Study on Developing World-Class Operations

Description
Operations management is integral to the development and delivery of goods and services throughout the global economy. In essence, operations management is about the creation of customer value through the effective and efficient management of processes.

1
DEVELOPING
WORLD-CLASS OPERATIONS
1
O
perations management is integral to the development and delivery of goods and
services throughout the global economy. In essence, operations management
is about the creation of customer value through the effective and efficient man-
agement of processes. Whether we purchase a new automobile, visit a medical clinic, or
converse with friends in other parts of the world via the Internet, processes in the public
and private sectors underpin our daily lives. In a nutshell, processes transform inputs into
value-added outputs using a variety of resources. For example, your presence in Chicago,
an input, might be transformed using such inputs as a mobile phone, fiber-optic cable, cus-
tomer service personnel, and billing systems into your virtual presence a continent away
in London, an output.
For managers, several immediate concerns spring to mind from this general definition
of operations management. How do we define value? How should processes be configured
to be both efficient and effective? Which resources are most critical, and how should they
be managed? How might operations contribute a competitive advantage for the organi-
zation? In fact, it is these pivotal questions that this casebook seeks to explore through
decisions that confronted real managers.
CUSTOMER VALUE
To begin, it is important to identify what we mean by customer value from an operations
management perspective. Customers are interested in a product, which is usually a bundle
of goods and services. At the simplest level, a product might include a physical asset,
such as an automobile, and a straightforward service, such as peace of mind provided
by a 5-year warranty. However, increasing complex product offerings, such as the mobile
phone service described earlier, must synthesize a diverse array of goods and services into
a final product. Thus, value can be defined both in terms of what is offered, as well as how
well particular attributes are delivered.
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Operations management contributes to four general dimensions of customer value:
time, quality, flexibility, and cost. Each of these is considered in multiple case settings
throughout this book. Time captures aspects related to speed, reliability of delivery, and
rapid product and service development. Quality incorporates both the tangible and intan-
gible characteristics related to product or service design and consistency. Like quality,
flexibility also captures elements that are seen by customers, such as the ability to cus-
tomize products and services, as well as those that remain unseen, such as the capacity
to accommodate significant changes in demand. Finally, the last dimension, cost, is not
measured directly by customers but instead is translated by competitive forces into price.
BUILDING BLOCKS OF OPERATIONS MANAGEMENT
Six basic building blocks provide a structured approach for describing, diagnosing, and
improving an organization’s operations (see Figure 1.1). At the foundational level, under-
standing basic drivers of process effectiveness and efficiency explores three critical ele-
ments: process design, planning and control, and project management. At the immediate
level, managers must develop broader systems that transcend and integrate individual
process elements. Two primary systems that deserve much management attention are qual-
ity and supply chain management systems. Finally, the pattern of decisions and actions at
both the process and systems levels must be integrated into a coherent operations strategy,
which in turn is linked to corporate strategy.
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CASES IN OPERATIONS MANAGEMENT
Process
design
Supply
chain
management
Quality
Planning
& control
Operations
strategy
Project
management
Strategies
Systems
Processes
Figure 1.1 Building Blocks of Operations Management
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Drawing on this model, the cases at the end of this chapter overview the basic
challenges and decisions that are explored in much greater detail later in the book.
Chapter 2, “Process Design,” provides more insight into the fundamental structure and
management of processes. Using the conceptual relationship between product volume
and customization as a starting point, the cases in this chapter explore how process-
related decisions often involve trade-offs between two or more dimensions of customer
value. The cases illustrate a conceptual framework that links the concepts of process
capacity, inventory, and variability.
Chapter 3, “Planning and Control,” considers how customer demand drives much of the
planning process for operations resources. Forecasts must be developed, often with very
limited information, and these data can then be translated into both a plan to accommodate
that demand and/or a set of management actions to influence that demand. Once long-term
aggregate plans are in place, management must actively coordinate the use of resources to
meet demand and budget.
Chapter 4, “Project Management,” captures both strategic planning and practical tools
that collectively contribute to effective project management. Understanding these issues is
important for all managers throughout their careers, as much time is usually devoted to
coordinating short-term, team-based projects.
Chapter 5, “Quality,” focuses on defining and controlling quality. In addition, this
chapter emphasizes the importance of the systematic improvement of products (including
both goods and services) and processes. Improvement is undertaken through the adoption
and implementation of a total quality management (TQM) system, which involves align-
ing the entire organization around delivering customer value. Although the definition of
quality may differ between manufacturers and services, the strategic elements and quality
tools of TQM are the same in both operational contexts.
Chapter 6, “Supply Chain Management,” concentrates, from a total systems perspec-
tive, on the efficient and effective flow of information, materials, and services from raw
materials suppliers, to production facilities, to distributors, to end customers. Supply chain
management requires the timely coordination of upstream and downstream activities, and
many organizations have achieved significant strategic, financial, and operational advan-
tages through better configuring and managing their supply chains. Some of these opera-
tional advantages have included reductions in inventory levels and investment, as well as
increased delivery reliability and responsiveness.
The final chapter, “Operations Strategy,” involves the combination and synthesis of
operating processes and systems to gain a competitive advantage. Managers in manufac-
turing and service organizations have recognized the criticality of developing effective
operations, as well as the need to actively manage many of the process and system ele-
ments introduced in earlier chapters. Operations strategy also bridges between systems
and the broader corporate strategy. Organizations that successfully develop and manage
their operating resources in an integrated manner are likely to achieve an enviable strate-
gic advantage and, in some cases, world-class status.
WORLD-CLASS OPERATIONS
World-class operations is more than simply understanding the six building blocks of
operations. And it is more than developing and maintaining a reputation for offering solid
customer value. Organizations also must assess the business setting with their operational
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capabilities to identify emerging and unfilled market opportunities that leverage existing
strengths. Moreover, it is critical to recognize when competitive forces dictate the adapta-
tion of existing operational capabilities or the development of new ones.
Thus, world-class operations demonstrate industry leadership. New operational capa-
bilities must be developed ahead of the competitors, and operations must be leveraged to
deliver superior value over the long term (see Figure 1.2). This emphasis on operations
is a key opportunity to build a strong competitive advantage. For example, organizations
described in later cases, including Spin Master Toys, Electrosteel Castings, ASIMCO,
and the Atlanta Symphony Orchestra, are making great strides toward building such
capabilities.
As you move through the initial introductory cases in this chapter and the six chapters
that follow, two central concepts will emerge and continue to be reinforced. Both concepts
are crucial for every manager to understand about operations. First, operations must be
actively designed and managed to deliver and enhance customer value. Identifying impor-
tant managerial levers helps us to do this. Second, building world-class competitiveness
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CASES IN OPERATIONS MANAGEMENT
Process
design
Supply
chain
management
Quality
Planning
& control
Operations
strategy
Project
management
C
o
m
p
etitive environ
m
e
n
t
Building value
Systems
Processes
Strategies
Figure 1.2 Building Value With World-Class Operations
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is possible through operations; however, it is not a static competence focused on a single
dimension, but rather a dynamic set of capabilities that improve and evolve over time
across multiple dimensions.
INDUSTRIE PININFARINA: THE NEW CUSTOMER DECISION
Pininfarina SpA, a renowned Italian manufacturer and designer of niche vehicles for major
automobile companies, has traditionally competed on flexibility using a highly skilled
design and manufacturing workforce and low levels of automation. However, the European
auto market is threatened with a shakeout. Renato Bertrandi, manager of operations, must
decide whether to accept an offer from Mitsubishi to become the exclusive European man-
ufacturer of a sport utility vehicle. The order would more than double the company’s
manufacturing volume and relieve pressure to replace models currently in production.
However, the fit of the order with existing manufacturing strategy is poor, and major
changes in facilities and equipment as well as people and systems would be required.
Key learning points: introduce the basic concepts underlying operations strategy, exam-
ine industry-level evolution, and explore the dynamic nature of operations capabilities.
FELL-FAB PRODUCTS (A)
Fell-Fab Products is a Canadian manufacturer of interior coverings for airlines, bus com-
panies, and passenger rail services. Glen Fell, president of Fell-Fab Products, was recently
approached by a key customer with a request to expand its product offerings into servic-
ing all aspects of the interior coverings business. However, Fell was unsure whether this
new service dimension fit, if at all, with existing capabilities, what the financial returns
might be, or how to best leverage this opportunity.
Key learning points: examine product, process, and strategy differences for manufactur-
ing and service operations; identify strategic opportunities for product bundles of goods
and service; and understand the rationale for business process outsourcing.
UNICON CONCRETE PRODUCTS (H.K.) LTD.
Unicon supplies precast concrete products to the flourishing construction market in Hong
Kong. Herman Li, deputy managing director, is evaluating an opportunity to pursue a “blan-
ket” regulatory approval for Unicon’s custom-designed concrete products with its largest
customer, the Hong Kong Housing Authority. This opportunity promised to offer cost
savings to both Unicon and this customer, although questions remain about the broader
implications for Unicon’s manufacturing operations and other customers. At the same time,
Li must develop a plan to expand its manufacturing capacity if Unicon hopes to capitalize
on the rapidly expanding market and fend off new competitors from mainland China.
Key learning points: compete on dimensions of customer value, understand product and
process relationships in operations, develop congruence between operations and market-
ing, and adapt to low-cost competition.
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MANAGEMENT QUESTIONS ADDRESSED IN
DEVELOPING WORLD-CLASS OPERATIONS CHAPTER
1. How is customer value defined? How does customer value prioritize price, quality, time, and
flexibility?
2. What operational decisions must managers typically make, and what is the operations
challenge? What are the real problems, opportunities, and issues, and what are merely the
symptoms?
3. What are the basic elements of an operations strategy? How is it linked to corporate strategy?
To the competitive setting?
4. What forces push management to change an organization’s operational capabilities? How
quickly can these capabilities be changed?
5. What drives the cost structure for operations? Which costs are fixed? Which costs are
variable?
6. How important are labor versus material versus capital costs?
7. What criteria should be used to make a decision? Along what dimensions of customer value
are trade-offs necessary?
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CASES IN OPERATIONS MANAGEMENT
INDUSTRIE PININFARINA: THE NEW CUSTOMER DECISION
Neil Jones
Copyright © 1997, Ivey Management Services Version: (A) 2001-05-17
The 25th of April is a national holiday in Italy, but
it was not for Industrie Pininfarina (Pininfarina)
top management in 1996. A meeting between
Pininfarina and high level Mitsubishi executives
lasted the entire day. The following day, a Friday,
Renato Bertrandi, manager of operations at
Pininfarina, sat in his office at the Pininfarina
plant at Grugliasco, in the Piedmont region of
Italy. In a rare quiet moment, he reflected on the
challenges that lay ahead for the manufacturing
operations. On Monday, he would recommend
whether Pininfarina should accept European
manufacturing responsibility for a new vehicle,
the Mitsubishi Pajero. The vehicle presented both
a major opportunity and a significant commit-
ment, which would impact Pininfarina’s fortunes
through the year 2004 and beyond and it would
require major changes in manufacturing. The
contract would virtually double Pininfarina’s
output.
Once again, Bertrandi thought through the
company’s options and tried to evaluate the
near-term benefits and challenges to manufac-
turing as well as the longer-term consequences.
He thought with satisfaction about the many
achievements in manufacturing since the 1980s.
An active triathlete, he wondered where the
next phase of the competitive race in the chang-
ing global automotive industry would leave the
company.
PININFARINA BACKGROUND
In 1904, at the age of eleven, Battista “Pinin”
Farina began work in his brother’s coach-making
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business—which also specialized in making
seats for racecars. After long experience in the
emerging and rapidly expanding Turin auto-
mobile industry, he founded his own company
in 1930. Farina specialized in the design and
production of custom and small series auto-
mobiles. While he expected to build relatively
few “special” cars and was rooted in a tradition
of highly skilled craftworkers, he was much
impressed with the Ford system, which he had
seen on a plant tour in the United States in 1920.
The visit contributed to his conclusion that he
had to draw on the strengths of Ford’s method to
be successful. As he would later say,
I was looking for a third state, between the craft
we had to leave behind and industry. The state had
to have industrial norms and structures but it must
not suffocate that individual reality, which can be
defined as style. There was no tradition to which
we could appeal, our occupation was brand new
and we paid for any mistakes we made in person.
The company soon earned a reputation for
the quality and beauty of its designs. By 1939,
Farina Industrie employed over 500 workers
and manufactured close to 800 automobiles.
For a period of time during World War II, the
company product line included ambulances, air-
line seats, and stoves, but it returned to a focus
on automobiles after the war ended. And it was
in automobiles where it continued to find its
greatest success—producing revered designs
such as the Ferrari Berlinetta Dino and the Alfa
Romeo Spider Duetto (Exhibit 1). Farina’s
Cistalia automobile, designed in 1947, was cele-
brated in a collection of mobile sculptures at
New York’s Museum of Modern Art.
In 1954, after the great success of the Alfa
Romeo Spider, the company added facilities to
manufacture lower volume cars for major auto-
mobile manufacturers. To handle an increasing
demand, in 1958 the company moved from
Turin to a manufacturing plant in Grugliasco,
a nearby suburb. Upon Farina’s death in 1966,
management of the business was taken over by
his son, Sergio, and his son-in-law, Renzo
Carli. The family name and that of the business
were changed from Farina to Pininfarina by
presidential decree.
Throughout the 1960s and 1970s Pininfarina
continued to design and produce unique auto-
mobiles such as the Ferrari Berlinetta, the Lancia
Flaminia, the Austin A 40, and the Morris 1100.
By 1972, the company employed about 1900
people and was producing more than 23,000 cars
per year. In 1979, Pininfarina split its design and
manufacture divisions into Pininfarina Studi E
Ricerche and Industrie Pininfarina (IPF), under
the holding company Pininfarina S.p.A. In 1986,
30 per cent of the company’s shares were listed
and sold on the Italian stock market, and a
further three per cent of shares were sold to
Mediobanca. However, the company remained
closely held by the Pininfarina family who
retained 67 per cent.
THE NICHE MANUFACTURER
Pininfarina was considered a niche car manufac-
turer. Niche manufacturers were chiefly distin-
guished by their low production volumes, which
were often sub-contracted from a volume manu-
facturer. In Pininfarina’s case, typical production
volumes ranged from only one or two cars per
day (for example, the Bentley cabriolet) to per-
haps 50 to 60 cars per day for “special” sedans
such as the Fiat coupe (Exhibit 2). In contrast,
volume manufacturers might produce a thousand
cars per day or more at a factory dedicated to just
a few models or even one model.
However, not all volume manufacturers
were the same. In the early 1990s, Japanese
manufacturers on average produced around
70,000 cars per model per year, while an average
European or American manufacturer produced
around 200,000 per model per year. Japanese
producers also had shorter model lives at around
three years, while European producers had been
averaging four to seven years of model life.
Bertrandi felt that the best Japanese volume
producers were profitable on very much lower
production volume per model than even the
Japanese average. One Japanese producer had
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CASES IN OPERATIONS MANAGEMENT
Alfa Romeo Spider Duetto
Ferrari Berlinetta Dino
Exhibit 1
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Fiat Coupé
Bentley Azure
Exhibit 2
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told him that it would not consider outsourcing
production volumes of greater than 5000 cars per
year. In contrast, Pininfarina had produced over
17,000 Fiat Coupes in 1994.
Volume producers could apply considerable
pressure to niche producers to keep prices low.
Usually, they had detailed knowledge of the
product and production processes associated
with a model and often had their own experience
with part of the process. Further, a given volume
producer was usually a vastly larger company
and represented a high percentage of the niche
manufacturer’s total business. Volume producer
bargaining power was, therefore, high and niche
manufacturer margins were narrow, especially
during industry downturns. In general, margins
were higher for fully assembled vehicles, and
these offered more scope for production cost
reductions to be achieved and captured by niche
manufacturers. Profit margins for niche manu-
facturers were typically in the range of two to
four per cent of the target unit manufacturing
cost.
Advantages of Niche Production
Niche manufacturers provided three principal
advantages to the volume producers who per-
formed their own assembly for the vast majority
of their production: niche manufacturers had
lower total costs for cars made at low volumes,
they could accept higher levels of volume
uncertainty and their product designers brought
both superior designs and famous brand names
to volume producer models.
First, niche manufacturer costs for small-
volume products were lower than those usually
achieved by volume assemblers. At low daily
production rates, typical volume producer
process designs were too expensive to imple-
ment. A typical volume producer might have
capital and other fixed costs that were more than
twice the level of a niche manufacturer. Niche
manufacturers were forced to limit capital invest-
ments that were specialized to a particular model
because the costs had to be amortized over fewer
cars. As a result, niche manufacturers designed
production processes that used general purpose
equipment and required fewer dies, jigs and other
specialized tools. Usually they had fewer mechan-
ically performed operations and lower levels of
automation.
To achieve lower capital costs, a niche
producer was also skilled in making tradeoffs
between what could be accomplished by machine
and what could be done by hand. Bertrandi
explained:
It is mainly our engineering that provides an
advantage. We get the product to 90 per cent with
our process and compensate with skilled labor
to provide the last 10 per cent. For example, we
might decide to stamp a door in three stages
instead of the four a volume producer would use.
This can result in some small waves in the door
metal, but we can correct this by adding five
minutes of additional handwork. This can work
at a production of 30 cars per day, but it would be
suicide at 1,500 cars per day.
A more highly skilled workforce than that
typically found at a volume producer was used
to assemble parts and ensure quality in fit,
finish and function. Many niche producers did
not use a continuously moving assembly line.
The variety of work performed at each station led
Pininfarina, for example, to design a stop and
go process, with a time between moves that
might vary from about 10 minutes to about half
an hour, and even up to eight hours, depending
on the volumes needed.
Niche manufacturers sometimes based their
product and process designs on modifications to
a higher volume design that was being produced
at a major automobile assembler. Often, such
modifications required more skill of the work-
force than would be required if a similar product
had been designed from scratch. For example,
Pininfarina production of the Peugeot 406 coupe
was based on a sedan model produced at
Peugeot. Pininfarina took bodies supplied by
Peugeot and inserted a stamped part that altered
the slope from the roof to the trunk lid in the
rear. This alteration demanded a critical hand
weld at the intersection of the mass-produced
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and niche-produced metal parts. Achieving
proper part position and a strong, flat weld,
which could be properly finished, was essential
to ensure quality in this operation. The higher
proportion of labor required imposed an addi-
tional cost of some four to eight labor hours per
car for a niche manufacturer.
The second advantage of niche manu-
facturers was flexibility. Consequently, they
were often given contracts on models that had
higher than usual volume uncertainty and larger
seasonal fluctuations in sales. For example, a
convertible or cabriolet might have sales in
the spring that were 150 per cent of the low sales
in winter. Lifetime sales and the model life
of highly specialized niche vehicles were also
highly uncertain, as such products were aimed
at narrow consumer segments that were difficult
to specify and had rapidly shifting tastes. Some
of the risks associated with such products could
be shifted to niche producers. Contracts typi-
cally did not fully compensate niche producers
for the costs of unanticipated volume fluctua-
tions on a seasonal or overall basis. Uncertainty
over model life complicated niche manufac-
turer planning for new model introductions,
as, for example, models with low sales might be
discontinued.
Niche manufacturers coped by configuring
their facilities to be flexible and by devel-
oping elaborate contingency plans. Contingency
planning allowed the niche producers to rapidly
shift workers from one line to another as
demands fluctuated. For example, work at a
given station, which might be carried out by a
team of five during high volume periods, could
be reduced to a team of two when volumes were
low. Fewer people at a station meant that each
worker had to perform a greater number and
variety of the operations needed, and it usually
increased station time so that the line moved
more slowly. The line also had to be rebalanced
so that each work station’s output rate was
matched to keep worker idle time to a minimum.
A line that needed a higher output rate would
have more workers at a station and would assign
fewer and narrower tasks to each worker. When
necessary, workers could be temporarily laid off
or could be asked to work overtime.
The third benefit provided by niche manufac-
turers was highly competent and often renowned
design skills in product and process. Design ser-
vices were an independent source of revenue
for some niche manufacturers. At Pininfarina in
1994, design and engineering revenue totalled
nearly £90 billion
1
and was growing rapidly.
Work might be performed for a production
model or for prototype cars, which might never
go into production. Although manufacturing
contracts were not always awarded for suitable
models that had been completed by niche manu-
facturers, participation in design significantly
increased the chance of winning manufacturing
business.
Close links and effective joint problem-
solving between design and manufacturing were
considered a major advantage in the success
of a new car model. Some designers, such as
Pininfarina and Bertone, had widely recognized
brand names. These brands were believed to
command premiums and suggest luxury, fashion
and high performance. Although Pininfarina’s
major customers, Fiat and Peugeot, reported that
they made little, if any, money on niche models,
Bertrandi suspected their calculations excluded
the positive impact of image and the attraction
of niche cars in pulling potential buyers of other
cars to showrooms.
PININFARINA POSITION IN THE 1990S
After relatively high profits in the late 1980s,
the European auto market became less hospitable
in the 1990s. Industry returns on net assets fell
from their 1980s high of 10 per cent to 15 per
cent to below five per cent on average in the
1990s. In the view of many, the primary problem
was capacity utilization, which had averaged
below 75 per cent from 1990 to 1995.
Over-capacity was partly the result of low
underlying growth in the Western European
consumer base and partly due to the addition
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of new factories by globalizing competitors. The
spread of more efficient manufacturing practices,
which had been pioneered by Japanese firms,
also contributed to capacity growth. Although
shares had been relatively stable overall, “volun-
tary” Japanese restraints on European market
share were due to expire by the year 2000 in
many large markets and Korean firms had begun
to build a large European presence. In markets
without restraints, Japanese producer shares
were considerably higher than in markets with
them. Exhibit 3 shows industry sales and share
in Western Europe in the 1990s, and Exhibit 4
shows data on customer satisfaction. At the
beginning of the 1990s, European producers had
lagged behind other global competitors in some
key areas of performance, and despite improve-
ments were not believed to have fully closed the
gap. Exhibit 5 shows comparative regional data.
Manufacturing
Operations at Pininfarina
As it entered the 1990s, Pininfarina produced
both bodies and fully assembled cars at two major
production facilities, one in Grugliasco and the
other at San Giorgio, about 40 kilometres away.
The Grugliasco complex housed a full-scale wind
tunnel test facility, which had been one of the first
of its kind in the world. Production at Grugliasco
was divided among three major buildings. In one,
parts stamped by Pininfarina’s suppliers were
welded together to form the basic “Body in
White” (BIW), so named because the completed
bodies were not yet painted. Suppliers made
stamped parts to specifications set by the design-
ing firm—often, but not always Pininfarina Studi
E Riserche. The stamping process itself—the
sequence of steps whereby the metal was formed,
was typically specified by Pininfarina process
design engineers.
A second building contained the paint shop,
which painted all production models. The paint
shop performed six major steps, some separated
by drying phases. In the paint shop, the bare steel
was first galvanized, then phosphate-coated and
given an electrostatic treatment. Next, a primer
was applied and then a base coat, before a final
clear coating completed the process. The paint
shop had been upgraded in stages beginning
in 1985 at a total cost of some £100 billion. It
was initially designed for a capacity of 100 cars
per shift, but its capacity had been increased
to 140 cars per shift and then 160 cars per shift.
Throughput time was about seven hours.
The limited number of models produced by
Pininfarina came in a total of 52 possible colors.
The paint shop could change colors in about
one minute, but required some manual setup to
paint a specific model. At each arrival, the
paint shop changed colors and set up for the
appropriate model. Some cars, which needed
special painting processes, were painted in a
special area. The Rolls-Royce Bentley model,
for example, required multiple steps of coating
and surface preparation to achieve an adequate
finish. About 100 hours of labor were required.
The last step—the trim facility—installed all
the rest of the parts needed to form the complete
automobile. Here, engines, suspension and other
mechanical parts from suppliers were installed,
as were details of interior and exterior finish—
from door seals, seats and instrument panels
to exterior mirrors and bumpers. Trim steps
were greatly complicated by the wide variety
of options that were supplied to customers. For
example, each Fiat model came with a choice of
five different engines, and each was configured
slightly differently in the engine compartment.
Interior options and other options also increased
the complexity of process control in assembly
and resulted in inventory levels higher than
comparable higher volume facilities. At San
Giorgio, a more modern trim facility had been
built in 1985 primarily for the Cadillac Allante
business. Pininfarina’s test track was also located
at San Giorgio.
Improvements in the 1990s
In 1992, Pininfarina faced a crisis. Production
of bodies for the Cadillac Allante and Peugeot
205 and assembly for the Alfa Romeo Spider
were being rapidly phased out, while volume
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Exhibit 3 Western European Manufacturer Share of Total Number of Vehicles (in per cent)
Source: Company Files.
*Includes Innocenti, Ferrari, and Maserati after 1993
**Includes Maserati after 1991
***Part of BMW Group after 1991
Manufacturer 1990 1991 1992 1993 1994 1995
VW Group 15.6 16.4 17.5 16.4 15.8 16.7
General Motors Group 11.3 12.1 12.4 13.0 13.1 13.1
Opel/Saab/GM 11.3 12.1 12.4 13.0 13.1 13.1
Lotus 0.01 0.01
Peugeot-Citroen 12.9 12.1 12.2 12.3 12.8 12.0
Peugeot 8.2 7.6 7.4 7.4 7.7 7.0
Ford Group 11.6 11.7 11.3 11.3 11.9 11.9
Ford 11.4 11.7 11.2 11.2 11.8 11.7
Jaguar 0.1 0.1 0.1 0.1 0.1 0.1
Fiat Group 14.2 12.8 11.9 11.1 10.8 11.1
Fiat* 10.3 9.3 8.8 8.3 8.6 8.7
Lancia 2.3 2.0 1.7 1.6 1.4 1.4
Alfa Romeo 1.5 1.4 1.2 1.1 0.8 1.1
Innocenti 0.06 0.11 0.10 0.11
Ferrari** 0.019 0.021 0.023 0.018
Maserati 0.015 0.011
Renault 9.8 10.0 10.6 10.5 11.0 10.3
Mercedes 3.3 3.3 3.0 3.1 3.5 3.4
BMW 2.8 3.1 3.3 3.2 3.3 3.3
Rover*** 2.9 2.6 2.5 3.2 3.3 3.1
Nissan 2.9 3.3 3.2 3.5 3.2 3.0
Toyota/Lexus 2.7 2.7 2.5 2.7 2.6 2.5
Mazda 2.1 2.1 2.0 1.7 1.5 1.4
Volvo 1.8 1.5 1.5 1.5 1.7 1.8
Mitsubishi/DMS 1.3 1.4 1.2 1.2 1.0 1.1
Honda 1.2 1.3 1.3 1.4 1.4 1.5
Hyundai 0.1 0.3 0.6 0.7 0.7 0.8
Suzuki/Maruti 0.7 0.7 0.9 0.9 0.7 0.8
Chrysler 0.3 0.3 0.3 0.5 0.5 0.6
Subaru 0.4 0.4 0.3 0.4 0.3 0.3
Porsche 0.1 0.1 0.1 0.1 0.1 0.1
Others 2.0 1.8 1.5 1.2 0.9 1.4
Total 100 100 100 100 100 100
As Per cent of 1990 100 102 102 86 90 91
Total Vehicles 13,258,807 13,504,345 13,497,536 11,428,352 11,910,952 12,012,415
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CASES IN OPERATIONS MANAGEMENT
Problem Incidence/
Overall Index Parts/Service Resolution
Subaru 142 145 150
Honda 141 151 145
Daewo 140 134 89
Mazda 137 136 145
Toyota 137 142 141
Jaguar 136 158 118
Nissan 136 127 138
BMW 132 157 121
Daihatsu 130 129 137
Mercedes 128 159 131
Mitsubishi 124 117 129
Saab 124 139 112
Audi 119 109 118
Suzuki 116 101 122
Volvo 115 116 103
Hyundai 111 102 95
Renault 106 107 109
Volkswagen 105 104 105
Citroen 100 97 96
Rover 100 108 95
Peugeot 99 96 98
Fiat 95 88 94
Alfa Romeo 94 74 80
Ford 78 72 79
Lada 62 81 28
Total Industry 100 100 97
Exhibit 4 Customer Satisfaction Survey Sample Results by Make (United Kingdom Data)
Source: Company Files.
Japanese Japanese in American in
in Japan North America North America All Europe
Performance
Productivity (hours/vehicle)* 16.8 21.2 25.1 36.2
Quality (assembly defects/100 vehicles) 60 65 82.3 97
Layout
Space sq. ft./vehicle/year 5.7 9.1 7.8 7.8
Size of repair area (as % of assembly space) 4.1 4.9 12.9 14.4
Inventories (days) 0.2 1.6 2.9 2
Workforce
% of workforce in teams 69.3 71.3 17.3 0.6
Job rotation (0 = none, 4 = frequent) 3 2.7 0.9 1.9
Suggestions/employee 61.6 1.4 0.4 0.4
Number of job classes 11.9 8.7 67.1 14.8
Training of new production workers (hrs) 380.3 370.0 46.4 173.3
Absenteeism 5 4.8 11.7 12.1
Automation
Welding (% of steps) 86.2 85 76.2 76.6
Painting (% of direct steps) 54.6 40.7 33.6 38.2
Assembly (% of direct steps) 1.7 1.1 1.2 3.1
Exhibit 5 Summary of Assembly Plant Characteristics: Volume Producers (1989)
Source: Womack, J. P., D. T. Jones, et al. (1990). The Machine that Changed the World. New York, Rawson Associates.
*Includes all labor within factory walls.
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replacement sufficient to maintain existing
production levels had not yet been committed
for new models (Exhibit 7, see p. 17). The
shortfall eventually left 1993 production at less
than 50 per cent of the average level for the
1990s to that point. Margins were also squeezed
as European prices fell. Customers had begun to
press for operational improvements in quality,
cost and deliverability.
Further, the company had by now concluded
that despite some recent operational improve-
ments, more fundamental and far-reaching
changes to improve its manufacturing perfor-
mance would be necessary to ensure future
viability. Faced with deteriorating financial
results, Pininfarina laboriously negotiated with
its unions. The resulting accord, signed on July
28, 1992, was viewed by many as a new model
for Italian labor relations. It called for the early
retirement and “temporary” layoff
2
of some 435
blue-collar employees—50 per cent of the total
workforce.
Workforce and Quality Initiatives
Two major changes were introduced with
the new accord, designed to allow Pininfarina
to improve its operations to near Japanese
levels, while adapting to Italian conditions. First,
Pininfarina introduced a work team system
modelled on the Toyota NUMMI plant in
California, including systems to track morale
and elicit suggestions for improvement. Second,
a program of training for shop-floor workers was
instituted. The training program had two major
components. First, skills were built in specific
operations and techniques (for example, statistical
process control and problem-solving techniques).
Second, workers were given interpersonal skills
training intended to develop the capability of the
workforce to work in teams (doubts had been
expressed about the potential for Italian workers
to submerge a pride in individuality to the con-
straints of teamwork). A training program for new
workers was also instituted.
The training programs were a complement to
an expansion of the quality initiative that had
been underway since the middle 1980s. Renato
Bertrandi had originally joined the company in
1986 as a manager of quality control, reporting
to the general manager. After the accord of 1992,
the quality control function reported to Bertrandi
himself at the operations manager level.
Pininfarina, while adopting some of the
methods and practices of the quality movement,
decided to adapt the philosophy to Italian and
niche producer conditions. Renato Bertrandi
explained:
As a first step in our situation, it is better not to stop
the line for most types of problems. Stopping the
line lowers our production and costs us more. It is
better for us to have highly skilled people at the
end of the line fixing problems after they have
occurred. Of course, we also ask workers to iden-
tify problems they can’t fix on the line and work
to remove the source of some problems. I realize
this violates the philosophy of lean production, but
it doesn’t pay to fix the root causes of all of our
problems now. This will be our next step.
Supplier Development
At about the same time, and in concert
with the quality program, major programs were
also initiated in supplier relations. In 1991,
Pininfarina had about 650 suppliers. Typically,
competitive bids were held among suppliers
who were asked to meet Pininfarina’s pre-
determined design specifications. Volumes were
then split among several suppliers. By 1993, the
number of suppliers had been reduced to
350, despite a major decision to outsource the
stamping operations, which had been lagging
in the capital investment required to keep them
competitive. This reduction was achieved by
concentrating volumes in fewer, more capable
suppliers, with whom Pininfarina worked more
closely—even doing joint design work and parts
planning.
Major efforts had been made with the reduced
number of suppliers to increase the frequency of
deliveries, to correspondingly reduce their size,
and to increase quality while decreasing the total
amount of combined inspection. In the 1980s,
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CASES IN OPERATIONS MANAGEMENT
incoming parts inspection employed 70 people
to inspect all incoming supplier parts. In 1993,
30 people inspected only about 20 per cent of
the incoming parts. Pininfarina also believed
purchase prices and inventory levels had been
improved.
By 1996, the number of suppliers had
increased again to 450, driven by the new pro-
duction models and a shift in mix toward the
assembly of complete vehicles. This trend had
been offset slightly because new business was
with existing customers who had substantial car-
ryover of existing suppliers and similar needs.
About 25 people were needed to manage these
suppliers. Pininfarina could control the choice of
supplier for about half of its purchase monetary
volume and could negotiate freely on price for
about two-thirds of its volume. The other one-
third came mostly from major customers, who
were also major parts suppliers.
The progress of Pininfarina in achieving
improvements in some key operating parame-
ters is shown in Exhibit 6, and financial results
and operating statistics are shown in Exhibit 7.
Bertrandi was pleased with the fact that of
the 20 per cent of cars produced that did not
go immediately to a buyer, only 10 per cent
of these were due to quality problems. The
remaining 90 per cent were due to parts short-
ages of one type or another, typically the result
of last-minute changes in option mixes in the
production schedule and a consequent shortage
of the correct part.
Search for a New Customer
Budgeted improvements called for further
increases in the productivity of direct labor of
three per cent annually. To utilize the extra capa-
city created by productivity improvements, to
1992 1996
Performance
Productivity* (hours/vehicle) 60 42.5
Rework Cost** (% of Total) 12 ? 15 9
Layout
Space sq. ft./vehicle/year 380.25
Size of repair area (as % of assembly space) N/A
Inventories (days) .5 ? 3
Workforce
% of workforce in teams 0.25 95
Job rotation (0 = none, 4 = frequent) 3 2.7
Suggestions/employee 0 0.1
Number of job classes 4
Training of new production workers (hrs) N/A
Absenteeism 7.7 6
Automation
Welding (% of steps) 5 5 ? 34
Painting (% of direct steps) 35 40
Assembly (% of direct steps) 5 5
Exhibit 6 Pininfarina Assembly Characteristics
Source: Company Files.
*Includes all labor within factory walls.
**Includes cost of rework labor and materials only.
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Developing World-Class Operations
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17
1989 1990 1991 1992 1993 1994 1995
Sales (group total in billion lira) 372.0 479.5 501.9 412.4 417.2 731.4 670.0
Expenses:
Purchases & Services 270.7 258.7 175.2 201.0 556.6 410.4
Labor Cost 77.6 89.4 97.4 93.5 83.6 116.6
Depreciation 14.6 13.6 16.2 13.5 16.2 18.2
SG&A 92.7 113.4 121.8 98.0 72.5 117.1
Total Expenses 357.6 455.6 475.0 410.6 406.0 728.9 662.3
Operating Income 14.4 24.0 27.1 1.8 11.2 2.5 7.7
Production Model Mix 1989 1990 1991 1992 1993 1994 1995
Assembled Vehicles
Lancia Thema SW/K SW 3,010 3,456 2,536 1,894 1,310 806 0
Alfa Romeo Spider 3,978 7,106 9,073 3,640 1,956
Fiat Coupe 276 17,332 12,500
Bentley Azure 3 170 250
Peugeot Coupe
Total Assembled Vehicles (Units) 6,988 10,562 11,609 5,534 3,545 18,308 12,750
Total Revenue - Assembled 153 237 252 142 104 426 312
Vehicles (billion lira)
Revenue Per Assembled 21.9 22.4 21.7 25.7 29.3 23.3 24.5
Vehicle (Million Lira)
Bodies
Ferrari (Testa Rossa, 512TR, 456GT) 1,207 1,312 1,565 870 306 625 600
Cadillac 3 3,775 2,495 2,660 1,978
Peugeot 205 cabriolet 9,303 11,051 12,982 l1,718 3,450 784
Peugeot 306 cabriolet 414 11,154 11,600
Total Bodies 13,565 16,138 17,042 15,248 6,148 12,563 12,200
Total Revenue - Bodies (billion lira) 157 172 167 160 85 143 153
Workforce 1989 1990 1991 1992 1993 1994 1995
Direct Workers 803 964 889 846 824 927 864
Indirect Workers 443 444 431 408 352 351 344
Total Workers 1,246 1,498 1,320 1,254 1,176 1,278 1,208
Exhibit 7 Pininfarina Data
Source: Company Files.
Note: US$1 = £1,600 (Approximately)
leverage its newly achieved production skills, and
to diversify its risk of lower future volumes from
current customers, Pininfarina decided to seek a
third major customer in late 1994. Although some
production of new models from existing cus-
tomers would begin in 1996, these volumes would
be insufficient to replace the production that
would be phased out by the year 2000. The typi-
cal lead-time from the beginning of design until
the first production vehicle was 38 months.
Pininfarina actively marketed itself in the
auto industry for new business in product design
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CASES IN OPERATIONS MANAGEMENT
and manufacture, sometimes proposing joint
development of prototype design projects for
niche vehicles to volume manufacturers. Such
projects were a source of profit to Pininfarina’s
design division and could result in new manu-
facturing work for vehicles that were to go into
production. Although at present, only the
Peugeot 406 had been wholly designed at
Pininfarina, the interior of the Fiat coupe had
been a Pininfarina design, and Pininfarina had
competed with Fiat’s internal designers for the
exterior as well. Bertrandi felt that the present
low level of relationship between manufacturing
and design projects at Pininfarina was unusual
and did not represent a trend among volume
manufacturers to make the two functions more
independent of one another.
Pininfarina had worked with Peugeot’s
styling centre to create all of its major models
since the middle 1950s and had regularly per-
formed work for Fiat for an even longer time.
In addition, General Motors had been a large
customer. While the identity of niche manufac-
turers’ design customers was a closely guarded
secret, outside investment analysts’ reports
stated that Mercedes, BMW, Porsche, and
Honda were among Pininfarina’s current design
and development customers. Analysts had
anticipated the announcement of a major new
manufacturing customer in 1995, but, as yet,
no firm commitments from those prototyping
and developing cars with Pininfarina had
been received. Pininfarina’s prospects for a new
niche vehicle-manufacturing customer remained
good, however.
THE NEW CUSTOMER DECISION
Following a marketing contact with Mitsubishi
proposing a niche vehicle product design pro-
ject, in July 1995 Pininfarina was surprised to
receive a counterproposal from Mitsubishi.
Mitsubishi proposed that Pininfarina be the
manufacturer of one of their sport utility vehi-
cles, the Mini Pajero, which was to be marketed
in Europe and Asia. A Pajero built in Japan was
being successfully sold in Europe. A new model
was already designed to the prototype stage and
would be introduced first in Japan, in 1998.
Vehicles for Asian sales would be manufactured
by Mitsubishi; however, Mitsubishi proposed
that Pininfarina adapt the design and manu-
facture in Italy for all of Europe. The major
design work would be in adding a left-hand drive
model and in adapting the process design to
Pininfarina’s capabilities. Bertrandi was particu-
larly surprised at this offer since to that point,
Mitsubishi had not asked to visit or inspect
Pininfarina’s factories—a common practice of
volume manufacturers, who wished to verify
Pininfarina’s manufacturing capabilities. Beyond
the excellence of Pininfarina’s reputation and
recent performance improvements, Bertrandi
suspected that Mitsubishi had factored Italy’s
relatively low automotive labor costs into their
choice. Bertrandi believed these were one-half
Germany’s levels (see Exhibit 8).
The details of the Mitsubishi proposal had not
been fully specified, but the basic characteristics
of the proposal were clear. Based on previous
experience Bertrandi believed any decision to
proceed would be taken with many details not
completely specified. Mitsubishi proposed that
by no later than May 1999, Pininfarina should
begin volume production in Europe of the new
model, after a three-month trial and debugging
Germany 62.44
Belgium 44.6
Sweden 41.8
Japan 41.56
United States 38.52
Netherlands 34.75
France 33.08
Spain 28.06
Italy 27.79
United Kingdom 27.08
Exhibit 8 1996 Labor Costs in the Auto
Industry (DM per hour)
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period. Production would be at a rate of about
150 vehicles per day. Mitsubishi would pay
Pininfarina a standard margin on a target
cost that would be based on Mitsubishi’s own
experience in producing the model in Japan and
correction for differing process, parts and trans-
portation costs. The standard margin had not
been set, but it was clear it would be low—
perhaps one-half of the two to four per cent
margins Pininfarina earned on its current pro-
duction contracts. Bertrandi believed that if
Pininfarina could achieve production costs below
Mitsubishi’s target, Pininfarina would be able to
keep the additional profit.
Mitsubishi would guarantee that total volumes
would be at least sufficient for Pininfarina to
recoup any model-specific capital costs. How-
ever, Pininfarina would have to bear the risk of
investment in general purpose equipment such
as the basic facilities themselves or robots,
which could be used for other purposes. The
exact guaranteed volume would be calculated
on the basis of the standard margin that was
allowed Pininfarina by the production contract.
Total investments were expected to be £300
billion. General purpose capital equipment for
a new model was usually in the range of 10 to
15 per cent of total investment. As Mitsubishi
had roughly a three per cent share of the global
automobile market, and over US$20 billion in
worldwide sales, Pininfarina management had
few doubts as to Mitsubishi’s ability to meet its
commitments.
The term of the production phase would be
five years, expiring in 2003, with no obligations
on either side to continue the arrangement with
other models or services, beyond those which
might be part of the Pajero contract such as
warranty obligations or spare parts production.
Revenues to be collected by Pininfarina each
year on average over the life of the project were
expected to be £900 billion.
Some design changes would be needed for
Europe. These were well within Pininfarina’s
capabilities, although the model development
time would be less than the approximately three
years needed for a typical design project. As long
as the Japanese schedule was kept, Bertrandi felt
product and process design changes could be
made in time easily, since the model was already
in the prototype phase. In process design,
Mitsubishi would design much of the process.
Pininfarina had only to adapt the process to
its facility—designing an appropriate flow and
layout—and to adapt certain processes to a some-
what more labor-intensive system. Bertrandi felt
such differences would mainly be in the BIW
area where Japanese producers had a tendency to
place more robots than American or European
producers.
Capital Investment
As a result, new production facilities would
have to be acquired and equipped for Mitsubishi
production. Bertrandi felt confident such facili-
ties could be built or acquired in time since poten-
tial expansion sites had already been identified
near Grugliasco. Basic facilities were expected to
cost somewhat in excess of £4 billion, including
land, the trim facility and adequate parking for
workers. Mitsubishi would not cover these
expenses. Pininfarina would not invest in welding
automation for the Pajero.
The paint shop, which was currently
running at capacity, would have to be run for an
additional shift. To supply it, the logistics for
transporting BIW from the Mitsubishi facility
to the Grugliasco paint shop and back would
have to be set up, but this posed no problem in
principle since BIWs were already being painted
at Grugliasco and transported to San Giorgio
for trim. There would be additional expenses
with the paint shop, however, associated with
the Mitsubishi production. Currently, the
necessity of cleaning the painting system with
solvent to change paint color after each car
placed Pininfarina near the limits of what would
be acceptable under Italian pollution control
regulations. Additional volumes for the Mini
Pajero would force a switch to a water-based
system. The Pajero would offer a two-tone
painting option, and this also posed some prob-
lems for the paint shop. Two-tone painting
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required additional space to dry and store vehi-
cles in between painting stages, and this space
would also have to be created.
Quality
Although they had not yet been definitively
set, Bertrandi knew that Mitsubishi considered
its own quality standards to be very high and that
its focus would differ substantially from those
of Pininfarina’s existing customers. Some in the
company believed Mitsubishi might demand
defect levels of one-fourth the level of Pinin-
farina’s current customers, although what would
be considered a defect was not clear. Experience
had shown different customers considered dif-
ferent things in deciding what was a defect. For
example, some customers closely specified the
routes and positions of electrical harnesses and
hoses in the engine compartment, while for other
manufacturers, only the functionality was con-
sidered, aside from ensuring no basic hazards
such as a plastic hose resting on a hot running
part existed.
Parts Supply and Logistics
Major mechanical parts, including engines,
would be supplied by production in Japan—
either from Mitsubishi itself or one of its sup-
pliers. Other parts would be sourced from
Europe, predominantly from suppliers who
Mitsubishi qualified. Parts supply and logistics
from Japan would have to be established jointly
with Mitsubishi. Mitsubishi agreed to own the
inventory until it arrived at Pininfarina, but it
would be shipped at Pininfarina’s request.
Pininfarina would be responsible for having
sufficient parts on hand to meet its production
obligations.
Pininfarina had some experience in long
distance supply chains. In the 1980s and early
1990s, it had shipped BIW Cadillac Allantes to
Detroit for final assembly. However, the supply
chain to Japan was even longer and Mitsubishi
and Pininfarina calculated that some 13 days
shipping would be required, and a further three
days of inventory at port in Italy would be
needed, in addition to the normal supply of
inventory at the plant. Pininfarina logistics staff
believed these inventories would be adequate to
ensure supply even in the event of strikes. During
a strike or port closure, contingency plans would
be established to divert production to a free port
and to ship to Turin overland.
Many parts from within Europe would also
be shipped further than was usual for Pininfarina
operations. At present, the most distant sup-
plier was 900 kilometres away for Peugeots and
65 per cent were within 60 kilometres. However,
Mitsubishi, which had production in Holland,
wanted to retain many suppliers with which
it had familiarity. Many of these suppliers were
outside Italy, with the most distant being in
the United Kingdom—a three-day shipping
distance.
Many of the new suppliers would be unfamil-
iar to Pininfarina and would present challenges.
Despite the presence of Mitsubishi, Pininfarina
was responsible for parts supply and negotiation
of price. The volumes needed were much less
than those usual for volume manufacturers, and
this made negotiations of price and delivery
difficult compared with what could be accom-
plished by larger firms. Suppliers often incurred
extra costs in overhead and packaging and ship-
ping costs, as well as additional set-up costs
to supply smaller orders. Many of the suppliers
would be unfamiliar to Pininfarina and might
increase the number of Pininfarina’s suppliers by
150 or so.
Outgoing logistics would also be more
complex than usual since Pininfarina would
be shipping greater volumes to dealers in major
European markets, but this was not expected
to present insurmountable problems. It would
also be necessary to forecast sales further in
advance since the interval from parts order to
arrival would be about 46 days—considerably
longer than for the current models. For
example, for Peugeot, the current standard
20
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CASES IN OPERATIONS MANAGEMENT
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for orders was about 10 days in advance of
production.
Workforce
While Mitsubishi would pay for tooling and
fixtures under the volume guarantees at standard
margins, the workforce needed was another
matter. Bertrandi felt some 600 additional direct
workers (inside the factory) would be needed to
meet the Mitsubishi volume needs. At traditional
ratios of direct to indirect workers, this would
imply some 200 to 240 indirect workers.
However, Bertrandi felt that while some classes
of indirect workers could not be reduced from
usual levels, other classes could. For example,
purchasing might not need a fully proportional
addition to staff because some suppliers would
still be in common, some additional capacity
could be added in information systems and pre-
sent resources were not fully utilized. Bertrandi
estimated that only one-half the historical number
of additional indirect workers might be needed.
Increasing productivity would free some
direct labor capacity by 1999. Further, by the
year 2000, existing contract business would be
ramped down so that some of the current direct
labor force could be freed to work on the
Mitsubishi vehicle.
The Pajero might also present Pininfarina
with a learning opportunity. Bertrandi antici-
pated that work methods, jigs and tools would
be refined in Japan prior to beginning production
in Italy. Using Japanese designs and production
tools and processes, Bertrandi was excited by
the prospect of being able to compare his oper-
ations with world-class volume manufacturers.
Pininfarina would need to learn fast. After the
initial test and ramp-up phase, which would last
two to three months, Pininfarina would have to
meet the agreed target costs or else pay for any
overages itself. Bertrandi wondered if he should
accept the contract and the challenge.
NOTES
1. US$1 was equal to approximately £1,600.
2. Under Italian law, the government would,
under certain circumstances, use a fund created by
Italian companies to pay 80 per cent of a laid off
worker’s salary for up to two years.
Developing World-Class Operations
•
21
FELL-FAB PRODUCTS (A)
John MacDonald
John Haywood-Farmer
Larry Menor
Copyright © 2000, Ivey Management Services Version: (A) 2001-02-09
In December 1998, Glen Fell, president of
Fell-Fab Products of Hamilton, Ontario, knew
it was time to respond to North American
Airlines (NAA), one of Fell-Fab Products’
important aircraft interiors customers. Two
months earlier, NAA had asked Fell-Fab
Products whether it was interested in taking
over complete management of NAA’s aircraft
interiors business. Although the proposal was
financially promising, it represented a significant
departure from Fell-Fab Products’ traditional
business of interiors manufacturing. Now, after
01-Klassen-4641.qxd 4/1/2005 6:04 PM Page 21
considerable study and discussions with NAA,
Glen Fell had to decide whether Fell-Fab
Products should accept the offer and, if so,
how to implement it.
FELL-FAB PRODUCTS
Fell-Fab Products was a family firm that the
current chairman, Don Fell, had founded in
1952. The company described itself as a manu-
facturer of engineered textile products, all of
which required cutting and sewing (or welding
1
)
textiles according to a specified pattern. Its main
business (75 per cent) was the manufacture of
interior coverings such as seat covers, carpeting,
drapes, curtains, galley furnishings and maga-
zine pouches for the transportation industry.
Airlines accounted for 80 per cent of this
business; railways and bus lines accounted for
the remaining 20 per cent. The company’s
remaining revenues (25 per cent) came from a
diverse line of products such as tents and vests
for the Canadian military, carrier bags for news-
paper and mail delivery, liners for shipping con-
tainers and elevators, sofa beds for recreational
vehicles, microwave receiver dishes
2
, thermal
insulation blankets for aerospace applications,
custom-designed covers and the overhaul of
airline seat assemblies. Its customers for these
products included organizations in the aero-
space, material handling, packaging, industrial
and government sectors. The company’s cus-
tomer base and product mix had remained rea-
sonably stable. Among its core competencies,
Fell-Fab Products counted its ability to react
quickly through manufacturing flexibility, mate-
rials management and constant communication
with the customer.
Exhibit 1 shows an organizational chart. The
company’s head office and main manufacturing
facility were in Hamilton, where about 20 head
office and 180 manufacturing staff worked. The
Hamilton plant, which was ISO 9001 certified
and included a Class 100,000 clean room essen-
tial for aerospace products, produced Fell-Fab
Products’ full product line. FELLFAB, L.L.C.
near Atlanta, Georgia, employed about 60 people
and was devoted entirely to manufacturing parts
for transportation interiors. The company’s
annual revenues were about $27 million; about
$15 million of this amount originated from the
Hamilton plant and about $12 million from
the Atlanta plant. About $7 million came from
non-transportation products.
COMPETITORS
The North American aircraft interiors business
had many relatively small producers. John
MacDonald, Fell-Fab Products’ director of
sales and marketing, and a recent EMBA grad-
uate, believed that Fell-Fab Products’ Canadian
market share was about 20 per cent. The various
active companies tended to carve out roles
with different degrees of vertical and horizontal
integration. One Canadian competitor was a
subsidiary of a textile mill. One United States
company made complete seats. Other compa-
nies were involved in interiors replacement and
cleaning. According to MacDonald, Fell-Fab
Products’ experience, consistent product qual-
ity, design capability, two manufacturing sites
and ability to transfer design specifications
between them electronically made it competi-
tive. Transportation customers preferred to
avoid the risks of single sources and to deal
with suppliers near their major aircraft refur-
bishment sites. In North America, those sites
included Toronto and Vancouver in Canada, and
Atlanta, Chicago, Dallas and Los Angeles in the
United States.
THE SEAT COVER PRODUCTION PROCESS
Although making interior covers for an airplane
was not difficult, some salient features com-
plicated the process. There was a considerable
degree of asymmetry and variation in airline
seats. Each aircraft type had its own seats, often
in several configurations. Even for a single air-
craft type, each airline had its own seat needs.
Naturally, the larger seats in business and first
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class required different covers than the standard
economy class seats. However, left side seats
could differ from right side seats, and aisle,
centre and window seats could all differ.
Consequently, a row of seven seats might have
seven different covers. Special features of the
aircraft, such as the presence of bulkheads and
seats for each crew member, created yet more
cover designs and/or materials. Carpeting was
also complex. For example, the carpet kit for
a Dash 8, a short-haul commuter aircraft, had
a total of 23 pieces in 12 separate designs with
up to six pieces per design. And, because some
newer Dash 8-400s had custom interiors, all kits
for that series were different.
Aircraft interior manufacturing began with a
contract between the airline and a small number
of textile mills, typically from overseas, to sup-
ply material to certain specifications. The airline
then informed interiors manufacturers such as
Fell-Fab Products of the names of acceptable
suppliers and the product numbers and prices
of the proper materials. Fell-Fab Products
purchased fabric according to this list with lead
times of about 12 weeks. Advance planning was
crucial for Fell-Fab Products. When an airline
Developing World-Class Operations
•
23
Glenn Fell
President
Albert Tufts
Vice chairman
Donald R. Fell
Chairman
& CEO
Chris Karlos
Manufacturing
consultant
Roman Kuszczak
Services
manager
Brenda MacKay
Office
manager
John Walma
Engineering
manager
Hugh Kramer
Plant
manager
John MacDonald
Sales and
marketing
manager
Process
engineers
Production
supervisors
Account
executives
Accounts
payable and
accounts
receivable clerks
Buyers
Customer
service
representatives
Quality
inspectors
Design
engineers
Exhibit 1 Fell-Fab Products’ Organizational Chart
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needed interior coverings, it informed Fell-Fab
Products, typically requesting delivery in about
four weeks.
Fell-Fab Products drew the purchased mater-
ial from raw materials inventory (which averaged
about 60 days’ worth) and spread it in layers
on a large cutting table. The company stored
designs for the interiors electronically in a com-
puter aided design (CAD) and computer aided
manufacturing (CAM) system, which was able to
optimize a cutting pattern and cut up to 40 layers
of material. In addition to order size, the number
of layers cut depended on the thickness and com-
position of the material. Once cut, the material
continued to be handled in batches based on
the number of layers cut. It then passed through
about six sewing operations and was labelled
and bar coded. The final product was inspected,
gathered into kits and boxed ready for shipping.
Sewing and inspection were labour intensive
operations and it was more labour intensive to
process leather than man-made textiles. Although
it took only a few minutes to complete each step
for a single interior covering, from cutting to ship-
ping it took about a week to process a typical
order for a large commercial aircraft. In common
with other batching operations, queue time before,
during and after production was significant.
Fell-Fab Products’ transportation product
customers included 10 major airlines that, in
general, demanded high quality, prompt and on-
time delivery, and excellent customer service.
Occasionally, in the past, Fell-Fab Products had
lost business because it had failed to deliver on
time. All products had to be certified to particu-
lar safety specifications. Late shipments or other
problems with an order could result in lost rev-
enues for the airline as they would not fly with
even a single seat cover missing. For Fell-Fab
Products, the term “aircraft on ground” (AOG)
was a panic signal. In such cases the company
gathered the necessary materials and processed
them as quickly as possible using the regular
equipment and operators. Although the result
might satisfy the AOG-affected customer, the
practice could significantly disrupt the flow of
other orders.
NORTH AMERICAN AIRLINES
North American Airlines (NAA) was a full service
airline offering scheduled passenger, charter and
air cargo transportation services. In 1998, NAA
flew more than 10 million passengers to more
than 200 destinations in North America and 30
destinations in Asia, Europe and Latin America.
It was a founding member of a leading industry
alliance and was also affiliated on a code-sharing
basis with smaller regional carriers that served
shorter flights, often as feeders. NAA was among
the five largest passenger carriers between North
America and Asia in terms of total flights. NAA
had benefited significantly from its partnerships.
NAA prided itself on the quality of its service.
In recent years, it had undertaken a variety of
changes to its products and services based on
extensive benchmarking against its competitors
and partners along with customer surveys
encompassing check-in, boarding, in-flight, and
baggage retrieval. In evaluating NAA’s airline
equipment, facilities and uniforms, customers
believed that the airline was “friendly but tired.”
Customer research identified comfort and flexi-
bility as the important factors passengers con-
sidered when measuring a pleasant in-flight
experience. Among the most visible of NAA’s
improvements was a complete overhaul of the
aircraft fleet’s interiors and change in colour
schemes planned for early 1999. NAA’s fleet,
including those of its affiliated regional carriers,
consisted of about 130 aircraft in eight different
makes or models (see Exhibit 2).
Like its competitors, NAA spent a great deal
of money managing its fleet’s interior coverings.
As part of its interiors management program,
the buyers assigned to this product class were
responsible for inventory management and ser-
vicing, as well as purchasing the coverings.
Approximately every three months, while the
aircraft was on the ground for scheduled servic-
ing and mechanical upkeep at one of NAA’s
major service centres, an NAA crew stripped
the interior coverings from the aircraft and
replaced them with others from inventory. It
sent the removed coverings to an independent
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cleaner who dry cleaned all of them, regardless
of their condition. After cleaning, the dry cleaner
returned the coverings to NAA for storage.
NAA’s coverings inventory was thus found in
use on the NAA fleet, in stock in NAA’s ware-
house, in transit to or from the cleaners, and
at the cleaners for service. Although colour or
design modifications could prompt an earlier
change, the lifetime of a seat cover was approxi-
mately one year. Wear was the most common
reason for cover changes. It was important to
keep track of the number of dry cleaning cycles
for each seat cover because flammability specifi-
cations were typically compromised after 10 to
20 cleanings, depending on the fabric used.
NAA stored the covers in large bins, with one
complete set for a given aircraft per bin. It identi-
fied the bins by aircraft type. To reduce the risk of
being out of stock, NAA and other airlines often
stored extra coverings for emergencies. When
they came to put a cleaned set of covers on, the
replacement crew might also discover that some
covers had been damaged and needed replacing.
The crew discarded covers it identified as dam-
aged at the time of installation; if NAA could not
find adequate replacements in inventory, it placed
a rush order, under AOG conditions, with Fell-
Fab Products. As soon as possible after replacing
an aircraft’s interior coverings, the replacement
crew supplied NAA’s purchasing personnel with
scrappage reports. Purchasing, in turn, prepared
monthly scrappage reports to help forecast future
coverings purchasing requirements.
THE NAA PROPOSAL
In October 1998, NAA asked Fell-Fab Products
if it was interested in widening its business
relationship beyond the manufacture of interior
coverings. Fell-Fab Products was one of a few
airline interior manufacturers upon which NAA
relied. Since becoming a producer of these prod-
ucts for NAA in 1965, Fell-Fab Products had
seen its sales to NAA increase steadily; currently
it accounted for 35 per cent of NAA’s purchases
of cabin interiors. Exhibit 3 shows NAA’s
history of purchases from Fell-Fab Products.
In October 1998, MacDonald and a Fell-Fab
Products account executive met a purchasing
Developing World-Class Operations
•
25
Aircraft Typical Economy Seats Typical Business Seats
Number per Number per
Type Number Aircraft Total Aircraft Total
Boeing 747-400 4 379 1,516 42 168
DC10-30 10 228 2,280 24 240
Boeing 767-300ER 11 180 1,980 25 275
Airbus 320 12 108 1,296 24 288
Boeing 737 44 88 3,872 12 528
Fokker 28 27 85 2,295
Dash 8-100 10 37 370
Dash 8-300 14 50 700
Total 132 14,309 1,419
Exhibit 2 NAA’s Fleet
1
1. Although the number of aircraft of each type and the seating configuration varied from time to time, they were reasonably
stable.
01-Klassen-4641.qxd 4/1/2005 6:04 PM Page 25
manager and two buyers from NAA to discuss
the NAA proposal. The meeting focused on one
aspect of NAA’s interiors management program—
the management of aircraft interior coverings.
MacDonald described his impressions:
NAA approached us to express their intent to
withdraw from the interior coverings management
business and offer it to an external, though rep-
utable company like us. It makes sense: NAA is in
the flight business, we are in the cabin interiors
business. And, effective interior coverings manage-
ment is extremely important. A single missing seat
cover is enough to ground a plane. By purchasing
the complete management of interior coverings
from one or more external service providers, NAA
would realize four benefits:
• reduced costs,
• reduced interior coverings inventory,
• better use of their existing service crew, and
• a simpler interior coverings management
process.
Since a bin of coverings is typically unsorted
and the seat covers aren’t even identified by seat
type, the replacement crew spends a lot of time
sorting through the clean bin trying to fit seat
covers by trial and error. Besides dealing with
interior coverings, the crew is also involved with
other servicing and mechanical tasks such as
maintenance of telephones, the entertainment
system, seats, lighting, the heating and air condi-
tioning system, galleys and lavatories. Because
NAA has a high overhead structure and its
interiors coverings replacement crew is highly
paid, NAA wants them to work more on these
higher-value-added tasks. NAA officials believe
that lower-waged, unskilled workers could be
employed to replace coverings. However, NAA’s
employees are unionized and the union has
objected to using unskilled workers in the past.
NAA’s current process is complex because of
its many logistical difficulties related to tracking
the location and levels of interior coverings
inventory, the choice of independent cleaners,
and the sorting of cleaned covers. NAA is inter-
ested in withdrawing from the interior coverings
management business if it can’t simplify its
process internally.
26
•
CASES IN OPERATIONS MANAGEMENT
1996 1997 1998
January 12.0 11.5 21.7
February 18.5 21.3 15.1
March 4.9 14.6 11.2
April 9.1 18.1 19.7
May 21.8 12.2 23.6
June 7.6 11.9 16.9
July 17.8 21.9 15.6
August 10.9 8.0 23.0
September 10.3 18.5 15.0
October 14.6 20.0 21.2
November 13.0 15.1 19.4
December 9.2 13.8 19.0
Total 149.7 186.9 185.5
Exhibit 3 Fell-Fab Products’ Recent Sales to NAA
1
1. Figures are in thousands of dollars.
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Developing World-Class Operations
•
27
To date, no North American firm offers a service
as comprehensive as the one NAA envisages. This
opportunity deserves further study.
NAA’S INTERIOR
COVERINGS MANAGEMENT BUSINESS
Over the following weeks, MacDonald gathered
as much information as he could from NAA and
other sources. NAA seemed to know little about
its interior coverings management process. The
officials found it difficult to provide immediate
responses to basic questions such as: “How many
seat covers do you own?” and, “How long does it
take to change a cover?”
Interior Covering Replacements,
Inventory and Cleaning
NAA restricted interior covering replace-
ment on its Boeing 737, Boeing 767, DC-10 and
Airbus A300 aircraft to two North American cen-
tres, one in the east and one in the west. In total,
these sites changed an average of 1,350 seat cov-
ers per week. NAA changed the interior cover-
ings on its Boeing 747s during layovers in a city
in southeast Asia at a rate of 50 covers during
each layover with four layovers per week. NAA
changed the interior coverings on its DC-10s
once annually. NAA’s affiliated regional airlines
changed their interior coverings at their major
centres of operation.
On average, a seat cover was inspected
every 300 flying hours. NAA carried up to six
spare seat covers per aircraft aboard for emer-
gencies to eliminate the need to carry stock at
each of its line stations. NAA did not currently
account for the number of dry cleaning cycles
by seat type.
Interior Covering Management
Responsibilities and Expenses
Replacing a seat cover required approxi-
mately 19 worker minutes per seat at an average
cost of $20 per worker hour. The most recent
scrappage report indicated that for the preceding
12-month period, NAA discarded approxi-
mately 4,500 seat covers. The total number of
seat covers cleaned for 1998 numbered 48,000
at its western centre and 27,000 at its eastern
centre for an estimated total cost of cleaning
of Cdn$75,000, not including transportation,
repairs, sorting, or cover replacement.
The more Glen Fell and MacDonald investi-
gated this business opportunity, the more they
became intrigued by it. They estimated that it
would substantially increase Fell-Fab Products’
revenues and profits as the service offered a
potentially high contribution. Margins in the inte-
riors manufacturing business were 20 per cent to
60 per cent, with almost all of them at the low end
of that range. The two estimated that a contract
with NAA would provide annual revenues of
$1.2 million with costs of $475,000 per year for
labour, transportation, cleaning and storage.
They were also able to confirm that the
airline industry was moving towards buying
such services. Further, NAA’s offer to Fell-Fab
Products had not gone unnoticed; several of
NAA’s alliance partners as well as NAA’s
primary competitor were interested in the out-
come of the proposal.
MacDonald was concerned that the NAA
offer was too great a departure from Fell-Fab
Products’ traditional business. He described his
views:
Fell-Fab Products has an established reputation
as a quality-conscious manufacturer of engineered
textile products. Over the years, we have made
efforts to improve our production processes as well.
For example, we have incorporated CAD/CAM
technology to ensure the most economical use of
materials. This has improved our fabric yield and
further eliminated human error. Our computerized
cutting equipment ensures a high degree of accu-
racy in cut parts and permits us to work within tight
tolerances and our full electronic data exchange
capability and product bar coding provides more
efficient materials management and inventory con-
trol. Companies do business with us because we’re
good at making things. We probably made the car-
rier bags like those there on the wall used to deliver
your newspaper and mail today.
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NAA’s proposal would require us to invest about
$250,000 to acquire a crew experienced in dressing
aircraft, suitable cleaning equipment, and a fleet of
service vehicles to transport the crew and covers to
airport locations. Operating costs would be extra.
Accepting NAA’s offer would require us to be more
of a service-based business. Service organizations
make money by being good in executing activities,
not through making things. Fell-Fab Products cur-
rently provides some auxiliary services to its air
interiors customers. We have an in-house staff of
design engineers that can assist in the design stages
of particular products. Covers for the Canadarm and
robots and nuclear reactor insulation are examples.
Also, although we are able to provide our customers
with historical information regarding inventory, con-
sumption and other reports as needed, these services
are not our principal order winners.
What kind of service would NAA expect?
Cleaning, inventory management, and repair are
the obvious ones. But others are also possible.
The actual service would depend on just what
NAA wants. The quality of any service we provide
to NAA would rest on our ability to respond and
be reliable. At a minimum, the interior coverings
management business would necessitate greater
interaction with the customer. Would our sales
staff be able to provide the levels of assurance and
empathy required when dealing with an airline
executive forced to ground an aircraft because we
were not able to service all his or her aircraft inte-
rior needs? Value for Fell-Fab Products would have
to include issues related to customer allegiance too.
GLEN FELL’S DILEMMA
Glen Fell had decidedly mixed feelings concern-
ing this decision. Before committing to NAA’s
interior coverings management proposal, he was
mulling over a list of issues that he had to address.
He contemplated his vision for the future of his
company’s involvement in the airline industry. He
described his thoughts:
This could be a very attractive business for us. It
is a natural extension that complements our core
business of manufacturing aircraft interiors. We
already know this market. We also know NAA and
many of the other players in it. We understand
them well and have good relations with them. In
fact, a move like this should strengthen our rela-
tions with NAA. In addition, it wouldn’t involve
adding facilities as we could use our existing ones,
except for space for dry cleaning. We already have
a building lined up near our Hamilton plant for dry
cleaning. And, we could use this as an opportunity
to learn about running a service operation. That
would be a real asset if we decided to extend our
non-core businesses into service too.
The demand for such a service seems to be there,
although the picture is not entirely clear. Lots of
airlines are making noises about outsourcing inte-
riors management. One claims to have saved some
$5 million per year by doing so.
There are really two types of airlines. One is
already outsourcing a certain amount of business.
In those cases, our job would be to convince them
to switch suppliers. The other type does it in-
house. Our job would be to convince them that we
can do a better job than they can do themselves.
But, many of them have strong labour unions who
recognize outsourcing as a real threat to their
jobs. It would be tough to get them to go to the wall
with their workers over outsourcing refurbishment
services.
The possibility of a deal with NAA is intriguing.
They seem to want to help us by sharing what they
know. It was clear from our meeting that they are
going to go with someone. If we wait, they will go
with someone else, and we will find ourselves very
much behind.
Despite its potential, this deal makes me nervous.
Extending beyond our core competence in interior
coverings production is potentially risky. We don’t
have the logistical expertise at the centre of
NAA’s problems so we would have to develop our
own or get assistance. Over the years, we have
grown by diversifying. It is always risky to put all
your eggs in one basket. This diversification has
taken two routes. Don [Fell] is always looking for
opportunities to use our core strengths in sewing
fabric. Whenever he sees a possibility, we investi-
gate it. This has led to our wide range of small
volume products, which really share only one
thing—they involve sewn or welded fabric. But,
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we miss out because we don’t understand the
industries to which we sell the products. They
don’t have much in common at all.
The second route in our diversification has been
the acquisition of companies that make products
involving sewing or welding. Over the years,
we have made at least 10 of them. And yet, not
one of them is still operating. We have tended to
focus on the sewing and welding while ignoring
other aspects of the production process. In some
cases, we have not had the management skills to
handle those differences. In other cases, produc-
tion has been no problem, but we have had trou-
ble growing sales because of our inexperience in
those markets. We have been reluctant either to
leave our acquisitions alone or to develop the nec-
essary skills inside the company to deal with
them. Would the NAA opportunity be a success or
would it simply be one more failed attempt to
diversify?
If we were to go ahead, what would be the impact
on our manufacturing business? With our failures
in the past, we have been protected from major
effects because the part in trouble has been rela-
tively small. But this time, it would be different.
I am sure that if we were to fail to adequately serve
airlines through a logistics or cleaning mistake, we
could hold up an aircraft. Not only would that cost
us money, but the whole company would get a bad
reputation. And, we think that the airlines currently
buy about 20 per cent more interiors than they
actually need because they don’t maintain them
very well. Even if we were to succeed in service, it
might hurt our interiors sales.
We would also have to find, hire and train the right
people. We don’t quite know what service people
would be like, but we do know that our current staff
probably wouldn’t be right. And, we would need
new management systems for a service arm. The
whole logistics area would be quite different.
Managing aircraft interiors involves a lot of inven-
tory control that we don’t have experience in. Our
main inventory task right now is handling a small
amount of raw materials. In this business, we would
have to handle large numbers of finished goods and
make quality calls for our customers. It would be
our decision whether a seat cover was torn or worn
badly enough to need replacement. And, of course,
we know nothing about dry cleaning. We wouldn’t
want to have a problem and have seat covers last
only half as long as they should because we made
an error in the mix of solvents in the dry cleaning
process that affected fire retardation.
The Atlanta plant certainly adds to administrative
load and costs. Aircraft interior refurbishment
might mean a large number of additional sites, and
fairly quickly. A large carrier like NAA probably
wouldn’t want to wait too long while we expand to
other centres to serve them.
In our current business, we have a pretty good idea
what quality is and how to manage it. We have a set
of benchmarks to go on and well described stan-
dards set out in product specifications. When we
produce a new seat cover, the first two units we pro-
duce become test standards. We send them to our
customer for checking. If the customer is satisfied,
it signs off on them and returns one sample to us as
a reference that we can always refer to if we have
to. But how do you do that on the service side?
There are no benchmarks and certainly no reference
standards. And, almost everything would be done
by people. Their work is not nearly as reproducible
as a machine’s. Of course, maybe each customer
would want it different each time. We would have
to develop some comfort in dealing with quality in
such an environment and some systems to handle
it. These factors all point to developing a high level
of communication with customers.
It probably sounds odd for a manufacturer in the
just-in-time and zero inventory age to say it, but
services present a problem because they don’t
involve inventory. Although we try to cut inventory
wherever possible, the penalty we pay is that
inventory isn’t there to buffer the business from
fluctuations in the market. You wind up with a very
different capacity management task. We don’t have
any experience managing capacity in an inventory-
free environment. I am not sure we are up to it.
On the bidding side, we have limited experience
in estimating service contract costs. If we were
to get a fairly long-term contract below cost, we
could lose our shirt.
It seems to me that there are several key success
factors in implementing such a service. First,
communication between the customer and service
provider is vital, especially during the early stages of
developing the service relationship. The customer
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must communicate its needs to the service provider,
while the provider must communicate its capabili-
ties to the customer. Second, both parties must be
committed to the long-term success of the venture.
Third, a successful external aircraft interiors man-
agement business rests on developing a partnership
between the customer and the service provider.
So, my decision comes down to heading off in a
new direction with an attractive set of benefits
but also significant costs, or continuing to work on
improving our existing core manufacturing busi-
ness, which, as you can appreciate, is far from per-
fect. NAA plans to introduce a new colour scheme
in March 1999, so I have to decide quickly
NOTES
1. Welding two pieces of synthetic textile together
was very similar to welding two pieces of metal,
except that the source of heat was radiofrequency radi-
ation rather than an electric arc or acetylene combus-
tion. Like metal welding, the two pieces of textile had
to be of similar composition.
2. The heart of a microwave receiver was a small
electronic device, typically located at the focal point of
a curved reflecting surface where the radiation was
concentrated. The curved surfaces of some dishes were
made from fabric supported by a rigid frame. Fell-Fab
Products made the reflecting fabric surface rather than
the supporting frame or the electronic components.
30
•
CASES IN OPERATIONS MANAGEMENT
UNICON CONCRETE PRODUCTS (H.K.) LTD.
Fraser Johnson
Rob Klassen
Copyright © 1998, Ivey Management Services Version: (A) 2000-09-25
Herman Li, deputy managing director of Unicon
Concrete Products (H.K.) Ltd. (Unicon), was
considering what action he should take to address
the growing demand for two of his company’s
products, precast concrete facades and slabs. It was
now November 1997, and the construction industry
in Hong Kong was flourishing. Mr. Li felt that an
opportunity existed for Unicon to make changes to
the current process of submitting structural design
drawings to the Hong Kong Housing Authority for
approval. He believed that streamlining this process
would both reduce lead times and eliminate unnec-
essary costs. Because of the long lead time associ-
ated with such a change, Mr. Li felt compelled to
finalize his strategy quickly. He was concerned,
however, about the implications of this change on
Unicon’s operations and competitive position.
HONG KONG
Hong Kong was an important centre of economic
activity in southeast Asia. Located on the South
China Sea, Hong Kong was the economic gateway
to the People’s Republic of China (PRC). In fact,
60 per cent of all of China’s exports passed
through Hong Kong, while the Territory accounted
for approximately 70 per cent of the direct foreign
investment in the PRC. Hong Kong had the
world’s largest container port, where exports of
electronic products, clothing and textiles passed
through to North America and Europe.
Hong Kong reverted back to China from the
British on July 1, 1997, under the “one country,
two systems” approach to government. Although
the per capita income of Hong Kong was second
in Asia only to that of Japan, the Special
Administrative Region (SAR) faced certain
problems. With over six million people on only
1,076 square kilometers (415 square miles),
affordable housing was one of the most critical
problems facing the Hong Kong government.
Needless to say, housing in Hong Kong was
among the most expensive in the world. A typi-
cal 800 to 1,500 square foot apartment in Hong
Kong, with two or three bedrooms ranged in
01-Klassen-4641.qxd 4/1/2005 6:04 PM Page 30
price from HK$15 to HK$35 per square foot per
month for rental and between HK$5,500 to
HK$8,000 per square foot to purchase.
1
Even
apartments at the low end of the market, with
only two bedrooms and 500 to 800 square feet,
cost about HK$10 per square foot per month to
rent and between HK$3,200 to HK$5,500 per
square foot to purchase.
CONCRETE CONSTRUCTION MARKET
As a supplier to the construction industry, Unicon
sold its precast concrete products to general
contractors in Hong Kong. General contractors
were large firms capable of co-ordinating the
construction of large, expensive building projects.
These firms had expertise in building construc-
tion and design, together with the capabilities
to finance such ventures. Although there were
many general contractors in Hong Kong, the
largest of these, numbering approximately 12,
controlled an estimated 80 per cent of the market.
Unicon had historically worked with all 12 of
these organizations.
While seasonal variations were relatively small,
construction activity followed a cyclical pattern,
with infrastructure and superstructure devel-
opments peaking at different times. A developer
interested in constructing a superstructure com-
plex would secure the services of an architectural
firm to coordinate the design and build the project.
The architectural firm would provide engineering
support, dealing with both the substructure (the
foundation below ground) and superstructure (the
building complex above ground).
The typical process called for the architect to
engineer both the substructure and superstructure
concurrently. Under the existing superstructure
submission procedure for private development,
detailed design calculations and drawings had
to be prepared by a Registered Architect and a
Registered Structural Engineer (RSE) jointly and
submitted to the Government Building Depart-
ment for approval. The submission could be
approved, minor changes requested, or rejected.
This submission and review process could take
up to two months.
In Hong Kong, tender offers for the
superstructure were requested just prior to
completion of the substructure. General con-
tractors then were expected to be capable of
immediately commencing construction of the
superstructure following formal review of the
tenders. This placed considerable pressure on
the bidder to have subcontractors and suppliers
that could meet very tight schedules on time.
When constructing superstructures, the
general contractor used either the traditional
method of pouring concrete walls and floors on-
site, using forms built in place, or alternatively,
assembled precast concrete facades and slabs,
which were produced elsewhere. Facades were
the exterior walls of the superstructure, and slabs
were the interior floors. The use of either method
was determined in advance from the architect’s
specifications during the design phase. With
either method, the general contractor typically
used subcontractors to complete this phase of the
construction project.
Unicon’s products were used in all three
primary categories of superstructures in Hong
Kong (industrial, residential and office build-
ings). Although the cost of the precast materials
was generally three to four per cent more than
the traditional, pouring on-site method, other
advantages favored its use. First, precast systems
provided opportunities to reduce total costs in
the construction project. Building assembly time
could be shortened, site construction simplified
and site congestion reduced.
Second, reliance on skilled tradespeople,
such as carpenters and steel-fixers, was reduced.
Skilled tradespeople were in short supply in Hong
Kong, and these workers typically commanded
salaries of HK$1,500 per day, although during
peak times they could reach as high as double
that. Furthermore, the reduction of on-site work-
ers decreased the need for supervisory personnel
and administration.
Third, because precast products were produced
in a controlled environment, production was not
affected by the traditional problems that beset
the construction industry. For example, bad
weather and unscheduled shortages of labour and
equipment were not problems that affected precast
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production. Consequently, availability of products
could be assured. Fourth, for related reasons,
precast products offered quality advantages. The
exterior finish was regarded as superior to on-site
construction, and the window frames could be
cast in the concrete so as to avoid water seepage.
Notwithstanding these advantages, there were
several factors that continued to favor the use of
the traditional construction method. If the super-
structures were not initially designed with precast
materials in mind, and precast materials were then
considered, the general contractor was required
to resubmit revised designs for approval. This
resubmission could result in substantial delays.
Since the expectation was that construction of the
superstructure would begin immediately follow-
ing the formal review of the tenders, opportunities
to redesign the project to accommodate precast
components usually did not exist. Consequently,
precast systems had to be specified by the archi-
tect at the outset of the design process. In addition,
precast systems had to conform to standard
dimensions in order to be economically viable.
Such requirements placed restrictions on the cre-
ativity and originality that an architect could apply
to overall building design.
Finally, construction activities differed sub-
stantially when precast systems were used com-
pared to traditional methods. There was less
reliance on skilled labor and increased depen-
dence on equipment, such as tower cranes. As a
result, general contractors had to be capable of
supporting this particular method of superstruc-
ture construction.
HONG KONG HOUSING AUTHORITY
The Hong Kong Housing Authority (HKHA)
was a government agency responsible for pro-
viding affordable housing for local residents.
The HKHA provided both rental “blocks” and
home ownership scheme (HOS) “blocks.” The
approximate number of apartments in a residen-
tial block was 640; a typical block consisted of
a 41-floor superstructure, which required 1,120
facades and 3,400 slabs. A typical floor plan for
a residential block is provided in Exhibit 1.
The rental blocks offered apartments at below
market rates, while the home ownership schemes
provided Hong Kong residents with an opportu-
nity to acquire units at discounted prices. In
order to qualify for either the rental or ownership
properties, residents had to meet certain income
restrictions and not own other property. From a
design standpoint, each block, whether rental or
HOS, had the same structural layout. However,
the HOS building had a different finish that was
slightly more stylish.
Current regulations restricted the manufac-
ture of facades and slabs for HKHA projects to
production facilities located in Hong Kong.
However, the regulations were being revised
to permit firms in the PRC to supply these. This
revision was expected to take place by 1998.
For HKHA projects, the approval process was
quite similar to other superstructures. Detailed
design calculations and drawings had to be
prepared by an RSE employed by the general
contractor, who had successfully tendered for the
contract. These drawings were submitted to the
project architect, who was the supervising officer
representing the HKHA, for approval. The archi-
tect was obliged to issue his comments within
28 days.
HKHA construction projects represented
the largest segment of Unicon’s sales. Mr. Li
expected that approximately 80 per cent of the
company’s sales would be supported by HKHA
projects, while the balance would be split
between industrial and office projects. Under
present market conditions, Unicon expected to
receive HK$11.3 million per block, HK$4.8
million for facades and HK$6.5 million for
slabs.
The Hong Kong government had recently
announced an ambitious four-year program for
the construction of new residential blocks. The
most recent forecast provided to Unicon by
the HKHA indicted that contracts for a total of
179 blocks would be tendered in just the next
year alone. It was expected that approximately
50 per cent of these would require precast mate-
rials for construction. Under present conditions,
Mr. Li felt that Unicon had the capacity to man-
ufacture sets of facades and slabs for seven
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Exhibit 1 Residential Block Diagram
Precast Facade and Partitioning Location for Typical Floor Plan
Wing A
Wing D
Wing B
Wing C
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CASES IN OPERATIONS MANAGEMENT
blocks per year. Total current industry capacity
was estimated at only 20 blocks per year.
UNICON CONCRETE PRODUCTS (H.K.) LTD.
Unicon was part of International Tak Cheung
Holdings Limited (ITC), a multi-billion dollar
holding company with interests mainly in Hong
Kong. The 1997 ITC financial report listed 44
subsidiary and associated companies, with activ-
ities in a wide range of areas, including property
development, construction, petroleum trading and
sales, and electronic products.
A primary business activity of ITC was real
estate development and construction. In addition
to Unicon, ITC also owned Paul Y.—ITC
Construction Holdings Limited (Paul Y.). Paul Y.
was a major general contractor in Hong Kong
with annual sales of HK$7.5 billion in fiscal
1997. Approximately one-third of Unicon’s sales
were to this affiliated company.
Unicon manufactured precast concrete prod-
ucts, consisting of four principal product lines:
facades, slabs, stairs and partitioning walls
(Exhibit 2). Each of these products was used in
the construction of large, high-rise residential,
office and industrial complexes. Company sales
for fiscal year 1997 were HK$88 million, and
next year’s revenue was expected to continue
to grow substantially for fiscal 1997-98. Similar
growth was forecast for the following year (1998-
99), after which sales were expected to stabilize.
Company Products
Partitioning walls, the interior wall used in the
construction of superstructures, was the only
product manufactured by Unicon when it was
founded in 1992. Mr. Li described the company’s
evolution into other precast concrete products:
Our factory was originally built for producing par-
titioning walls. Unfortunately, we were unable to
support our operations with only that one product.
Eventually, we ventured into precast facades. This
led to the development of our process for precast
slabs as well.
In general, we are shifting our production process
from a reliance on skilled trades-people, which are
in short supply in Hong Kong these days, to a more
standardized product, which is machine-dependent.
This strategy has been enormously successful
for us. Of course, with the current high level of
demand, three other firms have entered the market,
and we expect to see two more before the end of
this year.
Although partitioning walls were a proprietary
design, they came in a variety of standard sizes,
with the typical product measuring approximately
eight feet (2.44 metres) high, two feet (0.6 m)
wide and three inches (0.075 m) thick. This prod-
uct was engineered to meet certain performance
requirements, such as fire resistance, structural
support and sound dampening. It was up to the
company to provide engineering certificates
demonstrating the quality of its partitioning walls.
In fiscal 1997, this product represented 40 per cent
of company sales. Growth in this market segment
was expected to correlate with the overall level of
activity in the residential construction industry.
The other two major product lines were
facades and slabs. Sales of these two products
were interrelated. Since designs were not stan-
dardized among the four Hong Kong manufac-
turers, customer orders tended to require
corresponding commitments for both products.
Consequently, production of slabs and facades
were make-to-order only. In contrast, sales of
partitioning walls, because of their modular
design, were independent of facades and slabs.
Thus, production of partitioning walls could be
make-to-stock.
Sales of facades represented 20 per cent of
total sales in 1997, while slabs were 34 per cent
for the same period. Management predicted that
sales of these product lines would grow much
faster than partitioning walls as general contrac-
tors and architects became more familiar with
the advantages of their use. Mr. Li considered
profit margins on both facades and slabs to be
very good—significantly higher than the margin
on partitioning walls.
Stairs were the smallest of Unicon’s product
lines, accounting for only six per cent of sales in
fiscal 1997. Profit margins on the stairs business
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35
Exhibit 2 Unicon Products
Precast concrete facades ready to be assembled and installed onto the floor slab
Precast concrete slab being hoisted into position
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CASES IN OPERATIONS MANAGEMENT
was comparable to that of the facades, which was
somewhat less than that of slabs. Roger Cheung,
sales director at Unicon, described the situation
as follows:
Stairs are a fairly standardized product, with no
engineering approvals required. Design is stan-
dardized. Customers that buy our facades and slabs
do not necessarily have to use our stairs. Usually,
we can’t justify contracts for producing stairs
based on industry pricing. However, if I can pick
up the business at a good margin, we will take it.
Facade and Slab Manufacturing
Unicon operated a 7,500 square metre facility
in Yuen Long, in the New Territories. All ship-
ments into and out of the plant were made by
highway transport. The plant layout is depicted
in Exhibit 3. Partitioning walls were producted at
one end of the plant, labeled “drywall production
area,” while slabs, facades and stairs were pro-
ducted at the other end.
Currently, Unicon employed 64 people,
including 46 in the production department and
18 staff. The production department included
supervision, quality control, maintenance and
14 production workers. These production workers
were dedicated exclusively to the manufacture of
partitioning walls.
In contrast, subcontractors were used for
facade, slab and stair production. One subcon-
tractor provided two teams of four workers for
facade production, another provided three teams
of four for slab production, and a single team of
three workers was provided by a third contractor
for stair production. Finally, another 14 produc-
tion workers in the bending area prepared the
reinforcing bar. These workers also were pro-
vided by a subcontractor.
The company operated a single shift that
ran between 8:00 a.m. and 6:00 p.m., with a one-
hour lunch break from noon till 1:00 p.m. The
average production worker at Unicon was paid
HK$15,000 per month, including benefits, but
not including overtime. The plant operated a
regular production schedule from Monday to
Saturday, plus overtime every other Sunday. Over
the course of the year, employees were entitled to
14 statutory paid holidays, in addition to regular
paid vacation days. Mr. Li estimated that labor
costs were 30 per cent of total revenue, while
material costs were approximately 40 per cent.
The balance was for plant overhead and profit.
The plant had 25 facade moulds and 64 slab
moulds, and some slab moulds were capable of
producing two slabs. Consequently, the production
of slabs could range from as low as 64 per day to
as high as 101 units per day, depending on the
design of the building under construction. The
production process for both facades and slabs
was identical, involving four groups of activities
(a detailed process flow diagram for facades is
provided in Exhibit 4).
Mould Setup
Mould setup, the first group of activities,
began each morning at about 8:30 a.m. First, the
steel moulds were cleaned with a high-pressure
air gun to remove loose debris. Oil was then
applied to the metal moulds in order to avoid
bonding between the mould and the concrete.
Cast-in items were then added to the mould. In
the case of facades, this included windows, sock-
ets and electrical boxes. In the case of slabs,
areas were “boxed-out” for electrical conduits.
Steel reinforcing bar was then placed into the
mould. This material was included to provide
structural support to the finished product, and
was prepared earlier in another dedicated area.
Finally, a quality control audit was performed
before the mould was “closed” and ready for
pouring. Mould setup activities were typically
completed by 11 a.m.
Pouring
Concrete was added to the mould during the
pouring stage. Concrete, which was comprised
of a mixture of cement, aggregate (e.g., stone or
gravel) and water, was mixed off-line by three
Unicon employees in the batching plant and
delivered to the moulds via an overhead crane.
Pouring commenced at 10:30 a.m. and con-
cluded at approximately 2 p.m. This operation
was suspended during the lunch break.
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CASES IN OPERATIONS MANAGEMENT
Fabrication of Steel Moulds
Checking of
Dimension?
Cleaning of Mould
Application of Mould Oil
Fixing of Reinforcement, Spacer &
Cast-in-product Materials
Assembly of Side Moulds
Preconcreting
Inspection?
Placing & Compaction of Concrete
Finished of Exposed Surface
Curing (Before Demould)
Cubes Testing for
Demould?
Demoulding
Product Identification Marking
Product Visual & Dimension Check
Product Visual &
Dimension Check?
Product Inspections
(if any)?
Storage
Delivery
Reinforcement
Return Steel Bars
to Supplier
Cutting & Bending of
Reinforcement
Receiving
Inspection &
Testing?
Rebars
Inspection?
Rectification
Further Curing
Repair/Making Good
Subject to Control of
Non-confroming
Products/Materials
Rectification
Concrete from
Supplier
Receiving
Inspection
Slump
Test?
Reject Concrete to
Supplier
Commencement of
curing (After Demould)
Completion of curing
(After Demould)
Fail
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Making & Curing of
Test Cubes
Exhibit 4 Process Flow Diagram
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39
Finishing
Finishing commenced at about 11:00 a.m.
Each product was specified as requiring either a
smooth or rough finish. Finishing was completed
in two phases. The first phase started immediately
after the pouring operation, while the second
occurred approximately 90 minutes later, because
the concrete finish deteriorated as it settled.
Finishing concluded at approximately 4:30 p.m.
in the summer months. However, in the winter
months, steam curing was required, which
extended this process till about 6:30 p.m. Finally,
the mould was then covered with a canvas
overnight. Each mould was required to cure for
14 hours following the second finishing phase,
before stripping the next morning. If accelerated
steam curing was applied, the curing period could
be reduced to eight hours.
Mould Stripping
The last group of activities was performed the
next morning after curing was completed.
Starting at 8 a.m., the steel mould was vibrated
to separate the mould from the finished precast
slab or facade. The mould and the precast prod-
uct was then rotated 90 degrees, after which the
mould was returned to it normal position on the
plant floor. An overhead crane was used to remove
the precast product to the finished storage area
where “remedial” work was performed to repair
any visual defects. Stripping was usually com-
plete by 10:30 a.m.
Teams often worked on different activities
concurrently. For example, as part of the team fin-
ished the stripping operation, other members of
the team would start the mould setup operation.
Quality was an important element of Unicon’s
operations. The company was first ISO 9002 cer-
tified in 1994. As part of the company’s quality
plan, samples were taken from products through-
out the manufacturing cycle to test for confor-
mance to material specifications.
Capacity Expansion
The current demand for Unicon’s product
lines, facades and slabs in particular, had forced
Mr. Li to evaluate possible options to expand
capacity. Mr. Li was considering the expansion
of the plant by 5,000 square metres in an effort
to double capacity. However, he did not expect
that the expansion could be completed before
August 1998.
The market was in the middle of a boom
and Mr. Li did not want to miss this opportunity.
He was considering two alternatives to expand
capacity in the short-term. First, he could add a
second shift. Mr. Li wondered how this would
affect quality and customer responsiveness.
Furthermore, he was concerned about how his
organization would cope with such a change
and what the additional costs of such a plan
would be.
The second alternative was to re-allocate
plant space. Plant space currently dedicated to
the production of stairs and partitioning walls
could be converted to slabs and facades. The dif-
ficulty of this strategy was that Unicon would
be abandoning two products, and Mr. Li was
concerned that such a move was short-sighted.
However, with the plant expansion, the opportu-
nity existed to re-enter the partitioning wall and
stairs markets in the future.
STRATEGY TO
PURSUE A BLANKET APPROVAL
Mr. Li was considering a strategy whereby
approved technical submissions for HKHA
projects could be resubmitted for future projects
and would not require review and approval by an
RSE or government authority. Mr. Li explained
his logic:
Despite the fact that the design has been used for
10 previous projects, you still have to submit it for
approval. This costs both time and money.
We want to get approval for future contracts if
the design has been previously approved by the
HKHA. Of course, we would still have to submit
our plans for record purposes, and the general con-
tractor would still expect to see our quality plan
and method statement.
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If his plan was accepted, the use of facades
and slabs in superstructure construction would
be similar to that for partitioning walls and
stairs. Unicon would still be required to submit
technical drawings for record purposes, but
avoid the long, expensive review process. Mr. Li
anticipated that on a typical contract, cost
savings for one housing block would be about
HK$150,000.
Mr. Li could see additional opportunities
for savings if his plan was implemented. For
example, lead times could be reduced by
approximately one month. This represented the
delays Unicon experienced as part of the
approval process. Furthermore, the company
could extend its product standardization. Minor
changes to moulds based on individual com-
ments from engineers would no longer be a
concern. From Mr. Li’s perspective, the deci-
sion regarding his efforts to establish a blanket
approval process was obvious:
This will reduce our costs as the engagement of a
RSE incurs expenses in the form of professional
fees. Another big advantage is that I won’t have to
wait for an order to support production. There are
no significant disadvantages that I can see.
THE FUTURE
Mr. Li was concerned with the matter of estab-
lishing the blanket approval process with the
HKHA. He wondered if this was an appropriate
move for the company; there were still several
lingering issues in his mind. What implications
would it have for his manufacturing operations?
How would such a move impact Unicon’s
competitive position in the marketplace? In the
short-term, his order book was full. However,
Mr. Li knew that the marketplace would
adjust, and he wondered about the long-term
implications.
He felt that two issues had to be resolved.
First, should he continue with his plans to estab-
lish a blanket approval? When he contacted
others in the precast industry, no one seemed
interested in working to develop industry-wide
standards. Second, if so, how could he convince
the HKHA to accept his recommendation? The
chief architect of the Design and Standard
Section at the HKHA had the authority to
approve such a proposal. However, he would
need to demonstrate the mutual advantages of
his plan.
Mr. Li expected that it would take approxi-
mately four months to negotiate a blanket
approval arrangement with the HKHA. He knew
that the process would have to be initiated
quickly, if this arrangement was to be in place
in time to take full advantage of the booming
market expected next year.
NOTE
1. In November 1997, HK$1 was equivalent to
US$0.1290 and C$0.1818.
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