SIX weeks/months industrial training report on BEL(BHARAT ELECTRONICS LIMITEDProject

BHARAT ELECTRONICS PROJECT REPORT

SUBMITTED BY: ROLL NO: 1

CONTENTS

1 2 3 4 5 6 7 8 9

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CERTIFICATE ACKNOWLEDGEMENT PREFACE BHARAT ELECTRONICS INDUSTRY B E: SALES ANS SERVICES FORMATION OF UNIT PROJECT : ROTATION PROJECT : RADAR TRANSMITTER

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TO WHOM SO EVER IT MAY CONCERN

I certify that , student of B.Tech (Electronics and Communication) from INDERPRASTHA ENGINEERING COLLEGE, GHAZIABAD has joined BEL, Ghaziabad for six weeks industrial training and he has been constantly working under my acknowledgement on the project assigned to him. He has worked on project RADAR TRANSMITTER. His contribution was in Study & Testing of Transmitter. This report accounts his experience and knowledge of the field he worked in. I have verified the report and sanction it.

(Project Guide )

(Project Head)

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ACKNOWLEDGEMENT I take this opportunity to express my sincere gratitude towards Training and placement officer of my college for forwarding my training letter to Bharat Electronics, Ghaziabad and also to Mr.B.K.Pant (Mgr.) HRD, Bharat Electronics, Ghaziabad for accepting my letter and allowing me to complete my training in Bharat Electronics Limited. I am extremely grateful to Mr. Jagdish Chand, (AGM, RADAR SBU), Mr. Dhyan Singh, (Sr.DGM, RADAR SBU), Bharat Electronics, for permitting me to join CAR- RADAR SBU.Further I would like to thank Ms Laxmi Chauhan, Mr. Ankur kumar for their time to time guidance and help extended during each stage our project. I am grateful to Mr. R.N. Tyagi, HRD to guide and help me throughout my project. It is not without his help I could have been able to complete my training here. I would like to express my deep satisfaction and gratitude for their support for their kind help extended during the entire period of training. Finally, I would like to thanks each and every member of BEL family for making me feel comfortable and helping me in every possible manner.

PREFACE 4

The six month training is a part of our B.Tech, Electronics and Communication. Practical Industrial Training mainly aims at making one aware of industrial environment; which means that one gets to know the limitation, constraint and freedom under which an engineer works. One also gets an opportunity to watch from close quarter that indicates manager relation. This training mainly involves industrial and complete knowledge about designing, assembling and manufacturing process of various equipments manufactured by an industry. During this six month period, as a student, there is a great opportunity of understanding Industrial practices. Most of the theoretical knowledge that has been gained during our course is useful only if it can be applied to production and services in the industry. The learnt is applied, tested, verified and rectified. Apart from this the student gets an opportunity to learn latest technology and is upgraded of the new trends immersing in the industry of interest. I had the opportunity to utilize my six month summer internship in BHARAT ELECTRONICS LIMITED, GHAZIABAD [U.P.]. I was a part of the company’s new venture CAR, which provided me a great deal of learning. My sphere of knowledge was expanded both at technical and personal level. I not only got chance to work on Live Project but also witnessed the related industrial processes and got acquainted to many of the prevalent technologies.

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INTRODUCTION OF BEL BHARAT ELECTRONICS LIMITED INDUSTRY

Bharat Electronics Limited (BEL) was established in 1954 as a Public Sector Enterprise under the administrative control of Ministry of Defence as the fountain head to manufacture and supply electronics components and equipment. BEL, with a noteworthy history of pioneering achievements, has met the requirement of state-of-art professional electronic equipment for Defence, broadcasting, civil Defence and telecommunications as well as the component requirement of entertainment and medical X-ray industry. Over the years, BEL has grown to a multi-product, multi-unit, and technology driven company with track record of a profit earning PSU. The company has a unique position in India of having dealt with all the generations of electronic component and equipment. Having started with a HF receiver in collaboration with T-CSF of France, the company's equipment designs have had a long voyage through the hybrid, solid state discrete component to the state of art integrated circuit technology. In the component arena also, the company established its own electron valve manufacturing facility. It moved on to semiconductors with the manufacture of germanium and silicon devices and then to the manufacture of Integrated circuits. To keep in pace with the component and equipment technology, its manufacturing and product assurance facilities have also undergone sea change. The design groups have CADDs facility, the manufacturing has CNC machines and a Mass Manufacture Facility, and Quality Control (QC) checks are preformed with multi-dimensional profile measurement machines, Automatic testing machines, environmental labs to check extreme weather and other operational conditions. All these facilities have been established to meet the stringent requirements of MIL grade systems. Today BEL's infrastructure is spread over nine locations with 29 production divisions having ISO-9001/9002 accreditation. Product mix of the company is spread over the entire Electro-magnetic (EM) spectrum ranging from tiny audio frequency semiconductor to huge radar systems and X-ray tubes on the upper edge of the spectrum. Its manufacturing units have special focus towards the product ranges like Defence Communication, Radar's, Optical & Opto-electronics, Telecommunications, Sound and Vision Broadcasting, Electronic Components, etc. Besides manufacturing and supply of a wide variety of products, BEL offers a variety of services like Telecom and Radar Systems Consultancy, Contract Manufacturing, Calibration of Test & Measuring Instruments, etc. At the moment, the 6

company is installing MSSR radar at important airports under the modernization of airports plan of National Airport Authority (NAA). BEL has nurtured and built a strong in-house R&D base by absorbing technologies from more than 50 leading companies worldwide and DRDO Labs for a wide range of products. A team of more than 800 engineers is working in R&D. Each unit has its own R&D Division to bring out new products to the production lines. Central Research Laboratory (CRL) at Bangalore and Ghaziabad works as independent agency to undertake contemporary design work on state-of-art and futuristic technologies. About 70% of BEL's products are of in-house design. BEL was among the first Indian companies to manufacture computer parts and peripherals under arrangement with International Computers India Limited (ICIL) in 1970s. BEL assembled a limited number of 1901 systems under the arrangement with ICIL. However, following Government's decision to restrict the computer manufacture to ECIL, BEL could not progress in its computer manufacturing plans. As many of its equipment were microprocessor based, the company continued to develop computers based application, both hardware and software. Most of its software requirements are in real time. EMCCA, software intensive naval ships control and command system is probably one of the first projects of its nature in India and Asia. BEL has won a number of national and international awards for Import Substitution, Productivity, Quality, Safety Standardization etc. BEL was ranked no.1 in the field of Electronics and 46th overall among the top 1000 private and public sector undertakings in India by the Business Standard in its special supplement "The BS 1000 (1997-98)". BEL was listed 3rd among the Mini Ratanas (category II) by the Government of India, 49th among Asia's top 100 Electronic Companies by the Electronic Business Asia and within the top 100 worldwide Defence Companies by the Defence News, USA. BEL has production units established at different parts of the country. The year of establishment and location are as follows:

Serial no.

Year of establishment

Location

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1.

1954

Bangalore

2.

1972

Ghaziabad

1979

Pune

5.

1979

Taloja (Maharashtra)

6.

1984

Hyderabad

1984

Panchkula (Haryana)

1985

Chennai

1985 1986

Machhilipathnam (A.P.) Kotdwara (U.K.)

3. 4.

7. 8. 9.

Motto Mission and Objectives 8

The passionate pursuit of excellence at BEL is reflected in a reputation with its customers that can be described in its motto, mission and objectives:

CORPORATE MOTTO

"Quality, Technology and Innovation." CORPORATE MISSION To be the market leader in Defence Electronics and in other chosen fields and products.

CORPORATE OBJECTIVES 

To become a customer-driven company supplying quality products at competitive prices at the expected time and providing excellent customer support.



To achieve growth in the operations commensurate with the growth of professional electronics industry in the country.



To generate internal resources for financing the investments required for modernization, expansion and growth for ensuring a fair return to the investor.



In order to meet the nation's strategic needs, to strive for self-reliance by indigenization of materials and components.



To retain the technological leadership of the company in Defence and other chosen fields of electronics through in-house Research and development as well as through Collaboration/Co-operation with Defence/National Research Laboratories, International Companies, Universities and Academic Institutions.



To progressively increase overseas sales of its products and services.



To create an organizational culture which encourages members of the organization to realize their full potential through continuous learning on the job and through other HRD initiatives?

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Manufacturing Units Bangalore (Karnataka) BEL started its production activities in Bangalore in 1954 with 400W high frequency (HF) transmitter and communication receiver for the Army. Since then, the Bangalore Complex has grown to specialize in communication and Radar/Sonar Systems for the Army, Navy and Air Force. BEL's in-house R&D and successful tie-ups with foreign Defence companies and Indian Defence Laboratories has seen the development and production of over 300 products in Bangalore alone. The Unit has now diversified into manufacturing of electronic products for the civilian customers such as D.O.T., V.S.N.L., A.I.R. and Doordarshan, Meteorological Dept., I.S.R.O., Police, Civil Aviation, and Railways. As an aid to Electorate, the unit has developed Electronic Voting Machines that are produced at its Mass Manufacturing Facility (MMF). Ghaziabad (Uttar Pradesh) The second largest Unit at Ghaziabad was set up in 1974 to manufacture special types of radar for the Air Defence Ground Environment Systems (Plan ADGES). The Unit provides Communication Systems to the Defence Forces and Microwave Communication Links to the various departments of the State and Central Govt. and other users. The Unit's product range included Static and Mobile Radar, Tropo scatter equipment, professional grade Antennae and Microwave components. Pune (Maharashtra) This Unit was started in 1979 to manufacture Image Converter Tubes. Subsequently, Magnesium Manganese-dioxide Batteries, Lithium Sulphur Batteries and X-ray Tubes/Cables were added to the product range. At the present the Unit manufactures Laser Sub-unit for tank fire control systems and Laser Range Finders for the Defence services. Machilipatnam (Andhra Pradesh) The Andhra Scientific Co. at Machilipatnam, manufacturing optics/Optoelectronic equipment was integrated with BEL in 1983. The product line includes Passive Night Vision Equipment, Binoculars, Binoculars and Goggles, Periscopes, Gun Sights, Surgical Microscope and Optical Sights and Mussle Reference Systems for tank fire control systems. The Unit has successfully diversified to making the Surgical Microscope with zoom facilities. To cater the growing needs of Defence Communications, this Unit was established in 1985. Professional grade Radio-communication Equipment in VHF and UHF ranges entirely developed by BEL and required by the Defence services are being met from this Unit.

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Chennai (Tamil Nadu) In 1985, BEL established another Unit at Chennai to facilitate manufacture of Gun Control Equipment required for the integration and installation in the Vijayanta tanks. The Unit is now manufacturing Stabilizer Systems for T-72 tanks, Infantry Combat Vehicles BMP-II; Commander's Panoramic Sights & Tank Laser Sights are among others. Kotdwar (Uttarakhand) In 1986, BEL started a Unit at Kotdwara to manufacture Telecommunication Equipment for both Defence and civilian Customers Focus is being given on the requirement of the Department of Telecommunications to manufacture Transmission and Switching Equipment. Taloja (Maharashtra) For the manufacture of B/W TV Glass bulbs, this plant was established in collaboration with coming, France in 1986. The Unit is now fully mobilized to manufacture 20" glass bulbs indigenously. Hyderabad (Andhra Pradesh) To coordinate with the major Defence R&D Laboratories located in Hyderabad, DLRL, DRDL and DMRL, BEL established a unit at Hyderabad in 1986. Force Multiplier Systems are manufactured here for the Defence services.

Joint Ventures BE-Delft Electronics Limited BE-Delft Electronics Limited, Pune, the first joint venture of the company with Delft Instruments, Holland and UTI was established in the year 1990 for conducting research, development and manufacture of Image Intensifier Tubes and associated high voltage power supplies for use in military, security and commercial systems. Its products include night vision goggles and binoculars, night vision weapon sights and low light level input applications.

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GE BE Private Limited GE BE Private Limited, Bangalore, a JV with General Electric Medical Systems, USA has been established in 1997-98 for manufacture of High End Rotating Anode Medical Diagnostic X-ray tube called CT MAX, which is used in CT Scanners. The joint venture unit will also establish a reloading facility for X-ray tubes and will also market the conventional X-ray tubes made at Pune Unit of BEL. South East Asia markets are addressed by this joint venture. BEL- Multitone Private Limited A joint venture between Bharat Electronics and Multitone Electronics Plc, UK has also been established in Bangalore in 1997-98 to manufacture state-of-art Mobile Communication for the workplace. Multitone invented paging in 1956 when it developed the world's first system to serve the "life or death" environment of St. Thomas Hospital, London. With the strength of Bharat Electronics in the Radio Communications field and the technology of Multitone, in the field of Radio Paging, the joint venture company is in a position to offer tailor made solution to the Mobile Communication needs at workplace in various market segments.

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Customer Profile & BEL Product Range Defence Army

Navy

Air Force Non-Defence Para-Military Space Department All India Radio Doordarshan (TV Network) NCERT Department of Telecommunications Videsh Sanchar Nigam and other Corporate Bodies Civil Aviation Meteorological Department Power Sector Oil Industry Forest Departments, Irrigation & Electricity Boards Medical & Health Care Railways

Tactical and Strategic Communication Equipment and Systems, Secrecy Equipment, Digital Switches, Battlefield Surveillance Radar, Air Defence and Fire Control Radar, Opto-Electronic Instruments, Tank Fire Control Systems, Stabilizer Systems, Stimulators and Trainers. Navigational, Surveillance, Fire Control Radar, IFF, SONAR Systems, Torpedo Decoys, Display Systems, EW Systems, Simulators, Communication Equipment and Systems. Surveillance and Tracking Raiders, Communication Equipment and Systems, IFF and EW Systems. Communication Equipment and Systems. Precision Tracking Radar, Ground Electronics, Flight and On-Board Sub-systems. MW, SW & FM Transmitters. Low, Medium and High Power Transmitters, Studio Equipment, OB Vans, Cameras, Antennae, Mobile and Transportable Satellite Uplinks. TV Studios on Turnkey Basis for Educational Programs. Transmission Equipment (Microwave and UHF) and PCM Multiplex, Rural and Main Automatic Exchanges, Flyaway Satellite Terminals, Solar Panels for Rural Exchanges. MCPC VSAT, SCPC VSAT, Flyaway Earth Stations. Hub Stations, Up/Down Converters, LNA Modems Airport Surveillance Radar, Secondary Surveillance Radar. Cyclone Warning and Multipurpose Meteorological Radar. Satellite Communication Equipment. Communication Systems, Radar. Communication Systems.

Clinical and Surgical Microscope with Zoom, Linear Accelerators. Communication Equipment for Metros, Microwave Radio Relays, And Digital Microwave Radio Relays.

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Equipment Components Defence Non-Defence All India Radio, Doordarshan (TV Network), Department of Telecommunications And Civil Industries Entertainment Industry Telephone Industry Switching Industry Instrumentation Industry Medical &Health Care

Transmitting Tubes, Microwave Tubes, Lasers, Batteries, Semiconductors-Discrete, Hybrid and Integrated Circuits. Transmitting Tubes, Microwave Tubes, and Vacuum Tubes.

B/W TV Tubes, Silicon Transistors, Integrated Circuits, Bipolar and CMOS, Piezo Electric Crystals, Ceramic Capacitors and SAW Filters. Integrated Circuits, Crystals. Vacuum Interrupters. Liquid Crystal Displays. X-ray Tubes.

Systems/Network Identity Card Systems Software, Office Automation Software, LCD On-line Public Information Display Systems and Communication Networks / VSAT Networks.

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Financial Performance BEL has a unique history of profit making Public Sector Enterprise right from its inception. There have been events of decrease in turnover and profit after Tax due to reasons beyond reasonable control of the company. But the company's strength lies in its capability to combat the threats, for example US Embargo on exports to BEL. BEL hopes to generate 25 per cent increase in turnover with a 15 per cent rise in net profit in the current fiscal year over the previous. Corrective measures against western sanctions have been undertaken, which are likely to translate into higher turnover and profitability. The company is putting all efforts to minimize the effect of the restrictions by early establishments of alternative arrangements. The Defence Research Laboratories and Academic Institutions are also being persuaded with for indigenization of certain special category of devices and components. The company is also opening an office in Singapore to procure components from Asian markets. Thus in the long run the restrictions will prove as blessings resulting in self-dependence and better profit margins. Also several R&D projects with long gestation periods will go into commercial production during the current fiscal.

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Product Range The product ranges today of the company are:

Radar Systems: 3-Dimensional High Power Static and Mobile Radar for the Air Force. Low Flying Detection Radar for both the Army and the Air force. Tactical Control Radar Systems for the Army Battlefield Surveillance Radar for the Army IFF Mk-X Radar systems for the Defence and Export ASR/MSSR systems for Civil Aviation. Radar & allied systems Data Processing Systems.

Communications: Digital Static Tropo scatter Communication Systems for the Air Force. Digital Mobile Tropo scatter Communication System for the Air Force and Army. VHF, UHF & Microwave Communication Equipment. Bulk Encryption Equipment. Turnkey Communication Systems Projects for defence & civil users. Static and Mobile Satellite Communication Systems for Defence Telemetry/Tele-control Systems.

Antennae: Antennae for Radar, Terrestrial & Satellite Communication Systems. Antennae for TV Satellite Receive and Broadcast applications. Antennae for Line-of-sight Microwave Communication Systems.

Microwave Component: Active Microwave components like LNAs, Synthesizer, and Receivers etc. Passive Microwave components like Double Balanced Mixers, etc Most of these products and systems are the result of a harmonious combination of technology absorbed under ToT from abroad, Defence R&D Laboratories and BEL's own design and development efforts.

Organization The operations at BEL Ghaziabad are headed by General Manager with Additional / Deputy General Manager heading various divisions as follows: 16

Design & Engineering Divisions : Development and Engineering-R Development and Engineering-C Development and Engineering-Antenna. 1. Equipment Manufacturing Divisions : Radar Communication Antenna Systems Microwave Components. 2.

Support Divisions: Material Management Marketing & Customer Co-ordination Quality Assurance & Torque Central Services PCB & Magnetics Information Systems Finance & Accounts Personnel & Administration Management Services.

Design & Engineering: The pace of development and technological obsolescence in their field of electronics necessitates a strong Research and Development base. This is all the more important in the area of Defence Electronics. BEL Ghaziabad has since its inception laid a heavy emphasis on indigenous research and development. About 70% of its manufacture today relate to items developed in-house. For the development and production of the Mobile Tropo scatter System and the IFF equipment, BEL was awarded the Gold Shield for Import Substitution. Design facilities are also constantly being modernized and substantial computeraided design facilities are being introduced including installation of mini- and micro17

computers and dedicated design application. About 170 graduate and post-graduate engineers are working on research and development and indication of the importance R&D has in BEL's growth. Three Design and Engineering groups are product based viz. Communication, Radar and Antenna. These divisions are further divided into different departments to look after products of a particular nature. Each of them has a drawing office attached to them, which are equipped with latest drafting and engineering software. The PCB layout and PCB master making is done at CADDs Center. A central Records & Printing section takes care of the preserving the engineering documents and distribution thereof. Most of the engineering documents are available online.

Equipment Manufacturing Divisions: As a supplier of equipment to the Defence services and professional user, strict adherence to specifications and tolerances has to be in-built into the design and manufacturing process. For this BEL Ghaziabad has well defined standards and processes for as well as manufacturing and testing activities. Activities are divided into various departments like Production Control, Works Assembly, and QC WORKS. The manufacture and control of production is through a central system, BELMAC, BEL's own homegrown ERP system. Apart from conventional machines, BEL Ghaziabad has been equipped with several Computer Numerical Control (CNC) machines for ensuring repeat occurrences and increased throughput. A separate NC programming cell has been set up to develop the programs for execution on the CNC machines.

Microwave Component Group: Frequencies greater than 1 GHz is termed as Microwaves. Microwaves Integrated Circuits (MIC) used extensively in the production of subsystems for Radar and Communication equipment constitutes a very vital part of the technology for these systems and is generally imported. Owing to the crucial and building block nature of the technology involved, BEL is currently setting up a modern MIC manufacturing facility at a planned expenditure of Rs. 2 crore. When in full operation, this facility will be the main center for the MIC requirements of all the units of the company. The manufacturing facilities of hybrid microwave components available at BEL, Ghaziabad includes facility for preparation of substrates, assembly of miniaturized component viz. directional couplers, low noise amplifiers, phase shiftier, synthesizers etc. involves scalar as well as vector measurements. For this state of the network analysis are used.

Material Management: Material Management division is responsible for procurement, storage handling, issue of purchased parts as well as raw materials required to manufacture various equipment and spares. It also takes care of disposal of unused or waste material. The division is divided into Purchase, Component store, Raw material store, Chemical store, Inwards good store, Custom clearance Cell, Inventory management & disposal.

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Marketing and Customer Co-ordination: This division is responsible for acquisition and execution of customer orders and customer services. Marketing department looks after order acquisition. Commercial department looks after order execution. Shipping takes care of packing and dispatch of material to customer.

Quality Assurance & Torque: In the area of professional Defence electronics, the importance of Quality and Reliability is of utmost importance. BEL has therefore established stringent processes and modern facilities and systems to ensure product quality- from the raw material to the finished product. IGQA, Environmental Labs, Test Equipment Support and QA departments are grouped under this division. All material for consumption in the factory passes through stringent inward goods screening in IGQA department before being accepted for use. Subsequent to manufacture and inspection, the end product is again put through a rigorous cycle of performance and environmental checks in Environmental Labs. The testing, calibration and repair facility of test Instruments used in the factory is under the control of Test Equipment Support. All the instruments come to this department for periodic calibration. Quality Assurance department facilitates ISO 9000 certification of various divisions. All production divisions of BEL Ghaziabad are ISO9000 certified. The microwave division is ISO9001 certified whereas the remaining three division viz. Radar, Communication and Antennae are also ISO9002 certified.

Central Services: Central services Division looks after plant and maintenance of the estate including electrical distribution, captive power generation, telephones, transport etc.

PCB Fabrication & Magnetics: PCB Fabrication, Coil and Magnetics, Technical Literature, Printing Press and Finished Goods are the areas under this division. Single sided PCB blanks- having circuit pattern only on one side of the board and double sided - having circuit pattern on both sides of the board are manufactured in house. However, Multi-layered PCBs, having many layers of circuit, are obtained from other sources. Magnetic department makes all types of transformers & coils that are used in different equipment. Coils and transformers are manufactured as per various specifications such as number of layers, number of turns, types of windings, gap in core, dielectric strength, insulation between layers, electrical parameters, impedance etc. laid down in the documents released by the D&E department.

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Information Systems: IS Department is responsible for BEL's own home grown manufacturing and control system called BELMAC. It comprises of almost all modules a modern ERP system but is Host and dumb terminal based.

Finance & Accounts: The F&A division is divided into Budget & Compilation, Cost and Material Accounts, Bills Payable, Bill Receivable, Payrolls, Provident Fund, Cash Sections

Personnel & Administration: There are at present about 2300 employees at BEL Ghaziabad, of which more than 400 are graduate and post graduate engineers. P&A Division is divided into various departments like Recruitment, Establishment, HRD, Welfare, Industrial Relations, Security and MI Room. Management Services: This department deals with the flow of information to or from the company. It is broadly classified into three major sub-sections - Management Information System, Industrial engineering department and Safety.

Production Control The main goals of the production control are: To improve the profits of the company by better resource management To ensure on-time delivery products To improve the quality of product To reduce the capital investment To reduce working capital needs by better inventory management Production control is responsible for producing the products, right from the stage engineering. Drawings are received to the stage where it is store credited as finished product. It’s basic function is to identify the parts/operations to be made, the best way of making them, the time when they have to be made and to arrange the production resources to the optimum. The commercial department obtains orders from equipments through quotations. The equipment stock order (ESO) is released by commercial department. Then the management services department issues work order for the quantity of equipment to be made. This is for the calculation for the cost of the project then D&E department develops the equipment and releases the following engineering documents: 20

KS

:

Key Sheet

PL

:

Part List

GA

:

General Assembly Diagram

CL

:

Connection List

WL

:

Wiring Diagram

Now the production control takes the responsibility of manufacturing the equipment. PC decides for items to be purchased from outside, for items to be manufactured by other companies and prepares documents for items to be made inside the company. Documents issued by the PC: I. Process sheet (fabrication): This process sheet indicates the process and the sequence of operation to be followed in various work cells and work centers. Every item is timed by productivity services. II. Process sheet (Assembly): This is similar to PS (fabrication) except that it is used in electronics assembly, PCB assemblies, cable form and cable assemblies. III. Process sheet (coils): This indicates operation analysis for transformer and coils. IV. Schedule for RM, fasteners and PPs: This gives the gross requirements for raw materials, purchased parts, fasteners etc. Based on this material control department initiates procurement action and store requisitions are released with reference to this schedule. Tool Planning 1. Some of the items while under fabrication require the use of some jigs and fixtures. 2. The cost estimation, revenue and budget plans are got approved by the board of management 3. Standard hour is approved by the department. This is the time, which is decided to complete the job by a worker in a stipulated time, which is decided on the previous records of the shop, type of machine used and the nature of work. 4. Report on production value is evaluated for each unit. My Training in BEL, was attended in two phases. In first phase, I was given a schedule to visit all the departments in BEL, relevant to my field of Electronics and Communication. In this period of orientation, I visited different departments and was introduced to the current technology used and the various industrial processes under practice. In the second phase I was allotted a Project under Project Manager, Mr. Chaturvedi (CAR- RADAR). I am briefing my experience and observation about various departments of the company in next paragraphs.

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ROTATION ABOUT VARIOUS DEPARTMENTS MICROWAVE INTEGRATED CIRCUITS Frequencies greater than 1 GHz are termed as Microwaves. Microwave Integrated Circuit used extensively in production of subsystems for Radar and Communication equipment constitutes a very important part of technology for these systems are generally imported. Owing to the crucial and building block nature of the technology involved, BEL is currently setting up a modern MIC manufacturing facility at a planned expenditure of Rs. 2 crore. When in full operation this facility will be the main center for the MIC requirements of all the units of the company. The manufacturing facility of hybrid microwave components available at BEL Ghaziabad includes facility for preparation of substrates, assembly of miniaturized components on substrates, bonding and testing. Testing of these microwave components viz. Directional couplers, Waveguides, low noise amplifiers, phase shifters, synthesis etc. involve scalar as well as vector measurements. For this state of the network, analyses are used. Various losses such as return loss, bending loss, insertion loss are measured and testing is done in a way to minimize these losses. MICROWAVE LAB This section undertakes: 1. Manufacturing of films and microwave components to meet internal requirements. 2. Testing of low power antenna for which test-site is about 100 Km from the factory at sohna. The main component testing in this department is: Oscillators Amplifiers Mixers Radiation elements (e.g. Feeders) Microwave components (e.g. Isolators, circulators, waveguides etc.) 22

Filters (e.g. LPF, BPF, Uniplexers, and Multiplexers etc.) Functioning of component is listed below: Frequency response Noise figure VSWR Directivity and coupling Power measurements Various instruments in the lab are: Adaptor Attenuator Coupler Mixer Detector

ENVIRONMENTAL LAB Various tests conducted in the environmental lab in BEL in order to ensure reliability. Reliability is defined as the probability of a device performing its purpose adequately for the period intended under the given operating conditions. In a given system reliability is given as R = R1 * R2 * R3 …… The standards available here are: JSS 55555 - Joint Services Specifications (Military Standard of India) Mil Standards - U.S. Military standards QM333 - Civil Aviation and Police TYPES OF TESTS 1. FIRST ARTICLE TEST (FAT) These tests are performed on the prototype. If these tests are successful then the mass production is taken up.

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1. 2. 3. 4. 5. 6. 7. 8. 9.

The tests are: Vibration Test System High Temperature Operate and Storage Low Temperature Operate and Storage Damp Heat Operate and Storage Altitude Chamber Bump Test Machine Salt Fog Chamber Tropical Storage Mould Growth Chamber

VARIOUS TESTS IN DETAIL: 1. Vibration Test System The item is vibrated when kept over the plate of the machine. The frequency Range is 1 to 2,000 Hz. Radar PCB’s are vibrated at 10 to 50 Hz at 2g (g=9.8m/s2) for 15’. 2. Humidity chamber Used to test the product under varying humidity conditions. For Navy instruments conditions for humidity are 95% at +45C for 16 hours. 3. Cold Heat This chamber has a temperature of –90 to +180. This chamber program is controlled and has an accuracy of +0.5 and has a graph plotting system. 4. Mould Growth This chamber is used to test how immune the product is against mould growth. 5. Salt Spray It is used to check the resistivity of the item produced against salty water. 6. Climatic Chamber Temperature range of – 65C to +200C and relative humidity is from 20% To 98%RH.

7. Walk – In Chamber This is a big chamber of size 2.6m, 2.4m, 3m Temp. range of – 60C to +100C and the humidity is from 20% to 90% RH. 8. Bump Machine Item is dropped from a certain height every time it receives bump from Machine. Maximum capacity of the machine is 11.35 Kg. Drop height is Around 1 inch. 9. Altitude Chamber Used to test the item under different temperature and humidity conditions. 24

The temperature range for this chamber is from -40C to +150C and can create environmental conditions as per a height of 50,000 feet’s. For airforce equipment the instrument is kept at a temperature of +40C for 30,000 ft and at 0C for 13,500 ft. 2. ACCEPTANCE TEST PROCEDURE This sets on the extent to which a test is to be conducted and also decides what tests should be conducted. There are three types of tests: a) Class A test: This test includes visual and dimensional checks. All equipments of regular production go through these checks. These include quality control and electrical tests. b) Class B test: These are quality assurance and reliability tests. Only 10% of equipments go through these tests. They include quality control, electrical tests and some environmental tests. c) Class C test: These are carried out on 1% of the components. All the environmental tests are performed. If any failure is seen, the component must be redesigned. Also the customer must be supplied with modified goods. This test comes in picture for bulk production only. FAILURE RATE GRAPH Failure rate graphIt is the failure versus time graph. The infant morality is the critical period. It is due to: Weak component Manufacturing defect This is the area where the producer tries to cover in the warranty period. The repeated failures are detrimental to a company’s reputation as these are eliminated by screening while in manufacturing stage. The other screening is the stress screening method. This consists of: a) HUMIDITY TEST: Humidity is created with the help of boilers and fans in the chamber. Required temperature and duration of the tests are selected as per the specified BEL standards. b) ALTITUDE TEST: The conditions such as very low temperature (created with the help of cooling systems) and very low temperature and pressure (created with the help of a vacuum pump) are maintained in a chamber. These conditions are comparable to those at high altitudes where the products have to work. c) AGEING AND THERMAL SHOCKS: One cycle of ageing is of 7 hours. Ageing is done to relieve the stresses developed in the PCB due to blazing, welding, riveting etc. The sample is first kept at ambient temperature (250 degree Celsius) and then cooled to -400 degree Celsius. 25

d) BUMP TEST: The sample is given bumps in one direction only, with the help of machine. The number of bumps to be given is set with the help of proper switches. The sample is operated after giving bumps. If it works properly, it is passed. e) VIBRATION TEST: The sample is subjected to vibrations. Required frequency and amplitude for vibrations is selected accordingly. f) SALT SPRAY TEST: Salt solution is sprayed in a chamber. The specimens are hanged in the chamber. The test helps to decide any corrosion that takes place due to spraying of solution. g) RAIN TEST: In this test, conditions are created such that the sample is made to bath in heavy rain, so that if any problem arises in the sample due to rain that can be sorted accordingly. h) DROP TEST : The sample is made to survive in such a environment where there is possibility of snow fall. Such conditions are created in a chamber, to sort out any problem arises due to this. i) ROADABILITY TEST: While doing bump test, bumps are given to the sample in unidirectional only. But in the roadability test, bumps are given to the sample in all the directions. It means that the test is being carried, considering the device to be moving in a zigzag manner on an uneven road. For e.g. in sand or in water etc. This test helps to make out any fault or loosening of components while moving the specimen from one place to another. j) BOMB TEST: This is a test conducted for special types of samples. In this the samples are exposed to a situation like a bomb blast and it is checked whether the sample is able to bear the bomb explosion. WALK IN CHAMBER A very huge used for conducting humidity and temperature tests. The size of the chamber is such that a person can easily walk into it. It is for large sized specimens.

PCB FABRICATION PCB is abbreviated form of printed circuit board. As the name suggests, in a PCB the electrical circuit is printed on a glass epoxy board. This reduces the complex writing network whose trouble shooting in case of shorting or misconnection is not easy. PCB fabrication is mostly done for house requirements. It also takes some external jobs. Types of PCB’s

Single Sided: Having circuit pattern only on one side of the board. Double Sided: Having circuit pattern on both sides of the board. Multilayered: Having many layers of circuit. BEL – Ghaziabad

produces only single-sided and double-sided PCB’s.

FABRICATION OF SINGLE SIDED PCB’s: 1. A copper clad sheet is taken. It is cleaned and scrubbed. 26

2. The sheet is laminated with a photosensitive solution. 3. Positive photo paint of the required circuit is placed over the laminated sheet and it is subjected to the UV light. As a result the transparent plate gets polymerized and the opaque part remains unpolymerized. 4. The plate is now dipped in solution in which the non-polymerized part gets dissolved. 5. Tin plating is done on the tracks obtained. 6. Lamination of the plate is removed (stripping). 7. The unwanted copper from the plate is also removed by dipping it in the solution that dissolves copper but not tin (etching). 8. Now drilling is done on the paths where the components are to be mounted. This process fabricates PCB. P C B MANUFACTURING PROCESS: 1. Copper clad 2. Drill location holes 3. Drill holes for T.H.P. (Through Hole Plating) 4. Clean scrub and laminate 5. Photo print 6. Develop 7. Copper electroplate 8. Tin electroplate 9. Strip film 10. Etch and clean 11. Strip tin 12. L.P.I.S.M. (Liquid Photo Imageable Solder Mask) 13. Photo print 14. Develop 15. Thermal baking 16. Hot air level 17. Legend marking/Reverse marking 18. Route and clean But these PCB’s have the following disadvantages: Due to very narrow spacing between adjacent tracks, there may be a chance of short circuit if the soldering is done by hands between the components on opposite side. Moisture or dust between the gaps may disrupt smooth soldering. These disadvantages are overcome by soldered mask PCB’s. in the later one an additional film is put on the earlier fabricated PCB, leaving points where components are to be soldered.

27

TEST EQUIPMENT & AUTOMATION TEST EQUIPMENT SUPPORT (TES) Main functions are: Develops technical support to other departments. Repair of equipment in case of failure. Maintenance of equipments. Periodic calibration of equipments. Provide technical support to other departments. This includes: 1. Handling requests from the other department for equipments. 2. Storage of rejected equipments. 3. Approval of equipments to be purchased.

This section deals with testing and the calibration of electronic equipments only the standards of this department are calibrated by National Physics Laboratory (NPL). AUTOMATION TEST EQUIPMENT (ATE) 1. Component testing gives faults of various discrete components of a PCB. 2. Integrated circuits tester tests various IC’s. 3. Functional testing compares output to decide whether the function is being performed to the desired level of accuracy.

WORKS ASSEMBLY This department plays an important role in the production. Its main function is to assemble various components, equipment’s and instruments in a particular procedure. It has two sections, namely: 1. 2.

PCB assembly Electronic assembly

In PCB assembly, the different types of PCB are assembled as per BEL standards. PCB is received from the PCB department on which soldering of component is done either by hand soldering or wave soldering. HAND SOLDERING: WAVE SOLDERING:

In case of hand soldering, soldering is done manually. Wave soldering is a procedure in which PCB’s are fed to the wave soldering machine from the opening on one side and the soldering is done by machine and after the soldering is done PCB’s are collected from the another opening of the machine and after that cleaning is done.

28

The PCB’s are than send to testing department for testing according to the product Test procedure issued by the D&E department. After testing PCB’s are lacquered and Send to the planning store for storage. In electronic assembly, the cable assemblies, cable forms modules, drawers, racks and shelters are assembled. Every shelter (e.g. - DMT) is made of racks, racks are made up of drawers, drawers are made up of modules and modules are made up of PCB’s, cable assembly and cable forms. Every module or drawer before using in next assembly is sent for testing according to their PTP. Shop planning collects the purchase from the IG store, takes fabricated parts, PCB’s etc. from planning stores and issued to the assembly department as per the part list of the assembly to be made. The documents issued to the assembly are: KS PL CL WL WD GA

: : : : : :

Key Sheet Parts List Connection List for cable form Wiring List for modules Wiring Diagram General Assembly diagram

This department has been broadly classified as: 1. WORK ASSEMBLY RADAR e.g. : INDRA-2 , REPORTER ,CAR 2. WORK ASSEMBLY COMMUNICATION e.g. : EMCCA , MSSR , MFC EMCCA: EQUIPMENT MODULAR FOR COMMAND CONTROL APPLICATION MSSR: MONOPULSE SECONDARY SURVEILLANCE RADAR MFC: MULTI FUNCTIONAL CONSOLE The stepwise process followed by work assembly department is: 1) 2) 3) 4)

Preparation of part list that is to be assembled. Preparation of general assembly. Schematic diagram to depict all connection to be made and brief idea about all components. Writing list of all components.

METHOD OF PCB PROCESSING 1. 2. 3. 4. 5.

Tinning Preparation Mounting Wave soldering Touch up 29

6. Quality control 7. Ageing 8. Testing 9. lacquering (AV) 10. Storing SURFACE MOUNTING TECHNOLOGY The works assembly has a totally computerized section of PCB assembling of SMD (Surface Mounting Device). In this section the operation of PCB assembling is totally controlled by computers. The various steps taken in computer PCB assembling of SMD’s are as follows: 1. Application of solder paste: Solder paste is applied onto the places on PCB where the SMD’s are to be soldered. This is done by computer controlled machine. The program is loaded in the machine; it reads the program and applies the solder paste at the required place. 2. Fixture of SMD’s: a) The SMD’s are fixed at the right place on PCB by another computer controlled machine. b) The components (SMD) are first fed to various feeder lines that are attached to the machine and the related software and program is loaded in computer. c) There is a provision for a camera also so that we can monitor the entire operation. d) The PCB is then fed to the machine. e) When the appropriate command is given to the computer, it initiates the machine attached to it f) The machine picks the correct SMD from the feeder line and fix it at the right place on the PCB and within seconds all SMD’s are fixed on the PCB. 3. Thermal Baking: After the fixture of SMD’s, thermal baking is done. In this the PCB is fed to the oven and after 10 to 20 minutes PCB is taken out. Surface Mounting Device (SMD) does not require any hole on PCB as they are mounted directly on the PCB. The pins of SMD components are called ’legs’ as they have leg like structure unlike simple components that have straight pins that are soldered in the holes on the PCB manually. NOTE:

SHOP ORDER Process Sheet (assembly) All operations fill the work order and shop order in operator’s time card (OTC). They punch the time of starting the job and its finishing time. By this productivity services calculates the time taken to complete the job.

30

Efficiency = time allotted in shop order

X 100 Actual time taken Time allotted is so called standard hours. This deals with the assembly of common projects e.g. DMT, 2 GHz radio relay, Mobile tropo, Static RRD etc.

MAGNETICS This department manufactures all types of transformers and coils that are used in various equipments manufactured by BEL. This department basically consists of four sections: 1. Planning section 2. Mechanical section 3. Moulding section 4. Inspection section The D&E department gives the following descriptions to the magnetics department. They are as follows: Number of layers Number of turns Type of winding Gap in core Insulation between layers Ac/dc impedance Dielectric strength Electrical parameters and Earthing The various transformers being made are: Open type transformer Oil cooling type transformer Moulding type transformer PCB moulding type transformer The transformer is mechanically assembled, leads are taken out and checking of specification is done. Winding machines are of three types: Heavier ones- DNR for 0.1 to 0.4 mm diameter LC controlled machines Torroidal machines having 32 operations from winding to mechanical assembly. 31

The various types of windings used are: Hand winding Torroidal winding Sector winding Pitch winding Variable pitch winding Wave winding Two main types of core used are: E-type for 3-phase C-type for single phase Following procedure involved in the manufacture of the transformer is as follows: 1. 2. 3. 4. 5.

6.

7. 8. 9. 10. 11.

Formers of glass epoxy Winding Core winding Varnishing Impregnation – In this process various varnished coils are heated, then cooled, reheated and put into vacuum. Then air is blown to remove the humidity. Moulding – Araldite (a certain type of strong glue) mixed with black dye is used to increase mechanical as well as electrical strength. Moulding is done at 120 degree Celsius for 12 hours. A RDB compound is used for leakage protection. Oil is then boiled at 70 to 80 degree Celsius under vacuum condition to remove air bubbles trapped inside during manufacturing process. After this the coils are dipped in varnish and core is attached. Painting Mechanical assembly Termination Stenciling Testing – Dielectric testing (both ac/dc) is done at 50 KV voltage is applied for a minimum of one minute. During inspection, the following characteristics are checked: a. b. c. d. e.

Turns ratio DC resistance for each coil Inductance No load voltage Leakage

This section the material used for making transformer is Bakelite comprising male and female plates which are joined alternately to form a hollow rectangular box on which winding is done. Winding is done with different material and thickness of wire. The 32

winding has specified number of layers with each layer having a specified number of turns. The distance between the two turns should be maintained constantly that is there should be no overlapping. The plastic layer is inserted between two consecutive layers. Types of Windings: 1) Layer Winding 2) Wave Winding 3) Bank Winding Different types of windings are done to control some parameters such as inductance and capacitance. Varying the spacing between the two turns can vary these parameters. Two consecutive turns act as capacitor. As gap between the turns increases the capacitance decreases and inductance increases. Since capacitance is inversely proportional to the gap between the plates of capacitor and inductance is directly proportional. After winding the core is inserted between the primary and secondary. Contact leads are taken out and molding is done for maximum heat dissipation. Rubber solution is used to give strength to the wires, so that they cannot break. This is done before molding. Varnishing is done as anti fungus prevention for against environmental hazard. After compilation of manufacturing process it is sent for testing. Different parameters such as inductance, capacitance efficiency, turns ration, continuity are tested.

QUALITY CONTROL WORKS According to some laid down standards, the quality control department ensures the quality of the product. The raw materials and components etc. purchased are inspected according to the specifications by the IG department. Similarly QC works department inspects all the items manufactured in the factory. The fabrication inspection checks all the fabricated parts and ensures that these are made as per the part drawing. Plating, Painting and stenciling etc are done and checked as per the BEL standards. The assembly inspection department inspects all the assembled parts such as PCB, cable assembly, cable form, modules, racks and shelters as per latest documents and BEL standards. The mistakes in the PCB can be categorized as: D&E mistake Shop mistake Inspection mistake A process card is attached to each PCB under inspection. Any error in the PCB is entered into the process card by certain codes specified for each error or defect. After mistake is detected, following actions are taken: Observation is made. Object code is given. 33

Division code is given. Change code is prepared. Recommended action is taken.

RADAR ASSEMBLY This deals with the assembly of RADARS, e.g. INDRA-I, INDRA-II, FLY CATCHER, EMMCA, IRMA, REPORTER, CAR etc. The main projects under construction are: CAR

In RADAR section RADAR being tested is REPORTER, FLY CATCHER, EMCCA, etc.

34

PROJECT

PROJECT

:

RADAR (RADIO DETECTION AND RANGING)

35

PROJECT: AN OVERVIEW

RADAR AND ITS COMPOSITE ENVIRONMENT 36

INTRODUCTION The two most basic functions of radar are inherent in the word, whose letters stand for RAdio Detection And Ranging. Measurement of target angles has been included as a basic function of most radar, and Doppler velocity is often measured directly as a fourth basic quantity. Discrimination of the desired target from background noise and clutter is a prerequisite to detection and measurement, and resolution of surface features is essential to mapping or imaging radar. The block diagram of typical pulsed radar is shown in Figure. The equipment has been divided arbitrarily into seven subsystems, corresponding to the usual design specialties within the radar engineering field. The radar operation in more complex systems is controlled by a computer with specific actions initiated by a synchronizer, which in turn controls the time sequence of transmissions, receiver gates and gain settings, signal processing, and display. When called for by the synchronizer, the modulator applies a pulse of high voltage to the radio frequency (RF) amplifier, simultaneously with an RF drive signal from the exciter. The resulting high-power RF pulse is passed through transmission line or waveguide to the duplexer, which connects it to the antenna for radiation into space. The antenna shown is of the reflector type, steered mechanically by a servo-driven pedestal. A stationary array may also be used, with electrical steering of the radiated beam. After reflection from a target, the echo signal reenters the antenna, which is connected to the receiver preamplifier or mixer by the duplexer.

37

A local oscillator signal furnished by the exciter translates the echo frequency to one or more intermediate frequencies (IFs), which can be amplified, filtered, envelope or quadrature detected, and subjected to more refined signal processing. Data to control the antenna steering and to provide outputs to an associated computer are extracted from the time delay and modulation on the signal. There are many variations from the diagram of Figure that can be made in radars for specific applications, but the operating sequence described in the foregoing forms the basis of most common radar systems. This project provides the basics of radar and many of the relationships that are common to most forms of target-detection radar. The emphasis is on the goals established for the radar or the system that contains the radar.

38

SYSTEM DEFINITION

CENTRAL ACQUISITION RADAR 39

INTRODUCTION The designed Radar would be a stand-alone all weather 3D surveillance radar. The radar operates in S-band and is capable of Track-While-Scan [TWS] of airborne targets up to 130 Kms, subject to line-of-sight clearance and radar horizon. The radar employs Multibeam coverage in the receive mode to provide for necessary discrimination in elevation data. It employs 8 beams to achieve elevation coverage of prescribed margin and a height ceiling of prescribed margin. The antenna is mechanically rotated in azimuth to provide 360 coverage. To get an optimum detection performance against various class of targets, different Antenna Rotation Rate [ARR] RPM modes are implemented and these can be selected by the operator. The unique feature of the radar is, its operation is fully automated and controlled from a Radar Console with sufficient menus, keys and Hot keys. The designed Radar is an offshoot of the fully and successfully developed and demonstrated radar called as 3D Central Acquisition Radar (3D-CAR). 3D-CAR is designed to play the role of medium range surveillance radar mounted on a mobile platform. The radar carries out detection, tracking and interception of targets with an RCS of 2m2 upto 130 Kms in range. The antenna can be manually positioned at different look angles in steps. In the receive mode the eight beams cater for a height coverage of required margin. The IFF antenna is placed atop the main antenna and it integrates the IFF for including of IFF data with the Primary Radar Data. The RDP (Radar Data Processor) is implemented on a SBC and is fully software-based system with adequate memory and external interfaces to handle upto 150 target tracks. Robust algorithms for filtering are used to lock on to maneuvering target upto 6g without loss of tracking. LAN interfaces are used to communicate with external systems. High-speed data transfer of target parameters can be done. This helps in data remoting upto a distance of 500 mtrs that can be extended with suitable repeaters. Facility for manual track indication for low speed targets and targets in heavy clutter zones are available to the console operator. The color display has features for monitoring of radar performance, the radar output selection for radar modes of operation. Interfaces to radar control signals are built-in. The Radar generates different videos viz., Analog and Digital videos at the Receiver and Signal Processor. These are interfaced to the display over dedicated lines and displayed In addition to providing real time data on screen for viewing, the consoles will provide facility for training controllers/operators/ technical crew. The system is capable of creating targets and assigns values for range, azimuth, height and speed as defined by operator. It will enable the operator to control the motion of these targets for gaining/ loosing height, turning left/right, cruising, and rolling out. The software running on console will provide an online handy aid, for target interception. The training part of the software will be active as an offline facility or with tracked targets in real time. The offline mode will be capable of using recorded data. 40

Salient features Radar are: 1. 3D Surveillance Radar 2. S-BAND 3. Capable of Track While Scan (TWS) of airborne Targets upto 150 Kms 4. Coherent TWT based Transmitter 5. Planar Array Antenna with low side lobes 6. Multiple beams in the receive mode. 7. ECCM (Side lobe blanking, Frequency Agility, Jammer analysis) 8. Integrated IFF 9. System operation is controlled from Radar Console in Data centre. 10. Redundant Power supply unit with UPS backup. I have been working in Transmitter section of CAR developed by BEL, Ghaziabad. Before explaining the technical details of Transmitter of Radar, it is necessity to understand the general working of Radar. This designed Radar has the following subsystems: 1. 2. 3. 4. 5. 6. 7. 8.

Multi-beam Antenna system Transmitter Receiver Signal Processor Radar Console Data centre Mobile Power Source IFF System

The Multi beam antenna system for Radar is planned to be realized to have 360 Coverage in Azimuth and prescribed coverage in elevation. The antenna will have a wide beam in transmit mode and eight simultaneous narrow beams in receive mode to give prescribed coverage in elevation. The requirement of Transmitter is to amplify the pulsed RF signal from few watts to high power RF signal while maintaining the phase noise (additive noise) to its minimal as demanded by the system. The Low Power Microwave Subsystem includes the major portion of Receiver RF System of the 3D-Radar. The Multibeam Antenna receives the reflected signals from the target. These signals are amplified by the Low Noise Amplifier, down converted to IF Frequency using two-stage superheterodyne receiver. The IF Output is given as final output of the Low Power Microwave Subsystem to be further processed in the signal processor. Customization of the console for user application will be carried out in the software and hardware. The Display Console is the operator's center to initialize, remotely setup, operate, observe, and diagnose the radar, both online and offline. The Primary and

41

secondary radar video, target tracks, plots, geographical map along with other diagnostic and configuration messages are presented in 2D. The Signal Processor for Radar is realized as 8 parallel and identical channels. Each Signal Processor accepts IF videos from the corresponding RF Receiver channel (8 beams + 1 Omni) and provides detection reports to the Radar Data Extractor (RDE) independently for these 8 channels. The detection reports for each channel must have range and strength information in addition to the associated flags. Jammer data is also to be reported. Configuration and mode control, diagnostics and status reporting are done through a Radar Controller (RC). The electronic equipment cabin is provided for installation of transmitter, signal processor, receiver, display console, IFF equipment and a working place for maintenance. The Data centre is required to provide basic functions like viewing of the air picture, remote operation of radar, and radio communication. At the same time the cabin provides shelter for the operators, with reasonable level of comfort and, protected against heat, rain and dust. Mobile power source is required to provide the main supply to Radar and Data Centre for electronic and mechanical units of Radar including air conditioning units. The Identification Friend or Foe (IFF) system is a good example of a secondary radar system that is in wide use in the military environment. A great deal of valuable information can be provided to the secondary radar by the target’s transponder. The transponder provides an identifying code to the secondary radar that then uses the code and an associated data base system to look up aircraft origin and destination, flight number, aircraft type and even the numbers of personnel onboard. This type of information is clearly not available from a primary radar system.

42

TRANSMITTER

43

Transmitter INTRODUCTION The transmitter for Radar is Coherent MOPA type that operates in S Band using TWT as the final amplifier. The transmitter is used to amplify the pulsed RF signal from low power RF signal to High power RF signal as demanded by the system. TWT dissipates large amount of energy, therefore it is subjected to both air and liquid cooling. The input to the transmitter is 3 phase, 415V, 50 Hz, which is later amplified to the optimal value for driving the TWT amplifier. A generalized diagram here briefly explains the inputs and outputs of the transmitter.

3-phase,400V,50Hz 3-channel liq cooling in 3-channel liq cooling out Air cooling in

ROHINI TRANSMITTER

RF out

Air cooling out BIT0 SP signals BIT1 RF PULSE Dry air

System status

PRETRG GRID PULSE

RF input

Input output diagram of Transmitter

The transmitter is designed to operate in the following modes defined as adequate controlled states

44

Transmitter modes a) OFF

: All subsystems switched OFF

b) Cold Standby

: Only LVPSU’s , TWT heater and Grid biases are switched ON. No High Voltage applied.

c) Hot Stand By

: High Voltages applied, No RF and No grid Pulsing.

d) Transmission

: RF power delivered to Antenna / Matched load.

i) Full Power mode

: Full RF Power delivered to the Antenna

ii) Reduced Power mode

: The transmitter is operated at 1/10 of its full power based on the selection by the user.

iii) Fail safe mode

: A low power at required duty delivered to antenna through Solid State Power Amplifier when liquid cooling fails.

Modes are selected by the operator.

Transmitter control a) Local

: To control through control panel on the transmitter.

b) Remote control

: To control from the operator console through control interface RS422.

45

MECHANICAL DESCRIPTION Three rack configuration of Transmitter describes complete functionality of Transmitter

1. Control Rack  Monitoring panel  Control panel  Synoptic panel  CPC  Inverter 2. High Voltage Rack  FDM (Solid state Switching)  Cathode Assembly  Collector Assembly  Blower Unit  Heater Unit 3. Microwave Rack  TWT  RF Plumbing  RF Drive Unit  SSPA  ION Pump Controller

46

CONTROL RACK

HIGH VOLTAGE RACK

MICROWAVE RACK

47

GENERAL DESCRIPTION The Transmitter amplifies the pulsed RF signal from few Watts to many KW while maintaining the phase noise (additive noise) to prescribed margin as demanded by the system. In addition, a Solid State Power Amplifier (SSPA) is provided, as a stand by option, to ensure fail-safe mode, in case of failure of liquid coolant. It employs a Traveling Wave Tube as final power amplifier. Low power amplifier stage (RF Driver) amplifies pulsed RF signal from 1mW (0 dBm) to few W which is necessary to drive the TWT amplifier. The RF Driver stage uses a PIN attenuator transistor followed by power amplifiers to amplify RF signal. This is followed by an isolator. The isolator protects the transistor power amplifiers against excessive reflections from TWT. The signal is thereafter passed through a DC, a RF switch and an attenuator to cater for the three transmission modes. The sampled output of the DC is used for monitoring the input RF signal to the TWT. The RF Driver output is given to the input of TWT, which amplifies the pulsed RF signal from few Watts to a level of many kW at the TWT output. High power RF plumbing components are connected at the output of TWT. The TWT output is given to an arc detector followed by a ferrite circulator. The Ferrite circulator is used to protect the microwave tube against failure /damage due to reflected power in case of excessive VSWR at Antenna input port. The output of Ferrite Circulator is given to High Power Dual Directional Coupler (DDC), which is used for measuring the transmitted and reflected power. If reflected power exceeds the specified limit of VSWR, a video signal is generated to cut off the RF drive through control and protection circuit. The output of the DDC is given to Antenna. To connect all the components in the required form, flexible sections, E-bends, H-bends and straight sections are used. Control and Protection Circuit ensures the sequential switching ON of the transmitter, continuous monitoring and interlocking of various parameters, detection and indication of errors. All these are achieved by dedicated hardware and software. Synoptic Panel consists of LEDs, switches and LCD display. LEDs are used to show the status of the transmitter. They also show the fault, if any, in the transmitter. The LCD display, mounted on Synoptic panel, is used to show the value of cathode voltage & current, collector voltage and current. It also displays the Filament voltage and current, Grid + ve and -ve voltages and RF forward power. The Inverter unit converts the incoming ac supply to DC and then converts the DC to high frequency AC (Pulse width controlled square wave) operating at 20 kHz. The output of the Inverter unit is given to HV rack for generation of Cathode and Collector voltages of the TWT amplifier.

48

High Voltage Power Supply unit (HVPSU) is used to supply high voltage to collector and cathode of the TWT. The Floating Deck Modulator (FDM) unit generates filament voltage with surge current protection and also generates grid +ve and grid -ve voltages. Switching of grid voltage as per pulse width and PRF requirements are also provided by FDM. Cooling Unit is used to cool the various components of the transmitter. The TWT, High Power Ferrite Isolator, high Voltage Power supplies and RF dummy load are cooled with de-ionized water and ethylene glycol mixture. Forced air-cooling is employed to cool other components using ambient air which is filtered to ensure dust free air. The Dry Air unit ensures that the wave guide is at all times pressurized and dry.

SSPA

RF DRIVER

TWT

COUPLER

W/G SWITCH TO ANTENNA

FIL., GRID, CATHODE, COLLECTOR SUPPLY

LIQUID COOLING

FWD AND RFLECTED PWR MONITOR

49

DETAILED DESCRIPTION

Control Rack

Control Rack provides the protection controls and indications. As mentioned before, this rack is divided in five sections according to their functions.

1. Monitoring Panel The Monitoring Panel provides monitoring ports for measuring of trigger signals to the transmitter, liquid cooling status, collector and cathode Inverter currents and bridge voltages. It provides an emergency switch OFF button and digital displays for collector and cathode voltages.

50

2. Control Panel The control panel controls the power supplies of various units such as the fans, heater, LVPSU, Inverter, Modulator, RF Drive Unit and SSPA. The hour meters for filament, EHT and RF are also placed on the control panel.

3. Synoptic Panel Synoptic Panel is located above the Control and Protection Circuit (CPC). It indicates the faults and status signals generated by CPC. Green LEDs represent status signals while Red LEDs represent faults. Audio alarms are also provided to indicate faults.

4. Control and Protection Circuits The CPC ensures the sequential switching ON/OFF of the transmitter, continuous monitoring and interlocking of various parameters, detection and indication of errors.

CPC BLOCK DIAGRAMO

RF DRIVER RF PARAMETERS & DIR COUPLERS

SSPA CTRL CARD

CROW BAR SIGNAL

C O M P A R A T O R C A R D S

EHT VOL SAMPLES HV POWER SUPPLIES EHT PROBES CROW BAR

EHT CURR SAMPLES BEAM CURR, COLL CURR CATH CURR

TWT LIQUID COOLING UNIT

COOLING CONDITIONS

SWITCH ON COMMANDS TO SOLID STATE RELAYS FOR HV, MAINS ON

3Ø 50Hz 400V AC IN

P T O

RADAR TIMINGS

STATUS

STATUS

I S O L A TMICRO O RCONT C ROLLER ACARD R D

TO RADAR CONTROLLER

GRID

PULS E INPUT POWER STATUS

POWER DISTRIBUTION

TIMING CARD

OPTICAL LINKS& F/V CARD

SWITCH ON COMMANDS

LCD INTERFACE

FIL VOL & I SAMPLES GRID VOL SAMPLES

FLOATING DECK MODULATOR AT - 45KV

FRONT PANEL WITH SWITCHES, LED & LCD DISPLAY

CPC card Configuration comprises of ten different cards.   

COMPARATOR CARD-I COMPARATOR CARD-II COMPARATOR CARD-III 51

      

TIMING CARD SSPA CTRL CARD F TO V CARD OPTPISOLATOR CARD MC-I CARD MC-II CARD OPTO TRANSCEIVER CARD

5. Inverter The Inverter is the main functional block of the (cathode/collector) HV Power supplies. A number of indicators are placed on the front panel of the Inverter unit.          

AC-DC CARD CATHODE PROTECTION CARD CATHODE IGBT DRIVER CARD COLLECTOR PROTECTION CARD COLLECTOR IGBT DRIVER CARD SOFT START CARD TEMPERATURE SENSOR CARD ZENER CARD (For Cathode and Collector) CURRENT SENSOR CARD (For Cathode and Collector) CURRENT SENSOR (PEAK) CARD (For Cathode and Coll.)

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High Voltage Rack

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This is central block of the transmitter, where cabins for HV Cathode and Collector are assembled. Above this is a FDM block where all the cards are installed and insulated from the transmitter that works on HV. As mentioned earlier, High Voltage Rack is divided in five more units. Each unit has its defined working. 1. FDM (Floating Deck Modulator)

230V- ph-ph 50Hz

Isol atio n tran sfor mer

FIL

FDM

GRID

To TWT

CATHODE

To CPC Optical links

Fil Voltage Fil Current Grid Positive Grid negative

From CPC Grid Pulse Optical link

Further in FDM there seven functional cards, which are as follows: • • • • • • •

LVPS Card Grid Bias Card Positive Grid Supply Card Switch Card Filament Supply & Timer Card-1 Filament Supply & Timer Card-2 V to F Card

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Microwave Rack

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The functional block diagram of microwave unit is shown in the figure. The microwave unit consists of the following functional assemblies:

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       

Low power amplifier [RF drive unit] High power TWT amplifier RF Plumbing, Wave-guide switch & dummy load Solid state power amplifier (2 kW) for low power transmission mode TWT ion pump supply Resistive TWT anode divider Microwave power measurement circuits Air cooling components

Low Power Driver for TWT (RF Driver) Low Power amplifier stage (RF Driver) amplifies pulsed RF signal from 1mW (0dBm) to few Watts power, necessary to drive the TWT amplifier. This low power RF Driver consists of following stages:

(a) Transistor Power amplifier 0dBm to 37dBm

: Amplifies the Pulsed signal from

(b) Separating isolator against excessive reflections

: Used to protect the transistor power amplifier from TWT.

(c) Directional Coupler

: To monitor the power available at the input TWT.

Figure given below shows the Input and output diagram of RF Driver

RF IN

To SSPA i/p To TWT i/p

Control i/p from CPC

RF DRIVER

To CPC for RF drive fail protection TWT drive MONITOR

High Power Microwave Stage High Power Microwave consists of mainly TWT, which amplifies the pulsed RF signal received from the RF Driver of few watt power to a level of 120 -185 KW at the TWT 57

output followed by High Power RF plumbing components. Figure given below shows the block diagram of high power chain. High Power RF stage consists of:      

Traveling Wave Tube (TWT) Ferrite Circulator Dual Directional Coupler (DDC) High Power dummy load Wave guide channel Wave guide switch

Traveling Wave Tube (TWT) TWT is available in three different constructs, these are listed here: 1. Helix TWTs These amplify relatively to low power levels, but it provides a very wide bandwidth, both in octave and multioctave. 2. Ring Loop / Ring Bar TWTs

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These amplify at relatively high power levels, and provide a wideband, that is of 25 % of bandwidth. 3. Coupled Cavity TWTs This TWT in family of TWTs provides highest amplified power levels. It has relatively narrower bandwidth that is 10% to 15 % of bandwidth. TWT is the main power amplifier used in the transmitter. A coupled cavity TWT type is selected for this transmitter. The collector in the TWT is further divided as: 1. Ground collector 2. Depressed collector   

Single stage depressed collector Double depressed collector Multi stage depressed collector

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LIQUID COOLING RF IN

RF OUT

-10V,10A

+800 -600

3kV,ION PUMP

-45kV,5kW

33kV,18kW

TWT POWER SUPPLIES CONNECTION DIAGRAM

Ferrite circulator Ferrite circulator is used to protect the microwave tube against failure / damage due to reflected power in case of excess VSWR at Antenna input port. The Four port Ferrite circulator type is used as an isolator. Dual Directional Coupler High Power Dual Directional Coupler (DDC) is used for measuring the Transmit Power and reflected power. If reflected power exceeds the specified limit of 2:1 VSWR, video signal is generated to cut-off the RF drive through control and protection unit. High power dummy load High power dummy load is used to test the transmitter with out connecting the antenna during standalone testing. Wave-guide Channel To connect all the components in the required form, flexible sections, E-bends, H-bends and straight sections are used. Standard W/G sections are being used for this purpose. Microwave Channel (High Power) 60

Figure below shows the schematic diagram of the microwave channel. The microwave channel consists of high power amplifier using TWT amplifier and high power RF plumbing components.

Schematic Diagram of microwave channel Antenna channel matching requirements Mismatch in the antenna channel, being the load of the transmitter, significantly decides of VSWR as seen from the TWT output. According to the Antenna System requirements, matching of the antenna channel at the transmitter output should be equivalent to VSWR prescribed margin in frequency range of S band in which the radar operates. It seems to be difficult to satisfy, because the TWT should operate at VSWR