Saturday, 15 December 2018

Thursday, 26 July 2018

Why Capacitors bank is connected parallel with a load to improve power factor

we can improve the power factor by connecting the capacitor bank in parallel or series.If we connect the capacitor bank in parallel that means additional installation and O&M costs can be saved. In fact when we connect the capacitor bank to the series there is a decrease in the power of those capacitors in the series, a distance between 10-20% of the minimum transmission voltage. So power outages are not a major issue. The real problem is protection and the resulting cost: in the event of a short-circuit fault in the load there is a chance that all the transmission voltage will be applied to those capacitors and may fail. As we know it can be protected from over voltage voltages by using appropriate switch switches and split gap sparks. It therefore means additional installation and O&M (operation and maintenance) costs that can be avoided simply by connecting the capacitors accordingly.
Another great advantage is that when we connect it seamlessly you separate your installation, which makes it easier to repair. For example, if you need to replace some bank capacitors, or add others, to the corresponding series you need to do to disconnect the bank throughout the network, instead of the whole facility if you were connected to a network. series.
Just for the record, there are cases where capacitors are connected in series, but not in the load terminals and do not affect the compensating capacitor banks that are active (well, not really). These are the conditions in which it is desired to increase the natural strength of the transmission line. They are also connected to the series to minimize the reaction of the long line (not to be confused with its feature). Therefore, increasing its current capacity and consequently increasing its capacity and stability.This measure is mainly used for long transmission lines, i.e. 500 km and more.

Monday, 11 September 2017

TRANSFORMER MAINTENANCE GUIDELINES

TRANSFORMER MAINTENANCE GUIDELINES
Following specific checking and maintenance guidelines as well as conducting routine inspections will help ensure the prolonged life and increased reliability of a transformer. The frequency of periodic checks will depend on the degree of atmospheric contamination and the type of load applied to the transformer.
Routine checks and resultant maintenance
Sl No
Inspection Frequency
Items to be inspected
Inspection Notes
Action required if inspection shows unsatisfactory conditions
1.1
Hourly
Ambient Temperature
-
-
1.2
Hourly
Oil & Winding Temperature
Check that temperature rise is reasonable
Shutdown the transformer and investigate if either is persistently higher than normal
1.3
Hourly
Load (Amperes) and Voltage
Check against rated figures
Shutdown the transformer and investigate if either is persistently higher than normal
2.1
Daily
Oil level in transformer
Check against transformer oil level
If low, top up with dry oil examine transformer for leaks
2.2
Daily
Oil level in bushing


2.3
Daily
Relief diaphragm

Relief diaphragm
3.1
Quarterly
Bushing
Examine for cracks and dirt deposits
Clean or replace
3.2
Quarterly
Oil in transformer
Check for dielectric strength & water content
Take suitable action
3.3
Quarterly
Cooler fan bearings, motors and operating mechanisms,
Lubricate bearings, check gear boxes, examine contacts
Replace burnt or worn contact or other parts

4.1

Yearly
Oil in transformer
Check for acidity and sludge
Filter or replace
4.2
Yearly
Oil filled bushing
Test oil
Filter or replace
4.3
Yearly
Gasket Joints
-
Tighten the bolts evenly to avoib uneven pressure
4.4
Yearly
Cable
boxes Check for sealing arrangements for filling holes.
Replace gasket, if leaking
4.5
Yearly
Surge Diverter and gaps
Examine for cracks and dirt deposits
Clean or replace
4.6
Yearly
Relays, alarms & control circuits
Examine relays and alarm contacts, their operation, fuses etc. Test relays
Clean the components and replace contacts & fuses, if required.
4.7
Yearly
Earth resistance

Take suitable action, if earth resistance is high
IR testing:
The transformer should be de-energized and electrically isolated with all terminals of each
winding shorted together. The windings not being tested should be grounded. The meg-ohmmeter
should be applied between each winding and ground (high voltage to ground and low voltage to
ground) and between each set of windings (high voltage to low voltage). The meg-ohm values
along with the description of the instrument, voltage level, humidity, and temperature should be
recorded for future reference.
The minimum megaohm value for a winding should be 200 times the rated voltage of the winding
divided by 1000. For example, a winding rated at 13.2kV would have a minimum acceptable value
of 2640 megaohms ([13,200V x 200] / 1000). If previously recorded readings taken under similar
conditions are more than 50% higher, the transformer should be thoroughly inspected, with
acceptance tests performed before reenergizing.
Turns ratio testing:
 The transformer turn ratio is the number of turns in the high voltage winding divided by the
number of turns in the low voltage winding. This ratio is also equal to the rated phase voltage of
the high voltage winding being measured divided by the rated phase voltage of the low voltage
winding being measured.
Transformer turns ratio measurements are best made with specialized instruments that include
detailed connection and operating instructions. The measured turns ratio should be within 0.5% of
the calculated turns ratio. Ratios outside this limit may be the result of winding damage, which has
shorted or opened some winding turns.
Insulation PF testing:
Insulation PF is the ratio of the power dissipated in the resistive component of the insulation
system, when tested under an applied AC voltage, divided by the total AC power dissipated. A
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perfect insulation would have no resistive current and the PF would be zero. As insulation PF
increases, the concern for the integrity of the insulation does also. The PF of insulation systems of
different vintages and manufacturers of transformers varies over a wide range (from under 1% to
as high as 20%). As such, it's important that you establish a historic record for each transformer
and use good judgment in analyzing the data for significant variations.
Acceptance testing
Acceptance tests are those tests made at the time of installation of the unit or following a service
interruption to demonstrate the serviceability of the transformer. This testing also applies to drytype
units. The acceptance tests should include IR testing, insulation PF measurement, and turns
ratio testing, all as described under periodic tests. In addition, winding resistance measurements
should be made and excitation current testing done.
Winding resistance measurement:
Accurate measurement of the resistance between winding terminals can give an indication of
winding damage, which can cause changes to some or all of the winding conductors. Such
damage might result from a transient winding fault that cleared; localized overheating that opened
some of the strands of a multi-strand winding conductor; or short circuiting of some of the winding
conductors.
Sometimes, conductor strands will burn open like a fuse, decreasing the conductor cross section
and resulting in an increase in resistance. Occasionally, there may be turn-to-turn shorts causing
a current bypass in part of the winding; this usually results in a decrease of resistance.
To conduct this test, the transformer is de-energized and disconnected from all external circuit
connections. A sensitive bridge or micro-ohmmeter capable of measuring in the micro-ohm range
(for the secondary winding) and up to 20 ohms (for the primary winding) must be used. These
values may be compared with original test data corrected for temperature variations between the
factory values and the field measurement or they may be compared with prior maintenance
measurements. On any single test, the measured values for each phase on a 3-phase
transformer should be within 5% of the other phases.
Excitation current measurement:
The excitation current is the amperage drawn by each primary coil, with a voltage applied to the
input terminals of the primary and the secondary or output terminals open-circuited. For this test,
the transformer is disconnected from all external circuit connections. With most transformers, the
reduced voltage applied to the primary winding coils may be from a single-phase 120V supply.
The voltage should be applied to each phase in succession, with the applied voltage and current
measured and recorded.
If there is a defect in the winding, or in the magnetic circuit that is circulating a fault current, there
will be a noticeable increase in the excitation current. There is normally a difference between the
excitation current in the primary coil on the center leg compared to that in the primary coils on the
other legs; thus, it's preferable to have established benchmark readings for comparison.
Variation in current versus prior readings should not exceed 5%. On any single test, the current
and voltage readings of the primary windings for each of the phases should be within 15% of each
other.
Applied voltage testing:
 The applied voltage test is more commonly referred to as the "hi-pot test." This test is performed
by connecting all terminals of each individual winding together and applying a voltage between
windings as well as from each winding to ground, in separate tests. Untested windings are
grounded during each application of voltage.
This test should be used with caution as it can cause insulation failure. It should be regarded as a
proof test to be conducted when there has been an event or pattern in the transformer's operating
history that makes its insulation integrity suspect.
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DC applied voltage tests are often conducted in the field because DC test sets are smaller and
more readily available than AC applied voltage sets. With DC tests, the leakage current can be
measured and is often taken as a quantitative measure. However, DC leakage current can vary
considerably from test to test because of creepage across the complex surfaces between
windings and between windings and ground.
The use of AC voltage is preferable since the transformer insulation structures were designed,
constructed, and tested with the application of AC voltage intended.
Impedance testing:
An impedance test may be useful in evaluating the condition of transformer windings, specifically
for detecting mechanical damage following rough shipment or a service fault on the output side
that caused high fault currents to flow through the transformer windings. Mechanical distortion of
the windings will cause a change in their impedance. To maximize the effectiveness of this test, a
measurement should be taken during the transformer's initial installation to establish a benchmark
value.
An impedance test is performed by electrically connecting the secondary terminals together with aconductor capable of carrying at least 10% of the line current and applying a reduced voltage to
the primary windings. This is easily accomplished by applying a single-phase voltage to each
phase in succession. The applied voltage is measured at the primary terminals and the current
measured in each line.
These values shall be recorded and then calculate the ratio of voltage to current for each phase.
This ratio should be within 2% for each phase and should not vary more than 2% between tests.
A variation of more than 2% indicates the possibility of mechanical distortion of the winding

conductors, which should be investigated as soon as possible.

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