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Planning of Sustainable Mining/Occupational Safety Engineering
01DVMNW
A.A. 2023/24
Occupational safety engineering
The course deals with Occupational Safety & Health (OSH) aspects related to industrial and mining/construction activities. The goal is to examine the different workplaces and conditions and learn about the main actions to prevent the hazards. The main risks and hazards are discussed and analyzed, as well as the preparation of a safety & health concept and its meaning on the process of mitigating the risks. Analysis of notable examples and statistics from different workplaces will be carried out in order to ease the learning process.
Planning of Sustainable Mining/Occupational Safety Engineering
Planning of Sustainable Mining Mine planning has the goal of minimizing the capital and operating costs of the ultimate project, while maximizing the operability and profitability of the venture: it sets the economic and technical direction of a project, by taking into account the correct strategy to be adopted for its economic, social, and environmental success. Geological analysis, computation of geological and minable reserves, determination of preproduction mining or development requirements, production and stripping schedules, labour and equipment requirements and costs, revenue forecasts, and cash flow management are all factors to consider in mine planning. A geological model, the ore distribution in the rock mass, and the geomechanical model of the ore deposit are the basis for the design of both open-pit and underground mines, for selecting the appropriate mine development and planning. The equipment selection, the exploitation sequence, and the stripping management, including the problems related to the waste, are fundamental aspects of mine planning. Moreover, following the approach of sustainability and circular economy, also the valorisation of the by-product should be planned and foreseen at the beginning of the work activities. The subject is inherently linked to resources and environmental sustainability, excavation engineering and mining plants, raw material processing and recycling, and environmental management of soil, water and groundwater in geoengineering. Occupational Safety Engineering The course deals with the issues related to work safety in civil and mining activities. The main risks associated with civil works and mining exploitation are analyzed to counteract them with the correct planning of the activities. Analyses of notable examples and statistics from different construction site works will be made.
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
Mine planning has the goal of minimizing the capital and operating costs of the ultimate project, while maximizing the operability and profitability of the venture: it sets the economic and technical direction of a project, by taking into account the correct strategy to be adopted for its economic, social, and environmental success. Geological analysis, computation of geological and minable reserves, determination of preproduction mining or development requirements, production and stripping schedules, labour and equipment requirements and costs, revenue forecasts, and cash flow management are all factors to consider in mine planning. A geological model, the ore distribution in the rock mass, and the geomechanical model of the ore deposit are the basis for the design of both open-pit and underground mines, for selecting the appropriate mine development and planning. The equipment selection, the exploitation sequence, and the stripping management, including the problems related to the waste, are fundamental aspects of mine planning. Moreover, following the approach of sustainability and circular economy, also the valorisation of the by-product should be planned and foreseen at the beginning of the work activities. The subject is inherently linked to resources and environmental sustainability, excavation engineering and mining plants, raw material processing and recycling, and environmental management of soil, water and groundwater in geoengineering.
Occupational safety engineering
The course deals with Occupational Safety & Health (OSH) aspects related to industrial and mining/construction activities. The goal is to examine the different workplaces and conditions and learn about the main actions to prevent the hazards. The main risks and hazards are discussed and analyzed, as well as the preparation of a safety & health concept and its meaning on the process of mitigating the risks. Analysis of notable examples and statistics from different workplaces will be carried out in order to ease the learning process.
Planning of Sustainable Mining/Occupational Safety Engineering
Planning of Sustainable Mining Mine planning has the goal of minimizing the capital and operating costs of the ultimate project, while maximizing the operability and profitability of the venture: it sets the economic and technical direction of a project, by taking into account the correct strategy to be adopted for its economic, social, and environmental success. Geological analysis, computation of geological and minable reserves, determination of preproduction mining or development requirements, production and stripping schedules, labour and equipment requirements and costs, revenue forecasts, and cash flow management are all factors to consider in mine planning. A geological model, the ore distribution in the rock mass, and the geomechanical model of the ore deposit are the basis for the design of both open-pit and underground mines, for selecting the appropriate mine development and planning. The equipment selection, the exploitation sequence, and the stripping management, including the problems related to the waste, are fundamental aspects of mine planning. Moreover, following the approach of sustainability and circular economy, also the valorisation of the by-product should be planned and foreseen at the beginning of the work activities. The subject is inherently linked to resources and environmental sustainability, excavation engineering and mining plants, raw material processing and recycling, and environmental management of soil, water and groundwater in geoengineering. Occupational Safety Engineering The course deals with the issues related to work safety in civil and mining activities. The main risks associated with civil works and mining exploitation are analyzed to counteract them with the correct planning of the activities. Analyses of notable examples and statistics from different construction site works will be made.
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
Mine planning has the goal of minimizing the capital and operating costs of the ultimate project, while maximizing the operability and profitability of the venture: it sets the economic and technical direction of a project, by taking into account the correct strategy to be adopted for its economic, social, and environmental success. Geological analysis, computation of geological and minable reserves, determination of preproduction mining or development requirements, production and stripping schedules, labour and equipment requirements and costs, revenue forecasts, and cash flow management are all factors to consider in mine planning. A geological model, the ore distribution in the rock mass, and the geomechanical model of the ore deposit are the basis for the design of both open-pit and underground mines, for selecting the appropriate mine development and planning. The equipment selection, the exploitation sequence, and the stripping management, including the problems related to the waste, are fundamental aspects of mine planning. Moreover, following the approach of sustainability and circular economy, also the valorisation of the by-product should be planned and foreseen at the beginning of the work activities. The subject is inherently linked to resources and environmental sustainability, excavation engineering and mining plants, raw material processing and recycling, and environmental management of soil, water and groundwater in geoengineering.
Occupational safety engineering
Students are asked to: - understand the leading causes of accidents or damage to workers' health in industrial and mining/construction activities; - properly identify the hazards in the working environments; - learn the operational techniques to mitigate the risks of planning operations and activities correctly and safely; - understand the process steps and structure of a safety&health concept (including risk analysis, safety analysis and their implementation).
Planning of Sustainable Mining/Occupational Safety Engineering
Planning Sustainable Mining The student will acquire the theoretical notions underlying the mine planning, to be able to design mining activities taking into account the economic, social and environmental sustainability. The mine planning competences are essential also to optimize the subsequent treatment process and to reach valuable yield for the target minerals. Occupational Safety Engineering Students are asked to understand the leading causes of accidents or damage to workers' health in civil works, quarries, and mines and the operational techniques to reduce the risk of planning operations and activities correctly and safely.
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
The student will acquire the theoretical notions underlying the mine planning, to be able to design mining activities taking into account the economic, social and environmental sustainability. The mine planning competences are essential also to optimize the subsequent treatment process and to reach valuable yield for the target minerals.
Occupational safety engineering
Students are asked to: - understand the leading causes of accidents or damage to workers' health in industrial and mining/construction activities; - properly identify the hazards in the working environments; - learn the operational techniques to mitigate the risks of planning operations and activities correctly and safely; - understand the process steps and structure of a safety&health concept (including risk analysis, safety analysis and their implementation).
Planning of Sustainable Mining/Occupational Safety Engineering
Planning Sustainable Mining The student will acquire the theoretical notions underlying the mine planning, to be able to design mining activities taking into account the economic, social and environmental sustainability. The mine planning competences are essential also to optimize the subsequent treatment process and to reach valuable yield for the target minerals. Occupational Safety Engineering Students are asked to understand the leading causes of accidents or damage to workers' health in civil works, quarries, and mines and the operational techniques to reduce the risk of planning operations and activities correctly and safely.
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
The student will acquire the theoretical notions underlying the mine planning, to be able to design mining activities taking into account the economic, social and environmental sustainability. The mine planning competences are essential also to optimize the subsequent treatment process and to reach valuable yield for the target minerals.
Occupational safety engineering
Fundamentals of geomechanics, continuum mechanics and chemistry
Planning of Sustainable Mining/Occupational Safety Engineering
Planning Sustainable Mining Students should be familiar with the fundamentals of physics, chemistry, statistics, and material sciences. They should also have some competence in the fields of excavation techniques and technologies, processing plants and be able to make a preliminary economic assessment. Occupational Safety Engineering Fundamentals of geomechanics and continuum mechanics
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
Students should be familiar with the fundamentals of physics, chemistry, statistics, and material sciences. They should also have some competence in the fields of excavation techniques and technologies, processing plants and be able to make a preliminary economic assessment.
Occupational safety engineering
Fundamentals of geomechanics, continuum mechanics and chemistry
Planning of Sustainable Mining/Occupational Safety Engineering
Planning Sustainable Mining Students should be familiar with the fundamentals of physics, chemistry, statistics, and material sciences. They should also have some competence in the fields of excavation techniques and technologies, processing plants and be able to make a preliminary economic assessment. Occupational Safety Engineering Fundamentals of geomechanics and continuum mechanics
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
Students should be familiar with the fundamentals of physics, chemistry, statistics, and material sciences. They should also have some competence in the fields of excavation techniques and technologies, processing plants and be able to make a preliminary economic assessment.
Occupational safety engineering
1. General aspects of Occupational Safety & Health (OSH) 2. The organization of activities; primary sources of risk for workers 3. International legislation on safety in the industrial and mining/construction sector 4. Analysis of occupational risks; causes of accidents and strategies for the containment of accidents in industrial and mining/construction activities 5. Safety and health concept (risk analysis, safety analysis and implementation) 6. Hazard awareness and identification; recognized and foreseeable hazard 7. Hierarchy of controls and its application 8. Emergency action and fire prevention plans 9. Risks in the industrial and mining/construction sector: dust, asbestos, radiation and electromagnetic pollution 10. Microclimate and basic ergonomics 11. OSHA’s “Fatal Four” (Falls, Caught-In or -Between, Struck-By and Electrocution) 12. Noise and vibration control in the industrial sector 13. Geotechnical risks
Planning of Sustainable Mining/Occupational Safety Engineering
Planning Sustainable Mining European and international mining legislation. Mining and sustainability: the ISO 55000 standard and the optimization of the asset management system in mining. Development of the mine and plant concepts; calculation or estimation of the equipment and all important amounts (of excavation, building area and volume, etc.); provisional construction schedule. Introduction to geostatistics and its contribution in a number of techniques which can be used in the design stage of underground and open pit mining. Reserve estimation, mining planning optimization, production forecasting, resources optimization. Cost estimating for underground mining/surface mining. Mining Economics and Strategies. Discretized orebody model of the deposit; the value of each block by comparing market prices for ore with extraction and processing costs. Cut-off grade and production rate for a sustainable mining. Planning for closure: lease agreements, surface and underground facilities, water management, site rehabilitation, socio-economic aspects. Corporate social responsibilities. The process to achieve the Social License to Operate and the Environmental Assessment for mining activities. Some significant case studies are presented and discussed with a view to the sustainable use of natural resources, referring both to open pit and underground mining. Occupational Safety Engineering 1. General aspects of safety issues 2. The organization of activities; primary sources of risk for workers 3. International legislation on safety in the civil and mining sector 4. Analysis of occupational risks; causes of accidents and strategies for the containment of accidents in civil works and mining 5. Risk of accidents and damage to the health of workers resulting from dust, asbestos, radiation and electromagnetic pollution, from the radioactivity of rock formations 6. Risks related to the poor lighting of underground environments 7. Risks linked to the particular conditions of the microclimate of underground spaces 8. Risks related to the noise produced by machines and plants 9. Risks due to the fall or slipping of rock blocks from the profile of the underground voids; risks of collapse of the excavation face or the heaps of the excavated material; the instability of mining landfills; the collapse due to buckling of support struts in underground cavities 10. Risks linked to the early activation of the mine blasting circuit, to the throwing of the shot down material, to the presence of unexploded sticks after blasting 11. Risks related to the explosion of the underground atmosphere in the presence of inflammatory gas and explosive dust; risks of fires in confined environments.
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
European and international mining legislation. Mining and sustainability: the ISO 55000 standard and the optimization of the asset management system in mining. Development of the mine and plant concepts; calculation or estimation of the equipment and all important amounts (of excavation, building area and volume, etc.); provisional construction schedule. Introduction to geostatistics and its contribution in a number of techniques which can be used in the design stage of underground and open pit mining. Reserve estimation, mining planning optimization, production forecasting, resources optimization. Cost estimating for underground mining/surface mining. Mining Economics and Strategies. Discretized orebody model of the deposit; the value of each block by comparing market prices for ore with extraction and processing costs. Cut-off grade and production rate for a sustainable mining. Planning for closure: lease agreements, surface and underground facilities, water management, site rehabilitation, socio-economic aspects. Corporate social responsibilities. The process to achieve the Social License to Operate and the Environmental Assessment for mining activities. Some significant case studies are presented and discussed with a view to the sustainable use of natural resources, referring both to open pit and underground mining.
Occupational safety engineering
1. General aspects of Occupational Safety & Health (OSH) 2. The organization of activities; primary sources of risk for workers 3. International legislation on safety in the industrial and mining/construction sector 4. Analysis of occupational risks; causes of accidents and strategies for the containment of accidents in industrial and mining/construction activities 5. Safety and health concept (risk analysis, safety analysis and implementation) 6. Hazard awareness and identification; recognized and foreseeable hazard 7. Hierarchy of controls and its application 8. Emergency action and fire prevention plans 9. Risks in the industrial and mining/construction sector: dust, asbestos, radiation and electromagnetic pollution 10. Microclimate and basic ergonomics 11. OSHA’s “Fatal Four” (Falls, Caught-In or -Between, Struck-By and Electrocution) 12. Noise and vibration control in the industrial sector 13. Geotechnical risks
Planning of Sustainable Mining/Occupational Safety Engineering
Planning Sustainable Mining European and international mining legislation. Mining and sustainability: the ISO 55000 standard and the optimization of the asset management system in mining. Development of the mine and plant concepts; calculation or estimation of the equipment and all important amounts (of excavation, building area and volume, etc.); provisional construction schedule. Introduction to geostatistics and its contribution in a number of techniques which can be used in the design stage of underground and open pit mining. Reserve estimation, mining planning optimization, production forecasting, resources optimization. Cost estimating for underground mining/surface mining. Mining Economics and Strategies. Discretized orebody model of the deposit; the value of each block by comparing market prices for ore with extraction and processing costs. Cut-off grade and production rate for a sustainable mining. Planning for closure: lease agreements, surface and underground facilities, water management, site rehabilitation, socio-economic aspects. Corporate social responsibilities. The process to achieve the Social License to Operate and the Environmental Assessment for mining activities. Some significant case studies are presented and discussed with a view to the sustainable use of natural resources, referring both to open pit and underground mining. Occupational Safety Engineering 1. General aspects of safety issues 2. The organization of activities; primary sources of risk for workers 3. International legislation on safety in the civil and mining sector 4. Analysis of occupational risks; causes of accidents and strategies for the containment of accidents in civil works and mining 5. Risk of accidents and damage to the health of workers resulting from dust, asbestos, radiation and electromagnetic pollution, from the radioactivity of rock formations 6. Risks related to the poor lighting of underground environments 7. Risks linked to the particular conditions of the microclimate of underground spaces 8. Risks related to the noise produced by machines and plants 9. Risks due to the fall or slipping of rock blocks from the profile of the underground voids; risks of collapse of the excavation face or the heaps of the excavated material; the instability of mining landfills; the collapse due to buckling of support struts in underground cavities 10. Risks linked to the early activation of the mine blasting circuit, to the throwing of the shot down material, to the presence of unexploded sticks after blasting 11. Risks related to the explosion of the underground atmosphere in the presence of inflammatory gas and explosive dust; risks of fires in confined environments.
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
60 hours will be organized as follows: European and international mining legislation. Mining and sustainability: the ISO 55000 standard and the optimization of the asset management system in mining (3h). Development of the mine and plant concepts; calculation or estimation of the equipment and all important amounts (of excavation, building area and volume, etc.); provisional construction schedule (6h). Introduction to geostatistics and its contribution in a number of techniques which can be used in the design stage of underground and open pit mining (5h). Reserve estimation, mining planning optimization, production forecasting, resources optimization (9h). Cost estimating for underground mining/surface mining (3h). Mining Economics and Strategies (5h). Planning for closure: lease agreements, surface and underground facilities, water management, site rehabilitation, waste management, socio-economic aspects (3h). Discretized orebody model of the deposit; the value of each block by comparing market prices for ore with extraction and processing costs. Cut-off grade and production rate for a sustainable mining (20h). Corporate social responsibilities. The process to achieve the Social License to Operate and the Environmental Assessment for mining activities. Some significant case studies are presented and discussed with a view to the sustainable use of natural resources, referring both to open pit and underground mining (6h).
Occupational safety engineering
Planning of Sustainable Mining/Occupational Safety Engineering
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
Occupational safety engineering
Planning of Sustainable Mining/Occupational Safety Engineering
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
Occupational safety engineering
The course is organized in theoretical lessons and exercises. The exercises will cover different environments typical of industrial and mining/construction activities. For each of them, the risks will be analyzed and the procedures for their containment will be defined. The exercises are carried out by the students in groups and are assisted by the lecturers.
Planning of Sustainable Mining/Occupational Safety Engineering
Planning of Sustainable Mining The course is organized in theoretical lessons and practical exercises. The exercises will focus on some aspects addressed during the course. Occupational Safety Engineering The course is organized in theoretical lessons and exercises. The exercises will cover different environments typical of civil and mining activities. For each of them the risks will be analyzed and the procedures for their containment defined. The exercises are carried out by the students in groups and are assisted by the teachers.
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
The course is organized in theoretical lessons and practical exercises. The exercises will focus on some aspects addressed during the course.
Occupational safety engineering
The course is organized in theoretical lessons and exercises. The exercises will cover different environments typical of industrial and mining/construction activities. For each of them, the risks will be analyzed and the procedures for their containment will be defined. The exercises are carried out by the students in groups and are assisted by the lecturers.
Planning of Sustainable Mining/Occupational Safety Engineering
Planning of Sustainable Mining The course is organized in theoretical lessons and practical exercises. The exercises will focus on some aspects addressed during the course. Occupational Safety Engineering The course is organized in theoretical lessons and exercises. The exercises will cover different environments typical of civil and mining activities. For each of them the risks will be analyzed and the procedures for their containment defined. The exercises are carried out by the students in groups and are assisted by the teachers.
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
The course is organized in theoretical lessons and practical exercises. The exercises will focus on metal and not metal mine case studies with reference to discretization of ore body and pit limits, taking into account the aspects related to sustainability.
Occupational safety engineering
a) Slide presentations and other documents used for classes; b) Reese C.D. (2017). Occupational Safety and Health. Fundamental Principles and Philosophies. CRC Press c) Selected additional readings d) Official reports from International Labour Office and other governing bodies such as OSHA
Planning of Sustainable Mining/Occupational Safety Engineering
Planning of Sustainable Mining Teaching material: the slides will be made available to students on the course portal. Furthermore, technical reports and open access publications relating to the topics of the course will be suggested. 1) Open Pit Mine Planning and Design-W. Hustrulid et al. 2) SME Mining Engineering Handbook-H.L. Hartman Occupational Safety Engineering a) Slide presentations and other documentary material used for lessons; b) indicated in-depth texts on each topic, available in the DIATI-Politecnico di Torino library or freely on Internet; c) official reports from International Labour Office and other governing bodies
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
Teaching material: the slides will be made available to students on the course portal. Furthermore, technical reports and open access publications relating to the topics of the course will be suggested. 1) Open Pit Mine Planning and Design-W. Hustrulid et al. 2) SME Mining Engineering Handbook-H.L. Hartman
Occupational safety engineering
a) Slide presentations and other documents used for classes; b) Reese C.D. (2017). Occupational Safety and Health. Fundamental Principles and Philosophies. CRC Press c) Selected additional readings d) Official reports from International Labour Office and other governing bodies such as OSHA
Planning of Sustainable Mining/Occupational Safety Engineering
Planning of Sustainable Mining Teaching material: the slides will be made available to students on the course portal. Furthermore, technical reports and open access publications relating to the topics of the course will be suggested. 1) Open Pit Mine Planning and Design-W. Hustrulid et al. 2) SME Mining Engineering Handbook-H.L. Hartman Occupational Safety Engineering a) Slide presentations and other documentary material used for lessons; b) indicated in-depth texts on each topic, available in the DIATI-Politecnico di Torino library or freely on Internet; c) official reports from International Labour Office and other governing bodies
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
Teaching material: the slides will be made available to students on the course portal. Furthermore, technical reports and open access publications relating to the topics of the course will be suggested. 1) Open Pit Mine Planning and Design-W. Hustrulid et al. 2) SME Mining Engineering Handbook-H.L. Hartman
Occupational safety engineering
Slides; Esercizi; Materiale multimediale ;
Planning of Sustainable Mining/Occupational Safety Engineering
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
Dispense; Libro di testo;
Occupational safety engineering
Lecture slides; Exercises; Multimedia materials;
Planning of Sustainable Mining/Occupational Safety Engineering
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
Lecture notes; Text book;
Occupational safety engineering
Modalità di esame: Prova orale obbligatoria;
Planning of Sustainable Mining/Occupational Safety Engineering
Modalità di esame: Prova scritta (in aula); Prova orale obbligatoria;
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
Modalità di esame: Prova scritta (in aula); Prova orale obbligatoria;
Occupational safety engineering
Exam: Compulsory oral exam;
Planning of Sustainable Mining/Occupational Safety Engineering
Exam: Written test; Compulsory oral exam;
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
Exam: Written test; Compulsory oral exam;
Occupational safety engineering
The exam is oral and requires answering questions regarding the course topics, including possible problem-solving related to actual cases. Students are expected to correctly understand the aspects of designing a safe working environment in different industrial and mining/construction sites and possibly understand and manage the risks associated with these works, in agreement with the expected learning outcomes.
Planning of Sustainable Mining/Occupational Safety Engineering
Planning of Sustainable Mining Written and oral exam. The written exam will focus on open theoretical questions and / or short exercises, and will last approximately 120 minutes. To access the oral exam, it is necessary to reach a score of at least 18/30. The oral exam will be focused on further details related to the written part, and the general understanding acquired on the topics of the course will be investigated. Occupational Safety Engineering The exam is oral and requires answering questions regarding the course topics, including possible problem-solving related to actual cases. Students are expected to correctly understand the aspects of designing a safe working environment in different civil and mining construction sites and possibly understand and manage the risks associated with these works, in agreement with the expected learning outcomes.
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
Written and oral exam. The written exam will focus on open theoretical questions and / or short exercises, and will last approximately 120 minutes. To access the oral exam, it is necessary to reach a score of at least 18/30. The oral exam will be focused on further details related to the written part, and the general understanding acquired on the topics of the course will be investigated. The single final score will result from the combination of the partial scores obtained in the two modules into which the course is divided. The exam is considered passed if the final score is not lower than 18/30.
Occupational safety engineering
Exam: Compulsory oral exam;
Planning of Sustainable Mining/Occupational Safety Engineering
Exam: Written test; Compulsory oral exam;
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
Exam: Written test; Compulsory oral exam;
Occupational safety engineering
The exam is oral and requires answering questions regarding the course topics, including possible problem-solving related to actual cases. Students are expected to correctly understand the aspects of designing a safe working environment in different industrial and mining/construction sites and possibly understand and manage the risks associated with these works, in agreement with the expected learning outcomes.
Planning of Sustainable Mining/Occupational Safety Engineering
Planning of Sustainable Mining Written and oral exam. The written exam will focus on open theoretical questions and / or short exercises, and will last approximately 120 minutes. To access the oral exam, it is necessary to reach a score of at least 18/30. The oral exam will be focused on further details related to the written part, and the general understanding acquired on the topics of the course will be investigated. Occupational Safety Engineering The exam is oral and requires answering questions regarding the course topics, including possible problem-solving related to actual cases. Students are expected to correctly understand the aspects of designing a safe working environment in different civil and mining construction sites and possibly understand and manage the risks associated with these works, in agreement with the expected learning outcomes.
Planning of Sustainable Mining/Occupational Safety Engineering (Planning of Sustainable Mining)
Written and oral exam. The written exam will focus on open theoretical questions and / or short exercises, and will last approximately 120 minutes. To access the oral exam, it is necessary to reach a score of at least 18/30. The oral exam will be focused on further details related to the written part, and the general understanding acquired on the topics of the course will be investigated. The single final score will result from the combination of the partial scores obtained in the two modules into which the course is divided. The exam is considered passed if the final score is not lower than 18/30.