INTRODUCTION
UPPCL will be professionally managed utility supplying reliable
and cost efficient electricity to every citizen of the state
through highly motivated employees and state of art technologies,
providing an economic return to our owners and maintaining
leadership in the country.We shall achieve this being a dynamic,
forward looking, reliable, safe and trustworthy organization,
sensitive to our customers interests, profitable and sustainable in
the long run, providing uninterrupted supply of quality power, with
transparency and integrity in operation, providingUttar Pradesh
Power Transmission Corporation Ltd. (UPPTCL) has a very large
network of high voltage transmission lines in whole UP (about
24,000Km). Transmission lines transfer power from power houses to
substations and from one substation to many other substations or
vice versa. Power is generated at low Voltage (of the order of
3.3KV to 25KV) and is stepped-up to high voltage (765KV, 400KV,
220KV & 132KV) for evacuating power into the grid network
through transmission lines.33/11KV Substations of distribution
companies (DISCOMs) draw power from transmission substations
through 33KV lines and distribute that to consumers (at 0.04KV,
11KV or in few cases at 33KV). Distribution companies have
industrial, rural and domestic load, which varies from time to time
of the day and from season to season of the year. Sometimes, large
variations in load cause over/under loading of lines, transformers
or generators. Variations beyond limits and breakdowns cause
fluctuations in voltages & grid frequency of the network.
Control Centers, in hierarchical form, are set up for smooth
functioning of the grid. Each generating unit or substation has its
own Control Centre. These are also named as Unit Control Board
(UCB)/Main Control Board (MCB)/Control Room. These Control Centres
report to Area Load Dispatch Station (ALDS). ALDS report to Central
Load Dispatch Station (CLDS at State Level), CLDS reports to
Regional System Coordination & Control Centre (RSCC at regional
level having a group of States and Central sector units of that
region) & finally on top is National Load Dispatch Centre
(NLDC) which is being set-up.These control centers need real time
information about generation, power flow, voltage, frequency, etc.
of generators & substations. This information is exchanged in
data or voice form. For exchange of such information, a reliable
and dedicated communication system is required. Substations or
power houses, situated at both ends of transmission line, need
information in voice form. Trip commands (also called protection
signal) are transmitted from one substation to the other
substation, through transmission line. When 'earth' or
'over-current' fault is sensed by one end of the transmission line,
a trip command is generated, which travels through communication
system and opens circuit breaker (switchgear) of the other end.
Dedicated communication system is required for transmission of
protection signal.Old Communication SystemMost of the high voltage
substations & power houses are located away from cities/towns
or in outskirt area of the city. In mid sixties, in erstwhile U.P.
State Electy. Board (UPSEB), even P & T lines were not
available for communicating messages among substations and
powerhouses. In some cases, telex messages were being sent through
P & T department between few Control Centers situated in major
cities. Later on, Power Line Carrier Communication (PLCC) systems
were used for voice communication among substations, powerhouses,
grid control centers and for sending protecting signals. In late
seventies, sub-VF band of few PLCC links were used for transmitting
tele-metering signal (containing data of power flow, voltage,
frequency, circuit breaker/Isolator status, etc.) to Control
Centers. Thereafter in eighties, microwave communication system was
introduced and 38 nos. microwave stations were set up in Uttar
Pradesh, starting from Rishikesh in the north-west to Rihand in the
south-east. It was an analogue communication system and was
partially successful. During this period, many 400KV substations
and power houses came up but main dependency remained upon PLCC
& P&T communication systems.Unified SchemeIn nineties, it
had been felt that facilities for operation and management of power
system were grossly inadequate. The erstwhile UPSEB was finding it
difficult to properly manage its grid, as it was running in
conjunction with other Constituents of Northern Region, comprising
of electricity boards/departments of States - Rajasthan, Punjab,
Haryana, HP, J&K, DESU and Central Sector Corporations (NTPS,
NHPC, and PGCIL). After every grid failure or isolation,
restoration time used to be very long. During post-mortem analysis
of grid failures, it was difficult to pinpoint, confidently, the
main culpri9t sub-station/State. At that time, only UPSEB had an
analogue microwave communication system, but it was operative in
few sections, while other States were totally dependent upon PLCC
& P&T lines. Side-by-side there was a plan for formation of
National Grid. To manage in inter-State & power drawal
(export/import of power) and maintain a discipline, come
rules/procedures (Grid Code) were being framed. In order to manage
regional grid, need of 'online information', in the form of data,
was felt. This online data, of grid substations & power houses,
required a reliable and dedicated communication system. Thus,
adoption upon that situation, Central Electricity Authority (CEA)
& Northern Region Electricity Board (NREB) asked all its
Constituents (UPSEB was also a Constituent of NREB) to make a
combined effort in this direction. This gave birth to a 'Unified
Scheme', a 'combined' project with other Constituents of NREB (NREB
has now been named as Northern Regional Power Committee-NRPC). This
project was formulated for establishment of modern computerized
Load Dispatch Centres (LDCs), for having SCADA (Supervisory Control
and Data Acquisition) and Energy Management System (EMS) along with
strengthening of telecommunication facilities of each State. Uttar
Pradesh (included area which is now in Uttaranchal) was a major
Constituent of NREB. Since, Power Grid Corporation of India (PGCIL)
had presence in every State, the responsibility for implementation
of 'Unified Scheme' was given to it by NREB, PGCIL got the
equipment, installed & commissioned in the whole northern
region. A Memorandum of Understanding (MoU) was signed between
PGCIL and all other Constituents of NREB in 1994. Thereafter, it
took four years for PGCIL to gather requirement of each Constituent
and finalize orders with their Vendors/Contractors under Global
offers. Later on, same scheme was implemented in other Regional
Electricity Boards of India (such as Eastern, Western, North-east
& Southern). By mid of 2002, major works of commissioning of
'Unified Scheme' were over in northern region.
Load Dispatch CentresBefore implementation of 'Unified Scheme'
U.P. State had a 'Central Load Dispatch Station' (CLDS), at 5th
floor of Shakti Bhawan, Lucknow. It was being assisted by its four
'Area Load Dispatch Stations' (ALDSs), situated at Sahupuri, Panki,
Moradabad and Roorkee. After modernization & computerization of
control centers, the nomenclatures of these control centers have
been changed. A hierarchy of Control centers has been formed. The
basic control centre, ALDS of every State has been named as
sub-Load Dispatch Centre (subLDC) CLDS has been named as State Load
Dispatch Centre (SLDC). Regional System Coordination & Control
Centres (RSCC) of northern region at New Delhi has been named as
Northern Regional Load Dispatch Centre (NRLDC).
In the above Figure 1 National Load Dispatch Centre (NLDC) has
been shown at the top. Its Control Centre has been setup at New
Delhi and will be operational in month of May/June 2008. Below
this, five nos. regional level Load Dispatch Centers have been
shown. Presently, except for Southern Region, grids of all other
regions are interconnected and are running in combined form. This
way, Northern Regional Load Dispatch Centre (NRLDC) is now part of
all India Grid or say 'National Grid'. The role of the NRLDC is to
monitor and supervise the grid and power generation of the region.
It focuses attention on the regional interconnected network. By
using 'Energy Management System' (EMS) and advanced application
programmes, NRLDC coordinates with all inter-region and inter-state
power exchange.Below NRLDC, State level SLDCs and Central Project
Coordination & Control Centre (CPCC) have been shown. The
primary role of SLDCs is to monitor, control and coordinate the
generation, transmission and distribution of power within the State
while ensuring safety and continuity of its transmission and
sub-transmission power networks. CPCC (North) coordinates with all
Central sector projects of northern region such as those of NTPC,
NHPC, Power Grid, Tehri, etc. CPCC gets data from Central Sector
projects and that data is added at regional level. Each RLDC has
the ability to exchange data with other RLDCs as well as with NLDC,
but direct data transmission does not take place between SLDC of
one State with SLDC of another State.SLDC of Uttar Pradesh is
situated at 5th Floor of Shakti Bhawan, Lucknow. This SLDC has the
ability to exchange data with NRLDC, New Delhi and its sub-LDCs.
Under it, there are five sub-LDCs. SLDC of UP & each subLDC is
manned 24 hours of the day by shift engineers (except for subLDC
Sultanpur, which is being managed from subLDC Panki). Each subLDC
collects data from various 'Remote Terminal Units' (RTUs),
installed at important sub-stations (400KV, 220KV and few 132KV)
and powerhouses. So far in UPPTCL, 72 RTUs have already been
integrated with the system. Each RTU automatically picks up
required information (MW, MVAr, KV, Hz, Circuit breaker &
isolator status) of the sub-station/powerhouse and transmit it to
its subLDC through communication system. This information is
processed in the data Server of subLDC. Data in the form of binary
stream of pulses are sent by RTU at the speed of 300, 600 or 1200
bits per second rate (baud). At subLDC, the information is updated
within 10 sec.For managing power system at load dispatch centers,
communication plays a vital role by providing path for transmitting
of data & voice. Work of these control centers is dependent
upon SCADA (Supervisory Control and Data Acquisition) System and
various types of communication systems.Uttar Pradesh Power
Transmission Corporation Ltd. (UPPTCL) has a very large network of
high voltage transmission lines in whole UP (about 24,000Km).
Transmission lines transfer power from power houses to substations
and from one substation to many other substations or vice versa.
Power is generated at low Voltage (of the order of 3.3KV to 25KV)
and is stepped-up to high voltage (765KV, 400KV, 220KV & 132KV)
for evacuating power into the grid network through transmission
lines.33/11KV Substations of distribution companies (DISCOMs) draw
power from transmission substations through 33KV lines and
distribute that to consumers (at 0.04KV, 11KV or in few cases at
33KV). Distribution companies have industrial, rural and domestic
load, which varies from time to time of the day and from season to
season of the year. Sometimes, large variations in load cause
over/under loading of lines, transformers or generators. Variations
beyond limits and breakdowns cause fluctuations in voltages &
grid frequency of the network. Control Centers, in hierarchical
form, are set up for smooth functioning of the grid. Each
generating unit or substation has its own Control Centre. These are
also named as Unit Control Board (UCB)/Main Control Board
(MCB)/Control Room. These Control Centres report to Area Load
Dispatch Station (ALDS). ALDS report to Central Load Dispatch
Station (CLDS at State Level), CLDS reports to Regional System
Coordination & Control Centre (RSCC at regional level having a
group of States and Central sector units of that region) &
finally on top is National Load Dispatch Centre (NLDC) which is
being set-up.These control centers need real time information about
generation, power flow, voltage, frequency, etc. of generators
& substations. This information is exchanged in data or voice
form. For exchange of such information, a reliable and dedicated
communication system is required. Substations or power houses,
situated at both ends of transmission line, need information in
voice form. Trip commands (also called protection signal) are
transmitted from one substation to the other substation, through
transmission line. When 'earth' or 'over-current' fault is sensed
by one end of the transmission line, a trip command is generated,
which travels through communication system and opens circuit
breaker (switchgear) of the other end. Dedicated communication
system is required for transmission of protection
signal.Transmission of DataBelow in Figure 2, main equipment from
substation/power house to its subLDC has been shown in a very
simple form.
Figure 2: Transmission of Data from substation/Power house to
subLDCCurrent Transformers (CTs) and Potential Transformers (PTs),
installed on transmission lines, provide inputs to transducers of
SIC (Supervisory Interface & Control) & RTU (Remote
Terminal Unit) panel. Circuit breakers & isolators' status are
extended up to SIC panel. If for such extension extra potential
free contacts are not available in the Control Panels, Contact
Multiplying Relays (CMRs) are used to provide potential free
contacts. The output of RTU is connected to the communication
equipment, through Modem. In between substation & subLDC, a
communication link has been shown. Telephone exchanges are
connected with the communication equipment. Such communication
links can be of any type. UPPTCL has got its own three different
type of communication systems, i.e. PLCC (Power Line Carrier
Communication), microwave and fibre-optic. PLCC system is more
prevalent in UPPTCL. Modem output at receive side is connected with
the CFE (Communication End Frame). Its output is connected with
data takes over. Each RTU is automatically polled by Server of
subLDC to obtain each data of repeats at least once in 10 sec and
is stored in the database of subLDC. This data is processed in
database formats and is retrieved for different applications. These
formats or graphics are displayed or printed as per requirement. At
subLDC, System Control Officers use this data to monitor and
analyze position of the grid.Below in Figure 3, main equipment from
subLDC to SLDC, Lucknow has been shown in a very simple form.
A systematically combined/processed data of all RTUs, in server
of subLDC, is transmitted to SLDC Lucknow. This data in the form of
64Kb/s signal is sent through multiple paths/channels. Presently
four channels are used. For this purpose 'Routers' are used.
Routers basically work as modem but is has multiple paths for LAN,
WAN or internet, etc. In UPPTCL, for transmission of data, from
subLDC to SLDC, only wideband communication system (microwave or
fibre-optic links) is being used. In SLDC, data from all other
subLDCs is also received simultaneously and are processed for
different purposes and applications. From Inter-Control Centre
Communications Protocol (ICCP) Servers of SLDC, complete data of
all subLDCs is sent to NRLDC, New Delhi through wideband
communication system. This way communication plays a major role in
grid management.Communication for Power SystemFollowing are mainly
three inter-related areas of functions in UPPTCL for management of
power system:A) TelecommunicationB) SCADA- Supervisory Control and
Data Acquisition System.C) EMS- Energy Management SystemA)
TELECOMMUNICATIONThere are three different types of
telecommunication systems in UPPTCL i.e.i. Microwave Communication
System,ii. Fibre-optic Communication System,iii. PLCC-Power Line
Carrier Communication.Voice Frequency (VF) channels of all these
systems have been integrated/interconnected to make a hybrid
communication system. Microwave & Fibre Optic are
multi-channels communication systems and are also called 'Wideband
communication system'. PLCC is single channel communication system.
A brief overview of these three types of telecommunication system
of UPPTCL is as below:Microwave Communication SystemMicrowaves
travel in 'Space' and any object in the path can obstruct
communication system. Microwave is called 'line-of-sight'
communication system. As such, its antennas are mounted on high
towers so that even trees should not obstruct path of microwaves.
UPPTCL is using frequency band between 2.3 GHz to 2.5 GHz. The
height for antenna are calculated by taking into account many
factors, such as, distance between two locations, path clearance,
height from sea level of these locations, tropical area, reflection
points, and so on. As such, height of towers varies from location
to location. Tower heights at our microwave stations range from 30
to 110 meters. Starting from Muzaffarnagar (220KV substation Nara),
in the north-west, to Rihand (Pipri), in south-east of UP, 33
microwave stations have been established. A list of microwave
stations with height of towers has been given at the end of this
write-up. This covers a route length of over 1000 Km. Erstwhile
UPSEB had an analogue microwave system which was converted to
digital microwave system in 2001. Previous analogue microwave
equipment was being used with 'frequency diversity' system where
frequencies of Transmitters & Receivers of 'Normal' and
'Standby' equipment were different. In Frequency Diversity system
both Transmitters & Receivers are connected with antenna
simultaneously. In present digital microwave system, Transmitters
& Receivers of 'Normal' and 'Standby' equipment has got same
frequency and is called 'hot standby' system. Only one column is
equipment has got same frequency and is called 'hot standby'
system. Only one column is connected with the antenna. Microwaves
are susceptible to 'fading phenomenon' due to change in atmospheric
medium above the earth, during day & night and from season to
season. Some links, which are suspected for excessive fading during
propagation of signal, have been provided with additional antennas
for 'space diversity'. In space diversity system, Transmitters
& Receivers have additional antennas, located at different
heights. Each system has got its own advantages. New digital
microwave system has got many useful features for easy maintenance.
Its 'Network Management System' (NMS) helps in remote diagnosis
operation and maintenance. As an example, microwave NMS equipment
at Lucknow detects defective circuits between Obra-Pipri and
diagnoses its problem. In some cases, the maintenance personnel at
Lucknow implements remedial actions and reallocate channels, if
required. This way immediate site visits for minor faults, in many
cases, are not required. Microwave equipment is of 'Nokia' Finland
make.Fibre Optic Communication SystemIt is new communication system
and has been introduced in UPPTCL since 2001. Optical fibre cable,
in the form of 'Optical Fibre Composite Ground Wire' (OPGW), has
been installed on transmission towers by replacement of earth wire.
Earth wires of following five transmission lines, total route
length of 408 Km., have been replaced:1. 400KV line between 400KV
S/S Muradnagar - 400KV S/S Moradabad;2. 220KV line between 400KV
S/S Moradabad - 220KV S/S C.B. Ganj;3. 400KV line between 400KV S/S
Unnao - 400 KV S/S Panki;4. 220KV line between 220KV S/S Sahupuri -
400KV S/S Sarnath and5. 400KV line between 400KV S/S Sarnath -
400KV S/S Azamgarh.'Optical Line Terminal Equipment' (OLTE) have
been manufactured by Fujitsu, Japan and have been installed at
eight sub-stations (Muradnagar, Moradabad, C.B.Ganj, Unnao, Panki,
Sahupuri, Sarnath & Azamgarh). The electrical signal of 2Mb/s
or 34Mb/s, as the case may be, from OLTE is connected with Primary
Multiplexing equipment supplied by 'Nokia' Finland. Its NMS
provides operational support for the 'Fibre Optic Transmission
System' (FOTS). For testing, commissioning & maintenance
'FLEXR' and 'FLEXR Plus' computer software programmes have been
provided. 'FLEXR' is used for initial settings of OLTEs of fibre
optic network. Similar to microwave NMS, 'FLEXR Plus' helps in
remote diagnosis, operation and maintenance of fibre optic network.
For complete communication control system, a NMS100 system has
installed at NRLDC, New Delhi, which is in position to diagnose
faults of whole northern region.OPGW has been manufactured by
Farukawa, Japan. They have done replacement work, on live (hot)
lines, by using a unique installation technology. The OPGW in our
system has got twelve (12) 'Dual Window Single Mode' (DWSM) type
fibres in it. Optical signals of 1310 or 1550 nanometer (nm)
wavelength are being used. Only two fibres are required for a
multi-channel link between two stations. One fibre is used for
transmitting optical signal and second for receiving from other
end. In our system two fibres have been used for 'Normal'
communication path and two fibres for 'protection' path. Fibre
optic communication system has got a wide bandwidth transmission
capability. Two fibres are sufficient for providing more than one
lakh telephone channels on both sides. As such, a high-speed data,
containing large volumes of information can be transmitted at low
cost.Power Line Carrier Communication SystemPower Line Carrier
Communication (PLCC) is a single channel communication system in
which its channel (300 to 3400 Hz) is divided into two parts i.e.
speech band is generally kept 300 to 2400Hz or 300 to 2000Hz and
rest is used as data band. Due to narrow speech band in PLCC, voice
of poor quality is available in comparison to wideband
communication system. In this system, signal travels on the
transmission line from one end to other end. Transmitter output
(Radio Frequency signal) is fed to the transmission line through a
Coupling Capacitor or CVT. RF power output is in frequency band
from 70 KHz to 500 KHz. Inductors, called 'Wave Traps' are used at
the ends of the signals. PLCC is also used for line protection
signal. Protection signals are transmitted through PLCC system for
tripping circuit breaker of other end of transmission line. UPPTCL
has a wide network of PLCC links. Presently, its number of PLCC
links are about 550.B) SCADA SYSTEMIn SCADA system measured values,
i.e. analogue (measured value) data (MW, MVAR, V, Hz Transformer
tap position), and Open/Closed status information, i.e. digital
data (Circuit Breakers/Isolators position i.e. on/off status), are
transmitted through telecommunication channels to respective
sub-LDCs. For this purpose Remote Terminal Units (RTUs) at 400KV,
220KV and few important 132KV sub-stations have been installed.
System values & status information below 132 KV have not been
picked up for data transmission, except for 33KV Bus isolator
position and LV side of generators. Secondary side of Current
Transformers (CT) and Potential Transformer (PT) are connected with
'Transducers'. The output of transducers is available in dc current
form (in the range of 4mA to 20mA). Analogue to digital converter
converts this current into binary pulses. Different inputs are
interleaved in a sequential form and are fed into the CPU of the
RTU. The output of RTU, containing information in the form of
digital pulses, is sent to subLDC through communication links.
Depending upon the type of communication link, the output of RTU is
connected, directly or through Modem, with the communication
equipment. At subLDC end, data received from RTU is fed into the
data servers. In general, a SCADA system consists of a database,
displays and supporting programmes. In UPPTCL, subLDCs use all
major functional areas of SCADA except the 'Supervisory
Control/Command' function. The brief overview of major 'functional
areas' of SCADA system is as below:1. Communications - Sub-LDC's
computer communicates with all RTU stations under its control,
through a communication system. RTU polling, message formatting,
polynomial checking and message retransmission on failure are the
activities of 'Communications' functional area.2. Data Processing -
After receipt of data through communication system it is processed.
Data process function has three sub-functions i.e. (i)
Measurements, (ii) Counters and (iii) Indications. 'Measurements'
retrieved from a RTU are converted to engineering units and
linearised, if necessary. The measurement are then placed in
database and are checked against various limits which if exceeded
generate high or low limit alarms. The system has been set-up to
collect 'Counters' at regular intervals: typically 5 or 10 minutes.
At the end of the hour the units is transferred into appropriate
hour slot in a 24-hour archive/history. 'Indications' are
associated with status changes and protection. For those statuses
that are not classified as 'alarms', logs the change on the
appropriate printer and also enter it into a cyclic event list. For
those statuses, which are defined as an 'alarms' and the indication
goes into alarm, an entry is made into the appropriate alarm list,
as well as in the event list and an audible alarm is generated in
the sub-LDC.3. Alarm/Event Logging - The alarm and event logging
facilities are used by SCADA data processing system. Alarms are
grouped into different categories and are given different
priorities. Quality codes are assigned to the recently received
data for any 'limit violation' and 'status changes'. Alarms are
acknowledged from single line diagram (or alarm lists) on display
terminal in LDCs.4. Manual Entry - There is a provision of manual
entry of measured values, counters and indications for the
important sub-station/powerhouse, which are uncovered by an RTU or
some problem is going on in its RTU, equipment, communication path,
etc.5. Averaging of Measured Values - As an option, the SCADA
system supports averaging of all analogue measurements. Typically,
the averaging of measured values over a period of 15 minutes is
stored to provide 24 hours trend.6. Historical Data Recording (HDR)
- The HDR, i.e. 'archive', subsystem maintains a history of
selected system parameters over a period of time. These are sampled
at a pre-selected interval and are placed in historical database.
At the end of the day, the data is saved for later analysis and for
report generation.7. Interactive Database Generation - Facilities
have been provided in such a way that an off-line copy of the SCADA
database can be modified allowing the addition of new RTUs, pickup
points and communication channels.8. Supervisory Control/Remote
Command - This function enables the issue of 'remote control'
commands to the sub-station/powerhouse equipment e.g. circuit
breaker trip command. Though, there is provision of this function
in this system, yet it is not used in U.P. As such,
related/associated equipment have not been ordered.9. Fail-over - A
'Fail-over' subsystem is also provided to secure and maintain a
database of devices and their backups. The state of the device is
maintained indicating whether it is 'on-line' or 'failed'. There is
a 'backup' system, which maintains database on a backup computer
and the system is duplicated.SLDC Lucknow has a large and active
'Mimic Board' in its Control room. This mimic board displays single
line diagram of intra State transmission system i.e. grid network
of 400KV, 220KV and important 132KV sub-stations, transmission
lines, thermal & hydro powerhouses. Outgoing feeders, shown in
the mimic board, have 'achieve' (LED display) colored indications,
of three different colors, to show the range of power flow at any
moment i.e. 'Normal', 'Nominal' or 'Maximum' of its line capacity.
UPPTCL's transmission network is expanding rapidly and thereby
number of RTUs is also increasing. For new substations and lines,
displays in active and passive forms are required to be made in the
Mimic diagram. But, Mimic Board has a limitation that it cannot
incorporate/add large volume of displays for substations/power
houses/transmission lines in 'active' form due to space constraint
and congestion. Due to this Mimic Board is going to be supplemented
with a Video Projection System (VPS) at SLDC, Lucknow in near
future. Also in SLDC & subLDCs, displays of single line
diagrams of RTU sub-stations/power house are viewed on VDUs of
large size (21").C) ENERGY MANAGEMENT SYSTEM (EMS)For energy
management of the power system, control personnel and application
software engineers use SCADA data available in the database by
using EMS software. The software functions are based on the Energy
Management Platform (EMP). All servers have 'Open VMS' operating
system. All Personal Computers (PCs) have 'Window NT' operating
system. Important features are as below:1. The Data Base Compiler
provides a consistent source of data usable for the applications in
an efficient form. The Data Base Compiler does final checking for
completeness and consistency of the entries for a specific
application and prepares those special tables which are needed for
the efficiency of specific application programmes.2. Recording of
'Sequence of Events' (SOEs) is the most innovative feature provided
in this system. A RTU has the ability to accurately time tag status
change and report this information to sub-LDC. All RTUs in the
system are 'time synchronised' with the master station. Global
Positioning System (GPS) system has been used at all subLDCs &
SLDC. In the event of any tripping, sequence of events can be well
established on time scale with a resolution of 10 milliseconds.3.
Normally, 'Automatic Generation Control' (AGC) function issues
control commands to generating plants using the concept of Area
Control Error (ARE). It is base on deviations in 'standard
frequency (50 Hz)' and 'scheduled area interchanges' from that of
the 'actual frequency' and 'actual area interchanges'. The scope of
AGC function for UPPTCL has been limited to open loop operation
i.e. the software provides the desired corrective actions for each
plant, but the actual command are not issued. It is left to 'System
Control Officer' to take necessary action as divided by AGC
Controller. In the event of unavailability of sufficient generation
to satisfy the AGC requirement, the System Control Officer can
enforce required quantum of load shedding.4. For 'Operation
Scheduling' the application software has 'short-term' and
'long-term' 'System Load Forecasting' functions to assist
dispatching Engineer/control Officer in estimating the loads that
are expected to exist for one to several days in advance. This
function provides a scientific and logical way of scheduling of
resources in a very effective manner. Under 'Short-term Load
Forecasting' function, application software engineers are able to
forecast weekly peak demands and load duration curves for several
months into the future. Under 'Long-Term Load Forecasting'
function, forecasting of monthly peak demands and load duration
curves for several years into the future can done for the use of
'Power System Planner'.5. The other functions like economic
dispatch, reserve monitoring, production costing, inter system
transactions scheduling, etc. are available to guide System Control
Officer to optimally use available resources.6. Power System
Control Officer/Analyst would be able to use contingency analysis
function to assess the impact of specified contingencies that would
cause line (s) overloads, abnormal voltages, and reactive limit
violations.7. The EMS software system may have many other
applications for use, which include network topology, performing of
state estimation, optimal power flow (OPW) programme, stability
programme, power flow displays, help and instructional displays,
tabular displays, single line diagram displays, etc.LIST OF
MICROWAVE STATIONS OF UPPTCLS.N.Name of Microwave stationLocation
DistrictTower Height (m)Type (Channel Dropping/ Repeater
1PipriHydro Power Station RihandSonebhadra60Dropping
2DallaNear Dalla Cement FactorySonebhadra 100Repeater
3ObraThermal Power House ObraSonebhadra30Dropping
4Robertsganj132KV substation Robertsganj110Dropping
5Marihan33KV substation MarihanMirzapur110Repeater
6Mirzapur132KV substation MirzapurMirzapur100Dropping
7Chunar132KV substation ChunarMirzapur70 Repeater
8Sahupuri220KV substation SahupuriChandauli80Dropping
9Handia132KV substation HandiaAllahabad90Repeater
10Allahabad132KV substation Rewa RoadAllahabad80Dropping
11Mauaimma33KV substation MauaimmaAllahabad90Repeater
12Ramganj33KV substation SultanpurSultanpur110Repeater
13Sultanpur400KV substation SultanpurSultanpur35Dropping
14Gauriganj3KV substation GauriganjSultanpur100Repeater
15Raibareli132KV substation RaibareliRaibareli100Repeater
16Samesi33KV substation SamesiLucknow80Repeater
17LucknowShakti Bhawan, LucknowLucknow100Dropping
18Sarojininagar40KV substation
SarojininagarLucknow30Dropping
19Ajgain33KV substation AjgainUnnao80Repeater
20Panki400KV substation PankiKanpur100Dropping
21Bilhaur33KV substation BilhaurKanpur Dehat90Repeater
22Gurshaiganj33KV GurshaiganjKannoj110Repeater
23Nibkharori132KV substation NibkaroriFarrukhabad60Repeater
24Mainpuri220KV substation MainpuriMainpuri110Dropping
25Etah132KV substation EtahEtah110Dropping
26Sikandrarao132KV substation SikandraraoHathras70Repeater
27HarduaganjThermal Power Stn. HarduaganjAligarh100Dropping
28Khurja220KV substation KhurjaBulandshahar80Dropping
29Gulawati132KV substation GulawatiBulandshahar60Repeater
30Muradnagar-II220KV substation
MuradnagarGhaziabad100Dropping
31Muradnagar-I400KV substation MuradnagarGhaziabad30Dropping
32Modipuram220KV substation ModipuramMeerut60Dropping
33Nara220KV substation NaraMuzaffarnagar100Dropping
