmeter. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Technician A says that batteries should be charged as fast as possible. Technician B says that the ideal charging rate is the CCA divided by 70. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Technician A says that lead oxide acts as an insulator on the battery posts and has to be scraped away. Technician B says that current can leak across the dirt on the surface of the battery. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Technician A says that checking the specific gravity will indicate the battery’s cold cranking amps. Technician B says that a battery load test should be performed when the battery is heavily discharged. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Technician A says that a 12-volt battery has six cells. Technician B says that the more plates a cell in a battery has, the more voltage it creates. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Technician A says that the specific gravity of the electrolyte can be checked with a hydrometer. Technician B says that the specific gravity of the electrolyte can be checked with a refractometer. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Assignments

Review all materials from this chapter and be prepared for a chapter quiz to be administered (date to be determined by instructor).
Direct students to read the next chapter in Fundamentals of Automotive Maintenance and Light Repair, Second Edition as listed on your syllabus to prepare for the next class session.

Chapter 44

Starting and Charging Systems

Learning Objectives

After reading this chapter, you will be able to:

44-01 Describe starting system fundamentals.
44-02 Describe starter motor construction.
44-03 Describe starter motor engagement.
44-04 Describe armature windings and commutators.
44-05 Describe starter drives and the ring gear.
44-06 Describe solenoid operation.
44-07 Describe starter control circuit operation.
44-08 Test starter high-current draw.
44-09 Test starter control circuit voltage drop.
44-10 Test starter relays and solenoids.
44-11 Remove and install a starter.
44-12 Describe idle–stop/start–stop system operation.
44-13 Describe charging system operation.
44-14 Describe the rotor, slip ring, and brushes.
44-15 Describe the stator, end frames, fan, and pulley.
44-16 Describe rectification.
44-17 Describe voltage regulation.
44-18 Perform a charging system output test.
44-19 Perform charging system circuit voltage and voltage drop tests.
44-20 Replace alternator.

ASE Education Foundation Tasks

The following ASE Education Foundation Automobile Accreditation Tasks are covered in this chapter:

VIC1 Perform starter current draw test; determine necessary action.
VIC2 Perform starter circuit voltage drop tests; determine necessary action.
VIC3 Inspect and test starter relays and solenoids; determine necessary action.
VIC4 Remove and install starter in a vehicle.
VIC5 Inspect and test switches, connectors, and wires of starter control circuits; determine necessary action.
VIC6 Demonstrate knowledge of an automatic idle-stop/start-stop system.
VID1 Perform charging system output test; determine necessary action.
VID3 Remove, inspect, and/or replace generator (alternator).
VID4 Perform charging circuit voltage drop tests; determine necessary action.

Readings and Preparation

Review all instructional materials, including the chapter in Fundamentals of Automotive Maintenance and Light Repair, Second Edition, and all related presentation support materials.

Support Materials

Lecture PowerPoint presentation, including all Skill Drills

Pre-Lecture

You Are the Automotive Technician
- A progressive case study that encourages critical thinking skills.
- Direct students to read the “You Are the Automotive Technician” scenario found at the beginning of each chapter.
- Group Activity: Direct students to review the discussion questions at the end of the scenario and prepare a response to each question. Facilitate a class discussion centered on the questions.
- Homework Assignment: Ask students to turn in their comments on the questions.
Teaching Tip: Explain to students how this material applies to the workplace. Provide an example of a situation to make it relevant and meaningful. How does it fit into the broader picture? Is it building on something they already know? Will it help them master a skill? Students need to understand that what we are teaching is of importance on the job. This can be done by describing interesting starting and charging system problems you have experienced. You can also have students complete the online pre-test for this chapter in the CDX online system. This will help them understand what they do and do not know about starting and charging systems.

Lecture

44-01 Describe starting system fundamentals.

The starting system provides a method of rotating (cranking) the vehicle’s internal combustion engine (ICE) so that the combustion cycle can begin.
Modern vehicles use an electric starter motor that draws its electrical power from the vehicle’s battery.
The starting/cranking system consists of two electrical circuits: the high-amperage circuit that powers the starter for cranking the engine over and the low-amperage circuit used to control the high-amperage circuit.
The high-amperage circuit consists of battery, high-amperage side of the solenoid, and starter motor assembly.
The control circuit consists of the battery, ignition switch, safety switch (clutch switch or neutral safety switch), and the low-amperage side of the solenoid.
The starter motor converts electrical energy to mechanical energy for the purpose of cranking the engine over.
There are three sections to the typical starter: the electric motor, the drive mechanism, and the solenoid battery.
Starters can be either direct-drive (where the starter drive is mounted directly on one end of the armature shaft) or gear reduction (which use an extra gear between the armature and the starter drive mechanism).

44-02 Describe starter motor construction.

A starter motor normally consists of the following components: field coils or large permanent magnets, an armature, a commutator, brushes, a drive pinion with an overrunning clutch, and a drive pinion engagement solenoid and shift fork batteries.
The armature is the revolving component of the DC motor; the armature shaft is supported at each end by bushings or bearings pressed into end frames.
The commutator end frame carries copper-impregnated carbon brushes that conduct current through the armature when it is being rotated in operation.
The brushes are mounted in brush holders and are kept in contact with the commutator by tensioned spiral springs.
Starter motors use two magnet types: electromagnetic and permanent magnet.
Electromagnetic fields are created as current flows through heavy copper windings wound around iron pole shoes to concentrate the magnetic field.
The pole shoes are fastened to the starter case/barrel.
Permanent magnets are located similarly but they do not need electricity and therefore occupy less space.

44-03 Describe starter motor engagement.

Engagement is initiated by operation of the ignition switch, which activates a starter-mounted solenoid.
The solenoid plunger attached to a pinion shift lever and operating fork is moved by solenoid operation, causing the pinion to engage with the ring gear and the plunger contacts to bridge the main starter terminals.

44-04 Describe armature windings and commutators.

A conductor loop that can freely rotate within the magnetic field is the most efficient motor design.
When current flows through the loop, the stationary magnetic field is distorted and the lines of force try to straighten, forcing one side of the loop up and the other side of the loop down, and causing the loop to rotate until it is at 90 degrees to the magnetic field.
To continue rotation, the direction of current flow in the conductor must be reversed at this static neutral point.
A commutator is used to continually reverse the current flow in the loop, which keeps the armature rotating.

44-05 Describe starter drives and the ring gear.

The starter drive transmits the rotational drive from the starter armature to the engine via the ring gear mounted on the engine flywheel, flexplate, or torque converter.
The starter drive is composed of a pinion gear, an internal spline that mates with the slightly curved external spline on the armature shaft, an overrunning clutch, and a meshing spring.
The pinion gear is small in comparison to the ring gear.
The overrunning clutch drives the pinion gear in one direction while allowing it to freewheel in the opposite direction.
The overrunning clutch prevents the starter motor from being driven by the engine once the engine starts.

44-06 Describe solenoid operation.

The solenoid is typically a cylindrical device mounted on the starter motor constructed with two electrical windings, a pull-in winding, and a hold-in winding.
Two main functions performed by solenoid are the following: it switches the high current flow required by the starter motor on and off and it engages the starter drive with the ring gear.

44-07 Describe starter control circuit operation.

The starter control circuit provides a means of operating the starter motor only within certain parameters: when the transmission is in Park, the clutch is depressed, the brake pedal is applied, or the proper ignition key is being used.
These requirements help prevent accidentally starting the vehicle in gear and also help prevent the vehicle from being stolen.
When the required parameters are met, the PCM either activates a starter relay or activates the solenoid directly.
Vehicle immobilizers are computer-managed security systems that disable the vehicle starter and engine systems by using an electronic system to uniquely identify each vehicle key by a security code system.
Another type of immobilizer system uses a static code programmed into circuitry built into the key.
Immobilizer systems now use keyless starting where the vehicle has a start button on the dash and does not require the key; the start button will start the vehicle only if the key is in the proximity of the vehicle.
A further variation of keyless starting is where the vehicle can be started remotely (e.g., inside the house); a start button is located on the key fob.

44-08 Test starter high-current draw.

Starter motors can be tested in two ways: on vehicle or off vehicle.
The on-vehicle test is usually called a starter draw test and the off-vehicle test is called a starter no-load test.
As the starter motor and engine cranking speed increase, the current draw decreases and quickly stabilizes once the engine reaches full cranking speed; it is at this point that the amperage is read and then compared with specifications.
Starter test equipment used to test starter draw uses an inductive high-current ammeter to measure the cranking current flow.

44-09 Test starter control circuit voltage drop.

Voltage drop can occur across both the high-current and control circuits; however, the high-current circuit is more susceptible to voltage drop.
When testing the voltage drop on the high-current side, for the measurement to be meaningful, the starter must be activated.
A digital multimeter (DMM) is used to measure voltage drop across all parts of the circuit.
A voltmeter with a minimum/maximum range setting is very useful when measuring voltage drop.
Voltage drop is tested while the circuit is under load.
The starter control circuit activates the starter solenoid, which activates the starter motor.
If there is a problem in the starter control circuit, the vehicle will likely not crank over at all, or maybe intermittently.
The control circuit is made up of the battery, fusible link, ignition switch, neutral safety switch (automatic transmission vehicles), clutch switch (manual transmission vehicles), starter relay, and solenoid windings.
Start by placing the DMM’s black lead on the battery positive terminal, place the red lead on the solenoid’s input terminal (control circuit terminal), and measure the voltage drop with the key in the crank position.
If the voltage drop is more than 0.5 volts, perform individual voltage drop tests on the power side of the control circuit.
If the voltage drop is less than 0.5 volts, then measure the voltage drop on the starter ground circuit.

44-10 Test starter relays and solenoids.

Relays must be tested in two or three ways depending on the relay.
The simplest test is to measure the resistance of the relay winding; if it is out of specifications, the relay will need to be replaced; if it is OK, the contacts will need to be tested for an excessive voltage drop.
Solenoids can be difficult to test on the vehicle due to poor access; the tests will usually be limited to voltage and voltage drop tests on the main contacts.
It is usually best to disconnect the control circuit connector from the solenoid.
Use a jumper wire to apply battery voltage to the control circuit terminal on the solenoid; if the solenoid clicks, then there is likely a fault in the control circuit wiring; if it does NOT click, then the solenoid windings are open, or the starter brushes are likely worn.

44-11 Remove and install a starter.

Starter motors are usually located close to the flywheel end of the engine.
They can be in difficult-to-reach locations.
Some engine components or covers may need to be removed to gain access.
In most cases, the starter can be accessed more easily from underneath the vehicle.

44-12 Describe idle–stop/start–stop system operation.

This system automatically shuts the engine off at times, typically when the vehicle is stopped, and then restarts the engine when needed.
Some vehicles use a flywheel-mounted motor/generator or geared motor generator to start the engine quickly.
The second type uses an upgraded starter motor, which can turn the engine over faster than normal.
The third type of system is unique because it does not rely solely on a starter motor; instead, it ignites a combustible mixture in an appropriate cylinder.

44-13 Describe charging system operation.

DC generators have not been used on most vehicles since the 1960s; alternators have taken over.
Both DC generators and alternators produce electricity by relative movement between conductors and a magnetic field which induces an electrical potential or voltage within the conductors.
Alternators or AC generators create the needed electrical energy whenever the engine is operating.
The main parts of the charging system include the battery, alternator, voltage regulator (internal or external), charge warning light, and wiring that completes the circuit.
The battery stores electrical energy in chemical form.
The battery acts as an electrical dampening device and also provides the electrical energy for cranking the engine.
Once the engine is running, the alternator converts some of the engine’s mechanical energy into electrical energy, which is used to operate all the electrical components on the vehicle.
The alternator also charges the battery to replace the energy used to start the engine.
The voltage regulator circuit maintains optimal battery state of charge.
The alternator converts mechanical energy into electrical energy by electromagnetic induction.
The value of the electromotive force (EMF) or voltage potential induced by an AC generator depends on four factors relating to the strength of the magnetic field. Increasing the strength of the magnetic field increases the value of the induced EMF, the speed at which the magnet rotates, the relative distance between the magnet and conductors, and the number of turns of wire on the stationary coil.

44-14 Describe the rotor, slip ring, and brushes.

The alternator consists of a stationary winding assembly called the stator, a rotating electromagnet called the rotor, with a slip ring, a brush assembly, a rectifier assembly, two end frames, and a cooling fan and drive pulley engine.
The rotor is an electromagnet that rotates freely in the alternator and is supported on each end by ball bearings.
The rotor consists of a coil of insulated wire wound around an iron core and pressed onto a steel shaft.
When current is passed through the slip rings and the coil winding, it establishes strong north and south poles at the ends of the iron core and the shaft.
Slip rings and brushes aid in making an electrical connection to the rotating rotor assembly.
Slip rings are normally copper bands that are molded onto an insulating material, and then pressed onto the steel shaft of the rotor.
Each end of the rotor winding is connected to one of the copper bands.
Brushes are made of a combination of copper and carbon and are carried in brush holders mounted in the end frame of the alternator.
As the rotor rotates, the brushes maintain a constant connection with each end of the winding.
Alternator brushes can wear out and cause breakdowns.
Brushless alternators induce current flow into the rotor through one stationary field winding in the housing and a separate armature on the rotor.

44-15 Describe the stator, end frames, fan, and pulley.

The stator consists of a cylindrical, laminated iron core; it carries the three- (or four-) phase windings in slots on the inside.
The stator is mounted between the two end housings.
The alternator housings are typically constructed from aluminum and have vents within the frames to provide for a large amount of airflow to assist in dissipating heat.
The alternator’s cooling fan is a powerful centrifugal type of fan mounted on the rotor shaft and may be an integral part of the drive pulley or part of the rotor.
Overrunning alternator pulley (OAP) is a new feature that has been added to alternators over the past number of years; another type is called an overrunning alternator decoupler (OAD) or alternator decoupling pulleys (ADPs).
The following functions are provided by ADPs: reduce belt noise and vibration, reduce stress placed on the tensioner and belt, extend belt and tensioner life, and improve fuel economy.

44-16 Describe rectification.

Rectification is a process of converting AC into DC.
DC is required by the battery and nearly all of the automobile systems.
To change AC to DC, automotive alternators use a rectifier assembly, which consists of diodes in a specific configuration.
A diode allows current to flow in one direction but blocks the flow of current in the other direction.
A three-phase “bridge” rectifier has a minimum of six diodes (three positive and three negative); it rectifies the AC output of the stator windings to DC.

44-17 Describe voltage regulation.

The voltage regulator monitors battery voltage; it adjusts the current flowing through the rotor appropriately.
When voltage output is low, the regulator allows more current to flow through the rotor field winding, which increases the strength of the magnetic field and alternator output.
As the output voltage increases to the maximum regulated voltage, the voltage regulator reduces the current flow through the rotor, which reduces the strength of the magnetic field and alternator output.
In an A-type regulating circuit, alternator B+ output is fed directly to the rotor, and voltage regulation is done on the ground side of the field.
In a B-type circuit, the voltage regulator is on the positive side of the rotor field, and the ground is constant.
The voltage regulator in modern vehicles is a solid-state electronic device with an electronic circuit that senses the battery voltage and switches the rotor circuit on and off rapidly.

44-18 Perform a charging system output test.

The testing of an alternator output initially involves testing the system’s regulated voltage using a voltmeter.
Regulated voltage should be between the manufacturer’s specified minimum and maximum regulated voltage.
Once the regulated voltage is confirmed, the charging system output is checked by using an external electrical load.
A carbon pile is commonly used to reduce the battery voltage, which tricks the regulator into full-fielding the alternator, making it produce maximum output.
The output is read using an inductive ammeter and compared with the manufacturer’s rated output specifications.

44-19 Perform charging system circuit voltage and voltage drop tests.

A DMM is used to measure voltage drop across all parts of the charging system circuit.
Voltage drop tests are valid only when the circuit is under load.
To measure for voltage drop across charging system circuit, the DMM is connected in parallel across the component, cable, or connection that is to be tested.

44-20 Replace alternator.

Alternators have to be replaced whenever they are electrically or mechanically faulty.
Electrical faults include no-charge, undercharge, or overcharge conditions.
Mechanical faults include worn bearings or other internal or external mechanical damage.
When replacing an alternator, the negative terminal of the battery should be disconnected.

Post-Lecture

Direct students to read and individually answer the question sets located in the Wrap-Up section at the end of each chapter. Allow approximately 10–20 minutes for this part of the activity.
Facilitate a class review and discussion of the answers, allowing students to correct responses as may be needed. Use the answers noted in the Answer Key to assist in building this review.
You may wish to ask students to complete this activity on their own and turn in their answers on a separate piece of paper.

Review Questions

This question set is designed to assist students in understanding the chapter content by asking knowledge-based comprehension questions.

Which of the following is part of the starter control circuit?
1. The high-amperage side of the solenoid
2. The starter motor assembly
3. The ignition switch
4. The flywheel

Starter motor magnet types are typically permanent magnet and:
2. semi-permanent magnet.
3. temporary magnet.
4. part-time magnet.

Which part of the starter assembly is responsible for moving the drive pinion gear into engagement with the ring gear?
1. The electric motor
2. The solenoid plunger
3. The armature windings
4. The one-way clutch

Which of the following is true when performing a starter draw test?
1. The engine should be allowed to start up during the test.
2. The starter should be off-vehicle and placed in a test stand.
3. The engine should be disabled so it will crank but not start.
4. The spark plugs should be removed from the engine.

All of the following are ways to test a starter relay, EXCEPT:
1. Measure resistance of the coil windings.
2. Check voltage drop across the contacts.
3. Use a 9 V battery on the winding terminals.
4. Reverse the relay position in the fuse box.

How should a technician prevent sparks or short circuits when replacing a starter?
1. Disconnect the negative battery terminal.
2. Remove the starter fuse.
3. Remove the starter relay.
4. Take the key out of the ignition.

Which charging system component is responsible for maintaining the optimal battery state of charge?
1. The stator windings
2. The charge warning light
3. The voltage regulator
4. The slip rings and brushes

Which component is an electromagnet that rotates freely inside an alternator?
1. The brush assembly
2. The slip ring
3. The rectifier
4. The rotor

If a technician uses a screwdriver to short out the shorting tab on the back of an alternator, what should happen?
1. The circuit breaker should trip to protect the circuit.
2. The alternator should charge at full output.
3. The engine should stall out and not restart.
4. The charging light should turn on in the instrument panel.

Which of the following is most likely to cause an overcharging condition?
1. A loose or slipping drive belt
2. Worn brushes in the alternator
3. Voltage drop in the alternator output circuit
4. A faulty voltage regulator

ASE Technician A/Technician B Style Questions

This question set is designed to assist students in gaining a further understanding of and familiarity with ASE Technician A/Technician B questions.

A starter motor is being discussed. Technician A states that if a conductor is placed so it cuts across a magnetic field, the conductor will be forced out of the magnetic field. Technician B states that the commutator reverses the current flow through the armature as it spins. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

A starter solenoid is being discussed. Technician A states that the starter solenoid switches the high current flow to the starter motor on and off. Technician B states that the solenoid is controlled by the PCM on some vehicles. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

A starter control circuit is being discussed. Technician A states that the neutral safety switch is used to prevent the engine from being started in gear. Technician B states that automatic transmission equipped vehicles use a clutch pedal switch as part of the starter control circuit. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Testing high current starter circuit voltage drop is being discussed. Technician A states that the battery should be disconnected for this test. Technician B states that typically the starter cable should not drop more than 0.5 volts during cranking. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Testing the starter control circuit is being discussed. Technician A states that the voltage tests on the circuit should be performed with the key in the crank position. Technician B states that a problem in the starter control circuit often causes the starter to crank slowly. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

The idle stop/start system is being discussed. Technician A states that the purpose of start/stop systems is to make the starter last longer. Technician B states that some start/stop systems don’t use a starter motor to crank the engine over. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

An alternator is being discussed. Technician A states that the stator is the rotating part connected to the pulley. Technician B states that some alternators have an overrunning pulley that can be turned on or off by the PCM. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Alternators are being discussed. Technician A states that the purpose of a rectifier is to convert AC to DC. Technician B states that a rectifier consists of a total of three diodes. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

A charging system output test is being performed. Technician A states that the alternator output involves measuring the system voltage with a volt meter. Technician B states that a carbon pile tester can be used to trick the alternator into charging at full output. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

An alternator is being replaced. Technician A states that the battery negative terminal must be disconnected to prevent a possible short circuit when removing the output terminal. Technician B states that belt tension needs to be checked as part of replacement. Who is correct?
1. Technician A
2. Technician B
3. Both A and B
4. Neither A nor B

Assignments

Review all materials from this chapter and be prepared for a chapter quiz to be administered (date to be determined by instructor).
Direct students to read the next chapter in Fundamentals of Automotive Maintenance and Light Repair, Second Edition as listed on your syllabus to prepare for the next class session.

Due: 08/16/2025

Tue, 12 Aug 2025 15:35:16 PDT

1.https://mycareertech.com/v/z2yvpx/shop-and-personal-safety

2.https://mycareertech.com/t/z2yvpx/shop-and-personal-safety

please watch the safety video and then do the test, you must score a 100, no if no and and no buts, keep taking the test