CASAMod11eAeroplaneSystemsElectricalB111eSR20230815sml.pdf

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MODULE 11A

Category B1 Licence

CASA B1-11e
Aeroplane Systems - Electrical
 Copyright © 2020 Aviation Australia

All rights reserved. No part of this document may be reproduced, transferred, sold or
otherwise disposed of, without the written permission of Aviation Australia.

CONTROLLED DOCUMENT

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 Knowledge Levels
Category A, B1, B2 and C Aircraft Maintenance Licence

Basic knowledge for categories A, B1 and B2 are indicated by the allocation of knowledge levels indicators (1, 2
or 3) against each applicable subject. Category C applicants must meet either the category B1 or the category
B2 basic knowledge levels.

The knowledge level indicators are defined as follows:

LEVEL 1

Objectives:

The applicant should be familiar with the basic elements of the subject.
The applicant should be able to give a simple description of the whole subject, using common
words and examples.
The applicant should be able to use typical terms.

LEVEL 2

A general knowledge of the theoretical and practical aspects of the subject.

An ability to apply that knowledge.

Objectives:

The applicant should be able to understand the theoretical fundamentals of the subject.
The applicant should be able to give a general description of the subject using, as appropriate,
typical examples.
The applicant should be able to use mathematical formulae in conjunction with physical laws
describing the subject.
The applicant should be able to read and understand sketches, drawings and schematics
describing the subject.
The applicant should be able to apply his knowledge in a practical manner using detailed
procedures.

LEVEL 3

A detailed knowledge of the theoretical and practical aspects of the subject.

A capacity to combine and apply the separate elements of knowledge in a logical and comprehensive manner.

Objectives:

The applicant should know the theory of the subject and interrelationships with other subjects.
The applicant should be able to give a detailed description of the subject using theoretical
fundamentals and specific examples.
The applicant should understand and be able to use mathematical formulae related to the subject.
The applicant should be able to read, understand and prepare sketches, simple drawings and
schematics describing the subject.
The applicant should be able to apply his knowledge in a practical manner using manufacturer's
instructions.
The applicant should be able to interpret results from various sources and measurements and
apply corrective action where appropriate.

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 Table of Contents
Electrical Power (11.6) 8
Learning Objectives 8
Aeroplane Electrical Power System 9
Electrical Power System Maintenance 9
Electrical Power Distribution 9
Aeroplane Batteries 10
Aircraft Battery Systems 10
Ventilation Requirements 14
Battery Connection 16
Battery Compartments 17
Battery Installation Procedures 18
Battery Servicing 18
DC Power Generation 19
DC Power 19
AC Power Generation 21
AC Power 21
Constant-Speed Drive Systems 22
Integrated Drive Generator 23
CSD/IDG Indication and Warnings 24
Emergency Power Generation 29
Introduction to Emergency Power Generation 29
Emergency AC Generation System 29
Voltage Regulation 32
Voltage Regulators 32
DC Generator Voltage Regulation 32
DC Generator Vibrating-Type Voltage Regulator 33
DC Three-Unit Regulator 34
DC Carbon Pile Voltage Regulator 36
Solid State Voltage Regulators 39
Transistorised Voltage Regulator – DC Alternator 40
AC Brushless Alternator Control 41
Power Distribution Systems 44
Electrical Bus Systems 44
Basic DC Generation Bus System 46

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 Basic Twin-Engine Split DC Bus System 46
Basic Twin Engine Split AC Bus System 46
Basic Twin AC Tied Bus System 47
Multi-Engine Split AC Bus System 48
Relays, Breakers and Contactors 49
Bus Tie Breaker 50
Generator Circuit Breaker 50
Auxiliary Contacts – Bus Tie Breaker and Generator Circuit Breaker 51
Inverters, Transformers and Rectifiers 53
Inverters 53
Transformers 55
Rectifiers 57
Transformer Rectifier Unit 57
Circuit Protection 60
Fuse 60
Current Limiter 60
Circuit Breakers 61
Switched Reverse Current Relay 64
Reverse Current Circuit Breakers 65
DC Overvoltage Protection 67
AC Overvoltage Protection 68
Differential/Feeder Fault 69
Merz-Price Protection System 71
External and Ground Power 72
Introduction to External and Ground Power 72
DC Power Receptacle 72
DC External Power Circuit 72
AC Power Receptacle and Plug 73
Ice and Rain Protection (11.12) 76
Learning Objectives 76
Ice and Rain Protection 77
Ice Protection 77
Rain Protection 77
Ice Formation 78
Types of Ice 78
Dangers of Ice Forming on an Aeroplane 80
Ice Detection 82

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 Ice Detection Methods 82
Visual Ice Detection 82
Electrical Ice Detection 82
Anti-Icing and De-Icing Systems 86
Types of Ice Control Systems 86
De-Icer Boots 86
De-icer Boot Inspection, Maintenance and Repair 87
Chemical De-icing 89
Propeller De-icing – Fluid System 90
Electrical Propeller De-Ice Control 90
Thermal Pneumatic Anti-Icing Systems 92
Engine Air Inlet Anti-Ice Systems 94
Electric Windshield Anti-Icing 97
Probe and Drain Heating 100
Pitot Static Probe Heaters 100
Pitot Static Probe Heater Circuit 101
Total Air Temperature Probe Heater Circuit 102
Galley and Lavatory Drain Heaters 103
Rain Removal and Repellent Systems 106
Windshield Wipers 106
Windshield Wiper Circuit 108
Windshield Washers 109
Pneumatic Rain Removal System 110
Rain Repellent System 111
Lights (11.14) 113
Learning Objectives 113
Aircraft Exterior Lighting 114
Exterior Lighting Systems 114
Navigation Lights 114
Anti-Collision Beacons 116
White Collision-Avoidance Strobe Lights 118
Landing Lights 120
Taxi Lights 122
Ice Detection or Wing Leading Edge Lights 123
Internal Lighting Systems 125
Cabin Lighting 125
Cabin Window Lighting 125

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 Passenger Advisory Signs 126
Lavatory Lighting 127
Passenger Reading Lights 128
Flight Compartment Lighting 129
Integral Instrument Panel Lighting 129
Post or Pillar Lights 130
Trans-Illuminated Panels 131
Floodlights 132
Utility or Wander Lights 133
Cargo Compartment Lights 134
Emergency Lighting 136
Emergency Lights 136
Emergency Exit Lights 136
Warning and Caution Lighting 138
Troubleshooting Lighting Systems 139

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 Electrical Power (11.6)
Learning Objectives
11.6.1 Explain the installation and operation of aeroplane batteries (Level 3).
11.6.2 Explain the purpose and operation of aeroplane DC power generation (Level 3).
11.6.3 Explain the purpose and operation of aeroplane AC power generation (Level 3).
11.6.4 Explain the purpose and operation of aeroplane emergency power generation (Level
3).
11.6.5 Explain the purpose and operation of aeroplane voltage regulation (Level 3).
11.6.6 Explain the purpose and operation of aeroplane power distribution (Level 3).
11.6.7 Explain the purpose and operation of aeroplane inverters, transformers and
rectifiers (Level 3).
11.6.8 Explain the purpose and operation of circuit protection (Level 3).
11.6.9 Explain the purpose and operation of external/ground power (Level 3).

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 Aeroplane Electrical Power System
Electrical Power System Maintenance
When performing maintenance on aircraft electrical systems, reference to electrical power can be
found in the relevant aircraft system of manuals. These manuals include the Aircraft Maintenance
Manual, The Wiring Diagrams Manual, the Illustrated Parts Catalogue and component vendor
manuals. Transport aircraft maintenance manual systems comply with the Air Transport Association
(ATA) Specification Reference under chapters ATA 20 Standard Practices and ATA 24 Electrical
Power.

Electrical Power Distribution

Aircraft electrical power distribution block diagram

A typical large aircraft electrical power system makes and supplies AC and DC power to the aircraft.
A standby AC and/or DC system gives normal and emergency power.

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 Aeroplane Batteries
Aircraft Battery Systems
Aircraft, almost without exception, use a negative-ground or single-wire earth (or ground) returns
system. This means that the negative terminal of the battery is connected directly to the metallic
portion of the aircraft structure, which places the structure at a negative potential. This allows
electrical components to be connected to the structure for a return path to the battery to complete a
closed circuit. Benefits for grounding in this manner include the reduction of Radio Frequency
Interference (RFI) by having fewer wires that can emit RFI energy and reduced weight. The electrical
components need only a single wire from the positive voltage source and a negative connection to
the aircraft structure.

The exception to this design occurs when the aircraft is built using composite materials in place of
metallic structures. As most composite materials are non-conductive, a two-wire electrical system
must be used.

Negative-ground, single wire system

The image shows a typical battery circuit for a light aircraft. The positive terminal of the battery
connects to the battery solenoid, which is a normally-open heavy-duty switch.

Some manufacturers refer to a solenoid as a contactor, but both terms are used to describe
components that essentially perform the same task to remotely control a large current source with a
small conductor and switch.

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 Starter contactor

When the master switch is closed, it completes a ground path to energise the battery solenoid coil.
Once the coil is energised, the main power connection is closed (in the solenoid) to complete the
circuit from the battery to the electrical distribution bus.

Freewheeling Diode
A freewheeling diode is installed across the coil of the solenoid to eliminate spikes when the master
switch is opened and the magnetic field from the coil collapses. Without a freewheeling diode, the
voltage spikes could cause damage to sensitive electronic components or arcing across the master
switch. The freewheeling diode allows the induced EMF (from a collapsing coil) to feed back into itself
rather than back into the distribution system.

Effect of a freewheeling diode

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 Typical Battery System

A typical battery system

A battery may be used for starting an aircraft. Once the generator is online, the generator will supply
power to applicable systems. It will also charge the battery.

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 Aircraft Ground Battery Charging
Some aircraft isolate the battery when external DC power is applied to prevent the possibility of
thermal runaway of a Nickel-Cadmium (Ni-cad) battery. Aircraft that do not have this feature
incorporate battery charger units that automatically disconnect charging current above a pre-set
battery temperature.

Battery temperature monitor system

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 Battery Temperature Monitor System
Many aircraft that use Ni-cad batteries have a battery temperature monitor system. Typically, this
system provides a continuous temperature indication of the battery or batteries. They may also warn
of high temperature conditions. A high-temperature indication enables action to be taken to isolate
the battery and prevent possible damage arising from excessive battery temperature.

A battery temperature monitor system

There are two independent temperature sensors (thermistors) in each battery. Each thermistor is
mounted on an intercell connector link of the battery. One sensor provides the temperature input for
the temperature indication circuit, while the other is used by the overheat warning circuit.

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 Ventilation Requirements
Lead acid batteries give off large quantities of hydrogen and oxygen (gassing) when charging.
Adequate ventilation is therefore required to safely remove these fumes and dump them outside the
aircraft. The aircraft’s airstream can be used to create a positive airflow ventilation system for the
battery compartment or sealed case by creating a pick up and outflow pipe through the aircraft’s skin.
Pressurised aircraft can also use the internal pressurised air, which is passed through a non-return
valve and finally dumped overboard.

Battery ventilation

System A uses a sump jar with a neutralising agent in it so that the fumes pass over the felt pad,
neutralising any acid or alkaline fumes before they exit the aircraft. This prevents damage
occurring to aircraft skin.
System B is a typical light aircraft system and does not incorporate sump jar.
System C is a pressurised aircraft system which passes pressurisation system air through a
non-return valve and into the battery case or compartment. It may or may not utilise a sump
jar.

If the battery is of the sealed-case type, the ventilation system will be connected to the case to
maintain some airflow through the case.

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 Battery showing vent and sump jar

Battery Connection
Light aircraft batteries have bolt-on connections like auto batteries. Smear lugs with an approved
lubricant before connection to inhibit corrosion.

Light aircraft lead acid battery

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 Larger fully enclosed batteries, where external connections cannot protrude though the case safely,
will usually have a quick disconnect socket fitted to the case. This type of connector requires some
form of positive locking device so that the connector does not unscrew during flight. If there is no
inbuilt locking device, the connectors should be lockwired closed with 26 AWG copper wire (safety
lockwire).

Quick-release type battery connections

Usually, these quick release terminals are lubricated with white petroleum jelly to prevent any
corrosion forming on the contacts which could affect serviceability or, worse still, make the battery
very difficult to remove. Remember: Once a battery is fitted to an aircraft, it may stay there for many
months before it is touched again.

Battery Compartments
All aircraft batteries need to be securely mounted in the aircraft. Whether it has its own isolated
compartment, or shares space with other equipment, it must be firmly bolted into a mounting cradle.

Battery tie down

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 Large metal batteries will have lugs built into the cover through which the hold down bolts can pass.
Plastic-cased batteries will generally have a metal clamp over the top. Whether wing nuts, hexagonal
nuts or quick release clamps are used for securing purposes, all should be lockwired for security
purposes.

Battery Installation Procedures
Before installing any battery in an aircraft, ensure the battery is the correct type. Refer to aircraft
maintenance manual. Before installing, check that its mounting tray, box or compartment and the
surrounding area are clean and free of corrosion or contamination. Check that the vent and drain
lines are in good condition and not blocked. Check that the neutralising jar is serviceable.

Usually, aircraft batteries with bolted terminals have the negative terminal of the battery connected
to the aircraft structure. When installing a battery, always connect the positive lead first. This way, if
contact is inadvertently made between the battery and the aircraft with a wrench, it will not cause a
spark. When removing a battery, always disconnect the negative lead first. If high or difficult lifting is
involved, get help or use some mechanical lifting device. If there is a possibility of contacting and
shorting the battery terminals, fit an insulator plug/cap onto the terminal connector.

Remember: Safe work practices must be applied to at all times.

Battery Servicing
The only servicing permitted on lead acid batteries fitted to an aircraft is the check and adjustment of
electrolyte levels and cleaning of terminals. If any electrolyte is spilt, always neutralise it before
washing it away. Lead acid batteries require a solution of water and bicarbonate of soda. Spills on
aircraft from Ni-Cad batteries require a chromic acid solution as a neutralising agent. Spills off
aircraft can be neutralised with a boric acid solution or vinegar.

After a battery servicing, always wash your hands before going to the toilet. Acid or alkaline burns on
sensitive skin are not nice.

Battery servicing caution

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 DC Power Generation
DC Power
On light aircraft, where a relatively small amount of electric power is used, an AC generator requiring
a constant-speed drive is simply too heavy. Modern light aircraft use DC alternators to produce
electric power. A DC alternator produces an AC voltage and uses internal rectifiers to produce a DC
output.

Light aircraft electrical system schematic

On larger aircraft, the normal DC power supply is produced by Transformer Rectifier Units (TRUs)
which change the engine-driven AC-generated 115-V AC to 28-V DC. The aircraft may also have
following DC power sources:

Aircraft main battery
Main battery charger
Auxiliary battery
Auxiliary battery charger.

The batteries are the backup DC source if other sources do not operate.

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 Twin commercial jet electrical schematic

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 AC Power Generation
AC Power
AC generators, often called alternators, are used as the principal source of electric power in almost all
transport-category aircraft. The AC system supplies almost all the electric power required for the
aircraft. Where DC is needed, rectifiers are used. For emergency situations, AC generators driven by
Auxiliary Power Units (APUs) or Ram Air Turbines (RATs) are often used.

AC power systems produce more power per weight of equipment than DC systems; however, most
AC generators require a constant-speed drive to maintain a constant AC frequency. A Constant-
Speed Drive (CSD) is a type of transmission that maintains a constant output rpm with a variable
input rpm.

Alternators are classified according to voltage, amperage, phase, power output (watts or kilovolt-
amperes [kVA]) and power factor. Three-phase alternators are typical for most aircraft applications.

The aircraft electrical power system has four main AC power sources and a standby power source:

Left engine driven generator
Right engine driven generator
APU generator or starter-generator
External power.

Typical aircraft power generation and distribution

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 On a turbine-powered aircraft, the engine-driven generators are driven through a Constant Speed
Drive (CSD). More modern aircraft use an Integrated Drive Generator (IDG), which is a constant-
speed drive and generator integrated into one unit.

The generators supply three-phase, 115/200-V AC at 400 Hz. The typical AC power system design
prevents two sources to the same load at the same time.

A static inverter supplies a single-phase, 115-V AC output to the AC standby power system.

Constant-Speed Drive Systems

Constant-speed drive and generator assembly

In an AC power system, it is usually necessary to maintain a constant speed in the AC generator. This
is because the frequency of the AC generator is determined by the speed with which it is driven. It is
especially important to maintain constant generator speed in installations in which the generators
operate in parallel. In this case, it is essential that generator speed be kept constant within extremely
close limits.

A Constant-Speed Drive (CSD provides constant-speed generator operation in an AC electrical
system. CSD units are manufactured in many designs to fit a variety of applications. The principle of
operation for all CSDs is essentially the same.

The complete CSD system consists of an Axial Gear Differential (AGD), whose output speed relative
to input speed is controlled by a flyweight-type governor that controls a variable-delivery hydraulic
pump. The pump supplies hydraulic pressure to a hydraulic motor, which varies the ratio of input rpm
to output rpm to maintain a constant output rpm to drive the generator and maintain an AC
frequency of 400 Hz.

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 Most CSDs are equipped with a Quick Attach/Detach (QAD) adapter. This unit allows generator and
CSD assembly removal and replacement in a matter of minutes. The QAD ring is mounted to the CSD
by means of several bolts through the mounting flange.

To remove the generator from the aircraft, one must only release the QAD using one fastener. This
mounting technique allows for quick line repair of an aircraft that has a defective generator CSD.

Integrated Drive Generator

Integrated drive generator (IDG)

Modern turbine-powered aircraft produce AC using an Integrated Drive Generator (IDG). The IDG
contains both the generator and the CSD in one unit. This concept helps to reduce both the weight
and the size of the traditional two-unit system.

The generator is an integral part of the IDG and cannot be replaced separately from the IDG. The
generator is mounted on the aft face of the CSD. The CSD, containing hydraulic trim units and a
differential assembly, converts the variable engine rpm to an alternator input speed of 12 000 rpm.
Older alternators typically rotate at 8000 to 9000 rpm. The 30 percent increase in alternator speed,
along with improved cooling features, has allowed for a reduction in alternator size without a
decrease in output power.

The IDG used on the Boeing 747 produces 90 kVA three-phase power for aircraft electrical systems
at 115 volts 400 Hz at 12 000 rpm. Three electrical subassemblies make up the generator (alternator)
portion of the IDG: the Permanent Magnet Generator (PMG), the exciter generator and rectifier
assembly and the main generator. The term generator is still used even though these items are
brushless alternators.

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 CSD and IDG quick attach/detach (QAS) adapter

An integrated drive generator is shown. However, CSD installations are similar.

CSD/IDG Indication and Warnings
A normal operating temperature for the cooling oil is approximately 93 °C (200 °F). To maintain the
correct cooling capacity, the oil level should be monitored periodically. A sight glass is installed on
most constant-speed drives to allow a quick check of the oil level.

In the case of an in-flight oil loss or an over temperature condition, a warning indicator will illuminate
on the flight deck. In this situation, the CSD is disengaged and inspected upon landing.

Most constant-speed drive units are equipped with an electrically activated generator-drive
disconnect mechanism. This disconnect couples the CSD input shaft to the CSD input spline. The CSD
disconnect is switched manually from the aircraft’s flight deck or automatically by a generator
control unit. The disconnect is activated in the event of certain generator system failures. After
disconnection, The CSD can only be reconnected on the ground.

Example of an generator panel

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 IDG/CSD Operation

IDG operational diagram

The IDG installation (a CSD and generator assembly is similar) consists of an alternating current
generator and a hydraulic transmission with mechanical control governing the rotational speed of the
alternating current generator (CSD). The power used to drive the alternating current generator is
controlled and transmitted from the aircraft engine through the combined effects of the differential,
the variable displacement hydraulic units and the fixed displacement hydraulic units.

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 Governing Section
In the governing section of the CSD, the governor is a spring-biased, flyweight-operated hydraulic
control valve. It functions to control porting of transmission charge oil to the control cylinder. During
steady state operation, supply pressure is reduced to the required control pressure. Depending on
valve stem position, charge oil is ported to the control piston or control oil is drained to the
transmission case. The normal operating frequency of the system is 400 (±4) Hz; however, the
governor can be adjusted on the aircraft by means of the adjustment screw to compensate for
frequency variations.

Clockwise rotation of the adjustment screw increases the frequency.
Counter-clockwise rotation of the adjustment screw decreases the frequency.
A 360-degree turn of the adjustment screw changes the frequency by approximately 3–4 Hz.

Note: Unstable and erratic frequencies cannot be corrected by governor adjustment.

Charge Pump
The charge pump is in the hydraulic circuit between the all-attitude reservoir, the charge filter and
the transmission. The charge pump supplies filtered oil to the cylinder blocks, governor, control
piston, lubricating system and generator cooling circuit.

Transmission Scavenge Pump
The transmission scavenge pump is in the hydraulic circuit between the transmission sump and the
scavenge filter. The transmission scavenge pump picks up lube oil and internal leakage and pumps it
through the scavenge filter and the aircraft IDG cooler into the all-attitude reservoir.

Generator Scavenge Pump
The generator scavenge pump is in the hydraulic circuit between the generator and the scavenge
filter. The generator scavenge pump picks up generator cooling and lube oil and pumps it through the
scavenge filter and aircraft cooler into the all-attitude reservoir.

Charge Relief Valve
The charge relief valve is in the hydraulic circuit between the hydraulic units and the reservoir. The
charge relief valve regulates the operating pressure of the charge oil system. The valve accomplishes
this function by controlling/metering the discharge of oil from the charge oil system to maintain the
pre-set charge pressure.

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 Oil Cooler
The oil cooler uses fan air from the engine to cool the CSD oil. The cooler has a pressure-operated
bypass valve that opens if the pressure differential across the cooler reaches a pre-determined value
(such as cold oil).

Hydraulic System Reservoir
The reservoir de-aerates the oil, returning some to the transmission sump. The remainder supplies
the charge pump.

Hydraulic Filters
Two filters are used to filter the oil in the hydraulic system: the charge filter, located in the charge
pressure line; and the scavenge filter, which is in the scavenge line between the scavenge pump and
the reservoir.

Note: These filters don't have by-pass capabilities, therefore, if either becomes blocked, and the
Differential Pressure Indicator is showing, the IDG must be replaced.

Differential Pressure Indicator
The scavenge filter housing contains a differential pressure indicator. This indicator warns of an
impending blockage and should not be ignored.

Note: As previously stated, if the Differential Pressure Indicator is visible, the IDG must be
replaced.

CSD Disconnect Mechanism
The disconnect is an electrically actuated device that de-couples the input shaft from the input spline
shaft in the event of a transmission malfunction. When the disconnect solenoid is activated by the
flight crew, a spring-loaded pawl moves into contact with threads on the input shaft. The input shaft
acts as a screw, and input rotation causes the input shaft to move away from the input spline shaft,
separating the driving dogs on the two shafts. When the driving dogs have been separated, the input
spline shaft, which is still being driven by the aircraft engine, spins freely in the transmission without
causing transmission rotation. Reset may be accomplished, with the engine stationary, by pulling out
on the reset handle until the solenoid snaps into position.

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 Generator Cooling
Owing to their compact size, most AC generators require some means of cooling during operation.
Older and/or less powerful generators are typically cooled by means of ram air forced through the
units. Newer systems use oil as the cooling agent.

The oil is sent from the CSD through the generator and then through an air/oil heat exchanger. The air
cools the oil, which is once again cycled through the CSD and generator. The use of oil cooling allows
for a higher-speed rotor within the generator section. A higher-speed rotor means a lighter, more
compact generator.

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 Emergency Power Generation
Introduction to Emergency Power Generation
Emergency power generation is installed on many aircraft to supply essential power in the event of
losing all normal power generation. Such a situation could arise if the engine-driven generators failed.
Emergency generators are driven either directly by an airstream-driven generator or driven from a
hydraulic motor being supplied pressure from an airstream-wind-driven hydraulic pump.

Emergency generators are, normally without exception, permanent magnet alternators and are
typically constructed with a permanent magnet rotor and do not require battery power to function.

Emergency AC Generation System

Hydraulic electrical generating system (HEGS)

Larger transport aircraft utilise a hydraulic motor-driven emergency generator system to provide
emergency or standby electrical power in the event of the loss of both normal main generator buses.
The Airbus A330 system will be discussed here.

The emergency AC generation system consists of a hydraulic motor-driven generator which is
designed to restore the essential power network in case of the loss of the two main generator buses
(AC bus 1 and AC bus 2). Hydraulic power for the hydraulic motor is supplied by a ram air turbine.

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 Ram air turbine

A Ram Air Turbine (RAT) is installed on most large or complex twin-engine passenger aircraft to
provide an emergency source of hydraulic and electric power. The RAT is an airstream-driven
hydraulic pump that provides emergency hydraulic power for the flight controls if hydraulic power is
lost on both engines. On some aircraft, the RAT is automatically deployed if both engine-driven
generators fail, providing emergency hydraulic power to run a hydraulic motor-driven generator and
emergency hydraulic power.

The hydraulic electrical generating system consists of the following components:

Hydraulic Constant Speed Motor and AC Generator (CSM/G)
Generator Control Unit (CSM/G GCU).

The hydraulic constant speed motor can be supplied by the aircraft’s main hydraulic system, which is
powered either by the engine driven hydraulic pumps or by the Ram Air Turbine (RAT) pump. The RAT
will supply hydraulic pressure if both engines or both engine-driven hydraulic pumps fail.

With the loss of the main AC busbars, the CSM drives the AC generator, which is controlled by the
Emergency Generator Control Unit CSM/G GCU. The AC power supplied is three-phase 115-V AC at
400 Hz, which is fed to the essential AC and DC buses through the Emergency Bus Supply contactor
and Essential Transformer Rectifier unit (ESS TR).

If power is lost to the essential AC and DC main busbars, the battery supplies the DC essential bus
(DC ESS BUS) and the AC ESS BUS via the static inverter and the emergency bus supply contactor.

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 The AC ESS shed bus and the DC ESS shed bus are shed respectively by their essential shed bus
contactors when the CSM/G is supplied by the RAT hydraulic pump. In the battery only configuration,
the AC ESS bus shed network is isolated by the emergency bus supply contactor.

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 Voltage Regulation
Voltage Regulators

Voltage regulators

Regardless of whether it is an AC generator, DC generator or DC alternator, typically the voltage
regulator senses the output and controls (regulates) the field current under varying load conditions.
As load conditions change, the voltage regulator adjusts the field current, automatically (typically)
maintaining the generator output at the required output voltage. Typically, aircraft DC
generators/alternators are regulated to 28-V DC (14-V DC for 12-V light aircraft) and AC generators
to 115-V AC (200-V AC 3Ø).

DC Generator Voltage Regulation

Control of the field current using a rheostat in the field coil circuit

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 Efficient operation of electrical equipment in an aircraft depends on maintaining a fixed supply
voltage under varying load requirements.

One factor which determines the voltage output of a generator is the strength of the field current,
which can be easily controlled. One way to control the field current is to install a rheostat in the field
coil circuit.

When the rheostat is set to increase the resistance in the field circuit, less current flows through the
field coils, and the strength of the magnetic field decreases. Consequently, less voltage is induced into
the armature, and generator output decreases.

When the resistance in the field circuit is decreased with the rheostat, more current flows through
the field coils, and the magnetic field becomes stronger. This allows more voltage to be induced into
the armature, which produces a greater output voltage.

One thing to keep in mind is that the weaker the magnetic field is, the easier it is to turn the armature.
On the other hand, if the strength of the magnetic field is increased, more force is required to turn the
armature. This means that when the load on a generator increases, additional field current must be
supplied to increase the voltage output, and additional force is required to turn the armature.

DC Generator Vibrating-Type Voltage Regulator

Vibrating-type voltage regulator

This basic rheostat principle is further developed by the addition of a solenoid which electrically
connects or removes the field rheostat from the circuit as the voltage varies. This type of setup is
found in a vibrating-type voltage regulator.

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 When the output voltage rises above a specified critical value, the downward pull of the solenoid’s
coil exceeds the spring tension and contact B opens. This reinserts the field rheostat in the field
circuit. The additional resistance reduces the field current and lowers output voltage. When the
output voltage falls below a certain value, contact B closes, shorting the field rheostat, and the
terminal voltage starts to rise. Thus, an average voltage is maintained with or without load changes.

The dashpot P provides smoother operation by acting as a dampener to prevent hunting, and
capacitor C across contact B helps eliminate sparking.

With a vibrating-type voltage regulator, contact B opens and closes several times per second to
maintain the correct generator output. Based on this, if the solenoid should malfunction or the
contacts stick closed, excess current would flow to the field, and generator output would increase.

DC Three-Unit Regulator

A three-unit regulator

Many light aircraft employ a three-unit regulator for their generator systems. This type of regulator
includes a current limiter and a reverse current cut-out in addition to a voltage regulator.

The action of the voltage regulator unit is like the vibrating-type regulator described earlier. The
second of the three units is a current regulator to limit the output current of the generator. The third
unit is a reverse current cut-out that disconnects the battery from the generator. If the battery is not
disconnected, it will discharge through the generator armature when the generator voltage falls
below that of the battery, thus driving the generator as a motor. This action is called “motoring” the
generator and, unless prevented, will discharge the battery in a short time.

The operation of a three-unit regulator shown is described in the following paragraphs.

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 The action of vibrating contact C1 in the voltage regulator unit causes an intermittent short circuit
between points R1 and L2. When the generator is not operating, spring S1 holds C1 closed; C2 is also
closed by S2. The shunt field is connected directly across the armature.

When the generator is started, its terminal voltage will rise as the generator comes up to speed, and
the armature will supply the field with current through closed contacts C2 and C1.

As the terminal voltage rises, the current flow through L1 increases and the iron core becomes more
strongly magnetized. At a certain speed and voltage, when the magnetic attraction on the movable
arm becomes strong enough to overcome the tension of spring S1, contact points C1 are separated.
The field current now flows through R1 and L2. Because resistance is added to the field circuit, the
field is momentarily weakened and the rise in terminal voltage is checked. Also, since the L2 winding
is opposed to the L1 winding, the magnetic pull of L1 against S1 is partially neutralized, and spring S1
closes contact C1. Therefore, R1 and L2 are again shorted out of the circuit, and the field current
again increases; the output voltage increases, and C1 is opened because of the action of L1. The cycle
is rapid and occurs many times per second. The terminal voltage of the generator varies slightly but
rapidly above and below an average value determined by the tension of spring S1, which may be
adjusted.

The purpose of the vibrator-type current limiter is to limit the output current of the generator
automatically to its maximum rated value to protect the generator. L3 is in series with the main line
and load. The amount of current flowing in the line determines when C2 will open, placing R2 in series
with the generator field. This action decreases the field current and the generated voltage. When the
generated voltage is decreased, the generator current is reduced. The core of L3 is partly
demagnetized, and the spring closes the contact points. This causes the generator voltage and
current to rise until the current reaches a value sufficient to start the cycle again. A certain minimum
value of load current is necessary to cause the current limiter to vibrate. By reducing the output
voltage, we also reduce generator current.

The voltage regulator is actuated by line voltage, whereas the current limiter is actuated by line
current.

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 Inside a three-unit regulator

The purpose of the reverse current cut-out relay is to automatically disconnect the battery from the
generator when the generator voltage is less than the battery voltage.

If this relay was not used in the generator circuit, the battery would discharge through the generator,
driving the generator as a motor (termed “motoring the generator”). This could flatten the battery,
damage the generator windings, stall the engine or break the connecting generator engine quill shaft.

There are two windings, L4 and L5, on the soft iron core. The current winding, L4, consisting of a few
turns of heavy wire, is in series with the line and carries the entire line current. The voltage winding,
L5, consisting of many turns of fine wire, is shunted across the generator terminals.

When the generator is not operating, contact C3 is held open by the spring S3. As the generator
voltage builds up, L5 magnetizes the iron core. When the current (because of the generated voltage)
produces sufficient magnetism in the iron core, contact C3 is closed, as shown. The battery then
receives a charging current. The coil spring, S3, is so adjusted that the voltage winding will not close
the contact points until the voltage of the generator is more than the normal voltage of the battery.
The charging current passing through L4 aids the current in L5 to hold the contacts tightly closed.
Unlike C1 and C2, contact C3 does not vibrate. When the generator slows down or, for any other
cause, the generator voltage decreases to a certain value below that of the battery, the current
reverses through L4 and the magnetic field of L4 opposes that of L5. This reduction in the magnetism
of the core causes C3 to open, preventing the battery from motoring the generator. C3 will not close
again until the generator terminal voltage exceeds that of the battery by a predetermined value.

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 DC Carbon Pile Voltage Regulator

Aviation Australia
Carbon-pile voltage regulator

Since contacts tend to pit or burn when large amounts of current flow through them; vibrating-type
regulators and three-unit regulators cannot be used with generators that require a high field current.
Therefore, heavy-duty generator systems require a different type of regulator, such as the carbon-
pile voltage regulator.

Carbon-pile voltage regulators controlling compound-wound generators with reverse-current cut-
out relays were used in older aircraft DC generating systems.

Compound wound generators DC generators have both series and shunt field windings. The output
voltage remains relatively constant for all values of load current within the design of the generator.

The carbon-pile voltage regulator derives its name from the fact that the regulating element (variable
resistance) consists of a stack, or pile, of carbon discs. Usually, the carbon pile has alternate hard
carbon and soft carbon discs contained in a ceramic tube with a carbon or metal contact plug at each
end.

At one end of the pile, several radially arranged leaf springs exert pressure against the contact plug,
thus keeping the discs pressed firmly together. For as long as the discs are compressed, the resistance
of the pile is very low. If the pressure on the carbon pile is reduced, the resistance increases. By
placing an electromagnet in a position where it will release the spring pressure on the discs as the
voltage rises above a predetermined value, a stable and efficient voltage regulator is obtained.

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 Carbon pile voltage regulator circuit

The carbon pile voltage regulator is connected with the carbon pile in series with the generator field,
and the voltage coil is shunted across the generator output. A small manually operated rheostat is
connected in series with the voltage coil to provide a limited amount of voltage adjustment.

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 Equalising Circuit
When two or more generators are connected in parallel to a power system, the generators should
share the load equally. If the voltage of one generator is slightly higher than that of the other
generators in parallel, that generator will assume the greater part of the load. For this reason, an
equalising or paralleling circuit must be provided that will cause the load to be distributed evenly
among the generators.

An equalising circuit includes an equalising coil wound with the voltage coil in each of the voltage
regulators, an equalising bus to which all equalising circuits are connected and a low-resistance shunt
in the ground lead of each generator. The equalising coil will either strengthen or weaken the effect of
the voltage coil, depending on the direction of current flow through the equalizing circuit. By
controlling the generator output voltages, each generator shares the load current equally.

The low-resistance shunt in the ground lead of each generator causes a difference in potential
between the negative terminals of the generators that is proportional to the difference in load
current. The shunt is of such a value that there will be a potential difference of 0.5 V across it at
maximum generator load.

Equalising circuit

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 Solid State Voltage Regulators

The grounded regulator type (L) and the grounded field type (R)

Two regulator designs can be used:

The grounded regulator type—the regulator controls the amount of battery ground (negative)
going to the field winding in the rotor.
The grounded field type—the regulator controls the amount of battery positive (B+) going to
the field winding in the rotor.

Transistorised Voltage Regulator – DC Alternator

Transistorised voltage regulators

Transistorised voltage regulators have now superseded other forms of voltage regulators in modern
aircraft. The regulator discussed in this section is used on a light aircraft alternator rectifier unit.

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 Operation
The master switch is turned on, and the charge light illuminates, gaining its earth via the alternator (L)
terminal, alternator rotor and transistor T1 (which is biased on). This small current gives the field
initial excitation. Once the engine is started, the alternator output builds up.

The rotor voltage is half wave rectified by the field exciter diodes and supplies the alternator rotor
field gaining earth via the biased-on transistor T1. When the alternator voltage approaches battery
voltage, the charge indicator light has near equal potential on each side and will extinguish.

Alternator output voltage is dropped across resistors R1, R2 and R3. When the set voltage value is
reached, the Zener Diode (ZD) will conduct biasing transistor T2 on. The flow of current through T2
and R4 causes a voltage drop across R4 which biases T1 base emitter off.

T1 switching off stops the rotor field current, and the alternator voltage drops. This drop-in voltage
across R1, R2 and R3 causes the zener diode to stop conducting, and transistor T2 switches off. T2
switching off lowers the voltage drop across R4 and the base of transistor T1 increases (more
positive) and switches on, allowing field current to flow. This process is repeated at a rate required to
maintain alternator output voltage at the set value with varying load and speed conditions.

The surge quench diode in the regulator is connected across the alternator rotor field winding. When
power is applied to the field by transistor T1, the surge quench diode is reverse biased and will not
conduct. When transistor T1 switches off the field current, the magnetic field around the field coil
collapses, inducing a current in the field coil with opposite polarity to that of the applied voltage
(inductor theory). The opposite polarity forward biases the diode, which conducts and shorts out the
current induced in the field coil, preventing transistor T1 from sustaining any damage if the induced
voltage exceeds the peak inverse voltage of T1.

Note: Late model transistorised regulators are now mounted in the alternator rectifier unit and
are sealed. They are encapsulated, and if they are unserviceable, repair can only be done by
replacing them with a new item. Some light twin engine aircraft have one regulator controlling
both alternators and one regulator as an alternate that can be selected by the pilot if the first
regulator fails.

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 AC Brushless Alternator Control

Brushless generator control schematic

There are three separate generators within one case: (1) the permanent magnet generator, (2) the
exciter generator, and (3) the main generator. Each of these three units is an essential part of the
modern brushless alternator.

The permanent magnet, which is connected to the rotor, is used to induce an alternating current into
the stationary PMG three-phase armature winding. The Generator Control Unit (GCU) rectifies the
AC armature current and sends a DC voltage to the exciter field winding. The exciter field induces an
alternating current into the exciter armature. The exciter armature is connected to the rotating
rectifier, which changes the alternating current to direct current and sends a current to the main
generator field.

The main field induces an AC voltage into the main generator armature. The main generator armature
is a three-phase winding that produces 115 volts across a single phase and 200 V across two phases.
This armature is connected to the output terminals of the generator and hence supplies the electric
power for the aircraft systems.

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 Brushless alternator electrical schematic

The GCU monitors the main generator output and in turn regulates the exciter field current as
needed. If more generator output is required, the GCU will increase the exciter field current; this will,
in turn, increase the exciter armature output and the main field current. A stronger main field will
increase the main armature’s output. If less generator output is needed, the GCU will weaken the
exciter field current, and the generator output will decrease.

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 Power Distribution Systems
Electrical Bus Systems

Aircraft bus system

The output from generating sources is connected to one or more low resistance conductors known as
bus bars. Bus bars can be a copper or aluminium strip or cables to which the supply and feed
connections can be made. Large aircraft contain several bus bars. Each has a specific task necessary
for power distribution and load sharing between different loads.

Bus systems are categorised into their order of importance or hierarchy:

Hot battery bus
Essential DC bus
AC bus (main generator buses)
AC essential bus
AC non-essential bus.

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 Hot battery bus functional diagram

Hot Battery Bus
The aircraft battery is normally directly connected to the hot battery bus. The hot battery bus
supplies power directly to a few critical loads, e.g., fire extinguishers and fuel and hydraulic fire shut
off valves.

Essential DC Bus
The essential DC bus, also referred to as the battery bus, is connected to the hot battery bus via a
contactor.

AC Bus
The AC bus is fed from its respective main generator.Essential buses are connected AC bus systems.
They supply power to essential lighting, flight control systems, communication and navigation
systems and other high-priority electrical systems required to ensure safe flight in an
emergency.Non-essential buses supply galley power, non-essential lighting and other low-priority
electrical systems which can be isolated in an in-flight emergency. Non-essential buses may also be
called shed buses or isolation buses.

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 Load Shedding
Non-essential systems are isolated (turned off) during partial generator system failure. This is to
prevent overloading the active generator, which would be incapable of supplying electrical power to
all aircraft systems.

Basic DC Generation Bus System
This is a simple representation of a small aircraft with one generator and how the power is
distributed. The battery would be charged from the bus when generator was outputting at a higher
voltage. The inverter provides the aircraft with AC voltage.

Simple single-generator system

Basic Twin-Engine Split DC Bus System
A split bus configuration occurs when each generator powers its own individual bus. If one generator
fails, then the failed generator is isolated from its bus, and the power on the other bus is coupled to
that bus by a Bus Tie Breaker (BTB).

Tied bus system

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 Basic Twin Engine Split AC Bus System
In this example, the AC generators (alternators) supply their individual buses. The AC bus then feeds
the Transformer Rectifier Unit (TRU or T/R) which provides the DC requirements of the aircraft as
well as charge the battery. The emergency AC bus is fed from the AC bus directly. Should this AC
supply fail for any reason, the static inverter would be commanded to start and provide emergency
AC from the battery.

Basic twin-engine split AC system

Basic Twin AC Tied Bus System

Tied bus system

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 A tied bus system means the AC generators outputs are connected onto the same bus. Before the AC
generators can be connected or paralleled, they must be matched so their output waveforms must be
the same:

Their output voltages must be the same.
They must have the same frequency.
Their voltages are in phase.
They must have the same phase rotation (3 phase).

The phase rotation will be correct if the generators are all connected to the lines in the same way. If
this is not correct, synchronisation will not be achievable.The split system breaker (SSB) will not close
if the buses’ properties are outside the limits of voltage, phase rotation sequence or frequency.

Multi-Engine Split AC Bus System
When operated on the ground with external power connected and no engines running, all loads will
be supplied by the external power source via the external power relay and the closed contacts of the
BTB (note that both GCBs will be tripped and the changeover relay will be energised closed).

Multi-engine split AC bus system

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 When one of the aircraft’s engines is started and its generator is operating within system limits, its
GCB will energise close. This will cause the external power relay to open, removing external power
from the system loads. The BTB, however, will remain closed, connecting the three-phase power from
the operational generator to all the aircraft’s loads.

When the second aircraft engine is started and its generator is operating within system limits, its
GCB will close. As the power to the BTB’s close coil is now redirected through the auxiliary contacts
of the GCB to the BTB’s trip coil, the BTB will trip, causing the operational generators to supply their
individual busbars. Power from the generator busbars is then distributed to the AC non-essential
loads and TRUs. The essential AC loads are supplied from the AC essential bus, which under normal
operating conditions (both AC generators operating within system tolerance), is connected via a
changeover relay to the no. 1 generator bus.

If one of the generators should become inoperative (fail or be switched off), its GCB will trip. Power is
now supplied via the auxiliary contacts of the tripped GCB to the close coil of the BTB, causing the
BTB to close. When closed, the BTB connects both generator buses together, thereby enabling the
output from the serviceable generator to supply power to all system loads.

The normal, essential and emergency buses are separated from each other, particularly with respect
to order of importance for flight safety and in relation to redundancy following power malfunctions.
If, for any reason, both generators should become inoperative (failed or switched off) then both GCBs
will trip. Battery power will energise the BTB closed; however, as both generators are off line, no
power will be available to operate the non-essential loads. In this situation, the changeover relay
between the no. 1 generator bus and the essential AC bus will automatically de-energise and connect
the essential bus to the static inverter. The system’s essential AC loads will be supplied with 115-V AC
from the static inverter, while the non-essential AC loads will be effectively isolated. As we saw in DC
systems, if the system operates for a long period of time under these conditions, the battery will
become discharged. Therefore, before this occurs, the circuit’s battery relay will be turned “off,”
isolating the aircraft’s AC and DC essential loads from power while allowing the aircraft to operate
under emergency DC power.

Relays, Breakers and Contactors
There is much confusion surrounding the terminology of relays and solenoids because of their
similarities. Relays are often called solenoids and vice versa. Many aircraft manufacturers have
substituted the term contactor, relay or breaker for electrical switching solenoids. Relays are usually
used for low-current switching applications.

Relay (L) and contactor (R) functional diagram

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 The part of the relay attracted by the electromagnet to close the contact points is called the
armature. The movement of the armature either closes or opens the contact points. In some cases,
the electromagnet operates several sets of contact points simultaneously.

Bus Tie Breaker

Typical contactors used in high-current applications

Bus Tie Breakers (BTBs) contain three heavy-duty contacts which connect three-phase power to the
generator bus bars, where it is distributed to the aircraft AC loads. They also contain several auxiliary
contacts that are used to connect various control and indication circuits within the AC distribution
system.

Power supplied to the close coil causes the main contacts to close and the auxiliary contacts change,
so the normally open contacts close and become mechanically locked in this position. Power can now
be removed from the close coil, and the breaker remains in the closed position.

Power applied to the trip coil releases the mechanical lock, and spring-tension forces the main
contacts to open and the auxiliary contacts to return to the normally closed position.

BTBs may be interchangeable with three-phase contactors, Generator Circuit Breakers (GCB) or Bus
Tie Contactors (BTC) of the same part number; however, each will perform different functions within
the electrical circuit.

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 Generator Circuit Breaker
The same contactor can be used a Generator Circuit Breaker (GCB).

The main functions of the GCB in a split bus system are:

To connect the AC generator’s output to its respective bus if the generator is serviceable
To ensure that when the generator’s output is connected to the generator bus the bus tie
breaker is tripped, therefore ensuring that the AC loads receive power from only one power
source at any one time
To isolate the generator’s output from the aircraft’s loads if a fault is detected by the generator
control unit.

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 Auxiliary Contacts – Bus Tie Breaker and Generator Circuit
Breaker
Interlocking circuitry through auxiliary contacts of contactors and breakers is used to prevent
unsynchronised power sources being connected in parallel. The auxiliary contacts have both normally
closed and normally open contacts. The bottom set of contacts will trip all the other generator
breakers, so ground-power cannot be connected to any generator.

Switching on the oncoming source automatically switches off the present source. For example, if
ground power is supplying the loads, and the APU generator is switched on the APU breaker will
close. The APU breaker auxiliary contacts de-energise the ground power contactor, disconnecting
ground power from the bus system.

GCBs and BTBs

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 Inverters, Transformers and Rectifiers
Inverters
An inverter is used in some aircraft systems to convert a portion of DC power to AC. These inverters
are usually built to supply current at a frequency of 400 Hz, but some are designed to provide more
than one voltage, for example, 26-V AC in one winding and 115 V in another.

There are two basic types of inverters: rotary and static. Either type can be single phase or
multiphase.

Rotary Inverter

Rotary inverter

Rotary inverters are motor-generators; a constant-speed DC motor is employed to drive an
alternator (AC generator) designed to produce the power required.

The rotors of the motor and the alternator are dynamically balanced and are mounted on the same
shaft. Fans are also mounted on the shaft to provide for air cooling.

Inverters utilize an input voltage of 26 to 29-V DC. The output is 115 V, single-phase; 115 V, three-
phase; or 200 V, three-phase. The frequency is 400 Hz for all phases.

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 Maintenance of rotary inverters is set forth in the manufacturer’s maintenance or service manual.
The control box on top of the inverter should not be disassembled in the field. If it appears to be
defective, the entire inverter should be sent to a repair shop that is equipped to perform the electrical
and electronic work and tests that may be required. Rotary inverters have automatic load demand
(they begin operation once a load is activated and shut down when the load is removed).

Disadvantages of a rotary inverter are a lack of frequency control, low surge capability (50% above
maximum rating) and lower efficiency (50% to 80%). Rotary inverters generally require more
scheduled maintenance than their equivalent static types due to the mechanical aspects of the DC
motor, i.e., brushes and commutator. In most cases, rotary inverters have now been replaced by static
inverters.

Static Inverters
A static or solid-state inverter serves the same functions as other inverters. However, it has no
moving parts and is therefore subject to less maintenance problems than the rotary inverter.

Static inverter

The unit shown uses an input voltage of 18 to 30-V DC and produces an output of 115 V, single-phase
alternating current with a frequency of 400 Hz.

Static Inverter Basic Operation

Static inverter block diagram

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 The internal circuitry of a static inverter contains standard electric and electronic components, such
as diodes, transistors, capacitors and transformers. Refer to the block diagram:

The filter provides a clean DC voltage to the 400 Hz oscillator.
A 400 Hz oscillator produces signals with the correct timing (2.5 mS between pulses).
The pulse shaper and power driver produce a 400 Hz square wave at the correct voltage and
frequency.
The harmonic filter removes everything that is not 400 Hz.
The output stage/final filter conditions the signal for use (pure sine wave).
A regulator circuit ensures the correct voltage and frequency are maintained.

If static inverters require repair, they should be sent to an approved facility that is equipped to
perform the work required. Because of miniaturisation of electronic components, static inverters
have become relatively small and lightweight. This has made it possible for light single-engine aircraft
to employ AC electrical systems for instrumentation.

Transformers

Transformer

Transformers allow the values of AC voltage and current to be changed using mutual inductance. A
typical transformer consists of two coils of wire wound around a common core but not connected
electrically.

When some alternating current flows in the primary coil, a voltage is induced into the secondary coil.
The amount of voltage generated in the secondary coil is equal to the voltage in the primary times by
the turns ratio between the two coils.

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 For example, 100 turns in a primary coil and 1000 turns in a secondary equates to a turns ratio of
1:10. Therefore, if 115 volts flows across the primary, 1150 volts are induced across the secondary.
Since a transformer does not generate any power, the product of the voltage and the current in the
secondary coil must be the same as that in the primary coil (less the transformer losses).

Therefore, whenever volts are increased in a transformer, amperes must decrease by the same ratio.
In other words, if the voltage is increased by a ratio of 1:10, the current must decrease by a ratio of
10:1.

A transformer can have its primary coil connected directly across an AC power line, and if there is an
open circuit in the secondary coil, the back voltage produced in the primary coil blocks the source
voltage so almost no current flows through the primary winding. However, when the circuit is
complete in the secondary coil, secondary current flows, producing lines of flux that oppose the back
voltage and allow source current to flow in the primary coil.

Multiple secondaries or tappings

Some transformers may have multiple secondaries or tappings for various voltages (both higher and
lower than supply voltage). A tap is nothing more than a wire connection made at some point on a
winding between the very ends

Multi-tap transformer

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 The winding turn/voltage magnitude relationship of a normal transformer holds true for all tapped
segments of windings.

Rectifiers
Rectifier Principles

Rectifier circuit

It is often necessary to convert alternating current into direct current to power various circuits in the
aircraft or within electronic equipment. The conversion of alternating to direct current is
accomplished by a circuit referred to as a rectifier. Rectifier circuits typically employ diodes; these
allow current flow in only one direction.

In the illustration, the input would be stepped down from 115/200-V AC to around 30-V AC, which
would then be rectified for a 28-V DC output.

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 Transformer Rectifier Unit

Transformer rectifier unit

Transformer Rectifier Units (TRUs) are designed to operate on a three-phase AC input and provide a
continuous DC output.

In the usual circumstance, it is 115-V AC (200-V AC phase to phase) 400 Hz going in and 28-V DC out.
In the case of more modern aircraft (a 787, for example), the generators produce 235-V AC but are
frequency wild (frequency governed by the rotational speed of the engine).

They consist of a transformer and two three-phase bridge rectifier assemblies. The transformer has a
star-wound primary winding and two secondary windings, one star and one delta. Each secondary is
connected to an individual bridge rectifier, which is made up of six silicon diodes connected in parallel.

A shunt connected in series with the output enables reading of amps at auxiliary terminals. Cooling of
TRUs is typically by fan forced airflow. A thermal switch provides warning through an overheat (light)
(set at 150 °C to 200 °C).

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 400 Hz, three-phase AC full wave rectified

The 400 Hz, three-phase AC, when full wave rectified by the six diodes, produces a DC voltage with a
ripple frequency of 2400 Hz. A star-to-star transformer’s input and output are in phase. A star-to-
delta transformer’s input and output are 30 degrees out of phase. The outputs of both secondary
outputs are then full wave rectified. Therefore, the parallel rectified outputs of the two secondary
windings have a DC ripple frequency of 4800 Hz. With such high frequency ripple, the DC voltage is
almost linear, and the capacitive effect of the rectifier diodes smooths the ripple to an almost
negligible amount.

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 Circuit Protection
Fuse

© Aviation Australia
Typical fuses

One of the cheapest and most simple forms of protection for electronic circuit is the fuse. Although
the outer appearance of fuses varies widely in electronic and electrical appliances, the basic
components of the physical construction are the same. These components are the body or case,
mounting and fuse link.

The body or case can be made of glass, ceramic, fibre or another non-conducting material. The body
not only holds the fuse together, but its design and construction material have important functions.
For example, a glass body allows easy identification of a blown fuse. Some ceramic fuses are designed
for use in areas where a spark from a blowing fuse could be a hazard, especially in combustible
environments.

The mounting forms the electrical connection to the circuit. There are several types of mountings,
including knife blade, cartridge or ferrule, and lead connection.

The fuse link connects to the mounting and is the part of the fuse that ‘breaks’ the circuit. The fuse
link is designed to disconnect circuit current once predefined limits are exceeded. The limits are
determined by the size and composition of a fusing link. Once the current limit of the fusing link is
exceeded, the heat generated by the current flowing through the fusing link will melt (or blow) the
fusing link. There are various types of fuse link, including bead, element filament and others.

In the cartridge fuse, the fuse link is enclosed in a tube of insulating material with metal ferrules at
each end (for contact with the fuse holder). Some common insulating materials are glass, Bakelite or a
fibre tube filled with insulating powder. In the slow-blow fuse illustration shown above, a wire wound
resistor limits current flow and introduces a time factor.

A fuse should only be replaced with one of the same voltage and current rating.

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 Current Limiter

Current limiter

The current limiter is another kind of fuse commonly found in aircraft power distribution systems and
other high-current DC power systems. It is a device that behaves more like a fusible link than a fast-
blow fuse. It is designed to protect against hard faults as opposed to continuous but small overloads.
This device will carry nearly two times their rated current indefinitely and take over six times longer
to open than a fast-blow fuse.

Due to the long time constant and overload capability, current limiters are not subject to the nuisance
tripping encountered with fuses. Current limiters are used in large aircraft to protect long power
distribution leads that carry huge starter-generator currents and battery feeds.

Circuit Breakers
Circuit breakers overcome the one major disadvantage of a fuse when protecting a circuit. A fuse
destroys itself, whilst a circuit breaker ‘trips’ and can be reset once the fault is rectified. Another
advantage is that it gives a visual indication that circuit parameters have been exceeded and the
circuit is no longer operating. There are magnetic and thermal circuit breakers.

Magnetic Circuit Breaker

Magnetic circuit breaker

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 Inside the sensing coil is a non-magnetic delay tube which houses a spring-biased moving magnetic
core. An armature links the contacts to the coil mechanism, which functions as an electro-magnet.
When the circuit breaker is set (button actuator pushed in, rocker actuator to the correct position,
etc.), current flows through the sensing coil, and a magnetic field is created around the coil. As current
flow increases above the circuit breakers ‘rated’ current, the following occurs:

The strength of the magnetic field increases.
The core moves towards the pole piece.
Magnetic circuit efficiency is increased and electro-magnetic force increases.
The core reaches the fully ‘in’ position.
The armature is attracted to the pole piece.
The trip mechanism activates (and the circuit breaker is ‘tripped’).
The contacts are opened.
The circuit breaker must be reset manually.

Thermal Circuit Breaker

Thermal circuit breaker

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 A thermal circuit breaker uses a bimetallic strip to operate. The basic internal construction of a
thermal circuit breaker is shown above. The thermal circuit breaker consists of three major
assemblies:

Bimetallic thermal element
Contact-type switch unit
Mechanical latching mechanism.

In normal operation, current flows through the main contacts and thermal element to the load. The
heat produced in the thermal element is radiated away quickly. When current exceeds the circuit
breakers rating (as in a short circuit), the temperature of the thermal element begins to build up.Due
to the different rates of expansion of the two metals in the thermal element, the following actions
occur:

The thermal element distorts.
The latch mechanism releases.
The main switch contacts open.
The push button extends.
The circuit breaker has now tripped.
No current is supplied to the load.

Circuit breaker panels are clearly labelled to show the circuits they protect, and circuit breakers must
clearly show their current rating in amps. The primary reason why circuit breakers and fuses are so
close to the power supply (busbar) is to protect the wiring run from short circuits, which would cause
an overload and possible fire. The secondary feature is to protect the component at the end of the
wiring.

Tripped circuit breaker

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 A small white band shows when the circuit breaker is tripped, activated or popped. This aids with the
identification of tripped circuit breakers on aircraft panels.

Trip-Free/Non-Trip Free Circuit Breakers
Circuit breakers are classified as being trip free or non-trip free.

A trip-free circuit breaker is a circuit breaker that will trip (open) even if the operating mechanism
(on-off switch) is held in the on position. A non-trip-free circuit breaker can be reset and/or held on
even if an overload or excessive heat condition is present. In other words, a non-trip-free circuit
breaker can be bypassed by holding the operating mechanism on.

Trip-free circuit breakers are used on circuits that cannot tolerate overloads and on nonemergency
circuits. Examples of these are precision or current sensitive circuits, nonemergency lighting circuits
and nonessential equipment circuits.

Non-trip-free circuit breakers are used for circuits that are essential for operations. Examples of
these circuits are emergency lighting, required control circuits and essential equipment circuits.

Circuit Breaker Notes
A small white band shows when tripped.
They protect circuit wiring.
They can be reset and there is no need to carry spares.
There are magnetic or thermal (bimetallic) types.
Breakers are either trip free or non-trip free.
Trip free will still trip even if trying to reset.
Thermal trip free must cool down before being reset.
Non-trip free can be manually held closed.
The most common is trip-free thermal.

Circuit Breaker Precautions
If a circuit breaker has tripped, do not immediately reset it. First, isolate the faulty circuit or
component and repair it, then reset the circuit breaker. Resetting it immediately could result in
further damage to the circuit or equipment being protected. When replacing a damaged or
unserviceable circuit breaker, only use the circuit breaker stated in the applicable publication. Failure
to adhere to this could damage the circuit or equipment the circuit breaker is protecting.

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