HEAT EXCHANGERS : Selection, Rating, and Thermal Design- I

HEAT EXCHANGERS : Selection, Rating, and Thermal Design- I, available at $44.99, has an average rating of 1.5, with 50 lectures, based on 2 reviews, and has 11 subscribers.

You will learn about Understand the principles of heat transfer and thermodynamics as applied to heat exchanger design. Learn the different types of heat exchangers, including shell-and-tube, plate-and-frame, and air-cooled exchangers, and be able to select the appropriate heat e Gain knowledge of heat exchanger sizing and rating methods, including log mean temperature difference (LMTD), effectiveness-NTU method, and heat exchanger perfo Learn the steps involved in thermal design of heat exchangers, including the calculation of heat transfer coefficients, determination of flow arrangements, and This course is ideal for individuals who are Engineers and technicians who work in the design, selection, and operation of heat exchangers. or Researchers and scientists who need to use heat exchangers in their work. or Industry professionals who are looking to stay up-to-date with the latest developments in heat exchanger technology and design practices. It is particularly useful for Engineers and technicians who work in the design, selection, and operation of heat exchangers. or Researchers and scientists who need to use heat exchangers in their work. or Industry professionals who are looking to stay up-to-date with the latest developments in heat exchanger technology and design practices.

Enroll now: HEAT EXCHANGERS : Selection, Rating, and Thermal Design- I

Summary

Title: HEAT EXCHANGERS : Selection, Rating, and Thermal Design- I

Price: $44.99

Average Rating: 1.5

Number of Lectures: 50

Number of Published Lectures: 50

Number of Curriculum Items: 50

Number of Published Curriculum Objects: 50

Original Price: ₹6,900

Quality Status: approved

Status: Live

What You Will Learn

Understand the principles of heat transfer and thermodynamics as applied to heat exchanger design.
Learn the different types of heat exchangers, including shell-and-tube, plate-and-frame, and air-cooled exchangers, and be able to select the appropriate heat e
Gain knowledge of heat exchanger sizing and rating methods, including log mean temperature difference (LMTD), effectiveness-NTU method, and heat exchanger perfo
Learn the steps involved in thermal design of heat exchangers, including the calculation of heat transfer coefficients, determination of flow arrangements, and

Who Should Attend

Engineers and technicians who work in the design, selection, and operation of heat exchangers.
Researchers and scientists who need to use heat exchangers in their work.
Industry professionals who are looking to stay up-to-date with the latest developments in heat exchanger technology and design practices.

Target Audiences

Engineers and technicians who work in the design, selection, and operation of heat exchangers.
Researchers and scientists who need to use heat exchangers in their work.
Industry professionals who are looking to stay up-to-date with the latest developments in heat exchanger technology and design practices.

HEAT EXCHANGERS: Selection, Rating, and Thermal Design is a course that covers the fundamental principles, design, and analysis of heat exchangers. Topics covered include types of heat exchangers, selection criteria, rating methods, thermal design, and performance analysis. The course is intended to provide students with a solid understanding of the fundamental concepts and practical applications of heat exchangers in various industries such as power generation, chemical processing, and HVAC. The course is designed for mechanical engineering students and professionals in related fields such as chemical engineering, aerospace engineering, and energy engineering.

Topics we covered in this course:

1. Classification of Heat Exchangers

1.1 Introduction

1.2 Recuperation and Regeneration

1.3 Transfer Processes

1.4 Geometry of Construction

1.5 Heat Transfer Mechanisms

1.6 Flow Arrangements

1.7 Applications

1.8 Selection of Heat Exchangers

2. Basic Design Methods of Heat Exchangers

2.1 Introduction

2.2 Arrangement of Flow Paths in Heat Exchangers

2.3 Basic Equations in Design

2.4 Overall Heat Transfer Coefficient

2.5 LMTD Method for Heat Exchanger Analysis

2.6 The ε-NTU Method for Heat Exchanger Analysis

2.7 Heat Exchanger Design Calculation

2.8 Variable Overall Heat Transfer Coefficient

2.9 Heat Exchanger Design Methodology

3. Forced Convection Correlations for the Single-Phase Side of Heat Exchangers

3.1 Introduction

3.2 Laminar Forced Convection

3.3 Effect of Variable Physical Properties

3.4 Turbulent Forced Convection

3.5 Turbulent Flow in Smooth Straight Noncircular Ducts

3.6 Effect of Variable Physical Properties in Turbulent

3.7 Summary of Forced Convection in Straight Ducts

3.8 Heat Transfer from Smooth-Tube Bundles

3.9 Heat Transfer in Helical Coils and Spirals

3.10 Heat Transfer in Bends

4. Heat Exchanger Pressure Drop and Pumping Power

4.1 Introduction

4.2 Tube-Side Pressure Drop

4.3 Pressure Drop in Tube Bundles in Crossflow

4.4 Pressure Drop in Helical and Spiral Coils

4.5 Pressure Drop in Bends and Fittings

4.6 Pressure Drop for Abrupt Contraction, Expansion, and Momentum Change

4.7 Heat Transfer and Pumping Power Relationship

5. Micro/Nano Heat Transfer

5.1 PART A—Heat Transfer for Gaseous and Liquid Flow in Microchannels

5.2 PART B—Single-Phase Convective Heat Transfer with Nanofluids

6. Fouling of Heat Exchangers

6.1 Introduction

6.2 Basic Considerations

6.3 Effects of Fouling

6.4 Aspects of Fouling

6.5 Design of Heat Exchangers Subject to Fouling

6.6 Operations of Heat Exchangers Subject to Fouling

6.7 Techniques to Control Fouling

7. Double-Pipe Heat Exchangers

7.1 Introduction

7.2 Thermal and Hydraulic Design of Inner Tube

7.3 Thermal and Hydraulic Analysis of Annulus

7.4 Parallel–Series Arrangements of Hairpins

7.5 Total Pressure Drop

7.6 Design and Operational Features

Course Curriculum

Chapter 1: Introduction

Lecture 1: Introduction

Chapter 2: Classification of Heat Exchangers

Lecture 1: Classification of Heat Exchangers

Lecture 2: Transfer Processes

Lecture 3: Shell-and-Tube Heat Exchangers

Lecture 4: Spiral Plate Heat Exchangers

Lecture 5: Plate-Fin Heat Exchanger

Lecture 6: Tubular-Fin Heat Exchangers

Lecture 7: Applications

Chapter 3: Basic Design Methods of Heat Exchangers

Lecture 1: Basic Design Methods of Heat Exchangers

Lecture 2: Basic Equations in Design

Lecture 3: Overall Heat Transfer Coefficient

Lecture 4: Parallel- and Counterflow Heat exchangers

Lecture 5: The ε-NTU Method for Heat Exchanger Analysis

Lecture 6: Heat Exchanger Design Calculation

Lecture 7: Variable overall Heat Transfer Coefficient

Chapter 4: Forced Convection Correlations for the Single-Phase Side of Heat Exchangers

Lecture 1: Forced Convection Correlations for the Single-Phase Side of Heat Exchangers

Lecture 2: Introduction

Lecture 3: Laminar Flow through Concentric Annular Smooth ducts

Lecture 4: Laminar Flow of Liquids

Lecture 5: Turbulent Flow in Smooth Straight Noncircular Ducts

Lecture 6: Summary of Forced Convection in Straight Ducts

Lecture 7: Heat Transfer in Helical Coils and Spirals

Lecture 8: Heat Transfer in Bends

Chapter 5: Heat Exchanger Pressure Drop and Pumping Power

Lecture 1: Heat Exchanger Pressure Drop and Pumping Power

Lecture 2: Noncircular Cross-Sectional ducts

Lecture 3: Helical Coils—Laminar Flow

Lecture 4: Pressure Drop for Abrupt Contraction, Expansion, and Momentum Change

Chapter 6: Micro/Nano Heat Transfer

Lecture 1: Micro-Nano Heat Transfer

Lecture 2: Knudsen number

Lecture 3: Brinkman number

Lecture 4: Heat Transfer in gas Flow

Lecture 5: Friction Factor

Lecture 6: Friction Factor-II

Lecture 7: Laminar to Turbulent Transition regime

Lecture 8: Engineering Applications of Single-Phase Liquid Flow in Microchannels

Lecture 9: Single-Phase Convective Heat Transfer with Nanofluids

Lecture 10: Thermal Conductivity of nanofluids

Lecture 11: Clustering of Nanoparticles

Lecture 12: Thermal Conductivity experimental Studies of nanofluids

Lecture 13: Constant Wall Heat Flux Boundary Condition

Lecture 14: Experimental Correlations of Convective Heat Transfer of nanofluids

Chapter 7: Fouling of Heat Exchangers

Lecture 1: Fouling of Heat Exchangers

Lecture 2: Effect of Fouling on Pressure drop

Lecture 3: Particulate Fouling

Lecture 4: Attachment

Lecture 5: Fouling Resistance

Lecture 6: Techniques to Control Fouling

Chapter 8: Double Pipe Heat Exchangers

Lecture 1: Double-Pipe Heat Exchangers

Lecture 2: Hairpin Heat exchangers with Multitube Finned inner Tubes

Lecture 3: Parallel–Series Arrangements of Hairpins

Instructors

EasyShiksha Learning
e-learning

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