This course introduces you to manufacturing, with emphasis on the following intertwined themes:
a) Mechanical behavior and technologies of the materials;
b) Manufacturing processes (casting, forming, machining, joining);
c) Fundamental of production organization and Design for manufacturing.
Course Content - Last names M-Z
This course introduces you to manufacturing, with emphasis on the following intertwined themes:
a) Manufacturing processes (casting, forming, machining, joining);
b) Equipment and automation;
c) Variation and quality;
d) Design for manufacturing.
- Giusti F., Santochi M., "Tecnologia Meccanica e Studi di Fabbricazione", casa ed. Ambrosiana
- Gabrielli F., Ippolito R., Micari, F., "Analisi e Tecnologia delle lavorazioni Meccaniche", ed. McGraw Hill
- Kalpakjian S., Schmid S.R., "Tecnologia Meccanica", ed. Pearson
Detailed readings:
- Smith, W.F., Hashemi, J., " Scienza e Tecnologia dei Materiali", ed. McGraw Hill
- Zompì A, Levi R., "Tecnologia Meccanica - Lavorazioni per Deformazione Plastica", ed. UTET
- Zompì A, Levi R., "Tecnologia Meccanica - Lavorazioni per Asportazione di Truciolo", ed. UTET
- Giusti F., Santochi M., "Tecnologia Meccanica e Studi di Fabbricazione", casa ed. Ambrosiana
- Gabrielli F., Ippolito R., Micari, F., "Analisi e Tecnologia delle lavorazioni Meccaniche", ed. McGraw Hill
- Kalpakjian S., Schmid S.R., "Tecnologia Meccanica", ed. Pearson
Detailed readings:
- Smith, W.F., Hashemi, J., " Scienza e Tecnologia dei Materiali", ed. McGraw Hill
- Zompì A, Levi R., "Tecnologia Meccanica - Lavorazioni per Deformazione Plastica", ed. UTET
- Zompì A, Levi R., "Tecnologia Meccanica - Lavorazioni per Asportazione di Truciolo", ed. UTET
Learning Objectives - Last names A-L
On completion of the course, the students should have the tools and confidence to enter a manufacturing enterprise, and be able to:
• Understand the principles and techniques of casting, forming, joining and finishing operations and be able to determine their suitability.
• Internalize the four attributes by which the performance of a manufacturing process, machine, or system can be measured: quality, cost, rate and flexibility.
• Calculate and understand appropriate single-point machining relationships taking tool material and machine constraints into consideration.
• Understand the principles and appropriateness of traditional machining processes.
• Select a suitable manufacturing process in order to achieve the specified product performance and design criterion while considering cost.
• Understand the role of control in processes and systems, especially in the presence of variation.
• Be aware of the future of advanced manufacturing, via the increased roles of software, robotics, and automation. Overall, become an expert thinker in manufacturing via combining all of the above throughout the semester.
With reference to the knowledge (CC) identified for the course, reference is made to the following descriptors:
- cc3: Knowledge of the technology of the materials that can be used, and of the technologies for mechanical component’s production.
- cc12: Knowledge and understanding of the most suitable production process for the realization of mechanical components, and definition of process parameters able to meet the requirements of product feasibility.
With reference to the competences acquired (CA) identified for the Course reference is made to the following descriptors:
- ca3: the choice of the best production process aimed at the creation of mechanical components.
- ca10: Applying knowledge and understanding problems related to the choice of the most suitable production process for the production of mechanical components, and to define the process parameters able to satisfy the product feasibility requirements.
Learning Objectives - Last names M-Z
On completion of the course, the students should have the tools and confidence to enter a manufacturing enterprise, and be able to:
• Understand the principles and techniques of casting, forming, joining and finishing operations and be able to determine their suitability.
• Internalize the four attributes by which the performance of a manufacturing process, machine, or system can be measured: quality, cost, rate and flexibility.
• Calculate and understand appropriate single-point machining relationships taking tool material and machine constraints into consideration.
• Understand the principles and appropriateness of traditional machining processes.
• Select a suitable manufacturing process in order to achieve the specified product performance and design criterion while considering cost.
• Understand the role of control in processes and systems, especially in the presence of variation.
• Be aware of the future of advanced manufacturing, via the increased roles of software, robotics, and automation. Overall, become an expert thinker in manufacturing via combining all of the above throughout the semester.
With reference to the knowledge (CC) identified for the course, reference is made to the following descriptors:
- cc3: Knowledge of the technology of the materials that can be used, and of the technologies for mechanical component's production.
- cc12: Knowledge and understanding of the most suitable production process for the realization of mechanical components, and definition of process parameters able to meet the requirements of product feasibility.
With reference to the competences acquired (CA) identified for the Course reference is made to the following descriptors:
- ca3: the choice of the best production process aimed at the creation of mechanical components.
- ca10: Applying knowledge and understanding problems related to the choice of the most suitable production process for the production of mechanical components, and to define the process parameters able to satisfy the product feasibility requirements.
Prerequisites - Last names A-L
In order to successfully follow the course students have to be able to interpret and specify dimensional and geometric tolerances, be aware of materials strengths, stress and strain state. A low intermediate level of English is required.
Prerequisites - Last names M-Z
In order to successfully follow the course students have to be able to interpret and specify dimensional and geometric tolerances, be aware of materials strengths, stress and strain state. A low intermediate level of English is required.
Teaching Methods - Last names A-L
Manufacturing Engineering and Technology is a 9-CFU course. Each week, on the average, the course requires 4 hours of lecture, 2 hours of exercises.
The learning methods presume a combination of study, discussion, and practice, designed to build fundamental knowledge and hands-on experience on the methods and challenges of manufacturing. Support material consists of a set of slides used by the teacher during the lessons.
http://e-l.unifi.it will have lecture slides, exercises handouts, archive of announcements, etc. To register to the course it is necessary to have a registration key provided by the teacher at the beginning of the course.
Teaching Methods - Last names M-Z
Manufacturing Engineering and Technology is a 9-CFU course. Each week, on the average, the course requires 4 hours of lecture, 2 hours of exercises.
The learning methods presume a combination of study, discussion, and practice, designed to build fundamental knowledge and hands-on experience on the methods and challenges of manufacturing. Support material consists of a set of slides used by the teacher during the lessons.
http://e-l.unifi.it will have lecture slides, exercises handouts, archive of announcements, etc. To register to the course it is necessary to have a registration key provided by the teacher at the beginning of the course.
Further information - Last names A-L
In order to take the exam, please register to:
http://sol.unifi.it/prenot/prenot
Further information - Last names M-Z
In order to take the exam, please register to:
http://sol.unifi.it/prenot/prenot
Type of Assessment - Last names A-L
The level of knowledge acquired will be evaluated by three intermediate tests during the course.
Topics of the first test will be: geometric and dimensional tolerances, roughness, stress and strain states, Mohr circles. The second test will be focused on casting and forging processes, while in the third test issues related to machining will be considered.
Students that will not met performance required, will have to undergo a comprehensive written evaluation test (1.5 hour) and an oral examination. Students that will not fully met the performance expectation, will have to give just an oral examination.
Tests and oral examination aim at highlighting the acquired knowledge cc3 e cc12, and verifying the capabilities ca3 e ca10.
Type of Assessment - Last names M-Z
The level of knowledge acquired will be evaluated by three intermediate tests during the course.
Topics of the first test will be: geometric and dimensional tolerances, roughness, stress and strain states, Mohr circles. The second test will be focused on casting and forging processes, while in the third test issues related to machining will be considered.
Students that will not met performance required, will have to undergo a comprehensive written evaluation test (1.5 hour) and an oral examination. Students that will not fully met the performance expectation, will have to give just an oral examination.
Tests and oral examination aim at highlighting the acquired knowledge cc6, cc10 e cc12, and verifying the capabilities ca8 e ca10.
Course program - Last names A-L
1. Introduction. Processing overview. Materials-process matrix. Manufacturing systems
2. Manufacturing Processes
2.1. Technological and Economic Aspects
2.2. Manufacturing capabilities: Facilities Layouts
2.3. New Product Development
3. Metrology
3.1. Dimensional and geometric tolerance
3.2. Roughness
4. Microstructure and Material properties
4.1. Introduction to Strengths of Materials/Statics Review
4.2. Physical, Mechanical and Technological properties
4.3. Principle Stresses and Mohr’s Circle
4.4. Materials Selection (Ashby approach using materials selection maps)
4.5. Experimental tests: Tensile test, Hardness tests
5. Casting
5.1. Liquid to solid transition; phase diagrams.
5.2. Microstructure of castings, Solidification Time, Shrinkage
5.3. The importance of oxide films and residual stresses
5.4. Sand casting, Die-casting, Centrifugal casting, Slush casting
5.5. Shell Molding, Investment casting
5.6. High pressure Die Casting
5.7. Design for castings
5.8. Defects in castings, Porosity
5.9. Trends in casting
6. Thermo-mechanical processing (forging, extrusion and rolling)
6.1. The importance of grain size;
6.2. Forging: General deformation characteristics, Hot working, Cold working, Open die forging, Closed die forging, Impression die forging.
6.3. Rolling: dynamics, forces, design.
6.4. Extrusion: Direct and indirect extrusion processes. The role of friction in extrusion.
6.5. Sheet Metalworking: Bending, Deep Drawing, Shearing and Blanking, Ironing, Spinning
6.6. Forming Limit curve
7. Machining processes
7.1. Orthogonal cutting: Tool geometry, Chip formation, Chip types, Cutting forces, Shear angle vs. shear stress
7.2. Cutting Processes: Turning, Milling, Drilling, Boring, Broaching, Sawing
7.3. Tool materials, tool wear mechanisms, tool life (Taylor law)
8. Finishing: Abrasive machining, Grinding
9. Process Selection: How to select a process.
Course program - Last names M-Z
1. Introduction. Processing overview. Materials-process matrix. Manufacturing systems
2. Manufacturing Processes
2.1. Technological and Economic Aspects
2.2. Manufacturing capabilities: Facilities Layouts
2.3. New Product Development
3. Metrology
3.1. Dimensional and geometric tolerance
3.2. Roughness
4. Microstructure and Material properties
4.1. Introduction to Strengths of Materials/Statics Review
4.2. Physical, Mechanical and Technological properties
4.3. Principle Stresses and Mohr's Circle
4.4. Materials Selection (Ashby approach using materials selection maps)
4.5. Experimental tests: Tensile test, Hardness tests
5. Casting
5.1. Liquid to solid transition; phase diagrams.
5.2. Microstructure of castings, Solidification Time, Shrinkage
5.3. The importance of oxide films and residual stresses
5.4. Sand casting, Die-casting, Centrifugal casting, Slush casting
5.5. Shell Molding, Investment casting
5.6. High pressure Die Casting
5.7. Design for castings
5.8. Defects in castings, Porosity
5.9. Trends in casting
6. Thermo-mechanical processing (forging, extrusion and rolling)
6.1. The importance of grain size;
6.2. Forging: General deformation characteristics, Hot working, Cold working, Open die forging, Closed die forging, Impression die forging.
6.3. Rolling: dynamics, forces, design.
6.4. Extrusion: Direct and indirect extrusion processes. The role of friction in extrusion.
6.5. Sheet Metalworking: Bending, Deep Drawing, Shearing and Blanking, Ironing, Spinning
6.6. Forming Limit curve
7. Machining processes
7.1. Orthogonal cutting: Tool geometry, Chip formation, Chip types, Cutting forces, Shear angle vs. shear stress
7.2. Cutting Processes: Turning, Milling, Drilling, Boring, Broaching, Sawing
7.3. Tool materials, tool wear mechanisms, tool life (Taylor law)
8. Finishing: Abrasive machining, Grinding
9. Process Selection: How to select a process.