PORTALE DELLA DIDATTICA

PORTALE DELLA DIDATTICA

PORTALE DELLA DIDATTICA

Elenco notifiche



Manufacturing processes

01NLEJM

A.A. 2018/19

Course Language

Inglese

Degree programme(s)

1st degree and Bachelor-level of the Bologna process in Ingegneria Meccanica (Mechanical Engineering) - Torino

Course structure
Teaching Hours
Lezioni 60
Esercitazioni in aula 20
Lecturers
Teacher Status SSD h.Les h.Ex h.Lab h.Tut Years teaching
De Maddis Manuela Ricercatore IIND-04/A 36 0 0 0 13
Co-lectures
Espandi

Context
SSD CFU Activities Area context
ING-IND/16 8 B - Caratterizzanti Ingegneria meccanica
2018/19
The course is aimed at developing the knowledge of production methods typical of mechanical industry. Description is than given of plastic deformation processes of metals, welding processes, foundry techniques and material removal processes, analyzing the relationships among them and the product requirements (i. e. performances and costs).
The course is aimed at developing the knowledge of production methods typical of mechanical industry. Description is than given of plastic deformation processes of metals, welding processes, foundry techniques and material removal processes, analyzing the relationships among them and the product requirements (i. e. performances and costs).
The knowledge of production processes utilized by the mechanical industry is necessary as the student must be capable of : - choosing process technologies, - choosing and, if required, collaborating in the design of production means; - preparing the manufacturing cycle of the part. At the end of the course the student must: - know and apply the relationships between materials and processes; - know and apply manufacturing techniques; - know and apply basic performances of production means (machines, tools/moulds/dies, fixtures and measurement/testing instruments); - know and apply process variables and their interactions with part requirements (quality, tolerances, surface roughness etc.) - know and apply the right actions in order to minimize the part cost; - know and apply the regulations concerning the industrial safety. As to judgement independence and communication cleverness, the student must: - write technical reports, also in English, with a high level of professionalism - evaluate production problems and find quickly their solutions as he knows the interactions among the various players in the production process and he has a sufficient experience in the evaluation of the magnitude order of involved variables; - get easily into touch with people, using English too.
The knowledge of production processes utilized by the mechanical industry is necessary as the student must be capable of : - choosing process technologies, - choosing and, if required, collaborating in the design of production means; - preparing the manufacturing cycle of the part. At the end of the course the student must: - know and apply the relationships between materials and processes; - know and apply manufacturing techniques; - know and apply basic performances of production means (machines, tools/moulds/dies, fixtures and measurement/testing instruments); - know and apply process variables and their interactions with part requirements (quality, tolerances, surface roughness etc.) - know and apply the right actions in order to minimize the part cost; - know and apply the regulations concerning the industrial safety. As to judgement independence and communication cleverness, the student must: - write technical reports, also in English, with a high level of professionalism - evaluate production problems and find quickly their solutions as he knows the interactions among the various players in the production process and he has a sufficient experience in the evaluation of the magnitude order of involved variables; - get easily into touch with people, using English too.
Ability in technical drawing, as every production process starts from the detailed drawing of the component; extensive knowledge of materials, especially metal. The mastery of English, spoken and written is essential.
Ability in technical drawing, as every production process starts from the detailed drawing of the component; extensive knowledge of materials, especially metal. The mastery of English, spoken and written is essential.
The course is aimed at developing the basic knowledge on manufacturing processes. Through lectures, demonstrations, and practical applications, the students will be introduced to the different types of manufacturing processes with the aim of making them able to select the most economic process which best meets the design requirements. The principal topics are: Mechanical fundamentals: ˑ Elastic and plastic behavior ˑ Stress and strain ˑ Stress and strain relationship for elastic behavior ˑ Element of the theory of plasticity Application to material testing ˑ Tensile test. Bridgman correction. Effect of temperature and strain rate. ˑ Compression test. W&F theory. ˑ Hardness test Fundamental of metalworking Bulk deformation Process ˑ Forging: open die forging process. ˑ Forging: closed die forging. ˑ Closed die design ˑ Extrusions. Material removal processes ˑ Orthogonal cutting. ˑ Chip types and chip removal mechanism. ˑ Velocity relationship. ˑ Cutting forces. Ernst & Merchant theory. ˑ Cutting pressure. Cutting power. ˑ Temperatures in cutting. ˑ Oblique cutting. Machining operations and machine tolls ˑ Turning. Engine lathe, CNC lathes, fixtures, tools geometry, characteristic angles, forces, powers. Surface roughness ˑ Milling: peripheral milling. Chip thickness. Cutting force. MRR. Helical milling cutter. Surface finish in milling. Working time. ˑ Milling: face milling. Chip thickness. Cutting force, Working time. ˑ Drilling: drill press e work holding. Cutting force and power. Drilling time Cutting tool technology ˑ Toll wear. Toll life . Taylor and Kronenberg equations. Economic and product design ˑ Optimization of cutting condition. Cutting speed for maximum production and minimum cost. Solidification processes ˑ Fundamental of metal casting. ˑ Sand Casting: from the draw to the pattern. Feeding system, gating system design, metallostatic force. ˑ Casting manufacturing processes: discussion of several expandable and permanent mold processes. ˑ Casting quality. Welding processes. Manufacturing system ˑ Computer Numerical Control. Programming (G-code, APT). ˑ Program structure. CNC milling.
The course is aimed at developing the basic knowledge on manufacturing processes. Through lectures, demonstrations, and practical applications, the students will be introduced to the different types of manufacturing processes with the aim of making them able to select the most economic process which best meets the design requirements. The principal topics are: Mechanical fundamentals: ˑ Elastic and plastic behavior ˑ Stress and strain ˑ Stress and strain relationship for elastic behavior ˑ Element of the theory of plasticity Application to material testing ˑ Tensile test. Bridgman correction. Effect of temperature and strain rate. ˑ Compression test. W&F theory. ˑ Hardness test Fundamental of metalworking Bulk deformation Process ˑ Forging: open die forging process. ˑ Forging: closed die forging. ˑ Closed die design ˑ Extrusions. Material removal processes ˑ Orthogonal cutting. ˑ Chip types and chip removal mechanism. ˑ Velocity relationship. ˑ Cutting forces. Ernst & Merchant theory. ˑ Cutting pressure. Cutting power. ˑ Temperatures in cutting. ˑ Oblique cutting. Machining operations and machine tolls ˑ Turning. Engine lathe, CNC lathes, fixtures, tools geometry, characteristic angles, forces, powers. Surface roughness ˑ Milling: peripheral milling. Chip thickness. Cutting force. MRR. Helical milling cutter. Surface finish in milling. Working time. ˑ Milling: face milling. Chip thickness. Cutting force, Working time. ˑ Drilling: drill press e work holding. Cutting force and power. Drilling time Cutting tool technology ˑ Toll wear. Toll life . Taylor and Kronenberg equations. Economic and product design ˑ Optimization of cutting condition. Cutting speed for maximum production and minimum cost. Solidification processes ˑ Fundamental of metal casting. ˑ Sand Casting: from the draw to the pattern. Feeding system, gating system design, metallostatic force. ˑ Casting manufacturing processes: discussion of several expandable and permanent mold processes. ˑ Casting quality. Welding processes. Manufacturing system ˑ Computer Numerical Control. Programming (G-code, APT). ˑ Program structure. CNC milling.
During the course, the students will solve different practical exercises using numerical tools, such as excel, Q_Form and CNC simulator, and will visit a laboratory of the Polytechnic of Turin.
During the course, the students will solve different practical exercises using numerical tools, such as excel, Q_Form and CNC simulator, and will visit a laboratory of the Polytechnic of Turin.
Manufacturin Engineering and Technology S. Kalpakjian, S.R. Schmid Pearson Fundamentals od Modern Manufacturing Mikell P. Groover John Wiley & sons, inc. Mechanical Metallurgy George E. Dieter Mc Graw - Hill Book Company Slides and exercices available on the Didactic Portal at the end of each lesson.
Manufacturin Engineering and Technology S. Kalpakjian, S.R. Schmid Pearson Fundamentals od Modern Manufacturing Mikell P. Groover John Wiley & sons, inc. Mechanical Metallurgy George E. Dieter Mc Graw - Hill Book Company Slides and exercices available on the Didactic Portal at the end of each lesson.
Modalità di esame: Prova scritta (in aula); Prova orale facoltativa; Progetto di gruppo;
Exam: Written test; Optional oral exam; Group project;
... The overall exam consists of two compulsory parts: 1) A written examination concerning the whole program and including theoretical questions (max 4 points) and practical exercises (max 20 points). Score range is 0-24. Time exam is 1,5 / 2 hours. Students are allowed to use a personal formula sheet (a single A4 page) and a simple calculator (i.e. not scientific). Students cannot use any material, such as books or electronic devices (i.e. mobile phones/notebooks). 2) A homework on plastic deformation of metals and relative manufacturing processes. Score range is 0-6. The homework is developed in a team composed of 4-5 students. Members of the teams are announced within the two-third of the lectures. Each team is charged to face and analyze a case study using the tools and the methods introduced during the lectures and, at the end of their task, deliver a report on the performed activity and the obtained results. The final report must be uploaded on the didactical portal using the tab “elaborati”, one week before the first official session exam. The report on the assigned case study must be presented and discussed by the team during the official exam session. The personal evaluation of the homework is based on the report and the individual presentation and discussion of the case study. Homework score will be valid only in the current A.Y. The final exam score will be the sum of the marks obtained in the two parts. Students pass the exam if the sum ranges between 18 and 30 marks. The student who does not upload the report within the deadline or doesn’t get a “pass” mark in the oral discussion can achieve a final exam score limited to the written exam evaluation.
Gli studenti e le studentesse con disabilità o con Disturbi Specifici di Apprendimento (DSA), oltre alla segnalazione tramite procedura informatizzata, sono invitati a comunicare anche direttamente al/la docente titolare dell'insegnamento, con un preavviso non inferiore ad una settimana dall'avvio della sessione d'esame, gli strumenti compensativi concordati con l'Unità Special Needs, al fine di permettere al/la docente la declinazione più idonea in riferimento alla specifica tipologia di esame.
Exam: Written test; Optional oral exam; Group project;
The overall exam consists of two compulsory parts: 1) A written examination concerning the whole program and including theoretical questions (max 4 points) and practical exercises (max 20 points). Score range is 0-24. Time exam is 1,5 / 2 hours. Students are allowed to use a personal formula sheet (a single A4 page) and a simple calculator (i.e. not scientific). Students cannot use any material, such as books or electronic devices (i.e. mobile phones/notebooks). 2) A homework on plastic deformation of metals and relative manufacturing processes. Score range is 0-6. The homework is developed in a team composed of 4-5 students. Members of the teams are announced within the two-third of the lectures. Each team is charged to face and analyze a case study using the tools and the methods introduced during the lectures and, at the end of their task, deliver a report on the performed activity and the obtained results. The final report must be uploaded on the didactical portal using the tab “elaborati”, one week before the first official session exam. The report on the assigned case study must be presented and discussed by the team during the official exam session. The personal evaluation of the homework is based on the report and the individual presentation and discussion of the case study. Homework score will be valid only in the current A.Y. The final exam score will be the sum of the marks obtained in the two parts. Students pass the exam if the sum ranges between 18 and 30 marks. The student who does not upload the report within the deadline or doesn’t get a “pass” mark in the oral discussion can achieve a final exam score limited to the written exam evaluation.
In addition to the message sent by the online system, students with disabilities or Specific Learning Disorders (SLD) are invited to directly inform the professor in charge of the course about the special arrangements for the exam that have been agreed with the Special Needs Unit. The professor has to be informed at least one week before the beginning of the examination session in order to provide students with the most suitable arrangements for each specific type of exam.
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