Marine Electrical Systems: An Overview

High Voltage for Ship
Generation, Conversion ,
Transformation and Distribution

Marine Electrical System
• Maritime electric systems include power generation, distribution and
control, and consumption of electric power on supply- service- and fishing
vessels as well as offshore installations.
• Electric propulsion has increased especially for vessels with several large
power consumers, for example cruise ships, floating production systems,
supply- and service vessels.
• Maritime electric systems are autonomous power systems. The prime
movers, including diesel engines, gas- and steam turbines, are integral parts
of the systems.
• The power consumers are large compared with the total capacity of the
system, as for example thruster and propulsion systems for DP operated
vessels, drilling systems, HVAC systems on board ship

Marine Electrical System
• The overall power train efficiency with DEP is around 87-
90%. Use of permanent magnets in electric generators and
motors as well as general advances in semiconductor
technology may improve this figure to around 92-95% in the
near future. Electrical transmission will consist of three basic
energy conversions:
• From (rotating) mechanical energy into electrical energy: E-
generator
• From electrical energy into (rotating) mechanical energy: E-
motor
• Some form of fixed or controlled electrical conversion in
between: power converter

Systematic overview of existing types
E-generator

• Mechanical ==> Electrical: E-Generators
• - DC Generators
• - AC Generators

E-Motors

• Electrical ==> Mechanical: E-motors
• - Driving motors
• - Synchronous Motor
• - Positioning motors

Power converters
Electrical ==> Electrical: power conversion or transformation
• - Fixed transformers
• - Controlled converters
• - Static converters
• -Inverter

Structure of a combined power plant
for ships

Electric Propulsion System (AES)
• Electric propulsion of ships has been know for a long time to human
• Dynamic changes in human discovery has given several up and down in
history
• Recent time have seen a a lot of Passenger ships being built with all
electric system for various advantage that over the conventional prime
movers
• Early large passenger vessels employed the turboelectric system which
involves the use of variable speed, and therefore variable frequency, turbo-
generator sets for the supply of electric power to the propulsion motors
directly coupled to the propeller shafts. Where, the generator/motor system
was acting as a speed reducing transmission system.
• Electric power for auxiliary ship services required the use of separate
constant frequency generator sets. System with generating sets to provide
power to both the propulsion system and ship ancillary services.
• However fixed voltage and frequency system are suitable to satisfy the
requirements of the ship service loads.

• Other complication associated with earlier systems is difficulties in using multiple
motor per shaft when required propulsion power was beyond the capacity of a single
d.c. motor .
• Developments in high power static converter equipment have – presented a very
convenient means of providing variable speed a.c. and d.c. drives at the largest
ratings likely to be required in a marine propulsion system.
• The electric propulsion of ships requires electric motors to drive the propellers and
generator sets to supply the electric power. It may seem rather illogical to use electric
generators, switchgear and motors between the prime-movers (e.g. diesel engines) and
propeller when a gearbox or length of shaft could be all that is required.
• In the light of the above, hybrid of gas turbine or Diesel with electric couple with dual
fuelling that include natural gas, is explorable option for existing vessels, all electric
ship using natural gas is also a good option.
• Currently there is interesting development for new ship need exploration on
technologies to improve integrated full electric propulsion with advanced power
management systems:
• Improved converter and power electronics technology
• Improved generators and motors

• The AES give widespread electrification of auxiliaries and the opportunity
to use upgradeable and flexible layouts. It will include a low risk, cost
effective and comprehensive Platform Management System that has a
standardized Human-Computer Interface supportable for its entire service
life and the goal to be an Environmentally Sound Ship.
• The fit into the goals of the Environmentally Sound Ship where : freedom
of operation in MARPOL special and restricted areas; unrestricted littoral
operations; port independence; minimum onboard storage of waste and
reduced manpower whilst reducing cost of ownership and port reception
costs.
• the also promise potential for replacing the current traditional systems used
in steering gear, fin stabilizers with compact, power-dense actuators.
• They also offer potentials for possible use of electric valve actuators that
will simplify system architectures systematic integration of upper deck to
machinery.

Power generation
• A 2001 study concluded that fitting a Navy cruiser with more energy-
efficient electrical equipment could reduce the ship’s fuel use by 10% to
25%.
• Ship fuel use could be reduced by shifting to advanced turbine designs such
as an intercooled recuperated (ICR) turbine. Shifting to integrated electric-
drive propulsion can reduce a ship’s fuel use by 10% to 25%.
• There is Potential alternative hydrocarbon fuels Like biodiesel and liquid
hydrocarbon fuels made from coal
• Recent time has seen firms offering kite-assist systems to commercial ship
operators.
• Solar power might offer some potential for augmenting other forms of
shipboard power.
• Talking about the question now the electric propulsion , especially with
hybrid system offer the best answer to problem of energy

Power generation
• Integrated electric-drive system derived from a commercially available system that
has been installed on ships such as cruise ships requires a technology that is more
torque-dense (i.e., more power-dense) .
• Candidates for a more torque-dense technology include a permanent magnet motor
(PMM) and a high-temperature superconducting (HTS) synchronous motor.
• In addition, electric drive makes possible the use of new propeller/stern
configurations, such as a podded propulsion ... that can reduce ship fuel
consumption further due to their improved hydrodynamic efficiency
• Podded drives offer greater propulsion efficiency and increased space within the
hull by moving the propulsion motor outside the ships hull and placing it in a pod
suspended underneath the hull.
• Podded drives are also capable of azimuth improving ship maneuverability. Indeed,
podded drives have been widely adopted by the cruise ship community for these
reasons.
• The motors being manufactured now are as large as 19.5 MW, and could provide
the total propulsion power.

Comparison of propulsion plants
efficiency

Prime movers
Gas Turbines
• Gas turbine have been selected as the future prime mover primarily because
of their high power to weight ratio.
• 4. Weight sensitive ship designs favor gas turbines and projected light
weight fuel cell power plants such as PEM.
• They also provide significant reduction in the amount of routine
maintenance required when compared with diesel generators.
• The other significant factor is the low emissions.

Diesel engine
• Diesel engines offer fuel costs savings of 50% if heavy fuels can be used,
and if emissions can be maintained at acceptable levels.
• Maintenance may include engine modifications such as dual fuel capability
for in-port use, water injection, and timing retard, and exhaust treatment
such as selected catalytic reduction and oxidation catalysts.
• Heavy fuel use also requires careful selection of cylinder material and lube
oil

Turbina
• A gas turbine, also called a combustion turbine, is a rotary engine that
extracts energy from a flow of hot gas produced by combustion of gas or
fuel oil in a stream of compressed air.
• It has an upstream air compressor radial or axial flow mechanically coupled
to a downstream turbine and a combustion chamber in between.
• Energy is released when compressed air is mixed with fuel and ignited in
the combustor.
• The resulting gases are directed over the turbine's blades, spinning the
turbine, and, mechanically, powering the compressor.
• Finally, the gases are passed through a nozzle, generating additional thrust
by accelerating the hot exhaust gases by expansion back to atmospheric
pressure.

• A steam turbine is a mechanical device that extracts thermal energy from
pressurized steam, and converts it into useful mechanical work.

COGAG
• Combined gas turbine and gas
turbine (COGAG) is propulsion
system for ships using two gas
turbines connected to a single
propeller shaft.
• A gearbox and clutches allow either
of the turbines to drive the shaft or
both of them combined.
• Using one or two gas turbines has the
advantage of having two different
power settings.
• Since the fuel efficiency of a gas
turbine is best near its maximum
power level, a small gas turbine
running at its full speed is more
efficient compared to a twice as
powerful turbine running at half
speed, allowing more economic
transit at cruise speeds.

Prime movers
Electric drive
• Electric drive transmissions have a higher specific fuel consumption, specific
weight and volume than mechanical drive systems, but has advantages in
arrangement which may compensate for these disadvantages.
• Advanced technology motors can be located very close to and on line with the
propulsors, at the extreme aft end of the ship, or in external pods.
• Electrical generator sets can be optimally spaced around the ship and electrically
connected. In the longer term, combined with fuel cells, SFC, specific weight and
volume are comparable with gas turbine and diesel prime movers for direct drive
systems.
Zone Concept :
• The concept of dividing future classes of ship into zones to maximize survivability
also extends to the power system.
• Each zone would be autonomous and include ventilation systems, cooling systems,
power distribution and other services which could be affected by damage to another
part of the ship.
• At least two supplies would be provided for all essential loads. Current classes,
using split generation and distribution, rely on the provision of normal and
alternative supplies via Automatic Change-Over Switches

Fuel cell
• The fuel cell stack operates by utilizing electrochemical reactions between an
oxidant (air) and a fuel (hydrogen), with two electrodes separated by a
membrane.
• The voltage of the fuel cell output can be controlled by a converter and it is
therefore able to connect to any point in the ship service or propulsion
distribution system.
• The fuel cell stack is modularity give redundancy advantage. It also has the
additional advantages of zero noxious emissions, and low thermal and acoustic
signatures.
• In the short term the fuel cell system is required to use marine diesel fuel.
Diesel fuel will require reforming within the fuel cell stack, or using an external
process, to produce a hydrogen rich gas which the fuel cell stack is capable of
processing.
• The reformer will clearly add both size, weight and complexity to the fuel cell
system. In the longer term technologies such as the Solid Oxide Fuel Cell
(SOFC) are contenders, which are more forgiving of impurities and can use a
fuel available world-wide, either methanol or gasoline.

Storage option
• The technologies being assessed for energy storage include are electro-
chemical batteries (both conventional and advanced), regenerative fuel
cells (otherwise known as redox flow cells ) Superconducting Magnetic
Energy Storage (SMES) and Supercapacitors.
• Regenerative fuel cells store or release electrical energy by means of a
reversible electrochemical reaction between two salt solutions (the
electrolytes). The reaction occurs within an electrochemical cell.
• The cell has two compartments, one for each electrolyte, physically
separated by an ion-exchange membrane.
• In contrast to most types of battery system, the electrolytes flow into and
out of the cells and are transformed electrochemically inside the cells. The
power is therefore determined by the size of the cell but the endurance is
determined by the size of the two electrolyte tanks

Prime movers
• All primemovers are potentially compliant with emerging emission
requirements, however, complexity for achieving compliance varies with
prime mover and fuel type.
• Diesels require the most attention to emissions control followed at some
distance by gas turbines, where ultra low emissions levels have been
achieved for land-based systems.
• Fuel cells emit the lowest levels of pollutants of all the primemovers
• Heavier fuel cell systems and diesels represent larger machinery and
structural weight.
• Fuel cells can be used as a prime mover in an Integrated Full Electric
Propulsion (IFEP) system providing DC electrical power output, and are
being developed as a replacement for diesel generators and gas turbine
alternators.

Propulsion motor
• For efficient operation of propulsion motor there is a
requirement for a compact, power dense, rugged
electrical machine to be utilized for the propulsion
motor.
• For the full benefits of electric propulsion to be
realized the machine should also be efficient,
particularly at part load,
• In order to achieve suitable compact designs rare
earth permanent magnet materials may be required.
• The machine topologies available for PMM are
deemed to be those based on radial, axial and
transverse flux designs.

Power for LNG ships
• These alternatives are more economical and offer greater overall efficiency
with an added advantage of providing greater flexibility and redundancy
• Diesel plant also raises are inherited with problem of vibration on
membrane
• LNG carrier it is necessary to understand the interaction between the
structural resonance that is excited by the diesel engine and the separate
resonance that is created within the membrane containment system
interacting with LNG.
• The traditional application of gas fired boilers for steam turbine propulsion
systems is no longer the only available option for LNG Carriers,”
• Direct drive, slow speed diesel plants, coupled with an on-board
liquefaction plant to handle the cargo boil off, or 4 stroke medium speed
diesel electric propulsion or gas turbine with diesel electric drive appear to
offer the greatest operational efficiencies for the new designs of large LNG
carriers.

Power generation for LNG ships
• Although slow or medium speed diesel engines have been selected for some of the
recent LNG carriers with dual fuel installation option that uses both gas boil-off and
ordinary bunkers.
• Variations of the dual fuel arrangements include:
-diesel engine or gas turbine driven generators with one propulsion shafting system and
a liquefaction plant;
-diesel engine or gas turbine driven generators with two propulsion shafting systems
and a liquefaction plant;
-diesel engine or gas turbine driven generators with two azimuth thrusters and a
liquefaction plant.
• To date, slow speed diesel with re-liquefaction plant as well as a gas combustion
unit, and medium speed dual fuel diesel with gas combustion units, are the
preferred options for the new large LNG carriers recently ordered in Korea.
• It would appear that gas turbine with simple and combined cycles using heat
recovery units to drive steam turbo alternators are another alternative being
explored. Industry is currently developing the fuel gas systems for these gas turbine
options.

Power generation for LNG ships
• A dual fuel diesel-electric system uses forced boil-off from the cargo tanks
as the primary fuel and marine diesel oil as back-up fuel. The arrangement
can also be adapted to current LNG carrier designs.
• Shipbuilders and engine designers that are proponents of dual fuel systems
point out that a gas-electric propulsion plant is more compact than the
traditional steam turbine plant used for LNG carriers, increasing cargo
capacity within the same dimensioned hull.
• The IMO Gas Carrier Code requires two means of utilizing boil-off gas on
all LNG carriers. Conventional systems use the main boilers for generating
steam for propulsion. When this cannot be used, excess steam is redirected
to the condensers. Similar arrangements are required for the diesel
propulsion systems. Current industry proposals for the alternative means of
boil-off gas utilization are a liquefaction plant or a gas combustion unit.
• Risk assessment methods are recommended for option selection

Power Distribution
• As the demand for electrical are 3.3 kV or 6.6 kV but 11 kV is
used on some offshore platforms and specialist oil/gas
production ships e.g on some FPSO (floating production,
storage and offloading) vessels.
• By generating electrical power at 6.6 kV instead of 440 V the
distribution and switching of power above about 6 MW
becomes more manageable.
• As for electrical Power increases on ships (particularly
passenger ferries, cruise liners, and specialist offshore vessels
and platforms) the supply current rating becomes too high at
440 V.
• To reduce the size of both steady state and fault current levels,
it is necessary to increase the system voltage at high power
ratings.

Component parts of an HV
• The component parts of an HV supply system are standard equipment with:
HV diesel generator sets feeding an HV main switchboard.
• Large power consumers such as thrusters, propulsion motors, air-
conditioning (A/C) compressors and HV transformers are fed directly from
the HV switchboard.
• An economical HV system must be simple to operate, reasonably priced
and require a minimum of maintenance over the life of the ship.
• Experience shows that a 9 MW system at 6.6 kV would be about 20% more
expensive for installation costs.
• The principal parts of a ships electrical system operated at HV would be the
main generators, HV switchboard, FV cables, HV transformers and HV
motors.
• An example of a high voltage power system is shown

HV Systems
• In the example shown the HV generators form a central power station for
all of the ship's electrical services.
• On a large passenger ship with electric propulsion, each generator may be
rated at about 10 MW or more and producing 6.6 kV, 60 Hz three-phase
a.c. voltages.
• The principal consumers are the two synchronous a.c. propulsion electric
motors (PEMs) which may each demand 12 MW or more in the full away
condition.
• Each PEM has two stator windings supplied separately from the main HV
switchboard via transformers and frequency converters.
• In an emergency a PEM may therefore be operated as a half-motor with a
reduced power output. A few large induction motors are supplied at 6.6 kV
from the main board with the circuit breaker acting as a direct-on-line
(DOL) starting switch.

Ship high voltage systems
These motors are:
o Two forward thrusters and one aft thruster, and
o Three air conditioning compressors

• Other main feeders supply the 440 V engine room sub-station (ER sub)
switchboard via step-down transformers.
• An interconnector cable links the ER sub to the emergency switchboard.
• Other 440 V sub-stations (accommodation,galley etc.) around the ship are
supplied from the ER sub.
• Some installations may feed the ships sub stations directly with HV and step-
down to 440 V locally.
• The PEM drives in this example are synchronous motors which require a
controlled low voltage excitation supply current to magnetise the rotor poles.
• This supply is obtained from the HV switchboard via a step-down
transformer but an alternative arrangement would be to obtain the excitation
supply from the 440 V ER sub switchboard.

High Voltages solid state AC-
DC-AC conversion

Solid State Switching Principle
• The power systems engineers is interested in high voltages primarily for
power transmission, and secondly for testing of his equipment used in
power transmission in laboratory
• High voltage can be obtained locally from power generating plant through
the use of solid state
• In many testing laboratories, the primary source of power is at low voltage
(400 V three phase or 230 V single phase, at 50 Hz). From which high
voltage can be obtained
• On board ship the same technology can be used to use high voltage
• Laboratory test are aimed to design the required high voltage
• Since insulation is usually being tested, the impedances involved are
extremely high (order of M ohm and the currents small (less than an
ampere).
• High voltage testing does not usually require high power.
• Thus special methods may be used which are not applicable when
generating high voltage in high power applications.

Solid State Switching Principle
• In the field of electrical eng. & applied physics, high voltages are required for
several applications As:
-a power supply (eg. hv dc) for the equipments such as electron microscope and
x-ray machine.
-Required for testing power apparatus – insulation testing.
-High impulse voltages are required for testing purposes to simulate over
voltages due to lightning and switching.
• Sometimes, high direct voltages are needed in insulation test on cables and
capacitors. Impulse generator charging units also require high dc voltages of
about 100-200kV.
• Normally for the generation of dc voltages of up to 100kV, electronics valve
rectifiers are used and the output currents are about 100mA. The rectifier
valves require special construction for cathode and filaments since a high
electrostatic field of several kV/cm exists between the anode and cathode in
the non-conduction period.
• The ac supply to the rectifier tubes maybe of power frequency or maybe of
audo frequency from an oscillator. The latter is used when a ripple of very
small magnitude is required without the use of costly filters to smoothen the
ripple.

Half and Full Wave Rectifier
• Rectifier circuits for producing high dc voltages from ac sources
maybe
a. Half-Wave
b. Full-Wave

o The rectifier can be an electron tube or a solid state devices.
Nowadays, single electron tubes are available for peak inverse
voltages up to 250kV and semiconductor or solid state diodes up
to 250kV.

o For higher voltages, several units are to be used in series. When
a number of units are used in series, transient voltage
distribution along each unit becomes non-uniform and special
care should be taken to make the distribution uniform.

RL
Vin V out

Half Wave Rectifier

V
p
V
AVG
0

T

Mean Load Voltage or Average Value of half wave output

D1

+

to t1 t2
RL

D2

-

Full wave Rectifier Circuit

figure 1.7 : Full-wave rectifier circuit
Vp
V AVG

to t1 t2

Mean Load Voltage or Average Voltage Full-wave output

Voltage Multiplier Circuits
• Both full-wave as well as half-wave circuits can
produce a maximum direct voltage corresponding to
the peak value of the alternating voltage.
• When higher voltages are required voltage multiplier
circuits are used. The common circuits are the voltage
double circuit
• Used for higher voltages.
• Generate very high dc voltage from single supply
transformer by extending the simple voltage doubler
circuit.

Types of high voltages;
• High d.c. voltages
• High a.c. voltages of power frequency
• High a.c. voltages of high frequency
• High transient or impulse voltages of very short
• duration - lightning overvoltages
• Transient voltages of longer duration – switching
• surges

• The voltage doubler circuit makes
use of the positive and the
negative half cycles to charge two
different capacitors. These are
then connected in series aiding to
obtain double the direct voltage
output. Figure shows a voltage
doubler circuit.

• In this case, the transformer will
be of small rating that for the
same direct voltage rating with
only simple rectification. Further
for the same direct voltage output
the peak inverse voltage of the
diodes will be halved. Voltage doubler circuit

High Alternating Voltages
• Required in laboratories and a.c. tests as well as for the
• circuit of high d.c. and impulse voltage.
• Test transformer are generally used.
• Single transformer test units are made for high alternating voltages
up to about 200 kV.
• However, for high voltages to reduce the cost (insulation cost
increases rapidly with voltage) and make transportation easier, a
cascade arrangement of several transformers is used.
• For higher voltage requirement, series connection or cascading of
the several identical units of transformer is applied.

Cascade arrangement of
transformers

1600 kV, 9.6 MVA Cascaded Power Transformer

Cascade arrangement of transformers
• A typical cascade arrangement of transformers used to obtain up
to 300 kV from three units each rated at 100 kV insulation. The
low voltage winding is connected to the primary of the first
transformer, and this is connected to the transformer tank which
is earthed.
• One end of the high voltage winding is also earthed through the
tank.
• The high voltage end and a tapping near this end is taken out at
the top of the transformer through a bushing, and forms the
primary of the second transformer.
• One end of this winding is connected to the tank of the second
transformer to maintain the tank at high voltage.
• The secondary of this transformer too has one end connected to
the tank and at the other end the next cascaded transformer is fed.

• This cascade arrangement can be continued further if a still
higher voltage is required.
• In the cascade arrangement shown, each transformer needs
only to be insulated for 100 kV, and hence the transformer can
be relatively small. If a 300 kV transformer had to be used
instead, the size would be massive. High voltage transformers
for testing purposes are designed purposely to have a poor
regulation.
• This is to ensure that when the secondary of the transformer is
short circuited (as will commonly happen in flash-over tests of
insulation), the current would not increase to too high a value
and to reduce the cost. In practice, an additional series
resistance (commonly a water resistance) is also used in such
cases to limit the current and prevent possible damage to the
transformer.


• What is shown in the cascade transformer arrangement is the basic principle
involved. The actual arrangement could be different for practical reasons.
• In the cascade arrangement shown, each transformer needs only to be insulated for
100 kV, and hence the transformer can be relatively small. If a 300 kV transformer
had to be used instead, the size would be massive. High voltage transformers for
testing purposes are designed purposely to have a poor regulation.
• This is to ensure that when the secondary of the transformer is short circuited (as
will commonly happen in flash-over tests of insulation), the current would not
increase to too high a value and to reduce the cost. In practice, an additional series
resistance (commonly a water resistance) is also used in such cases to limit the
current and prevent possible damage to the transformer.
• What is shown in the cascade transformer arrangement is the basic principle
involved. The actual arrangement could be different for practical reasons.

High D.C. Voltages

• Generation of high d.c. voltages is mainly
required in research work in the areas of pure
and applied physics.
• Needed in insulation test.
• Use rectifier circuit (diode) to convert a.c. to
d.c.
• voltage. – vacuum rectifiers, semiconductor
diodes

Impulse High Voltage
• Impulse voltages (IVs) are required in hv tests to simulate the
stresses due to external and internal overvoltages, and also for
fundamental investigations of the breakdown mechanisms.
• Usually generated by discharging hv capacitors through
switching gaps onto a network of resistors and capacitors.
• In hv technology, a single, unipolar voltage is termed an
impulse voltage.
• Rectangular and wedge-shaped IVs are normally used for basic
experiments while for testing purposes, double exponential IVs
are used.
• Standard test of impulse voltages can be represented as double
exponential wave, and its mathematical equation is defined as
follows;
V = Vo [exp(-αt) – exp(-βt)]
Where α and β are constants of microsecond values.

Controlled Rectification
• The generated three power supply on a phase a.c. electrical ship
has a fixed voltage and frequency. This is generally at M0 V and
60 Hz but for high power demands it is likelv to be 6.6 kV and
60 Hz.
• Speed control for a propulsion motor requires variable voltage
for a d.c. drive and variable frequency * voltage for an a.c. drive.
• The set bus-bar a.c. voltage must be converted by controlled
rectification (a.c.--d.c.) ind/or controlled inversion (d. c. * a. c. )'
to match the propulsion motor type.
• A basic rectifier uses semiconductor diodes which can only
conduct current in the direction of anode (A) to cathode (K) and
this is automatic when A is more positive than K.
• The diode turns-off automatically when its current falls to zero.
Hence, in –a single-phase a.c. circuit a single diode will conduct
only on every other half-cycle and this is called half-wave
rectification.

Single-phase controlled rectification.

Controlled Rectification
• In this circuit an inductor coil (choke) smooth the d.c. load current even
though the d.c. voltage is severely chopped by the thyristor switching action.
• An alternative to the choke coil is to use a capacitor across the rectifier output
which smooths the d.c. voltage. Full wave controlled rectification from a
three-phase a.c. supply is achieved in a bridge Circuit with six thyristors a
shown
• Other single-phase circuits using a biased arrangement with two diodes and a
centre-tapped transformer will create full-wave rectification Similarly, four
diodes in a bridge formation will also produce a full-wave d.c. voltage output.
• An equivalent three phase bridge requires six diodes for full-wave operation.
A diode, having only two terminals, cannot control the size of the d.c. output
from the rectifier.
• For controlled rectification it is necessary to use a set of three-terminal
devices such as thyristors (for high currents) or transistors (for low - medium
currents).

Three-phase controlled rectifier bridge circuit.

• A basic a.c.-d.c. control circuit using a thyristor switch is shown in the
next slide. Compared with a diode, a thyristor has an extra (control)
terminal called the gate (G).
• The thyristor will only conduct when the anode is positive with respect to
the cathode and a brief trigger voltage pulse is applied between gate and
cathode (gate must be more positive than cathode).
• Gate voltage pulses are provided by separate electronic circuit and the
pulse timing decides the switch-on point for the main (load) current. The
load current is therefore rectified to d.c. (by diode action) and controlled by
delayed switching.
• In this circuit an inductor coil (choke) smooth the d.c. load current even
though the d.c. voltage is severely chopped by the thyristor switching
action.
• An alternative to the choke coil is to use a capacitor across the rectifier
output which smooths the d.c. voltage. Full wave controlled rectification
from a three-phase a.c. supply is achieved in a bridge Circuit with six
thyristors a shown

• The equivalent maximum d.c. voltage output is taken to be about 600 V as
it has a six-pulse ripple effect due to the three-phase input waveform.
• Controlled inversion process - A d.c. voltage can be inverted (switched)
repeatedly from positive to negative to form an alternating (u.c.) voltage by
using a set of thyristor (or transistor) switches. A controlled three-phase
thyristor bridge inverter is shown
• The inverter bridge circuit arrangement is exactly the same as that for the
rectifier. Here, the d.c. voltage is sequentially switched onto the three
output lines. The rate of switching determines the output frequency.
• For a.c. motor control, the line currents are directed into (and out of) the
windings to produce a rotating stator flux wave which interacts with the
rotor to produce torque.
• The processes of controlled rectification and inversion are used in
converters that are designed to match the drive motor.

Three-phase inverter circuit and a.c. synchronous motor

Converter Types
The principal types of motor control converters are:
- >a.c.-d.c. (controlled rectifier for d.c. motors) . a.c.-d.c.-a.c. (PWM for
induction motors)
- >a.c.- d.c.-a.c. (synchroconverter or synchronous motors) .
-> d.c.-a.c. (cycloconverter for synchronous motors)

These are examined below:
a.c.- d.c. converter
• This is a three phase a.c. controlled rectification circuit for a d.c. motor
drive.
• Two converters of different power ratings are generally used for the
separate control of the armature current and the field current which
produces the magnetic flux .
• Some systems may have a fixed field current which means that the field
supply only requires an uncontrolled diode bridge

Converter Types
• Shaft rotation can be achieved by reversing either the field current or the
armature current direction.
• Ship applications for such a drive would include cable-laying, offshore
drilling, diving and supply, ocean survey and submarines.

a.c.- d.c.-a.c. PWM converter
• This type of converter is used for induction motor drives and uses
transistors as the switching devices.
• Unlike thyristors, a transistor can be turned on and off by a control signal
and at a high switching rate (e.g. at 20 kHz in a PWM converter).
• The input rectifier stage is not controlled so is simpler and cheaper but the
converter will not be ablg to allow power from the motor load to be
regenerated back into the mains supply during a braking operation.

Controlled rectification converter and d.c. motor

PWM converter and a.c. induction motor

Converter Types
• From a 440 Y a.c. supply, the rectified d.c. (link) voltage will
be smoothed by the capacitor to approximately 600 V.
• The d.c. voltage is chopped into variablewidth, but constant
level, voltage pulses in the computer controlled inverter
section using IGBTs (insulated gate bipolar transistors).
• This process is called pulse width modulation or PWM. By
varying the pulse widths and polarity of the d.c. voltage it is
possible to generate an averaged sinusoidal ac. output over a
wide range of frequencies typically 0.5-120Hz.
• Due to the smoothing effect of the motor inductance, the
motor currents appear to be nearly sinusoidal in shape.
• By sequentially directing the currents into the three stator
windings, a reversible rotating magnetic field is produced with
its speed set by the output frequency of the PWM converter.

Converter Types
• Accurate control of shaft torque, acceleration time and resistive braking are
a few of the many operational parameters that can be programmed into the
VSD,usually via a hand-held unit.

• The VSD can be closelv tuned to the connected motor drive to achieve
optimum control and protection limits for the overall drive.
•
• Speed regulation against load changes is very good and can be made very
precise by the addition of feedback from a shaft speed encoder.

• VSDs, being digitally controlled, can be easily networked to other
computer devices e.g. programmable logic controllers (PLCs) for overall
control of a complex process.

Converter Types
a.c.*d.c.+a.c. synchroconverter
• This type of convert is used for large a.c. synchronous motor
drives (called a synchrodrive) and I is applied very
successfully to marine electric propulsion.
• A synchroconverter has controlled rectifier and inverter stages
which both rely on natural turn-off (line commutation) for the
thyristors by the three phase a.c. voltages at either end of the
converter.
• Between the rectification and inversion stages is a current-
smoothing reactor coil forming the d.c. link.
• An operational similarity exists between a svnchrodrive and a
d.c. motor drive. DC link synchroconverter and a dc motor
drive.

Inverter current switching sequence

Converter Types
• This view considers the rectifier stage as a controlled d.c.
supply and the inverter/synchronous motor combination as a
d.c. motor. with the switching inverter acting as a static
commutator.
• The combination of controlled rectifier and d.c. link is
considered to be a current source for the inverter whose task is
then to sequentially direct blocks of the current into the motor
windings
• The size of the d.c. current is set by the controlled switching of
the rectifier thyristors.
• Motor supply frequency (and hence its speed) is set by the rate
of inverter switching.
• The six inverter thyristors provide six current pulses per cycle
(known as a six-pulse converter)

Converter Types
• A simplified understanding of synchroconverter control is that
the current source (controlled rectification stage) provides the
required motor torque and the inverter stage controls the
required speed.
• To provide the motor e.m.f. which is necessary for natural
commutation of the inverter thyristors, the synchronous motor
must have rotation and magnetic flux in its rotor poles.
• During normal running, the synchronous motor is operated
with a power factor of about 0.9 leading (by field excitation
control) to assist the line commutation of the inverter
thyristors.
• The d.c. rotor field excitation is obtained from a separate
controlled thvristor rectification circuit.

Converter Types
• As the supply (network) and machine bridges
are identical and are both connected to a three-
phase a.c. voltage source, there roles can be
switched into reverse.
• This is useful to allow the regeneration motor
power back into the mains power supply which
provides an electric braking torque during a
crash stop of the ship.

Cycloconverter circuit and output
voltage waveform.

Converter Types
a.c.- a.c. cycloconverter
• While a synchroconverter is able to provide an output
frequency range typically up to twice that of the mains input
(e.g. up to 120 Hz), a cycloconverter is restricted to a much
lower range.
• This is limited to less than one thtird of the supply frequency
(e.g. up to 20 Hz) which is due to the way in which this type of
converter produces the a.c. output voltage waveform.
• Ship ropulsion shaft speeds are typically in the range of 0-145
rev/min which can easily be achieved by the low frequency
output range of a cycloconverter to a multi-pole synchronous
motor.
• Power regeneration from the motor back into the main power
supply is available. A conventional three phase converter from
a.c. to d.c. can be controlled so that the average output voltage
can be increased and decreased from zero to maximum within a
half-cycle period of he sinusoidal a.c. input.

Converter Types
• By connecting two similar converters back-to-back in each line an a.c.
output frequency is obtained.
• The switching pattern for the thyristors varies over the frequency range
which requires a complex computer program for converter control.
• The corresponding current waveform shape (not shown) will be more
sinusoidal due to the smoothing effect of motor and line inductance.
• The output voltage has ripple content which gets as the output frequency it
is this feature that limits useful frequency.
• There is no connection between the three motor windings because the line
converters have to be isolated from each other to operate correctly to obtain
line commutation (natural) switching of the thvristors.
• The converters may be directly supplied from the HV line but it is more
usual to interpose step-down transformers. This reduces the motor voltage
and its required insulation level while also providing additional line
impedance to limit the size of prospective fault current and harmonic
voltage distortion at the main supply bus-bar.

Shuttle Tanker Electrical System Layout

Shuttle Tanker Electrical Line Diagram

Drill Ship Electrical System Layout

The future
• Propulsion of ships by help of standard diesel engines
usually gives a non-optimal utilization of the energy.
• Today an increased use of diesel electrical propulsion
of ships can be seen. New power electronics and
electrical machines will be developed for propulsion
and thrusters, as well as other application on board.
• Knowledge has to be developed about how such large
motor drives will influence the autonomous power
systems on-board.
• Even development of new integrated electrical
systems for replacement of hydraulic systems (top-
side as well as sub-sea) are becoming areas of need.

Typical system of all electrical ship
• Generator sets complete with prime movers and engine controls
• HV/LV Switchboards, distribution systems and group starter boards
• Propulsion and thruster motors complete with power electronic
variable speed drives
• Power conversion equipment
• Shaft braking
• Power factor correction and harmonic filters
• (as necessary)
• Power management
• Machinery control and surveillance
• Dynamic positioning and joystick control
• Machinery control room and bridge consoles
• Setting to work and commissioning
• Operator training

Future electrical ship
• Future HV ships systems at sea may require voltages up to
13.8 kV to minimize fault levels
• It is therefore essential that all Marine Engineering personnel
are trained in safe working practices for these voltages.
• The Electrical officers of the near future must be fully trained
to carry out maintenance and defect rectification on Medium
Voltage (MV) systems.
• This will mean a considerable increase in the electrical content
of all training.
• Training will also need to be given to non-technical personnel
to ensure everybody is aware of the dangers of these higher
voltages.

Marine Electrical Systems: An Overview

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