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INDIAN INSTITUTE OF TECHNOLOGY
DELHI
M.Tech in
T H E R M A L E N G I N E E R I N G
PLACEMENT BROCHURE
2016 - 2017
IN
“Since five decades a team of thoroughly knowledgeable facultymembers are committed to nurture young innovative engineersinto professionals who provide optimal solution to industrialchallenges. Students are exposed to academic excellence alongwith extracurricular activities to inculcate competence in impactfulR&D/technical activities and to work as a leader in highly esteemedcompanies world wide.”
“The post graduates from our department are ambitious and youthful groupof innovative technologists who will carve a niche for themselves in theworld of technology by the virtue of their zeal for excellence and hard work.It is an honour for us to invite the recruiting corporates for the campusplacement and we are confident that you will leave the campus equallyprivileged.”
DR. S.K SAHAHead, Dept. of Mechanical Engineering
KEY POINTS
Eminent faculty from International universities
*Consultancy
services is provided to government and leading corporate
organizations
*Students get the
opportunity to work with foreign
universities and research labs.
I.C. ENGINES
FUEL POLLUTION
FLUID MECHANICS
THERMAL SCIENCE
TURBO MACHINERY
HEAT AND MASS TRANSFER
REFRIGERATION & AIR CONDITIONING
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QUANTIFICATION OF UNCERTAINTY IN MODELLING OF μ SCALE ION TRANSPORT• Simulations of transport of ions under applied electric field (termed electrophoresis) are used widely for
designing electrophoretic techniques. However, the input parameters of these simulations are often uncertainwhich further trickles down to final results.
• Thus identification, minimisation of this uncertainty in computational and real world applicationsis the objective of this project.
• Microscale transport finds application in cases where there is transport of ions under the influence of externalelectric field i.e - electrophoresis. DNA analysis primarily employs this method.
DEVELOPMENT OF MOVING MULTI-BLOCK LATTICE BOLTZMANN METHOD FOR 3D FLUID FLOW PROBLEMS• Development of moving multi-block lattice boltzmann method for 3D fluid flow problems.• The method of the lattice Boltzmann equation (LBE) has emerged as a successful computational technique for
solving fluid dynamic systems. Using multi-block method, there is significant potential for the LBE method to beapplied in practical flow problems.
STUDY OF DYNAMIC MODE DECOMPOSITION OF MICROSCALE FLOWS • The dynamic mode decomposition (DMD) is a data-decomposition technique that allows the extraction of
dynamically relevant flow features from time-resolved experimental (or numerical) data.• It is based on a sequence of snapshots from measurements that are subsequently processed by an iterative
Krylov technique.• Demonstrations of the method are presented consisting of a plane channel flow, flow over a two-dimensional
cavity, wake flow behind a flexible membrane and a jet passing between two cylinders.
EXPERIMENTAL AND COMPUTATIONAL ANALYSIS OF HEAT TRANSFER ENHANCEMENT USING DUAL PAIRED WINGLETS• Applicable for cross flow and tube heat exchanger. Uses delta winglet to enhance heat transfer
coefficient• At particular Reynold’s Number. The main objective is to promote turbulence to reduce wake region.
Software to be used in the used in project include Gambit and Fluent.• Finds practical applications in food and Milk industry, Refrigeration and AC too
TO STUDY FLOW AND HEAT TRANSFER CHARACTERISTICS OF ULTRA SUPER CRITICAL HIGH PRESSURE TURBINE• The different conditions of steam in ultra super critical turbine presents a problem for analysis of flow
through blades in steam turbine. Because of constantly changing steam conditions as it passes throughthe blade cascade, there is gradual change in flow pattern which needs investigating.
• Secondary flow features in such cases play a very important role in determining the heat transfercharacteristics and shear stresses which will be observed on blade surfaces.
• ICEM CFD , Fluent will be employed to analyze the steam flow through blade cascades.
INVESTIGATION OF FLAME STRUCTURE AND STABILITY FOR OXYGEN ENHANCED NON PREMIXED COMBUSTION OF LOW CV GASES• The aim of this research is to make an in-depth study of LCVG combustion with oxygen enhanced oxidizer
in laminar, coaxial, diffusion based combustion and evaluation of its flame structure and stability
• ANSYS FLUENT simulation developing various computational domain, mesh size, boundary conditions andchoosing proper optimization technique. Simulation results are validated with experimental results.
EXPERIMENTAL AND COMPUTATIONAL STUDY OF HEAT TRANSFER CHARACTERISTICS AND STABILITY OF ARRAY PREMIXED FLAME BURNER• This study undertakes interaction of premixed flame between array of burners. Study of flame characteristics is
done with variation based on equivalence ratio, flow properties, inter burner distance and fuel dilution.• Computational simulation will involve meshing, developing computer domain and different chemical reaction rate
mechanism. Experimental setup will be designed and no of experiments will be carried out for better comparisonwith simulations.
• Finds application in gas turbines, furnaces, process industry and automobile sector.
DEVELOPMENT OF CFD CODE FOR THE FVM BASED ADAPTIVE MESH REFINEMENT AND COARSENING FOR STUDY OF HEAT TRANSFER AND FLOW CHARACTERISTICS• Development of Adaptive mesh Refinement and Coarsening Grid to capture the solution gradient and focus grid in
that particular domain of computation.• Development of Finite Volume Method (FVM) based CFD solver code incorporating adaptive meshing and
verification against CFD Ansys Fluent Solver to Study Flow and Heat Transfer Characteristics.
TO MODEL HEAT TRANSFER AND FLUID FLOW THROUGH POROUS MEDIA AT HIGH TEMPERATURE• Due to low relative density, high thermal conductivity, large accessible surface area per unit volume, the porous
material is highly useful for manufacturing of compact heat exchangers.• Such materials find applications in air borne equipment, air cooled condenser towers, compact heat sinks for
power electronics.• The Project will employ Gambit and MATLAB for analysis
• Interested companies contact professor-in-charge or placement officer,Training and Placement Cell for a Job Notification Form (JNF)at [email protected].
• JNF requires the companies to fill in mandatory details of the job profile– role offered, pay package, place of posting, eligible departments.
• Once the filled-in-JNF with all the required details is received,companies are assigned username/password to access their onlineaccount on T&P website.
• Companies are also assigned space on the server on which they mayupload any presentation, videos, data or other information they wantthe students to see.
• The JNF has to be frozen on the T&P website by the company till adeadline, after which the students shall be able to view all the details,and the eligible students may apply.
• After the application deadline for the students, the resumes are visibleto the company. The company submits shortlist on its online accountbefore a deadline.
• Shortlisted students get notified. The placement office allots the datesfor the campus interviews.
• After the completion of the selection procedure on campus, company isrequired to announce the final list of the students on the same dayitself.
• If a student is selected, the job is registered against him/her and he/shewould not be allowed to appear for more interviews as per placementpolicy.
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Professor-in-ChargeProf. Sandeep SenTraining and Placement CellIIT DelhiPhone : +91-11-2659 1731/32Email: [email protected]
Head of the DepartmentProf. S.K SahaDept. of Mechanical Engineering,IIT Delhi Phone: +91-11-2659 1135 / 6139Email: [email protected]
Industrial Liaison OfficerMs. Anishya O. MadanIIT DelhiPhone: +91-2659 1731/32Email: [email protected]://tnp.iitd.ac.in
Faculty CoordinatorsDr. S. AravindanDept. of Mechanical EngineeringIIT DelhiPhone: +91-11-2659 6350Email: [email protected]
Dr. Amit GuptaDept. of Mechanical EngineeringIIT DelhiPhone: +91-11-2659 1270Email: [email protected]
