AP03_5.vp


1 Introduction
Due to global competition, industrial companies need to

develop competitive products in a shorter time. The methods
of Integrated Product Development are aimed at supporting
designers in this endeavour [2]. The methods and tools of
Integrated Product Development are objects of investiga-
tion in design research. The circumstances in an industrial
environment, such as time pressure and immense quality
requirements, necessitate an effective and efficient approach.

Fig. 1 illustrates possible stages in the product develop-
ment process. The x-axis represents the life cycle of a product.
The y-axis represents the requirements which are not fulfilled
yet (maximum number at the beginning of a project), or the
failures which have occurred.

Curve 1 shows a trouble free procedure. The conceptual
design of the product is detailed step by step according to the

design approach analysis, searching solutions, evaluating and
selection. Before launch deadline the product meets all crite-
ria required by the customer.

Curve 2 represents a project which is characterised by
some failure. To handle the situation, the results of preventive
measures (i.e., FMEA) are implemented.

Curve 3 exemplifies a project disturbed by extensive fail-
ures. Compared to curve 2, the results of preventive measures
are not applicable. This situation is well known in industrial
practice. Despite methods of risk management and quality
management, troubleshooting situations caused by product
failure occur in the product development process. This can
be due to time reasons: it is impossible to consider all possi-
ble contingencies within the scope of quality management.
As shown in Fig. 1, the time for searching a solution is very
short (the worst case would be a serious failure after prod-
uct launch). Therefore there is extremely high pressure to
succeed.

Curve 3 is a case for troubleshooting. An error has oc-
curred which seriously endangers the success of the project
extremely.

The basic steps of conventional product development are
usually supported by methods and tools. Methods for system-
atic searching (i.e., a list of physical effects) and creativity tech-
niques (i.e., brainstorming, TRIZ) support the design teams
in the phase of solution searching. The goal is to create a lot of
innovative solutions.

Afterwards the ideas are evaluated. The criteria for evalu-
ation result from the customer’s requirements and the
economic and technical feasibility. Depending on the level
of detail of the solutions, and on the number of solutions
some provisional criteria are considered for evaluation. Ac-
cordingly, simple or more extensive evaluation methods can
be used.

In troubleshooting situations, time spent on creating
ideas which are not appropriate for solving the problem
is lost. Due to the fact that the problem occurs shortly be-
fore or after product launch, a characteristic feature of

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Acta Polytechnica Vol. 43  No. 5/2003

Reducing Time for the Product
Development Process by Evaluation in
the Phase of Solution Searching
B. Jokele, D. K. Fuchs

Less and less time is available for product development process. To prevent product failures and the resulting time intensive and cost
intensive iteration steps, some preventive measures must be taken. Within the scope of quality management, FMEA anticipates possible
problems concerning product and process properties. Nevertheless, in industrial practice designed products can have failures which were not
considered within FMEA. The time pressure is immense, and efforts which do not make a contribution to a successful solution are regarded
as lost time.
This paper introduces a systematic approach to troubleshooting, with the aim of reducing the time for solution searching by considering the
feasibility of ideas at an early stage.

Keywords: troubleshooting, change management, concurrent use of methods.

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Fig. 1: Possible stages in product development process



a troubleshooting situation is lack of time. Furthermore,
engineering change costs rise progressively during prod-
uct development [2].

The inadequacy of an idea frequently results from lack of
feasibility. This can be due to manufacturing tools which
would be necessary but are not available. Another reason can
be a very high level of risk, because the company has no expe-
rience with the technical princip of an innovative idea, and
appropriate testing tools are lacking.

The established approach and the established methods
and tools do not take these boundary conditions into account.
Therefore, there is a growing need for a systematic approach
and an adaptation of methods, aimed at avoiding time and
cost intensive iterations in troubleshooting phases.

2 Approach to troubleshooting
situations
Evaluating and searching for solutions should not be

strictly separated [1]. Concurrent searching and evaluating
solutions provide an opportunity to reduce the process time
(Fig. 2).

In order to arrange the solution search more efficiently,
the possibilities of modification should be already considered
within the solution search. The possibilities of modification
reflect themselves in the degrees of freedom of the product
and the degrees of freedom of the process (Fig. 3).

The aim is to concentrate on generating solutions which
can be realised with adequate efforts, and which promise

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Acta Polytechnica Vol. 43  No. 5/2003

Fig. 2: Reducing time by concurrent searching and evaluating

curve III: knowledge about product propertiescurve III: knowledge about product properties

curve I: engineering change costscurve I: engineering change costs

goal of ‚early evaluation

of product properties‘

goal of ‚early evaluation

of product properties‘

curve III: knowledge about product propertiescurve III: knowledge about product properties

curve I: engineering change costscurve I: engineering change costs

goal of ‚early evaluation

of product properties‘

goal of‚ early evaluation

of product properties‘

curve II: design freedom

Fig. 3: General trends relating to design freedom, knowledge about product properties, and engineering change costs (acc. to [2])



a successful troubleshooting outcome. Considering this, the
first step is to identify the company’s specific capabilities,
concerning production, assembly and testing.

The aim is to identify system components which can be
modified with minimum effort. Based on this information, so-
lution searching should concentrate on modifying of those
components.

3 Cause analysis
The first step is to analyse the causes of the problem. For

this purpose the system behaviour should be visualised
(Fig. 4). Usually the unwanted effects give a first indication
of the possible causes. Structuring the problem using the
TRIZ-method, the correlations between the effects of system
components are represented by an arrow. An arrow linking
two effects means that one effect is caused by the other (i.e.,
effect 1 is caused by effect 4). No other types of arrows are
used, because the visualisation should be as simple as possi-
ble. This ensures that the information can be communicated
easily to other persons who are or will be involved in the pro-
cess of problem solving. It is important to identify parts or as-
semblies of the product which are associated with the effects.
Based on this visualization of system behaviour, it becomes
apparent which system components are causing the fail-
ure, or which system components are affected.

4 Identifying the degrees of freedom
of the product
As mentioned above, the degree of design freedom de-

creases during the development process with increasing level
of detail of the product. Change management deals with basic
aspects of the effects caused by changing the system compo-
nents. A small initial change can instigate numerous other
changes, which may have serious cost implications [3]. There-
fore, in a troubleshooting situation the impact of the changes
has to be considered. The aim is to solve the problem without
causing too many changes. For this purpose the system com-
ponents have to be analysed concerning their impact and the
expected success in solving the problem. The results of this
analysis are shown as an example in Fig. 5.

5 Identifying the degrees of freedom
of the process
The next step is to identify the process steps which can

be modified easily. For this purpose it is necessary to record
the company’s manufacturing and assembly capabilities. De-
pending on the level of detail of the product, the modification
of some process steps is eliminated. For example: if expensive
tools have already been bought, changing the tool would have
intensive cost implications. Furthermore, it is not advisable to
use new process steps without experience. In a troubleshoot-
ing situation, the risk of yet another failure has to be reduced.

6 Searching solutions by expressing
questions
Degrees of freedom are not just a basis for obtaining crite-

ria for evaluation. The fundamental idea is to use the degrees
of freedom systematically in searching for solutions. It seems
beneficial to present some aims of a problem solver in terms
of simple structures of problems [4]. In the style of TRIZ, a
systematic approach is to express terms which simulate the
designer to create solutions according to realistic possibilities.

On the basis of the earlier steps, the table in Fig. 6 lists
the degrees of freedom. An appropriate term is expressed :

”Try to find a solution by modifying /component X/
by /process-step Y/.”

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Acta Polytechnica Vol. 43  No. 5/2003

Fig. 4: Structuring of the problem

Fig. 5: Matrix for prioritisation Fig. 6: Morphological box of degrees of freedom



This ensures that the focus in solution searching is on
realistic ideas. Not the most innovative idea, but the most
efficient idea is sought.

7 Example: troubleshooting in the
automotive industry

In cooperation with an automobile supplier the procedure
was applied in practice. A new product was derived from an
earlier successful product. However, the redesigned product
did not maintain the product quality. The main problem was
some unwanted acoustic effects, caused by an unexpected gap
between two parts of the product.

This problem occurred just before the start of production.
Cost-intensive forming tools had already been installed. The
customer was dissatisfied und demanded a quick solution.

The first meeting a cause analysis. Specialists in technical
design, manufacturing and assembly analysed the situation.
It was found that the gap was caused by a difference in
temperature of the parts. Compared to the earlier design, the
length of an edge of the redesigned product was longer. Due
to this, the expansion effect had a greater influence and
caused the gap.

In the subsequent analysis of degrees of freedom, it be-
came clear that modifications could hardly be realised.
Geometric modification of the affected parts would have
involved cost- intensive modification of the forming tools.

One option which resulted from the degrees of freedom
was:

”Try to prevent the gap by modifying part A by welding.”

The answer to this question produced quite simple solu-
tions which were easy to realise. By welding the two parts,
the expansion and thus the gap could be prevented. There
was no unwanted acoustic effect anymore. The company has
a lot of experience in welding, and has the appropriate
tools. The customer was satisfied and production started as
scheduled.

8 Conclusions and/or
recommendations
A troubleshooting situation is characterized by intensive

time pressure. Thus, not so much innovative as practicable
solutions should be the aim of product development in this
situation. In conventional product development procedures
the search for a solution is followed by an evaluation of the
generated ideas. An important criterion in the evolution
phase is the necessary effort, taking into account technical
realisation and the cost impacts.

The degrees of freedom concerning product and process
should be taken into account, leading to the development
of suitable solutions. The introduced approach reduces the
time for solution searching and feasibility studies, and is
appropriate not only in troubleshooting situations but also
in ordinary product development process.

References
[1] Wulf, J.: Elementarmethoden zur Lösungssuche. München:

Dr. Hut 2002. (Produktentwicklung München, Bd. 50);
Zugl. München: TU, Diss. 2002.

[2] Stetter, R.: Method Implementation in Integrated Product
Development. München: Dr. Hut 2000. (Produktent-
wicklung München, Bd. 41); Zugl. München: TU, Diss.
2002.

[3] Clarkson, J. et al: Prediction for Product Redesign. Proceed-
ings of ICED 2001.

[4] Savransky, S.: Engineering of Creativity. CRC Press LLC
2000, ISBN 0-88493-2255-3.

Dipl. Ing. Bernd Jokele
e-mail: jokele@pe.mw.tum.de

Dipl. Ing. Daniel-Karl Fuchs

Lehrstuhl für Produktentwicklung
Technische Universität München
Boltzmannstrasse 15
85748 Garching
Germany

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Acta Polytechnica Vol. 43  No. 5/2003