Supply chain resilience: a simulation study.
Carvalho, Helena ; Barroso, Ana Paula ; Machado, Virginia Helena 等
Abstract: This paper aims to analyze the supply chain behavior when
subject to disturbances using a simulation-based approach. The
disturbance explored in this study is the transportation interruption
between two suppliers in the automotive supply chain. The performance of
the different supply chain entities is used to analyze supply chain
design scenarios. The analysis of the outputs simulation study shows
that even when a redundancy strategy is used, the negative effects of a
disturbance are spread along the supply chain, but the resilience of
supply chain entities is enhanced. Key words: supply chain management,
resilience, case study, simulation
1. INTRODUCTION
Rupture conditions in supply chains (SC) are observed when SC
entities are subject to disturbances, caused by sudden and unforeseen
events. An example of disturbance event is September 11, 2001, where the
New York's World Trade Center Towers were destroyed by terrorist
attack. Automakers like Ford and Toyota had to stop their production
lines in US facilities due to part delays coming from foreign countries
(Sheffi, 2001). Others types of less catastrophic but highly severe
disturbances, could also occur; like the Robert Bosch GmbH example where
in 2005 a quality defect in a small part supplied by another SC entity
resulted in the recall of several thousands of cars (Wagner & Bode,
2006). Once the SC is affected by a disturbance, its performance is
jeopardized, that is, the short-term financial performance is reduced,
with a loss of competitiveness (Ji & Zhu, 2008). To sustain
competitiveness, SC entities and their SCs must be resilient, i.e., they
must develop their ability to react to unexpected events and to quickly
return to their original state or move to a new state after being
disturbed (Pettit et al., 2010).
The main objective of this paper is to analyze the SC behavior when
subject to disturbances. To this end a simulation-based approach is
proposed to observe SC behavior under different design scenarios. A case
study related to the simulation of a Portuguese automotive SC is
presented.
2. SIMULATION STUDY
To formulate adequate resilience strategies, it is necessary
considering the disturbances that may lead to poor SC performance. The
simulation models utilization is an effective method for considering the
disturbances occurring in a SC context (Melnyk et al., 2009). The
modeling process is crucial from the SC resilience perspective; the
simulation model should provide adequate performance measures to assess
the system behavior before and after the disturbance occurrence.
In this research, an exploratory case study was conducted at a
Portuguese automotive SC. The automotive SC was selected since it is
extremely vulnerable to disturbances (Thun & Hoenig, 2011). The case
study boundaries were defined after a preliminary interview with the
automaker SC manager. The case study involves only a sub-set of the
automotive SC (Figure 1). The metric fulfillment rate was selected to
evaluate each SC entity performance. The following disturbance was
pointed out as relevant to this study: material transportation
interruption from Supplier 5 to Supplier 3, with duration of seven days.
[FIGURE 1 OMITTED]
To make easier the simulation development, an approach similar to
Pundoor & Herrmann (2006) was used. A set of modules was developed
to model the Source, Make and Delivery processes based on the Supply
Chain Operations Reference Model (Supply-Chain Council, 2009). The
simulation model was developed using the simulation software Arena
together with Microsoft Excel and Visual Basic for Applications. A total
of 10 replications was determined by statistical analysis of the lead
time. One simulation run is for 8 hours per day during a period of 60
days.
3. RESULTS ANALYSIS AND DISCUSSION
The following four SC scenarios have been developed: Scenario
1--current SC design without disturbance; Scenario 2 --current SC design
subject to the disturbance; Scenario 3- a redundancy SC design without
disturbance; and Scenario 4--redundancy SC design subject to the
disturbance. In scenarios 3 and 4 the same SC resilience strategy is
modeled: the inventory level of Material 7 in Supplier 2 is increased
from 3 to 7 days. All scenarios are subject to the same input values,
namely, demand patterns, bill of material, inventory data, resource
data, transportation time and cost data. As stated previously to assess
the SC performance the simulation returns the fulfillment rate for each
SC entity. Figure 2 contains the simulation outputs. In the scenarios
without disturbance (Scenarios 1 and 3) it can be seen that all SC
entities have some fluctuation in their behavior, arising from the
day-to-day uncertainty in the processes.
When the SC is affected by a disturbance, in day 15, with duration
of 7 days, which causes an interruption in the transportation of
Material 7 from Supplier 5 to Supplier 3, the plots have highlight in
color grey the area corresponding to a lower performance. Scenario 2
shows clearly the inability of Supplier 5 to deliver Material 7 on-time
to Supplier 3 when no resilience strategies are applied. The grey area
in Supplier 5 plot clearly shows a decrease of performance after the
disturbance occurrence. Plots of Suppliers 2 and 3 also evidence the
lack of resilience of these entities. However, not all SC entities are
affected by the disturbance. Supplier 1 and Supplier 4 maintain their
normal behavior. Only when the disturbance fades away Supplier 5 is able
to recover the initial state, delivering all the late orders at once,
increasing the fulfillment rate. Supplier 3 is unable to deliver all the
late orders at once, as it requires 4 days to restore its normal
behavior. The behavior of the upstream entities will affect Supplier 2
suffering two waves of material shortage: the first caused by the
disturbance, and the second when Supplier 3 delivers materials after the
disturbance, since the recently delivered material will be used to
produce late orders, leading to another stock-out situation.
[FIGURE 2 OMITTED]
In a SC design based on redundancy, Supplier 2 increases the safety
stock to 7 days (Scenario 3), also increasing the inventory hold cost.
If the disturbance occurs (Scenario 4), all SC entities are able to
fulfill their customer needs, except Suppliers 5 and 3. In this
situation Supplier 2 uses the safety stock to avoid a production
stoppage and deliver the material on time. If the disturbance occurs,
this strategy is effective in overcoming the negative effects, but two
SC entities (Supplier 5 and Supplier 3) change their normal behavior,
being affected by the disturbance negative effects. So, although the
redundancy strategy reduces the disturbance impact it propagates its
negative effects along the SC. These results are in line with the ones
obtained by Tang & Tomlin (2008) which propose flexibility as a
means to reduce the disturbance negative effects, since the redundancies
can hinder SC inefficiencies. The case study results also reveal some
trade-offs in SC design, such as higher performance from having low
inventory in the SC under normal operating conditions, but it increase
the fragility during periods of disruption (Svensson, 2000).
4. CONCLUSION
This paper uses a simulation study to analyze the SC entities
behavior when subject to a disturbance. Taking into account all the
diversity associated with disturbances and cascading unexpected effects
on SC behavior, in this paper the use of simulation is proposed as a
tool to assist the design of SCs for resilience helping to visualize the
negative effects of SC disturbance under diverse scenarios. The case
study results show that even when a redundancy strategy is used, the
disturbance negative effects are spread along the SC, but the resilience
of SC entities is enhanced.
This study has several limitations. The research is related to the
automotive SC and the findings may not be universally applicable across
different sectors with different processes specificities. The main
limitation is related to the system boundaries; only a small subset of
the whole SC was considered. This represents an oversimplification of a
real SC and the actual SC response to disturbances could be difficult to
reveal. Moreover only one SC disruption had been modeled, an
interruption in transportation. Consequently, future studies are needed
to identify the main effects between SC resilience design and SC
performance and the various moderating and mitigating factors. SC design
for resilience remains an important but relatively under-studied area of
SC.
5. ACKNOWLEDGMENTS
This research is funded by Fundacao para a Ciencia e Tecnologia
(Project MIT-Pt/EDAM-IASC/0033/2008). The first author was supported by
a PhD fellowship from Fundacao para a Ciencia e Tecnologia
(SFRH/BD/43984/2008).
6. REFERENCES
Ji, G. & Zhu, C. (2008). Study on supply chain disruption risk
management strategies and model. Proceedings of 5th International
Conference Service Systems and Service Management, ICSSSM'08, June
30-July 2, Melbourne, VIC, ISBN: 978-1-4244-1671-4, pp. 1-6
Melnyk, S., Rodrigues, A. & Ragatz, G. (2009). Using Simulation
to Investigate Supply Chain Disruptions. In Supply Chain Risk, G. A.
Zsidisin & B. Ritchie, (Ed.), 103-122, Springer US, ISBN:
978-0-387-79933-9, Boston, MA.
Pettit, T., Fiksel, J. & Croxton, K. (2010). Ensuring supply
chain resilience: development of a conceptual framework. Journal of
Business Logistics, Vol. 31, No. 1, pp. 1-21
Pundoor, G. & Herrmann, J. (2006). A hierarchical approach to
supply chain simulation modelling using the Supply Chain Operations
Reference model. International Journal of Simulation and Process
Modelling, Vo. 2, No. 3/4, pp. 124-132, ISNN: 17402123
Sheffi, Y. (2001). Supply chain management under the threat of
international terrorism. The International Journal of Logistics
Management, Vol. 12, No. 2, pp. 1-11 Supply-Chain Council, 2009. SCOR
Overview, 9.0 version. Available at: http://supply-chain.org/
Svensson, G. (2000). A conceptual framework for the analysis of
vulnerability in supply chains. International Journal of Physical
Distribution & Logistics Management, Vol. 30, No. 9, pp. 731-750,
ISSN: 09600035
Tang, C. & Tomlin, B. (2008). The power of flexibility for
mitigating supply chain risks. International Journal of Production
Economics, Vol. 116, No. 1, pp. 12-27, ISSN: 09255273
Thun, J. & Hoenig, D. (2011). An empirical analysis of supply
chain risk management in the German automotive industry. International
Journal of Production Economics, Vol. 131, No. 1, pp. 242-249, ISSN:
09255273
Wagner, S. & Bode, C., 2006. An empirical investigation into
supply chain vulnerability. Journal of Purchasing and Supply Management,
Vol. 12, No. 6, pp. 301-312, ISSN: 14784092
