Operations Management Midterm Reviewer PDF

Summary

This document provides an overview of Operations Management, covering its importance, definitions, strategies, and productivity. It details market-based and resource-based approaches, different manufacturing strategies, and considerations regarding Design for Manufacturing (DFM).

Full Transcript

GROUP1
THE IMPORTANCE OF OPERATIONS MANAGEMENT
- OM is at the heart of business and cultural shifts, responding to changes in customer
preferences, supply networks, and work environments.
- OM managers are responsible for finding solutions to technological, environmental, social, and
globalization challenges.

DEFINING OPERATIONS MANAGEMENT
- Operations Management refers to the administration of business practices to create the highest
level of efficiency possible.
- It focuses on converting materials and labor into goods and services efficiently to maximize
profits.
- OM involves planning and production of goods or services, requiring a well-defined operations
strategy.

OPERATIONS STRATEGY

- Operations strategy is the long-term plan that shapes the capabilities of operations and their
contribution to overall business strategy.
- It reconciles market requirements with operational resources.
- It sets performance objectives for operations based on market requirements.

- It makes decisions on the deployment of resources to achieve those objectives.

MARKET-BASED VS. RESOURCE-BASED OPERATIONS STRATEGY
- Market-Based Approach - Focuses on understanding and targeting specific markets and
customer needs.
- Resource-Based Approach- Focuses on internal strengths and capabilities to create a
competitive advantage.
- Both approaches are crucial for successful operations strategy.

PRODUCTIVITY
- Productivity measures the efficiency of converting inputs (labor, capital) into outputs (goods and
services).
- It can be measured at individual, workforce, sector, team, national, or global levels.

- Productivity is vital for profitability and business growth.
- The formula for productivity is: Output / Input.

INCREASING PRODUCTIVITY
- Productivity can be increased through:
- Technological improvements
 - Technical efficiency
- Organizational improvements
- Increasing scale. COMPETITIVE PRIORITIES
- Competitive priorities are the key dimensions or attributes that a company focuses on to
compete in the market.

- They determine how a company positions itself relative to its competitors.
- The presentation identifies five key competitive priorities:
- Cost - Offering products or services at a lower price.
- Quality - Meeting or exceeding customer expectations.

- Flexibility - Adapting to changes in customer demands or market conditions.
- Delivery - Providing products or services quickly and on time.
- Innovation - Introducing new products, services, or processes to differentiate from
competitors.

MANUFACTURING STRATEGIES
- Manufacturing strategies are the approaches and practices a company adopts to produce goods
efficiently and effectively.
- The presentation outlines several key manufacturing strategies:

- Lean Manufacturing - Minimizing waste and maximizing efficiency.
- Agile Manufacturing - Emphasizing flexibility and rapid response to changes.
- Mass Customization - Combining mass production with customization.
- Total Quality Management (TQM - Embedding quality in every aspect of production.

- Six Sigma - Reducing variation and defects to improve quality and efficiency.
- Just-In-Time (JIT - Reducing inventory levels by producing only what is needed.
- Sustainable Manufacturing - Minimizing environmental impact and conserving resources.
- Flexible Manufacturing System (FMS - Using automated machines to produce different
products.
- Continuous Improvement (Kaizen - Working together to improve processes, products, and
services.
- Make-to-Order (MTO - Manufacturing only after customer orders are received.

CONCLUSION
- The presentation concludes with a call to action, emphasizing the importance of understanding
and implementing effective operations management strategies.
- It highlights the need to adapt to changing market conditions, prioritize competitive advantages,
and embrace continuous improvement.
GROUP2
DESIGN FOR MANUFACTURING (DFM)
- DFM bridges the gap between product design and manufacturing, focusing on making products
easier and more efficient to manufacture.
- It aims to reduce production costs, optimize material use, and improve profitability.

IMPORTANCE OF DFM

- COST REDUCTION- Simplifying designs, using standardized parts, and optimizing processes.
- QUALITY IMPROVEMENT- Minimizing defects, leading to higher quality and customer
satisfaction.
- TIME EFFICIENCY - Streamlining production, resulting in shorter lead times.

- MARKET COMPETITIVENESS- Producing cost-effective and high-quality products.

PRINCIPLES OF DFM
- SIMPLICITY- Straightforward designs with fewer parts and less complexity.
- STANDARDIZATION- Using standardized parts and processes for compatibility and efficiency.

- MODIFIABILITY- Designing for easy modifications to adapt to market changes.
- EASE OF ASSEMBLY- Products that are easy to assemble with minimal tools and labor.
- MATERIAL SELECTION- Choosing the right materials for both product performance and
manufacturing.

INTEGRATING DFM WITH PRODUCT DEVELOPMENT
- PHASE INTEGRATION- Incorporating DFM principles at every stage of development.
- COLLABORATION- Close collaboration between design and manufacturing teams.

- FEEDBACK LOOPS- Regular feedback to identify challenges early and make adjustments.
- PROTOTYPING- Building prototypes to test designs and identify potential problems.

CROSS-FUNCTIONAL COLLABORATION
- TEAM DYNAMICS- Strong team dynamics that foster mutual respect and understanding.
- COMMUNICATION STRATEGIES- Clear and structured communication to ensure alignment.
- ROLES OF ENGINEERING AND MANUFACTURING- Clearly defined roles for accountability and a
seamless workflow.
- CONFLICT RESOLUTION- Structured approaches to resolving conflicts to ensure collaboration.

TOOLS AND TECHNIQUES
- DESIGN GUIDELINES- Best practices to help designers make informed decisions.
- DFM CHECKLISTS- Checklists to ensure all DFM considerations have been addressed.

- PROTOTYPING- Building prototypes to identify potential design flaws.
- SIMULATION SOFTWARE- Software to simulate manufacturing processes and enable early
design adjustments.

COST IMPLICATIONS
COST ANALYSIS- Comparing initial investments with expected savings.
- BUDGETING- Incorporating DFM into budgeting processes to allocate resources effectively.
- COST REDUCTION STRATEGIES- Implementing cost reduction measures early in the design
process.
- LONG-TERM VALUE- Sustainable cost savings and improved product quality, generating long-
term value.

QUALITY MANAGEMENT
- QUALITY ASSURANCE- Ensuring products meet specific standards, enhancing customer
satisfaction.
- DEFECT REDUCTION- Proactively addressing potential defects during the design phase.
- COMPLIANCE SYSTEMS- Adhering to industry standards and regulations, minimizing risks.

- CONTINUOUS IMPROVEMENT- Ongoing evaluation and enhancement of processes and
products.

SUSTAINABILITY IN DFM

- ECO-DESIGN PRINCIPLES- Creating functional, cost-effective, and environmentally friendly
products.
- MATERIAL EFFICIENCY- Optimizing material use to minimize waste and lower production costs.
- WASTE REDUCTION STRATEGIES- Implementing waste reduction initiatives throughout the DFM
process.
- LIFECYCLE ASSESSMENT- Evaluating the environmental impact of products throughout their
lifecycle.

CHALLENGES IN DFM
- RESISTANCE TO CHANGE- Hesitation to adopt new practices.
- MISALIGNMENT BETWEEN TEAMS- Balancing innovative designs with manufacturing
capabilities.
- DESIGN CONSTRAINTS- Design limitations that restrict DFM implementation.

- BUDGET CONSTRAINTS- Limited budgets that hinder DFM strategies.

REAL-WORLD EXAMPLES
- CONSUMER ELECTRONICS- Reducing product weight and size for portability.
- AUTOMOTIVE INDUSTRY- Streamlining assembly lines by designing parts that are easier to
produce and assemble.
THE FUTURE OF DFM
- INDUSTRY 4.0- Smart manufacturing technologies and the Internet of Things (IoT) enable real-
time adjustments and data-driven decision-making.

- AUTOMATION- Automation streamlines operations and minimizes human error, increasing
efficiency.
- ARTIFICIAL INTELLIGENCE- AI assists in optimizing designs and processes, facilitating innovative
solutions.

- GLOBAL SUPPLY CHAIN INFLUENCE- Robust DFM approaches are needed to account for varied
production capabilities and design requirements across regions.

CALCULATING PRODUCT RELIABILITIES

- INTRODUCTION- Assessing product reliability to maintain consistent quality and performance.
- WHY RELIABILITY MATTERS- Identifying weaknesses, predicting product lifespan, reducing
maintenance costs, and enhancing customer satisfaction.
- WHAT IS RELIABILITY- The ability of a product to function consistently without failure.
- MEAN TIME BETWEEN FAILURES (MTBF- A metric used to assess product reliability.

- FAILURE RATE- The frequency of failures for a product over a specific period.
- RELIABILITY FUNCTION- A mathematical model for predicting the likelihood of successful
operation.
- WEIBULL DISTRIBUTION- A model used to analyze product and system failure times.

- CONCLUSION- The importance of assessing product reliability and using metrics to evaluate
product durability and predict failures.