24-IDL-EE 466-UNIT 3-Technical Aspects of Power Systems Planning PDF.pdf

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EE 466
Power Systems Planning & Optimization
UNIT 3:
TECHNICAL ASPECTS OF POWER SYSTEMS PLANNING

Jan 2014
Dr. E. K. Anto
[email protected]//0208201565; 0243225858
 3.0: Technical Considerations

The various technical aspects must be considered for both NORMAL
(STEADY-STATE) and ABNORMAL (FAULTY) operating conditions

The TECHNICAL CONSIDERATIONS include:
1) Modelling of network components
2) Load flow analysis
3) Voltage drop
4) System earthing – (has been given detailed treatment already)
5) Fault analysis – (has been given detailed treatment already)
6) Overvoltages and overcurrents
7) Estimation of load growth / Load forecasting – (to be given
special consideration as a Unit topic)
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 MODELLING OF NETWORK COMPONENTS

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 3.1: Modelling of Network Components (1/1)

Modelling is the mathematical representation of the components of
the system

In the modelling, one makes use of ‘equivalent circuits’ for various
components,

These equivalent circuits are then combined, in order to represent
the interconnection of the components in the actual electrical
network.

After combining them, network/circuit theories are used in the
analyses of the system performance
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 LOAD FLOW ANALYSIS

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 3.2: Load Flow Analysis (1/1)

Normally, LOAD FLOW STUDIES provide information concerning the
system when it is operating UNDER NORMAL OR STEADY-STATE
CONDITIONS.

With simulation or analytical tools like load flow analysis and
contingency analysis, the planner can evaluate the capability of
each alternative expansion plan for providing the level of
performance desired

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 VOLTAGE DROP

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 3.3: Voltage Drop (1/2)

As far as voltage drop in cables and overhead lines is concerned, it
is important to obtain the following information:
The accurate route lengths for the cables and lines;
the maximum continuous current the conductors will have to carry.

It should be recalled that the VOLTAGE DROP IS INFLUENCED BY the:
i. Load current
ii. Power factor of the load
iii. Dimensions (R and X) of the linking conductor

Voltage drop in the circuit must not be overlooked, as this can have
a bearing on the conductor size chosen.
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 3.3: Voltage Drop (2/2)

It is also important to remember that some electrical equipment,
such as direct-on-line (DOL) start squirrel-cage induction motor, can
take a starting current that is some 6 to 7 times the equipment’s
normal running current.
This means that for a short period of time, the voltage drop may be
higher than the 5 % permitted by regulation.
An EXCESSIVE REDUCTION IN VOLTAGE, even for a short period of
time, may have an ADVERSE EFFECT ON THE STARTING
CHARACTERISTICS OF THE MOTOR LOADS and in certain
circumstances could affect its correct operation.
Again, a SUDDEN DROP IN VOLTAGE can have NEGATIVE EFFECT ON
ELECTRONIC EQUIPMENT.

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 OVERVOLTAGES

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 3.4: Overvoltages

Overvoltage is the condition when the peak value of the voltage
applied to a device exceeds the limits defined in a standard or
specification.

Consideration may be given for THREE (3) TYPES OF OVERVOLTAGE:
1. Power-Frequency Overvoltage
2. Switching Overvoltage
3. Lightning Overvoltage

A look will also be taken at CONSEQUENCES of overvoltages

We shall also treat PROTECTIVE MEASURES to address overvoltages
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 3.4.1: Power-Frequency Overvoltages (1/1)

By definition, POWER-FREQUENCY OVERVOLTAGES include all
overvoltages with frequency under 500 Hz.
These overvoltages may be CAUSED BY THE FOLLOWING:
1) Insulation breakdown faults – (phase-to-ground faults)
2) Resonance overvoltage by fault – Under certain resonant
conditions, internal overvoltages can be produced in a network.
3) Ferroresonance – a rare non-linear oscillatory phenomenon
arising from a circuit containing a capacitor and a saturable
inductance (e.g. a power transformer).
4) Overcompensation of reactive power
5) Break of the neutral conductor
6) Faults on alternator regulators or tap-changing transformer
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 3.4.2: Switching Overvoltages (1/1)

SWITCHING OVERVOLTAGES are produced by rapid modifications in
the network structure as a result of a switching activity, be it for
protection in the event of a fault, OR for maintenance purposes. (For
example, opening protective devices, etc.).

The following THREE (3) DISTINCTIONS are made:

i. Switching overvoltage at normal load.
ii. Overvoltage produced by the normal switching operations
(intentional switching) in the system.
iii. Overvoltages due to the tripping (unintentional, fault-induced
switching) in the system.
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 3.4.3: Lightning Overvoltages (1/1)

Lightning is a natural phenomenon occurring during storms.

LIGHTNING OVERVOLTAGES are thus due to atmospheric or lightning
strikes.

When traveling along a line, the voltage waves are attenuated and
distorted, and have steep fronts of the order of hundreds of kilovolts
per microsecond

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 CONSEQUENCES OF OVERVOLTAGES

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 3.4.4: CONSEQUENCES of Overvoltages (1/1)

The consequences of overvoltages are varied according to the
period of application, repetitivity, magnitude, mode and frequency.
Some of the CONSEQUENCES OF OVERVOLTAGE include
1) Dielectric breakdown – causing significant permanent damage
to equipment (electronic components, etc).
2) Degradation of equipment through ageing – repetitive rather
than destructive overvoltages
3) Long interruptions – caused by the destruction of equipment
(leads to loss of sales for distribution company, loss of production
for industrial companies)
4) Disturbances – in control systems and low current
communication circuits
5) Electrodynamic and thermal stress
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 3.4.5: PROTECTIVE MEASURES For Overvoltages (1/1)
1) A substation can be shielded from direct lightning strokes by a
system of overhead earthwires as LIGHTNING ARRESTERS.
2) Protection against transient overvoltages is given by SURGE
DIVERTERS:
a) that shunt the lightning current to earth but
b) resist the power-frequency current, so that protective devices
are not operated and circuits not interrupted unnecessarily.
3) SHIELDING alone does not provide complete protection, and is
usually COMBINED WITH SURGE DIVERTERS. On the other hand,
conditions sometimes justify the use of surge diverters alone.
4) In areas of low isokeraunic levels (areas with reduced susceptibility
to lightning strokes), ROD GAPS are used instead of surge diverters
to save cost.

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 OVERCURRENTS

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 3.5: Overcurrents (1/1)

An overcurrent is either an overload or a short-circuit/fault current.

The OVERLOAD CURRENT is:
an excessive current that flows under normal conditions, but
one that is confined to the normal conductive paths provided by
the conductor and other components and loads of the
distribution system.

A SHORT-CIRCUIT CURRENT is one which flows outside the normal
conductive paths, and usually due to fault or abnormal condition.

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 3.5.1: Overloads (1/1)

Overloads are most often between one and six times the normal
current level.

They may be (i) transient or (ii) continuous.

Transient overloads are usually caused by harmless temporary surge
currents that occur when motors are started-up or transformers are
energized.

Continuous overloads can result from defective motors (such as
worn motor bearings), overloaded equipment, or too many loads on
one circuit.
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 3.5.2: Short-Circuit Currents (1/1)

The ampere interrupting capacity (AIC) rating of a circuit breaker or
fuse is the maximum short-circuit current which the breaker will
interrupt safely.

This AIC is at rated voltage and frequency.

Whereas overload current can occur at rather modest levels, the
short-circuit or fault current can be many hundred of times larger
than the normal operating current.

Typically, a high level fault may be 50,000 A (or larger).

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 EXERCISES

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 3.6: EXERCISES

(1) State any 5 planning objectives that must be considered to
ensure a good planning of an electrical power system.
(2) Mention any 5 technical considerations that need to be taken in
the planning of a power transmission system, and explain the
significance of those considerations in the overall planning of the
power system.
(3) What 3 main categories of overvoltages do you know of? Discuss
very briefly how they occur under each category.
(4) Enumerate 5 consequences of overvoltages that a planning
engineer will seek to avoid.
(5) Mention any 4 protective measures for addressing overvoltages

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 END OF UNIT 3

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Jan 2014