SCADA SYSTEM IN VISAKHAPATNAM STEEL
PLANT
A Project report submitted in partial
fulfillment of the requirements for the
award of
Bachelor of Technology
In
Electronics and communication
Engineering
Submitted by
K.S.GAYATRI R.ARUNA
SHEIK NAGOOR MEERAVALI
Y.VENKATA RAMANA Y.ARUNA
KUMAR
Under the Guidance of
B.KRUPANANDAM
Manager(Telecom)
Visakhapatnam Steel Plant
Visakhapatnam
ST.THERESSA INSTITUTE OF ENGINEERING AND TECHNOLOGY
(Affiliated to JNTU)
GARIVIDI
CERTIFICATE
This is to certify that the Project work entitled “ SCADA system in
VSP” is a bonafide record of work done by Y.Venakta Ramana,
K.S.Gayatri, Shaik Nagoor Meera Vali, R.Aruna and Y.Aruna Kumar,
students of St.Theressa Institute of Engineering and Technology, Garividi
have been sincere, dedicated and the conduct throughout the study has been
excellent in partial fulfillment of the requirement for the award of degree in
BACHELOR OF TECHNOLOGY under the guidance and supervision in
VISAKHAPATNAM STEEL PLANT.
Visakhapatnam Signature of Guide
Date :
ACKNOWLEDGEMENT
We hereby take this opportunity to express our sincere gratitude to the
following eminent personalities whose aid and advice helped us to complete
this project work successfully without any difficulty.
We are thankful to Mr. B.Krupanandam, Manager (Telecom) who has
been with us all through the project to spend his valuable time and to share
his knowledge.
As a token of our feeling, we would like to acknowledge our sincere
regards to our internal guide Mr. B. Vijaya Bhaskar Rao and our HOD Mr.
B.Rajesh Kumar, for allowing us to take up a project in a working plant we
express our gratitude to Sri.V.V.Narayana Murthy (Principal) STIET and
Sri. M.Sreenivasa Rao (Correspondent), for their cooperation during the
project period. We are also thankful to faculty members for their kind
cooperation and assistance.
INDEX
Abstract
Major Department of Visakhapatnam Steel Plant
Different Communication Systems in Visakhapatnam Steel
Plant
Introduction
Supervisory control and data acquisition system -
Architecture
Remote telemetry unit (RTU) – Block Diagrams
Modems
Cables
Master Station
Power supply requirements and specifications
Software
Conclusion
ABSTRACT
In this modern world of Industrialization and automation, energy
plays a major role in the growth of any organization. The utilization of
energy plays an impacting and direct role in the growth of organizations like
Visakhapatnam Steel Plant.
In Vizag Steel Plant, there is a supervisory control and data
acquisition system (SCADA) present for monitoring of energy networks
which are present through out the plant. The objective of this proposed
SCADA system is to monitor the energy usage and demands of various
consumers of the plant and exercise effective control over their energy
consumption optimum utilization of in-house energy resources.
In this modern world of competition, the technology is changing very
rapidly. To compete with the changes and to sustain the development,
Visakhapatnam Steel Plant is going for upgradation of its existing SCADA
system with the latest state of art – technology with the features like using
high speed processors having cache – memory and using the powerful unix
based OS.
This project makes a brief study of existing “SCADA” system present
in Visakhapatnam Steel Plant and the changes that are going to come to in
the proposed SCADA system that is to be installed in the near future.
GROWTH AND IMPORTANCE OF STEEL
INDUSTRY IN INDIA
Steel comprises one of the most important inputs in all sectors of economy. Steel
industry is both a basic core industry. The economy if any depends on strong base of iron
and steel industry in that nation. History has shown base of iron and steel industry in that
nation.
History has shown that countries having a string potentiality for iron and steel
production have played a prominent role in the advancement of civilization in the world.
Steel is such a versatile commodity that every object we see in our day to day life has
used steel either directly or indirectly.
However its use is innumerable to mention a few, it is used for such small items as
nails, pins, needles, etc., through surgical instruments, agricultural implements, ships,
boilers, frigates, railway materials, automobile parts etc., the great investment that has
gone in to the fundamental research in iron and steel technology has helped both directly
and indirectly many modern fields of today's civilization without steel. Steel is versatile
and indispensable item. The versatility of steel can be traced to mainly three reasons:
It is the only material item, which can be conveniently produced in tonnage
quantities.
It has got very good strength coupled with ductility and malleability.
Its property can be changed over a wide range.
It alloys easily with many of the common elements.
The properties can be manipulated to any extent by proper heat treatment
techniques.
Taking these factors in to consideration, it can be said without committing a
serious error, that the types of steel available are innumerable.
"Visakhapatnam steel plant is an integrated steel plant."
CHARACTERISTICS OF INTEGRATED STEEL PLANT:
This integrated steel plant has large capacities, highly capital intensive, labour
intensive and they would have all facilities including raw material resources, water
supply, power supply, testing and inspection facilities, township facilities, medical,
educational recreational etc., all under one administrative control. This would reduce
the extent of dependency on outside agencies, which would help the smooth running of
the plant.
TECHNOLOGY IN STEEL PLANT:
Visakhapatnam steel plant is the most sophisticated and modern integrated steel plant
in the country. Modern technology has been adapted in the many areas of production,
some of them for the first time in the country, among these are :
Selective crushing of coal.
Evenching of coke
Conveyor charging and bell less top for blast furnace.
100% continous casting of liquid steel.
Gas expansion turbine for power generation utilizing blast furnace top gas pressure.
Hot metal desulphurization.
Etensive treatment facilities for effluents for ensuring proper environment protection.
Computerization for process control.
Sophisticated, high speech and high production rolling mills.
HALL OF FAME:
Visakhapatnam steel plant has the distinction to be first integrated steel plant in
India to become a fully ISO9002 certified company. The certificate covers the quality
systems of all operational, maintenance, service units. Besides purchase systems,
training and marketing functions spreading over regional marketing offices,20 branch
offices and 22 stock yards located all over the country.
Visakhapatnam steel plant by successfully installing and operating efficiency
Rs.480 crores worth of pollution control and environment equipments and converting
barrel landscape by planting more than three million plants has made the steel plant
township and surroundings in to heaven of greenery.
Visakhapatnam steel plant exports quality pig iron and steel products to Srilanka,
Myanmar,Nepal, Middle East ,USA and South East areas.RINL- Visakhapatnam steel
plant was awarded "STAR TRADING HOUSE" status during 1997-2000. Having
establishing a fairly dependable export market.
Having a total man power of 17250 Visakhapatnam steel plant has envisaged a
labour productivity not less than 230 tonnes of liquid steel per man, which is the best in
the country and is comparable with the international levels.
MAJOR DEPARTMENTS OF
VISAKHAPATNAM STEEL PLANT
RAW MATERIAL HANDLING PLANT(RMHP):
The RMHP receives the basic materials required for the steel making process from
various sources through wagons which are stacked and reclaimed by stackerd and
reclaimed by stackers-cum reclaimers and distributed to various departments of
Visakhapatnam steel plant through conveyor systems.
COKE OVENS (CO):
Coke is a hard, porous mass obtained by fractional distillation of coal in the absence
of air at a temperature above 200deg.centigrade for period of 16 hrs to 18 hrs. It is used
as a fuel and reducing agent of iron ore in blast furnace. Three coke oven batteries for
production of 2.26 MT dry coke, each with 7 meters tall 67 ovens. Each battery is
provided with facilities for dry cooling of coke using nitrogen as quenching media for dry
cooling of coke as well as for recovering sensible heat of coke. As a by-product a CO
gas is produced in this processes and this gas is having a very high calorific value for
about 2400-2700KCAl and is produced throughout the plant as a fuel.
SINTER PLANT:
Sintering is one of the most widely used and economic agglomeration techniques.
Sinter is a hard and porous lump obtained by agglomeration of fines of iron ore, coke,
limestone , and metallurgical waste. Sinter increases the productivity of blast furnace,
improves the quality of pig iron and decreases the consumption of coke rate. Two 312
square meter sinter machines with 420 square meter straight stand type coolers for annual
production of 5.26 MT sinter.
BLAST FURNACE(BF):
Pig iron or hot metal is produced in the Blast Furnace. The furnace is named as
BF as it is run with blast at high temperature and pressure of 1500 deg. C. Raw materials
required for pig iron and iron are iron making ore, sinter, coke, and lime stone. There are
two 3200 cubic meter blast furnace to meet 3.0 MT annual metal requirement. Each
furnace is designed for 205 at mg top pressure, and will be belt charged and equipped
with bell-less Paul-wurth top. Each furnace is provided with a set of four hot blast
furnace stoves designed for supplying air blast up to 1300 deg.C. Three turbo
blowers ,one for each furnace and one stand by common to both furnaces are provided
with 12 MW top pressure recovery turbo generating power. BF gas is produced from
each furnace is being cleaned in gas cleaning plant comprising dust catcher, high pressure
scrubber and is distributed through out the plant as a fuel.
STEEL MELT SHOP(SMS):
Steel is an alloy iron and carbon ,where carbon should be less than 2%.Hot metal
produced in B.F contains impurities like carbon, sulphur, phosphorous, silicon etc., these
impurities will be removed in steel making by oxidation process. These are the three L.D
convertors to convert hot metal in to steel. The steel melt shop complex comprising two
1300-ton hot metal mixers, three 130-ton LD converters (two operating) and six 4-stand
bloom casters. Each converter is being provided with gas cleaning plant for cleaning and
recovery of LD gas, which will be used as fuel in plant.
ROLLING MILLS(RM):
Blooms cannot be used as they are in daily like. These blooms have to be reduced
in size and properly shaped to fit for various jobs. Rolling is one of the mechanical
processes to reduce large size sections in to smaller ones. The cast blooms from CCM
are heated and rolled in to long products of different specifications like high capacity,
sophisticated high-speed rolling mills. The rolling mill complex comprises :
Light and medium merchant mill (LMMM)
Wire rod mill (WRM)
Medium merchant and structured mill (MMSM).
Each mill is well equipped with required number of walking beam furnaces for
heating of walking beam furnaces for heating of blooms or billets and except for wire rod
mills, each furnace is provided with evaporative cooling system for generation of steel for
plant consumption.
THERMAL POWER PLANT(TPP):
The estimated power requirement for V.S.P in 280 at 3.0 MT stages, the peak
load being 292 MW essential loads being 49 MW. The generating capacities 286.5
MW. A captive power having 3*60 MW turbo-generator sets and 5*330 ton/hr steam
generators. In this plant, 6000 Nm^3/min turbo blowers are being provided for supplying
cold air blast furnaces.
TYPES OF COMMUNICATION EQUIPMENT AVAILABLE
In this modern age of industrialization telecommunications plays a very important
role in coordinating the activities of various departments / sections and in achieving the
set targets and also in improving the performance of any organization. In Visakhapatnam
Steel Plant, different types of communication systems are being used to meet the internal
and external communication needs. These are broadly classified as follow:
a. General purpose communication systems.
b. Process communication systems.
c. Monitoring & Signaling Systems.
GENERAL PURPOSE COMMUNICATION SYSTEMS :
The following facilities are provided under category of general purpose communication
systems:
3000 lines Electronic Exchange in Plant.
2000 lines Electronic Exchange in Township.
100 lines Electronic Exchange in Visakha Steel General Hospital.
44 lines Electronic exchange in Hill Top Guest House.
2500 Lines Electronic Exchange of Bharat Sanchar Nigam ltd (BSNL) in Project
Office is catering to the needs of Plant area and Sectors-I to VII in township.
Another 2000 Lines Electronic Exchange of Bharat Sanchar Nigam ltd (BSNL) in
Township is catering to the needs of Sectors-VIII to XI in Township.
The 3000 Lines electronic exchange in plant and 2000 lines exchange in township
are having the following facilities:
Extension (subscriber) to extension call, Auto call back, Hot lines, Music on hold,
Reminder Alarm, Automatic line testing facility, Faults man ring back, Call consult
facility, Malicious call tracing facility, 3 party conference Facility and Howler Tone alert
etc.
All exchanges working in the steel plant are interconnected by means of junction
lines and have closed numbering scheme. For communicating with any subscriber of any
exchange no extra digits have to be dialed and only the desired number is to be dialed. –
connection pattern given at fig 1.
The 2000 lines exchange in township is interconnected to the BSNL network. Due
to this interconnection all the subscribers of this exchange can receive incoming calls
from any part of the world. A few subscribers are provided with facility to contact
subscribers connected to the BSNL network and cellular and mobile phones in and
around Visakhapatnam.
PROCESS COMMUNICATION SYSTEMS :
To facilitate coordination, operation & management activities of production,
maintenance & service departments, the following process communication systems are
provided:
a) Despatcher communication system
b) Loudspeaker intercom systems
c) Loudspeaker broadcasting systems
d) Loudspeaker conference communication system
e) Industrial public address system
f) Hotline communication systems
g) VHF communication systems
A) DESPATCHER COMMUNICATION SYSTEMS:
Initially cordless switch board type manual exchanges of electromechanical
version were provided. Since manufacture of such systems and their spares is
discontinued in the country, these despatcher systems are being replaced by Electronic
exchanges progressively. Except the ones in CCCP other systems have been replaced.
These would also be replaced very soon.
Production coordination at plant level being conducted by ED (Works) with all
HODs in the morning every day is facilitated with the help of the digital EXCOM system
provided in the plant control room.
B) LOUDSPEAKER INTERCOM SYSTEMS:
Loudspeaker intercom systems are working LMMM & WRM. These systems are
used for communication between various sections of the same production shop.
Communication is made possible using microphones and loudspeakers provided in the
subscriber stations. This system is very useful in noisy environment where conventional
telephones are ineffective. This system helps to establish communication between any
two stations having interconnectivity on selection basis. By using group call facility it is
possible to communicate to all the subscribers in the group at a time.
c) LOUDSPEAKER BROADCASTING SYSTEMS:
Loudspeaker broad casting systems are provided in C&CCD, BF, SP and SMS
departments. This system is useful to make general announcements to the entire area of
working and so can be used to locate operation / maintenance personnel working on the
shop-floor so as to pass-on important instructions from the control room.
D) LOUDSPEAKER CONFERENCE COMMUNICATION SYSTEMS:
Loudspeaker conference communication systems is working in CCCP. These
systems are provided with both paging and private channel communication facilities. In
case of paging a general announcement can be made which is heard on all the stations. In
the private mode communication is possible between two selected stations only. Here
also communication is carried out by means of microphones and loudspeakers provided
in the subscriber stations.
E) INDUSTRIAL PUBLIC ADDRESS SYSTEM:
Industrial Public Address System is working in TPP. It is a combination of
loudspeaker broadcasting system and conference communication system. From the main
control room it is possible to make announcements which are heard on the shop-floor.
From certain locations the communication can also be established through handsets in
private mode with the main control room.
F) HOTLINE COMMUNICATION SYSTEMS:
To ensure direct telephone communication between closely related critical
locations hot lines are provided. By using the hot lines specified locations are connected
permanently. Communication is possible only between these two locations. When one
subscriber lifts his telephone the other will immediately get a ring and communication
can be had without any loss of time. This is useful to pass-on urgent messages. These hot
lines are initially provided with direct line communication systems which are electro
mechanical systems. Due to obsolescence electronic systems are now being used for most
of the locations. Hot lines are working in CCCP, BF,SMS, LMMM, WRM, MMSM,
TPP, PPM, DNW and WMD departments.
G) VHF COMMUNICATION SYSTEMS:
VHF communication systems are used in our plant to establish two way
communication between two or more when either or one of them is moving. There are
three models working in our plant. They are hand-held units (walkie-talkie), vehicle
mounted – mobile units and base station units. Walkie-talkies are used by operation and
service personnel in almost all of the production shops. Vehicle mounted units are being
used by DNW, CISF (Fire) and CISF (security). Base station units are used by CISF
(fire), CISF (Security), Administration, DNW and largely by CCCP departments. In
CCCP these can be seen in pusher cars, charging cars, door extractors, electric locos,
lifters and CDCP area.
MONITORING AND SIGNALING SYSTEMS :
To facilitate monitoring production, maintenance & service activities, the following
monitoring and signaling systems are provided:
a) Closed Circuit Television Systems (CCTV):
b) Central fire alarm signaling system
c) SCADA system
d) Shift change Announcement Siren System
A) CLOSED CIRCUIT TELEVISION SYSTEMS (CCTV):
For monitoring critical operations in different production units continuously from the
concerned control rooms / pulpits CCTV systems are used in SP, BF, SMS, LMMM,
WRM and MMSM departments. CCTV system comprises of CCTV camera with a lens
and a CCTV monitor. In some cases a video switcher, a central control console, pan and
tilt head and zoom lens are also used. These are interconnected by means of control
cables and / or coaxial cables Necessary protection is provided for the CCTV equipment
depending on the locations where they are used
B) CENTRAL FIRE ALARM SIGNALING SYSTEM:
The central fire alarm system is provided for communicating the exact location of
outbreak of fire in any part of the steel plant complex to the central fire station and
simultaneous actuation of sirens to alert personnel of the affected plant zone. The system
employs manual call points located all over the plant.
c) SCADA SYSTEM :
To monitor the consumption of energy by various users in the plant SCADA system is
provided. This is placed at Energy and Telecom centre. The system comprises of a master
station equipment with supervisory consoles and mimic panels located in the Energy &
Telecom Building, 23 Nos Remote Telemetry Units (RTUs) installed in different plant
units and 3 local RTUs for driving the mimic panel in the Energy centre. The RTUs will
be collecting the signals from the local instrumentation & electrical systems and
transmitting to the master station by means of RTUs. The RTUs are connected to the
master station by under ground telephone cables.
D) SHIFT CHANGE ANNOUNCEMENT SIREN SYSTEM:
The shift change announcement siren system is provided for ensuring uniform and
accurate shift timings throughout the plant. This system consists of two(2) nos quartz
crystal controlled master clocks in the Energy & Telecom Centre. The shift timings are
programmed in the Master Clock. At the specified time, the signal will be transmitted for
energizing the sirens located at strategic points in plant area simultaneously at the preset
timings.
Apart from the above facilities Telecom department maintains the following cable
networks also
a) DATACOM cable network in plant
b) Telephone cable network in plant and township
INTRODUCTION
Acronym for supervisory control and data acquisition, a computer system for
gathering and analyzing real time data. SCADA systems are used to monitor and control
a plant or equipment in industries such as telecommunications, water and waste control,
energy, oil and gas refining and transportation. A SCADA system gathers information,
such as where a leak on a pipeline has occurred, transfers the information back to a
central site, alerting the home station that the leak has occurred, carrying out necessary
analysis and control, such as determining if the leak is critical, and displaying the
information in a logical and organized fashion. SCADA systems can be relatively simple,
such as one that monitors environmental conditions of a small office building, or
incredibly complex, such as a system that monitors all the activity in a nuclear power
plant or the activity of a municipal water system.
SCADA systems were first used in the 1960s.
CENTRAL SUPERVISORY CONTROL AND DATA ACQUISITION
SYSTEMS :
The system comprises of Micro VAX ll based Master station equipment with
supervisory controls and mimic panels located in the energy and telecom building
and 23 RTUs installed in different plant units and 3 local RTUs for driving the mimic
panel in the energy centre . The RTUs will be connecting in the signals from the
instrumentation and electrical systems and transmitting to the Master station when
polled by the latter. The RTUs are connected to the master station by under ground tele
phone cables . Supervisory controls are also provided in MRS & EMD departments in
area shop office of utilities .
The system enables continuous monitoring of the energy networks in the steel
plant and generation of reports as required for taking strategic decisions in times of
crisis . The maintenance of RTUs mimic panel and the cable network between the
field / local RTUs & modem panel in the Master station is carried out by the telecom
department .
The signals for a plant unit will normally be concentrated in the control room
of the unit from where the unit is being operated . RTUs of the CSCS will be in
stalled in these main control rooms and the tele -- transmission signals identified for
the units will be wired to the RTUs . The RTU are called as Remote terminal /
telemetry units.
The RTUs are micro processor based intelligent units , responsible for
Acquisition of inputs from the plant units and convert them in to digital code for Tele
-- transmission to the Master station computer of CSCS through the 5 pair telephone
cable . Some plant unit where few signals are available for tele – transmission , A
junction box will be installed in the control room ( instead of an RTUs) for the
termination of inputs and these inputs are furthur connected to the nearest RTUs
through the multi – core control cables.
The system consists of computer based Master station with dual hot Stand
by computers . The peripherals like terminals , printers , communication Ports etc…
which are common requirements for the computer system are Connected through a
peripheral transfer switch ( PTS ) to the computers . The 23 RTU s are located in
different parts of the plant are connected to the center Master station through modems
in a multi dropped fusion to different channels Of communication controller . The
Master station located in the Central Dispatcher station ( C D S ) of the
Visakhapatnam steel plant will acquire all Information through RTU and
communication controller module ( CCM ) and Process the information for displays
and report generation .
The SCADA system shall acquire various electrical & utility parameters for
effective monitoring & control operation . The various parameters acquired shall be
such as electric power , voltages , currents , etc… under electrical monitoring and
parameters such as flows , temperatures, pressures , etc … for operation and
functional convenience the system categorized in to 2 following systems.
Utility systems
Electrical systems
UTILITY SYSTEMS :
The utility system covers the services like fuel , gases , stream , comprised
air, water etc…. The services covered by the utility systems of CSCS are
broadly classified in to following groups.
Fuel gases system : CO, BF ,Mixed & converter gases.
Process gas system : Nitrogen, Oxygen ,Argon, Acetylene.
Stream Distribution system: Stream at 40 KSCG,13 KSCG.
ivCompressed air system: Compressed air and instrumentation grade air
Chilled water system: Chilled water.
Fuel oil system : LSHS,LDO and LTF.
Water systens: make up water, fire and drinking water.
ELECTRICALSYSTEM
The electrical system covers the complete electrical distribution network
Inside the Visakhapatnam steel plant like 220 KV ,11 KV, 6.6 KV systems in
MRS, LBSS , 1, 2 , 3 , 4 and 5 , LBDSS , HVLCS and HUMCCS.
For centralized super visory of above services in utility and electrical systems
and also to exercise control over their optimum utilization ,following types of signals are
considered for the uses .
Analog input (AI)
Digital input (DI)
Analog output(AO)
Digital output (DO)
Pulse input (PI)
The input signals acquired by the RTUs are tele-transmitted to the Master station
and are sorted out according to the above subsystem division i.e utility and electrical. The
MS is provided with separate operator stations for utility &electrical system for
independent operations.
SCADA systems monitors a total no 5000 different signals originating at
different dept in VSP. Among these 5000 signals 1500 signals are catered to monitor
utility system and 3500 signals are electrical system.
The CSCS MS hard ware comprising of Micro computer, Peripheral devices
like operator stations, printers & power suppl unit like U P S , batteries, distribution
board will be housed in the second floor of the CDS building where separate rooms with
A.C facilities are provide in VSP.false flooring is provided for inter connection cables.
Full graphic type of mosaic wall boards one for utility system and another for
electrical system displaying the distribution network of various services and power flow
inside the VSP envisaged. The wall boards are located in thr main control room of the
supervisory center where the operator consoleof the CSCS is located.
There are interconnecting cables between
# RTU and the MS.
# Junction box and the RTU.
# Remote video terminals and MS.
Modems are provided for both th ends of communication link for inter
connection of Remotely placed units to the MS.These are placed to make up the cost
potential in the line .
Software in the Ms is also required to meet all the functional requirements such
as data acquisition,display, reporting ,trending ,performing application programs etc….
The maintenance of RTUs mimic panel and cable network between the field /
local RTUs and the modem panel in the MS is carried out by the telecom dept.
REMOTE TELEMETRY UNIT (RTU)
The micro processor based RTU s are installed at various plant Units.
The RTUs will be collecting the signals from the local Instrumentation &
Electrical systems and transmit to the MS when they are polled by the latter.
The RTUs are connected to the MS by under ground telephone
cables with ac MODEMS at MS end and dc MODEMS at RTU end.
OUTSTATION RTU HARDWARE:
The RTU H/W has the following contents:
(1) RTU cabinet
(2) Gland plates / field cables
(3) Terminations and interprosing relays
(4) Basic Tier
(5) I/O Tier
(6) Power Supply Arrangements
(7) Basic Modules
(8) I/O Modules
(9) RTU I/O configuration
RTU CABINET :
The RTUs are houses in standard fabricated steel cabinets of Rugged
construction.
The RTU cabinet has an internal structure for:
# Routing the field cable to the terminations.
# Mounting the terminations and interprosing relays.
# Routing the I/O cables from the termination and
interposing relays to the electronic tires.
# Mounting the electronics comprising PCCs fitted in tires.
# Mounting the Power supply unit for providing the logic supplies
to all cards.
The genrnal layout of the RTU cabinet is attached.
A signal cabinet can accommodate a basic tier and an I/O tier. If
further expansion requires two I/O tiers can be added.
GLAND PLATES / FIELD CABLES :
All external connections to the RTU enter the cabinet through Gland plates.
The external connections are communications connection, Power connection and
mainly the field cable connecting to the plant Instrumentation.
Termination & interposing relays :
The field cables entering the RTU are terminated on screwed
Terminals mounted on vertical rails. The interposing relays are plug in type and are
accommodated in power supply
cabinet installed adjacent to RTU cabinet.
The interposing relays are provided where the output control Logic
power is not sufficient to operate a high voltage and current Points.
The connections are made by standard multicore twisted paid Cables
and gold ribbon connectors.
Dia : Testing of in coming signals to RTU from field.
BASIC TIER :
The basic tier is fitted at the top of the cabinet . It houses
1. The basic cards comprising microprocessor card (MP 3) the Analog/Digital
converter (ADC 4) and the master control / test Cards (MCT 2).
2. Upto 8 input / output cards.
3. Power supply Adapter card to distribute the supplies to PCBs.
INPUT / OUTPUT TIER :
The input / output tier is fitted below the basic tier and can
Accommodate upto 19 input / output cards.
POWER SUPPLY ARRANGEMENTS :
All RTUs are provided with 230 KV AC operation. The RTU Power
supply unit operates on 24 V DC input and generates all logic Supplies +5V, +12V
and -12V required for the oprations of the RTU. The input 24 V DC is derived
from local mains power supply with a Battery back –up provisiopn with
maintenance free sealed lead acid batteries for 8 hours.
BASIC MODULES :
a) Micro Processor Module (MP 3) :-
The MP 3 is a signal printed circuit board designed for general Use in
telecontrol systems to provide intelligence at the out station, Master station front
end to the main computers telecontrol test Equipment and standby system
operation.
# The units is based on 8 bit Motarola M6800 micropocessor.
# The module incorporates a maximum of 8K bytes of PROM
and 4 K bytes RAM.
# The data acquisition, data processing, communication and
housekeeping information of the RTU are performed using
this module with memory.
# This card provides I /O bus catering to the I /O modules end
serial communication interface to modem for communication.
The logic requires the following supplies for a fully fitted card +5
at 2A, +12V at 0.3A and -12V at 0.15A.
# Facility has been provided for memory extension.
b) Master control test card ( MCT 2 ) :
# This module provides the number of RTU house keeping and
security checking functions.
# This card is degigned to fit a standard I / O card position.
# Main functions :
# Supply of powre to state control relays with local isolation
racllities.
# Generation of check logic pattern on a spection monitor
adderss.
# Generation of ADC calibration check reference voltage .
LEDs are provided to indicate controls.
Internal power required +12V at 28mA
+12V (HU) at 1mA
+15V (ISOL) at 1mA
External power required 24 V or 48 V.
c) Analog to digital conversion card ( ADC 4 ) :
This card provides successive approximation A / D converter which
Converts 1- 5 volts full scale into 11 bits plus sign digital value.
# This card is used to convert analog input signals into digital
binary data (2’s complement or unipolar or offset binary )
# Opto Isolater s -> to form a barrier between the floating
analog conversion side and an 8 bit moniter high way.
# Analog input are superimposed on common mode. Voltages
to be digitized. Maximum voltage is 50 V dc & value is –80 bd.
# A start conversion signal starts the ADS digitizing cycle and
resets the clock control at the end of conversion.
# When the cycle is complete, the digital data is transferred to
shift register and clocked out across the isolation barrier to a
second shift register. Then data transfer complete signal resets
the clock control and also generates an ADC interrupt / Resets
to indicate data is ready to transfer.
# The basic conversion time is 300ms.
# An ADC output enable signal enables the two- byte transfer
of digitized data on to the moniter highway .
First byte consists of 8 MSB bits includes sign bit ( if bipolar )
Second byte contains the 4 LSB bits.
I / O MODULES :
I/O module unit comprises of the following five I/O cards.
1. ANALOG INPUT MODULE (AMFS 3) :
The AMFS cardscales and filter 8 high level analog current or Voltage
input which are multipexed by relays on to a common output circuit .
# It accepts voltage or current input presented by the instrumentaion.
# The card multiplxexes 8 input to the ADC
# The card accepts either 4—20 m Amps or 1—5 Volts Signals .
# The card function address ( lower ) is set by switches or liens on
the card
# For an 8 bit A/D conversion 1 function adderss is required .
For more than 8 bit conversion 2 function adderss is required .
# In cases of Ms. 8 bits of each of 4 digitized values are allocated
byte position 0,2,4 and 6. The remainder of each value is placed
in the adjacent add byte.
# The card operates from a + 12 V source at 1mA .
( for CMOS Logic )
(2). STATE MONITER BARRIER ( SMB 11 ) :
The SMB 11 card provides an electrically isolated interface between 32
signal bit plant status inputs and an 8 bit monitor high way . Plant input is
typically a dry contract switching 24 volts ( negative ) to a filter , limiter and opto
isolators which gives 1500 volts plant to logic isolaction . The filter time constant
is nominally set to 10 mA . The current for each input is 5 mA and the 32 inputs
have a common positive return.
The card is addressred from a function highway and the 4 x 8 bit bytes
are selected by a slot highway . Function and addresses are set by switches or
links on the cards . When the card in addressed and strobed a card present
signal is generated .
The CMOS logic operates from a + 12 volt supply at 10 mA .
(3). STATE CONTROL BARRIER ( SCB 8 ) :
The SCB 8 provides 8 signal bite stae control output an 8 bit control
Highway . Electrical isolation is provided by the use of opto-isolators- ( 1500
volt isolated ) which provide an output of 100 mA at 24 V DC . An ‘on’ output
sinks into a common negative rail .
The card is addressed from an 8 bit function highway , the control
portion responding to four consecutive addresses each of which allows control
data to be latched in one or four 8 bit latches . Each 8 bit batch is associated with
a timer which will reset the controls after a pre--set time each opto—coupler
input is monitored using a signal monitor address along with the
appropriate slot address by a three ploe switch.
In each case the switches may be replaced by appropriate wire links .
Circuitry is provided to ensure that control security is maintained During
switch ON/OFF etc . These circuits are also associated with External control
allow and inhibit signals .
The CMOS logic operates from a 12 volt supply and requires 4 mA plus a
nominal 30 mA for each control energized .
(4). TOTALISER CARD ( TL 3 ) :
The TL 3 card count 4 independent pulse stream , in to 8 digit BCD
counters . Each total , 32 bits , can be read by the appropriate function address on
to the moniter highway in 4 byte each of 8 bits .
The card is addressed from an 8 bit function highway . which with A
strobe and slot address selects the appropriate total . each card Requires 2 or
4 function addresses . Switches are links on the card set
The lowest address when the correct funtion address is received a card present
signal is generated . Varlants of the card input pulses up to 50 V , and TTL
or variable level inputs . Each pulse stream has a maximum has a
maximum pulses of less than a duration set by the card variant .
Local reset is affected by 4 card mounted push buttons . Remote
Reset is provided is by the two LSB s on the control highway in
conjunction with current function address .
A fast count test facility , witch can be isolated by switches on the card , is
provided for each store .
The CMOS logic operates from 12 V supply at 8 mA , which may be Supplied
from external battery back up to hold the count when the Main supplies fail .
(5). ANALOG CONTROL ( AC 5 ) :
The AC 5 card stores and converts 8 bit digital word from a control
Highway in to current or voltage isolated outputs . Each card has four
independent D / A converters which provide the analog outputs when enabled
by the appropriate funtion address. The card has four consecutive control address ,
which are selected as a block by the 6 most significant switches or the card .
The card is addressed from a 8 bit function highway , which in
Conjunction with a strobe , allows the digital word on a control highway To be
read in and stored .
The stored outputs operate opto – electric devices which from an Isolating
barrier between the digital logic and the D / A converters . This
Allows the analog outputs to be operated from independent power
Supplies . The status of each store can be monitored via the Monitor Highway
on receipt of the appropriate function / slot address .
The latches can be powered from an independent 12 V hold up Supply
and during switch ON—OFF this supply the latches are set to give zero analog
output . This circuit is also associated with an external analog control inhibit
signal . A card present signal is indicated when the correct function is present .
The external load should be the range 250 — 500 ohms . The analog
output are isolated from the control logic and each other . The output circuits
required external isolated power supplies each of 24 V at 26 mA .The CMOS logic,
together with the op--to isolators ,operates from a 12 V at 1.2 mA when other supplies
are present and 2.2 mA when other supplies fail .
PRINCIPLES OF SYSTEM OPERATION :
The basic principle of this system of data transmission between the Master
Station ( MS ) and any particular RTU in either direction is time – division
multiplexing .
Where the MS has to communicate with a number of RTU’s
multidropped on a common communication circuit . this system normally uses
time — division multiplexing between RTU’s .This is achieved by use of the uniqe
outstation address encoded in the hardware of each RTU.
The basic of data transmission is the word . In interrogation mode the word
comprises two message , the interrogation message directed from MS to RTU s .
Each message comprises up to 32 bytes . The first byte contains RTU
addressing information . The second byte indicates message length. There then
follows a number of information and or status bytes and finally
A Bose - Chaudhury - Hoocquenhem ( BCH ) check character generated Over
the message using the generator polynomial .
X ^ 8 + X ^ 7 + X ^ 5 + X + 1
Each byte comprises a start bit ( logic zero ) eight data bits and byte
comprises A start bit (logic zero) , eight data bits and a stop bit (logic one ).
The Eight data bits are numberded 0 , least significant ( LS ) to 7 , most
Significant ( MS ) . Bit 0 is terminated to a serial communication channel first , bit
7 last .
INTERROGATION MODE WORD STRUCTURE:
Address byte: out station address.This is the unique address of the RTU being
interrogated.
Byte count Byte: this is the number of information bytes in the message.
Information bytes: function address and data bytes.These bytes may be used to transmit
information to the RTU, or to define which information to the RTU is to transmit back to
the MS.
Check byte: BCH code check.
Reply Message(13 bytes):
Address byte: outstation address. This is the repeat of the first byte of the interrogation
message.
Byte count byte: this is the number of information/status bytes in the massage.
Information bytes: function address and data where information has been transmitted to
the RTU ; these bytes are used as acknowledgement, which may include information
received by the RTU. When information is requested information is transmitted in these
bytes.
Status bytes: RTU status. This is a monitor of important RTU status conditions.
Check byte: BCH code check.
MODEMS
The multi-tech computers multi 748 A is a microprocessor controlled CCIT V.27
bits/tier compatable leased line modem. It can be operated at 2400 or 4800 baud, in either
two or four wire synchronous modes. Two-wire operation is only half duplex. The multi
modem 748 A incorporates fall back to 2400 baud when operating the V.27 internal DIP
switches, jumpers and modem commands control the mode of operation.
The multi modem 748 A uses 8 level DPSK modulation. The carrier frequencies are
1800 Hz at 4800 baud. The transmit level is adjustable from 0 DBm with the help of a
potentiometer given on the PCB. In asynchronous operation the character length is 10 bit.
The receiver sensitivity of the multi modem 748 A is 43 DBm.
Operation:
On power up or reset of the multi modem 748 A, the microprocessor reads the
operating parameters from either the DIP switch settings and ROM or if the user has told
options from RAM.
The speed switch on the front panel controls the speed of the data rate. The rate
of high and low speeds is determined by the mode of operation.
There are two blocks of DIP switches on the multi modem 748A circuit board
used for configuring various options. 8 positions and 4 positions DIP switch, are both
accessed from the bottom of the chassis.
INTERPOSING RELAYS
MODEMS :
PRESENT SYSTEM :
Presently the power supply (230 Volts AC) arrangement to the PSU and AC
modems (18 nos.), which are at MS, is taken from one breaker (5 Amps), which is in side
by system department room. This power supply is directly terminating in terminal strip
in loop as a loop out fashion. The PSU of AC modem is directly connected to another
side of the terminal strip. There is no ON / OFF control on PSU in order to do
maintenance or attend problem of PSU of AC modem. Working of AC modems are
intiable the functioning of CSCS. So in order attend complaint at power supply unit of
AC modem the main breaker has to switch off, which in turn causing total shut down of
CSCS.
PRESENT DIFFICULTIES:
The PSU arrangement to PSU of AC modems is in such a way that to attend the
complaint in one PSU of AC modem requires total shut down of CSCS does not permit
coordination and meeting the demands of the various in plant consumers and to exercise
effective control over their consumption for optimum utilization of energy resources.
More over permission for total shut down of CSCS is very lengthy process. The
main breaker, which is in systems department room, is not in convenient for maintenance
position.
PROPOSED SYSTEM :
In proposed system of power supply 230 AC arrangement to PSU of AC modems
has to take AC power supply from U.P.S and install one double pole, double breaker is
fed to 18 nos. of single pole breakers and output of breakers is connected to terminal
strip. At another side terminal strip it is connected to PSU neutral has to directly take
from double pole switch and it should connect to terminal strip directly in loop out put
fashion. All breakers should keep in one enclosed box and it should install nearby AC
modem rack. So while doing maintenance or attending problem in any PSU of any
modem it is easy maintenance people. Another important advantage is that avoids the
total shutdown of CSCS.
REQUIREMENTS :
To carry out the modification of the power supply arrangements to PSU and AC
modem of CSCS needs.
o One Double pole double switch
o Eighteen pole single switch.
o Eighteen, 50 mts multi strand
o Enclosures for installation of all these switches
o Locking arrangements
BENEFITS :
The modification in power supply arrangements to PSU of AC modems of CSCS
is mainly intended to increase the availability of system in generation.
This modification,
Eliminates the down time to total CSCS
Increases the optimum utilization of resources like fuel utilities and electric
power.
Helps in reducing specific energy consumption of steel.
Improvement in safety, quality of service
Ease in maintenance.
CABLES
Objective :
In both interrogation and broadcasting mode there is a continuous Transfer
of information between the RTU and the MS so there is a Necessity of a
physical medium to facilitate the flow of information
( Electrical Signal ) . Cables perform the job of interconnected the field
RTU’s and MS .
The inter connectig cables required for connecting various terminals Can be
clssified in to 3 categories and the technical specification of various cables are
also given below .
CATEGORY – I :
Telephone cables required for inter connection of RTU’s and the MS.
# 5Pair Petroleum jelly filled.
# Armored.
# Over all polythene packeted.
# Solid annealed high conductivity copper.
# Diameter 0.633mm.
# Resistance 57 ohm /KM.
CATEGORY-- II :
Twited pair cables rwquired for the inter connection of remote video
terminal to the master stations .
# 5Pair.
# Diameter 7/ 0.2 MM.
# Individually and over all shielded.
# Armored cables.
CATEGORY – III :
Control cables required for the inter connection of signals from plant units
and junction boxes to the RTU’s .
# Size 1.5 mm.
# Solid annealed copper conductor.
# Multi core control cable.
# Armored and unarmored.
# Thickness 0.8 mm.
# Resistance 12.1 ohm / KM.
# PVC Insulated.
The cables will be laid partly on cable trays in cable tunnels and
balance the directly buried under ground .
MASTER STATION
OBJECTIVE:
The Master Station located in the CDS building in VSP will acquire all
information through RTUs and CCMS and process the information for displays and
report generations which are very important at the times of crisis to take strategic
decisions.
The master station hardware comprises of the following:
Host computer Micro VAX II
Communication concentrator module(CCM)
S/3 intelligent colour console
Peripheral transfer switch (PTS)
DELNI
System Console
Magnetic tape subsystem
Hard disk subsystem
VT-320
Digitizer pad
Communication transfer switch
Common controller interface module
1. HOST COMPUTER:
The host computer is the main controlling element of the S/3 SCADA system. The
host contains the S/3 application S/W and is responsible for the bulk data storage
functions . The typical host consists of a computer unit ,tape and/or disk drives and alarm
types. The host computer is one of the Digital Equipment Corporations (DEC) VAX
family of general -purpose computers .
The VAX runs under VMS -Virtual Memory System operating system.
The S/3 application S/W runs under the direction of the VMS OS .All S/W
transportable from one VAX model to another, allowing host systems upgrades as the
application dictates .The current value from the RTU is sent to the host where it is used
to update a current value table CVT .The CVT is accessed by the color console S/W to
update value displays and by database access tasks. In addition the values from the CVT
are sent to the current trend , historical trend and achieve databases .
Redundant hosts are supported by the S/3 system. In redundant applications, both
hosts are updated with databases information and current values in order to
ensure a bump less transfer in the event or a system failure .
HOST COMPUTER OPTIONS:
There are several types of VAX computers available for the S/3 system.The size of the
computer is dependent on the actual S/3 system. Each VAX processor includes a CPU , a
memory management, Hardware, sixteen 32 bit internal general registers, 32 interrupt
priority levels and an I/O subsystem. External disk and tape devices augment processor
operation. The VAX features time sharing, virtual memory management, packed decimal,
fixed point and floating arithematic functions and a high precision programmable real
time clock.
1. Micro VAX ll :
The micro VAX is a small stand -alone micro computer system design system for
small S/3 system. The micro VAX contains Q-Bus based architecture with a 32 -bit
structure. The unit is supplied in a compact caster mounted cabinet , which provides rear
access to all cable connections. A 296 MB of internal RAM memory and houses dual 159
MB disk drives for program and mass storage.
2. Communication Concentrator Module (CCM):
The communication concentrator module functions as the communications interface
between the Host and RTU. The CCM also provides the interface link to external
programmable logic controllers-PLC or other external intelligent through an optional
foreign RTU interface board.
The CCM is a microcomputer, which performs the data acquisition function and stores
all the data in its buffer memory and upon the instruction from host transfers the required
data to the latter.
CCM is comprised of up to 4 functional blocks. An intelligent board is dedicated to
each of the functional blocks. The boards interface to each other through the CCM multi
use.
CPU Boards:
It is the controlling device in the CCM and is responsible for controlling all data
transfer functions within CCM
N1301B Ethernet Communications Controller Board :
This board accomplishes data traffic between the host and the CCM.
MCS-1062+Serial communications controller board:
This board accomplishes data traffic between the CCM and the RTU.
Foreign RTU interface FRI board:
The FRI board is a specially configured 86/35 or ODO01/0000 CPU board that is used
to interface with programmable controllers or other intelligent devices.
S/3 intelligent colour console:
The S/3 colour console serves as the main operator interface to the S/3 system.
The colour consoles main function is to provide the operator with a convenient method to
access process data and process parameters. All interaction with the S/3 system can be
accomplished through the colour console. In the terminal mode the console uses the DEC
command language DCL to access various host databases and A/3 files.
The colour console connects directly to the host computer to an RS-232/C serial
communications link. The console communication requests to the host and is capable of
accessing information for any point resident in the host's point database. Colour console
can also be installed directly on the ethernet or locally at an RTU. Consoles locally
connected to RTU only access information pertaining that RTU.
The colour console is a self-contained micro computer sub-system. All S/W tasks
and graphic data bases are resident on an internal hard disk drive. The unit handles all the
graphic formatting revealing the host of considerable overhead. The tasks running on the
console are self-sufficient and only require interaction from the hosts when accessing
current point values and alarm information.
Users present processed data on the console display in a variety of display
formats, which display the data in the most appropriate manner for efficient
interpretation. Displays are organised in a heirarchy and present data in varied levels
progressing from an entire plant overview down to single point display.Each display
includes pertinent information about the displayed data. Certain areas on the display are
reserved for the presentation of system and alarm messages.
Access to the displays and interaction with other console functions is
accomplished through console keyboard. The console keyboard is divided in to four
dedicated key pad areas, which provide access to all S/3 functions with a minimum
number of keystrokes. The provision exists to place the console in a VT series emulatoin
mode-terminal mode -tht allows data base management functions performed directly
from the console.
An S/3 graphics package is available to craete and use custom graphic display that
allow an operator to quickly and easily acquire data for complete process monitoring and
control. The custom graphic displays are in addition to the performated displays. The
custom graphic displays are created by the user can be customized for any application.
3. Peripheral transfer switch with watchdog timer:
The two number micro VAX2 host computers complete with working memory, bulk
memory units like hard disk, magnetic tape drive, floppy drive units and interface
modules etc., are connected in hot stand by redundant mode and the common peripherals
like S/3 video terminals remote video terminals remote video VT-320 terminals printers
communication interface parts etc., are connected to the host computers through the PTS
switch are shown in the diagram.
Normally the peripheral devices are connected to one of the host computers and that
computer performs as the main MS.Where as the other host remains in hot stand by mode
tracking and the main computer function.In the event of failure of main host,all the
peripheral devices are switched over to the stand by host through PTS and stand by host
stands functioning as the MS.
4. DELNI:
DELNI stands for Digital Equipment Corporation Ethernet Local Network
Interconnect. The CCM communicates with the host through an Ethernet communication
link. Communications traffic from the host is analysed by the CCM and directed by the
appropriated RTU. A multi bus to Ethernet communication controller board performs this
function in the CCM. The Ethernet communications link is routed to an Ethernet
interface, DELNI, for direct connection to the Ethernet network.
Ethernet Overview:
Ethernet is a basement local area network optimised for the high speed exchange of
data between processors. It was developed as a result of joint effort between DEC, Intel,
and Xerox in 1979. The ethernet specifications applies to the two lowest levels of overall
network architecture as defined by the ISO/OSI committee.
Physical layer:
It has a medium of shielded coaxial with manchester encoded digital baseband signalling
and data rate of 10 million bps. It uses a bus topology in the shape of a branching tree. A
maximum of 1024 nodes may be separated by up to 2.8Km.
Data link layer:
It is a multi accessed layer and is fairly distributed to all nodes. The access
method used for network devices employs contention control for when two nodes try to
transport at the same time and is known as carrier sense multiple access with collision
detection - CSMA/CD. Each Ethernet packet has a length from 64 to 1518 bytes with a
variable data field from 46 to 1500 bytes.
The physical and data link layers provided for delivery of a packet of data, or
datagram, between two nodes in a network. It is necessary to provide higher level
interfaces and protocols for complete application to application operation of the network.
These higher-level interfaces include:
Network management
Error recovery
Internet work communication
The application interface.
These layers correspond to top five layers of the ISO model. Digitals DEC net
products have integrated Ethernet in to its digital network architecture(DNA).
The physical components of Ethernet at the physical layer are the coaxial
cable(the carrier) , a tranceiver tied to an Ethernet communications controller.
The Ethernet controller also handles the data encapsulation, decapsulation and the
link management collision handling of the datalink layer.
5. System console:
The S/3 consoles located in the utility area shop office and MRS will be provided
with all the operation features like mimic diagram displays, alarm displays, operation of
remote control devices etc., as provided in the operator work stations. The command
signals for opening and closing of the circuit breakers in the electrical distribution
network are normally released from the S/3 console in the MRS.
The VT-320 video terminals and printers connected to each of the host micro
VAX2 computers normally function as system consoles. Through these system consoles,
basic system functions such as configuration, booting file management, system diagnosis
etc., are performed.
6. Magnetic tape sub system:
It consists of TQK 50 controller and TK 50 streamer tape of the capacity 95 MB.
7. Hard disk sub system:
It consists of one RQDK 3 controller and two RD 54 159 MB hard disk and one
RX 50 800 KB floppy disk drive.
8. VT 320:
The remote video VT 320 terminals are located in the area shop offices of the
different zones inside the VSP.
Normally the alarm conditions and important events pertaining to a particular zone
are reported to the respective area shop office terminals .Also special reports and logo
will also be routed to these terminals from the system whenever a request is made.
9. Line printer:
The LP 27, 1200 LPM line printer connected to the main host computer will print
the logging and reporting files of the system at the and of every shift, day, month etc.,
and also print special reports whenever a request is made.
10. Dot Matrix printer:
The LA 75 matrix printers which are a part of the operated work station of utility
and electrical system are normally used for printing alarms, event logging and operator's
action etc.
11. Digitizer Pad:
The digitizer pads and pens are provided in the operator work station, will be used
to generate customs graphicdisplays for the colour console. Graphic display generation is
greatly enhanced by the digitizer pad, at all the graphic components are selected directly
from the pad.
12.Communication transfer switch(CTS):
Communication transfer switch along with the watch dog timer module is used for
automatic change over between the redundant communication control modules.
13. Common Controller Interface Module:
Two number common controller interface modules KMI A provided in each host
computer will perform the data transmission between the supervisions control computer
and power plant computer and control planning computer. These modules one of micro
computer based intelligent units compising of a dedicated micro processor buffer
memory units and S/W blocks etc. For conversion of the data in to a required formatted
and transmission to other computers. The data transmission format confirming to X.25,
HDLC protocol will be adopted both at the supervision computer and central planning
computer ends fro perfect hand shaking between the computers.
POWER SUPPLY REQUIREMENTS AND
SPECIFICATIONS
OBJECTIVE :
The S/3 supervisory control and data acquisition SCADA system is a versatile
network of intelligent sub system like RTUs, cables, MS etc. all these sub system
contained hardware components, which require electrical power for their functioning.
There are wide range of hardware components present.
So it is the function of power supply unit to cater the needs of these components
with a wide range of power inputs.
MASTERSTATION :
For supervisory control center , a 415 Volts A.C., 3 phase , 50 hertz
Power supply feeder will be provided by Visakhapatnam steel plant in CDS For
power distribution to the MS hardware .
An U.P.S. if capacity 30 K VA with battery back up for 30 min . is
envisaged to provide a clean power to the hardware .
A dual U.P.S. each of capacity of 30 K VA complete With converts ,
Charges , invertors etc .. are connected in parallel in hot stand by mode . Under
normal conditions both U.P.S. are in line share the system load on A 50 % basis .
In the event of failure of 1 , the other will take over the full Load .
In addition to the hot stand by , a by pass regulating transformer / server
Control voltage stabilizer will also be provided along with the static switches ,
tracking devices etc., to supply at constant output voltage in the event of failure of
both U.P.S. systems .
A battery bank consisting of a group of lead acid batteries having the
voltage output of 240 Volts DC will be provided and capacity of battery bank
will be adequate to support the complete load for 30 min . in the event of mains
supply failure . The floating battery bank will be connected to the P.C input of
each inverter and maintain continity of AC Power output with out interruption
through the inverters . The battery charging will be automatic from the mains
supply and the charger will have provision for float charging and battery bank .
U.P.S SPECIFICATION :
INPUT:
Voltage : 415 V+ / -10 % AC 30 Phase
Frequency : 15 Hz +/- 5 %
Power Factor : 0.8 lag to 1
OUTPUT:
Voltage : 230 Volts AC 1 Phase
Frequency : 50 Hz
Voltage Regulation : +/- 1 %
Frequency Regulation : +/- 0.1 Hz
Line Sync. Rage : +/- 0.5 to 1 Hz ( adj )
Over Load Current : 125 % for 10 min.
150 % for 10 Sec.
REMOTE TELEMETRY UNIT :
The power supply cabinet which is installed adjacent to the RTU
Cabinet contains linear power supply ( LPS ) unit cum battery charger and Modem .
LINEAR POWER SUPPLY :
A linear power supply unit 1 provided with the RTU , which is a
standard 19- rack mountable unit mounted in the power supply cabinet . This unit
supplies 24 Volt DC supply to RTU as well as field .This supply
Will be uninterrupted when a battery is connected across the battery
Terminals . A charger is also incorported in the unit charge the batteries when the
AC supply is a available .
The unit on 230 Volt AC input 50 Hertz signal phase and 36 Volt
Battery connected at battery terminals .
DC -- DC CONVERTER :
GENERAL DESCRIPTION :
The power supply is a standard 19 – rack mountable unit mounted
Below the basic and input / output tiers in RTU cabinet . The output of This unit
is extended to the tiers through PSU adapter board with a suitable cable .
The unit provides logic requires for reqires for the operation of RTU from
a DC voltage sorce with an efficiency of 60 % ( typical ). The power Consumption
of the unit is 80 – 90 Watts typical providing 3 separate DC output each
giving 20 Watts DC to the load .
SPECIFICATIONS :
INPUT :
Voltage : 24 Volt / 48 Volt .
Tolerance : +20%
OUTPUT :
3 Isolated DC outputs : +5V&3A
: +120V & 1.5 A
: -12V& 0.5 A
Regulation : +0.2%
Ripple : less than 50mV ( peak to peak)
Input / Output : 24 KV rms
Operating temperature range : 0.55 deg. Celsius
Weight : Kgs.(Approx)
Dimensions : 465mmX 300mm
Efficiency : 50%
Storage temperature range :-25 deg.Celsius to +85 deg.Celsius .
Supply shall be switched OFF when the input voltage falls below
A limit lower than threshold on when the voltage falls below a limit lower
than threshold and shall be switched on when the voltage restored back to a level
above the limit i.e., upper threshold .
Insulation shall with stand for 1.5 KV DC between DC input terminals
shorted and earthed insulation shall stand for 250 Volts DC between output
and earth .
POWER SUPPLY CABINET
MODEM
FAN MODULE
LINEAR POWER SUPPLY UNIT
WITH BATTERY CHARGER
BATTERY HOUSING
SOFTWARE :
System is required in MS to meet all the functional requirements such
as data acquisition, display, reporting, bending and performing application
programs etc. ECIL responsible to install run and commission various
software modules in the system.
Multi programming also makes use of memory in better way. Since
one program will not normally be larger enough to occupy full memory.
Multiple programs make further use of memory.
Multi programming operating system is more complex than single
program operating system since it has to decide which programs are to
resident (Swapper), which programs will run next (scheduler).
Swapping : It means moving images back and forth between storage and
memory. In time sharing environment waiting program gets swapped out of
priority based environment.
Scheduling : It means deciding which program runs next. These are two
types
Priority Scheduling – Priority based
Time sharing scheduling – Round robin
VMS uses a combination of both systems.
Virtual memory : It is a mechanism of memory management which
combines limited physical memory and auxiliary stogie, give user an illusion
of vast amounts of main memory.
The operating systems take care of many of details of memory
management and programmer works in a symbolic virtual address space of
tremendous size.
Merits of virtual memory :
Memory efficiency
Protection
Relocation
Sharing
Demerits :
Overheads
Thrashing
COMMUNICATION SOFTWARE:
The CSCS exchanges vital data with two other computer systems i.e. the plant
central computer and power plant computer systems through data links for effective
integration between planning and supervisory levels.
The CSCS include 2 no.s KM VIA (communication processors with firmware
supporting X.25 defining HDLC as protocol) per micro VAX2. The communication
processor is able to handle all X.25 link level functions such as frame header generation,
error checking and retransmission.
S/3 databases:
Several databases reside in the host that is used to define the S/3 systems. These
databases exists in both off-line and on-line version. The on-line version is used to run
the current S/3 SCADA applications.The off-line version is the "master copy" of the
database. The S/3 databases are created by menu-driven utilities supplied as a part of the
S/3 applications. The databases reside at the host and are selectively downloaded to the
other nodes on the network as required. The following databases are a part of the S/3
system.
Network configuration:
It is the database that defines the S/3 network and the relationships that exists
between the different S/3 processes.
Asssosciation table:
It is the database that defines the different nodes- Host,CCM,and RTU's-on the
network.The database defines the names used for the different nodes and their hierarchi
assosiations with each other.
RTU Profile:
It is the database that defines the hardware configuration on the I/O board slot
assignments and the allocations of different point types with in the RTU.
Point database:
It is a large database that defines each I/O point in the S/3 system. The database
contained information concerning point location, point descriptor, point descriptor, point
type, display limits, engineering unit type, and so on.
Console database:
It is a database residing at the colour console that contains a library of graphics used for
the S/3 graphic displays.
PLC database:
It is an optional database used to support the foreign RTU interface. This database
defines the elements required to interface with a PLC or other intellgent device.
Historical trend list:
It is a list that defined the point marked for historical trending.
Current trend list:
It is a list of points that are marked for current trending.
Alarms management database:
It is a list of current alarm messages in the system.
APPLICATION OF MK 1 SYSTEM
(1) Word structure
(2) Out station address allocation
(3) Function address allocation
(4) RTU operation
(5) State monitor operation
(6) Analog monitor operation
(7) Totaliser operation
(8) RTU status monitoring
(9) Local RTU
WORDSTRUCTURE :
RTU s are arranged in a radial / Multidrop configuration. The communication is
used in half duplex mode .
The interrogation message has a fixed length of 5bytes , and the reply has a fixed
length of 13 bytes.
OUTSTATION ADDRESS ALLOCATION
Out station addresses are set in the range 1 –255 by dual in line (DIL) switches
encoded in binary on the RTU basic tier motherboard.
Field RTUs are assigned addresses 001,002 ,………023.no RTU is assigned the
address ‘ 000 ‘ as it is mean for Broadcasting information from the MS to all the RTU s
simultaneously. When the network expand in future , the present SCADA system, the
new RTUs will be assigned addresses 024,025…
FUNCTION ADDRESS ALLOCATION :
Function address are allocated as shown bellow . Use of the function address
is described under the individual heading in the reminder of this section .
32 -- 47 Analog control select
48 -- 63 Pulse input, Totoliser
88 -- 95 Digital input state monitor
96 -- 159 Analog input analog monitor
160 -- 225 Master control test – 2, Check monitor
RTU OPERATION :
The center of RTU operation is the microprocessor which essentially acts as a
buffer between communication with the MS and control / monitoring of the plant .
The microprocessor maintains in its store a record of plant interface modules
fitted and in the case of monitor modules it maintains a record of the corresponding plant
data. The plant data record is regularly updated, although the actual stimulus for updating
a varies between systems , and between different types of plant input,.
Communication between the microprocessor and the plant interface cards is
through a common input – output highway to which all the plant interface cards are
connected.
STATE MONITOR OPERATION :
The allocation to function address is arranged to allow monitoring of upto 512
single bit inputs.
After intialization the RTU microprocessor uses the input – output highway to
monitor the state of all state monitor inputs, and creates a stored record of the initial
status . The microprocessor continues to monitor the inputs on a regular basis ,
nominally every 20 msec and compares the monitor state with the stored state when a
discrepancy is found the micro processor record is updated, and a change of state marker
is set against the changed bit. There after no change to the record of that bit is made untill
the change of state marker is cleared.The marker is cleared after interrogation of the
RTU on the appropriate state monitor function addresss. Associated with the state
monitors are two change of state status bits. The first is set if any changed of state marker
set in the function range 88 – 91 and is monitor inbit 4 of the statua byte of every
message from RTU to MS.
The second operates similarly for function addresses 92 –95 and is monitored in
bit 5. the bits are clear if there are no changes outstandig beyond those indicated in the
reply to the current interrogation.
The MS recover the status of the state monitors from the stored record
interrogation mode. The information bytes of the interogation message comprise a state
monitor function address which define a group of 64 bits, follows by zero data byte. The
information bytes of the reply message comprise a repeat of the received state moniter
function followed by 8 data bytes contaning the state monitor data.
ANALOG MONITOR OPERATION:
The allocation of funtion adderss is arranged to allow monitoring of up to 256
analog values . Each analog value is reprasented as 11 bits pulse signal . Thus two bytes
are required for each analog value . The first byte contains the sign byte in the most
significant position,0 representing positive value and most 7bits in the remaining
positions. The second byte contains the remining 4 bits in the most significant
positions,followed by four zero bits .
The analog instrumentation is permanently powered and all inputs are
permanently on – scan . After initialization the RTU uses the input – output high way and
ADC to build a stored record of the value of all the inputs. There after the stored record is
up dated at two second intervals , or continously if the time taken to scan all analog value
exceeds to seconds .
If the time taken to scan all analog exceeds 4sec the analog scaning system is
reinitialized and RTU soft ware status of the bite is monitored in bit 4 of the check
monitor RTU status byte described latter, and is monitored by the MS . the bite is cleard
again when a successful analog scan achieved .
The MS may recover the value of the analog monitors from the stored record
using interrogation mode . the information bytes of the interrogation message comprise
an analog monitor function adderss , with defines a group of 4 analog values , followed
by 0 data byte . the information bytes by the reply message comprise a repeate of the
received analoge monitor,followed by 8 data bytes formed as 4paires each with 1 analog
value .
TOTALISER OPERATION :
The allocation of function addresses is arranged to allow monitoring of up to 16
inputs.
Each totaliser input pulse stream is accumulated in a 6 decade hardware counter
on the paint interface totaliser card . On initialization the RTU uses the RTU input –
output high way to reset total to zero. There after the Microprocessor monitors the
hardware toyals on a regular basis.
The RTU Microprocessor maintains two records of each totaliser value. One is
the 6 decade software record of the accumulated total. Designated the basic total and this
is regularly updated at all times .The other designated the message total is normally a
copy of the first and is used to generate the reply message data to MS interogations. The
MS can freeze the message total, but not the basic total , of all totaliser at any time by
using the totaliser freeze control function address.
The MS may recover each total from the stored record using interrogation mode .
The information bytes of the interrogation message comprise a totaliser function address
followed by a zero data byte. The informaton bytes of the reply are shown under reply for
totaliser.
RTU STATUS MONITORING :
The RTU status is monitored in two ways . The first is the RTU status byte
included in every message from RTU to MS . The second in the special check monitor
function.
LOCAL RTU :
3nos. local RTU s are employed to drive the wall mimic lamps using stae
control outputs and digital panel meters ( DPMS ) using analog control outputs. The
facilities of the local RTU are similar to other RTU s expect that Each local
RTU allows for up to 320 state control outputs.So analog outputs and no plant
monitoring . To achieve this the local RTU has different function address set . The
allocation of function addresses is given at figure . Unlike the normal RTU s , more
that one control can be active at any give time.
DATA ACQUISITION AND CONTROL:
The communication handler at central station of SCC shall perform the task of
transmitting the collecting information to and from each RS,determining the information
as data or control and respond to all requests of central processing unit(CPU) according
to established procedures.This shall scan the remote station in periodic and /or event
driven mode on a programmed poll basis to collect up-to-date status of various
parameters as well as transmission of control commands to the destined stations under
directives of the CPU . Any command signal issued from the destines stations under
directives of the CPU. Any command signal issued form the supervisory control or
remotely located VDU at MRS shall be routed through this communication handler to the
relevant RS / RS s over the same and /or separate cable communication line based on the
application programs to handle a specified volume of tele-- control signals.
The intelligent remote stations (RS) acting as slave to the central station shall
continuously scan various parameters and keep the updated information ready for further
transmission to the central station .The exchange of information between the central
station and RS shall be achieved on standard protocol consisting of 'interrogation ' from
the central station followed by 'reply' from the RS .The entire communication shall be
carried out under the control of central station software .The normal polling sequence will
allow the RS s to return date with transmission priorities for different types of
information.
The text structures for data transmission shall preferably be as recommended by
CITT. Generating suitable check codes and performing necessary validity checks shall
provide transmission protocol handling and safeguarding the integrity of data against
communication noise. All information shall be protected against transmission error to
detect and/or correct single and multiple errors including inverse code check for
protection of command transmission during tele --control functions.
INFORMATION PROCESSING:
The system shall handle a variety of information for the utility and power
distribution networks for function outlined in item 6.2 and 6.3.the network information
comprises the following categories :
Indication derived mainly from the ON/OFF contact status .
Measurands being a digital representation of any analog signal.
Pulse relating to counting of the rate of certain physical value.
A real time data base forming a part of system software shall handle all the
above type of Input/Output data to have continuous telemeter,telesignaling,telecontrol
and computation functions as required for the plant.This will cater for data updating,
request/receive of data from RSs,signal definition,scaling of data,accessing and
processing of data.
COMMUNICATION WITH EXTERNAL COMPUTER SYSTEM:
The supervisory control system computer shall have communication link with the
central computer system as well as power plant computer system independently for data
exchange. The supervisory system computer shall be provided with data transmission
adaptor along with necessary software for handling communication protocol so that the
external computer systems could be linked through MODEM for establishment of
communication as required.
CONCLUSIONSupervisory control and data acquisition system is a versatile network of
intelligent sub systems, which has brought revolution in the field of monitoring and
controlling systems. Earlier due to lack of sophisticated equipment it was very difficult
to predict whether the channel corrupted the data coming to the monitoring station or it is
the date pertaining to a functional error in a particular department. Further it was a very
time consuming process to undo the effect causing the problem (only after making sure
the data received is correct). In the mean time a lot of energy is waste and sometimes
even unacceptable hazards also used to take place. Also there was no privilege to track
the position that is responsible for the error.
The supervisory control and data acquisition system over comes all the above
bottlenecks. It has host computer in the master station to store the data for a long period
of time so that it can be sued to take strategic decisions sat the time of crisis.
The proposed SCADA System for Vizag Steel Plant shall acquire various
electrical and utility parameters for effective monitoring and control operations. The
various parameters acquired shall be such as electric power, voltages, currents, etc.
under electrical monitoring and parameters such as flows, temperatures pressures, etc.
under utility monitoring.
These parameters are logged into the system using a suitable database
management system. The data is processed and presented in the plant to the concerned
officials and operators using user-friendly graphical interfaces.
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