iete-sf report 2015-16...iete-sf report 2015-16 the academic year 2015-16 saw a series of some...
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IETE-SF REPORT 2015-16
The academic year 2015-16 saw a series of some really successful events
including a series of seminars. We organised two seminars with two offbeat
themes. The topics covered were:-
1) Technical Paper Presentation
2) Applications of Embedded Systems in Industry
TECHNICAL PAPER PRESENTATION SEMINAR
The Technical Paper Presentation seminar was held on 27th of February,
2016. This seminar was given by Dr. Amit Deshmukh, HoD, Department of
Electronics and Telecommunication, DJ Sanghvi College of Engineering.
Given below are point-wise details of the matter covered in this seminar.
Technical Papers
- Log book for mini-projects
Types of Articles
- Research article
- Review article
- Letter (for fast communication research paper)
- Communication reply (In order to reply to comments on discrepancies.)
Paper for Conference
While writing a paper for a conference we need to take into consideration,
the following points:
- Selection of conference: International/National
- Organizing committee
- Scope of conference (Theme)
- Topics covered
- Number of years of conference
- NCC organised by IITs and IISc
The digital libraries available for technical paper writing are- IEEE Xplore,
Springer, Elsevier (increases citation of paper)
There is another common doubt among students:
“What care to take while sending a paper to a journal or a conference?”
ANS: Papers can be sent to either a conference or a journal. Conference gives
idea of the work but there is a page limit. The paper for conference is not
supposed to be detailed. For a journal, a full length with additional data is to be
submitted.
Template- One or two columns, depending on where the paper is to be
published, i.e. depending on format of digital library.
Now, there can two types of articles:
a) Research article- own contribution.
b) Review article- not necessarily your own contribution. Review several
papers on a particular topic. You will be comparing your paper with similar
papers and will be coming up with a conclusion.
- Invited paper from relevant areas from eminent researcher
- Proper referencing needs to be given.
- The books are published based on reviews carried out by referring
different papers.
- Your own comments
- In-depth review of at least 10-15 years’ papers.
- Author comments are necessary.
- Demerits and merits.
- Advancements that need to be done in the reported work, needs to be
focussed upon.
- Text/figures carries reference number ( may not be your own
contribution0
- Literature survey- PG/PhD thesis, forms a base for a research/review
article
PAPER CONTENT
- Title- not too long. Must convey the concept and content information.
- Affiliation- Mention clearly. Parent Institute. Include guide’s name.
- Abstract- Should highlight the novelty in the proposed work(not more the
100-500 words)
- Keywords-Used to index the paper.
- Introduction- Previous work (literature survey) & proposed work. How is
simulation or measurement being done? Prototype in the end. Give
references everywhere.
- Main content- Divide the paper in appropriate sections to maintain the
flow of proposed work.
- Figures:- Non-lossy, TIFF, PNG format,300dpi( preparation of high
resolution image)
- Placement of figures- should immediately follow the relevant text-
Sometimes changes as per conference format.
- Restrict sub-figures to less than four
- Readable in print format
- Provide reference- if figures are from different sources.
- Content- Text/ figures should be as per area of research.
- Conclusion- highlight idea being presented and comparison with reported
work.
- Reference- Adequate in number that reports previous work in detail.
PAPER FOR JOURNAL
- IEEE, IEL,IJMOT,SPRINGER,ICJA, Science Direct
- Selection of appropriate journal-scope
- Type of paper
- Editorial board of the journal
- Impact factor
- Content
- Page limit and charge
- Status of paper
- For accepted papers
- Rejected papers
REVIEWER PERSPECTIVE
- Blind review (preferred)
- Title/Abstract
- Introduction
- Implementation
- Paper contents
- Figures
- Conclusion
- References
PAPER PRESENTATION- CONFERENCE
- Poster/Oral representation
- Both carry equal weightage
- Poster presentation-6 to 8 pages
- Oral presentation -15 to 20 minutes.
PLAGIARISM
- Software available to check plagiarism-Turnitin
- Content wise copy- Plagiarism
- Avoid using sentences which have been used in previous papers.
At the end of the event, we are sure that the students went home being more
excited and educated about writing papers then they were. It was a very
successful event with registrations for the event in upwards of 150 people.
EMBEDDED SYSTEMS SEMINAR
The embedded systems Seminar was held by Dr. Saurabh Mehta on 16th of March. This was another interesting seminar which gave us an insight of how the embedded systems form a base of every smart technology today. The seminar introduced us to some of the basic, yet highly potential embedded systems. The seminar began with a brief introduction of the Speaker, Dr. Mehta, who is an IIT-B alumnus and presently the founder and CEO of a firm which is into innovation of smart embedded systems based user friendly technologies. We were then showed a series of DIY projects and were encouraged to try out different projects, as it increases our subject knowledge, we can work upon higher versions of such projects to gain an extra edge over the others. This also makes us market ready, as we know things beyond the curriculum and also are aware of what the market needs! The seminar had an overwhelming attendance of over 110 students from the second and third year crowding a classroom of 60 students! This seminar opened the doors of a totally new world for us. The students inclined towards the research made the most out of this seminar. It was followed by a brief discussion session, where the students freely interacted with Dr Mehta. The session was concluded by a thanksgiving speech by The HoD of EXTC, Dr. Amit Deshmukh.
Industrial Visit to Reliance Textile Plant, Silvassa
Introduction
The Silvassa Manufacturing Plant of Reliance Industries Limited is India’s
1st ranked polyester manufacturing plant. This accounts for a great share, since
India stands second in polyester manufacturing, following China. 40 students
from the college were selected for the IV on a first come first serve basis.
This plant was built up in the backward integration process which lead to the
exponential growth of Reliance group.
In an effort to become self-sufficient in textile production, the Vimal textiles of
the Reliance group needed to produce its raw material on its own. Thus was
born, the Silvassa Textile manufacturing plant.
This plant produces primarily three types of yarns:
1) Partially Oriented Yarn (POY)
2) Fully Drawn Yarn(FDY)
3) Polyester Texturized Yarn (PTY)
The manufacturing capacity of this plant is over 2200 tonnes of yarn per day. Of
which, 900 tonnes consist of PTY.
The Silvassa manufacturing plant has proved its mettle in the textile industry by
bagging several awards which include The Sword of Honour of the British Safety
Council, Green-Tech award, Best CASHe Project Award, Quality surveillance
golden award, to name a few. It also has an ISO certification and the Okeo-Tex
certification for its products. It also holds the largest employee magnitude with
an on-plant workforce of 6000.
The CSR activities held by this unit are:
Pulse polio drives, school health camp, bone-mineral testing, blood donation
camp, cleanliness drives, safety drives, etc.
Downstream production line PFY project summary:-
STAGE I
CP (Condensed Polymer)
This stage produces the elementary raw material for all yarns. Polyester is
essentially a petrochemical product. When crude oil is fractionally distilled, one
of the products is naphtha. (Purified terephthylic Acid)PTA is a by-product of
naphtha. This PTA powder is mixed with mono-ethylene glycol (MEG) liquid to
form a slurry. This is then dehydrated to form a condensed paste and is sent to
the next stage. This process is done by poly-condensation, which eliminates the
time consuming and costly batch process. The product formed here is a complex
PTA-MEG.
Till now, the process was chemical oriented. Now, 2nd stage onwards we deal
with our field of interest, i.e. electronic automation.
STAGE II
Spinning unit and tune chamber:
The raw material obtained from the first stage is passed on to an esterifier unit,
where it is heated to around 280°C. The melting point of PTA-MEG is 259°C.
Thus, the molten complex is ejected through a sieve pump into the tune
chamber. Here, cool air at 21°C is blown onto the glass rod like thin filaments of
the molten complex. This cools them to room temperature. Then they are
coated with a finishing oil and sent to the spinning and winding station. Here,
we obtain the intermediate product of the process, i.e. POY (Partially Oriented
Yarn).It is quite elastic in nature.
STAGE III
POY PTY
This process is carried out by the automated AFK machine. The POY produced in
previous stage is brought in the form of bobbins to this section. Here, robotic
arms unpack the POY batches and feed them to the creel, which is a POY stack
unwinding station. Here, each bobbin is placed on an indexed creel and is sent
to the heating station of the same index number. This indexing simplifies
preventive maintenance. The unwound yarn is then sent to the heating
chamber. At high temperature the yarn expands. The heating tenure is decided
by the index number on the yarn which is scanned while unwinding. This process
is called Auto-Doffing. The expanded yarn is then sent to cooling section and
polishing section. Then, a combination of high pressure air jet and a compressor
act on the yarn to form nipped pattern as shown below. [unit: nips/m]
9000 meterof yarn= 500 Dinear (weight equivalent)
Thus, we obtain the PTY. The bobbins of PTY are of different sizes depending on
their use. These are then segregated into different batches accordingly and sent
to next stage.
STAGE IV
Inspection, quality check and packaging unit:
This unit has an automated quality check and packaging unit. Damage inspection
is done manually. This unit is fully governed by robotic machinery. Batches of
different size are automatically loaded onto shuttles. Theshuttles and the
running tracks have barcodes on them. This helps in locating every batch and
the operator has full control on the route to be followed by every batch. Every
shuttle has a photocell mirror on it. Thus, if a shuttle is moving from position A
to B and senses another shuttle in the proximity of B, it waits till that shuttle
crosses B. This also prevents overloading of any station in the whole unit. The
three routes taken by incoming shuttles are as follows:-
1) Damage inspection unit
2) Quality testing unit
3) Storing unit
After passing through all these units, the batches are further bifurcated for next
procedure. Some go for texturing, some for colouring and some are directly
packed.
TEXTURING:
The yarn formed is a water resistant yarn. In order to make it wearable, it is sent
to the texturing unit where its surface is ruptured in order to create air cavities
to enable ventilation. It resembles cotton. This textured yarn is much finer than
non-textured yarns.
COLOURING:
Colouring of produced yarn is needed when it is to be sent to textile industries.
Thereafter, the yarn can be used to make various synthetic linens like chiffon,
bassos, etc.
PACKAGING UNIT:
The main function of this section is quantisation and patterning of each bobbin.
This is carried out by WINGS i.e., Winding Integrated Godet Solution machine.
This machine is programmed according to required batch size. In any case, the
rpm needs to be maintained constant. Thus, the batch size and functioning
frequency (typically 20Hz to 220 or 420Hz) is altered. This machine has been
innovated in Germany. It is a high end, fool proof mechanism and one machine
costs almost 1Cr.
The machine quantizes each bobbin size and winds it by traversing mechanism,
i.e. in the shape of “∞”. This prevents slacking of yarn over the reel.
Patterning: It is repeating of patterns obtained by the ratio rpm/cpm which
should give an integer. Yet, in case of a low value of this ratio, critical operational
cases may appear. To avoid this, anti-patterning mechanism is also used.
Standard batch size of a WINGS machine is 3000m/min.
Remarkable features of the process:-
1) Auto-Doffing
2) Online testing for ultimate flow degree
3) Disk diversion: automated diversion of batch shuttles, leading to
notable reduction in TAKT time.
4) Harnessing of robotic arms for opening of raw yarn stacks and
palletizing of finish products to maintain sterility.
5) Barcoding for error-proofing and to keep a track if every batch.
6) Use of AWH to transport station from packaging area to reduce goods
loading efforts.
Plant details:-
1) Spread over an area of approximately 250 acres.
2) Produces almost 3,25,000 bobbins/day.
3) Homes a huge water reservoir which is used to for all purposes in the
plant.
4) A separate section for temperature control unit.
5) A separate water distribution and control unit.
6) Every unit has multiple escape routes in case of any emergency
evacuation.
7) A number of safety units are spread all over the plant as a part of
disaster control and management plan.
IETE INDUSTRIAL VISIT (17th March 2016)
Onida - MIRC Electronics Pvt Ltd, [Kudus village, Wada, Thane]
Introduction:
Onida was started in Mumbai in the year 1980 in affiliation with MIRC
Electronics. Since its inception, the brand has evolved into a multi-product
company with products ranging from television sets to home appliances like
microwaves.
This plant at Wada is no exception to the fact that over the years, the brand
wishes to establish itself as a global competitor in it’s domain. The plant is
completely self-sufficient, with even substances like thermocols ( used for
packaging purpose) being manufactured there itself.
It spans across 2,17,040 square metres. The location is strategically chosen in
such a way that it finds connectivity to the international airport in Mumbai,
which is 80 kms far, railway station Vasai being 45 kms far and the Jawaharlal
Nehru Port Trust located in Uran, from where majority of the export takes place,
being located 100 kms away.
There are three stages in the process of manufacturing:
1] Automatic Insertion
2] Complete knock-down
3] Semi knock-down (further divided into two stages I & II)
The company follows a strict organisational structure. They are firm believers of
moral values like commitment to society, fairness in employment sector and
encouragement to innovation.An overview of the manufacturing process is
shown in the flow chart.
AUTO INSERTION DEPARTMENT:
The heart of any television set, the processing unit or the PCB is fabricated in
this unit. An 8 layered PCB is used in this case. The main objective of this unit is
to help the facilitation of bonding between several components and the PCB
layer. The components are either glued or soldered to the PCB, to ensure that
their connection remains intact.
The process is known as ‘Surface Mould Soldering’ which consists of a series of
automated machinery, inter connected with the help of conveyer belts. A
computer program helps in assembling this machinery, and the desired work can
be done. The centre of the PCB is used as a reference point and likewise the
entire structure is soldered. A flipper is placed so that the components can be
placed on both the sides of the PCB. Generally, a chip ( IC ) is placed on the
Designing of
prototype
by R & D
5 models
produced,
quality and
other
parameters
tested.
Initial
production
of 25
samples
Pilot
production
of 100
samples
Mass
production
opposite side. The components such as capacitors, resistors and jumpers are
connected in this unit. The soldering machine can solder over 2000 minute joints
in 3 seconds.
Soldering is a warm process and a temperature of about 150` C is required.
A settling time of around 3 minutes is provided so that the bondage turns robust
and the chances of the components falling off are negligible.
Salient features of AI;
Highly efficient as human intervention is negligible.
The production rate is very high.
Owing to the smaller size of product to be synthesized, the unit is
compact.
Over 9000 PCBs pass through the unit daily.
COMPLETE KNOCK DOWN:
After passing through a series of automated machines, the PCBs, now with basic
components are brought into the next unit. This unit is an amalgamation of
manual work as well as automation. There are several lines, consisting of
conveyer belts.
These lines consist of technicians who manually place the components on
the PCBs. As the unit deals with both, Cathode Ray Tube televisions as well as
the Light Emitting Diode televisions, the circuitry is assembled as per the
requirement.
Several significant components such as transformers, frequency tuners, line
filters and transistor ICs are placed on the PCBs by the technicians. Audio/Video
jacks are also placed in this unit. A schematic circuit diagram is provided to each
of these technicians and they are evaluated on the basis of a simple technique
– less the faults, more the grades.
After having assembled these essential components on the board, again the
need for soldering arises. A unique method known as ‘Wave Soldering’ is
implemented this time. The PCB is made to pass through a chamber wherein a
wave of soldering material oozes out. The entire layout experiences this wave
and the areas required to be soldered get soldered easily. This takes place at
250` C.
At the end of this stage, a sample television box is available for experimenting
the readied layout. If any flaws are found, the PCB is sent back for repairing. This
helps in ruling out errors at a very early stage.
Salient features of the CKD department:
The unit consists of several lines, and the work is equally distributed
amongst the technicians.
The entire unit is clean, with no room for dust.
The co-workers work in a conducive atmosphere, with music being played
to sooth them.
SEMI KNOCK DOWN (I & II):
In this unit, the production reaches an intermediate stage and it is
completely synthesized thereafter. Here, the PCBs which were already equipped
with components in the earlier stages are now detached to the frame of the
television set. The frame or body or chassis is separately manufactured in the
plant itself, and it is fed to this unit with the help of conveyer belts.
There are technicians who assemble or mount the circuit on the frame.
The panel is placed on the board. Several other connections such as speakers,
and cables are done here itself. A primary testing of these sets is done and the
audio video quality is tested.
The assembling process comes to an end with this, and a television set is
produced!The sets are then packed into card board boxes with thermocols
present as buffers to protect them.
Salient features of the SKD:
A dynamic unit, with the products continuously being circulated through
conveyer belts.
325 pieces are generated per hour.
These predominantly consist of LEDs.
In a day, over 1500 sets are produced during off season, and the number
shoots up to 1800 during peak season.
PRODUCT EVALUATION UNIT:
The product, in this case essentially a television set, has to undergo some
serious testing before it is out in the market. A dedicated unit to evaluation is
thus set up in the plant. It is tested for several parameters, and is sent back to
the earlier units if not found up to the mark.
Several primary tests include the ESD & EMC tests. The audio and video
quality is yet again tested. The next part of the same unit brings us to a unique
form of testing. There are several chambers set up in a room, and the
temperature is fiercely varied amongst these. This gives rise to tests like ‘Dry
Heat Test’ in which the temperature is 50` C, the ‘Damp Heat Test’ as well as the
‘Cold Test’. Various other endurance tests like ‘Vibration Test’, ‘Drop Test’ and
the ‘Bump Test’ are carried out so that the product is deemed fit for
transportation.
STORAGE UNIT:
The packaged television sets are stored in dry conditions, and an utmost
care is taken in this unit. An interaction with one of the co-workers here revealed
the fact that over 60% of the total area of the plant is utilised for storage
purpose.
PRODUCTION OF OTHER MATERIALS:
The plant at Wada is an abode to automation machinery as mentioned
earlier. It is self-sufficient in producing other useful materials like thermocol,
thereby saving a lot of capital and increasing it’s profit margin.
The thermocol production takes place with the help of a technique called
‘Injection Moulding’. Here, small granules of expandable polyster are
synthesized, and they give rise to blocks commonly called ‘thermocol’. The
machinery used here is imported from Germany, and is the finest machinery
available on globe to get this task done. It is known as ‘Kurtz Machine’.
The chassis or the frame which is made up of plastic is also synthesized in
the plant itself. The machine used for this purpose is termed as ‘24`` IGO LED’. It
consists of a mould and a hooper, and a similar process is applied to fetch the
desired output.
The moulding is brought about in a chamber, where the raw materials are
injected. This is done at a higher temperature, and the finished product is in the
molten form in the moulds. After cooling it down, the material takes the desired
shape and thus, a frame or a chassis is produced.
With processes such as moulding along with several automated machines,
the plant is an abode to technological advances.
Industrial Visit to MIRC Electronics, Wada
17th March 2016
Industrial visit to MIRC Electronics with Dr. Amit Deshmukh (Professor and Head, EXTC,
DJSCE), Prof. Venkata A.P.C. and Prof. Tushar Sawant
INDUSTRIAL VISIT TO COCA-COLA PLANT
INTRODUCTION:
Management is all about practical implications of theoretical concepts. In lieu of
this, students are required to have Industrial Visits besides their classes in order
to have a thorough understanding of the Industrial modus-operandi. With this
objective in mind, a one – day Industrial Visit was organized by IETE-SF of D.J.
Sanghvi College of Engineering on 17thMarch, 2016 to The Coca-Cola Plant
situated in Wada, Maharashtra.
The group was taken to the training hall first after reaching the site. Within the
plant premises, the Plant Managertook charge and had taken the group to the plant around noon and briefed up with the introduction about the plant as well as the number of production lines. The products were segregated in three categories:-Carbonated Soft Drinks[CSD], Juices, and Aerated Water.
BOTTLE MANUFACTURING UNIT:-
The bottles were manufactured in a separate part of the factory. There were two types of bottles manufactured namely, Reusable Glass Bottle (RGB) and Plastic PET bottles.
PET Vials(or preforms) are lined up on a conveyor belt and the air is blown into them, inside a bottle shaped mould. Thus, shaping it up and then cooled down. The bottles are then washed using normal soft water whose water intake is taken from nearby Vaitarna River.
One amusing fact is that 600 bottles are produced per minute, on one line. The production lines for each beverage were separate.
The beverages they produce are
Thumbs Up
Maaza
Sprite
Fanta
Coke
Kinley
BOTTLE FILLING:-
Before filling the beverages in their respective bottles, it is required that the bottles need to be sterilized. So, they are heated up to 95oC, also known as Filling
Temperature. The bottle-necks are then held and their crowning is performed. Crowning is a process wherein the bottles are shut with their lids on tightly.
The Plant Manager also mentioned about every activity happening in the plant
like washing of bottles, filling, capping, labeling and packaging. He also answered the queries of the students regarding marketing and manufacturing.
PPE ZONE:-
This was the plant where Maaza was manufactured separately. RGB Line was utilized, different from the usual used for the CSD. The juice that is to be filled is brought from the Jalgaon Company Plant.
The drink is segregated in two parts, namely, concentrated Mango Pulp, Raw
sugar, and filtered water. The composition is then filtered and heated up in a specialized chamber at 300oC with Caustic Soda and Hot water.
The bottles are then passed through Dip cleaning, and Jet cleaning. The bottles are then passed through a Bottle Inspection Machine to check for dirt, etc. using
specialized software.
The plant is fully automated. Students were amazed at the speed at which the process occurred and how the automated systems could work according to the
requirements. The manufacturing process adopted by them is batch process.
Advantages of batch process:-.
a. For large scale production, batch process reduces the production time and
increases the overall efficiency of the plant
b. Leading to reduced manufacturing and storage costs
STORAGE:-
Their motto is first in, first out. The cold storage temperature is –9oC. CSD are
stored in three parts dry part, liquid part, and raw syrup.
TERMINAL STAGE:-
The last stage involved Palletization and Packaging.
1.5 Lakh cases are produced per day where every case consists of 15 bottles on
an average.
Waste water is processed at an EPP plant and then is reused for gardening, for washroom, etc.
CONCLUSION:-
The plant is very hygienic and workers (including us) were supposed to wear hair caps while touring the plant site.
The industrial visit to Coca-Cola was an enriching experience for students in getting live exposure of manufacturing which can help them in their internships
and further career enhancements.
Industrial Visit to Coca-Cola Plant
17th March 2016
Industrial visit to Coca- Cola plant with Dr. Amit Deshmukh (Professor and Head, EXTC,
DJSCE), Prof. Venkata A.P.C. and Prof. Tushar Sawant
REPORT ON DJ SPARK 2016
The IETE-SF of DJ Sanghvi college of Engineering held its flagship
event, DJSPARK, on the 9th of April, 2016. IETE-SF aims at
encouraging the brilliant minds to go that extra mile to aspire and
innovate. DJSPARK 2016 undoubtedly, did just that. Students all over
Maharashtra submitted in their project papers, which were reviewed
by our erudite professors and the top 27 projects were chosen to be
displayed at the competition and also would be published in the DJ
Spark journal which has an ISBN number. The number of paper
submissions received for this event was huge, and we had a staggering
20% acceptance rate and we had only a certain number of slots
available. We had broken all our records of outhouse submissions in
this 5TH edition of our very own event.
On the day of the competition, the students arrived before time, with
the zeal to compete and win. The projects were all prepared for
display. The event commenced with a ribbon cutting and lighting of
the lamp by our Honourable Principal sir, Dr. Hari Vasudevan, our
Vice Principals, Daptardar Sir and Joshi Sir, the HOD of the EXTC
department, Dr Amit A .Deshmukh, in the presence of numerous
esteemed professors from the college.
It was our honour to have a revered panel of judges;
1. Mr Pritam Bhosle: He is the Global R&D Manager,
Mammography Solutions at Philips Healthcare.
2. Mr. Rahul Abhyankar: He is working as an Entrepreneur at Insight
Pro Consult Tech.
3. Dr. Saurabh Mehta: He is the CTO of Vayve Technologies.
The judges made a tremendous effort to examine each and every
project and then give their views. All three judges individually
reviewed every project on display, meticulously listened to every
student and then engaged the students in an intellectual discussion,
asking question, providing constructive criticism as well as inputs to
improve the quality of the project. The judges separately marked each
project and the average of the three judges was considered for the final
result.
After the inauguration ceremony, the judges visited the stalls given to
each teams to evaluate. At around 1 we took the lunch break. All the
teams wherein were served lunch along with the faculty members of
the college. The IETE-SF organizing team were constantly on their
toes for making everything pass smoothly without any glitches.
The participants displayed their aptitude in all spheres of life. There
were projects to protect our environment and curb deterioration using
smart gadgets. There were projects based on 3-D printing, robotics,
utilities for helping the blind, a smart bag, robotic arms, as well as a
mobile protection application, a website for college amenities like
attendance, games on ghost typing, automatic lawn lowers and traffic
signals, to name a few.
The organizing team had done an incredible job with technical
attractions like a Line follower robot, an LED board and a rotating
billboard welcoming all the students and teachers at the event. The
college, especially the Electronics and Telecommunications
department was decorated with drawings and circuits all pertaining to
the context of the event.
The closing ceremony was conducted in our college seminar hall
where our Principal sir was all praises for the execution and quality of
the event. Principal sir gave a short speech appreciating the hard work
put in by the participants, the organizers and the faculty members to
have pulled of a smooth and excellent competition, all the in duration
of one day.
Our revered HOD Sir, then declared the winners of the competition.
In third place was a team from second year of DJ Sanghvi college who
made a project titled ‘Application of Gesture Recognition and Ghost
Typing for Controllers’. For the first time in the history of the event,
we had two teams tied at 2nd Runners up place. A Third year Computer
Engineering team from KC College Thane won that place with the
project titled ‘MOBIPROTECTOR’.
The first runner-up was a team from Ramrao Adik Institute of
Technology who had their project on ‘Automated College Attendance
System’.
Finally, in first place came the project ‘Smart Utilities for the Blind’,
which was a team of final year students from DJ Sanghvi College of
Engineering.
The feedback from the participants only added glory to the event. The
comments ranged right from the delicious food, to appreciating the
organizing team as well as the valuable input given by the judges.
All in all, the event was carried out smoothly, with very few glitches
and we can proudly say, DJ Spark 2016, was an absolute success.
1. Photo Gallery
D J Spark 2016 – 9th April 2016
D J Spark 2016 Inauguration by Dr. Hari Vasudevan (Principal DJSCE) with Dr. Amit
Deshmukh (Professor and Head, EXTC, DJSCE)
Release of DJ Spark Proceedings by Dr. Hari Vasudevan (Principal DJSCE) with
Dr. Amit Deshmukh (Professor and Head, EXTC, DJSCE) and Industry judges, Mr
Pritam Bhosle (Global R&D Manager, Mammography Solutions at Philips
ealthcare), Mr. Rahul Abhyankar (Insight Pro Consult Tech) and Dr. Saurabh Mehta
(CTO, Vayve Technologies).
D J Spark 2016 – 9th April 2016
Mr. Rahul Abhyankar (Insight Pro Consult Tech) discussing with the students about
their project.
D J Spark 2016 – 9th April 2016
Winner team of D J Spark 2016 receving certificate from Dr. Hari Vasudevan (Principal
DJSCE)
IInd runner up team receiving certificate from Mr. Rahul Abhyankar (Insight Pro
Consult Tech)
Tech Expo – 7th and 9th April 2016
BE and TE students project display in Tech- Expo 2016
Thank you!!