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CHAPTER ONE
1.0 INTRODUCTION
The project is about the reinforcement of Electricity Power Supply and
Installation of 1 NO. 300KVA, 11KV/415V Transformer at Onicha-Ugbo in
Aniocha North Local Government Area of Delta State at the cost of five
million nine hundred and forty-nine thousand twenty naira seventy kobo
(N5,949,020.70k). My work as an Electrical Engineer attached to Onicha-
Ugbo in Aniocha North Local Government Area is to go for survey on areas
that have made request for reinforcement of electricity power supply or
those areas that do not have electricity power supply. I visited the Onicha-
Ugbo community on request for reinforcement of Electricity power supply
by the indigenes.
On getting to the areas concerned, feasibility studies which covers where
the transformer can be installed suitably is put into consideration. The
distance from the existing High Tension Overhead (OH) line is also
considered. The case of installing a 300KVA, 11/.415KV transformer at
Onicha-Ugbo covers a distance of five hundred (500) meters for the High
Tension Overhead (OH) lines.
1.1 SCOPE OF WORK
The scope of work for the project includes (i) construction of 11kv High
Tension Overhead lines and low tension lines (ii) Installation of
300KVA,11KV/415V transformer substation (iii) Inspection and testing.
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1.2 DELIMITATION OF THE REPORT
This report is restricted to Delta North Senatorial District of Delta State.
While in some areas that are waterlogged, details cannot be given as Delta
North Senatorial District is not known to be waterlogged. Onicha_Ugbo
town is taken into consideration and the scope is limited to only a small
part of Delta State.
1.3 OBJECTIVE OF THE TECHNICAL REPORT
At the end of the exercise the technical report exposed the reader to the
operation of various components used in the reinforcement of electricity
power supply and installation of transformers. The technical report will also
serve as a teaching aid on the basic principles of installation of
transformers.
The need for the report became necessary since one of the criteria for
Chartership in the engineering profession is to give a small technical report
on one’s experience within few years of practical application of engineering
teachings, therefore, my work experience.
DESIGN CRITERIA/METHODOLOGY APPLIED ON THE PROJECTS
In carrying out the design for reinforcement of electricity power supply in
Onicha-Ugbo, the following considerations, criteria and methods were put
into use.
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2.0 Survey / Drawing/Design
2.1 Survey
Survey of the area is done by taking note of existing High tension/low
tension lines. There may be need to extend the high tension only or with
low tension lines running across it. Then I will find out the best option in
taking electricity to that point that is in need. The mapping out of the area
for the transformer substation is also covered in the survey. The distance of
the high tension line is measured locally by taking each step as one metre
and in every forty-five steps a span of low tension line is concluded while by
taking a step of seventy a span of high tension line is concluded. Metre tape
can be used if available and naming of street is made in the survey for
better accuracy and if the distance is much, the car speedometer can be
initialized while the distance is recorded at the point where the distance
covers.
2.2 DRAWING / DESIGN
In drawing, we represent the low tension lines, high tension lines,
transformer, streets, roads and necessary guide that can lead one to install
as designed. The representation covers both existing and proposed lines as
shown in the design figure I. The legend will surely show how/where the
poles are to be placed and where the transformers are to be installed. The
span for low tension line is forty-five metres while for high tension lines
outside the town is seventy metres. At every ten spans, there exists an
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interpole or H-pole with four stay-wires with each pole having three pin
insulators and four shackle insulators and steel galvanized cross arm.
The conductor for high tension and low tension is 100mm2 AAC/ACSR
Aluminium conductor wire. The height of the High tension pole is 10.4 m
while … will be buried. The height of the low tension is 8.5m while will be
buried. Concrete poles as support were used in the installation.
2.3 CONNECTIONS (SUBSTATION)
The following connections were done at the substation. The H-pole must be
mounted at the substation. The H-pole will bear the two or more channel
iron, the lightening arrestor and J&P fuses. The 35mm2 x 3HT dropper cable
runs from the 11KV over head (OH) High Tension line to the primary or high
voltage side of the 300KVA, 11KV/415V transformer.
The 300mm2 x 1PVC/SWA/PVC (U/G) cable will run from the secondary or
low voltage side of the transformer and linking up to the feeder pillar. The
provision for the feeder pillar is 800A 4-way and the up-riser cable of
150mm2 x 4LT will now distribute to the 4-wire Low Tension (LT) lines. The
schematic representation of this section is as shown in fig.ii, fig.iii and
fig.iv,
The high tension overhead is made up of 10.4m concrete pole, steel
galvanized cross arms, channel iron, tie straps, pin insulators, disc insulator
and j-hooks, clamps, clevis. The high tension overhead pole has three pin
insulators and for every ten (10) poles of HT line, two poles are mounted
(H-pole) which will bear the steel galvanized channel iron. The tie straps
support the steel galvanized cross arms. Eighteen number disc insulators
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are used for 33KV line where there is only one section while six number disc
insulator will be adequate where there is only one section for 11KV line.
Danger plates are mounted on every high tension overhead pole. Anti-
climbers of 3 meter per pole is also placed around the pole. Every high
tension pole should be earthed. The j-hooks, clamps, clevis should be the
anchor for the disc insulator.
2.5 TRANSFORMER PROTECTION
The setting up of a high tension line that goes with a transformer involves
huge amount of money. Therefore, there is need to protect the
transformer network. The provision made by the use of J&P fuses,
lightening arrestors and aerial line isolator (especially for 33KV overhead
line) go a long way in protecting the transformer network.
EARTHING
Earthing is done to limit the potential (with respect to the general mass of
the earth) of current-carrying conductors forming part of the system, and
non-current carrying metal work associated with equipment, apparatus and
appliances connected to the system.
The sizes of earthing and bonding connections should be based on the
following; High Voltage steel work earth lead or bonding – to be suitable for
each fault currents of the H.V. system typical conductor requirements for
11KV are as follows:
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Since the project in question is ground mounted substations – earth leads
32mm2 (3/3.75mm2) copper conductor, bonding connections 25mm x 3mm
copper strip or 25mm x 6mm aluminium strip. The MV neutral shall be
connected to earth electrodes at or near the substation and to any metallic
sheath and armouring of the MV distributors. The combined value for these
electrodes should not exceed 10 ohms. The HV steel work earth electrodes
provided for this purpose should be capable of passing a fault current of at
least twice the value required to operate the line protection equipment.
The maximum resistance of these electrodes should not exceed 70 ohms.
In general, earthing is done on the transformer, feeder pillar and the
conductors. The trenches dug in order to bring the earth pole are of four /
three holes measuring 5ft x 5ft for the transformer, 4ft x 4ft for the feeder
pillar, conductors and lightening arrestors.
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CHAPTER THREE
DESCRIPTION OF MATERIALS AND RATING
3.0 LINE CONDUCTORS – Material Sizes and Stranding
The line conductors for new distribution systems shall preferably be
aluminium or ACSR (Aluminium Copper Steel Reinforced) of appropriate
size as recommended below. Copper line conductors shall be used for
maintenance purposes only where copper lines already exist. Copper
conductors will, however, continue to be required for special purposes such
as drop leads to equipment, earthing etc. The recommended conductors
for the project are shown in the following table:
Copper or copper
equivalent to B.S.
125 1970
To B.S. 215 part 1
1970
ACSR
Metric Metric Current
rating
Area
metric
Stranding
AL (mm) Steel (mm)
35mm2
70mm2
50mm2
100mm2
150mm2
181A
271A
346A
-
50mm2
100mm2
-
6/3.35
6/4.72
-
1/3.35
7/1.57
The neutral conductor shall be of the same size as the phase conductor.
The normal arrangement of conductors for a three phase, 4-wire from
top to bottom shall be as follows:
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Red phase no. 1
Yellow phase no. 2
Blue phase no. 3
Neutral no. 4
3.1 MINIMUM HEIGHT OF CONDUCTORS
The lowest conductor (neutral) on the pole shall not be less height above
ground level at any point, after adjusting for the increased sag at 150oF (65
C), than
Over roads and streets - 5.5m
Along roads or over other places accessible to vehicular traffic -4.91m
Over places normally accessible to pedestrian traffic only -4.30m
3.2 LENGTH OF SPAN
The standard span of 45 metres shall be regarded as normal for spans over
45 meters, the high tension overhead line span may be considered up to
70m outside town.
3.3 SUPPORTS
The approved poles are pre-stressed, reinforced concrete poles of 10.4m
(34ft) for high tension pole and 8.6m (28ft) for low tension pole.
3.4 INSULATORS
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Insulators shall be of brown porcelain or of toughened glass
3.5 STAYS
Stay wire shall be of 4/8 S.W.G and 7/8 S.W.G galvanized steel strand of 45
ton quality and shall comply with B.S 183 as applicable. Please see fig v.
3.6 RODS
Stay rods shall be galvanized steel and comply with the requirement shown
in fig.vi.
3.7 GROUND MOUNTED TRANSFORMER
The substation shall be fenced using block and cement. The substation
compound shall be surfaced with crushed stone, graded 1 ½ “ down and
finished with a ¾ ” nominal size stone chippings. The transformer plinth and
foundation of the feeder pillar shall be taken through the topsoil with a
minimum (150mm) depth of mix concrete. This may be increased when
necessary to good load bearing ground.
3.8 SUBSTATION EQUIPMENT – TRANSFORMER
The transformer is oil-immersed, naturally cooled (typed On) suitable in all
respects for outdoor operations, three phase 11000/415 volts, 300KVA. The
schematic representation of this section is as shown in fig. vii, fig. viii and
fig. ix.
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Transformer is a static electromagnetic apparatus which transforms one
alternating current system into another with different voltage and current
levels, but of the same frequency. Transformers are designed in various
forms for different applications, some of these are:
a. Power transformers used for the transmission and distribution of
electric power.
b. Instrument transformers – used for connecting instruments for the
measurement of current and voltage.
c. Radio transformers – used in radio and electronic circuit.
INSULATOR: A device that opposes the flow of current and does introduce
resistance into the circuit e.g, sand, paper etc.
CONDUCTOR: A device that allows the flow of current and does not
introduce any resistance to it. E.g, copper, aluminium, steel etc.
SPAN: The span is the horizontal distance between two adjacent supports.
INTERMEDIATE POLE: AN intermediate pole is a pole on which the
conductors are supported on pin insulators.
SECTION POLE: A section pole for the purpose of this specification is an ‘H’
pole inserted into the line where additional strengthening is required,
stayed both ways in the direction of the line of route and with the
conductors made off on tension insulation on each side.
BONDING WIRE: The bonding wire is a conductor connecting together
metal components.
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EARTHING WIRE: A conductor connecting components or a bonding wire to
an earth electrode.
CHAPTER FOUR
THE BILL OF ENGINEERING MEASUREMENT AND EVALUATION / TESTING OF
FINISHED PROJECT
4.0 THE BILL OF ENGINEERING MEASUREMENT AND EVALUATION
Herein referred to as BEME is a document showing the materials and
quantity of materials with their local costing in one’s currency or
international currency and at the back cover, the total cost for the
execution of the Engineering job. Please see fig.x,xi,xii,xiii and fig.xiv for the
enclosure of BEME for the reinforcement of electricity power supply at
Onicha-Ugbo in Aniocha North of Delta State.
In the case of my area of work, the costing for survey, high tension line
materials, high tension overheads labour, substation materials, substation
labour, transportation of materials, contingency, amount allowed for
Ministry of Mines, Power and steel and PHCN pre-commissioning testing
fees and connection to PHCN National Grid and value added tax of 5%. This
BEME is only restricted as a presentation from the Department of Electricity
Power supply, Ministry of Energy, Asaba.
My job entails designing the high tension (HT) overhead lines, low tension
(LT) overhead lines, township distribution network (TDN) lines, the
installation of transformers (transformer substation).
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4.1 TESTING
All pre-commissioning and commissioning tests in substations are the
responsibility of PHCN and Federal Ministry of Energy. My department
carries out supervision and inspection of electrical projects. The following
write-up describes some of the tests to be performed but the actual test
figures may vary.
Overall Requirements
i. High voltage test shall be conducted in accordance with PHCN safety
rules (distribution).
ii. The insulation level of the equipment under test shall be measured
by means of a constant voltage insulation level set e.g, a “megger”
before and after the application of a high voltage test
iii. The application of a high voltage test to any item of equipment shall
be recorded in a “Record of High Voltage Test” form. Please see fig.
xv-xix for the enclosure of test results.
4.2 MATHEMATICS OF DERIVATION OF VALUE FOR BEME
In below column is a little mathematics that will throw more light on the
derivation for High Tension and Low Tension values for materials used in
the design.
Taking the case of the project into consideration that is the reinforcement
of electricity power supply and installation of 2 no. 300 KVA 11KV/415V
transformer S/S at Illah, we have:
H.T Material
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The distance for high tension is 500 meters for the second transformer
while the first is a direct dropping. The five hundred meter will cover about
eleven (11) poles of high tension. Note that for every ten poles, there is a
section of two poles. This will make a total of twelve (12) poles. In this case
two extra poles are used to tie-off the high tension line for the first
transformer dropping. The twelve poles plus the two poles will make a total
of fourteen (14) poles. To derive for cross arm, use the formula as:
Cross arms = Total No. of poles – (section x 2). The total no. of poles here is
12 poles.
Therefore, cross arm = 12 – (section x 2)
= 12 – 2 = 10
Channel Iron = section x 2
Two section exist in this case, therefore, 2 x 2 = 4
Tie straps = Total no. of poles – no. of section = 12-2 = 10
Pin insulation = 3 x cross arm + 2 x no. of section
= 3 x 10 + 2 x 2 = 34
Disc insulator length = No. of span x 3 x distance of one span
= 10 x 3 x 50 = 1.5km = 1.6 km for sagging.
Danger plate = no. of poles = 14
Anti-climber device (barbed wire) = 3meters x no. of poles
= 3 x 14 = 42 meters.
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Stay assembly (complete) = no. of conductor stringing = 12
Earthing system complete with soil treatment
= total no. of pole – ½ (no. of section) + 1
= 14 – ½ (4) = 12
Aerial line isolator, complete handle pole and H.T. accessories = no. of
substation
This is mostly used for 33KV overhead lines
LT Earthing = No. of Poles (not applicable)
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HT Earthing = No. of Poles – section
= 14 – 2 = 12
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CHAPTER FIVE
CONCLUSION, PROBLEM ENCOUNTERED, RECOMMENDATION AND APPENDICES
5.0 PROBLEM ENCOUNTERED
It must be stated here that a little problem was encountered in the course
of the project. Solution was also proffered hence the installation work was
a success. The problem was due to the earthing. From the test the earth
resistance was very high (above 20 ohms) which was not acceptable
Moreover, the earthing was improved by bringing the high resistance to an
acceptable level with connection of more earth rod and earth mat at
different nearby position properly linked with 70mm copper wire.
Another problem that was experienced in the process of preparing the
certificate for the payment of the project, is the delay in pre-commissioning
test by PHCN and Federal Ministry of Energy.
5.1 RECOMMENDATION
i. Proper earthing network should be put in place especially at
substation in order to protect the entire network
ii. PHCN and Federal Ministry of Energy should respond quickly to pre-
commissioning test
5.2 CONCLUSION
The electrification project of Onicha-Ugbo village was satisfactorily
completed. I ensured the use of standard materials. For the installation,
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with earthing and protective devices put in place to achieve the maximum
performance of the installed transformers. The voltage level at the
consumer end was between 220V – 230V at frequency of 50hz at the time
of completion.
Recommended