PME

I
J

https://ojs.upv.es/index.php/IJPME

International Journal of 
Production Management 
and Engineering

http://dx.doi.org/10.4995/ijpme.2014.1860

Received 2013-11-11 - Accepted 2013-11-25

Packaging as source of efficient and sustainable advantages in supply 
chain management. An analysis of milk cartons.

García-Arca, J.a,i, González-Portela Garrido, A.T.b,iii and Prado-Prado, J.C.a,ii

a Grupo de Ingeniería de Organización (GIO), Departamento de Organización de Empresas y Marketing. 
Escuela de Ingeniería Industrial, Universidad de Vigo. 

Campus Lagoas-Marcosende, C/ Maxwell, 36310-Vigo. Spain.
i jgarca@uvigo.es

ii jcprado@uvigo.es  

b Departamento de Organización de Empresas y Marketing. 
Escuela Universitaria de Estudios Empresariales, Universidad de Vigo. 

Campus Ciudad, C/ Torrecedeira, 105, 36208-Vigo. Spain.
iii tgonzalez-portela@uvigo.es 

Abstract: In higher competitive markets, the suitable supply chain management (particularly, in logistic and productive 
processes) and the adoption of sustainability programs are strategic points in companies. In this context, no many companies 
have devoted special attention to the impact of packaging design on logistic efficiency and sustainability.  Thus, the integration 
of logistics and the packaging design has been conceptualized in the term «packaging logistics», particularly emphasizing 
its operational and organizational impact on supply chain performance. Going beyond, authors consider that a greater 
emphasis should be given to the important strategic connotations to do with packaging design, in many cases this being 
one of the supports of competitive advantages in the supply chain management from an overall perspective of efficiency and 
sustainability. To illustrate this statement, in this paper, not only the conceptual field of this concept is developed, but also its 
application, analysing different alternatives of products packed in cartons (“briks”) and based on case study methodology.

Key words: packaging, supply chain, logistics, sustainability, carton. 

1. Packaging and supply chain
Companies must face with the challenges, not only 
in terms of new products and processes, shorter 
life cycles or increased commercial range, but also 
in terms of the demand for ever lower prices, with 
increasingly improved quality and service standards. 

In this context, many organizations are searching for 
a more efficient management of their supply chains 
as a source of competitiveness (Christopher, 2000).

In the last few years, companies also have to deal 
with two situations of strong impact on supply 
chains’ efficiency: globalization of supply chains 
and the continuous increased costs of raw materials, 
particularly, the oil. 

The combination of these two phenomena is 
important because, strategically, underscores the 

urgency of action in pursuit of maximum performance 
in logistics activities undertaken across the supply 
chain (transport, handling, storage, production, ...), 
eliminating activities that do not add value to the 
market (in line with "Lean Manufacturing" approach) 
but also developing and implementing innovations in 
processes and products.

On the other hand, the growing sensitivity in 
society as regards a responsible management should 
imply that the supply chain management should be 
enlarged to take in the concept of sustainability and 
its three pillars associated: environmental, economic 
and social (Ciliberti et al., 2008).

Beyond the isolated vision of one company, this 
concept of sustainability should be extended to the 
other companies in the supply chain, where-by all 
their organizations should take an active part in 

15Int. J. Prod. Manag. Eng. (2014) 2(1), 15-22Creative Commons Attribution-NonCommercial 3.0 Spain

http://dx.doi.org/10.4995/ijpme.2014.1860


designing and implementing logistic processes that 
can be considered as sustainable (Ciliberti et al., 
2008; Carter and Rogers, 2008; Seuring and Müller, 
2008; Andersen et al., 2009). Thus, sustainability and 
efficiency should be considered as complementary 
(Mejías-Sacaluga et al., 2011).

In the context commented previously, packaging 
arises as one of the key elements that makes it 
possible the combined implementation of efficiency 
and sustainability strategies (Jahre and Hatteland, 
2004; Klevas, 2005; Verghese and Lewis, 2007; Azzi 
et al., 2012). 

Beyond the traditional (but nonetheless important) 
view of packaging as a means of protecting products 
(Williams et al., 2008), over the last few years, new 
design requirements have been added for packaging: 
on the one hand, to improve the differentiation 
capacity of the product (commercial function), and 
on the other, to improve the efficiency of the product 
at logistic and productive level (logistic function).

This contribution of packaging to logistic and 
productive efficiency should be considered not 
only in terms of its direct view (in the processes of 
supplying, packing, handling, storing and transport), 
but also reversely (re-use, recycling and/or recovery 
waste from packaging). All this has, in practice, 
meant the development of specific legislations 
(e.g. European Directive 94/62/EC; 1994 and its 
updated version 2004/12/EC) and introduces the 
environmental function, not only in reverse logistics, 
but also in direct logistics. 

Authors such as Saghir (2002), García-Arca and 
Prado-Prado (2008a), Bramklev (2009) and Azzi 
et al., (2012) identify in packaging three main 
functions: the commercial function, the logistics 
function and the environmental function. 

Also, in order to put these functions into practice, 
it is essential to consider the packaging as a system 
comprising three levels (Saghir, 2002): the primary 
packaging (“consumer packaging”), the secondary 
packaging (“transport packaging”; tipically, boxes) 
and the tertiary packaging (several primary or 
secondary packages grouped together on a pallet).

When considering packaging from a global 
perspective, the interaction among different levels 
would become manifest, depicting the dependence 
among them. In fact, the adaptation of a set level 
of packaging should not be contemplated if the 
integration of the set of all the levels of grouped form 
is not also considered

The choice of the type of packaging is usually subject 
only to considerations involving cost reduction. 
Thus, packaging design affects costs both directly 
(costs of purchasing and waste management) and 
indirectly (packing, handling, storage and transport). 
It is precisely this indirect way that makes difficult 
an adequate under-standing of the repercussions of 
certain decisions in packaging design (García-Arca 
and Prado-Prado, 2008a).

García-Arca and Prado-Prado’s study (2008b) of 
more than 300 companies in the supply chain of 
the Spanish food industry, shows that logistics 
costs (direct or indirect) due to packaging were 
approximately 40% of packing companies’ revenue 
(14% direct and 26% indirect), and 10% of 
distributors’ revenue. 

This percentage of distributors’ costs does not 
include the logistic costs at the point of sale. Some 
studies calculate the handling cost at the point of sale 
to be 10% of the product’s price (Saghir and Jönson, 
2001). 

In this line, Azzi et al. (2012), in their literature 
review comment that approximately 9% of the cost 
of any product is likely to be the cost of its packaging. 
This study also shows that hidden costs associated 
with overpackaging in Europe, seem to be 20 times 
higher than the cost of excessive packaging materials 
itself.

On the other hand, García-Arca and Prado-Prado’s 
study (2008b) shows that at least 18% pallets 
employed downstream in the supply chain were 
inefficient in terms of volume and/or weight. 

An European study (2009) on consumer markets, 
carried out in five European countries, points out 
that the wasted volume between the primary and 
secondary packaging varied between 34% and 50%. 
Between the secondary packaging, which is typically 
a box, and the pallets, the unoccupied space varies 
between 46% and 64%.

With this broader view of packaging, over the 
last few years, the integration of logistics and the 
packaging design has been conceptualized in the 
term “packaging logistics”, particularly emphasizing 
the operational and organizational repercussions 
(Hellström and Saghir, 2006; García-Arca and 
Prado-Prado, 2008a). 

Shagir considers “packaging logistics” as “the 
process of planning, implementing and control-
ling the coordinated packaging system of preparing 
goods for safe, efficient and effective handling, 
storage, retailing, consumption and recovery, reuse 

16 Int. J. Prod. Manag. Eng. (2014) 2(1), 15-22 Creative Commons Attribution-NonCommercial 3.0 Spain

García-Arca, J., González-Portela Garrido, A.T. and Prado-Prado, J.C.



or disposal and related information combined with 
maximizing consumer value, sales and hence profit”. 

As a result of the packaging logistics implementation, 
it is possible to deal with the search for packaging 
able to meet the needs of the companies based on 
the possibilities associated with the combinations 
in the packaging structure (primary, secondary and 
tertiary packaging) and with the four main decisions 
to be taken in design: selection of the materials, 
dimensions, groupings (the number of packs/
package) and “graphic artwork” (or the aesthetic 
design of the packaging).

2. Research Method
With the conceptual definition of the “Packaging 
Logistics” in mind, the main objective of this paper 
is to illustrate the potential of applying this approach 
in the supply chain of milk cartons (“Briks”). This 
paper is based on a previous paper presented at CIO 
2013 Conference in Valladolid (Spain).

The “Brik” was developed by Ruben Rausing in 
1951 in Lund (Sweden). It can be made for up to six 
different layers and for guidance, a brick pack would 
comprise 75% cardboard, 20% plastic (Polyethylene) 
and 5% of aluminum. 

Despite its usefulness to preserve perishable liquid 
foods (including milk) without refrigeration and 
preservatives and its good logistical efficiency 
(volumetric occupation), this package is still blames 
environmental misbehavior. However, this difficulty 
of recycling has improved as technology evolves in 
separation of layers. 

For theory testing, the authors have adopted the 
“action research” approach, directly participating in 
the “packaging logistics” implementation process 
in a dairy company. Thanks to this approach (action 
research), the researchers have the opportunity to 
witness the process, not only as mere observers, but 
also as real “agents of change” in intervention and 
know-how compiling processes (Maull et al., 1995; 
Prado-Prado, 2000).

Action research can be seen as a variant of case 
research (Yin, 2002), but whereas a case researcher is 
an independent observer, an action researcher “…is a 
participant in the implementation, but simultaneously 
wants to evaluate a certain intervention technique...” 
(Coughlan and Coghlan, 2002). The analysis was 
complemented by a literature review and a field 
study of dairy products (based on cartons) in three 
supermarkets chains in Galicia (Northwest Spain). 

3. Action Research Analysis
The analyzed company, based in Galicia (Northwest 
Spain), is one of the most important manufacturers 
in dairy Spanish market (among the 12 main 
manufacturers), with an annual turnover of over 
100 million euros and over 250 employees. This 
company produces and distributes various dairy 
products such as milk, liquid yoghurts, cream and 
butter, milkshakes and cheeses. 

In the analysis, the authors have focused on the 
products packaged in milk cartons. In this kind of 
product, the company packs more than 100 million 
liters/year). Particularly, we have focused on the 
1 liter milk carton with cap (primary packaging), 
grouped in packs of 6 cartons (secondary packaging) 
and palletized in EUR pallet (tertiary packaging).

The logistics of milk cartons does not demand 
special requirements of conservation (temperature) 
as it happens with other milky products like cheese, 
yoghurt and cream (with a specific supply chain, due 
to temperature-controlled conditions). 

So, the supply chain of the dairy company 
selected could summed up including processes 
from packaging purchases, packing and physical 
distribution to reverse logistics. 

Thus, the cost associated to this last supply chain 
could be summarized in the following categories: 
Packaging purchases, Packing, Handling, storage 
and picking in manufacturer´s warehouse, Transport 
(mainly full truck) from manufacturer to distributors, 
Handling, storage and picking in distributors´ 
warehouses, Transport (mainly combined truck) 
from distributor and supermarkets, Handling and 
storage in supermarkets and, finally, Reverse 
Logistics (Green Dot).

Furthermore, in the analysis 4 milk carton formats 
were selected (see Figure 1; A, B, C and D) as well 
as 5 of the most widely used formats of packs (see 
table 1 at the end of the paper; A.1, A.2, B.1, C.1 and 
D.1). 

In the figure 2, different options of grouping cartons 
in pack are presented. Among all these combinations 
the company used, initially, carton A and pack A.1.

Regarding the packaging process purchases, 
indicating that the final price depends on the type of 
carton format, material and weight (A, B, C and D), 
as well as purchase volume (economies of scale).

As a simplification for the analysis, it was considered 
that for the same volume of purchase, the final cost 
of each carton depends on its individual weight (see 

17Int. J. Prod. Manag. Eng. (2014) 2(1), 15-22Creative Commons Attribution-NonCommercial 3.0 Spain

Packaging as source of efficient and sustainable advantages in supply chain management.  
An analysis of milk cartons.



table 3 at the end of the paper), although, also would 
be affected by the number of layers and the type of 
material of each layer. 

Also, the cost of pack (secondary packaging) is 
determined by the type of materials, their weight 
and by the number of cartons/pack. Furthermore, 
the packing process is highly automated, although 
their flexibility and adaptation to different formats 
of cartons and packs is low (high impact of setup). 

Figure 1. Alternatives of carton formats analysed.

Figure 2. Alternatives of grouping cartons in packs.

Table 3. Improvements in a “wrap-around” box, reducing 
the flaps length. 

Flaps size 
(mm)

Cardboard surface 
(m2)

Initial stage 85 0.445
First change 50 0.407 (–9%)
Second change 60 0.389 (–13%)

This aspect limits, in general, the coexistence of 
various formats of cartons and packs in the same 
manufacturing line so that, in practice, these lines 
are specialized.

In the last few years the amount of raw materials 
used in packs has been reduced thanks to technology 
and design improvements. For example, in table 3 
and figure 3 the reduction of flaps in “wrap-around” 
boxes are presented (“wrap-around” box is a kind of 
box especially designed for automating the packing 
process).

Figure 3. Development of a wrap-around box  
(source: AFCO).

With regard to the physical distribution (handling, 
storage and transport), the efficiency of palletizing 
is conditioned by the type of carton but also by the 
part of the supply chain that focuses on the analysis 
(see table 1 at the end of the paper). In this sense, 
the milk cartons pallet has a high density and high 
consumption. 

A priori, this product could be distributed efficiently, 
optimizing the activities of handling, storage and 
transport, looking for a larger number of liters per 
pallet, within the constraints of strength of carton 
and pack. In this regard, the maximum number of 
layers per pallet is conditioned not only by the type 
of carton, but also by the location of the cap (other 
formats without cap can withstand more layers).

However, the type of transport between manufacturer 
and distributors´ warehouses is “full load truck" 
(maximum load limit of 33 EUR pallets and 24.4 
tonnes). Traditionally, manufacturers have not paid 
much interest in improving the volumetric efficiency 

18 Int. J. Prod. Manag. Eng. (2014) 2(1), 15-22 Creative Commons Attribution-NonCommercial 3.0 Spain

García-Arca, J., González-Portela Garrido, A.T. and Prado-Prado, J.C.



of pallet (although there are significant differences 
as shown in table 2), since the weight determines the 
maximum number of pallets per truck. In fact, in the 
company, the number of pallets per truck does not 
exceed 30. 

All this significantly affects, not only to the efficiency 
of handling and storage in the ware-houses of the 
manufacturer, distributors and supermarkets, but 
also in transport between distributors´ warehouses 
and supermarkets.

In particular, in the latter transport, the type of truck 
changes, not only in the capacity (typically with less 
capacity vehicles), but also in the configuration of 
goods, due to mill pallets are combined with other 
pallets of products food with lower densities (mono-
reference and / or multi-reference pallets). 

By combining these different kinds of products, 
generally, the average weight in each pallet on this 
new truck is reduced, enabling a priori a better pallet 
volume. In figure 4, the filling rate in trucks (%) is 
presented according to density of products and the 
designed height in pallets.

This brings additional advantages in supermarkets 
that have opted to present directly at the point of sale 
the milk pallet (minor handling and better occupancy 
in supermarkets).

Even, company can adopt alternatives that reduce the 
weight of traditional wooden pallet (25 kilograms per 
pallet) to gain useful load capacity on trucks. Among 
these alternatives are: the plastic pallet (6 kg), the 
cardboard pallet (12 kg), the "loading ledge" (1.5 kg) 

or the “slip sheets” (1 kg approximately). In an initial 
full load truck (30 pallets), the analyzed manufacturer 
could earn more than 700 kilograms (option with 
loading ledge and slip sheets), equivalent to an 
additional pallet on each truck (3.33%). 

In the other options, also an additional pallet per 
truck is load except in the option D. However, any of 
these alternatives would require a change in the pool 
system (exchange of pallets or "loading ledges"). 
Besides, the “loading ledges” and “slip sheets”, 
moreover, requires changes in the palletizing system 
at the manufacturer's premises and in the handling 
machines. Therefore, it has not been considered all 
these options in the final analysis.

Finally, at the level of reverse logistics, the Green 
Dot cost also depends on the selection of the carton 
and the pack. Table 2, at the end of the paper, 
summarizes the total costs of Green Dot per each 
alternative. The Ecoembes fees in 2014 are: 0.323 €/
kg carton; 0.068 €/kg cardboard; 0.472 €/kg plastic.

4. Results and discussion
As a final decision, it was decided to choose the 
most efficient carton format in logistics (format 
D), since is the alternative with major level of total 
savings (see tables 2 and 3). This alternative involves 
no substantial changes in the system of packing in 
carton and pack and implies savings in handling and 
storage of over 16,000 pallets a year (a reduction of 
11.7%). 

10%

20%

30%

40%

50%

60%

70%

80%

90%

100%

110%

0.45	
  m 0.65	
  m 0.85	
  m 1.15	
  m 1.45	
  m 1.85	
  m 2.3	
  m

322	
  kg.*EUR*1	
  m	
  height

401	
  kg.*EUR*1	
  m	
  height

500	
  kg.*EUR*1	
  m	
  height

624	
  kg.*EUR*1	
  m	
  height

645	
  kg.*EUR*1	
  m	
  height

10%

20%

30%

40%

50%

60%

70%

80%

90%

100%

110%

0.45	
  m 0.65	
  m 0.85	
  m 1.15	
  m 1.45	
  m 1.85	
  m 2.3	
  m

322	
  kg.*EUR*1	
  m	
  height

401	
  kg.*EUR*1	
  m	
  height

500	
  kg.*EUR*1	
  m	
  height

624	
  kg.*EUR*1	
  m	
  height

645	
  kg.*EUR*1	
  m	
  height

Figure 4. Analysis of filling rate of trucks according to density and height in pallets.

19Int. J. Prod. Manag. Eng. (2014) 2(1), 15-22Creative Commons Attribution-NonCommercial 3.0 Spain

Packaging as source of efficient and sustainable advantages in supply chain management.  
An analysis of milk cartons.



This improvement is also an annual reduction in the 
number of full trucks to 92 trucks (2% reduction). 

Only in transport between the manufacturer and 
distributors, this change should involve saving of 
60,000 euros/year (at least, total savings of 35,000 
euros/year). 

Additional savings could be achieved thanks to the 
reduction of handling and storage in manufacturers, 
distributors and supermarkets, but also of the 
transport costs between the distributors' warehouses 
and supermarkets.

In summary, Packaging design could be considered 
as a “microworld” where every millimeter and 
gram counts in the context of overall supply chain 
efficiency and sustainability.

Going beyond, redesigning packaging can lead not 
only to savings, but also increased sales. To achieve 
this, the global impact of design decisions must be 
measured in the whole chain.

In this context, the key to achieving efficient and 
sustainable packaging is the coordination and 
collaboration between all areas, departments or 
companies throughout the supply chain.

This last statement implies that packaging formats 
selected should not be considered ‘fixed’, but rather 

a solution that can be constantly improved. Thereby, 
design decisions should be regularly revised in case 
commercial, logistic or environmental requirements 
change, or if new innovations in materials and/
or technical solutions occur within the packaging 
industry.  

On the other hand, the role of “change agents” (the 
authors of this paper), as promotors of “packaging 
logistics” implementation in line with the scientific 
approach “action research,” must be outlined.

5. Conclusions
In a competitive and global world, companies 
should face supply chain design from a sustainable 
and efficient perspective. The real challenge for 
companies is how to integrate, proactively and 
strategically, both concepts. 

In this scenario, redesigning packaging by applying 
the “Packaging Logistics” concept is an example 
of this integration as it was illustrated in the dairy 
company with cartons analysis. As described in 
this paper, the supply chain as a whole has also 
succeeded in making substantial savings at logistics 
and environmental level.

Table 1. Logistics comparison among carton alternatives.

Type and 
carton 
dimensions  
(mm, W×L×H)

Type of pack and 
dimensions  
(mm, L×W×H) Palletization

Pallet height  
(m, incl. pallet)

Pallet weight  
(kg, incl. pallet) Transport efficiency

Type A 
(60×90×195)

Type A.1; 
Card-board box 
(wrap-around); 
282×127×216

720 cartons;  
24 packs/layer;  
5 layers/pallet

1.33 807 30 pallets/truck;  
21,600 cartons/truck  
(initial solution)

Type A 
(60×90×195)

Type A.2;  
Card-board tray 
and plastic cover; 
282×128×210

720 cartons;  
24 packs/layer;  
5 layers/pallet

1.3 800 30 pallets/truck ;  
21,600 cartons/truck;  
(no improvement)

Type B 
(65×70×252)

Type B.1;  
Plastic cover; 
219×130×265

768 cartons; 
(+6.66%);  
32 packs/layer;  
4 layers/pallet

1.31 848 28 pallets/truck; 
21,504 cartons/truck; 
(-0.44%)

Type C 
(71×75×204)

Type C.1;  
Plastic cover and 
car-board sheet; 
227×150×205

864 cartons; 
(+20%);  
24 packs/layer;  
6 layers/pallet

1.4 951 25 pallets/truck;  
21,600 cartons/truck;  
(no improvement)

Type D 
(62×70×239)

Type D.1;  
Card-board tray 
and plastic cover; 
228×128×245

816 cartons; 
(+13.3%);  
34 packs/layer;  
4 layers/pallet 

1.23 903 27 pallets/truck;  
22,032 car-tons/trailer;  
(+2%)

20 Int. J. Prod. Manag. Eng. (2014) 2(1), 15-22 Creative Commons Attribution-NonCommercial 3.0 Spain

García-Arca, J., González-Portela Garrido, A.T. and Prado-Prado, J.C.



The path taken by the company in the implementation 
of the "packaging logistics" combining logistics 
efficiency and sustainability (strategy "Lean and 
Green"), could be assimilated and adapted by other 
companies, regardless of sector or size, as it would 
contribute to improving competitiveness through 

innovation of products and processes within the 
supply chain.

In fact, the adoption of the Packaging Logistics 
reinforces the initial vision that efficiency and 
sustainability are not incompatible terms but, rather, 
are complementary terms.

Table 2. Sustainable comparison among cartons alternatives.

Carton 
model

Carton weight 
(g; without cap)

Carton Green Dot 
(million €/year)

Pack 
model

Type of 
pack

Pack 
weight

Pack Green Dot 
(million €/year)

TOTAL 
GREEN DOT 

(million €/year)
A 38 1.227 A.1 Cardboard box 

(wrap-around)
87 g 0.098 1.325

A 38 1.227 A.2 Cardboard tray 
(C) and plastic 

cover (P)

44 g (C); 
12 g (P)

0.149 1.376 (+3.44%)

B 39 1.26 B.1 Plastic cover 15 g 0.118 1.378 (+3.90%)

C 36 1.162 C.1 Plastic cover (P) 
and carboard 

sheet (C)

14 g (P); 
22 g (C)

0.135 1.297 (–2.11%)

D 36 1.162 D.1 Cardboard tray 
(C) and plastic 

cover (P)

51 g (C); 
13 g (P)

0.160 1.322 (–0.23%)

References
Andersen, M., Skjoett-Larsen, T. (2009). Corporate social responsibility in global supply chains. Supply chain management: An International 

Journal, 14(2), 75-86. doi:10.1108/13598540910941948

Azzi, A., Battini, D., Persona, A., Sgarbossa, F. (2012). Packaging Design: General Framework and Research Agenda. Packaging Technology 
and Science, 25(8), 435-456. doi:10.1002/pts.993

Bramklev, C. (2009). On a proposal for a generic package development process. Packaging Technology and Science, 22(3), 171-186. 
doi:10.1002/pts.850

Carter, C.R., Rogers, D.S. (2008). A framework of sustainable supply chain management: moving toward new theory. International Journal 
of Physical Distribution & Logistics Management, 38(5), 360-387. doi:10.1108/09600030810882816

Ciliberti, F., Portrandolfo, P., Scozzi, B. (2008). Logistics social responsibility: Standard adoption and practices in Italian companies.  
International Journal of Production Economics, 113(1), 88-106. doi:10.1016/j.ijpe.2007.02.049

Christopher, M. (2005). Logistics and Supply Chain management strategies for reducing cost and improving service. 3ª edition, Financial 
Times Pitman Publishing, London, UK.

Coughlan, P., Coghlan, D. (2002). Action research for operations management. International Journal of Operations & Production Management,  
22(2), 220-240. doi:10.1108/01443570210417515

Europen. (2009), The European Shopping Baskets, Europen and Packforsk, Brussels, Belgium.

García-Arca, J., Prado-Prado, J.C. (2008a). Packaging as source of competitive advantages. Universia Business Review, 17, 64-79.

García-Arca, J., Prado-Prado, J.C. (2008b). Packaging design model from a supply chain approach. Supply Chain Management: An 
International Journal, 13(5), 375-380. doi:10.1108/13598540810894960

Hellström, D. Saghir, M. (2006). Packaging and logistics interactions in retail supply chain. Packaging Technology and Science, 20(3), 197-
216. doi:10.1002/pts.754

Jahre, M., Hatteland, C.J. (2004). Packages and physical distribution: Implications for integration and standardization.  International Journal 
of Physical Distribution and Logistics Management, 34(2), 123-139. doi:10.1108/09600030410526923

Klevås, J. (2005). Organization of packaging resources at a product-developing company.  International Journal of Physical Distribution and 
Logistics Management, 35(2), 116-131. doi:10.1108/09600030510590309

21Int. J. Prod. Manag. Eng. (2014) 2(1), 15-22Creative Commons Attribution-NonCommercial 3.0 Spain

Packaging as source of efficient and sustainable advantages in supply chain management.  
An analysis of milk cartons.

http://dx.doi.org/10.1108/13598540910941948
http://dx.doi.org/10.1002/pts.993
http://dx.doi.org/10.1002/pts.850
http://dx.doi.org/10.1108/09600030810882816
http://dx.doi.org/10.1016/j.ijpe.2007.02.049
http://dx.doi.org/10.1108/01443570210417515
http://dx.doi.org/10.1108/13598540810894960
http://dx.doi.org/10.1002/pts.754
http://dx.doi.org/10.1108/09600030410526923
http://dx.doi.org/10.1108/09600030510590309


Maull, R.S., Weaver, A.M., Childe, S.J., Smar, P.A., Bennett, J. (1995). Current issues in business process reengineering. International Journal 
of Operations and Production Management, 15(11), 37-52. doi:10.1108/01443579510102882

Mejías-Sacaluga, A., García-Arca, J., Prado-Prado, J.C., Fernández-González, A.F., Comesaña, J.A. (2011). Modelo para la aplicación de la 
Responsabilidad Social Corporativa en la Gestión de la Cadena de Suministro.  Dirección y Organización, 45, 20-31.

Prado-Prado, J.C. (2000). El proceso de mejora continua en la empresa. Pirámide, Madrid, Spain.

Saghir, M. (2002). Packaging Logistics Evaluation in the Swedish supply Chain. Lund University, Sweden.

Saghir, M., Jönson, G. (2001). Packaging handling evaluation methods in the grocery retail industry. Packaging Technology and Science, 
14(1), 21-29. doi:10.1002/pts.523

Seuring, S., Müller, M. (2008). From a literature review to a conceptual framework for sustainable supply chain management.  Journal of 
Cleaner Production, 16(15), 1699-1710. doi:10.1016/j.jclepro.2008.04.020

Verghese, K., Lewis, H. (2007). Environmental innovation in industrial packaging: a supply chain approach.  International Journal of Production 
Research, 45(18-19), 4381-4401. doi:10.1080/00207540701450211

Williams, H., Wikström, F., Löfgren, M. (2008). A life cycle perspective on environmental effects of customer focused packaging development.  
Journal of Cleaner Production, 16(7), 853-859. doi:10.1016/j.jclepro.2007.05.006 

Yin, R.K. (2002). Applications of Case Study Research, Ed. Sage Publications, Thousands Oaks, CA, USA.

22 Int. J. Prod. Manag. Eng. (2014) 2(1), 15-22 Creative Commons Attribution-NonCommercial 3.0 Spain

García-Arca, J., González-Portela Garrido, A.T. and Prado-Prado, J.C.

http://dx.doi.org/10.1108/01443579510102882
http://dx.doi.org/10.1002/pts.523
http://dx.doi.org/10.1016/j.jclepro.2008.04.020
http://dx.doi.org/10.1080/00207540701450211
http://dx.doi.org/10.1016/j.jclepro.2007.05.006