Introduction
Background and Terms of Reference
Background
Recycled plastic materials and articles shall only be placed on the market if the recycled plastic is from an authorised recycling process. Before a recycling process is authorised, the European Food Safety Authority (EFSA)'s opinion on its safety is required. This procedure has been established in Article 5 of Regulation (EC) No 282/20081,2 on recycled plastic materials intended to come into contact with foods and Articles 8 and 9 of Regulation (EC) No 1935/20043 on materials and articles intended to come into contact with food.
According to this procedure, the industry submits applications to the competent authorities of Member States, which transmit the applications to EFSA for evaluation.
In this case, EFSA received from the Austrian Competent Authority (Bundesministerium für Soziales, Gesundheit, Pflege und Konsumentenschutz) an application for evaluation of the recycling process Green PET Recycling, European Union (EU) register No RECYC277. The request has been registered in EFSA's register of received questions under the number EFSA-Q-2022-00271. The dossier was submitted on behalf of Green PET Recycling Ltd, Kidmat Galil Industries Park 1522801, Kidmat Galil, Israel.
Terms of Reference
The Austrian Competent Authority (Bundesministerium für Soziales, Gesundheit, Pflege und Konsumentenschutz) requested the safety evaluation of the recycling process Green PET Recycling, in accordance with Article 5 of Regulation (EC) No 282/2008.
Interpretation of the Terms of Reference
According to Article 5 of Regulation (EC) No 282/2008 on recycled plastic materials intended to come into contact with foods, EFSA is required to carry out risk assessments on the risks originating from the migration of substances from recycled food contact plastic materials and articles into food and deliver a scientific opinion on the recycling process examined.
According to Article 4 of Regulation (EC) No 282/2008, EFSA will evaluate whether it has been demonstrated in a challenge test, or by other appropriate scientific evidence, that the recycling process Green PET Recycling is able to reduce the contamination of the plastic input to a concentration that does not pose a risk to human health. The poly(ethylene terephthalate) (PET) materials and articles used as input of the process as well as the conditions of use of the recycled PET are part of this evaluation.
Data and Methodologies
Data
The applicant has submitted a confidential and a non-confidential version of a dossier following the ‘EFSA guidelines for the submission of an application for the safety evaluation of a recycling process to produce recycled plastics intended to be used for the manufacture of materials and articles in contact with food, prior to its authorisation’ (EFSA, 2008) and the ‘Administrative guidance for the preparation of applications on recycling processes to produce recycled plastics intended to be used for manufacture of materials and articles in contact with food’ (EFSA, 2021).
Additional information was sought from the applicant during the assessment process in response to requests from EFSA sent on 09 November 2022 and was subsequently provided (see ‘Documentation provided to EFSA’).
In accordance with Art. 38 of the Regulation (EC) No 178/20024 and taking into account the protection of confidential information and of personal data in accordance with Articles 39 to 39e of the same Regulation, and of the Decision of EFSA's Executive Director laying down practical arrangements concerning transparency and confidentiality,5 the non-confidential version of the dossier has been published on Open.EFSA.6
According to Art. 32c(2) of Regulation (EC) No 178/2002 and to the Decision of EFSA's Executive Director laying down the practical arrangements on pre-submission phase and public consultations,2 EFSA carried out a public consultation on the non-confidential version of the application from 03 January to 24 January 2023, for which no comments were received.
The following information on the recycling process was provided by the applicant and used for the evaluation:
General information:
- – general description,
- – existing authorisations.
Specific information:
- – recycling process,
- – characterisation of the input,
- – determination of the decontamination efficiency of the recycling process,
- – characterisation of the recycled plastic,
- – intended application in contact with food,
- – compliance with the relevant provisions on food contact materials and articles,
- – process analysis and evaluation,
- – operating parameters.
Methodologies
The risks associated with the use of recycled plastic materials and articles in contact with food come from the possible migration of chemicals into the food in amounts that would endanger human health. The quality of the input, the efficiency of the recycling process to remove contaminants as well as the intended use of the recycled plastic are crucial points for the risk assessment (EFSA, 2008).
The criteria for the safety evaluation of a mechanical recycling process to produce recycled PET intended to be used for the manufacture of materials and articles in contact with food are described in the scientific opinion developed by the EFSA Panel on Food Contact Materials, Enzymes, Flavourings and Processing Aids (EFSA CEF Panel, 2011). The principle of the evaluation is to apply the decontamination efficiency of a recycling technology or process, obtained from a challenge test with surrogate contaminants, to a reference contamination level for post-consumer PET, conservatively set at 3 mg/kg PET for contaminants resulting from possible misuse. The resulting residual concentration of each surrogate contaminant in recycled PET (Cres) is compared with a modelled concentration of the surrogate contaminants in PET (Cmod). This Cmod is calculated using generally recognised conservative migration models so that the related migration does not give rise to a dietary exposure exceeding 0.0025 μg/kg body weight (bw) per day (i.e. the human exposure threshold value for chemicals with structural alerts for genotoxicity), below which the risk to human health would be negligible. If the Cres is not higher than the Cmod, the recycled PET manufactured by such recycling process is not considered of safety concern for the defined conditions of use (EFSA CEF Panel, 2011).
The assessment was conducted in line with the principles described in the EFSA Guidance on transparency in the scientific aspects of risk assessment (EFSA, 2009) and considering the relevant guidance from the EFSA Scientific Committee.
Assessment
General information7
According to the applicant, the recycling process Green PET Recycling is intended to recycle food grade PET containers using the Starlinger iV+ technology. The recycled PET is intended to be used at up to 100% for the manufacture of materials and articles for direct contact with all kinds of foodstuffs for long-term storage at room temperature, with or without hotfill, such as bottles for mineral water and beverages. The recycled pellets may also be used for sheets, which are thermoformed to make food trays. The final articles are not intended to be used in microwave or conventional ovens.
Description of the process
General description8
The recycling process Green PET Recycling produces recycled PET pellets from PET containers (e.g. bottles), from post-consumer collection systems (kerbside, deposit systems and mixed waste collection).
The recycling process comprises the four steps below.
Input
- In step 1, the post-consumer PET containers are processed into hot caustic washed and dried flakes. This step may be performed by a third party or by the applicant.
Decontamination and production of recycled
- In step 2, the flakes are dried and crystallised in a reactor under air flow at high temperature.
- In step 3, the flakes are extruded under vacuum at high temperature and then crystallised.
- In step 4, the crystallised pellets are preheated before being treated in a solid-state polycondensation (SSP) reactor at high temperature and under vacuum.
The operating conditions of the process have been provided to EFSA.
Pellets, the final product of the process, are checked against technical requirements, such as intrinsic viscosity, acetaldehyde, pellets size and bulk density.
Characterisation of the input9
According to the applicant, the input material for the recycling process Green PET Recycling consists of hot caustic washed and dried flakes obtained from PET containers, e.g. bottles, previously used for food packaging, from post-consumer collection systems (kerbside, deposit systems and mixed waste collection). A small fraction may originate from non-food applications. According to the applicant, the proportion will be no more than 5%.
Technical data for the hot washed and dried flakes are provided, such as information on physical properties and on residual contents of moisture, metal, poly(vinyl chloride) (PVC), polyolefins and other plastics than PET (see Appendix A).
Starlinger
Description of the main steps10
The general scheme of the Starlinger iV+ technology, as provided by the applicant, is reported in Figure 1. The steps are:
- Drying and crystallisation (step 2): In a continuous process, the flakes are dried and crystallised in a reactor at high temperature and under air flow.
- Extrusion and crystallisation (step 3): The flakes from the previous step are fed into an extruder under high temperature and vacuum for a predefined residence time. The pellets are then crystallised at high temperature in a continuous reactor under atmospheric pressure.
- SSP (step 4): The crystallised pellets are preheated in a reactor before being introduced into a semi-continuous SSP reactor running under vacuum at a high temperature and for a predefined residence time.
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The process is run under defined operating parameters11 of temperature, pressure, air/PET ratio and residence time.
Decontamination efficiency of the recycling process12
To demonstrate the decontamination efficiency of the recycling process Green PET Recycling, a challenge test performed at pilot plant scale was submitted to EFSA.
PET flakes were contaminated with toluene, chloroform, phenylcyclohexane, benzophenone and lindane, selected as surrogate contaminants in agreement with the EFSA guidelines (EFSA CEF Panel, 2011) and in accordance with the recommendations of the US Food and Drug Administration (FDA, 2006). The surrogates include different molecular masses and polarities to cover possible chemical classes of contaminants of concern and were demonstrated to be suitable to monitor the behaviour of PET during recycling (EFSA, 2008).
Conventionally recycled13 post-consumer PET flakes were soaked in a heptane/isopropanol solution containing the surrogates and stored for 14 days at 40°C. After decanting the surrogate solution, the flakes were rinsed with water and air-dried. The concentration of surrogates in these flakes was determined.
The Starlinger IV+ technology was challenged at the Starlinger facilities in pilot plant scale. The contaminated flakes were introduced directly into the drier (step 2), then sampled after each step (2–4) to measure the residual concentrations of the applied surrogates. Instead of being processed continuously, the SSP reactor was run in batch mode. However, since the reactor in the process works practically with no mixing, the Panel agreed that the batch reactor in the challenge test provided the same cleaning efficiency when run at the same temperature, pressure and residence time.
The decontamination efficiency of the process was calculated from the concentrations of the surrogates measured in the washed contaminated flakes before drying and crystallisation (before step 2) and after SSP (step 4). The results are summarised in Table 1.
Table 1 Efficiency of the decontamination of the Starlinger iV+ technology in the challenge test
Surrogates | Concentration of surrogates before step 2 (mg/kg PET) | Concentration of surrogates after step 4 (mg/kg PET) | Decontamination efficiency (%) |
Toluene | 563 | < 0.8(a) | > 99.9 |
Chloroform | 1,900 | < 0.5(a) | > 99.9 |
Phenylcyclohexane | 538 | < 0.3(a) | > 99.9 |
Benzophenone | 694 | 10.8 | 98.4 |
Lindane | 373 | 33.9 | 90.9 |
As shown in Table 1, the decontamination efficiency ranged from 90.9% for lindane to more than 99.9% for toluene, chloroform and phenylcyclohexane.
Discussion
Considering the high temperatures used during the process, the possibility of contamination by microorganisms can be discounted. Therefore, this evaluation focuses on the chemical safety of the final product.
Technical data, such as on physical properties and residual contents of PVC, polyolefins and metals, were provided for the input materials (i.e. washed and dried flakes, step 1). These are produced mainly from PET containers, e.g. bottles, previously used for food packaging, collected through post-consumer collection systems. However, a small fraction may originate from non-food applications, e.g. bottles from window cleaner or shampoo. According to the applicant, the collection system and the process are managed in such a way that this fraction will be no more than 5% of the input stream, as recommended by the EFSA CEF Panel in its ‘Scientific opinion on the criteria to be used for safety evaluation of a mechanical recycling process to produce recycled PET intended to be used for manufacture of materials and articles in contact with food’ (EFSA CEF Panel, 2011).
The process is adequately described. The washing and drying of the flakes from the collected PET (step 1) is conducted in different ways, depending on the plant, and, according to the applicant, this step is under control. The Starlinger iV+ technology comprises drying and crystallisation (step 2), extrusion and crystallisation (step 3) and SSP (step 4). The operating parameters of temperature, residence time, pressure and air/PET ratio have been provided to EFSA.
A challenge test to measure the decontamination efficiency was conducted at pilot plant scale on process steps 2–4. The reactor was operated under pressure and temperature conditions as well as residence time equivalent to or less severe than those of the commercial process. The Panel considered that this challenge test was performed correctly according to the recommendations in the EFSA guidelines (EFSA, 2008). The fourth step is expected to be the most critical step for the decontamination, but drying and crystallisation (step 2) as well as extrusion and crystallisation (step 3) are relevant, too. Therefore, the Panel considered that these three steps (drying and crystallisation, extrusion and crystallisation, SSP) were critical for the decontamination efficiency of the process. Consequently, the temperature, the air/PET ratio and the residence time for the drying and crystallisation (step 2), as well as the temperature, the pressure and the residence time for extrusion and crystallisation (step 3) and SSP (step 4) should be controlled to guarantee the performance of the decontamination (Appendix C).
The decontamination efficiencies obtained for each surrogate, ranging from 90.9% to >99.9%, have been used to calculate the residual concentrations of potential unknown contaminants in PET (Cres) according to the evaluation procedure described in the ‘Scientific Opinion on the criteria to be used for safety evaluation of a mechanical recycling process to produce recycled PET’ (EFSA CEF Panel, 2011; Appendix B). By applying the decontamination percentages to the reference contamination level of 3 mg/kg PET, the Cres for the different surrogates was obtained (Table 2).
Table 2 Decontamination efficiency from the challenge test, residual concentrations of the surrogates (Cres) related to the reference contamination level and calculated concentrations of the surrogates in PET (Cmod) corresponding to a modelled migration of 0.1 μg/kg food after 1 year at 25°C
Surrogates | Decontamination efficiency (%) | Cres for 100% rPET (mg/kg PET) | Cmod (mg/kg PET) |
Toluene | > 99.9 | < 0.003 | 0.09 |
Chloroform | > 99.9 | < 0.003 | 0.10 |
Phenylcyclohexane | > 99.9 | < 0.003 | 0.14 |
Benzophenone | 98.4 | 0.048 | 0.16 |
Lindane | 90.9 | 0.273 | 0.31 |
According to the evaluation principles (EFSA CEF Panel, 2011), the dietary exposure must not exceed 0.0025 μg/kg bw per day, below which the risk to human health is considered negligible. The Cres value should not exceed the modelled concentration in PET (Cmod) that, after 1 year at 25°C, results in a migration giving rise to a dietary exposure of 0.0025 μg/kg bw per day. Because the recycled PET is intended for the manufacturing of articles (e.g. bottles) to be used in direct contact with drinking water, the exposure scenario for infants has been applied (water could be used to prepare infant formula). A maximum dietary exposure of 0.0025 μg/kg bw per day corresponds to a maximum migration of 0.1 μg/kg into food and has been used to calculate Cmod (EFSA CEF Panel, 2011). The results of these calculations are shown in Table 2. The relationship between the key parameters for the evaluation scheme is reported in Appendix B.
As Cres values are lower than the corresponding modelled concentrations in PET (Cmod), the Panel considered that under the given operating conditions the recycling process Green PET Recycling using the Starlinger iV+ technology is able to ensure that the level of migration of unknown contaminants from the recycled PET into food is below the conservatively modelled migration of 0.1 μg/kg food, at which the risk to human health is considered negligible.
The Panel noted that the input of the process originates from Israel. In the absence of data on misuse contamination of this input, the Panel used the reference contamination of 3 mg/kg PET (EFSA CEF Panel, 2011) that was derived from experimental data from an EU survey. Accordingly, the recycling process under evaluation using a Starlinger iV+ technology is able to ensure that the level of unknown contaminants in recycled PET is below a calculated concentration (Cmod) corresponding to a modelled migration of 0.1 μg/kg food.
Conclusions
The Panel considered that the process Green PET Recycling using the Starlinger iV+ technology is adequately characterised and that the main steps used to recycle the PET flakes into decontaminated PET pellets have been identified. Having examined the challenge test provided, the Panel concluded that the three steps (drying and crystallisation, extrusion and crystallisation, and SSP) are critical for the decontamination efficiency. The operating parameters to control its performance are the temperature, the air/PET ratio and the residence time for the drying and crystallisation (step 2), as well as the temperature, the pressure and the residence time for extrusion and crystallisation (step 3) and SSP (step 4).
The Panel concluded that the recycling process Green PET Recycling is able to reduce foreseeable accidental contamination of post-consumer food contact PET to a concentration that does not give rise to concern for a risk to human health if:
- it is operated under conditions that are at least as severe as those applied in the challenge test used to measure the decontamination efficiency of the process;
- the input material of the process is washed and dried post-consumer PET flakes originating from materials and articles that have been manufactured in accordance with the EU legislation on food contact materials and contain no more than 5% of PET from non-food consumer applications;
- the recycled PET obtained from the process Green PET Recycling is used at up to 100% for the manufacture of materials and articles for contact with all types of foodstuffs, including drinking water, for long-term storage at room temperature, with or without hotfill.
The final articles made of this recycled PET are not intended to be used in microwave or conventional ovens and such uses are not covered by this evaluation.
Recommendation
The Panel recommended periodic verification that the input material to be recycled originates from materials and articles that have been manufactured in accordance with the EU legislation on food contact materials and that the proportion of PET from non-food consumer applications is no more than 5%. This adheres to good manufacturing practice and the Regulation (EC) No 282/2008, Art. 4b. Critical steps in recycling should be monitored and kept under control. In addition, supporting documentation should be available on how it is ensured that the critical steps are operated under conditions at least as severe as those in the challenge test used to measure the decontamination efficiency of the process.
Documentation as provided to
Dossier ‘Green PET Recycling’. April 2022. Submitted on behalf of Green PET Recycling Ltd, Israel.
Additional information, November 2022. Submitted on behalf of Green PET Recycling Ltd, Israel.
- bw
- body weight
- CEF Panel
- Panel on Food Contact Materials, Enzymes, Flavourings and Processing Aids
- CEP Panel
- Panel on Food Contact Materials, Enzymes and Processing Aids
- Cmod
- modelled concentration in PET
- Cres
- residual concentrations in PET
- iV
- intrinsic viscosity
- PET
- poly(ethylene terephthalate)
- PVC
- poly(vinyl chloride)
- rPET
- recycled poly(ethylene terephthalate)
- SSP
- solid-state polycondensation
Abbreviations
Appendix A – Technical data of the washed flakes as provided by the applicant9
Parameter | Value |
PVC content | < 200 mg/kg |
Polyolefin content | < 100 mg/kg |
Metal content (Aluminium, ferrous, others) | < 200 mg/kg |
Other plastics | < 200 mg/kg |
Dust | < 1.5% |
Moisture | < 2.5% |
Bulk density | 200–600 kg/m3 |
Amount of non-food application PET | < 5% |
Appendix B – Relationship between the key parameters for the evaluation scheme (EFSA CEF Panel, 2011)
*: Default scenario (infant). For adults and toddlers, the migration criterion will be 0.75 and 0.15 μg/kg food, respectively. The figures are derived from the application of the human exposure threshold value of 0.0025 μg/kg bw per day applying a factor of 5 related to the overestimation of modelling.
Appendix C – Table of operational parameters14
■■■■■
■■■■■
■■■■■
Process Green PET Recycling (RECYC277) based on the Starlinger iV+ technology | |||||||||
Step 2 Drying and crystallisation | Step 3 Extrusion + vacuum degassing: 1st line Crystallisation: 2nd line | Step 4 SSP process | |||||||
Parameters | t (min) | Air/PET ratio (m3/kg) | T (°C) | t | P (mbar) | T(°C) | t (h) | P (mbar) | T (°C) |
Challenge test (Fraunhofer report 4452/05) | ■■■■■ (batch) | ~ ■■■■■ | ■■■■■ |
■■■■■ s ■■■■■ min (crystallisation: batch) |
■■■■■ atmospheric |
■■■■■ ■■■■■ |
■■■■■ (batch) | ■■■■■ | ■■■■■ |
Process | ≥ ■■■■■ (continuous) | ~ ■■■■■ | ≥ ■■■■■ |
■■■■■s ≥ ■■■■■ min (crystallisation: continuous) |
≤ ■■■■■ atmospheric |
≥ ■■■■■ ≥ ■■■■■ |
≥ ■■■■■ (semi-continuous) | ≤ ■■■■■ | ≥ ■■■■■ |
EFSA (European Food Safety Authority), 2008. Guidelines for the submission of an application for safety evaluation by the EFSA of a recycling process to produce recycled plastics intended to be used for manufacture of materials and articles in contact with food, prior to its authorisation. EFSA Journal 2008;6(7):717, 12 pp. [DOI: https://dx.doi.org/10.2903/j.efsa.2008.717]
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Abstract
The EFSA Panel on Food Contact Materials, Enzymes and Processing Aids (CEP) assessed the safety of the recycling process Green PET Recycling (EU register number RECYC277), which uses the Starlinger iV+ technology. The input is hot caustic washed and dried poly(ethylene terephthalate) (PET) flakes mainly originating from collected post‐consumer PET containers, with no more than 5% PET from non‐food consumer applications. The flakes are dried and crystallised in a first reactor, then extruded into pellets. These pellets are crystallised, preheated and treated in a solid‐state polycondensation (SSP) reactor. Having examined the challenge test provided, the Panel concluded that the drying and crystallisation (step 2), extrusion and crystallisation (step 3) and SSP (step 4) are critical in determining the decontamination efficiency of the process. The operating parameters to control the performance of these critical steps are temperature, air/PET ratio and residence time for the drying and crystallisation step, and temperature, pressure and residence time for the extrusion and crystallisation step as well as the SSP step. It was demonstrated that this recycling process is able to ensure that the level of migration of potential unknown contaminants into food is below the conservatively modelled migration of 0.1 μg/kg food. Therefore, the Panel concluded that the recycled PET obtained from this process is not of safety concern when used at up to 100% for the manufacture of materials and articles for contact with all types of foodstuffs, including drinking water, for long‐term storage at room temperature, with or without hotfill. The final articles made of this recycled PET are not intended to be used in microwave and conventional ovens and such uses are not covered by this evaluation.
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