Lectures related to Machinability and Cutting Tools

Conventional Machining: Material Removal and Processes

Explores conventional machining processes, emphasizing the importance of precise part shapes and dimensional accuracy.

Mechanical Construction I: Dimensioning Principles

Explores dimensioning principles and machining processes, emphasizing the importance of cutting parameters and tool wear.

Metal Forming Processes: Deep Drawing and Cutting Techniques

Covers advanced metal forming processes, focusing on deep drawing and cutting techniques, including their mechanics and applications in manufacturing.

Glass Microfabrication: Mechanical Structuring

Explores glass microfabrication techniques, including precision machining and ultrasonic machining, focusing on mechanical properties and fracture behavior.

Material Strength and Hardness

Explores material strength, hardness, and toughness, covering ductility, plastic deformation, fracture, and hardness testing methods.

Mechanical Construction I: Fundamental Principles of Dimensioning

Delves into the fundamental principles of dimensioning and cutting in mechanical construction, emphasizing quality and cost-effectiveness.

Cost Modelling for Sustainable Innovation

Introduces cost modelling as a tool for sustainable innovation and covers topics such as transport CO2 emissions and material properties.

Conventional Machining: Physics of Manufacturing

Explores conventional machining processes, tool wear, cutting temperature, chip formation, and machining economics.

Shear Behavior: Evaluation and Laws

Explores material behavior in shear, shear forces, stress, equilibrium, shear laws, tension/compression, plane shear, shear rate, constrained slip, and shear strength.

Mechanical Properties of Materials: Toughness and Hardness

Explores toughness, hardness, and material properties, including critical crack length and hardness testing methods.

Practical Machining Stage at ETML

Covers a practical machining stage at the ETML, focusing on hands-on skills development in Microengineering.

Machining Tools and Techniques

Covers the use of specialized tools in machining materials like plywood.

Building Technology: Construction and Materials Overview

Introduces building technology, covering construction methods, materials, and the architect's role in design and execution.

Fracture and Toughness of Materials

Covers stress intensity, fracture, and toughness of materials, including the behavior of ductile and brittle materials.

Material Selection: Microtechnology Design

Explores material selection criteria in microtechnology design and the influence of fatigue on material limits.

Chemistry: Atomic Structure and Thermodynamics

Covers atomic structure, thermodynamics, material properties, and ideal gas law.

Fracture and Toughness of Materials

Explores fracture, toughness, and crack propagation in materials, emphasizing surface energy and material resistance.

Shock Waves and Brittle Material Response

Covers shock waves, brittle material response, phase transformation, and Hugoniot relationships in materials under stress.

A Random Walk Through Random Materials

Explores random materials, solutes, and their impact on mechanical performance, including strength, toughness, and fatigue.

Modeling Shock Response of Brittle Materials

Explores shock response modeling of brittle materials, including spall strength evaluation and shear failure mechanisms.