Cranking System 9 © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ 07458 Advanced Automotive Electricity and Electronics.

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Presentation transcript:

Cranking System 9 © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ Advanced Automotive Electricity and Electronics James D. Halderman

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.1 A typical solenoid-operated starter.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.2 Some column-mounted ignition switches act directly on the electrical ignition switch itself, whereas others use a link from the lock cylinder to the ignition switch.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.3 To prevent the engine from cranking, an electrical switch is usually installed to open the circuit between the ignition switch and the starter solenoid.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.4 Instead of using an ignition key to start the engine, some vehicles are using a start button which is also used to stop the engine, as shown on this Jaguar.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.5 The top button on this key fob is the remote start button.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ 07458

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.6 This series-wound electric motor shows the basic operation with only two brushes: one hot brush and one ground brush. The current flows through both field coils, then through the hot brush and the loop winding of the armature, before reaching ground through the ground brush.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.7 The interaction of the magnetic fields of the armature loops and field coils creates a stronger magnetic field on the right side of the conductor, causing the armature loop to move toward the left.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.8 The armature loops rotate due to the difference in the strength of the magnetic field. The loops move from a strong magnetic field strength toward a weaker magnetic field strength.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.9 Magnetic lines of force in a four-pole motor.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.10 A pole shoe and field winding.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.11 This wiring diagram illustrates the construction of a series-wound electric motor. Notice that all current flows through the field coils, then through the armature (in series) before reaching ground.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.12 This wiring diagram illustrates the construction of a shunt-type electric motor, and shows the field coils in parallel (or shunt) across the armature.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.13 A compound motor is a combination of series and shunt types, using part of the field coils connected electrically in series with the armature and some in parallel (shunt).

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.14 A typical starter motor showing the drive-end housing.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.15 Pole shoes and field windings installed in the housing.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.16 A typical starter motor armature. The armature core is made from thin sheet metal sections assembled on the armature shaft, which is used to increase the magnetic field strength.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.17 An armature showing how its copper wire loops are connected to the commutator.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.18 A cutaway of a typical starter motor showing the commutator, brushes, and brush spring.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ 07458

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.19 This starter permanent magnet field housing was ruined when someone used a hammer on the field housing in an attempt to “fix” a starter that would not work. A total replacement is the only solution in this case.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.20 A typical gear-reduction starter.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.21 A cutaway of a typical starter drive showing all of the internal parts.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.22 The ring gear to pinion gear ratio is usually 15:1 to 20:1.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.23 Operation of the overrunning clutch. (a) Starter motor is driving the starter pinion and cranking the engine. The rollers are wedged against spring force into their slots. (b) The engine has started and is rotating faster than the starter armature. Spring force pushes the rollers so they can rotate freely.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ 07458

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.24 A Ford movable pole shoe starter.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.25 Wiring diagram of a typical starter solenoid. Notice that both the pull-in winding and the hold-in winding are energized when the ignition switch is first turned to the “start” position. As soon as the solenoid contact disk makes electrical contact with both the B and M terminals, the battery current is conducted to the starter motor and electrically neutralizes the pull-in winding.

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ 07458

9 Cranking System Advanced Automotive Electricity and Electronics James D. Halderman © 2013 Pearson Higher Education, Inc. Pearson Prentice Hall - Upper Saddle River, NJ FIGURE 9.26 A palm-size starter armature.