WEB Trish Melton Lean Manufacturing July 2005

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THE BENEFITS OF LEAN MANUFACTURING

What Lean Thinking has to Offer the Process IndustriesT. MELTON

MIME Solutions Ltd, Chester, UK

How many people in the manufacturing industry can truly say that they have not heardof LEAN? Not many. Yet how many of these believe in lean, have implementedlean, are the passionate change agents who have convinced senior stakeholders

than lean is the way forward for their company? Less. Much Less. Lean is a revolutionitisnt just about using tools, or changing a few steps in our manufacturing processesitsabout the complete change of our businesseshow the supply chain operates, how the direc-tors direct, how the managers manage, how employeespeoplego about their daily work.

Everything. So what is this revolution, and how is it impacting the process industries? Thebackground of lean thinking is based in the history of Japanese manufacturing techniqueswhich have now been applied world-wide within many types of industry.

Keywords: lean manufacturing; waste; value; flow; value stream; bottleneck.

A BRIEF HISTORY OF LEAN

Mention lean and most lean thinkers will know that thisis a reference to the lean production approach pioneered byToyota but also the subject ofThe Machine that Changedthe World(Womacket al., 1990); a book which first high-lighted Japanese production methods as compared to tra-ditional Western mass production systems; it alsohighlighted the superior performance of the former. Thefollow-on book, Lean Thinking: Banish Waste and CreateWealth in your Organisation (Womack and Jones, 1996),is equally a key step in the history of lean as it summarizesthe lean principles which guide action. It also coined thephrase Lean Production.

But lets go back to the beginningthe birth of lean wasin Japan within Toyota in the 1940s: The Toyota Pro-duction System was based around the desire to produce

in a continuous flow which did not rely on long productionruns to be efficient; it was based around the recognition thatonly a small fraction of the total time and effort to process aproduct added value to the end customer. This was clearlythe opposite of what the Western world was doingheremass production based around materials resource planning(MRP) and complex computerized systems was developingalongside the mass production philosophies originallydeveloped by Henry Ford, i.e., large high volume pro-duction of standardized products with minimal productchangeovers.

Taiichi Ohno had started work on the Toyota Productionsystem in the 1940s and continued its development into thelate 1980s unhindered by the advancements in computerswhich had allowed mass production to be furtherenhanced by MRP Systems. By the 1970s Toyotas ownsupply base was lean; by the 1980s their distributionbase was also lean.

Key tools and techniques within the lean system,included:

. Kanbana visual signal to support flow by pulling pro-duct through the manufacturing process as required bythe customer.

. 5 Ssa visual housekeeping technique which devolvedcontrol to the shopfloor.

. Visual controla method of measuring performance atthe shop floor which was visual and owned by the oper-ator team.

. Poke yokean error-proofing technique.

. SMED (single minute exchange of dies)a changeoverreduction technique.

However let us return to the 1990s and the two landmarkworks discussed at the start of this section.

The Machine that Changed the World (Womack et al.,1990) compared and contrasted the Mass ProductionSystem seen in the US and Europe, with the Lean ProductionSystem, seen in Japan, within the automotive industry.

Table 1 is a summary of some of the comparisons high-lighted by Womacket al. (1990).

. The mass producers were able to maintain long pro-

duction runs using standard designs which ensured thatthe customer got a lower cost; they also got less variety

Correspondence to: Dr T. Melton, MIME Solutions Ltd, Gable Cottage,Childwall Farm, Kelsall Road, Kelsall, Chester, CH3 8NR, UK.E-mail: [email protected]

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02638762/05/$30.00+0.00# 2005 Institution of Chemical Engineers

www.icheme.org/journals Trans IChemE, Part A, June 2005doi: 10.1205/cherd.04351 Chemical Engineering Research and Design, 83(A6): 662673


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as did the workforce who found this mode of operationtedious.

. In comparison, the term lean comes from the upsideof the production method which requires half thehuman effort, half the manufacturing space, half theinvestment and half the engineering hours to develop

a new product in half the time.However, it is not difficult to see that the world of car-partsand conveyor belt production lines did not immediatelygrab the interest and excitement of the process industries.Apart from the packaging lines the analogies seemed hardto find.

However, Lean Thinking (Womack and Jones, 1996)helped us to understand the principles of lean:

. The identification ofvalue.

. The elimination ofwaste.

. The generation offlow (of value to the customer).

It clearly demonstrated that this was not a philosophy or

technique which was only applicable to the automotiveindustry.

THE BENEFITS OF BEING LEAN

The benefits seen within non-process industries (seeFigure 1), such as the automotive industry, are welldocumented:

. decreased lead times for customers;

. reduced inventories for manufacturers;

. improved knowledge management;

. more robust processes (as measured by less errors andtherefore less rework).

This makes lean a very real and physical conceptespecially for manufacturing.

Lean production has now expanded and lean thinking hasbeen applied to all aspects of the supply chain. There aremany well documented examples of the application oflean thinking to business processes such as project man-agement (Melton, 2003); construction, design, and so on.

Lean can be applied to all aspects of the supply chain andshould be if the maximum benefits within the organizationare to be sustainably realized. The two biggest problemswith the application of lean to business processes are theperceived lack of tangible benefits and the view thatmany business processes are already efficient. Bothassumptions can be challenged (Melton, 2004):

. There are many tangible benefits associated with leanbusiness processes. A lean business process will befaster, e.g. the speed of response to a request for thebusiness process will be faster, and as most business pro-cesses are linked to organizational supply chains, thenthis can deliver significant financial benefits to acompany.

. The perception that a business process is already efficientis all too often an illusion. Functionally, many businessprocesses may appear very efficient, however the appli-cation of Lean Thinking forces us to review the wholesupply chain in which the business process sits, andthis frequently reveals bottlenecks and pockets ofinefficiency.

But for now let us return to the world of manufacturingwithin the process industries.

WHATS STOPPING US?

With the benefits so apparently obvious the question hasto bewhats stopping us?

For some in the process industries the answer is simplenothing! There are good examples of the implementation oflean philosophies across the process industries. Forexample, PICME (Process Industries Centre for Manufac-turing Excellence), an organization part funded by theDTI to specifically help manufacturing in the processindustries to become more efficient and more competitive,

quote estimated projected savings of over 75 millionover their first 5 years of operation (PICME, 2004).

Table 1. Production Systems Compared.

Mass production Lean production

Basis Henry Ford Toyota

Peopledesign Narrowly skilled professionals Teams of multi-skilled workers at all levels in the organization

Peopleproduction Unskilled or semi-skilled workers Teams of multi-skilled workers at all levels in the organization

Equipment Expensive, single-purpose machines Manual and automated systems which can produce large

volumes with large product variety

Production methods Make high volumes of standardized products Make products which the customer has ordered

Organizational philosophy Hierarchicalmanagement take responsibility Value streams using appropriate levels of empowermentpushing responsibility further down the organization

Philosophy Aim for good enough Aim for perfection

Figure 1. The benefits of lean.

Trans IChemE, Part A, Chemical Engineering Research and Design, 2005, 83(A6): 662673

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But for some the case for change cannot be as compel-ling as it would appear to be. Figure 2 is a force field dia-gram which shows some of the drivers and resistors withinthe manufacturing sector of the process industries; it is onlywhen the specific driving forces for an organization aregreater than the opposing forces that the change willoccur. The ultimate sustainability then requires additionalsupporting forces to further reduce and eliminateopposition.

Within the process industries specific sectors have beenunder increasing pressure:

. Chemical Industrythe continuing pressure on the costbase.

. Pharmaceutical manufacturingthe pressure on thesupply chain has increased as there are more externalcompetitive pressures for manufacturers to deliver new,safe efficacious drugs quicker than ever before.

Butlean manufacturing has now been applied within thepharmaceutical sector both within primary and secondaryoperations and the use within the wider process indus-tries is increasingly likely as the breadth of benefits aredemonstrated and the driving forces for change increase.

Lean thinkers would probably want an additional drivingforce for change: lean is easy to implement! But althoughthe principles and tools associated with lean thinkingmay appear at face value an easy concept to use within

an apparently willing industry they present huge changechallenges to any business truly wishing to become lean.

Perhaps the biggest resisting force for the process industrieswill be the huge inertia that must be overcome: the resist-ance to change.

Lean thinking involves a serious challenge to the statusquo and for many this level of challenge to the way wedo things round here is a sufficient deterrent to appli-cationparticularly after the surge of business changesimplemented following initiatives seemingly aiming for asimilar goalgreater business effectiveness and thereforeprofit! However it can be demonstrated that the forcessupporting the application of lean are greater than thoseresisting it.

WHAT IS LEAN THINKING?

Lean Thinking starts with the customer and the definitionofvalue. Therefore, as a manufacturing process is a vehicleto deliver value (a product) to a customer, the principles oflean thinking should be applicable to the Process Industriesand the specific manufacturing processes within thatindustry.

We can removewastefrom many steps of our manufac-turing processes, from how we develop the initial productand process design, how we assure compliance, to howwe design to operate a completed facility. However, to betruly lean we have to link all these elements within arobust supply chainwe need to ensure the flow of value.

This leads to what many are calling a lean enterprise(LERC, 2004).

Figure 2. The forces opposing and driving a change to lean.


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The Lean Enterprise Research Centre (LERC, 2004) atCardiff Business School highlighted that for most pro-duction operations:

. 5% of activities add value;

. 35% are necessary non-value activities;

. 60% add no value at all.

Therefore, there is no doubt that the elimination of wasterepresents a huge potential in terms of manufacturingimprovementsthe key is to:

. identify both waste and value;

. develop our knowledge managementbase;

. realize that sustainable improvement requires the buyin of the people operating the processes and managingthe business, and therefore a culture of continuousimprovement.

Value

The identification of value and the definition of valuepropositions for specific customers is the starting point.Without a robust understanding of what the customervalues you cannot move forwards (see Table 2). Outsideof the process industries there are many examples ofwhat we mean by a value propositionas a consumerbuying a washing machine what we value may be the abil-ity to wash our clothes at home; for others the value may berelated to cost or specific design features or even the colour.The challenge for the manufacturer is to develop a productportfolio based on these value propositions.

Table 2 gives some examples of value propositionswhich manufacturers in the process industries havedeveloped as related to their specific customer group,

their product portfolio and their potential capabilities.For customer A, development of the process they hand-

over to the toll manufacturer is a value added activity;for customer B this would be considered waste.

Waste

Any activity in a process which does not add value to thecustomer is called waste. Sometimes the waste is a

necessary part of the process and adds value to the com-pany and this cannot be eliminated, e.g., financial controls.

Otherwise all Muda, as the Japanese call waste, should beeliminated.

There are seven main types of waste as outlined inFigure 3 and further detailed in Table 3.

Initially, waste can be easily identified in all processesand early changes can reap huge savings. As the processescontinually improve, the waste reduction will be moreincremental as the company strives to achieve a waste-free process. Continuous improvement is at the core oflean thinking.

The data in Table 3 is only the tip of the iceberg in termsof the amount and types of waste which will be within ourmanufacturing processes and overall supply chains. Thekey is to identify it, i.e., to ensure that the root causethe real wasteis eliminated, not just the symptom.

Flow

Flow is probably the hardest lean concept to understand.It is the concept which most obviously contradicts withmass production systems; the comparison of one pieceflow versus batch and queue processes.

It is a lack of flow in our manufacturing processes which

accounts for the huge warehouses which house the mass ofinventory which consumes the working capital of thebusiness.

To understand flow you need to understand the conceptof the value streamthat linkage of events or activitieswhich ultimately delivers value to a customer. A valuestream crosses functional and, usually, organizationalboundaries.

Figure 4 shows a simple value stream which wouldbe typical for a toll manufacturer. The value stream doesnot show all the supporting activities, only the mainvalue adding stages and the key multi-functional teamsinvolved.

Flow is concerned with processes, people and culture and

it is appropriate at this stage to mention the work ofGoldratt and Cox (1993) whos bookThe Goal introduced

Figure 3. The seven types of waste.

Table 2. Examples of value propositions within the process industries.

Customer type Value proposition Manufacturer type

A. Majorpharmaceuticalmanufacturer ofdrug products

Robust process andproduct developmentat fast track speedensuring regulatorycompliance

Tollmanufacturer ofpharmaceuticalintermediates

B. Othermanufacturer ina low cost baseindustry

Correct specification,low cost anddelivered on timein the volumesspecified

Bulk chemicalsmanufacturer

C. The patient (viathe companieswho distributethe drugs)

High quality, safedrugs that work atan appropriate price

Majorpharmaceuticalmanufacturer ofdrug products




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the Theory of Constraints. This theory aligns with leanthinking in the way it considers an organization as asystem consisting of resources which are connected by pro-cesses which ultimately make product which can be sold.

It effectively talks about a value stream and the maincauses for the lack of flowconstraints in the system.

Godratt and Cox (1993) introduced some development ofoperational rules to guide how a production plant should beoperated based on three measurements:

. Throughput: the rate at which the system generatesmoney through sales (use sales not productionif youproduce something, but do not sell it, it is not through-

put)this links into the lean philosophy of producingproduct when the customer pulls for it.

. Inventory: all the money that the system has invested inpurchasing things which it intends to sell.

. Operational expense: all the money the system spends inorder to turn inventory into throughput.

They then define the goal of that production operation asincreasing throughput while simultaneously reducing bothinventory and operating expense and that any plantimprovement must be challenged against this, i.e.,

. as a result of this improvement will we: Sell any more products? (Did Throughputgo up?) Reduce the amount of raw materials or overtime?

(Did Operating Expense go down?) Reduce the plantInventory?

Table 3. The seven types of waste.

Type of waste Description Within the process industry Example symptom

1. Overproduction

Product made for no specificcustomer

Development of a product, aprocess or a manufacturingfacility for no additional

value

Large campaignlarge batch andcontinuous large-scale manufacturingprocesses

Development of alternative process routeswhich are not used or the development of

processes which do not support thebottleneck

Redesign of parts of the manufacturingfacility which are standard, e.g., reactors

The extent of warehouse space neededand used

Development and productionorganization imbalance

An ever changing process (tweaked) Large engineering costs/time

associated with facility modifications

2. Waiting As people, equipment orproduct waits to beprocessed it is not addingany value to the customer

Storage tanks acting as product buffers inthe manufacturing processwaiting to beprocessed by the next step

Intermediate product which cannot leavesite until lab tests and paperwork arecomplete

The large amount of work inprogress held up in themanufacturing processoften seen onthe balance sheet and as piles ofinventory around the site

3. Transport Moving the product toseveral locations

Whilst the product is inmotion it is not beingprocessed and therefore notadding value to the customer

Raw materials are made in severallocations and transported to one sitewhere a bulk intermediate is made. This isthen transported to another site for finalproduct processing

Packaging for customer use may be at aseparate site

Movement of pallets of intermediateproduct around a site or between sites

Large warehousing and continualmovement of intermediate material onand off site rather than final product

4. Inventory Storage of products,intermediates, raw materials,and so on, all costs money

Economically large batches of rawmaterial are purchased for largecampaigns and sit in the warehouse forextended periods

Queued batches of intermediate materialmay require specific warehousing orsegregation especially if the lab analysisis yet to be completed or confirmed

Large buffer stocks within amanufacturing facility and also largewarehousing on the site; financiallyseen as a huge use of working capital

5. Overprocessing

When a particular processstep does not add value tothe product

A cautious approach to the design of unitoperations can extend processing timesand can include steps, such as hold ortesting, which add no value

The duplication of any steps related to thesupply chain process, e.g., sampling,checking

The reaction stage is typicallycomplete within minutes yet wecontinue to process for hours or days

We have in process controls whichnever show a failure

The delay of documents toaccompany finished product

6. Motion The excessive movement ofthe people who operate themanufacturing facility iswasteful. Whilst they are inmotion they cannot supportthe processing of the product

Excessive movement ofdata, decisions andinformation

People transporting samples ordocumentation

People required to move work in progressto and from the warehouse

People required to meet with other peopleto confirm key decisions in the supplychain process

People entering key data into MRPsystems

Large teams of operators moving toand from the manufacturing unit butless activity actually within the unit

Data entry being seen as a problemwithin MRP systems

7. Defects Errors during the processeither requiring re-work oradditional work

Material out of specification; batchdocumentation incomplete

Data and data entry errors General miscommunication

Missed or late orders Excessive overtime Increased operating costs


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The final concept they introduce is that of thebottleneckthat step in a process which determinesthe throughput of the whole process. This also aligns withlean pull production which tells production that its OKto stop production! (if there is no customer pull).

Within the process industries we do strive for pro-duction efficiencies, however, a value stream perspectivemeans working on the big picture, not just individualprocesses, and improving the whole, not just optimisingthe parts (Rother and Shook, 1999). In other wordswe need to improve the efficiency and effectiveness ofthe whole supply chain not just improve one part ofit and we need to operate the supply chain not the pro-duction unit.

Figure 5 summarizes the above discussion on flow bydemonstrating how a part of a supply chain could operate

if pulled rather than pushed. In a push system pro-duction works as much as it can to fill a warehouse; In apull system production works only when it needs to atthe pull of customer orders.

Figure 5 demonstrates that the process (the grey boxes)only operates when an appropriate signal is seen:

. The packaging operation only operates when it is packa-ging for a customer order (its signal to pack). It takesproduct from a final product silo (kanban).

. When the level in the silo falls past the red line this is asignal for the final product manufacture to commence.Once the silo is at the green level this is a signal forthe manufacture to stop. This operation takes its material

from the raw materials kanban and the intermediatekanban.

Figure 4. A simple value stream.

Figure 5. Pull production exampleusing kanbans.




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. Both of these are storage areas. Specific kegs are placedon a coloured floor. When enough kegs have been usedso that the red area of the floor can be seenthis is asignal for the preceding operation to commence, i.e.,intermediate manufacture or purchasing of raw materials.

The sizing of the kanbans and their operation to ensure

FIFO (first in-first out) has to be thought through but thiscan be an effective method of:

. Implementing a pull production system.

. Reducing lead-time to the customer.

. Reducing inventory at all stages in a process.

Knowledge Management

The knowledge we have in our systems and more impor-tantly, our people, is fundamental to the implementationof lean.

The success of lean in some manufacturing organizationshas been in part due to the reorganization of the teams at

both operational and management level.Example changes are:

. reorganization of all resources around value streams;

. multi-skilled or cross-functional teams with moreresponsibility for the day to day operation of a manufac-turing unit.

Additionally, formally capturing knowledge of processes isnecessary especially within a work environment where cor-porate knowledge is no longer defined by the large numbersof employees who have worked there all their lives. Some

companies have used some form of IT solution to captureknowledge formally; for others a process of knowledgesharing spreads the knowledge wider than previously. Awell-managed knowledge base is critical to the sustainabil-ity of change.

Continuous Improvement

Lean thinkers are aiming for perfection and in doing sothe improvement cycle is never ending. For many in theprocess industries this culture change is the hardestchange of all.

However, for assured sustainability the organizationswho are truly lean will invest the time and effort to supporta change in culturethe way we do things around here.The case study attempts to highlight some of the ways inwhich culture can be impacted.

HOW TO START LEAN THINKING

A data-rational, structured approach is needed if the keyprinciples of value, waste and flow are to be rigorouslyapplied along the supply chain.

The process of how to lean (Figure 6) can be summar-ized as:

. Document current process performancehow do we doit now.

. Define value and then eliminate waste.

. Identify undesirable effects and determine their rootcause in order to find the real problem.

Figure 6. How to lean.


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. Solve the problem and re-design the process.

. Test and demonstrate that value is now flowing to thecustomer of that process.

There are many tools and techniques to support each stepin the above processthey support implementation of theprinciples.

Table 4 shows a sample of the tools a lean thinkerwould have in their toolkit. What surprises many skepticsis that the lean principles can be put into action usingtools which are very familiar to those who have beeninvolved in performance improvements.

What is different is the fact that they are used toensure that:

. manufacturing processes deliver value to theircustomers;

. all activities which do not add valuewasteare elimi-nated or reduced;

. the manufacturing processes flow within a robust andlean supply chain.

PRESENTING THE EVIDENCE: A CASE STUDY

The following case study is taken from a real situationit aims to demonstrate the benefits from lean manufacturingand also lean supply chainstwo facets of lean thinkingwhich are revolutionising the parts of process industriesin which they have been implemented.

Making a Value Stream: The Design andImplementation of Lean

The following is a case study example taken from theprocess industries. It shows how the three principles oflean supported by the enabling principles, can deliver stepchange business benefits and ongoing incremental benefits.

A multi-product manufacturing process was taking 10weeks from the introduction of raw materials to the com-pletion of final product processing. The customers gener-ally expected a lead-time of 6 weeks from orderplacement to receipt of the goods.

Table 4. A sample lean toolkit.

Tool Description Typical Use

Force fielddiagramming

A tool which allows analysis of the forcessupporting or resisting a particular change

When looking at a potential design When looking at the implementation planning for a change

following design

IPO diagramming A basic flowchart tool mapping inputs, processesand outputs. Based on the required outputs, theappropriate process can be defined and therequired inputs specified

To design a team session at any stage of the implementation oflean, e.g., data collection day, kaizen day (implement achange in one day), implementation planning

Process flow mapping A map showing each process step in the valuestream

A data collection activity Also used to analyze the VA (value-add) and NVA (non value-

add) steps and as a tool for redesign

Time-value mapping A map of the time taken for each process step inthe value stream

A data collection activity Also used to analyze the VA and NVA steps and as a tool

for redesign

Spaghettidiagramming

A map of the physical path taken by a product asit passes down the value stream

A data collection activity

Five whys Taiichi Ohno (Womacket al., 1990) had apractice of asking why five times whenever aproblem was found. In this way the root causewas solved rather than the symptom.

As a part of the data analysis so that the root cause problemcan be solved in the design phase

Five Ss Five activities used to create a workplace suitedfor visual control and lean practices:

Seiriseparate required from unnecessary toolsand remove the latter

Seitonarrange tools for ease of use Seisoclean-up

Seiketsudo the above regularlymaintain thesystem youve set up

Shitsukeget into the habit of following the firstfour Ss

Can be used at the start of a lean induction to break downbarriers and get a team to own their workspace

Often used during Kaizens as workplace layout and tidiness isoften an issue which causes waste (unable to find the rightequipment, use whats there, lose key paperwork, and so on)

Risk assessment A structured assessment of what could stop theachievement of specific objectives and how thiscan be mitigated

Assessment of a design prior to implementation as a finalchallenge of the design

Assessment of the issues post-implementationlookingspecifically at what would stop the sustainability ofthe change

Kaizen An improvement activity to create more valueand remove waste. Commonly called abreakthrough kaizen

Kaizen workshops are a common method to kick-off thestart of a large step change within an area or value stream

Kaizens would actually start with data collection and continueto do some data analysis, design and even implementation

Kanban Japanese for signboard. This is a visual shopfloor pull system which means that each

supplying work centre does not make anythinguntil the next work centre requests supply

This is a design solution to materials flow problems within aprocess (examples within both manufacturing and lab

situations have been seen)




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As the Manufacturing Time . Customer Lead-Time allproduction was scheduled according to a sales forecast.

Sales forecasts within this particular organization, aswith many others, were unreliable and the Production Man-ager had to build up significant stock of finished product toensure that all eventual orders could be met.

The Site Director was faced with a set of key perform-

ance indicators (KPI) which showed a trend for late orincorrect customer orders, decreasing product quality,increasing manufacturing time and another request for anadditional warehouse for all materials associated with themanufacturing process as well as finished product.Additionally, a new KPI was emerging: the amount of pro-duct which became unsaleable due to shelf life issuesindicating both a problem with the length of time productwas being stored in warehouses and the process by whichproduct was chosen for customer orders.

Initially a Kaizen was used to pull together a cross-sectionof all the operational teams that were involved in the manu-facturing unit: Operators, Lab Analysts, Warehouse Staff,

Customer Service Staff, Schedulers, MRP Data Handlers,Technical Support Scientists, and so on.The aim of the Kaizen was twofold:

. to collect and analyse data to identify the REAL problemand design some solutions;

. to start to break down functional barriers and generalskepticism about lean thinking.

The data collection and data analysis phases yieldedsome key problems:

. Process mappingthe total number of steps both withinand outside of the manufacturing process was 34;

approximately 60% of these involved either travel orwaiting, i.e., pure waste (see Figure 7). The process mapping was reviewed via closer obser-

vation after the kaizen and a number of variationscame to light as well as a realisation that the discretenumber of steps was nearly double!

Typical variations were seen when urgent orders

were expedited through the system and the teamsworked closer together to naturally eliminate stepswhich didnt help get the product to the customer

. Spaghetti mappingdemonstrated the extent to whichthe product, its associated batch documentation, theoperators, the samples and the support staff had totravelit was miles!

. Time-value mappingof the 10 weeks to produce a typi-cal product from raw materials only 25% was valueadding (Figure 8). The data collected during process mapping was con-

verted into a time-value map (Figure 8). This type ofanalysis denotes value added activities as green and

waste as red, i.e., the initial days are shown as wait-ing for the schedule. The Blend sample test (1 day) also has a 50% waste

content as only 50% of the tests done on the sampleever fail.

The space between each activity is the waiting time. This gives an excellent visual representation of the

overall processif all the red and white space isremoved then the process could theoretically bereduced from 10 weeks to 1 week!

. Undesirable effects analysisthe supply chain wasmanaged via functional silos with little or no contactbetween them; the support functions did not behave asthough they were actually producing a product for a

Figure 7. Process mappingbefore.


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customerjust a lab analysis or a signed batch record;the financial systems pushed all parts of the supplychain to large supply purchases in order to reap supplierdiscounts

. Root cause analysisthe symptoms revealed by the dataanalysis were root caused with a major issue being thelack of flow in the process and another being the func-

tional behaviour of the various parts of the supplychain. The real problems were identified as: Lack of flow and functional behaviourlack of

connectivity of the supply chain; each step was oper-ated as a distinct entity; functional teams werepraised for functional efficiency even when customerorders were not being filled.

Lack of flowthe system was literally too full. Thewarehouse was full of work in progress; the lab wasoverflowing with samples; the production area con-tained kegs of raw materials and intermediateswaiting to be processed.

Functional behaviourno one person in the supplychain was accountable for the delivery of customer

orders apart from the site director who had nodirect influence on this. Functional effort was see-mingly better whilst overall cycletime got worse.

As a result of the Kaizen event a number of quickchanges were able to take place:

. Communicationthe Kaizen team could see that it madeno sense NOT to communicate with each other moreoftenformal agreements were made (and subsequentlykept!): Production operators were going to speak to the

warehouse each morning to check on key materials. Lab analysts were going to speak to the production

area each day to check on the volume of sampleslikely that day.

. Production and lab stoppagesboth the production areaand the lab had a culture of team breaks which effec-tively stopped value adding activities and reduced thecapacity of the plant; i.e., parts of the supply chainwere identified as the bottleneck (lab) or a near-bottleneck (packaging) The lab agreed to stagger break times for analysts so

that the processing of samples could continue with-out stoppage. The production areas agreed to review the system of

breaks and to ensure that cover was provided to thenear bottleneck process during break periods (thisarea was highly automated and did not have alarge team even through it was one of the most unre-liable areas in the supply chain from an equipmentperspective).

The design phase for the main change project took sometime as it extended to all parts of the supply chain:

. Value streams were formedthese were dedicated to a

family of products with similar manufacturing processesand with similar customer requirements. This impacted the manufacturing, laboratory and

warehouse layout. It changes the whole organization of resources

associated with the product.. Kanbanswere introducedthese were only at key stages

in the overall process but they visually signaled whenproduction was requiredno signal no production. Laboratoryanalysts worked in cells dedicated to

the value stream and within the lab a kanbansystem was set up to ensure that all materials wereavailable for the anticipated volume of samples.The system was very visual.

Manufacturing areaearlier stages in the manufac-turing process were signaled to commence if they

Figure 8. Time-value mappingbefore. . .




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received a visual signal from the kanban (a storagebased visual system as per Figure 5); this wasimportant as they had a capacity far greater thanthe packaging step.

. Visual factory was introducedthis ensured that valuestream KPIs were aligned along the value stream andwere available either in the production area, the lab or

the warehouse. As soon as you entered each area it was clear how

the area was performing; how many samples werebeing processed in the lab; what level of order fulfill-ment to target lead-time had been achieved in thewarehouse; the throughput of the value chain.

Functional measures were no longer used.

Overall the benefits for the organization can be measuredin hard terms:

. Approximately 50% reduction in overall supply chaincycle time (see Figure 9).

. Approximately 25% increase in customer order accuracy

(delivery and quality).. Approximately 30% reduction in inventory (including

safety stock kept due to the inherent inaccuracy insales forecasts).

There are also softer benefits and these should not beforgotten:

. Breakdown of in-company functional barriers.

. Joint development of value stream KPIs with all func-tions buy-in.

Changing the Manufacturing Culture:

Sustaining LeanFollowing the completion of the change project it was

critical that key sustainability measures were tracked:

. Were the new processes being followed?

. Was the layout being kept as per the design?

. Was the visual performance board being used?

A process of hot tagging was used within the value streamto consolidate the culture. This process involved all the teammembers highlighting when a part of the value stream wasnot in alignment, e.g., kanbans being overfilled; sloppyhousekeeping not in line with the 5 Ss (see Table 4).

LOOKING AHEAD: APPLICATION WITHIN THEPROCESS INDUSTRIES

Clearly lean manufacturing has, and could be further,applied within the process industries. The tools and tech-niques described in previous sections can and have beenused within chemicals and pharmaceuticals manufacturing

in the UK.For some parts of the process industries the revolutionhas yet to beginfor others it is a case of expanding leanthinking into all parts of the supply chain.

. To start the implementation of lean thinking: start on a manufacturing process; build a small cross-functional team; ensure senior management demonstrate their

support; ensure that all change is based on a structured data

rational process; communicate success effectively.

. To develop lean thinking further within your

organization: communicate the sustainable successes from theimplementation within manufacturing;

review the value chain for a specific customer or setof customers;

review the business processes as well as the physicalprocesses and apply the same structured data rationalprocess, based on using cross-functional teamsempowered to implement change;

keep looking for waste, keep checking up on thevalue you deliver to customers, keep controllingthe flowmake it a part of your business culture.

CONCLUSIONS

It is clear that the climate for change within the processindustries over the last couple of years has been an opendoor to lean thinkers. We are seeing, and hearing of, moreand more examples of how manufacturing processes withinthe chemicals and pharmaceuticals industries are beingimproved through the use of relatively simple techniques.

It is obvious what lean has to offer the processindustries:

. Performance improvements across the whole supplychain supporting increased business performance.

Ultimately lean will enable UK based manufacturingoperations to compete more globallybut only if thetime, expertise and senior management backing isavailable.

Implementing lean is a revolution but one that the pro-cess industries should be welcoming with open arms. Theleaders of this revolution will have to continue to showby example the financial, cultural and organizationalbenefits of starting down a route of REAL continuousimprovementthis is not an initiative, not a fad, its a phil-osophy which has the potential to transform your business.The data can speak for itself:

. Release of working capital.

. Increased supply chain speed.

. Reduced manufacturing costs.Figure 9. Cycle time reduction results.


672 MELTON


12/12

Lean manufacturing has been applied within the processindustries, most notably chemicals and pharmaceuticalssectors, to great effect. The wider use is increasinglylikely, but more than that it is required!

Lean thinking is applicable to all business processeswithin the process industries. The challenge, if we decidewe want to be lean, is whether we know enough about

our ways of working, what customers of the business pro-cesses truly value, and how our businesses operate andneed to operate.

REFERENCES

Goldratt, E.M. and Cox, J., 1993, The Goal, 2nd edition (Gower Publish-ing, Aldershot, UK).

LERC, 2004, Lean Enterprise Research Centre, Cardiff Business School,www.cf.ac.uk/carbs/lom/lerc.

Melton, P.M., 2003, Agile project management for API projects: getagiledeliver faster, Proceedings of the ISPE European Conference,Brussels, Belgium.

Melton, P.M., 2004, To lean or not to lean? (that is the question), TheChemical Engineer, September 2004 (759): 3437.

PICME, 2004, Process Industries Centre for Manufacturing Industries,www.picme.org.uk.

Rother, M. and Shook, J., 1999, Learning to See: Value Stream Mapping

to Create Value and Eliminate Muda, The Lean Enterprise Institute,Version 1.2.Womack, J.P. and Jones, D.T., 1996, Lean Thinking: Banish Waste and

Create Wealth in Your Corporation (Simon & Schuster, New York,USA).

Womack, J.P., Jones, D.T. and Roos, D., 1990, The Machine that Changedthe World: The Story of Lean Production (HarperCollins Publishers,New York, USA).

This paper was presented at the 7th World Congress of Chemical

Engineering held in Glasgow, UK, 10 14 July 2005. The manuscript

was received 15 December 2004 and accepted for publication 21 March

2005.



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WEB Trish Melton Lean Manufacturing July 2005

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