This document provides information about Pramod Kumar's knowledge, skills, and experience for the role of developing CORUS. It includes details about his educational background in engineering, IT, and management. It then discusses the technical knowledge, communication skills, and experience needed for the role, including experience with analytical calculations, prediction/simulation software, and managing teams. The document also provides a brief introduction to CORUS, nanotechnology, and how Pramod's knowledge and experience could apply to developing CORUS, such as in areas of materials properties, coating, and environmental impact.
2. Synopsis Introduction Knowledge & Skills for the Role About CORUS Nano Technology Knowledge & Experience – CORUS Inspiration through Education Summary Appendix I & II
3. Introduction Engineering BE - Electronics, Instrumentation and Material Science Engineering MSc – Nanoscale Science and Technology Projects: National Thermal Power Plant Material Science Research Project Information Technology PGDCA Software Programming Project Management BMT & LCE PLMS, HACCP, H&S
4. Knowledge & Skills for the Role Technical Knowledge and support Effective Communication - verbal & Non verbal Open Discussions Functional Structured Composite 12 Different 1,2,3D structures (Natural Roughness) Material to choose EXPERIENCE Analytical Calculations Prediction n Simulation 3D, Ht3, DIGIPAC, MATLAB and C language Analytical Vs Simulated Values Manager, IT Team leader Multi tasking, Business Development, Customer focus Attitude, Behaviour Qinetiq, Thomas Swan, Pratham, School, JBS Scholarships, University, Projects TECHNICAL Communication Innovation Management & Presentation Skills Engineering Role Analytical Interpretation Dedication Technical data Materials properties and characteristics Structure and Packing NTPC prediction control MSc, BE, PGDCA, MBA, LCE Learnt, Shared, and Applied Nano & Fuzzy Technologies Environment and Natural resource CO2 storage and EOR
5. CORUS CORUS STRIP LONG STEEL DIST& BUILD AL About Corus BRAND & ORGANISATIONS IISI, EUROFER,ISSB UK STEEL, IAI, EAA DANIELI CORUS TATA STEEL 9.7B, 18.3M TON 50 COUNTRIES MARKET POTENTIAL RESPONSIBILITIES DEVELOPMENT AREAS INTEGRATION ENVIRONMENTAL SOCIAL ECONOMIC SUSTAINABILITY LOCAL INITIATIVES CHARITY REPUTATION CORE VALUES RECYCLING METALLURGY CERAMICS METAL PROCESSING COATING ENGINEERING ENVIRONMENT TRANSPORT CONSTRUCTION AUTOMOTIVE PACKAGING AUTOMOTIVE ENGINEERING ENERGY CONSTRUCTION PACKAGING RAIL CONSUMER PRODUCTS DEFENCE AND SECURITY YELLOW GOODS SHIP BUILDING
6. Nanotechnology Nanotechnology: “The technology at molecular scale” Nano:one billionth of a metre (10-9 m) Composite:a material that is made from several different substances. Human hair: 1µm Nano composite: Structures created by packing nanoparticles in a well defined pattern.
9. Inspiration through Education What inspiration? Creativity and motivation Why does it inspire me? Interest in Science, Einstein’s Ideas and Father’s Encouragement Inspiration = (Power) (Creativity. Confidence. Challenge) I = P C3-----------(Equation 1) Whereas, According to Ampere’s Law, P=VI = I2 R Equation 1 can be written as I = (I2 R) C3 --------(Equation 2) According to great Einstein’s equation E = mC2 C2=E/m -----(Equation i) Substituting Equation (i) in Equation 2 we get, I = I2 R (C. E/m) Which can be written after solving m = I C R E (me, Motivation, mass)= (Inspiration) (Creativity) (Recognition) (Education) Motivation (Encouragement) = (Individual) (Creativity) ------- Einstein’s greatest quote
10. Summary Introduction My Knowledge & Skills for the Engineering Role Brief about CORUS Nano Technology and Properties Knowledge & Experience applied to CORUS Inspiration through Education Appendix I and II
11. Appendix I Conductivity (Energy, Transport, Consumer appliances) Ag>Cu>Au>Steel>China>Glass>Plastic + CNT (good electrical and heat conductor) light wt, strong Ceramic Magnets (metal oxides + carbonates) Magnetic Lev trains Corrosion (Automotive, Aerospace, Industrial Engineering) Na>Mg>Al>Zn>Fe>Sn>Pb>Cu>Ag>Au Metals + (Cr, Ni, Zn, by grease/paint/plastic/plating) to avoid corrosion Metals + Polymers (Nano coatings) Less corrosion, solar panels for automotive industry To avoid oxidation from water, air etc., Metal + Hydrophobic surface (nano particles) repels water and stops corrosion EXAMPLE FOR HYDROPHOBIC SURF NANO-COMPOSITE/POLYMER COATING ON WELL CAPS WITH HYDROPHOBIC SURFACTANTS WATER REPELLANT =OIL RECOVERY PROCESS (EOR) EXAMPLE FOR HYDROPHILIC SURF ALLUMINIUM ALLOYS +H2O HYDROPHILIC SURFACTANTS NANO-COMPOSITE COATINGS ALLUMINIUM OXIDE + H2 = H2 IS FUEL FOR CARS AND AUTOMOBILES NOTE : SURF = SURFACTANTS; CONTENT FROM SCIENCE DAILY AND GOOGLE WEBSITES
12. Appendix II Elastic Behaviour (depends on the load , force and extension) Metals + CNT Increase in Elastic behaviour Measured by Young’s Modulus e = Fl/EA (Extension = Load*Length/Young’s Modulus*Cross-sectional Area) Natural resources NTPC – prediction and simulation of final output by calculating the sensor values at initial stage Adv – Control of natural resources (such as coal), and energy Recycling and proper training for nation will control the metal ore wastage Environmental Effect CO2 - During steel production carbon dioxide and monoxide are released Fe2O3 + 3CO 2Fe + 3CO2 CO2 can be controlled by dumping, storing or sending into enclosed agricultural area/ used in Enhanced oil recovery (EOR) in oil exploration and upstream production Other Innovative Ideas Car with solar/wind/fuel cell/ hydrogen power/ heat energy – a collective source of renewable car Super computer with 117.9 Trillion calculations/second (TATA) has been revealed – used in quantum physics, weather, chemical compounds, aircraft technical calculations, and also in nuclear power control