Sunday, September 13, 2015

Industrial Engineering and Productivity Improvement - Coal Mining Sector - by - Prof K.V.S.S. Narayana Rao




How to improve supply chain productivity for Miners: Part Two
http://www.logiworx.com.au/latest-news/the-worx-article/t/how-to-improve-supply-chain-productivity-for-miners:-part-two-/i/17/?p=1

Mining in the 21st Century - Quo Vadis
19th World Mining Congress 2003

First Keynote Address on Sustainable Development and Coal Mining. Important.
https://books.google.co.in/books?id=BKu9u51lVE0C&printsec=frontcover#v=onepage&q&f=false



UNIONISM AND PRODUCTIVITY IN WEST VIRGINIA COAL MINING: A LONGER VIEW
William M. Boal* July 2014
Coal was a vital industry, employing 860,000 workers in the U.S. at its peak in 1923, and the United Mine Workers of America was a huge union, counting 422,000 dues-paying members in the U.S. at its peak in 1921.

The paper examines the effect of unionism on productivity in coal mines of west virginia. It did not give any numerical estimates of productivity per employee in any year of the study.
aeaweb.org  2015 annual meeting paper. It can be downloaded from aeaweb.org
https%3A%2F%2Fwww.aeaweb.org%2Faea%2F2015conference%2Fprogram%2Fretrieve.php%3Fpdf

2010
Desk Reference: Rock Mechanics, Drilling & Blasting
Agne Rustan, Claude Cunningham, William Fourney, Alex Spathis, K.R.Y. Simha
CRC Press, Nov 10, 2010 - 466 pages
https://books.google.co.in/books?id=LMTLBQAAQBAJ



1996
K.S. Prakasha Rao, Modelling and simulation of coal extraction and transportation system, Industrial Engineering Journal, July 1996, Vol 25, No 7, pp 13-20 (along with P. Subramaniam)


Great Britain - 1987

Saleable coal per man shift (OMS - output per shift) in coal mines during September 1983 was 2.44 tonnes. Two years later, it increased to 2.71 tonnes. During 1986/7, it averaged 3.29 tonnes. In March 1987, it increased to record level of 3.76 tonnes. It is a striking rise in productivity in three and half years as compared to long term trend.



Efficiency and Capacity of Boilers
Chapter of Steam: Its Generation and  Use
http://www.gutenberg.org/files/22657/22657-h/chapters/efficiency.html

Productivity Change in the Coal Industry and the New Industrial Relations
Ray Richardson and Stephen Wood
British Journal of Industrial Relations
Volume 27, Issue 1, pages 33–55, March 1989
http://onlinelibrary.wiley.com/doi/10.1111/j.1467-8543.1989.tb00207.x/abstract



1983
Mine Management  - The Book has focus on productivity
by Douglas Sloan
https://books.google.co.in/books?id=8l__CAAAQBAJ&printsec=frontcover#v=onepage&q&f=false



Coal Mining Process and Methods



Websites

http://emfi.csmspace.com/  -


2013
Modern American Coal Mining: Methods and Applications
Bise, Christopher J.
SME, Oct 18, 2013 - 576 pages
Modern American Coal Mining: Methods and Applications covers a full range of coal mining and coal industry topics, with chapters written by leading coal mining industry professionals and academicians. Highlights from the book include coal resources and distribution, mine design, advances in strata control and power systems, improvements in surface mining, ventilation to reduce fires and explosions, drilling and blasting, staffing requirement ratios, management and preplanning, and coal preparation and reclamation.

The text is enhanced with 11 case studies that are representative of underground and surface mines in the United States. Narrative descriptions and appropriate mine plans are presented, with attention given to unique features and situations that are addressed through mine design and construction. A useful glossary is included, as are many examples, figures, equations and tables, to make the text even more useful.
https://books.google.co.in/books?id=bZKvAQAAQBAJ



2012
Design of Underground Hard-Coal Mines
J. Pazdziora
Elsevier, Dec 2, 2012 - 246 pages

The escalating worldwide demand for energy has had the effect, among other things, of promoting the development of coal mining. In some countries specialist design offices were set up and students trained as specialists in mine design and construction. Poland, a country having mining traditions stretching over many centuries, is a good example, and has gained a place in the forefront, not only as a coal producer and exporter, but also as an originator and exporter of technical mining know-how. The author of this book has himself had 25 years of practical experience in mine design, in the supervision of mining investment implementation both at home and abroad, and also in directing the activities of the Chief Mine Design and Studies Office in Poland, plus more than 20 years' teaching experience in the training of mining engineers, in particular as head of the Mine Design Department of the Mining Faculty at the Silesian Polytechnic University in Gliwice. This vast wealth of experience has prompted him to write the present book which discusses the basic problems met with in the design of underground hard-coal mines.

The author's primary aim has been to deal with all those questions in mine design which have not yet been answered in mining textbooks and which, from his own personal experience, he considers to be of importance. Accordingly, he presents the general principles governing the design of new mines and the reconstruction of working mines, the development of mining regions, the design of coal-preparation plant, and energy economy in mines. Making use of the broad experience gained by the Polish mining industry in the implementation of mining investment projects, he has quoted several examples of technical and organizational solutions which effectively shorten the mine construction cycle.

The book is addressed chiefly to investors and engineers engaged in preparing plans for the development of mining regions, for the construction of new mines, and the reconstruction of existing mines and preparation plants, as well as to students in mining departments of technical schools and universities. The information offered here is of great practical value and may well stimulate the development of new ideas for design and implementation concepts.
https://books.google.co.in/books?id=sRk7AAAAQBAJ


Measuring Coal Supply in a Power Plant - Issues
https://blogs.siemens.com/measuringsuccess/stories/130/


2010
International Coal Preparation Congress 2010 Conference Proceedings
Rick Q. Honaker
SME, 2010 - 978 pages

This 992-page book is a compilation of 118 state-of-the-art technical papers presented at the industry's most prestigious gathering. A CD containing the full text is included. Read what coal preparation experts from 20 countries have to share on a variety of current issues, including: • Water-based coal processing facilities and a review of plant designs and operations used throughout the world.• Breakthroughs in dense medium separations, water-based separation processes, froth flotation, and de-watering.• New wear-resistant materials proven to help plant operators reduce maintenance costs, elevate plant availability, and maintain a high level of process efficiency.• Groundbreaking methodologies that maximize the amount of coal recovered while meeting the required product specifications.• The processing and potential uses of waste.• Innovative online monitoring and control methods and the latest on the application of modeling and simulation.• Advancements in technologies that can upgrade coal without the use of water, including density-based, thermal, and optical dry cleaning.• And much, much more.
https://books.google.co.in/books?id=O9jyn-45eoAC

2007

Coal: Research and Development to Support National Energy Policy
Chapter 4 Coal Mining and Processing
National Academies Press Book
http://www.nap.edu/openbook.php?record_id=11977&page=58





1992
Manual of pillar extraction
http://www.resourcesandenergy.nsw.gov.au/__data/assets/pdf_file/0004/419512/MDG-1005-part-1-of-2.pdf





India - Coal Mining Technologies

Coal Mining technologies - Tribal Energy and Environment Information
http://teeic.indianaffairs.gov/er/coal/restech/tech/index.htm




Industrial Engineering Methods in Coal Mining



Product Design Efficiency



Application of Value Engineering in Optimizating Mine Production System Capacity
Dai, Shao-jun; Hao, Chuan-bo
2nd International Conference on Value Engineering and Value Management, 2009/10/16-2009/10/17, pp93-99, 2009.
In the process of checking production capacity, coal mine has surplus production capacity in some parts of production systems or processes, and it causing unnecessary resource wastes; therefore it is essential to optimize production capacity of coal mine production system which having much more resources wastes. In order to solve the problem, the paper propose that it used value engineering method to estimate the cost, function and value of optimize scheme of coal mine production system capacity, established model of choosing experts and optimizing model of coal mine production system capacity, then took and analyzed an example. The result shows that value engineering method is suitable for optimizing coal mine system capacity and it can guide coal mine practical...












Methods Efficiency


International Journal of Scientific and Research Publications, Volume 4, Issue 10, October 2014 1
ISSN 2250-3153
www.ijsrp.org
Optimum Utilisation of Continuous Miner for Improving Production in Underground Coal Mines
Vijaya Raghavan*, Dr Syed Ariff**, Paul Prasanna Kumar***
*Department of Mining Engineering, Dr.Thimmaiah Institute of Technology, Oorgaum, Kolar Gold Fields-563120
**Assistant Professor, Professor, Senior Lecturer.
***Department of Mining Engineering, Dr.T.Thimmaiah Institute of Technology, Oorgaum, Kolar Gold Fields-563120
http://www.ijsrp.org/research-paper-1014/ijsrp-p3464.pdf

raghavan_pp  at rediffmail.com  -  Vijaya Raghavan


Analysing the Benefits of Value Stream
Mapping in Mining Industry
N. Pavan Kumar
Team Lead, Cyient Ltd., Plot No.11, Software Units Layout, Infocity, Madhapur, Hyderabad, Telangana, India.
http://www.ijirset.com/upload/2014/october/35_Cost.pdf



PRODUCTIVITY IMPROVEMENT IN UNDERGROUND COAL MINES – A CASE STUDY
Devi Prasad Mishra1*
, Mamtesh Sugla2
, Prasun Singha3
1 Department of Mining Engineering, Indian School of Mines (Dhanbad, Jharkhand, India)
2 JPMorgan India Pvt Ltd, Mafatlal Centre, Nariman Point (Mumbai, Maharashtra, India)
3 Marandoo Mine, Rio Tinto Iron Ore (Pilbara Region, Western Australia, Australia)
* Corresponding author: devi_agl @ yahoo.com, tel.: +91 9430191673, fax: +91 326 2296628/2296563

Journal of Sustainable Mining
J. Sust. Min. Vol. 12 (2013), No. 3, pp. 48–53
http://kwartalnik.gig.eu/sites/default/files/articles/en/jsm_130306_full_text.pdf

Industrial Engineering Optimization


2010
Optimizing through value driver modelling - PWC
http://www.pwc.com.au/industry/energy-utilities-mining/assets/ValueDriverModelling-Nov10.pdf

2007
OPTIMIZATION OF BLASTING PARAMETERS
IN OPENCAST MINES
A THESIS SUBMITTED IN PARTIAL FULFILLMENT OF THE
REQUIREMENTS FOR THE DEGREE OF
BACHELOR OF TECHNOLOGY IN MINING ENGINEERING
 BY
MANMIT ROUT & CHINMAY KUMAR PARIDA
DEPARTMENT OF MINING ENGINEERING, NATIONAL INSTITUTE OF TECHNOLOGY
ROURKELA-769008
2007
http://ethesis.nitrkl.ac.in/4287/1/Optimization_of_Blasting_Parameters_in_Opencast_Mines_06.pdf


1987
LI, Z. and TOPUZ. E. Optimizing design capacity and field dimensions of underground coal mines. APCOM 87. Proceedings of the Twentieth International Symposium on the Application of Computer and Mathematics in the Mineral Industries. Volume I: Mining. Johannesburg. SAl MM. 1987. pp. 115 - 122.
http://www.saimm.co.za/Conferences/Apcom87Mining/115-Li.pdf

Industrial Engineering Statistics


2008
Risk Management in Mines - The Six Sigma Way
S. K. Sinha
Indian Institute of Coal Management, India
http://ro.uow.edu.au/cgi/viewcontent.cgi?article=1025&context=coal

Industrial Engineering Economics


American Journal of Industrial and Business Management, 2014, 4, 31-39
Published Online January 2014 (http://www.scirp.org/journal/ajibm)
Introduction of Innovative Equipment in Mining: Impact
on Productivity
Bryan Boudreau-Trudel1, , Kazimierz Zaras2, , Sylvie Nadeau1, , Isabelle Deschamps3
http://www.scirp.org/journal/PaperInformation.aspx?PaperID=42314


Soviet Mining
November–December, 1989, Volume 25, Issue 6, pp 577-582
Effect of the efficiency of capital expenditures on the optimal design output of a mine
A. A. Ordin
http://link.springer.com/article/10.1007%2FBF02528313

Human Effort Engineering


Mining Publication: Ergonomics and Mining: Charting a Path to a Safer Workplace
Original creation date: September 2006

Image of publication Ergonomics and Mining: Charting a Path to a Safer Workplace
Ergonomics processes described in the literature have been associated mostly with manufacturing, financial, electronics, and office settings where working conditions tend to be rather constant and repetitive. The information presented in this document demonstrates, however, that an ergonomics process can also be implemented in a setting such as mining where working conditions frequently change and workers are periodically exposed to extreme weather conditions. This document describes how Bridger Coal Company implemented an ergonomics process at its Jim Bridger Mine from 2001 through 2004. The process developed by the Ergonomics Committee, the promotion of the process to management and employees, and the impacts of the process on working conditions at the mine are reviewed. Barriers overcome and lessons learned are also described. Quotes from Bridger Coal Company employees are included in the document to add a personal perspective. Other industries with working conditions similar to mining, such as construction and agriculture, may find this information useful.

Authors: J Torma-Krajewski, LJ Steiner, P Lewis, P Gust, K Johnson
http://www.cdc.gov/niosh/mining/works/coversheet1686.html

Work Measurement, Cost Measurement, and Productivity Measurement



Time Studies in Underground Coal Mining by Ludwig W. Koch
University of Utah - MS Thesis in Department of Mining and Geological Engineering
December 1958
http://content.lib.utah.edu/utils/getfile/collection/etd1/id/52/filename/236.pdf

Management of IE Studies, Projects



Productivity Measurement

Productivity in the Mining Industry: Measurement and Interpretation
Productivity Commission Staff Working Paper
December 2008
http://www.pc.gov.au/research/completed/mining-productivity/mining-productivity.pdf

India - Cola Mining Companies


The Singareni Collieries Company Ltd. is a Government owned public sector company with around 69000 employees.It is the second largest coal producing company in India.It is situated in the state of Andhra Pradesh,India.   Presently, company operates 36 underground coal mines and 14 opencast mines.

The Superintending Engineer, Industrial Engineering
Dept,.O/o. The Singareni Collieries Ltd., GM's Office,
Mandamarri, Dist., Adilabad Dist.-504 231., AP


Related Article

Mining - Productivity, Industrial Engineering and Lean Production
http://nraoiekc.blogspot.com/2014/02/mining-productivity-industrial.html


Updated  20 June,  12 June,  21 April 2015
First published on 28 March 2015

Improving R & D Productivity


Nature Reviews Drug Discovery 9, 203-214 (March 2010) | doi:10.1038/nrd3078

How to improve R&D productivity: the pharmaceutical industry's grand challenge
See also: Correspondence by Denee et al.

Steven M. Paul1, Daniel S. Mytelka1, Christopher T. Dunwiddie1, Charles C. Persinger1, Bernard H. Munos1, Stacy R. Lindborg1 & Aaron L. Schacht1


http://www.nature.com/nrd/journal/v9/n3/full/nrd3078.html

Thursday, September 10, 2015

A Study of the Toyota Production System from an Industrial Engineering Viewpoint - Shigeo Shingo - Google Book



http://books.google.co.in/books/about/A_Study_of_the_Toyota_Production_System.html?id=RKWU7WElJ7oC

The first and only book in English on JIT, written from the industrial engineer's viewpoint. When Omark Industries bought 500 copies and studied it companywide, Omark became the American pioneer in JIT.

Here is Dr. Shingo's classic industrial engineering rationale for the priority of process-based over operational improvements in manufacturing. He explains the basic mechanisms of the Toyota production system, examines production as a functional network of processes and operations, and then discusses the mechanism necessary to make JIT possible in any manufacturing plant.

#Provides original source material on Just-in-Time
#Demonstrates new ways to think about profit, inventory, waste, and productivity
#Explains the principles of leveling, standard work procedures, multi-machine handling, supplier relations, and much more
#If you are a serious student of industrial engineering, you will benefit greatly from reading this primary resource on the powerful fundamentals of JIT.

Table of Contents


Chapters

Mechanism of the production function
Improvement of process
Improvement of operation
Development of non-stock production
Interpretation of the Toyota Production System
Mechanism of TPS
Development of a "kanban" system
Regarding TPS
Course of TPS
Introduction and development of TPS
Summary



My Summary of the book

Industrial Engineering in Toyota Production System - Lean Production
http://nraoiekc.blogspot.in/2013/12/toyota-production-system-industrial.html


Detailed Table of Contents



1. Introduction
           Production Mechanism
2. Improving  process
           Process Elements
                 Basic Process Analysis
           Process Improvement
           Improving Inspection
           Transport Improvement
           Eliminating Storage (Delays)
3. Improving operations
           Common Factors in Operations
           Improving Setup (Exchange of Dies and Tools)
           Improving Principal Operations
                 Separating worker from Machine
                 Development of Pre-automation or Autonomation
                 Improving Margin Allowances

4. Conclusions on Developing Non-stock production
            Naturally Occurring Stock
            "Necessary Stock"
Interpretation of the Toyota Production System

5. The Principles of the Toyota Production System
           What is the Toyota Production System?
           Basic Principles
                 Waste of Overproduction
                 Just-in-Time
                 Separation of Worker from Machine
                Low Utilization Rates
                 Perform an Appendectomy
           Fundamentals of Production Control
                 Adopting a Non-Cost Principles
                 Elimination of Waste
                 Mass Production and Large Lot Production
                 The Ford and Toyota Systems Compared

6. Mechanics of the  Toyota Production System: Improving Process - Schedule Control and Just-in-Time
             Schedule Control and Just-in-Time
                   Production Planning
                   Schedule Control and Stockless Production
                   Adopting SMED
                   Flexibility of Capacity
                   Elimination of Defects
                   Eliminating Machine Breakdowns

7.  Mechanics of the  ToyotaProduction System: Improving Process - Leveling and the Nagara System
             What is Leveling?
                    Balancing Load and Capacity
                    Segmented and Mixed Production
                    Segmented Production Systems and Small Lot Production Systems
                    The Toyota Complex Mixed Production System
                    Lveling and Non-Stock
              The Nagara System

8. Mechanics of the  ToyotaProduction System: Improving Operations
             Components of Operations
                    Preparation and After-Adjustment
                    Principal Operations
                    Marginal Allowances
             Standard Operations
                    Standard Operations and Toyota Production System
                    Three Temporal Aspects of Standard Operations
             From Worker to Machine
             Manpower Cost Reduction
                    Improving Methods of Operation

Development of a "kanban" system
Regarding TPS
Course of TPS
Introduction and development of TPS
Summary



Updated 10 Sep 2015
First Published  16 Sep 2014




Wednesday, September 9, 2015

Industrial Engineering - Foundation of Toyota Production System


Toyota Production System or Lean Philosophy

Elimination of Waste
Low Inventory
Low Order to Delivery Period using low cycle time.


Toyota Production System - Lean Tools or Techniques


SMED
Poka Yoke
Value stream mapping to find cycle time and processing time.
TIE - Total Industrial Engineering.
TQM – Zero defects
TPM – High OEE
TPMgmt – Annual Planned Cost Reduction

Shigeo Shingo

A Study of Toyota Production System from an Industrial Engineering Viewpoint by Shigeo Shingo

Book published by Productivity Press
Components of Lean System


Shigeo Shingo said
80% of the lean system (TPS) is waste elimination that is industrial engineering,
15% - production management and
5% - kanban (sign board) communications

What is Industrial Engineering?

Industrial Engineering is eliminating Muda, Muri and Mura.
IE is improving technology for cost reduction (Machines and Men) (Fundamental).
IE is improving management processes of planning, organizing and controlling (associated activity)
IE is improving business processes (Augmented)



In Preface to the Japanese Edition

Shigeo Shingo had written that management consultants were not allowed to disclose any confidential or proprietary information. Taiichi Ohno authored two books describing Toyota Production System (TPS).  That allowed Shigeo Shingo, to use the published material as the basis to explain industrial engineering principles behind TPS.

Shigeo had as his objectives in writing the book:

1. Explaining the principles of the Toyota Production System.
2. Explanation of the system of practicing these principles.
3. Description of the practical application of the methods following these principles.

Chapter 1 Introduction


Production is a network of processes and operations.
Process – transforming material into product is accomplished through a series of operations.
Process – flow of material in time and space.
Process analysis examines the flow of material or product.

In an operation a transformation occurs.
Process analysis questions whether that transformation is required.
Operation Analysis
Operation analysis examines the work performed on products by workers, machines and tools.
Process analysis, operation analysis, motion study and time study form part of methods efficiency engineering.
Process analysis and operation analysis are engineering activities specific to each branch of engineering.
http://nraoiekc.blogspot.in/2012/04/method-study-methods-efficiency.html


Chapter 2 Improving Process

Improve process before improving individual operations.
Process is flow of material through operations.

Process Chart - Gilbreth

Processing operation
Inspection operation
Transport operation
Storage operation – Temporary, Permanent (Delay operation)

Process Improvement
Process can be improved in two ways.
The first improves the product itself through design efficiency engineering (value engineering, design for manufacture, design for assembly, and design optimization techniques).
The second improves manufacturing method through methods efficiency engineering, motion studies and production optimization and variability reduction methods.

ECR Method of Process Improvement

Eliminate the operation – sometimes it is found to be not necessary or sometimes it is due to improvement of earlier operation.
Combine operations with earlier one or latter one.
Rearrange the sequence of operations


Processing Operations Analysis

Examples in the book
Manufacturing operations can be improved by alternatives related to proper melting or forging temperatures, cutting speeds or tool selection.
Examples related to vacuum molding, plating and plastic resin drying are given in the book.
Eliminating Flashing in Castings (Die)
Flashing in die castings occurs due to escape of air.
Removing the air in mould with a vacuum pump eliminated flashing.
Removing Foam in High-Speed Plating
Spraying or showering the surface to be painted resulted in a 75% reduction.
Drying Plastic Resin
Letting the resin dry a little at a time by allowing it to float to the surface resulted in a 75% reduction of electric power consumption.


Analysis of Inspection Operations

Shingo said normal inspection is judgment inspection.
It separates good and defective items.
Rework done on defective items if possible
Informative inspection asks for process improvement.
It is like medical examination that leads to treatment.
Statistical Process Control
SPC is sampling based informative inspection.
But Shingo says even it is not sufficient to assure zero defects.
To assure zero defects we need to inspect every item but at low cost per item.
Shingo’s Suggestions
Informative Inspections

Self Inspection
Successive Inspection
Enhanced Self Inspection – Inspection enhanced with devices  - poka-yoke

Example 2.4 – Vacuum Cleaner Packing
Cleaner along with attachments and leaflets to be packed.
When a leaflet is taken from the pile,  a limit switch is operated.
When attachments are taken from the container, a limit switch is operated.
Then only, the full package is allowed to be sealed.
Principle
The purpose of inspection is prevention of the defect.
Quality can be assured when it is built in at the process and when inspection provides immediate and accurate feedback at the source to prevent the defective item to go further.
Self Inspection
It provides the most immediate feedback to the operator.
He can improve the process and also rework on the item.
Disadvantage inherent.
There is potential for lack of objectivity.
He may accept items that ought to be rejected.
Successive Inspection
The operator inspects the item for any defect in the previous operation before processing it.
Shingo says, when this was introduced defects dropped to 0.016% in Moriguchi Electric Company in television production
Inspection enhanced by Poka Yoke
Human operation and inspection can still make errors unintentionally.
Poka Yoke will take care of such errors.
Ex: Left and right covers are to be made from similar components with a hole in different places.
The press was fitted with a poka yoke which does right cover pressing only when the hole is in proper place.
Source Inspection
This is answering the question: What is the source of the defect in the process/operation?
Two types proposed.
Vertical
Horizontal
Source Inspection – Vertical, Horizontal
Vertical source inspection traces problems back through the process flow to identify and control conditions external to the operation that affect quality.
Horizontal source inspection identifies and controls conditions within an operation that affect quality.
Poka-yoke Inspection Methods
Poka-yoke achieves 100% inspection through mechanical or physical control.
Poka-yoke can either be used as a control or a warning.
As a control it stops the process so the problem can be corrected.
As a warning, a buzzer or flashing lamp alerts the worker to a problem that is occurring.

Three types of control poka-yoke
Contact method - identify defects by whether or not contact is established between the device and some feature of the product's shape or dimension
Fixed value method - determines whether a given number of movements have been made


Motion step method - determines whether the established steps or motions of a procedure are followed

Choosing/Designing  Poka Yoke
First decide stage of inspection – Self or Successive
Second – Type of regulation
Control or warning.
Third decide Error Sensing type – Contact, fixed number or motion step


Analysis of Transport Operations

Transport within the plant is a cost that does not add value.
Hence real improvement of the process eliminates the transport function as much as possible.
This involves improving the layout of process.

Ex – 7. Transport Improvement
Tokai Iron Works – process layout -  presses, bending machines, embossing
Layout Change: Flow based layout.
A 60 cm wide belt conveyor with ten presses on either side.
WIP reduced. Production time shortened. Delays disappeared.
200% increase in productivity.
Principle
Only after opportunities for layout improvement have been exhausted should the unavoidable transport work that remains be improved through mechanization.

Eliminating - Storage Operations (Delay)


Process Delay – Permanent storage – Whole lot is waiting
Lot Delays – Temporary storage – One item is being processed. Other items in the lot waiting.
Another classification is storage on the factory floor and storage in a controlled store.
Eliminating - Storage Operations (Delay)
There are three types of accumulations between processes:

E storage - resulting from unbalanced flow between processes  (engineering)
C storage - buffer or cushion stock to avoid delay in subsequent processes due to machine breakdowns or rejects (control)
S storage - safety stock; overproduction beyond what is required for current control purposes

Eliminating E-Storage

E-storage is due to engineering/planning/design of the production-distribution  system
This can be eliminated through leveling quantities, which refers to balancing flow between high and low capacity processes and synchronization.

Leveling would mean running high-capacity machines at less than 100% capacity, in order to match flow with lower capacity machines that are already running at 100% on short interval basis.
At Toyota, the quantity to be produced is determined solely by order requirements (Takt time).

Principle
Presence of high capacity machines should not be used to justify large lot processing and resulting inventory.
Process capacity should serve customer requirements/production requirements and should not determine them
synchronization.
The lots especially one piece lot is processed without delay in a flow.
It is efficient production scheduling that ensures that once quantities are leveled (output is matched), inventories do not pile at any stage due to scheduling conflicts.
Synchronize the entire process flow.


Eliminating C storage - Cushion

Cushion stocks compensate for:
machine breakdowns,
defective products,
downtime for tool and die changes and
sudden changes in production scheduling.

Eliminate Cushion Storage
Prevent machine breakdowns:
Determining the cause of machine failure at the time it occurs, even if it means shutting down the line temporarily.
Total Productive Maintenance movement.

Eliminate Cushion Storage
Zero Defect Movement.
Total quality management.
Use better inspection processes:
Self Inspection.
Successive Inspection.
Enhancement to inspection through Poka Yoke
Eliminate Cushion Storage
Eliminate Lengthy setups and tool changes
Implement SMED to eliminate long set-up times and tool changes
Running smaller batch sizes to allow for quick changes in production plans

Eliminate Cushion Storage
Absorb Change in Production Plan
Running smaller batch sizes allows for quick changes in production plans without disturbing flow production to significant extent.

Eliminating Safety (S) storage

Safety stock is kept not to take care of any predicted problem but to provide additional security
It may guard against delivery delays, scheduling errors, indefinite production schedules, etc.
Ex. 10 Delivery to stores
In example 2.10 Shingo mentions a company wherein vendors supply to store and from store components are supplied to assembly line.
Shingo suggested that vendors should directly supply the day’s requirements to assembly floor and in case of any problem, components in the store can be used.
Less Need for Safety Stock Observed
That practice led to the observation that very less safety stock is needed in the store.

Shingo recommends keeping a small controlled stock that is only used when the daily or hourly scheduled delivery fails or falls behind.
In case of unexpected defects also it can be used.


The safety stock can then be replenished when the scheduled materials arrive, but the supply of materials due for the process go directly to the line, rather than normally going into storage first.
This is the essence of the just-in-time supply method.


Eliminating lot delays
While lots are processed, the entire lot, except for the one piece being processed, is in storage (is idle).
The greatest reduction in production time can be achieved when transport lot sizes are reduced to just one; the piece that was just worked on.

SMED
Using SMED (single-minute exchange of dies), set up time is decreased so large lot sizes are no longer necessary to achieve machine operating efficiencies.
SMED facilitates one item lot sizes.


Layout Improvement - Flow
Transportation changes can be accomplished through flow  layout and using gravity feed Chutes which result in shorter production cycles and decreases in transport man-hours.

Reducing Cycle Time
Generally, semi-processed parts are held between processes 80% of the time in a production cycle time.
It quantity leveling is used and synchronization of flow is created, the cycle time can be reduced by 80%.
By shifting to small lot sizes will further reduce cycle time.


TPS – Reduction of Delays or Storage
Methods of reducing production time delays (JIT) is the foundation of Toyota Production System.
It clearly brings down production cycle time and thereby offers small order to delivery time.

Process Improvements in Toyota
Mixed model small lot production was attempted in Toyota to compete with American manufacturers.
First, inefficiencies in processing operations, inspection operations and transport operations were removed.
Then storage operations were attacked and inventories eliminated.
Toyota surpassed American manufacturers.

Now TPS is promoted as Lean System



Chapter 2 End

Ch. 3 Improving Operations

Operation may be classified as follows:

Set up operations - preparation
Principal operations - performance
Margin allowances - machine breaks
Personal allowances - worker breaks


Improving Setup
SMED

Improving principal operations
The easiest way to improve principal operations is to separate the worker from the machine.
Reduce involvement of man in machine running and production.
This involves the "one worker, many process" theory.
One worker attends 5-6 machines,
The principle is that cost reduction is more important than high machine operating rates.
Machines should not unnecessarily function and produce excess inventory.
But the operable time of the machine should be high.
Whenever needed machine must be ready for production.

Autonomation
Machine detects problem and stops.
Workers correct the problem.
The next step is to make the machine correct the problem

Improving margin allowances

Main operations are automated by marginal activities like removing chips, feeding materials and stocking products are still done by hand by men.
They also need to be automated.
Lubrication: Consider automatic lubrication, use of oil impregnated metals etc.
Cutting oil – Consider automatic oiling or cutting without oil.
Chip removal – Consider powdering chips or automatic lubrication and chip removal.

Workshop allowances

Automate the following:
Automate feeding for materials.
Automate product storage.
By adopting the SMED system, Toyota achieved dramatic reductions in setup time and inventory cost.
Adding multi-machine handling and autonomation further increased productivity.

Summary of Remaining Chapters of the Book

http://nraoiekc.blogspot.com/2013/12/toyota-production-system-industrial.html

Updated 9 Sep 2015
First published 9 Sep 2014

Toyota Production System - Origin and Development - Taiichi Ohno


Toyota Production System - 2015 Reading by KVSS Narayana Rao

1. Paper by Sugimori in 1977 in IJPR

Mutagenization of Toyota Production System: The Story of Hyundai Motor Company
Byoung-Hoon Lee†, Hyung-Je Jo‡
† Department of Sociology, Chung-Ang University, 221 Heuksuk-dong, Dongjak-gu, Seoul, 156-751, South Korea.
‡ Department of Sociology, Ulsan University

The Contradictions That Drive Toyota’s Success
Hirotaka Takeuchi, Emi Osono, and Norihiko Shimizu
FROM HBR, THE JUNE 2008 ISSUE
Hirotaka Takeuchi (htakeuchi@hbs.edu) is a professor at Harvard Business School. They are the authors of The Knowledge-Creating Company (Oxford, 1995).
Emi Osono (osono@ics.hit-u.ac.jp) is an associate professor;
and Norihiko Shimizu (nshimizu@ics.hit-u.ac.jp) is a visiting professor at Hitotsubashi University’s Graduate School of International Corporate Strategy in Tokyo. 
This article is adapted from their book Extreme Toyota: Radical Contradictions That Drive Success at the World’s Best Manufacturer, John Wiley & Sons.


____________________________________________________________


Summary of What Taiichi Ohno Shared in His Book


I. Starting From Need


"Catch Up With America" Toyoda Kiichiro (1894-1952)


15 August 1945 . Japan lost the war. Toyoda Kiichiro, President of theToyota Motor Company said, "Catch up with America in three years. Otherwise, the automobile industry of Japan will not survive"


Just-In-Time


The basis of the Toyota production system is the absolute elimination of waste. The two pillars needed to support the system are:

Just in time
Autonomation - Intelligent machine that does not produce defect and also stops on it own. Also intelligent operator that do not produce defective parts and investigate and remove the root cause whenever a defective part is produced.

Just in time system eliminates one of the seven wastes specified by Ohno. In an assembly flow process, the right parts needed reach the appropriate place at the time they are needed, inventories can be reduced drastically even up to zero. But to reach the JIT ideal, many existing conventional management methods have to be changed.

Using a Common-Sense Idea

The common sense idea is making only those components demanded or used by the downstream process.

Ohno said, I am fond of thinking about a problem over and over.  The normal planning and production process is for the component producer to produce as per plan and keep it inventory for the assembly department to draw when needed. But Ohno changed this method. Assembly department will go and take what they want and component department has to replenish that component only. So component department has no independent plan. Only assembly department has the plan. Every link in the production flow process or chain is connected with this method and synchronized. With this practice, the management work force is reduced drastically. This information system is given the name kanban.

Give the Machine Intelligence


At Toyota,  machines automated along with an automatic stopping device in case of a problem
 are utilized. In this way, human intelligence is given to machines. The machine stops in case of a problem and the management will come to know of it. Expanding the rule, even operators are asked to stop the flow, if there is a problem. Rapid counter measures are taken to prevent recurrence of a problem.

The Power of Individual Skill and Teamwork


A champion team must have good teamwork and people with individual skill. Likewise autonomation is individual machine skill and JIT is teamwork.

Cost Reduction is the Goal


Frequently we use the word "efficiency" when talking about production, management, and business. "Efficiency" means cost reduction. At Toyota, profit can be obtained only by reducing costs.  We cannot set prices based on our costs.  Consumer sets the price and if the manufacturer sets a higher price due to his high manufacturing cost, the consumer will simply turn away. Cost reduction has to be the goal of manufacturers. The management has to develop human resources ability to its fullest capacity to best enhance creativity, and fruitfulness, to utilize facilities and machines well, and to eliminate all waste.

The Illusion of Japanese Industry


Japanese industry believed in mass production. Till 1973 oil crisis, Japanese manufacturers had the illusion that this system fits their needs


Establishing a Production Flow


Establishing production flow in machine shop was difficult. But in 1947, Ohno arranged machines in a flow order and tried having one worker operate three or four machines (different machines). Even though working time did not go up, operators did not like the new system. Also Ohno wrote, that many adjustments that an operator has to make to machine created difficulties for the operators.  Hence, Ohno said he became patient to implement the system even though he was convinced that the direction was right.

Production Leveling


We got the idea that we should spread production evenly throughout the workday.  We wanted to get away from having to produce everything around the end of the month.

In the Beginning There was Need.


The key to progress in production improvement, I feel, is letting the plant people feel the need.
Opportunities to take care of the needs are always there. Once a need if felt, we just have to drive ourselves to find the practical opportunities that satisfy the needs.

A Revolution in Consciousness Is Indispensable


A person in business may feel uneasy about survival in this competitive society without keeping some inventories of raw materials, work-in-progress, and products. But Ohno says a revolution in consciousness is needed to realize that overproduction and the consequent inventory is a waste that has to be eliminated rather than accumulated.

2. Evolution of the Toyota Production System


Repeating Why Five Times


By asking why five times and answering it each time, we can get to the real cause of the problem, which is often behind behind more visible symptoms.

May be we can interpret it as  prevention - appraisal - failure model. We see failure. We need to know ways to prevent the event very early in the event sequence.

Complete Analysis of Wastes


Improving efficiency makes sense only when it is tied to cost reduction. The efficiency of each operator has to be improved, each production line has to be improved and efficiency of the entire plant has to be improved due to them.

       Waste of overproduction
       Waste of time on hand (waiting)
       Waste in transportation
       Waste in processing itself
       Waste of stock on hand (inventory)
       Waste of Movement
       Waste of making defective products

Ohno made the statement that eliminating these seven wastes completely can improve the operating efficiency by a large margin. To eliminate these wastes, we must make only the quantity needed, thereby releasing extra manpower. Management has to identify excess manpower and utilize it effectively in other activities. Eliminating wasteful and meaningless jobs and creating useful jobs enhances the value of work for workers.


My Plant-First Principle


A proper work procedure cannot be written from a desk. It must be tried and revised many times in the production plant. Production managers have to be in the plant which is a major source of information.

Writing the Standard Work Sheet Yourself


Standard work sheet is basis for all improvements in Toyota production system. Improving machining processes, improving tools, improving transportation processes, and optimizing the inventory, rearranging machines, all such things are implemented through standard work sheets only. The job of the field supervisor, section chief or group foreman is to train workers in standard work. The trainer must actually take the hand of the worker and teach them. Workers of a team also help their team members.

Teamwork is Everything


Team work is essential in manufacturing also like many of the sports. Assigning responsibility to individuals is not sufficient. Teamwork is essential.

The Skill of Passing the Baton
The work area is like track relay. There is a wide area in which baton can be passed.
       Mutual Assistance Campaign

An Idea from the U.S. Supermarket


The communication system of Toyota is Kanban and Ohno got the idea for it from watching the transactions in Supermarkets of USA. At supermarkets buyers buy what they need.  Supermarkets have to facilitate it.

The idea of supermarket was implemented in Toyota and to avoid a situation wherein large quantity of a component is demanded suddenly, production leveling was also introduced.

What is Kanban?


         Kanban is a method for communicating production and use related messages among the plant personnel. Its most frequently used form is a piece of paper contained in a rectangular vinyl envelope. It contains 1. pickup information 2. transfer information and production information.  The kanban method is used for information flow vertically and laterally within Toyota itself and between Toyota and its supply partners.

Kanban is autonomic nerve of the production line.

(The word Kanban literally means visible record).

Incorrect Use of Kanban Causes Problems


Incorrect use of Kanban system causes problems. Close supervision of the kanban rules is required to derive best results from it.

1. An assembly process (more generally later process) can pick up items only in the quantity specified in the kanban from the earlier process. So the quantity the assembly process can pick up at a time is specified in the kanban system.
2. Earlier processes produce items in the quantity specified in the kanban which is provided by the later process after withdrawing the item from stocks of earlier process.
3. No items are withdrawn or transported or produced without a kanban indicating it.
4. All items have to move with an attached kanban.
5. Defective items cannot be sent ahead from any processing station. The assembly line can be stopped if there are no defect-free components or assembly in process. But a defective item cannot move forward.
6. Reducing the batch quantities indicated in the Kanban would make the system more sensitive and makes the system more synchronized.



The Talent and Courage to Rethink What We Call Common Sense


Productivity improvement ideas may come but implementing them requires understanding by top management. The ideas when they defy the present conventional thinking or common sense, requires much more understanding the by the top management and the greater the commitment of top management, the more successful will be the implementation.

Ohno wrote that he came up with many revolutionary ideas and implemented them. They were sometimes regarded as high handed. But Toyota's top management watched the situation quietly and allowed Ohno to implement them.

In 1963 only JIT was extended to outside suppliers. Till that only internal production was handled on JIT basis.

Establishing the Flow is the Basic Condition


Toyota helped its suppliers or cooperating firms to set up flow systems first. Then Kanban system was introduced.

Kanban is the communication tool for implementing or realizing JIT. This tool works well when all the supporting processes are flow processes. So flow process is a basic condition for realizing JIT through Kanban communication system.  The other important conditions are levelled production (eliminating surprise withdrawals of components) and working using standard work methods

Use Your Authority to Encourage Them,


Ohno said his ideas were not understood and hence not used initially by many. But he applied them in his department and when he was given more departments to manage, or was shifted to other departments, he implemented them there also, till Kanban became a company wide practice.

Mountains Should be Low and Valleys Should be Shallow


There must be efforts to level the production during the year. The mountains should be low and valleys should be shallow as much as possible and sales department has to strive for more uniform sales.

Challenge to Production Leveling


TPS works for production leveling during the year, the month and even a day. If 250 sedans, 125 hardtops, and 125 wagons are made daily, in assembly there are done in the sequence One sedan, one hard top, one sedan and then wagon etc. That gives a lot size of one. But lot size of one was not achieved overnight in various shops. In a die-press, in 1940 changing the die took to two or three hours. With such a die changing time, one cannot make small lots. So a decision was taken to make efforts to decrease the die changing times. During 1950s, the die change time went down to one hour. Then it was further reduced to 15 minutes. By late 1960s, the die changing time was drastically reduced to 3 minutes.

The challenge to production leveling and small lots was high set up times. The need for quick die changes was generated or identified and steps were taken to understand the issue and develop a solution.  This problem was not attempted earlier. To do this, initial solutions were developed and the workers were trained. But subsequently, the enthusiasm spread and everybody chipped in with suggestions and method improved beyond the initial description. The system became the product of the effort of large number of people.

Product Leveling and Market Diversification


Ohno emphasized that production leveling (small batch quantity) is much more advantageous than the planned mass production system (larger batch quantity) in responding to the diverse demands especially of the automobile market.

Product leveling or small batches is more advantageous to respond to the market diversification. But still, leveling becomes more difficult as diversification develops. Toyota copes up with this problem well enough and keeps market diversification and production leveling in harmony.  In this endeavor, it is important to avoid the use of dedicated facilities and equipment and also equipment that has very general utility. It is important to put in effort and develop specialized, and yet versatile production processes through use of machines and jigs that can handle minimal quantities (Lot sizes of one). It is difficult but we must utilize all available knowledge to avoid undermining the benefits of mass production.

Kanban Accelerates Improvements

Carrying Carts as Kanban

The Elastic Nature of Kanban


3. Further Development


An Autonomic Nervous System in the Business Organization


Ohno says that human body has autonomic nerves that work as instant reflux to certain external stimuli and motor nerves that work under the command of the brain.

Similar to that in TPS, worker make some decisions without the involvement of production control or engineering departments. Production control and engineering departments are the brain of the organization.

In TPS workers stop the plant when problem occurs, decide the sequence to follow in making parts and also decide when overtime is necessary. They need not involve brain in reacting to some small changes in plans.

Provide Necessary Information When Needed


Computers should not be bought and used indiscriminately. It should not lead to higher costs. Processing customer orders and information on market needs and wants by computers can be very effective. But  kanban communication system is more effective in production communication.

The Toyota Style Information System


Toyota does production planning like other companies.  It has an annual plan, say for instance making 2 million cars in the year.  Next, there is a monthly plan, announced a month ahead. Based on the monthly plan daily production schedule is established and this is based on production leveling. Each production line is informed of the daily production quantity. But the daily sequence schedule (sequence of models and color) is sent to only one place - the final assembly line.

The production order for a specific car is issued to the process 1 of the assembly line. This production order will have all the information needed for its production and the workers in the following assembly  processes can tell which parts to use by at the car this  production order attached to car. Workers in the subprocesses can know what to do as soon as they see the car in assembly at the first stage. If needed they are sent the information directly.  Toyota makes sure the right information reaches the operators at the right time by letting the products being produced carry the information needed to assemble them.

Fine Adjustment


To cope with a constantly fluctuating market, the production line must be able to respond to schedule changes.  One day, the line may make four Car A's and six Car B's. But on another day, the ratio might turn out be the reverse - six car A's and four car B's. Such reversed ratios are followed the production line as per the information carried by the Kanban

Coping with Changes

Fine adjustment also means that mistakes are corrected immediately.

What Is True Economy?


True economy is tied directly to the survival of business. In Toyota production system, economy or efficiency is thought in terms of manpower reduction and cost reduction for making one car. Manpower reduction is a means for cost reduction, which the most critical condition for the growth of the business and its survival. The criterion for all decision making in Toyota is cost reduction.

Many improvement ideas are to be generated and each idea has to be thorougly investigated. The cost of improvement should not be more than the cost reduction. Unless, the judgment is made carefully, cost increasing improvements may be undertaken.

At Toyota, we still use many old machines, by maintaining them properly and daily, improving work methods and making layout changes. A layout must make worker activities easy and should not impede production flow.

Re-Examining the Wrongs of Waste


TPS is a method to thoroughly eliminate waste and enhance productivity. Waste refers to all activities of production that increase cost but not add any value (No increase in price takes place due to them). For example, excess people, inventory, and equipment.

The primary waste of excess people, inventory and equipment give rise to secondary wastes.  Complete understanding of waste is essential to implement TPS successfully.

Generate  Excess Capacity


If excess capacity is there, we can use it for various purposes. At Toyota, through continuous improvement, we create excess capacity first and then use it profitably.

The Significance of Understanding


Ohno emphasize the importance of thoroughly understanding production and improvement of production methods and organization and the process of manpower reduction and cost reduction.

Understanding needs an approach to examine an objective positively and comprehend its nature. Careful inspection of a production area reveals waste and scope for improvement.  Only a very close observation reveals waste and work. There are work movements which are not processing, and there are processing activities which are a waste. Manpower reduction means raising the ratio value added processing activities to 100 percent of the working time.

Utilizing the Full Work System


All sources of waste have to be detected and crushed. Waste of overproduction is eliminated in TPS by strictly adhering to standard inventory. If the standard inventory is specified as 5, on a day when it becomes 3 only 2 are produced. On a day when it becomes 4 only one is produced. We call it a full work system, when all standard inventories are replenished in a day. We do not want any overproduction in a day.

Tact Time

(Do Not Make a False Show)

Tact is the length of time, in minutes and seconds, allowed by the customer demand to make one piece of the product. Tact is obtained by dividing the operable time per day (of the machine) by the required number of pieces per day.  Operable rate in TPS refers to the time machine is available for production in a day. The ideal operable rate is 100 per cent. To achieve this, maintenance has to be regular to prevent breakdowns and setup times are to be reduced. Operating rate refers to the production per day.

At Toyota, improvements increase the production quantity per day from a group of workers. But, if excess production is not required as per demand, the number of workers are reduced from the team and only required production is made. Unnecessarily producing excess is no efficiency.

Required Numbers Are All-Important


For each production line, numbers or quantity required by the market is important. In Toyota, we do not produce extra above the required quantity in any line. The excess manpower is transferred to other lines where needed. The required number is adhered to in a disciplined way.

The Tortoise and the Hare


At Toyota we produce according to the needs of the market at slow or fast rate everyday. It is the way of tortoise. We do not run very fast some days and then take rest on other days like a hare.

Take Good Care of Old Equipment


Ohno says, the expertise of a worker increases overtime. But in case of machine, the depreciation of the machines is the popular idea. If machines are poorly maintained and driven close to death, enormous costs are incurred in replacement.  Ohno says, with adequate maintenance, machines will have a longer life.

Look Straight at the Reality

When estimating future business, Ohno recommends that one must be realistic and be ready for instant declines in business.

0.1 Worker is Still One Worker


The savings that come from automation should result in saving a full worker. Then only automation will give cost reduction. Ohno says at the design stage of the production system itself, fewer workers are to be employed. One should not employ more workers initially and then remove them when not needed.

Ohno, in this point also stresses that, they form teams of workers and do not allow only one worker to work in isolation.

Management by Ninjutsu

Management by Ninjutsu means acquiring management skills by training.

In an Art Form, Action is Required
An engineer is an artist. Art requires action not speaking.

Profit Making Industrial Engineering at Toyota


Advocating Profit-Making Industrial Engineering

Surviving the Slow-Growth Economy

4. Genealogy of the Toyota Production System


This chapter gives many passages from the thoughts and sayings of Toyota Sakichi and Toyoda Kiichiro.

Toyoda Kiichiro once told Toyoda Eiji that the best way to work in an automobile assembly plant would to have all parts for assembly at side of the line just in time for their use. The words "just-in-time" attracted many managers of Toyota and Ohno was also attracted by those words.

Taiichi Ohno had experience of cost reduction at Toyota Spinning and Weaving also. The company was implementing cost reduction measures  to catch up and surpass  Lancashire and Yorkshire companies. Toyoda Sakichi had world class view. Toyoda Kiichiro also had world class view. In the two pillars of TPS, autonomation came from Toyoda Sakichi and JIT came from Toyoda Kiichiro.

Toyoda Sakichi said that he observed a grand mother hand weaving for a full day and developed interest in developing a machine for it. Ohno likes that idea of observing on the shop floor to understand things. He wrote "Stand on the shop floor all day and watch - you will eventually discover what has to be done."

Toyoda Kiichiro visisted America and he must have thought about how surpass America's highly developed automobile production system and utter the idea of JIT.

Toyoda Sakichi talked of inventions made by Japanese efforts, knowledge and intellect.He made 100 inventions with patents.







A Global World Around Us



Two Extraordinary Characters

Learning from the Unyielding Spirit

I believe just-in-time was Toyoda Kiichiro's dying wish  - Ohno

Toyotaism with a Scientific and Rational Nature

Provide Good Equipment Even If the Factory Is Simple

Pursuity of a Japanese-Style Production Technique

Making Products That Have Value

Toyoda Kiichiro recognized that the market always demands reasonably priced products.  He wrote "We know our cars will not sell unless they are cheaper than foreign models. "We might manage to sell 50 to 100 cars per month by appealing to patriotism. But selling 200 or 500 cars per month would be difficult. In the end, prices must be competitive."

Can we actually produce economical cars domestically? Cars with proper materials and proper quality?

A Chess Player's View

In Search of Something Japanese

Witnessing a Dialectic Evolution

Toyoda Kiichiro  " we shall learn production techniques from the American method of mass production. But we will not copy it as is. We shall use our own research and creativity to develop a production method that suits our own country's situation."

I believe this was the origin of Toyoda Kiichiro's idea of just-in-time.

5. The True Intention of the Ford System


The Ford System and the Toyota System


Ohno acknowledges - Henry Ford without dispute created the automobile production system. Toyota system uses the flow system developed by Ford. But the difference is that at Ford they were concerned about warehousing the parts and moving the chassis past the warehouse. Toyota eliminated the warehouse.

Small Lot Sizes and Quick Setup


The American automobile business has continuously shown that planned mass production has the greatest effect on cost reduction. The Toyota system takes the reverse course. The slogan is "small lot sizes and quick setups." Toyota system works on the premise of totally eliminating the overproduction generated by inventory and costs related to workers, land, and facilitates needed for managing inventory.

Toyota system works on the premise of totally eliminating the overproduction generated by inventory and costs related to workers, land, and facilities needed for managing inventory.

Rapid changeovers are an absolute requirement for the Toyota Production System. Teaching workers to reduce lot sizes and setup times took repeated on-the-job training.

The Foresight of Henry Ford


Ford said what we do have to bother about is the waste of human labor.  Material in our factory represented labor. When we are wasting material we are wasting labor of some body. We will use material more carefully if we think of it as labour.  Our studies and investigations up to date have resulted in the saving of 80,000,000 pounds of steel a year and this amounts to about 3 million dollars a year.


Standard are Something to Set Up Yourself



Prevention Is Better than Healing


Toyota's strength does not come from its healing processes - it comes from preventive maintenance.

Is There a Ford after Ford?


Ohno said "I think the TPS can be applied in America where the market for many types in large quantities is there."

Toyota has learned a lot from the Ford system.

Inverse Conception and Business Spirit


Is cotton the best material we can use here?  (in seats) As an answer to this question Ford came up with flax and methods to handle it mechanically. Ohno said, "I was intrigued by Ford's question. Is cotton the best material we can use here?"  As Ford pointed out, people follow tradition. This might be acceptable in private life, but in industry, outdated customs must be eliminated. This process of aking why represents Ford's business spirit.  Ohno said reading Ford shows many such brilliant inverse conceptions.

Getting Away from Quantity and Speed

Is efficiency in production systems wrecking all the finer things in life?

Efficiency is merely doing the work in the best way you know rather than in the worst way. It is the taking of a trunk up a hill on a truck rather than on one's back. It is training of the worker and the giving to him of power so that he may earn more and have more and live more comfortably.

6. Surviving the Low-Growth Period


The System Raised in the High-Growth Period

Raising Productivity during Low Growth

Learning from the Flexibility of Ancient People

Important Terms Used to Describe Toyota Production System


Andon

Autonomation

Baka-Yoke

Baton Passing Zone

Do NOt Mkae Isolated Islands

Five Why's

Just-in-Time

Kanban

Labor Saving to Worker Saving to Reducing Number of Workers

Moving vs. Working

Multi-Process Operation System

Operating Rate and Operable Rate

Production Leveling

Profit-Making Industrial Engineering

Real Cause

Required Numbers Equal Production Quantity

Small Lot Sizes and Quick Setups

Standard Work Procedures

Stopping the Line

Tact Time

Toyota Production System

Visual Control (Management by Sight)

Waste Recognition and Elimination

Work Flow and Work Forced to Flow


Work Improvement vs. Equipment Improvement
Work productivity improvement is productivity improvement using the existing equipment. Only tools, jigs and fixtures are introduced as required in work productivity improvement.
If equipment improvement comes first, manufacturing processes will never be improved.



Shigeo Shingo -  Study of Toyota Production System from Industrial Engineering Point of View." - Summary


Shigeo Shingo, the famous industrial engineer from Japan, taught training programmes in Toyota Motors and also gave consultancy services. Based on Taiichi Ohno's book on Toyota Production System, Shingo gave further details of the system in the a book titiled "Study of Toyota Production System from Industrial Engineering Point of View."

You can read the summary of the books in these two parts.

http://nraoiekc.blogspot.com/2014/02/industrial-engineering-foundation-of.html

http://nraoiekc.blogspot.com/2014/02/industrial-engineering-foundation-of.html








Updated 9 Sep, 5 Sep 2015, 30 Nov 2013



Tuesday, September 1, 2015

Manufacturing Ideology: Scientific Management in Twentieth-Century Japan - William M. Tsutsui - Book Information

Technology and Manufacturing Process Selection - Elsa Henriques et al. - Book Information

Flexibility and Efficiency - Both Can be Improved - Paul S. Adler


Flexibility Versus Efficiency? A Case Study
of Model Changeovers in the Toyota
Production System
Paul S. Adler • Barbara Goldoftas • David I. Levine
School of Business Administration, University of Southern California, Los Angeles, California 90089-1421
Program in Writing and Humanistic Studies, Massachusetts Institute of Technology,
Cambridge, Massachusetts 02139
Haas School of Business, University of California, Berkeley, California 94720


Much organization theory argues that efficiency requires bureaucracy, that bureaucracy impedes flexibility,
and that organizations therefore confront a tradeoff between efficiency and flexibility. Some researchers have challenged this line of reasoning, arguing that organizations can shift the efficiency/flexibility tradeoff to attain both superior efficiency and superior flexibility

The authors analyze an auto assembly plant that appears to be far above average industry performance in both efficiency and flexibility. NUMMI, a Toyota subsidiary located in Fremont, California, relied on a highly bureaucratic organization to achieve its high efficiency. Analysis of  two recent major model changes, the authors  find that NUMMI used four mechanisms to support its exceptional flexibility/efficiency combination.

ORGANIZATION SCIENCE/Vol. 10, No. 1, January–February 1999 pp. 43-68

The Birth of Lean - Koichi Shimokawa - 2012 - Book Information


The Birth of Lean: Conversations with Taiichi Ohno, Eiji Toyoda, and Other Figures who Shaped Toyota Management


Koichi Shimokawa (Editor), Takahiro Fujimoto (Editor)

Lean Enterprise Institute, 04-Mar-2012 - Business & Economics - 300 pages
This is an honest look at the origins of lean, written in the words of the people who created the system. Through interviews and annotated talks, you will hear first-person accounts of what these innovators and problem-solvers did and why they did it. You'll read rare, personal commentaries that explain the interplay of (sometimes opposing) ideas that created a revolution in thinking.

Google Book Link with Preview Facility
http://books.google.co.in/books?id=SDYLbXoW_EcC


Interesting explanations by Ohno in the book. The call by Toyoda to catch up the with American Productivity was there in this book also.  Page 7


Table of Contents


Preface

Introduction

Chapter 1 How it all began - Taiichi Ohno

Chapter 2. What I learned from Taiichi Ohno - Michikazu Tanaka

Chapter 3. Putting a Pull System in Place at Toyota - Kikuo Suzumura

Chapter 4. The Evolution of Buffering at Toyota - Kaneyoshi Kusunoki

Chapter 5. Total Quality Control and the Toyota Production System - Masao Nemoto

Chapter 6. The Guiding Management Perspective - Eiji Toyoda

Afterword


Updated  1 Sep 2015
First published  24 August 2013