A
railway electrification system supplies
electrical energy to railway
locomotives and
multiple units so that they can operate
without having an on-board
prime mover. There are several
different electrification systems in use throughout the world.
Railway electrification has many advantages but requires heavy
capital expenditure for installation.
Characteristics of electric traction
The main advantage of electric traction is a higher
power-to-weight ratio than forms of
traction such as
diesel or
steam that generate power on board. Electricity
enables faster
acceleration and higher
tractive effort on steep grades. On locomotives equipped with
regenerative braking,
descending grades requires very little use of air brakes as the
locomotive's traction motors become generators sending current back
into the supply system and/or on-board resistors, which convert the
excess energy to heat.
Other advantages include the lack of exhaust fumes at point of use,
less noise and lower maintenance requirements of the traction
units. Given sufficient traffic density electric trains produce
fewer carbon emissions than diesel trains, especially in countries
such as Austria and France where electricity comes primarily from
non-fossil sources.
A fully electrified railway has no need to switch between methods
of traction thereby making operations more efficient. One country
that approaches this ideal is Switzerland.
The main disadvantage is the capital cost of the electrification
equipment, most significantly for long distance lines that do not
generate heavy traffic. Suburban railways with closely-spaced
stations and high traffic density are the most likely to be
electrified, and main lines carrying heavy and frequent traffic are
also electrified in many countries.
Classification
[[Image:Europe rail electrification.png|thumb|Electrification
systems in Europe:
High speed lines in France, Spain, Italy and Belgium are
25 kV.]]
Electrification systems are classified by three main
parameters:
Direct current
Early electric systems used low-voltage
DC.
Electric
motors were fed directly from the traction supply, and were
controlled using a combination of
resistors
and
relays that connected the motors in
parallel or
series.
The most common DC voltages are 600 V and 750 V for
trams and
metro,
and 1,500 V, 650/750 V third rail for UK
Southern Region railways
and 3,000 V overhead for railways. The lower voltages are often
used with third or fourth rail systems, and voltages above 1,000 V
are normally limited to overhead wiring for safety reasons.
Suburb trains in Hamburg, Germany, have third
rail with 1,200 V, the French SNCF Culoz-Modane mainline
electrification in the Alps used 1,500 V and a third rail until
1976, when a catenary was installed, and the third rail was
disposed of. In the UK, South of London uses 750 V third rail while
inner London uses 650 V to allow inter-running with London
Underground which uses 650 V 4-rail but with the 4th (center) rail
connected to the running rails in inter-running areas.
During the mid 20th century,
rotary
converters or
mercury arc
rectifiers were used to convert utility (mains) AC power to the
required DC voltage at the feeder stations. Today, this is usually
done by
semiconductor rectifiers after transforming the voltage down
from the utility supply.
The DC system is quite simple, but it requires thick cables and
short distances between feeder stations because of the heavy
currents required. There are also significant
resistive losses. In the United Kingdom, the
maximum current that can be drawn by a train is 6,800 A at
750 V. The feeder stations require constant monitoring, and on
many systems, only one train or locomotive is allowed per section.
The distance between two feeder stations at 750 V third rail
is about 2.5 km (1.5 miles). The distance between two feeder
stations at 3,000 V is about 25 km (15 miles).
If auxiliary machinery, such as
fans
and
compressors, is powered by motors
fed directly from the traction supply they may be larger because of
the extra insulation required for the relatively high operating
voltage. Alternatively, they can be powered from a motor-generator
set, which was provided as an alternative way of powering
incandescent lights which otherwise had to be connected as series
strings (bulbs designed to operate at traction voltages being
particularly inefficient). Now solid-state converters (SIVs) and
fluorescent lights can be used.
Voltage
The permissible range of voltages allowed is as stated in standards
BS EN 50163 and IEC 60850. These take into account
the number of trains drawing current and their distance from the
substation.
| Electrification system |
Lowest non-permanent voltage |
Lowest permanent voltage |
Nominal voltage |
Highest permanent voltage |
Highest non-permanent voltage |
| 600 V DC |
400 V |
400 V |
600 V |
720 V |
800 V |
| 750 V DC |
500 V |
500 V |
750 V |
900 V |
1,000 V |
| 1,500 V DC |
1,000 V |
1,000 V |
1,500 V |
1,800 V |
1,950 V |
| 3,000 V DC |
2,000 V |
2,000 V |
3,000 V |
3,600 V |
3,900 V |
| 15,000 V AC,
16⅔ Hz |
11,000 V |
12,000 V |
15,000 V |
17,250 V |
18,000 V |
| 25,000 V AC, 50 Hz |
17,500 V |
19,000 V |
25,000 V |
27,500 V |
29,000 V |
|
Overhead systems
1 500 V DC
is used in the Netherlands, Japan, Ireland
, Australia (parts), India, France, New Zealand
(Wellington
) and the United States (Chicago area on the
Metra Electric district and the
South Shore Line interurban line). In Slovakia,
there are two narrow-gauge lines in the High Tatras (one a cog
railway). In Portugal, it is used in the
Cascais Line, and in Denmark on the suburban
S-train system.
In the United Kingdom, 1,500 V DC was used in 1954 for the
Woodhead
trans-Pennine route (now closed); the system used
regenerative braking, allowing for
transfer of energy between climbing and descending trains on the
steep approaches to the tunnel.
The system was also used for suburban
electrification in East
London and Manchester
, now converted to 25 kV AC.
In India, a 25 kV AC single-phase overhead system is commonly used.
With the help of
pantograph the
current is taken from these overhead lines.
3,000 V DC
is used in Belgium, Italy, Spain, Poland, the northern Czech
Republic, Slovakia
, Slovenia
, western
Croatia
, South Africa and former Soviet Union
countries. It was also formerly used by the
Milwaukee Road's extensive
electrification across the Continental Divide, and by the
Delaware, Lackawanna
& Western Railroad (now
NJ
Transit, converted to 25 kV AC) in the United
States.
Third rail
Arcs like this are normal and occur
when the collection shoes of a train drawing power reach the end of
a section of power rail.
Most electrification systems use overhead wires, but third rail is
an option up to about 1,200 V. While use of a third rail does not
require the use of DC, in practice all third-rail systems use DC
because it can carry 41% more power than an AC system operating at
the same peak voltage. Third rail is more compact than overhead
wires and can be used in smaller-diameter tunnels, an important
factor for subway systems.
Third rail systems can be designed to use top contact, side
contact, or bottom contact. Top contact is less safe, as the live
rail is exposed to people treading on the rail unless an insulating
hood is provided. Side- and bottom-contact third rail can easily
have safety shields incorporated, carried by the rail itself.
Uncovered top-contact third rails are vulnerable to disruption
caused by ice, snow, and fallen leaves.
DC systems are limited to relatively low voltages, and this can
limit the size and speed of trains and the amount of
air-conditioning the trains can provide. This may be a factor
favoring overhead wires and high voltage AC, even for urban usage.
In practice the top speed of trains on third-rail systems is
limited to 100 mph (160 km/h) because above that speed
reliable contact between the shoe and the rail cannot be
maintained.
Some road operating
trams (streetcars) used
conduit third-rail current collection. The third rail was below
street level. The tram picked up the current through a
plough accessed through a narrow
slot in the road. In the United States, the former trolley system
in Washington, D.C. was operated in this manner to avoid the
unsightly wires and poles associated with electric traction.
The
evidence of this mode of running can still be seen on the track
down the slope on the northern access to the abandoned Kingsway Tramway
Subway
(in central London, United Kingdom). The
slot between the running rails is clearly visible. The slot can
easily be confused with the similar looking slot for cable trams
(indeed, in some cases, the conduit slot was originally a cable
slot).
Fourth rail
The
London Underground in the
United Kingdom is one of the few networks that uses a four-rail
system. The additional rail carries the electrical return that on
third rail and overhead networks is provided by the running rails.
On the London Underground a top-contact third rail is beside the
track, energized at +420 V DC, and a top-contact fourth
rail is located centrally between the running rails at
-210 V DC, which combine to provide a traction voltage of
630 V DC.
The same system was used for Milan
's oldest
underground line (Milan Metro line 1) in
Italy; the more recent lines use an overhead catenary.
This scheme was introduced because of the problems of return
currents, intended to be carried by the earthed running rails,
flowing through the iron tunnel linings instead. This can cause
electrolytic damage and even arcing if the tunnel segments are not
electrically bonded together. The problem was exacerbated because
the return current also had a tendency to flow through nearby iron
pipes forming the water and gas mains. Some of these, particularly
Victorian mains that predated London's underground railways, were
never constructed to carry currents and had no adequate electrical
bonding between pipe segments. The four-rail system solves the
problem. Although the supply has one side linked to earth for
safety reasons, the connection is through resistors which ensure
that stray earth currents are kept to manageable levels.
London's sub-surface underground railways also operate on the
four-rail scheme, since in a number of areas (for example the
Piccadilly Line and Metropolitan Line services to Uxbridge)
sub-surface and deep-level stock run on the same tracks.
On lines shared with
National Rail
third-rail stock, the centre 'negative' rail is connected to the
return running rail, allowing both types of train to operate.
A system proposed (but not used) by the
South Eastern and Chatham
Railway around 1920 was 1,500 V DC four-rail. Technical details
are scarce, but it is likely that it would have been a "mid-earth"
system with one conductor rail at +750 volts and the other at -750
volts. This would have facilitated conversion to 750 V DC
three-rail at a later date.
A few lines of the Paris Metro in France also operate on a
four-rail power scheme, but for a very different reason. It is not
strictly a four-rail scheme as they run on rubber tyres running on
a pair of narrow roadways made of steel, and in some places,
concrete. Since the tyres do not conduct the return current, two
conductor rails are provided outside of the running 'roadways', so
at least electrically it fits as a four-rail scheme. The trains are
designed to operate from either polarity of supply, because some
lines use reversing loops at one end, causing the train to be
reversed during every complete journey (intended to save having to
run the locomotive round).
Alternating current
These are
overhead electrification
systems.
Low-frequency alternating current
15 kV 16+2/3 Hz AC traction
current used in Switzerland.
Common
commutating electric
motors can also be fed AC (
universal motor), because
reversing current in both
stator and
rotor does not change the direction of
torque. However,
inductance of the windings makes large motors
impractical at standard AC distribution frequencies. Five European
countries, including Germany, Austria, Switzerland, Norway and
Sweden have standardized on 15 kV 16⅔ Hz (one-third the
normal mains frequency) single-phase AC.
In the United States
(with its 60 Hz distribution system), 25 Hz (an older,
now-obsolete standard mains frequency) is used at 11 kV
between Washington,
DC
and New York City and between Harrisburg,
Pennsylvania
and Philadelphia
. A 12.5 kV 25 Hz section between New
York City and New Haven, Connecticut
was converted to 60 Hz in the last third of
the 20th century.
In the UK, the
London, Brighton and
South Coast Railway pioneered overhead electrification of its
suburban lines in London.
London Bridge
to Victoria
being opened to traffic on December 1, 1909.
Victoria
to Crystal
Palace
via Balham and West Norwood opened in May
1911. Peckham Rye
to West Norwood
opened in June 1912. Further extensions were
not made owing to the First World War.
Two lines opened in
1925 under the Southern
Railway serving Coulsdon North
and Sutton railway station
. It was announced in 1926 that all lines
were to be converted to third rail electric and the last overhead
electric service ran in September 1929. The lines were electrified
at 6.7 kV 25 Hz.
In such a system, the traction motors can be fed through a
transformer with multiple taps. Changing the
taps allows the motor voltage to be changed without requiring
power-wasting
resistors. Auxiliary
machinery is driven by low voltage commutating motors, powered from
a separate winding of the main transformer, and are reasonably
small.
The unusual frequency requires that electricity be
converted from utility power by
motor-generators or
static inverters at the feeding substations,
or generated at altogether separate
traction powerstations.
Since 1979 the three-phase
induction
motor has become almost universally used. It is fed by a static
four quadrant converter which supplies a constant voltage current
to a pulse width modulator inverter that supplies the three-phase
variable frequency to the motors. This system has made the
low-frequency systems advantageous again, because of its inherent
recuperation capability, something precluded by the phase-breaks in
the industrial frequency systems.
Polyphase alternating current systems
The Italian State railway system was 3,300 V at 15-16.7 Hz.
With such a low frequency the locomotives did not need gearing. It
is also possible to use the
polyphase
system regeneratively, as on the Italian State railway's
mountain lines, where a loaded train descending could supply much
of the power for a train ascending.
In the
United States, the Great
Northern Railway's (Cascade Tunnel
) first electrified line (1909-1927) was at
6,600 V, 25 Hz.
The main complexity with
three-phase systems is the need
for two conductors. Italian State Railways used a wide
bow collector which covered both wires. In the
United States, a pair of
trolley poles
were used. They worked well with a maximum speed limit of
15 mph.
A dual conductor pantograph system is used on four mountain
railways that continue to use three phase power (Corcovado Rack Railway in Rio de
Janeiro, Brazil
, Jungfraubahn and
Gornergratbahn
in Switzerland, and the Petit train de la Rhune in
France).
Standard frequency alternating current
Only in the 1950s after development in France did the standard
frequency single-phase alternating current system become
widespread, despite the simplification of a distribution system
which could use the existing power supply network.
The first attempts to use standard-frequency single-phase AC were
made in Hungary in the 1930s, by the Hungarian
Kálmán Kandó on the line between
Budapest-Nyugati and Alag, using 16 kV at 50 Hz. The
locomotives carried a four-pole rotating phase converter feeding a
single traction motor of the polyphase induction type at 600 to
1,100 V. The number of poles on the 2,500 hp motor could
be changed using slip rings to run at one of four synchronous
speeds.
Today, some
locomotives in this system
use a
transformer and
rectifier that provide low-voltage
pulsating DC current to motors. Speed is controlled by
switching winding taps on the transformer. More sophisticated
locomotives use
thyristor or
IGBT transistor circuitry to generate
chopped or even variable-frequency
AC that is then directly consumed by AC
traction motors.
This system is quite economical, but it has its drawbacks: the
phases of the external power system are loaded unequally, and there
is significant
electromagnetic interference
generated, not to mention acoustic noise.
A list of the countries using the
25 kV
AC 50 Hz single-phase system can be found in the
list
of current systems for electric rail traction.
The United States commonly uses 12.5 and 25 kV at 25 Hz
or 60 Hz. 25 kV AC is the preferred system for new
high-speed and long distance railways, even if the railway uses a
different system for existing trains.
To prevent the risk of out-of-phase supplies mixing, sections of
line fed from different feeder station must be kept strictly
isolated. This is achieved by
Neutral Sections (also known
as
Phase Breaks), usually provided at feeder stations and
midway between them, although typically only half are in use at any
time, the others being provided to allow a feeder station to be
shut down and power provided from adjacent feeder stations. Neutral
Sections usually consist of an earthed section of wire which is
separated from the live wires on either side by insulating
material, typically ceramic beads, designed so that the
pantograph will smoothly run from one
section to the other. The earthed section prevents an arc being
drawn from one live section to the other, as the voltage difference
may be higher than the normal system voltage if the live sections
are on different phases, and the protective circuit breakers may
not be able to safety interrupt the considerable current that would
flow. To prevent the risk of an arc being drawn across from one
section of wire to earth, when passing through the neutral section
the train must be coasting and the circuit breakers must be open.
In many cases, this is done manually by the driver. To help them, a
warning board is provided just before both the neutral section and
an advanced warning some distance before. A further board is then
provided after the neutral section to tell the driver they can
reclose the circuit breaker, although the driver must not do this
until the rear pantograph has passed this board. In the UK, a
system known as Automatic Power Control (APC) automatically opens
and closes the circuit breaker, this being achieved by using sets
of permanent magnets alongside the track communicating with a
detector on the train. The only action needed by the driver is to
shut off power and coast, and therefore warning boards are still
provided at and on the approach to neutral sections.
On French
LGV lines, the UK High
Speed 1 Channel Tunnel rail link and in the Channel
Tunnel
itself, neutral sections are negotiated
automatically.
World electrification
Railway electrification in Europe by
country.
In 2006 25% (240,000 km) of the world rail network was
electrified and 50% of all rail transport was carried by electric
traction (both by
locomotives
and
multiple units) and about 36% of
electric system is 25 KV AC.
Electrification advantages
Electrification of railways, like every other phenomenon, has some
positive and negative results. Some advantages of electrification
are: less weight and space for the same power (thus less locomotive
need in big passenger trains), less maintenance (more availability
and less cost in locomotive purchasing), less power loss at
altitude and in warm weather. Electrification allows more powerful
locomotives to be used than on non-electrified tracks. The rule of
thumb is that the power range of diesel locomotives begins at the
power of the strongest steam engines, while the power range of
electric locomotives begins at the high end of diesel locomotives.
The strongest locomotives of the world are all electric. More power
means higher top speeds and higher tractive effort.
Electrification disadvantages
.jpg/300px-Tragschnabelwagen_mit_Transformator_(8789).jpg)
Snabel car with an electrical
transformer near Koblenz
One of the restrictions of electrification is the clearance for
large size commodities like
double stack
container and big
transformers.
Fuel saving
US gasoline prices, 1919-2007 (real
and inflation adjusted)
One of the advantages of electrification is
fuel saving, because of the cheaper method of
electricity generation in
power plants that uses either
coal or some other sort of energy like gas,
heavy fuel with max.
efficiency of 55% and
Cogeneration (
CHP) with about 90% eff. and ...
also the
Bioenergy,
Waste management,
hydro electric and
nuclear energy.
[61042][61043][61044]
According to the world energy statistics the reserve of liquid fuel
is much less than gas and coal (15, 60 & 150 years
respectively) so it is vital to increase the railway share in
transport and to go for electrification because of source of useful
energy in different modes.We can consider electrification as one of
the important means to
consumption pattern reform
[61045] [61046].
External cost
The
external cost of railway is lower
than other modes of transport but the electrification brings down
it even more, if it is
sustainable.
This is specially due to railway safety relative to
road traffic safety, considering the
value of life. Also energy from
well to wheel, and the necessity to
reduce pollutions and greenhouse gas in earth according to the
Kyoto Protocol.
To have better interaction with society, using the help of
Think tank organizations (
NGO)
is vital.
Modes interaction
Electrification means higher speed for passengers and thus needs
the railway to have better connection to other modes of transport
like
metro,
light rail transit(LRT),
monorail,
Bus rapid
transit(BRT),
airport and
Airplane for
Flight.
Research and development
Another result of electrification is the affect on locomotive and
wagon productivity and it is going to be more effective by more
railway research in this field.The
trend of technology in railway electrification is very important to
adopt the efforts for better results, for example the trend from
GTO (
Gate turn-off
thyristor) to IGBT (
Insulated-gate bipolar
transistor) for more powerful locomotive with higher
reliability is one of the elements of
Technology roadmap (TRM) and the loop to
have a mature system as in
Maturity Road Mapping with the
Technology transfer provision.It
is necessary to predict future by the skills of
Futurology and to prepare the suitable conditions
for Technomart
[61047] .
Railway Electrification Statistics
It is an important stage to use the traffic data according to
railway statistics like in
Rail usage statistics by
country and
railway trend in
Iran.and
UIC in
2007 and (
List
of countries by GDP per capita).
| Rank |
Country |
area |
pop |
Av GDP |
Rail co |
Net km |
Dbl km |
El km |
HSR km |
Loco. No. |
pkm |
tkm |
HS. PKm |
train weight |
Pass. % |
Frt. % |
Pass/ pop % |
P. fare |
F. tariff |
Elec % |
income % |
| 17 |
|
17098 |
142 |
16 |
RZD |
84 |
36 |
42 |
0.6 |
|
173 |
2090 |
|
2528 |
42 |
67 |
9.1 |
4 |
2 |
80 |
107 |
| 2 |
|
357 |
82 |
35 |
DB |
34 |
18 |
20 |
1.2 |
|
74 |
91 |
22 |
410 |
10 |
17 |
22.4 |
11 |
3 |
60 |
109 |
| 3 |
|
552 |
82 |
34 |
SNCF |
29 |
16 |
14 |
1.8 |
|
81 |
40 |
48 |
496 |
|
|
16.8 |
12 |
4 |
|
105 |
| 4 |
|
380 |
127 |
34 |
JR |
20 |
8 |
12 |
2.5 |
|
253 |
23 |
79 |
368 |
29 |
|
69.6 |
|
|
100 |
124 |
| 5 |
|
100 |
48 |
28 |
KNR |
3 |
1 |
2 |
0.32 |
|
32 |
11 |
10 |
472 |
|
|
20.4 |
|
|
20 |
106 |
| 6 |
|
0.24 |
61 |
37 |
NR |
16 |
|
5 |
0.3 |
|
48 |
21 |
|
|
|
|
|
|
|
|
|
| 7 |
|
0.36 |
23 |
31 |
TRA |
1 |
0.67 |
0.69 |
0.33 |
|
9 |
1 |
|
|
|
|
|
|
|
|
77 |
| 8 |
|
0.51 |
45 |
31 |
Renfe |
15 |
5 |
9 |
1.27 |
|
21 |
11 |
4 |
|
|
|
|
|
|
|
105 |
| 9 |
|
0.3 |
59 |
31 |
FS |
16 |
7 |
12 |
0.82 |
|
45 |
21 |
9 |
|
|
|
|
|
|
|
96 |
| 10 |
|
0.78 |
74 |
13 |
TCDD |
9 |
04 |
1.9 |
0.25 |
|
6 |
10 |
|
572 |
|
|
|
|
|
24 |
69 |
| 11 |
|
0.04 |
8 |
43 |
SBB |
4 |
2 |
3 |
|
|
15 |
13 |
|
442 |
|
|
40.9 |
|
|
|
103 |
| 12 |
|
1.6 |
71 |
11 |
RAI |
7 |
1 |
0.15 |
0.25 |
|
13 |
21 |
|
1088 |
4 |
7 |
|
0.4 |
2 |
1 |
62 |
| 13 |
|
9.6 |
302 |
47 |
|
227 |
|
|
|
|
|
2820 |
|
5254 |
|
42 |
|
34 |
2 |
1 |
128 |
| 14 |
|
1 |
73 |
6 |
ENR |
5 |
1.5 |
0.07 |
|
|
41 |
4 |
|
|
|
|
6.1 |
|
|
|
80 |
| 15 |
|
3287 |
1132 |
3 |
IR |
63 |
17.4 |
17.8 |
|
|
696 |
481 |
|
1614 |
|
|
5.5 |
2 |
8 |
|
|
| 16 |
|
9561 |
1318 |
6 |
CR |
64 |
25.8 |
24.0 |
|
|
690 |
2211 |
|
2300 |
|
|
0.98 |
4 |
2 |
49 |
|
| 1 |
World |
150 |
6400 |
10 |
UN |
900 |
250 |
240 |
9 |
|
2468 |
9486 |
178 |
1677 |
10 |
20 |
|
|
|
50 |
|
| 18 |
|
313 |
38 |
17 |
PKP |
19 |
9 |
12 |
|
|
|
|
|
|
|
|
|
|
|
|
|
| 19 |
|
1221 |
48 |
10 |
SAR |
24 |
2 |
8 |
|
3421 |
14 |
109 |
|
2700 |
|
|
11 |
|
|
|
|
| 20 |
|
2725 |
16 |
11 |
KTZ |
14 |
5 |
4 |
|
1727 |
14 |
191 |
|
|
|
|
|
|
|
|
|
| 21 |
|
8547 |
189 |
10 |
|
29 |
|
0.5 |
|
2394 |
|
232 |
|
|
|
|
|
|
|
|
|
| 22 |
|
796 |
169 |
3 |
PR |
7 |
|
0.3 |
|
544 |
26 |
6 |
|
|
|
|
|
|
|
|
|
| 23 |
|
|
|
40 |
OBB |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
| 24 |
|
447 |
32 |
4 |
ONCFM |
2 |
0.6 |
1 |
|
|
4 |
6 |
|
915 |
|
|
0.8 |
|
|
89 |
|
| 25 |
|
|
|
|
UN |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
See also
References
- Technical specification for interoperability relating to the
energy subsystem of the trans-European high-speed rail system
- Southern Electric
- History of Southern Electrification Part 1
- History of Southern Electrification Part 2
- [1]
Sources
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