SWAGºÏ¼¯

To introduce you to the core factors of managing operations and the concept of flow in operations.

• An introduction to manufacturing organisations and functions.

• The theory of operations, flow in manufacturing and what enables/inhibits it.

• Order winners, Order qualifiers, and competitive priorities.

• Key Performance Indicators in manufacturing.

• Product/Process matrix, facility layouts, production strategies, product families.

• Customer Demand and capacity planning, and standardization.

• Process flow diagrams, and value stream maps.

• S&OP, Master Production Scheduling, BOM, and scheduling rules.

• Push vs Pull production.

• Information systems; MRP, MPRll, ERP, and Kanban systems.

• Maintenance management strategies.

• Dimensions of Quality, Quality management frameworks, and the cost of quality.

• Roles of inventory; inventory management systems and measures.

• Lean Manufacturing.

• Class discussion of cases, exercises, and videos to support this syllabus.

On successful completion of this module you will be able to:

1. Discuss the importance of the operations functions of an organisation and how operations performance can impact the success of the whole organisation.

2. Assess production and capacity management strategies that can be deployed to meet customer demand for products and services.

3. Assess the importance of inventory, maintenance, and quality management systems in achieving high levels of operational performance.

4. Determine the role of information in planning, control, and scheduling, including the role of IT systems.

5. Critique the different attributes of the Lean Production System and how they apply to contemporary operational contexts.

​To prepare you with the knowledge and skills required to influence, lead, and manage feasible change programmes effectively within the manufacturing industry.​

• Business Finance.

• Fundamentals of Business Finance.

• Financial Ratios for Manufacturing.

• Feasibility SWAGºÏ¼¯.

• Cash flow vs Profit.

• Business Case Development.

• Business Case Structure.

• Agile/waterfall Project Management techniques.

• Stakeholder Mapping & Communication.

• Negotiation.

• Procurement.

• Risk Assessment.

• Implementing Change.

• Industrial & Organisation Psychology.

• Organisational Structure & Culture.

• The Role of People in Change.

• Change Management Metrics.

• Sustaining Change.

• Innovation & Technology.

• Technology as enabler of change.

• Technology Analysis.

• Technology roadmapping.

• Incremental (Kaizen) vs Radical (Kaikaku) Innovation.

• Enablers and Inhibitors of Innovation.

• Innovation Tools.

On successful completion of this module you will be able to:

1. Analyse the financial end of change initiatives in manufacturing and their impact on financial indicators and cashflow.
2. Construct a comprehensive business case report covering key areas such as project charter, project feasibility, stakeholder communication, scenario analysis, procurement, and risk assessment.
3. Recognise the nature of change initiatives and the factors that influence effective delivery.
4. Assess the various project management tools for their project-specific suitability to aid in the design, planning, implementation, measuring, and sustaining change in manufacturing.
5. Appraise the different roles of innovation and technology, analyse different technologies, and apply innovative problem-solving techniques to successfully implementing change programmes in manufacturing.

To develop your skills to a rigorous and logical application of tools and techniques for the design and control operational systems.

• Six Sigma, Process capability, common and special cause variability, control charts, acceptance sampling.

• Lean Manufacturing elements such as Value Stream Mapping and Waste identification.

• Analysis of systems to produce simple models. IDEF0 and IDEF3 and their application. Business process fundamentals and the process review. Improvement procedures, modelling methods and process models. Performance measurement. Responding to and improving reliability.

To develop your understanding of complex manufacturing systems engineering through the application of different modelling and simulation tools, techniques and methodologies with a view to analyse and (re)design manufacturing systems that maximise efficiency, productivity and competitiveness.​​

• Introduction to modelling: taxonomy, overview of methods and techniques.

• Design of manufacturing layouts.

• Manufacturing layout Manufacturing Systems modelling using discrete-event simulation, Systems dynamics and Agent-based simulation techniques and methodologies.

• Case study Analysis of manufacturing systems using simulation.

On successful completion of this module you should be able to:

1. ​​​Differentiate the applicability of different modelling approaches applicable in manufacturing businesses.

2. ​Assess how production layout and system design influences manufacturing system performance.

3. ​Design a graphical simulation model using an industry leading discrete-event simulation tool.

4. ​Devise an experimental procedure and interpret the consequential results of the simulation model.

5. ​Appraise the effectiveness of manufacturing layout configurations.

​Provide an understanding of the methods and tools and develop the skills that enable sustainability-related decision-making in manufacturing systems at different scoping levels: from individual processes to world-wide complex supply chains.

What is sustainable manufacturing system analysis?

Sustainable manufacturing basics.

Net Zero targets drivers and challenges (barriers)

Sustainable:

• processes,

• enterprises,

• supply chains.

Industry 4.0 contribution to sustainability.

Analysis tools:

• Green VSM.

• LCA and relevant certification.

• Multiple Criteria Decision Analysis.

• Examples and case studies:

- process selection

- material selection,

- lean improvements.

On successful completion of this module you should be able to:

1. 1. Formulate an understanding of distinctive drivers and barriers of sustainability in manufacturing systems within the broader context of worldwide sustainability pressures.
2. 2. Synthesise approaches to sustainability in manufacturing systems based on stake-holder standpoints and relevant scoping.
3. 3. Evaluate quantitative sustainability indicators to supplement traditional decision-making in manufacturing systems according to different stake-holders.

To equip you with the knowledge needed to transition from traditional manufacturing to smart manufacturing environments by diving into the core technologies and enablers of smart manufacturing such as SCADA systems, Enterprise Systems, Industrial Internet of Things (IIoT), and Cyber-Physical Production Systems (CPPS), in addition to exploring data-driven decision-making.

• Smart manufacturing – Smart products.

• Enterprise Resource Planning (ERP).

• Industrial Internet of Things.

• Cyber Physical Production Systems (CPPS).

• Life Cycle Management.

• Programmable Logical Controller (PLC).

• Supervisory Control and Data Acquisition (SCADA) systems.

• Manufacturing Execution System (MES).

• Machine Learning.

• Cloud Manufacturing.

• Business Transformation.

• SAP systems.

On successful completion of this module you should be able to:

1. To construct solid knowledge of the functions and applications of PLCs, SCADA systems, Enterprise Systems, IIoT, and CPPS.

2. To revise the practice of resource management from an enterprise systems perspective using tools like SAP within a smart factory ecosystem.

3. To assess the opportunities for integrating Machine Learning and AI models into manufacturing processes.

4. To examine data analytics techniques on SCADA systems for production analysis and data-driven solutions using the appropriate methods..

5. To formulate an understanding of the upcoming changes in the manufacturing landscape such as human-machine interaction socio-technical systems.

To introduce you to the wider issues surrounding the management and optimisation of supply chains.

• Supply chain concepts

• Supply chain strategy

• Relationship management

• Supplier Selection and Evaluation

• Supplier Sustainability

• Supply chain Planning

• Design & Operating SC

• Outsourcing Product Design and Manufacturing

On successful completion of this module you will be able to:

1. Evaluate issues surrounding the development of the right supply chain strategy for the business / product groups. 

2. Create strategies for managing the information flows in a supply network in order to reduce the bullwhip effect and the challenges of accurate demand and forecast planning.

3. Evaluate the challenges with improving performance of supply networks and gain familiarity with the application of a variety of supply chain tools to help in the re-design of the SC.

4. Apply criteria in the sourcing, evaluation and validation of suitable providers of parts, design and manufacturing services for the supply of a complex engineered product.

5. Integrate procurement and supplier management for the supply chain to function effectively.

To develop your skills to analyse and manage the direction of a business, to design and develop manufacturing strategy to deliver competitive advantage and plan effective deployment of a strategy.

• Competitive manufacturing strategy concepts.
• Benchmarking of manufacturing system performance.
• Manufacturing strategy in business success.
• Strategy formation and formulation, leading on to system design.
• Structured strategy formulation and system design methodologies.
• Approaches to strategy formulation in differing business contexts.
• Realisation of new strategies/system designs, including approaches to implementation.
• Case study on design of competitive manufacturing strategy.

On successful completion of this module you should be able to:

1. Distinguish manufacturing strategy from corporate strategy.

2. Demonstrate manufacturing strategy formulation.

3. Apply a structured methodology to create a competitive manufacturing strategy.

4. Assess the impact of a proposed manufacturing strategy on business performance.