Collaboration Mechanism for Shared Returnable Transport Items in
Closed Loop Supply Chains
Fatima Ezzahra Achamrah
1,2
, Fouad Riane
1,2,3
, Abdelghani Bouras
1,2
and Evren Sahin
2
1
Complex Systems and Interactions, Ecole Centrale Casablanca, Casablanca, Morocco
2
Laboratoire Génie Industriel, Centrale Supelec, Paris Saclay University, France
3
Laboratory of Industrial Management and Innovation (LIMMII), University Hassan Premier, Morocco
Keywords: Collaboration Mechanisms, Closed Loop Supply Chain, Simulation, Returnable Transport Items.
Abstract: This paper addresses a relevant practical approach of collaboration in supply chains including reverse flows
of materials. The objective is to simulate a two-stage closed loop supply chains in which two producers use
reusable pallets to distribute their finished products to the same retailers. The producers supply raw materials
and new pallets they need from suppliers. For each producer, the flows of raw material, loaded/empty pallets
and finished products are triggered by information flows. Two simulation models are considered. In the first
model, supply chains are non-collaborative. Each producer manages his own pool of pallets. After receiving
replenishment orders, trucks deliver loaded pallets and simultaneously pick-up empty ones from retailers to
be returned to the producer. In the second model, the two producers share their pool of empty pallets. The
results show that collaboration can lead to economies of scale and costs reduction. They also highlight the
need for a third party to manage the entire system to promise mutual benefits for the concerned parties.
1 INTRODUCTION
A supply chain consists of a set of players including
raw material suppliers, manufacturers, wholesalers,
carriers, distributors and retailers. These entities are
involved in a series of processes and activities to get
a product or service to the customer. Supply Chain
Management (SCM) is generally recognized as the
biggest source of benefits for organizational
activities. It has also been the subject matter of many
papers in research literature in the fields of operations
management, operations research and economy since
supply chains are getting more complex.
Until now, to counteract complexity in supply
chains, the management emphasis has been on
exchanging information and coordinating the flow of
products between organizations. This is no more
enough to cope the increasing customer expectations,
the trend of online shopping and the pattern of
strongly individualized customer demand. The
growing complexity of most services and products
requires the use of more advanced (and costly)
resources. These resources can profit from large
economies of scale, which can be better caught if
resources are shared between organizations. The next
logical step is no longer focus only on coordinating
products and information flows, but also on sharing
assets in order to obtain maximum efficiency.
Increased concerns about the environmental
impact give rise to the emergence and the
development of the concept of closed-loop supply
chains (CLSC). A closed-loop supply chain consists
of both traditional forward activities and additional
return flow processes. The return flow under study in
this paper concerns Reusable Transport Items (RTI).
RTI consist of all means used to assemble goods for
transportation, storage, handling and product
protection in a supply chain that returns goods for
further usage (Iassinovskaia, et al., 2016). Examples
include pallets as well as all forms of reusable crates,
trays, boxes, barrels, trolleys, pallet, etc.
As RTI are by their very nature reusable, they
flow in a closed loop within the supply chain: they
can be collected and returned empty to the sender, or
they can be reused by the receiver so that he can in
his turn ship his products. Therefore, there exist two
types of flows that must be managed simultaneously
(Talaei and al., 2016): forward flows, which
correspond to the traditional distribution of goods
loaded on RTI, and reverse flows, which correspond
to the picking up of empty RTI. Players act as
independent intermediaries to manage the processing
Achamrah, F., Riane, F., Bouras, A. and Sahin, E.
Collaboration Mechanism for Shared Returnable Transport Items in Closed Loop Supply Chains.
DOI: 10.5220/0009162402470254
In Proceedings of the 9th International Conference on Operations Research and Enterprise Systems (ICORES 2020), pages 247-254
ISBN: 978-989-758-396-4; ISSN: 2184-4372
Copyright
c
2022 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
247
of flows between manufacturers and distributors via
logistics service providers (LSPs). This management
requires tools for identifying assets, centralising
information flows, planning of production, delivery
and pick-ups, synchronisation of operations
according to the requirements of each actor, tracking
and traceability of products. This centralisation of
flows enables the pooling of services and resources
with a perspective of sharing between several actors.
The management of RTI is still far from being
controlled. The challenges are enormous given the
costs of managing froward and reverse flows, sorting,
handling and costs due to losses. The drive for cost
reduction coupled with the willingness (not to say the
constraint) to track assets makes auxiliary resources
such as RTI a crucial issue that can impact the
performance of the whole supply chain. Indeed, a
stock shortage of these RTI or a delay in the supply
or in the return leads to a delay in production or even
an interruption of product flows, with all the
consequences that this entails. In addition, their
mismanagement lengthens lead times and encourages
players to over-invest in these assets. Their difficult
identification increases idle inventory and
counterfeiting. In addition, their mishandling impairs
the quality of the products shipped. Finally, the key
players in the chain, in a growing concern to
participate in sustainable development, are concerned
about controlling natural resources and preserving the
environment, by promoting sharing RTI, which
considerably reduces the costs of storage, stock-outs,
and the production of packaging waste.
Consequently, companies are increasingly
wondering the possibility of joining their forces and
sharing their RTI assets to develop an unsurpassably
competitive advantage. Sharing RTI can boost the
competitiveness of the entire supply chain while
decreasing the cost of sourcing, inventory and
transportation. The consequent savings allow players
to achieve higher outcomes.
The main objective of this paper is to provide a
what-if analysis of a two-stage closed loop supply
chains where two non-competing manufacturers
deliver their products using compatible, similar and
smart RTI to a network of common retailers. A
simulation approach is used to quantitatively evaluate
the pros and cons resulting from collaboration and
RTI sharing.
The remainder of the paper is organized as
follows. The related literature is briefly reviewed in
section 2. The problem is described in section 3. In
section 4 the experimental design is provided, and the
results are presented in section 5. Section 6 concludes
the paper recalling the major’s takeaways and
research perspectives for further research in this area.
2 RELATED WORK AT GLANCE
Collaboration among companies is classified by using
certain characteristics.Direction (vertical/horizontal),
time horizon (short/middle/long term), functional
cooperation (joint functions vs. complementary
functions), degree of legal arrangements (from formal
contracts to informal agreements), and the number of
involved parties (Freitag et al. 2016).
Regarding direction there exist three types of
collaboration: Vertical, Horizontal and Lateral
collaboration. The term supply chain management
refers to vertical collaboration and integration among
parties in different levels of a supply chain. “The key
drivers of cost savings are inventory and transport
reduction, logistics facilities or equipment
rationalization, and sharing information” (Cruijssen,
2006). Vertical cooperation includes for example
Collaborative Planning, Forecasting and
Replenishment (CPFR), Vendor Managed Inventory
(VMI), etc. Horizontal collaboration takes place
between companies operating at the same level of the
supply chain. Some examples of application are
Manufacturer Consolidation Centers (MCCs), joint
route planning, and purchasing groups. Co-opetition
is a variant of horizontal cooperation. It takes place
when enterprises are simultaneously cooperating and
competing. It concerns no-core activities while
competition remains unchanged for core activities
(Bengtsson and Kock, 1999). Finally, lateral
cooperation is defined as a combination of vertical
and horizontal cooperation (Simatupang and
Shridharan, 2002). It aims at gaining more flexibility
by combining and sharing capabilities in both vertical
and horizontal directions.
According to (Freitag et al. 2016), physical assets
sharing turns out to be a new type of collaboration and
the most flexible one, while the contractual
complexity of the required legal regulations between
the companies is kept low. It can be a short, mid- to
long-term collaboration and be set up either
vertically, horizontally or laterally. Basically, every
ICORES 2020 - 9th International Conference on Operations Research and Enterprise Systems
248
Figure 1: Simulation modelling flowchart of a two-stage closed loop supply chain.
asset can be sharable, e.g., machine, warehouse,
transport means, returnable transport items (reusable
pallets, boxes; crates, etc.), production line, etc.
The most closely aligned work with this paper is
the research stream that addresses physical assets
sharing particulary RTI as a part of horizontal
collaboration. (Reaidy, et al. 2015) and (Makacia, et
al. 2017) study collaborative warehousing schemes.
(Yilmaz, Savasaneril, 2011), (Pan, et al. 2019) and
(Wang, et al. 2018) examine transportation resource
sharing between independent and non-competing
companies. (Mlinar, Chevalier, 2016), (Becker,
Sterna, 2016) and (Khajavi, Holmström, 2017)
investigate machinery and production capacity
pooling. As for RTI, all papers address the problem
as a part of VMI and/or develop decision supports
models for costs reduction within a stochastic or
deterministic environment. An example of
application can be found in: (Kim, et al. 2014), (Cobb,
2016), (Iassinovskaia, et al. 2016).
As far as we are concerned, this literature review
shows that few papers exist that evaluate the
performance of sharing physical assets between
different supply chains let alone in closed loop supply
chains and in managing the so-called returnable
transport items. Indeed, most of the paper address
problems where coordination is based either on
sharing of information or on joint decision-making.
This paper addresses a relevant practical approach of
horizontal collaboration in closed loop supply chains
including sharing returnable transport items.
3 PROBLEM DESCRIPTION
Simulation has been identified by numerous authors
as an effective tool to evaluate collaboration
mechanism design in supply chain (Pirard, et al
2011). This technique makes it possible to take into
account the complexity and the dynamic behavior of
a system and to consider the uncertainty related to its
environment (e.g. customer demand, lead time).
Simulation also enables the decision maker to
evaluate several control policies. Numerous
replications of the simulation model, corresponding
to many possible situations, can be carried out in
order to evaluate the robustness of the considered
design. Simulation does not guarantee an optimal
design. However, this technique offers the manager
real help in establishing and in evaluating the
consequences of his decisions. We devote the
reminder of the paper to explain the simulation model
we developed in order to highlight the benefits of
promoting RTI sharing. The advantages of economies
of scale can be viewed in terms of cost savings and
better operational performance. The supply chain
players can achieve a higher service level at lower
Collaboration Mechanism for Shared Returnable Transport Items in Closed Loop Supply Chains
249
costs if they agree on a suitable collaboration
mechanism.
In this paper we study a two-stage supply chain in
which two non-competing manufacturers deliver
their products to a network of common retailers using
compatible, similar and smart RTI, namely pallets.
The simulation model we be built captures the
supply chain physical entities at the different levels,
the material and information flows between entities
and the different decisions made at each level by each
manufacturer or retailer. The architecture of the
simulation model that corresponds to the two-stage
supply chain is depicted in figure 1. When a retailer
receives information on the demands of his
customers, he checks whether his stock of non-
palletized finished products is enough to meet them.
If not, he depalletizes the stock of loaded pallets. If
the stock reaches its replenishment point, or a new
demand has unmet finished product requirements, he
sends a replenishment order to a producer. When a
producer receives this order, he checks whether his
stock of finished and palletized products is enough to
satisfy the demand of his customer. If the quantities
requested exceed the available quantities, the
producer releases a production order. In the same
veins, at the level of each producer if the quantity of
raw material or the quantity of empty pallets is less
than a minimum inventory, a producer sends a
replenishment order to suppliers. Thereafter, the
trucks, loaded with the ordered pallets, leave the
depot and visit retailers to deliver loaded pallets and
simultaneously collect a quantity of empty pallets -as
long as the capacity of trucks is not exceeded.
We evaluate two scenarios. The first corresponds
to the non-sharing case. Each producer manages
separately his own pool of pallets. When a producer
(manufacturer) receives replenishment orders from
retailers, he puts trucks on way to deliver loaded
pallets and simultaneously pick-up his empty ones to
be returned. Empty pallets are stored separately at the
retailer location.
We consider a second case where the two
producers can share their pool of empty pallets. The
pallets are considered to be substitutable and there is
no need to keep them in sperate storages at costumer
locations. The quantity of empty pallets, collected by
each producer’s trucks, is whenever possible equal to
the quantity of full pallets delivered. In terms of
profits sharing, we suppose that each partner pays a
certain amount of dollars for each pallet used and
owned by the other producer. The damage of the
pallets is also supported. Each producer pays a
penalty cost per damaged pallet.
In a previous work (Iassinovskaia, et al. 2016), we
have studied a two-stage supply chain where non-
shared RTI are used to protect and distribute products
from a manufacturer to a set of customers. We
modelled the problem as a pickup and delivery
inventory-routing problem. We formulated a mixed-
integer linear program (MILP) taking into
consideration different constraints inherent in
transport, routing construction, truck and inventories
capacity and demand satisfaction. The objective
function to optimize is a combination of
transportation costs, inventory costs of empty and
loaded RTI at customers and at the depot,
maintenance costs and the cost to buy new RTI.
We have extended the scope of the problem to
include a set of manufacturers and developed a
mathematical model for solving an inventory routing
problem where RTI are shared between
manufacturers (Achamrah, et al. 2019). In the present
contribution, we would like to extend the scope of the
problem to focus on the global loss of efficiency that
supply chain players may experience. This can be
induced by the distributed nature of their decision
structure and their independent- not to say conflicting
objectives and way of operating that may hinder the
search a win-win agreement. Simulation makes it
possible to take into account the complexity and the
dynamic behavior of the system and to consider the
uncertainty related to its environment (e.g. customer
demand, lead time at each level).
4 EXPERIMENTAL DESIGN
We consider two manufacturers who manage
independently their pool of pallets and deliver to the
same set of 9 retailers. The simulation horizon
corresponds to 7 days. Trucks have a similar capacity
of 20 pallets to be loaded. Each pallet contains 8
boxes filled with finished products. The different
pallet storage locations have been designed with a
capacity of 1000 in terms of number of pallets. The
same goes for holding capacities of finished products
at the level of each producer and retailer.
A replenishment order for each retailer is an
inventory level less than or equal to 5 in terms of the
number of loaded pallets. As for manufacturers, the
replenishment order regarding empty pallets is an
inventory level less than or equal to 10. And the
replenishment order regarding raw material is an
inventory level less than or equal to 15. For both
producers, the order production point is an inventory
ICORES 2020 - 9th International Conference on Operations Research and Enterprise Systems
250
Table 1: Service level at the level of producer 1 and producer 2 for each scenario under consideration.
Table 2: Service level at the level of retailer 1, 2 and 3 for each scenario under consideration.
Retailer 1 Retailer 2 Retailer 3
Lost
sales
Product
1
Product
2
Satisfied
demands
Product
1
Product
2
Service
level
(%)
Product
1
Product
2
Lost
sales
Product
1
Product
2
Satisfied
demands
Product
1
Product
2
Service
level
(%)
Product
1
Product
2
Lost
sales
Product
1
Product
2
Satisfied
demands
Product
1
Product
2
Service
level
(%)
Product
1
Product
2
Non-
collaborative
supply
chains
1007
10
945
902
48.4
98.9
188
475
567
2035
75.1
81.1
286
206
526
942
64.8
82.1
Collaborative
supply
chains
318
912
1634
912
83.7
100.0
111
80
644
2430
85.3
96.8
199
0
613
1148
75.5
100
level less than or equal to 4 in terms of the number of
loaded pallets.
At the level of each retailer depalletization order
corresponds to an inventory level of finished products
less than or equal to 5. The demand the retailers have
to satisfy is assumed to be a random variable with a
normal distribution of mean of 13 and standard
deviation of 2 in terms of the number of finished
products of the producer 1 and a normal distribution
of mean of 20 and standard deviation of 2 in terms of
finished products of the producer 2. Palletization
order at the level of each producer corresponds to an
inventory level of loaded pallets less than or equal to
10. At the beginning of the simulation, the initial
inventory level of empty pallets at producer 1 is equal
to 30 and equal to 35 at level of producer 2. The initial
inventory level of finished products at producer 1 is
equal to 90 and equal to 60 at level of producer 2. The
initial inventory level of raw material is equal to 40 at
the producer 1 and to 30 at the producer 2. The initial
inventory levels of empty pallets and finished
products at the level of each retailer are equal to zero;
For both producers and retailer, the initial inventory
level of loaded pallets is equal to zero;
For both producer the cost to buy a new pallet is
$15/pallet. In terms of profits sharing, we suppose
that each producer pays $1.5 per period for each pallet
used and owned by the other producer. Each producer
pays $3 per unowned and damaged pallet. Lost sales
cost of $8 associated to each unsatisfied demand at
level of each producer.
5 ANALYSIS AND DISCUSSION
To assess each scenario, we selected the following
criteria: (1) Lost sales in terms of the number of filled
pallets at the level of each producer and in terms of
the
number of boxes at the level of each retailer ; (2)
Satisfied demands in terms of the number of filled
pallets at the level of each producer and in terms of
the number of boxes at the level of each retailer; (3)
Service level at each producer and retailer; (4) Cost to
buy new pallets; (5) the savings, loss and pay-out at
level of each producer.
All the simulation steps have been performed on
a personal laptop computer (Windows10, Intel Core
i5, 2.4GHz, 4GB of RAM) and with FlexSim 19.2.3.
-
Producer 1 Producer 2
# of new
purchased
pallets
Lost
sales
Satisfied
demands
Service
level (%)
# of new
purchased
pallets
Lost
sales
Satisfied
demands
Service
level (%)
Non-
collaborative
supply
chains
924 288 874 75.2 1123 284 906 76.1
Collaborative
supply
chains
690 105 1057 91.0 852 86 1104 92.8
Collaboration Mechanism for Shared Returnable Transport Items in Closed Loop Supply Chains
251
Table 3: Service level at the level of retailer 4, 5 and 6 for each scenario under consideration.
-
Retailer 4 Retailer 5 Retailer 6
Lost
sales
Product
1
Product
2
Satisfied
demands
Product
1
Product
2
Service
level
(%)
Product
1
Product
2
Lost
sales
Product
1
Product
2
Satisfied
demands
Product
1
Product
2
Service
level
(%)
Product
1
Product
2
Lost
sales
Product
1
Product
2
Satisfied
demands
Product
1
Product
2
Service
level
(%)
Product
1
Product
2
Non-
collaborative
supply
chains
331
139
571
245
63.3
63.8
46
289
170
134
78.7
31.7
325
88
364
522
52.8
85.6
Collaborative
supply
chains
98
37
804
347
89.1
90.4
19
124
197
299
91.2
70.7
268
73
421
537
61.1
88.0
Table 4: Service level at the level of retailer 7, 8 and 9 for each scenario under consideration.
-
Retailer 7 Retailer 8 Retailer 9
Lost
sales
Product
1
Product
2
Satisfied
demands
Product
1
Product
2
Service
level
(%)
Product
1
Product
2
Lost
sales
Product
1
Product
2
Satisfied
demands
Product
1
Product
2
Service
level
(%)
Product
1
Product
2
Lost
sales
Product
1
Product
2
Satisfied
demands
Product
1
Product
2
Service
level
(%)
Product
1
Product
2
Non-
collaborative
supply
chains
184
91
571
333
75.6
78.5
279
498
841
1960
75.1
79.7
255
258
2435
164
87.3
86.3
Collaborative
supply
chains
144
42
611
382
80.9
90.1
211
102
909
2356
81.2
95.9
175
31
2615
391
93.7
92.7
The number of replicate simulations is equal to
100. We analyse the effectiveness of the mechanism
under consideration assuming the following
assumptions:
All the empty pallets present in the inventory at
the end of a period can be reused in the next
period;
10% of pallets returned from retailers in each
period are considered damaged (unrepairable);
Routing of trucks are not optimized and are
randomly constructed;
Processing time required for palletization at the
level of each producer includes the time
necessary for sending replenishment orders to
suppliers and for receiving the ordered quantity
of new pallets and also the time to palletize
finished products.
As mentioned earlier, in this paper we consider two
producers who manage independently their pool of
pallets and deliver to the same set of retailers. After
receiving a replenishment order, they deliver loaded
pallets to a set of 9 retailers and collect
simultaneously empty pallets. The mechanism
thereafter by which the collaboration is established
between the two producers is examined.
Table 1, 2, 3 and 4 summarize the results of
simulation for all cases under consideration.
As we can notice and taking into account the 10%
of pallets damaged at each period, sharing pallets
allows both producers to reduce the number of pallets
bought from suppliers. Indeed, each producer can
replace the same quantities of new empty pallets he
needs to palletize by the substituted quantities of
empty pallets of the other producer. As a result, the
service level is enhanced. Furthermore, sharing
allows them to deliver more loaded pallets to retailers
(the number of the replenishment orders is increased)
and hence, enhance the service level at the level of
each retailer. It also enables to increase processing
time. Indeed, this processing rate includes, in addition
to the time required for palletization, the time
required for each producer to send replenishment
orders to suppliers and to receive the ordered quantity
of new pallets. Since each producer can use the other's
ICORES 2020 - 9th International Conference on Operations Research and Enterprise Systems
252
Table 5: Breakdown of costs at the level of producer 1 and 2 for each scenario under consideration.
Cost break down
($)
1
st
scenario:
non-collaborative supply
chains
2
n
d
scenario:
collaborative supply
chains (sharing pallets)
Producer 1 Producer 2 Producer 1 Producer 2
New pallets cost 13 860 16 845 10 350 12 780
Saving (regarding the purchased pallets) - - 3 510 4 065
Pay-out (include the costs resulting from
the use and/or the damage of unowned pallets)
- - 3 455 4 639.5
Lost sales 2 304 2 272 840 688
Saving (regarding buying new pallet and
the lost sales)
- - 4974 5649
Gain 334.5
2 194
pallets, he does not always have to buy the pallets
from the supplier each time his stock of empty pallets
reaches its replenishment point. Thus, processing
time is spent more on palletizing. This means that
palletizing and responding to retailers’ replenishment
orders can be done faster and more efficiently.
Table 5 gives more insights on the efficiency of
pallets sharing. The saving, loss and pay-out are
deducted according to the profit-sharing policy
adopted in this paper.
From the table 5 we notice that by minimizing the
number of pallets bought, sharing pallets allows both
producers to realise economies of scale and reduce
the cost of purchasing new pallets as compared to the
first scenario. As the one can see, producer 2 benefits
more from sharing as compared to the producer 1
(
$2 194 vs $334.5). Therefore, for a better coordination
and profit allocation, it would be convenient to call
upon a third-party service provider to manage the
whole system. Indeed, if a player would be in charge
of deliveries and pick-ups, inventory and transport
costs and the resulting carbon footprint would be
reduced. In this way, all parties including the
suppliers would benefit from the gains. Regarding the
share of information flows, if a player exists, he
would manage all the inventories and replenishments
orders. Then, he would synchronize the different
flows so that the inventory cost at all levels would be
reduced. Future studies can help to understand the
impact of the presence of a player on the performance
and behaviour of collaborative supply chains.
6 CONCLUSIONS
This paper addresses the issue of sharing physical
assets between independent producers in a two stages
supply chain. We design a simulation model to
investigate different ways players can manage their
reusable transport items within a closed loop supply
chain. The model compares two cases. The first case
considered two producers working autonomously and
delivering their finished products using pallets to the
same retailers. The second scenario considers sharing
the pool of empty pallets between producers as a
mechanism of collaboration. Material and
information flows, the inventory and transportation
costs at the level of each producer are analysed and
assessed in order to get insight on the effectiveness of
coordination. The result of simulation shows that the
coordination lead to economies of scale and cost
reduction. It also rises the need for a third party to
manage the whole system for promising mutual
benefits to the members.
Our future research plans include studying the
effect of resources sharing in a more complex supply
chains where uncertainties and risks are exposed, and
cooperative games are analysed using shapely value
for example which may allow to assess different
collaboration mechanisms starting from sharing
information to sharing trucks, warehouses and
machineries. On the other hand, managing the whole
supply chains and evaluating the performance of
supply chain requires a player. Various scenarios may
be explored with the help of simulation.
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