Lean dynamics

Last updated

Lean dynamics is a business management practice that emphasizes the same primary outcome as lean manufacturing or lean production of eliminating wasteful expenditure of resources. However, it is distinguished by its different focus of creating a structure for accommodating the dynamic business conditions that cause these wastes to accumulate in the first place.

Contents

Like lean manufacturing, lean dynamics is a variation on the theme of creating efficiencies and greater value by optimizing flow rather than by maximizing economies of scale. [1] [2] As such, it represents an important chapter in the broader discussion of Taylorism, [3] Fordisim, [4] Alfred Sloan's standard volume methodology, [5] Peter Drucker's philosophy on the "theory of the business" [6] and Genichi Taguchi's analysis of loss. Its general philosophy has grown in popularity over recent years, in large part because of the increasingly challenging circumstances faced by the global business world (particularly evident during the 2008–2009 worldwide economic downturn.) [7]

This need to create greater efficiencies while competing in an environment that demands constant change and innovation seems to be responsible for the emergence of lean dynamics as a recognized business improvement approach. [8]

Overview

The term "lean" was first coined by a researcher at MIT and later popularized by the best-selling book, The Machine that Changed the World (1990). [9] Those implementing lean principles generally focus on applying lean tools which have been described in a number of references over the past two decades [10] [11] [12] with the focus of seeking out and directly targeting "waste" (its seven forms described by Taiichi Ohno in his book Toyota Production System [13] are well known.) This emphasis can result in greater efficiencies that do not necessarily respond well when business conditions shift.

Lean dynamics takes a different approach. Introduced by the book, Going Lean, [14] it does not directly target the desired outcome of waste elimination; instead, it focuses on identifying and addressing sources of "lag", or imbedded disconnects in flowing value through operations, decision-making, information, and innovation that lead to workarounds and amplify disruption when business conditions change. It promotes a different way of structuring the business that creates an inherent "dynamic stability" or greater responsiveness for accommodating shifting business conditions. Companies that are structured in this way show dramatically greater customer value[ citation needed ] as measured by their quality, innovation, and customer satisfaction; they also sustain greater corporate value as measured by profitability, market capitalization, and growth.

Lean dynamics uses the value curve as a data-driven way of directly comparing companies to distinguish lean firms from other industries.

Implementation of lean dynamics focuses on driving down the impact that variation [15] has on loss (based on the loss function from the Taguchi methods often described by the famous business statistician W. Edwards Deming [16] ), a concept describing the dramatic reduction of value-creating capabilities that traditional management systems display when subjected to sudden shifts in product demand, energy prices, or other conditions that affect operational stability or predictability.

Lean dynamics is particularly versatile in that it can be applied to a wide range of manufacturing and service industries. Its methods have been studied for Aerospace and Defense (particularly as applied to procuring hard to get spare parts [17] ), and medical, and distinguishes the few that stand out during crisis such as airlines, and retail.

Background

Lean dynamics has its roots in a global study of lean manufacturing in the aerospace industry aimed at understanding how to break its cycle of cost escalation that was making new products unaffordable. These results were described in the Shingo Prize winning book, Breaking the Cost Barrier. [18] This study showed that directly targeting “waste” reduction as the focal point for lean programs does not lead to significant cost savings. Instead, it provided strong evidence that emphasis should be placed on applying lean principles to mitigate the amplification of variation that causes workarounds. Addressing this variation was critical to overcoming the disruption that often causes waste to accumulate in the first place. Other sources cited this, identifying occurrences across other industries. [19]

Subsequent research of the aerospace industry showed that firms had accepted these findings, describing this approach of Variation Management as "...one of the most prominent approaches to transforming and improving military enterprise performance." [20]

This phenomenon was validated by correlating the disruption caused by variation in flow (measured as cycle time variation) with "loss" as described by the Taguchi Loss Function (see Taguchi Methods). Sudden changes in business conditions, such as spikes or decreases in production demand, cause increases in variation from forecasted conditions, causing disruption, and causing waste to accumulate. A lean dynamics approach restructures the way operations, organizations, information, and innovation are structured to overcome this. [21]

One method for companies to deal internally with externally driven variation (such as sudden spikes in demand), a core tenet of lean dynamics, was explored by the Defense Department under the Supplier Utilization through Responsive Grouped Enterprises (SURGE) Program. The SURGE program was partially sponsored by the Joint Strike Fighter Program (JSF)(F-35 Lightning II) This program aimed to reduce factory disruption due to demand variation by grouping parts together that shared similar manufacturing processes. It succeeded in reducing lead time on a number of critical aerospace items by as much as 60%. The SURGE program gained notoriety when it was mentioned on the popular TV Show JAG. [22]

See also

Terminology

Related Research Articles

Lean manufacturing Lean methodology used to improve production time by reducing wastes

Lean manufacturing is a production method aimed primarily at reducing times within the production system as well as response times from suppliers and to customers. It is closely related to another concept called Just-in-time manufacturing. Just-in-time manufacturing tries to match production to demand by only supplying goods which have been ordered and focuses on efficiency, productivity and reduction of "wastes" for the producer and supplier of goods. Lean manufacturing adopts the just-in-time approach and additionally focuses on reducing cycle, flow and throughput times by further eliminating activities which do not add any value for the customer. Lean manufacturing also involves people who work outside of the manufacturing process, such as in marketing and customer service.

Six Sigma () is a set of techniques and tools for process improvement. It was introduced by American engineer Bill Smith while working at Motorola in 1986.

Kanban Japanese business method

Kanban is a scheduling system for lean manufacturing. Taiichi Ohno, an industrial engineer at Toyota, developed kanban to improve manufacturing efficiency. The system takes its name from the cards that track production within a factory. Kanban is also known as the Toyota nameplate system in the automotive industry.

Kaizen is a concept referring to business activities that continuously improve all functions and involve all employees from the CEO to the assembly line workers. Kaizen also applies to processes, such as purchasing and logistics, that cross organizational boundaries into the supply chain. It has been applied in healthcare, psychotherapy, life coaching, government, and banking.

The Toyota Production System (TPS) is an integrated socio-technical system, developed by Toyota, that comprises its management philosophy and practices. The TPS is a management system that organizes manufacturing and logistics for the automobile manufacturer, including interaction with suppliers and customers. The system is a major precursor of the more generic "lean manufacturing". Taiichi Ohno and Eiji Toyoda, Japanese industrial engineers, developed the system between 1948 and 1975.

Taguchi methods are statistical methods, sometimes called robust design methods, developed by Genichi Taguchi to improve the quality of manufactured goods, and more recently also applied to engineering, biotechnology, marketing and advertising. Professional statisticians have welcomed the goals and improvements brought about by Taguchi methods, particularly by Taguchi's development of designs for studying variation, but have criticized the inefficiency of some of Taguchi's proposals.

Lean software development is a translation of lean manufacturing principles and practices to the software development domain. Adapted from the Toyota Production System, it is emerging with the support of a pro-lean subculture within the agile community. Lean offers a solid conceptual framework, values and principles, as well as good practices, derived from experience, that support agile organizations.

Shigeo Shingo Japanese engineer

Shigeo Shingo was a Japanese industrial engineer who was considered as the world’s leading expert on manufacturing practices and the Toyota Production System.

Muda is a Japanese word meaning "futility; uselessness; wastefulness", and is a key concept in lean process thinking, like the Toyota Production System (TPS) as one of the three types of deviation from optimal allocation of resources. Waste in this context refers to the wasting of time or resources rather than wasteful by-products and should not be confused with Waste reduction.

Genba is a Japanese term meaning "the actual place". Japanese detectives call the crime scene genba, and Japanese TV reporters may refer to themselves as reporting from genba. In business, genba refers to the place where value is created; in manufacturing the genba is the factory floor. It can be any "site" such as a construction site, sales floor or where the service provider interacts directly with the customer.

Taiichi Ohno Japanese businessman and engineer (1912–1990)

Ohno Taiichi was a Japanese industrial engineer and businessman. He is considered to be the father of the Toyota Production System, which inspired Lean Manufacturing in the U.S. He devised the seven wastes as part of this system. He wrote several books about the system, including Toyota Production System: Beyond Large-Scale Production.

Five whys is an iterative interrogative technique used to explore the cause-and-effect relationships underlying a particular problem. The primary goal of the technique is to determine the root cause of a defect or problem by repeating the question "Why?" five times. The answer to the fifth why should reveal the root cause of the problem.

Norman Bodek

Norman Bodek was a teacher, consultant, author and publisher who published over 100 Japanese management books in English, including the works of Taiichi Ohno and Dr. Shigeo Shingo, and taught a course on "The Best of Japanese Management Practices" at Portland State University. Bodek created the Shingo Prize with Dr. Vern Beuhler at Utah State University. He also was elected to Industry Week's Manufacturing Hall of Fame and founded Productivity Press, and was President of PCS Press. He died on 9 December 2020 at the age of 88.

In the fall of 2005, James P. Womack and Daniel T. Jones published an article in the Harvard Business Review describing a new theory called Lean Consumption.

Computer-aided lean management, in business management, is a methodology of developing and using software-controlled, lean systems integration. Its goal is to drive innovation towards cost and cycle-time savings. It attempts to create an efficient use of capital and resources through the development and use of one integrated system model to run a business's planning, engineering, design, maintenance, and operations.

Cycle time variation is a metric and philosophy for continuous improvement with the aim of driving down the deviations in the time it takes to produce successive units on a production line. It supports organizations' application of lean manufacturing or lean production by eliminating wasteful expenditure of resources. It is distinguished from some of the more common applications by its different focus of creating a structure for progressively reducing the sources of internal variation that leads to workarounds and disruption causing these wastes to accumulate in the first place. Although it is often used as an indicator of lean progress, its use promotes a structured approach to reducing disruption that impacts efficiency, quality, and value.

Lean IT is the extension of lean manufacturing and lean services principles to the development and management of information technology (IT) products and services. Its central concern, applied in the context of IT, is the elimination of waste, where waste is work that adds no value to a product or service.

Lean enterprise is a practice focused on value creation for the end customer with minimal waste and processes. The term has historically been associated with lean manufacturing and Six Sigma due to lean principles being popularized by Toyota in the automobile manufacturing industry and subsequently the electronics and internet software industries. The three key core competencies of a lean enterprise are scaled agile framework, efficient processes, and customer focus.

Lean product development (LPD) is a lean approach to counter the challenges of product development, notably:

Design for lean manufacturing is a process for applying lean concepts to the design phase of a system, such as a complex product or process. The term describes methods of design in lean manufacturing companies as part of the study of Japanese industry by the Massachusetts Institute of Technology. At the time of the study, the Japanese automakers were outperforming the American counterparts in speed, resources used in design, and design quality. Conventional mass-production design focuses primarily on product functions and manufacturing costs; however, design for lean manufacturing systematically widens the design equation to include all factors that will determine a product's success across its entire value stream and life-cycle. One goal is to reduce waste and maximize value, and other goals include improving the quality of the design and the reducing the time to achieve the final solution. The method has been used in architecture, healthcare, product development, processes design, information technology systems, and even to create lean business models. It relies on the definition and optimization of values coupled with the prevention of wastes before they enter the system. Design for lean manufacturing is system design.

References

  1. Womack, James P. and Jones, Daniel (1997), Lean Thinking: Banish Waste and Create Wealth in Your Company, Simon & Schuster, ISBN   0-7432-4927-5
  2. Liker, Jeffrey (2003), The Toyota Way, McGraw Hill, ISBN   0-07-139231-9
  3. Taylor, Frederick Winslow (1911), The Principles of Scientific Management, Norton, ISBN   0-393-00398-1
  4. Ford, Henry (1927), Today and Tomorrow, Productivity Press, ISBN   0-915299-36-4
  5. Sloan, Alfred P.(1965), My Years With General Motors, Macfadden
  6. Drucker, Peter (1995), Managing for a Time of Great Change, Truman Talley Books/Dutton, ISBN   0-525-94053-7
  7. [Going Lean as a Solution to Navigating Uncertainty and Crisis, Ivey Business Journal, March, 2009] "Ivey Business Journal - FEATURE ARTICLE". Archived from the original on 2009-12-21. Retrieved 2009-04-19.
  8. Going Lean Teaches You How to Live with Change, Six Sigma
  9. Womack, James P.,Jones, Daniel T., and Roos, Daniel (1991), The Machine That Changed The World: The Story of Lean Production, Harper Perennial, ISBN   978-0-06-097417-6
  10. Suzaki, Kiyoshi (1987), The New Manufacturing Challenge: Techniques for Continuous Improvement, Free Press, ISBN   0-02-932040-2
  11. Shingo, Shigeo, A Study of the Toyota Production System: From an Industrial Engineering Viewpoint (1989), Productivity Press, ISBN   0-915299-17-8
  12. Schonberger, Richard (1982), Japanese Manufacturing Techniques, Free Press, ISBN   0-02-929100-3
  13. Taiichi Ohno (1988), Toyota Production System, Productivity Press, ISBN   0-915299-14-3
  14. Ruffa, Stephen A. (2008), Going Lean: How the Best Companies Apply Lean Manufacturing Principles to Shatter Uncertainty, Drive Innovation, and Maximize Profits, AMACOM, ISBN   0-8144-1057-X
  15. Deming, W. Edwards, (1982), Out of the Crisis, MIT, ISBN   0-911379-01-0
  16. Deming, W. Edwards, (1993), The New Economics: For Industry, Government, Education, MIT, ISBN   0-911379-05-3
  17. Part Grouping: Angioplasty for the Supply Chain , (Spring 2003), Air Force Journal of Logistics
  18. Ruffa, Stephen A., and Perozziello, Michael (2000), Breaking the Cost Barrier: A Proven Approach to Managing and Implementing Lean Manufacturing, Wiley, ISBN   0-471-38136-5
  19. Schonberger, Richard J. (2001), Let's Fix It!, Free Press, ISBN   0-7432-1551-6
  20. Mathaisel, Dennis F. X., (2007), Sustaining the Military Enterprise: An Architecture for a Lean Transformation, Auerbach
  21. Ruffa, Stephen A. (2008), Going Lean: How the Best Companies Apply Lean Manufacturing Principles to Shatter Uncertainty, Drive Innovation, and Maximize Profits, AMACOM ISBN   0-8144-1057-X
  22. JAG Episode 9 (Season 6), "Family Secrets"(6:33), first aired December 12, 2000 [ permanent dead link ]
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.