3.1 STANDARDISATION IN 1947
The Electricity Act,
1947, in setting up the Central Electricity Generating Board (and its Scottish
equivalents) as well as the various Area Electricity Boards, continued the
process of standardisations of voltages and frequency started in 1926.
The centralising of
generation and the interconnection of power stations clearly required the
standardising of frequency throughout the United Kingdom, and this was set at
50Hz. In order that manufacturers could
standardise on equipment, local distribution voltage was set at 415V, 3-phase,
4-wire, giving 240V single-phase line-to-neutral.
3.2 VOLTAGES
3.2.1 The National
Grid and Supergrids
The National Grid
originally interconnected all the CEB power stations and transmitted power at
132kV. Later a ‘supergrid’ at 275kV was
superimposed on the National Grid, and more recently still 400kV transmission
with nationwide cover has come into use.
These supergrids in effect interconnect on a national level the 132kV
systems which are relatively local to their generating stations.
The 400kV system is
now the main trunk route for the transportation of bulk power. The 400kV, 275kV
and 132kV networks can be likened respectively to motorways, dual carriage-ways
and A-roads.
Figure 3.1 shows the
400kV (red) and the 275kV (blue) ‘supergrid’ networks as at present installed
in England, Wales and Scotland. Many of the 275kV lines, when originally
planned, were built with a view to possible conversion to a higher voltage
later. When the 400kV grid system was
inaugurated, the majority of the longer 275kV lines were re-insulated for 400kV
and are now operated at that voltage.
Those 275kV lines that remained were comparatively local to the main
centres of population, except for Scotland where no 400kV is used, except a
small amount in the Glasgow area. This
can be seen in Figure 3.1.
It should be noted
that none of these networks is a simple ‘radial’ system emanating from a single
power source, but each forms an interconnected system between several sources
of power. Moreover the links between the
400kV and 275kV systems are made at several different points through 400/275kV
auto-transformers.
Initially the 132kV
power transmitted by the national grid to all the Area Board regions was
transformed on receipt to 33kV or 11kV for distribution by each Area
Board. This arrangement is now (1985)
being modified. Most of the 132kV
systems are being turned over to the various Area Boards, where they then
become ‘distribution’ rather than ‘transmission’. The new system is shown typically in Figure
3.2. The CEGB operates the 400kV and
275kV systems and only retains a 132kV unit if it includes a generating
station. The transfer process is
continuing. The actual grid transformers
(400/132kV and 275/132kV) and the associated high-voltage switchgear at the
boundary between the CEGB and Board Areas remain the property of the CEGB.
On the Continent 700kV transmission has
been introduced because of the long distances involved, and even 1 000kV
is being considered, although the technical problems in using such voltage
levels are immense.
FIGURE
3.1
PRINCIPAL 400kV AND 275kV SYSTEMS AND CROSS CHANNEL LINK
3.2.2 The Cross-Channel DC Link
The UK network of the
CEGB is interconnected with the Continental network of Electricité de France
(EdF) by a cross-channel direct-current link, indicated in yellow in Figure
3.1. The period of peak loading in the
UK differs from that in France by about one hour, so that each country’s system
can support the other during such peak periods by a two-way interchange of
power. The link is also a very valuable
back-up in the event of either side having system faults which leave either one
short of generating capacity.
The link is operated
by direct current for the following main reasons:
(a) Smaller
and fewer cables are needed as compared with a.c. for a given transfer of power.
(b) Direct
current gives better control of power flow by reason of the thyristors.
(c) It
would be very difficult (though not impossible) to synchronise two such vast
systems as the UK and French networks.
(d) By
the use of a d.c. link without synchronism each country retains its freedom to
operate its own network by frequency control.
(e) A
fault on one side would not be fed by the other. Large faults are mainly reactive, and the
d.c. link cannot pass reactive power.
(f) A
long a.c. cable has considerable capacitance.
This would cause a large voltage rise and severe switching problems (see
Chapter 4). It would also give rise to
capacitive currents which could thermally overload the cable and thereby limit
the useful energy arriving at the far end.
The first undersea
cables were laid in 1961 between Lydd in Kent and Echinghen on the French
side. The system operated with two
cables at 200kV d.c. and transferred 160MW of power. At each end were
‘Converter Stations’ which used grid-controlled mercury arc rectifiers. They rectified the a.c. when transmitting
d.c. power and acted as inverters when receiving d.c. power and converting it
to a.c. I n time the cables, which were laid on the seabed, became increasingly
damaged by trawls and ships’ anchors, and they were difficult to repair in
mid-Channel. They were finally abandoned
in 1982.
A new and much larger
system was started in 1982, further to the east of the old one, between
Sellindge in Kent and Les Mandarins near Calais. It transfers 2 000MW of power at 540kV
d.c., using four parallel pairs of cables at +270kV and -270kV. Each cable is
45km long, and they are spaced 1 km between each pair. They are buried in pairs in four deep seabed
trenches to prevent damage and to avoid magnetic disturbance to ships’
compasses. The converter stations at
Sellindge and Les Mandarins use solid-state thyristors for rectifying and
inverting. They employ filter equipment
to reduce the harmonics caused by the rectifiers and inverters. This, together with the transformers and
switchgear, covers some 34 acres at each end.
The d.c. link is
connected at Sellindge into the 400kV supergrid transmission line from
Dungeness to Canterbury.
The cost of the whole 2 000MW project was only half that of a new power station
of the same output, and the UK paid only half of that cost. Moreover the project has brought benefits to
both countries.
FIGURE 3.2
TYPICAL GENERATION, TRANSMISSION AND
DISTRIBUTION
3.2.2 Choice of
Voltage
The choice of
transmission voltage depends mainly on the length of the line. The passing of currents along a line gives
rise to I2R power losses,
and the higher the voltage (and hence the lower the current for a given power)
the smaller the losses. This saving on
losses has to be set against the extra cost of very high voltage lines,
transformers and switchgear, and therefore a compromise has to be reached. A useful ‘rule of thumb’ for choice of
transmission voltage is 1.2kV per mile, or 0.75kV per kilometre.
The voltage of actual
generation can be chosen as desired, since it is not used outside the power
station. It was originally between 11kV
and 22kV but is now more usually at 25kV.
The generated voltage is immediately transformed at the station up to
the transmission voltage (132kV, 275kV or 400kV). Often the generator and step-up transformer
form a single electrical unit without any switchgear between them, the
transformer LV terminals being connected direct to the generator terminals, the
so-called ‘unit construction’. They
stand or fall together.
In the UK domestic and
small power users’ voltage has been set at 415/240V, and this is used in all
onshore oil installations. On the
Continent, however, 380/220V is not uncommon, still at 50Hz. In North and South
America 440V, 3-phase at 60Hz is standard, but for lighting and small power the
440V is transformed to 117V single-phase instead of using the phase-to-neutral
single-phase voltage of 254V as used elsewhere.
Most offshore
platforms have followed the American practice of using 440V, 60Hz, 3-phase for
distribution, but, instead of transforming to 117V for lighting and small
power, a 4-wire system is used to give 254V single-phase line-to-neutral.
3.3 CONTROL OF FREQUENCY AND VOLTAGE
It is the statutory
duty of the CEGB to hold their frequency to 50Hz within specified limits (±1%),
and their system of Regional Control Centres organises this. Whenever the loading on the whole national
network exceeds the total power being put into it by all generating stations,
the national frequency will slowly begin to fall. This is detected at power stations by
observing the loss of actual cycles compared with a standard. The National Control Centre orders selected
running stations to take on more load, or it starts up additional stations,
until a balance is achieved, the loss of frequency arrested and lost cycles
recovered. It should be noted that Area
Boards have no control over the frequency of the power which they deliver.
Similarly, CEGB
Regional Control Centres monitor the voltage at various parts of their systems
and take steps to see that it is kept within limits. There is no statutory limit for transmission
voltages, but there is for voltage at the consumer’s terminals (0 to +12% for
high voltage and ±6% for low voltage), and it is for the Area Boards to see
that this is met.
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