https://doi.org/10.1177/0734242X231168801
Waste Management & Research
 1 –15
© The Author(s) 2023
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DOI: 10.1177 0734242X231168801
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Introduction
Currently, the circular economy (CE) is seen as a solution to 
delink economic growth and environmental pressure (Hofmann, 
2019). Previous studies on 114 definitions showed that the con-
cept is widely perceived as end-of-life (EoL) management with 
strong focus on the recycling practice (Kirchherr et al., 2017). In 
contrast, some argued that the core of CE concerns resource man-
agement and value retention (Morseletto, 2020; Vermeulen et al., 
2018). It can be implied that EoL management is a part of CE, 
and its value retention principle covers product life cycle through-
out value chain. Nevertheless, the strong conception that identify 
CE as EoL is reasonable considering the state of global waste 
management (WM) where approximately two-thirds of the waste 
still go into landfill and open dumping (The World Bank, 2018), 
putting WM on the spotlight under the realm of CE.
Extended producer responsibility (EPR) is an environmental 
principle that requires policy instruments for its application to 
achieve sustainable WM (Lindhqvist, 2000). It started as a mech-
anism to shift responsibility in handling waste from municipali-
ties to the producers, progressing to the present day as a means to 
advance collection and its subsequent treatment as well as design 
for the environment (DfE) and closing the loop (Lindhqvist, 
2000; Massarutto, 2007; The Organization for Economic 
Cooperation and Development (OECD, 2016)). EPR in Europe 
includes a directive for electrical and electronic equipment 
(EEE), vehicles, batteries and accumulators and packaging 
(Deloitte, 2014). It is rooted in the European Union (EU) waste 
framework directive (Directive 2008/98/EC), which adopts dif-
ferent policy instruments in implementing the EPR.
EPR is critically important to facilitate funding that is 
dedicated to ensure proper collection, sorting and recovery of 
EoL products. Various studies have been done regarding EPR 
implementation such as tyres (Campbell-Johnston et al., 2020; 
Winternitz et al., 2019), packaging (Rubio et al., 2019), lamps 
(Richter and Koppejan, 2016), vehicles (Santini et al., 2011; 
Xiang and Ming, 2011) and e-waste (Leclerc and Badami, 2020; 
Wang et al., 2017). However, the majority of studies focused on 
EPR performance of a single product, and few of them studied a 
Circular economy through waste reverse 
logistics under extended producer 
responsibility in Finland
Bening Mayanti1  and Petri Helo2
Abstract
Extended producer responsibility (EPR) is commonly implemented as a strategy in waste management. The core of the concept itself 
is a waste reverse logistics (WRL), which dictates how the collection, inspection and processing of end-of-life products are performed. 
Existing studies of EPR mainly focused on single products instead of using broader perspective on national level. Its contribution 
towards circular economy through slowing and closing the loops also has not been widely discussed. This study examined the system 
architecture of the policy instruments used in the EPR and the similarities of the WRL networks across different products. A case 
study was used to investigate six products: portable batteries and accumulators, paper, packaging, vehicles, electrical and electronic 
equipment (EEE) and tyres. The study generated a WRL framework. It is also observed that closing the loop through recycling 
is the primary circular strategy and is found in all products, whereas closing and slowing the loop strategy through reuse/repair, 
remanufacture and repurposing is found in packaging, tyres, vehicles and EEE. This study shows that EPR can close the material 
loop, although improvement in design for the environment is necessary. It creates challenges and opportunities for the government, 
producer responsibility organization and producers to improve existing conditions by implementing new initiatives such as design for 
the environment indicators, standardization, tax and subsidy systems and tariffs for disposal fees.
Keywords
Waste reverse logistics, extended producer responsibility, circular economy, waste management, policy instruments
Received 28th September 2022, accepted 24th March 2023 by Associate Editor Nemanja Stanisavljevic.
1 Vaasa Energy Business Innovation Centre, University of Vaasa, 
Vaasa, Ostrobothnia, Finland
2 Department of Production, University of Vaasa, Vaasa, Ostrobothnia, 
Finland
Corresponding author:
Bening Mayanti, Vaasa Energy Business Innovation Centre, University 
of Vaasa, Yliopistonranta 10, Vaasa, Ostrobothnia 65200, Finland. 
Email: bening.mayanti@uwasa.fi
1168801WMR0010.1177/0734242X231168801Waste Management & ResearchMayanti and Helo
research-article2023
Original Article
2 Waste Management & Research 00(0)
couple of products. As a result, there is a lack of perspective 
regarding challenges, barriers and performance of overall EPR 
implementation on a national level. Moreover, existing studies 
have not yet looked into the network and policy instruments. As 
far as the authors are aware, no study has been conducted to 
investigate policy instruments and the reverse logistics (RL) net-
work of collective EPR in Finland. Hence, this study aims to 
examine the waste reverse logistics (WRL) networks of the col-
lective EPR system within the Finnish context. It intends to con-
tribute towards CE and provide knowledge to improve EPR 
implementation, such as setting new targets or applying new 
policy instruments. This goal is achieved by answering the fol-
lowing questions: (1) What is the system architecture of the 
policy instruments? and (2) How different or similar is the WRL 
network across different EoL products? Multiple analyses of the 
system architecture and WRL network are developed for six 
products under the EPR scheme: portable batteries and accumu-
lators, paper, packaging, vehicles, EEE and tyres.
Literature overview
Waste reverse logistics
RL deals with the flow of products from consumers because the 
products are defective, unwanted, recalled or discarded after use 
(De Brito and Dekker, 2004). In the context of WM, it deals with 
discarded products. WM is mostly about effective and efficient 
activities to prevent, collect, transport, recover and treat waste, 
whereas RL is concerned with recapturing value and directing it 
back to the market (Seadon, 2010; Triantafyllou and Cherrett, 
2010). Nonetheless, overlaps occur between WM and RL, as 
shown by definition evolving throughout the years. Within CE 
framing, WM and RL have contributions since CE emphasizes 
that waste is a resource and the remaining value should be cap-
tured and re-entered the supply chain (Potting et al., 2017).
RL comprises four main activities: gatekeeping, collection, 
sorting and recovery. Gatekeeping is a typical return manage-
ment activity where the company screens the returned products 
to decide whether those products are allowed to enter the reverse 
supply chain (Hjort, 2010). In WRL, the activity starts with the 
collection since all products will enter the reverse channel once 
discarded, regardless of the condition. Collection refers to trans-
ferring products from the source to where further treatment is 
applied (Barker and Zabinsky, 2008). The collection scheme can 
be the curbside, drop-off or pick-up method. The collected prod-
ucts are sorted based on quality to determine the following 
recovery options. The last step is recovery, which can be done 
on different product structure levels, such as whole product, 
component and material. In CE, the recovery level is expected to 
maintain the use of the product and material as long as possible 
through reuse, repair, refurbishing, remanufacturing, repurpos-
ing, recycling and energy recovery (Potting et al., 2017).
Extended producer responsibility
EPR is an extension of the ‘polluter pays principle’ whose 
implementation requires policy instruments to incentivize pro-
ducers in preventing waste generation (Campbell-Johnston 
et al., 2020). It intends to internalize an externality of EoL 
costs where the price typically does not capture all the costs 
(OECD, 2016). Policy instruments required in EPR are varied, 
and they define EPR efficiency. Different types of policy 
instruments in EPR implementations are shown in Table 1 
(OECD, 2016; Tojo, 2004).
Administrative instruments can be described as the command-
and-control type that involves implementing particular tasks or 
banning certain activities (Tojo, 2004). Common examples 
include landfill bans, take-back schemes or recycling targets. 
Economic instruments offer a monetary incentive to implement 
certain tasks or financial disincentives to refrain from performing 
certain activities (OECD, 2016). Examples of economic instru-
ments include taxing virgin material, paying an additional price 
when purchasing products, then receiving the payment back 
when the products are returned (deposit–refund system), or 
advanced disposal fees to finance waste treatment (Forslind, 
2005; OECD, 2016). Informative instruments affect EPR indi-
rectly through knowledge provision about the products and their 
impact on the environment (Lindhqvist, 2000). An example of an 
informative instrument is eco-labelling, which targets behav-
ioural change when consumers better understand products and 
their related impact (Tojo, 2004).
A study by OECD (2016) showed that three-quarters of EPR 
implemented various forms of take-back systems that can be 
done individually or collectively. The individual scheme means 
that the producers take responsibility for the EoL management of 
their products; meanwhile, a collective scheme occurs when the 
producers of the same products assemble to manage the EoL of 
their products with the help of a third-party organizer called pro-
ducer responsibility organization (PRO) (Tojo, 2003). Deposit–
refund system and advanced disposal fee cover almost the rest. 
A mix of different policy instruments is also commonly used. For 
example, beverage packaging in Finland implements a combina-
tion of three policy instruments. It applies a take-back scheme 
that primarily utilizes return vending machines, a deposit–refund 
system to incentive product return, a target for reuse and recovery 
and reporting to authorities (Palpa, 2019).
Table 1. Examples of policy instruments to implement extended producer responsibility.
Policy instruments Examples
Administrative Prohibition, recycling targets, regulation, take-back systems
Economic Deposit–refund system, disposal fee (e.g. collection fee or recycling fee), tax
Informative Eco-labelling, research and development, reporting
Mayanti and Helo 3
EPR has played a leading role in improving WM performance, 
as shown by relatively high collection and recycling rates (Niza 
et al., 2014; Tencati et al., 2016). Nonetheless, the collection rate 
and processing rate (recycling or recovery) remain varied signifi-
cantly across different products among EU members. Examples 
can be drawn from the recycling rate of packaging and vehicle in 
2018, where the performance ranged between 36–85% and 72–
91%, respectively (European Commission, 2021). Existing stud-
ies on EPR have focused on different aspects such as financing, 
evaluation of performance, challenges, a performance compari-
son between countries and responsibility fulfilment (Ahlers et al., 
2021; Deloitte, 2014; Kunz et al., 2018). These studies mainly 
focused on one type of product, such as waste electrical and elec-
tronic equipment (WEEE) (Andersen et al., 2020; Cahill et al., 
2011; Corsini et al., 2017; Rotter et al., 2011), tyres (Campbell-
Johnston et al., 2020; Winternitz et al., 2019), packaging (Cahill 
et al., 2011; Rubio et al., 2019), end of life vehicle (ELV) 
(Forslind, 2005; Xiang and Ming, 2011) and lamps (Richter and 
Koppejan, 2016). Focusing on one product allows for deep anal-
ysis leading to more detailed results. However this study, which 
examined EPR on a country level, provided insights into the dif-
ferences and similarities of each WRL network, including an 
evaluation to improve its performance.
WRL network design under collective EPR
Policy instruments concerning EPR implementation influence 
the decision made by various actors. These actors include the 
government, producers, PRO, consumers, logistics and recycling 
operators (Forslind, 2005). Particular actors can impose instru-
ments, while others can be affected directly by the instruments or 
indirectly through the actions taken by other actors. These deci-
sions can affect how producers or PROs handle EoL products, 
shaping the WRL network (OECD, 2016).
The governments as actors can impose and enforce official 
order in the form of specific instruments or regulations that affect 
multiple actors. They can mandate producers to arrange a free-of-
charge collection system which will affect the producers that 
have to bear the economic responsibility of collection and the 
subsequent treatment; hence, added fee is included at the point of 
sale (advanced disposal fee). This set of regulations from the 
government will be translated into strategies by the producers or 
PRO to meet EPR requirements and advocate for consumers to 
participate accordingly. The actions taken by producers and PRO 
are the ones that shape the WRL network. The producers and 
PRO will react to the instruments and make decisions that incen-
tive their action (Forslind, 2005). Another example is a collection 
target that requires high participation from the consumers. The 
collection target will affect planning the location or reception 
points in more accessible locations such as supermarkets or 
arranging curbside collection.
Thus far, the performance of EPR is evaluated through the 
achievement of the targets set by the government. Separate tar-
gets for reuse, recycling and recovery can be linked to CE strat-
egy in slowing and closing the loop.
Slowing the loop strategy on the product level is supported by 
design for durability as well as ease of repair and maintenance. 
Durability concerns the functionality of a physical product with-
out the need for excessive maintenance. Material choice becomes 
important in ensuring that the products last longer. An example of 
durability in a product can be observed by the treadwear rating of 
tyres, where a higher rating indicates it lasts longer under normal 
operating conditions. Design for repair and maintenance allows 
the product to be maintained to sustain its function. These initia-
tives enable EEE, tyres and packaging to have a second life and 
stay longer in use, while design for disassembly and reassembly 
enables slowing the loop on the component level. It concerns the 
ease of separating different components of a product and reassem-
bling it for reuse. Closing the loop is achieved through recycling, 
where the material is recovered without maintaining the physical 
geometry of the products. Design for recycling makes recycling 
feasible technically, environmentally and economically.
This literature overview demonstrates the importance of 
WRL and EPR. It is now being moulded together to show that 
WRL is the operational aspect of EPR. We present the architec-
ture of policy instruments to identify what improvements can be 
made, and we describe WRL network design based on studies 
of the main activities of RL. Actors can use the variety of con-
figurations from the WRL network to make decisions in arrang-
ing WRL.
Methodology
This article uses a case study to identify how WRL in a collec-
tive EPR scheme in Finland contributes to CE. A case study can 
be considered as the object of research or methodology, which is 
defined as the ‘exploration of a bounded system or a case (or 
multiple cases) over time through detailed, in-depth data collec-
tion involving multiple sources of information rich in context’ 
(Creswell, 1998, p. 61). This article applied a case study as a 
methodology because it is suitable for examining contemporary 
events where the associated behaviour cannot be manipulated 
(Rowley, 2002; Yin, 2003). A case study can thoroughly describe 
the system being studied within its contextual conditions (Yin, 
2003). This study uses a single case design, although multiple 
products were analysed separately. This type of study is called 
embedded-single-case, or a set of individual cases where multi-
ple analysis is made to the subunits within one case to provide 
opportunities for comprehensive analysis and extensive insights 
(Gibbs, 2012; Yin, 2003). This case study explores and describes 
EPR in detail since the data or evidence are collected in various 
forms through different data collection tools. The sources 
included literature, public documents, email communications 
and interview. Therefore, the discrepancy between what is writ-
ten in the literature and what is happening on a practical level 
with the PROs can be discovered. This method will also facili-
tate an investigation of important features and main problems 
within certain topics, providing insights into the direction of 
future studies.
4 Waste Management & Research 00(0)
This research follows the four steps of the case study strat-
egy namely defining the aim, developing the instruments, 
gathering the data, analysing the data and disseminating it 
(Stuart et al., 2002).
Stage 1: Formulating the aim of the research. The research 
aimed to examine the WRL of the collective EPR system in 
Finland. It was translated into research questions as follows: 
(1) What is the system architecture of the policy instruments? 
and (2) How different or similar is the WRL network across dif-
ferent EoL products? These research questions showed the focus 
of the work was to investigate the process (the system architec-
ture) and the outcome (how the RL scheme and its outcome 
under the EPR scheme are). The selection of six products sub-
jected to EPR to build the case study was also conducted in this 
stage. Those six products are covered by the collective EPR 
scheme in Finland; therefore, the inclusion of all of them could 
provide comprehensive result on national level and enable com-
parison across different products. The products are batteries and 
accumulators, EEE, vehicles, packaging, tyres and paper. It 
applied a set of individual cases over time, resulting in a com-
parative historical study. Overall, 17 PROs are responsible for 
all the products. Furthermore, it is common in Finland to have a 
service company that organizes multiple PROs responsible for 
the same products (e.g. Rinki for PROs packaging or Elker for 
PROs WEEE). The study centred on the collective scheme since 
most of the products subject to the EPR in Finland are managed 
through a collective scheme (e.g. all producers of paper, 
tyre, ELV and beverage packaging join a collective scheme; 
Pirkanmaan ELY-keskus, 2020).
Stage 2: Developing the instrument. Document analysis com-
plemented with personal communications were the selected 
instruments to conduct the case study. Firstly, an investigation 
was conducted on the implementation of EPR and RL through a 
literature study. The results were used as a basis to develop a 
strategy for data collection and analysis. The study on EPR 
implementation was a basis to assess the system architecture of 
the policy instrument. At the same time, literature studies on RL 
main activities would be utilized to analyse WRL network design. 
When developing the design framework for WRL, the main con-
siderations were waste type and recovery options (Van Engeland 
et al., 2020). Hence, once the EoL products have been identified, 
the next step is identifying the journey from the point of the prod-
ucts being discarded. Meanwhile, personal communication with 
representatives of PRO and ELY-keskus, a government body that 
oversees the EPR scheme, was also conducted.
Stage 3: Gathering the data. Information on EPR practice was 
derived from publicly available data, including ones provided by 
the PROs, government authorities, logistics and recycling opera-
tors, etc. The data were complemented by personal communica-
tion to confirm certain issues through email exchanges with 
representatives of Serty (a consortium of PRO for EEE), Rescer 
(PRO for battery and accumulator), Suomen Autokierrätys (PRO 
for ELV), Suomen Kuitukierrätys Oy (PRO for fibre packaging) 
and Pirkanmaan ELY-keskus (government authority) as well as 
an interview with a representative from Rinki (a service company 
handling PRO for packaging). Email exchanges included but 
were not limited to requests for the latest data concerning EPR 
statistics, information on how the products were collected, who 
processed the waste (original manufacturer or operator) and 
where the location was, etc. A semi-structured arrangement was 
used for the interview to stimulate more discussion around the 
topic. The interviewer introduced the idea of the study around 
EPR and WM, followed by an opening question regarding the 
existing structure of EPR for packaging in Finland.
Stage 4: Analysing the data. The documents were analysed 
using a deductive approach where pointers were developed based 
on the research questions and initial literature to find necessary 
information. Patterns and themes based on the RQ were identi-
fied from the data (e.g. how the waste is collected, where the 
waste is reprocessed, any recycling target for specific products, 
financing type, etc.). Along the way, the inductive approach was 
incorporated when information deemed essential was found. The 
results of personal communications were evaluated, and some 
quotes were the opinion of the correspondents. The results of 
these stages were utilized to develop a design framework, identi-
fying the level of product recovery and the circular strategies 
associated with each product.
The next step was determining the level of product recovery 
by examining whether the recovery was applied to the level of 
product, component or material. The circular strategy was then 
identified by inspecting the available recovery options (generated 
during design framework development) and examined using CE 
strategies namely slowing, closing and narrowing the loop 
(Bocken et al., 2016). They defined slowing the loop as prolong-
ing and/or intensifying utilization of a product, closing the loop is 
achieved through recycling and narrowing the loop aims at utiliz-
ing less resource per product. These strategies were chosen 
because they are broad enough to cover the product life cycle, 
aligning with the CE position at the strategic level and can be 
used to define the circular approach in the product system and 
business model.
Results
The system architecture of the policy 
instruments
Administrative, economic and informative instruments were 
applied to all products. The summary of the system architecture 
of the policy instruments applied in the EPR scheme in Finland is 
shown in Table 2. Take-back and reporting obligations were 
found across all products (Pirkanmaan ELY-keskus, 2020, 2021). 
The former requires the producers to provide a separate collec-
tion scheme free of charge, and the latter obliges the producers to 
monitor the implementation and report the result to the Finnish 
authority. The responsible parties in the take-back arrangement 
are varied among all products. Although EPR aims to shift 
responsibility from municipalities to producers in managing 
Mayanti and Helo 5
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6 Waste Management & Research 00(0)
waste, municipalities still have some role in EPR. Producers are 
the sole responsible party in take-back obligations for tyres, bat-
teries, accumulators, paper and vehicles. In comparison, munici-
palities are involved in collecting waste packaging and EEE. 
Municipalities and individual PRO negotiate the contract on 
WEEE collection, whereas, for packaging, municipalities may 
handle some of the curbside collection.
Collection target and treatment target are other administrative 
instruments used to complement take-back obligations. Batteries 
and accumulators, EEE, tyres and packaging are regulated under 
the EU directive, requiring uniformity among member states for 
reporting purposes. The uniformity can be seen in how the EEE, 
batteries and accumulators collection targets were adopted from 
the EU directive. The estimation is based on the average quantity 
of products placed in the market within 3 years. For vehicles, 
there is no collection target to meet. Paper and packaging are the 
other products without a collection target. However, the treat-
ment target of paper and packaging is based on the amount of 
product placed on the market, implying the minimum quantity to 
be collected. The treatment target refers to reuse, recycling and 
energy recovery. There is no stand-alone reuse target required 
by law across all products; instead, the target aims at reuse and 
recycling altogether.
The financial responsibility intends to cover collection, trans-
portation, sorting and reprocessing. These activities are financed 
by the producers that integrate the cost of handling EoL products 
into the price of products. Differences concerning financial 
instruments are present across products. Paper is the only product 
that does not apply a disposal fee because the revenue could 
finance the scheme. The scheme’s effectiveness is affected by the 
market value of recycled paper in Finland (Deloitte, 2014). Other 
products are financed through a disposal fee estimated by the 
PRO and paid by the producers. An exception applies to beverage 
packaging, which combines the fee with a deposit–refund system 
and container tax.
The deposit–refund system is implemented to increase the 
collection rate of beverage packaging by paying back the deposit 
to consumers when the products are returned. The deposit–refund 
system is commonly used to manage EoL beverage packaging 
because these products cause litter and are difficult to regulate 
(Zhou et al., 2020). In Finland, this instrument is mixed with 
container tax. This tax requires producers to pay a levy for each 
container placed in the market. However, producers can get 
an exemption from paying container tax by joining a PRO. 
This strategy will consolidate the return of beverage packaging 
through one channel to increase collection and recycling rate as 
well as take advantage of economies of scale (PRO, packaging).
WRL network design
The WRL was synthesized from the data collected during the 
study. Documents’ contents were analysed to find information 
regarding WRL logistics activities such as collection, sorting and 
reprocessing. Interview results and email communications com-
plemented this analysis. Each activity was scrutinized deeper to 
gather information concerning collection arrangement and where 
the sorting and reprocessing occur. Furthermore, the recovery 
options implemented for each product were examined to assess 
the type of circular strategy being applied. Table 3 summarizes 
the RL of six cases concerning the collection method, inspection 
and recovery.
Product recovery is about the location, whether it takes place 
in original or secondary facility, and the recovery options. The 
recovery can be performed on different levels: product levels, 
component levels and material levels through reuse, repair, 
remanufacture, repurpose, recycle and waste to energy (WtE) 
(Table 4). Although landfilling practice exists, it is not included 
in Table 4 since landfilling does not promote recovery at any 
product level.
Figure 1 presents a framework for WRL developed based on 
WRL structure and recovery options within this study. The 
framework can be used to develop a new WRL network or change 
an existing scheme for either individual or collective schemes.
Collection. Consumers’ participation determines the collection 
rate, which defines the EPR’s success. The participation is 
affected by convenience, incentive and awareness. There are 
four collection schemes: curbside, drop-off, pick-up and mobile 
collection. The collection of waste material is expensive, and 
when we have separate bins for several fractions, it is even more 
Table 3. Waste reverse logistics structure.
Products Number 
of PRO
Collection Inspection/sorting Recovery
Curbside Drop-off Pick-up Mobile Centralized Distributed Original 
facility
Secondary 
facility
Accumulators and batteries 4 x x x
EE 5 x x x x x
Packaging 5 x x x x x x
Beverage packaging 1 x x x
Paper 2 x x x x x
Tyres 1 x x x
Vehicles 1 x x x x
PRO: producer responsibility organization; EE: electronic equipment.
Mayanti and Helo 7
expensive. Our goal is to minimize the fees from customers 
(producers) (PRO packaging).
The drop-off scheme is used in all six waste streams as it is 
required by law to organize nationwide reception points. The 
curbside method is applied for paper and packaging made of 
plastic, metal, glass and cardboard. Properties are responsible for 
arranging a separate collection bin except for housing in sparsely 
populated areas. The curbside scheme is particularly beneficial 
for low-value products with a short lifetime generated in high 
volume by households so that the scheme takes advantage of 
economies of scale. It was reported that the curbside collection 
would result in the highest collection rate for paper and packaging 
(Larsen et al., 2010). This scheme is convenient and encourages 
compliance.
For beverage packaging, the deposit–refund system incen-
tivises the consumers to return the products to reception points 
instead of discarding them with other types of packaging. Zhou 
et al. (2020) reported a positive correlation between the deposit 
value and the return rate, although the ideal value was difficult to 
determine. This correlation was sensitive until the return rate was 
90% (Lindhqvist, 2000). EEE, vehicles, batteries and accumula-
tors, and tyres are collected mainly through the drop-off system. 
These products have a longer lifetime ranging from weeks to 
years, thus affecting the disposal frequency. The drop-off system 
is less costly than the curbside collection and relatively fast to 
implement. People are also willing to participate as long as the 
reception points are convenient (e.g. within 8 km for WEEE; 
Saphores et al., 2006; Wagner, 2013). Hence, the government 
regulate the number of reception points in Finland to reassure 
each population centre has access to it. Mobile collection for 
small WEEE is organized once or twice a year in sparsely popu-
lated areas to increase products’ return rates (Ylä-Mella, 2015). 
Table 4. Waste recovery options.
Products Product recovery options
Reuse/repair Remanufacture Repurpose Recycle WtE
Accumulators and batteries x x*
EE x x x
Packaging x x x*
Paper x x*
Tyres x x x x x
Vehicles x x x
EE: electronic equipment; WtE; waste to energy.
*The proportion is not explicitly mentioned in statistics, but some of these products end up in mixed waste and go into waste to energy plant.
Figure 1. Waste reverse logistics framework under collective extended producer responsibility in Finland.
8 Waste Management & Research 00(0)
The last scheme is a pick-up, available for large WEEE and vehi-
cles provided by a recycling operator or local environmental ser-
vice authority. The success of the WEEE collection is attributed 
to the citizen’s awareness (Ylä-Mella et al., 2014). Furthermore, 
setting a separate scheme to recycle paper has been a tradition in 
Finland since the 1990s. Therefore, when the practice was 
expanded into other types of waste, it was not a foreign practice.
Inspection/sorting. Sorting can be conducted in a decentral-
ized or centralized facility. Centralized facilities are common 
for products that require high-cost testing, specialized equip-
ment and labour. Accumulators and batteries as well as WEEE 
are inspected in centralized systems because they require more 
complex inspection and trained labour. For packaging, plastic 
material is sorted in a centralized facility at which optical sort-
ers based on infrared technology is used to distinguish differ-
ent type of plastics for further treatment. On the other hand, 
decentralized sorting that occurs at the collection points is suit-
able for products with consistent and easily replicable testing 
(Barker and Zabinsky, 2008), as well as simple products whose 
conditions are commonly uniform when discarded (e.g. paper) 
and easily distinguished.
Recovery options. Among the six cases, part of the paper, card-
board and wooden packaging are reprocessed in the original facil-
ity, while other products are recovered in a secondary facility. The 
recovery can occur on the product, component or material levels 
which depends on the available technology, product characteris-
tics and condition when discarded. Among the six products, EEE 
and tyres can undergo product, component and material recovery 
(for tyres, component recovery refers to retreading); packaging 
can be recovered on the product and material level; vehicles can 
be recovered on the component and material level, accumulators 
and batteries as well as paper can undergo material recovery.
From an economic perspective, material recovery (recycling) 
is not as expensive as collection, although the recycling costs 
vary across different materials. Metal is the best; you get money 
when selling it. For other materials like household plastics, 
nobody wants to recycle them without the money in the system by 
the responsible companies (PRO, packaging). It was also stated 
that policymakers saw EPR as a way to fund EoL management. 
People with first-hand experience managing EoL acknowledge 
how costly the system can be: Waste is not valuable as they often 
read in the newspaper, ‘Someone’s waste is valuable to someone 
else,’ it is not when you think about money. It takes money to col­
lect, sort and so on. You may get some money after that. We need 
somebody to pay, and now producers are more and more popular 
bodies to be responsible (PRO, packaging).
Collection and recovery performance
In general, the WRL across all products performs well compared 
to the target required by the legislation. Different collection strat-
egies used in each product support the performance to achieve 
the collection target. Since the target came into force, the average 
collection rate for WEEE, tyres and batteries were about 51, 104 
and 46%, respectively.
Figure 2 shows the recovery performance of all products 
under the collective EPR scheme in the past 10 years, with recy-
cling as the main contributor among other recovery options. The 
recovery options for ELV, packaging, paper, WEEE and tyre 
indicate the percentage of total products collected. However, for 
batteries and accumulators, the performance refers to efficiency, 
where it shows the ratio obtained by dividing the mass of recy-
cling output by the mass of waste input. For packaging and EEE, 
the results were average values obtained from 5 and 10 different 
products, respectively. Reuse rate in packaging was comparable 
with the recycling rate, especially from 2008 to 2012, followed 
by a declining trend in reuse. For metal packaging, the reuse 
trend was consistent since its inherent properties allow multiple 
reuses. However, a major shift occurred in glass packaging, at 
which the reuse rate declined throughout the year. The reuse rate 
was around 45–65% from 2008 to 2011, then declined to 9 and 
6%, respectively, in 2017 and 2018. The legislation change that 
did not require reuse for the refillable glass packaging caused 
the decline. The recycling of glass bottles was deemed to be 
more practical compared to reusing them.
In products such as packaging, paper and tyres, the total 
recovery rate reached more than 100%. It indicates that the waste 
is more than the product placed in the market. The treatment rate 
was calculated for tyres based on the product placed on the mar-
ket in the corresponding year, although tyres can last up to a few 
years. A free rider is also a common issue within the EPR scheme, 
where the magnitude can be difficult to estimate. For packaging, 
the quantity of reused products was derived from previous years, 
whereas the denominator was based on products placed on the 
market in the corresponding year, causing a recovery rate of more 
than 100%.
Circular economy strategies
Recovery options across different products are displayed in Table 4. 
These options, other than WtE, can be used to examine whether 
the products contribute to slowing or closing the loop. Although 
WtE allows a certain level of material recovery, this recovery 
option does not connect directly with product design. In other 
words, any design product can be processed in a WtE plant. Paper, 
portable accumulators and batteries are products that employ a 
closing-the-loop strategy through recycling. For batteries, pro-
moting reuse started recently, with the primary target being bat-
teries in electric vehicles (Pagliaro and Meneguzzo, 2019).
Packaging, tyres, EEE and vehicles are products that close the 
loop and slow the loop through reuse/repair, remanufacture and 
repurpose. Figure 3 shows the circular strategies in the past dec-
ade for tyres, vehicles, packaging and EEE, where recycling and 
reuse can be categorized as closing and slowing the loop, respec-
tively A similarity was found, where most of the products mainly 
rely on closing the loop through recycling. However, a different 
pattern was found in packaging, where the reuse trend decreased 
over the years while recycling increased. In order to compare the 
Mayanti and Helo 9
rate of reuse and recycling for packaging, the calculation was 
based on the sum of packaging placed in the market and the 
amount of reuse. One of the causes for the dynamic of reuse and 
recycling was a shift in the government regulation for beverage 
packaging. The decree on beverage packaging imposed a tax of 
0.51 € per litre of beverage on producers who did not connect to 
Figure 2. The recovery rate of (a) ELV, (b) packaging, (c) paper, (d) waste electrical and electronic equipment, (e) tyre and (f) 
batteries and accumulators.
Figure 3. Recycling and reuse rate of (a) tyres, (b) ELV, (c) packaging and (d) waste electrical and electronic equipment.
10 Waste Management & Research 00(0)
the deposit–refund system. The tax made it expensive for produc-
ers to stay out of the deposit–refund system. The decree also 
required producers in the deposit–refund system to reuse their 
packaging. This law was then amended, and the reuse obligation 
was not required anymore. The recycling organization was sim-
pler than reuse, causing the shift towards a lower level of product 
recovery.
Discussions and limitations
Main challenges: ELV and WEEE
Despite the well-performing EPR in Finland, some challenges 
are present and developments can improve EPR implementation. 
The future challenge in the EPR system in Finland is more pro-
nounced in products with higher complexity such as vehicle and 
EEE. There was no collection target for ELV, and it has consist-
ently had a collection rate of not more than 45% (Deloitte, 2014). 
Setting collection target for vehicles can be complex due to its 
long average age of 22 years, export practice and dismantling 
by unauthorized operators, and its active secondhand market 
(Autoalan Tiedotuskeskus, 2022; Inghels et al., 2016). Even 
though the handling may be environmentally sound, the dis-
mantled car will not be reported as an unregistered vehicle. 
Expanding network operators can be a solution to this issue. 
More information is to notify the consumers regarding the legal 
way of disposing of vehicles and their authorized operators.
Legislation covering WEEE in Finland may not serve the 
main goal of EPR optimally. Among others, the legislation does 
not require a separate reuse target, and it is one of the most chal-
lenging issues within environmental policy (D’Amato et al., 
2012; Horta Arduin et al., 2019). The reuse target has the poten-
tial to tap as the recast directive has suggested a 5% reuse 
target. A separate reuse target could promote higher recovery 
level, which aligns with the core of CE in resource management 
and value retention. However, there is a potential drawback of 
an increase in the overall environmental footprint (Esenduran 
et al., 2016). Older appliances consume high energy and may 
contain banned substances making them less attractive to reuse 
(Dalhammar et al., 2021).
Furthermore, the legislation necessitates EEE producers who 
serve private consumers to join PRO. This approach provides an 
advantage to the producers by removing their physical responsi-
bility in handling EoL products and the economies of scale, lead-
ing to a more efficient network, especially for collection and 
transportation in more sparsely populated areas in Finland. 
Currently, collective scheme has become more favourable due to 
the general lifespan of EEE that has become shorter, hence no 
hassle for the original producers (Richter and Koppejan, 2016). 
As shown by smartphones, television, washing machine and vac-
uum cleaner, their average lifespan is 2.3 years shorter than the 
design or the desired lifetime (EEA, 2020). Joining PRO also 
means that the recovery will take place in a secondary facilities 
that will not interfere with the original manufacturing process; 
hence, the producer does not need to adjust the process in the 
original plant. A collective scheme through PRO will increase the 
reassurance of collection target fulfilment as the stream of similar 
products from different brands are taken care of altogether. The 
downside of processing in a secondary facility is that all products 
produced by various producers will be treated indiscriminately 
regardless the design or composition which not supporting higher 
value retention.
Another downside, a collective scheme does not support the 
notion of DfE. The idea of collecting same products produced by 
different producers and treated indiscriminately do not provide 
an incentive to improve its design. The shared obligations of a 
collective scheme can lead to a risk in equalizing cost and respon-
sibility among various producers that can cause the lack of com-
pliance on an individual level (Pouikli, 2020). Nonetheless, 
implementing proportional costs according to the actual brands’ 
WM costs can be difficult since it requires assessing treatment 
costs up to the product level. Atasu and Subramanian (2012) 
reported that charging a recovery fee based on the mix of waste 
generation does not always offer a favourable outcome. This 
method could result in low-end producers free-ride the high-end 
manufacturers. Hence, it was suggested that brand separation is 
applied when dealing with mixed WEEE. Nonetheless, solely 
from logistical perspective, collective scheme is seen as the most 
reasonable way: This (collective scheme) is the only possibility 
and the best possibility for a single company to organize this 
(EPR). When they do it together through producer organization, 
that is the best way (PRO, packaging).
The importance of refining policy 
instruments and business model
Refining current policy instruments can improve EPR to achieve 
its main goals. Advanced fee modulation can be implemented 
to improve the DfE in a collective scheme. The European 
Commission endorses the member states to apply advanced 
fee modulation based on durability, reparability, reusability, 
recyclability and presence of hazardous substances (European 
Parliament, 2018). The conventional disposal fee, which is the 
form of basic fee modulation paid by the producers, reflects only 
the weight of the product placed on the market. Thus, the incen-
tive is obtained by manufacturing a lighter product. The environ-
mental aspect can be integrated into the system by applying 
advanced fee modulation. The producers need to provide a DfE 
factsheet of their products, including the lifespan of the products 
with normal usage. Some products, such as EEE, can take 
advantage of radio-frequency identification technology. It will 
provide information to the reader from the point of first selling 
until disposal. Therefore, the information from the DfE factsheet 
can be matched with the actual results of product recovery. 
Standardization will be needed on a European level to promote 
better recycling, covering a unified definition and terminology, 
uniform methodology in calculating the recycling rate, and 
defining the quality of secondary material. It can also support an 
international market in secondary materials by developing trust 
Mayanti and Helo 11
concerning the quality of secondary materials. Implementing 
either a penalty-only approach or modulated obligations is rec-
ommended to start advanced fee modulation practice, especially 
when multiple PROs exist (Ahlers et al., 2021). The first 
approach will require producers to continue paying a normal fee 
to the PRO, whereas producers with substandard products will 
pay the penalty. The penalty will be coordinated by an independ-
ent body to finance activities done by PROs related to WM. The 
latter would impose a bonus and penalty. PROs with many good 
producers will not only receive less contribution from the pro-
ducers but also require to collect less waste. The opposite applies 
to PROs with substandard producers.
Another example is tyres, at which the average retreading rate 
in Finland was around 1% in the past 10 years (Finnish Tyre 
Recycling Ltd, 2022). The waste hierarchy will require higher-
value recovery, making retreading a primary recovery option 
(e.g. Campbell-Johnston et al., 2020; Winternitz et al., 2019). 
However, this should be complemented by careful consideration 
of the type and quality of the products as well as whether higher-
value recovery will compromise the products’ safety and func-
tionality. Instead, more initiatives should support the aim of 
achieving DfE. By applying fee modulation and requiring a DfE 
factsheet, producers who can increase the durability will pay less. 
Moreover, when the products are used up to their lifespan and are 
not eligible for reuse, the recovery is still deemed a success 
although the higher-value recovery does not occur.
Tax and subsidy schemes can be introduced as an economic 
instrument in the EPR scheme in Finland. Introducing a tax and 
subsidy scheme can be seen as a means to promote DfE. The 
amount of tax companies pay depends on the product’s environ-
mental performance. The collected tax is then given to the com-
panies as a subsidy to support their innovation. The subsidy 
amount will be fixed regardless of the environmental perfor-
mance of the companies. Therefore, the greenest producers will 
pay the least tax and gain the same subsidy. A model simulation 
done by Brouillat and Oltra (2012) reports that a tax and subsidy 
system can create radical innovation in the design for recycling. 
Combining a mandatory recovery target with tax and subsidy 
will stimulate innovation and improve the outcome compared to 
combining a mandatory target with an advanced disposal fee 
(Brouillat and Oltra, 2012; Dubois, 2012). The mandatory target 
in Finland can be revisited regularly and adjusted. Setting an 
EPR target is ideally based on the social, environmental and 
financial impacts.
The producers must also reconsider their business model, 
moving from selling to leasing products. This business model can 
promote the shift towards individual schemes and DfE. Leasing 
does not transfer product ownership from producers to consum-
ers making producers responsible for the products throughout 
their life cycle. This type of arrangement gives producers indi-
vidual responsibility for the products. Applying a leasing system 
can incentivize companies to manufacture long-lasting products 
because the products will be intensively used, cost and material 
efficient, and reused as much as possible at the EoL stage (Tukker, 
2015). This proposition was confirmed by the economic model 
showing that compared with selling, leasing provides a higher 
incentive to produce durable products (Pangburn and Stavrulaki, 
2014; Steeneck and Sarin, 2018). The policy should be designed 
accordingly to support the leasing scenario optimally. So far, 
mandatory targets have been used to evaluate the system’s per-
formance. In the case of leasing, durability-dependent targets (a 
target tied to product failure) should be applied because manda-
tory targets may reduce the company’s willingness to manufac-
ture durable products (Pangburn and Stavrulaki, 2014). 
Implementing a leasing model can start with producers who serve 
the business by using pilot projects targeting a few businesses 
where the relationship is already built.
Transparency and economic implications
One of the aims of EPR, which was to shift the burden from the 
municipality, was reflected by the economic policy instruments 
found across different products. Disposal fee was universally 
used, except for paper, with additional policies such as a deposit–
refund system and beverage tax for the beverage packaging. 
Among others, economic instruments combined with collection 
and recycling targets will affect the costs, benefits and how the 
WRL network is designed. The costs and benefits are born among 
actors involved in the network, which can be classified into col-
lectors, sorters, recyclers and PROs. The same entity can have 
more than one role (e.g. recycler carries out sorting and recy-
cling) or multiple entities covering the same role (e.g. WM com-
pany and company handle collection). PRO determines the value 
of the fee and distributes it to ensure that each actor within the 
WRL network bears an equal financial burden. However, uneven 
distributions can be found where the municipality that is com-
monly involved in the collection experiences financial losses. In 
the case of plastic packaging, the municipality was compensated 
by the PRO for about 60–70% of the total cost; hence, the deficit 
was covered using tax waste (Andreasi Bassi et al., 2020). For 
WEEE, the municipality was reimbursed for not more than 16% 
of its expense (Favot et al., 2016).
Among four actors within the WRL, recyclers are not con-
nected directly to the PRO. They do not receive compensation 
from PRO as one of the financial benefits. Their revenues are 
from selling secondary materials or avoiding purchasing raw 
materials. Examples from plastics recycling showed the impor-
tance of the market substitution factor as the most sensitive 
parameter (Faraca et al., 2019; Mayanti & Helo, 2022). It implies 
market acceptance highly affects secondary material’s economic 
and environmental benefits. Hence, the economic viability of 
secondary material depends on the market demands, cost com-
petition with virgin material and cooperation among actors within 
the WRL network (Andreasi Bassi et al., 2020). A continuous 
evaluation of the WRL is necessary to investigate the most suit-
able network configuration in order to obtain optimum outcomes. 
With regard to the methodology, this study did not particularly 
investigate the economic impacts of EPR scheme. Future studies 
12 Waste Management & Research 00(0)
can focus on the economic impact of EPR scheme by applying 
cost–benefit analysis covering capital expenditure (building and 
equipment costs) and operating expense (the cost of energy, 
material and wage maintenance) (Andreasi Bassi et al., 2020).
Within the context of the study, it demands more transparency 
for data regarding EPR practice in Finland to expand the study, 
including quantifying the economic impact. The required data are 
more than what has been reported, such as the quantities placed 
on the market, collected, recycled and utilized. Some PROs dis-
close the cost of the disposal fees; however, information concern-
ing how and how much the municipality is being compensated is 
still unclear. The knowledge about costs and benefits distribution 
among actors can be utilized to improve the system since it pro-
vides information about the financial hotspot. Moreover, the eco-
nomic feasibility of the system can be analysed continuously 
when the authority plans to revise the legislation (e.g. increasing 
collection or recycling target). The summary of challenges and 
opportunity regarding the EPR implementation can be found in 
Table 5.
Methodology limitations and future 
works
Applying a case study methodology poses some strengths and 
limitations. Case studies can provide detailed accounts and 
insights on certain contemporary issues within their context. The 
variety of data used in a case study can offer insights and 
strengthen the study. For example, material recovery was seen as 
potential economic revenue to pursue in literature. In comparison, 
the interview with the PRO of packaging explicitly showed an 
account of how expensive the system is. It was highlighted that 
the system could be managed because producers put their money 
first, while the PRO continuously tries to reduce the fee. The case 
study can contextualize an issue, which in this case, provides an 
insight into the gap between the theory (waste is a resource) and 
the reality experienced by actors who are directly involved (waste 
is a waste). The other advantage of a case study is its design flex-
ibility. A set of choices can be made to conduct a case study: the 
number of cases (single and several), variability (temporal and 
spatial), focus (process and outcomes), how to evaluate the data, 
etc. The flexible nature enables a case study to keep up with 
evolving research objectives since analysis in the case study 
begins while the data collection process is still ongoing, making 
the whole process iterative. However, the flexibility and compre-
hensiveness of a case study can cause drawbacks since a vast 
amount of data is needed, and they may not be available.
Other limitations of a case study are subjectivity and validity. 
The flexibility offers much freedom to build the study yet is 
prone to subjectivity. Decisions made during data collection, 
analysis and interpretation are influenced by researchers’ knowl-
edge and what they consider important. Formulating research 
stages, as shown in Section ‘Methodology’, when working with a 
case study methodology can help with subjectivity. They provide 
guidelines such as the scope of the study, the required data, col-
lection and analysis methods. Another issue with case study Ta
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Mayanti and Helo 13
methodology is validity, where the study cannot be generalized 
statistically (as a sample representing a population). Nevertheless, 
it still provides insights since analytic generalization can be 
applied. The outcomes of a case study can result in a working 
hypothesis, lesson learned, principles deemed suitable for other 
situations and knowledge to support, alter or reject existing 
knowledge (Yin, 2003). This study supports what Barker and 
Zabinsky (2008) stated that decentralized or centralized sorting 
depends on the products and their sorting complexity. This study 
also verified their work, showing that most collective schemes 
use a secondary facility for reprocessing stage.
Future work can expand the study to other EU members to 
understand how their EPR system is. It will allow comparison 
and draw lessons in understanding the state of EPR implemen-
tation in different country members, primarily in understanding 
differences in policy instruments and policy design to achieve 
DfE as the main aim of EPR. Specific research about the effec-
tiveness of financial instruments in reducing the waste or incen-
tivizing DfE is also of interest. It can be conducted through an 
economic model to compare financial instruments such as dis-
posal fees and deposit–refund systems for waste reduction.
Conclusions
This article investigated the policy architectures and WRL net-
works of collective EPR in Finland for six different products: 
packaging, EEE, vehicle, batteries and accumulators, paper and 
tyres. Finland performs well in the collective EPR scheme, 
which can be associated to the system architectures of the policy 
instruments. It shows the significance of policy design and the 
stringency of the instruments. The positive outcomes associated 
with the EPR scheme are the results of a combination of differ-
ent instrument as well as its stringency, since same instruments 
are implemented for different products but produce different 
outcomes. Nonetheless, DfE is still an issue to address. Refining 
existing policy instruments can assist the shift towards DfE. 
Careful consideration is necessary to formulate a policy that can 
support DfE such as DfE indicators, standardization, tax and 
subsidy systems and tariffs for disposal fees. Furthermore, the 
research highlighted the importance of policy to support circu-
larity beyond closing the loop, which is still the main strategy 
within EPR. Finnish legislation that obliges EEE producers to 
join PRO will guarantee the fulfilment of recycling and energy 
recovery targets without prioritizing higher recovery value (e.g. 
product reuse or component reuse).
The study also generated WRL framework based on the 
existing EPR system in Finland. It facilitated assessment of the 
possible consequences due to differences in WRL network. 
The framework generated in this study can be used by PROs or 
producers to build WRL or switch from their existing system. 
The WRL networks were implemented to meet the target 
required by the administration instruments. Analysis of the 
WRL networks showed differences among Finnish PRO in 
managing the EoL products that was affected by waste type, 
quantity, value, cost, required sorting technique and available 
recovery options. The similarities in implementing a drop-off 
system and using secondary facilities were found across six 
products. This research further outlines the need for transpar-
ency. The publicly available information is insufficient to 
assess EPR performance comprehensively, particularly in 
quantifying the economic feasibility. Results showed multiple 
actors involved in the WRL networks that potentially experi-
ence uneven distribution of costs and benefits or even have a 
net loss. The interconnectedness among actors in the WRL net-
works also highlights their importance in linking the EoL stage 
with forward logistics to achieve circularity.
The research contributes to the limited number of current 
studies about EPR implementation which focusing on policy 
architecture and RL networks on a country level. The framework 
can serve as a guideline to develop efficient RL system while 
weighing the trade-offs. Moreover, the study puts EPR scheme 
into perspective since assessment on national level enables cross-
comparison among products so that improvement on the network 
design or policy instruments combination can be improved by 
related actors.
Declaration of conflicting interests
The authors declared no potential conflicts of interest with respect to 
the research, authorship, and/or publication of this article.
Funding
The authors received no financial support for the research, author-
ship, and/or publication of this article.
ORCID iD
Bening Mayanti  https://orcid.org/0000-0001-5073-7375
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