Online/ e-LMS
Self Paced
Moderate
1 Months
About
The Advanced Thermodynamics and Heat Transfer Program covers both fundamental and complex concepts in thermodynamics, heat transfer, and thermal system design. Participants will explore methods for optimizing energy systems, managing heat in industrial applications, and improving thermal efficiency through hands-on projects and simulations. The program uses industry-standard tools to provide a comprehensive learning experience, ideal for professionals in engineering roles where thermal management and energy optimization are crucial.
Aim
This program provides advanced training in thermodynamics and heat transfer, emphasizing their applications in real-world engineering scenarios. Participants will gain expertise in analyzing and designing thermal systems to enhance efficiency, energy conservation, and sustainability across industries like energy, automotive, and aerospace.
Program Objectives
- Understand the advanced principles of thermodynamics and heat transfer.
- Gain proficiency in analyzing and optimizing thermodynamic cycles and heat transfer systems.
- Learn computational methods for thermal simulations and design.
- Develop skills to design efficient thermal systems for energy conservation and sustainability.
- Complete a capstone project demonstrating thermal system design, analysis, and optimization.
Program Structure
Module 1: Fundamentals of Thermodynamics and Energy Systems
- Overview: This module introduces core concepts in thermodynamics, focusing on energy conservation and thermodynamic cycles.
- Topics Covered:
- The first and second laws of thermodynamics
- Thermodynamic cycles: Carnot, Rankine, and Otto cycles
- Energy conservation and entropy principles
- Project: Analyze a basic thermodynamic cycle, calculating efficiencies and identifying optimization opportunities.
Module 2: Conduction, Convection, and Radiation Heat Transfer
- Overview: Study the three modes of heat transfer—conduction, convection, and radiation—and their applications in engineering.
- Topics Covered:
- Conduction in solids and composite materials
- Forced and natural convection in fluids
- Radiative heat transfer and insulation methods
- Project: Design a heat-insulated system, considering material properties and thermal barriers to minimize heat loss.
Module 3: Heat Exchangers and Thermal Management Systems
- Overview: Explore the design and application of heat exchangers and thermal management systems for industrial applications.
- Topics Covered:
- Types of heat exchangers: shell-and-tube, plate, and air-cooled
- Efficiency, fouling, and performance metrics
- Applications in HVAC, power plants, and automotive cooling
- Project: Design a heat exchanger for a specific application, optimizing for heat transfer efficiency and system integration.
Module 4: Advanced Thermal Analysis and System Optimization
- Overview: Learn advanced thermal analysis techniques, including computational methods and system optimization strategies.
- Topics Covered:
- Computational Fluid Dynamics (CFD) for thermal analysis
- Finite element analysis (FEA) for heat distribution
- Optimization techniques in thermal management
- Project: Perform a CFD analysis on a thermal component, identifying hot spots and optimizing design for heat dissipation.
Module 5: Capstone Project in Thermodynamics and Heat Transfer
- Overview: Apply your skills in a capstone project focused on designing, simulating, or optimizing a complex thermal system.
- Project Options:
- Design an energy-efficient HVAC system for a commercial building, considering energy conservation and thermal comfort.
- Develop a cooling solution for a high-performance automotive engine, optimizing thermal management for reliability.
- Create a thermodynamic cycle model for a power plant, maximizing efficiency and reducing waste heat.
- Outcome: Complete a comprehensive thermal management project, demonstrating your skills in thermodynamics, heat transfer, and system optimization.
Participant’s Eligibility
- Mechanical and Thermal Engineers: Interested in mastering energy systems, heat transfer, and thermodynamic analysis.
- Engineering Students and Graduates: Seeking to deepen their understanding of thermal systems and energy applications.
- Professionals in Power Generation, HVAC, and Automotive Industries: Looking to optimize thermal systems and improve energy efficiency.
Program Outcomes
- Expertise in analyzing and designing thermodynamic cycles and thermal systems.
- Hands-on experience with computational tools for thermal simulations.
- Knowledge of heat transfer mechanisms and their applications in industry.
- Skills in optimizing energy systems to improve efficiency and reduce waste.
Fee Structure
Standard Fee: INR 9,998 USD 298
Discounted Fee: INR 4999 USD 149
We are excited to announce that we now accept payments in over 20 global currencies, in addition to USD. Check out our list to see if your preferred currency is supported. Enjoy the convenience and flexibility of paying in your local currency!
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Key Takeaways
Program Deliverables
- Access to e-LMS
- Real Time Project for Dissertation
- Project Guidance
- Paper Publication Opportunity
- Self Assessment
- Final Examination
- e-Certification
- e-Marksheet
Future Career Prospects
- Thermal Systems Engineer
- Energy Efficiency Consultant
- Power Plant Engineer
- HVAC Systems Designer
- R&D Engineer in Heat Transfer
- Renewable Energy Specialist
Job Opportunities
- Engineering roles in energy, automotive, and aerospace sectors focusing on thermal system design and management.
- R&D positions in companies developing energy-efficient technologies and advanced materials for heat management.
- Consultancy roles in energy optimization, sustainable engineering, and renewable energy applications.
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