EPD-IES-0028071:002

Cold Rolled Aluminium Coil

Cold Rolled Aluminium Coil is a flat-rolled aluminium product manufactured by cold rolling of cast aluminium, supplied in continuous coil form. The product has a thickness range of 0.2 to 4.0 mm and is produced in accordance with EN 485-2 for mechanical properties and EN 573-3 for chemical composition. The product provides high dimensional accuracy, uniform thickness, good surface quality, and excellent formability, making it suitable for further processing such as slitting, cutting, forming, embossing, or coating. Due to its lightweight structure, corrosion resistance, and mechanical stability, Cold Rolled Aluminium Coil is widely used as a semi-finished material in construction, HVAC systems, automotive components, packaging applications, heat exchangers, household appliances, and electrical applications. The environmental performance of the product is declared per 1 kg of Cold Rolled Aluminium Coil as a declared unit, in accordance with EN 15804 and the applicable Product Category Rules.

General information

EPD OwnerVİG METAL SANAYİ VE TİCARET ANONİM ŞİRKETİ
Registration numberEPD-IES-0028071:002
EPD typeEPD of multiple products based on the average results of the product group
StatusValid
Initial version date2026-01-19
Validity date2031-01-19
Standards conformanceISO 14025:2006, EN 15804:2012+A2:2019/AC:2021
LicenseeEPD Türkiye
Geographical scopeRepublic of Türkiye
An EPD may be updated or depublished if conditions change. This is the latest version of the EPD.

Programme information

ProgrammeThe International EPD® System 
AddressEPD International AB Box 210 60 SE-100 31 Stockholm Sweden
Websitewww.environdec.com
E-mailsupport@environdec.com

Product category rules

CEN standard EN 15804 serves as the Core Product Category Rules (PCR)
Product Category Rules (PCR)2019:14 Construction products (EN 15804+A2) (version 2.0.1) 2.0.1
PCR review was conducted byThe Technical Committee of the International EPD System. See www.environdec.com for a list of members. Review chair: Rob Rouwette (chair), Noa Meron (co-chair). The review panel may be contacted via the Secretariat www.environdec.com/support.

Verification

LCA accountabilitySeymanur Sülün, seymanursulun@semtrio.com, VİG METAL SANAYİ VE TİCARET ANONİM ŞİRKETİ
Independent third-party verification of the declaration and data, according to ISO 14025:2006, via
Third-party verifierIpek Goktas Kalkan (One Click LCA)
Approved byInternational EPD System
Procedure for follow-up of data during EPD validity involves third party verifier
*EPD Process Certification involves an accredited certification body certifying and periodically auditing the EPD process and conducting external and independent verification of EPDs that are regularly published. More information can be found in the General Programme Instructions on www.envrondec.com.

Ownership and limitation on use of EPD

Limitations

EPDs within the same product category but published in different EPD programmes, may not be comparable. For two EPDs to be comparable, they shall be based on the same PCR (including the same first-digit version number) or be based on fully aligned PCRs or versions of PCRs; cover products with identical functions, technical performances and use (e.g. identical declared/functional units); have identical scope in terms of included life-cycle stages (unless the excluded life-cycle stage is demonstrated to be insignificant); apply identical impact assessment methods (including the same version of characterisation factors); and be valid at the time of comparison.

Ownership

The EPD Owner has the sole ownership, liability, and responsibility for the EPD.

Information about EPD Owner

EPD OwnerVİG METAL SANAYİ VE TİCARET ANONİM ŞİRKETİ
Contact person nameHUSEYIN EROL
Contact person e-mailherol@viggroup.com.tr
Organisation addressTurkey KOCAELİ 43100 TAVŞANLI MAHALLESİ 4513. SOKAK NO:11 1.ORGANİZE SANAYİ BÖLGESİ 6.CADDE NO:15

Description of the organisation of the EPD Owner

Vig Metal Sanayi ve Ticaret A.Ş. is an industrial aluminium producer established in 2006 and located in the Kütahya Organized Industrial Zone, Türkiye. The company specializes in the production of cold rolled aluminium coils, sheets, and foils for a wide range of industrial applications, including construction, automotive, HVAC, packaging, and consumer goods. Vig Metal operates continuous 24/7 production with an annual capacity of approximately 45,000 tonnes and employs advanced manufacturing technologies to ensure high product quality and compliance with international standards such as EN 485 and EN 546. The company is committed to sustainability through energy efficiency measures, internal recycling of aluminium scrap, and the use of renewable energy sources, including on-site photovoltaic power generation.

Organisation images

Organisation logo

Product information

Product nameCold Rolled Aluminium Coil
Product identificationCold Rolled Aluminium Coil, manufactured by Vig Metal Sanayi ve Ticaret A.Ş., is a flat-rolled aluminium product produced by cold rolling, with a thickness range of 0.2–4.0 mm, supplied in coil form. The product is manufactured in accordance with EN 485-2 (mechanical properties) and EN 573-3 (chemical composition). The product is classified under UN CPC code 42115 – Other flat-rolled products of aluminium (thickness > 0.2 mm).
Product descriptionCold Rolled Aluminium Coil is a flat-rolled aluminium product manufactured by cold rolling of cast aluminium, supplied in continuous coil form. The product has a thickness range of 0.2 to 4.0 mm and is produced in accordance with EN 485-2 for mechanical properties and EN 573-3 for chemical composition. The product provides high dimensional accuracy, uniform thickness, good surface quality, and excellent formability, making it suitable for further processing such as slitting, cutting, forming, embossing, or coating. Due to its lightweight structure, corrosion resistance, and mechanical stability, Cold Rolled Aluminium Coil is widely used as a semi-finished material in construction, HVAC systems, automotive components, packaging applications, heat exchangers, household appliances, and electrical applications. The environmental performance of the product is declared per 1 kg of Cold Rolled Aluminium Coil as a declared unit, in accordance with EN 15804 and the applicable Product Category Rules.
Product information from external sourcesAdditional product information is available in the Environmental Product Declaration (EPD) and the associated Life Cycle Assessment (LCA) background report prepared in accordance with EN 15804:2012+A2:2019 and PCR 2019:14.
Technical purpose of productCold Rolled Aluminium Coil is intended for use as a semi-finished aluminium material for further processing in industrial and construction-related applications. The product is designed to be cut, slit, formed, embossed, coated, or otherwise processed into finished or intermediate products. Its technical purpose is to provide lightweight, corrosion-resistant, and formable aluminium material with stable mechanical properties and consistent dimensional quality, suitable for use in construction elements, HVAC components, automotive parts, packaging products, heat exchangers, household appliances, and electrical applications.
Manufacturing or service provision descriptionCold Rolled Aluminium Coil is manufactured through a continuous industrial process starting with the melting of aluminium ingots, primary aluminium, and aluminium scrap, followed by twin-roll continuous casting to produce cast coils. The cast material is subsequently processed through cold rolling to achieve the required thickness and mechanical properties. Cold rolling is combined with annealing to obtain the desired material characteristics. After rolling and heat treatment, the coils undergo degreasing, tension levelling, edge trimming, and slitting operations to ensure surface quality, dimensional accuracy, and flatness. The finished coils are wound on spools and packaged on wooden pallets for delivery from the factory gate.
Material propertiesVolumetric mass density: 2700 kg/m3
Volumetric mass density:
2700 kg/m3
Manufacturing siteVig Metal Sanayi ve Ticaret A.Ş. Kütahya Manufacturing Site Turkey Kütahya 43000 1. Organize Sanayi Bölgesi, 6. Cadde No: 15 Merkez, Kütahya, Türkiye
UN CPC codeNo applicable UN CPC code
Geographical scopeRepublic of Türkiye
Actual or technical lifespan50> year(s)

Product images

Technical characteristics and performance

Technical performance

Product nameDensity (g/cm³)Chemical composition (% by mass)Melting point (⁰C)Electrical conductivity (MS/m)Thermal conductivity (W/(m.K)Average Coefficient of thermal expansion 20⁰C to 100⁰C (Per ⁰C)Modulus of elasticity (Gpa)Hardness (HB)Yield strength (min) (Mpa)Ultimate tensile strength (min) (Mpa)Breaking elongation (min) (50 mm&4D) (%)
Cold Rolled Aluminium Coil2.69-2.73Varying alloy by alloy, 97-99.75632-66022-36170-22522.5-24 mm/m69-7116-9520351

Content declaration

Content declaration of multiple productsContent shares do not change for the products with different thicknesses.
Hazardous and toxic substancesThe product does not contain any substances from the SVHC candidate list in concentrations exceeding 0.1% of its weight.
Product content
Content nameMass, kgPost-consumer recycled material, mass-% of productBiogenic material, mass-% of productBiogenic material1, kg C/declared unit
Aluminium product0.991000
Others, kg0.009000
Total1000
Note 11 kg biogenic carbon is equivalent to 44/12 kg of CO2
Packaging materials
Material nameMass, kgMass-% (versus the product)Biogenic material1, kg C/declared unit
Pallet0.00670.90.003
Packaging film0.000200
Wood0.0010.10.0004
Total0.007910.0034
Note 11 kg biogenic carbon is equivalent to 44/12 kg of CO2

LCA information

EPD based on declared or functional unitDeclared unit
Declared unit and reference flowCold Rolled Aluminium Coil Mass: 1 kg
Conversion factor to mass1
Are infrastructure or capital goods included in any upstream, core or downstream processes?
Datasources used for this EPDecoinvent database (general) ecoinvent 3.10 database
LCA SoftwareSimaPro SimaPro 9.6
Additional information about the underlying LCA-based informationThe life cycle assessment was conducted in accordance with ISO 14040, ISO 14044, ISO 14025 and EN 15804:2012+A2:2019, following PCR 2019:14 v2.0.1 for construction products. The LCA model is based on site-specific primary data collected from Vig Metal’s manufacturing operations for the reference period from 1 August 2024 to 1 August 2025, complemented by secondary background data from the Ecoinvent v3.10 database. The assessment covers cradle-to-gate with options, including modules A1–A3, A4, C1–C4 and Module D.
Version of the EN 15804 reference packageEF Reference Package 3.1
Characterisation methodsCharacterisation factors and calculation rules according to EN 15804:2012+A2:2019 were applied. Global warming potential (GWP-GHG) is calculated in accordance with IPCC AR5 methodology, while all other impact categories follow the EN 15804+A2 mandatory and additional indicators.
Technology description including background systemThe foreground system represents the industrial production of cold rolled aluminium coil, sheet and foil at Vig Metal’s manufacturing facility in Türkiye, including melting, casting, cold rolling, annealing, finishing operations and packaging. Site-specific primary data were used for the core manufacturing processes (A3). The background system includes upstream and downstream processes such as raw material production, energy supply, transportation and waste treatment, which were modelled using generic datasets from the Ecoinvent v3.10 database. Internal aluminium scrap is treated as a closed-loop flow and fully reused within the production system in accordance with EN 15804.
Scrap (recycled material) inputs contribution levelLess than 10% of the GWP-GHG results in modules A1-A3 come from scrap inputs
Scrap (recycled material) inputs data
Material scrap nameMaterial scrap value
Pre-consumer recycled material0, kg CO2 eq./tonne
The share of the total scrap input that was assumed to come with an environmental burden0.2%

Data quality assessment

Description of data quality assessment and reference yearsThe data quality assessment was conducted in accordance with EN 15804:2012+A2:2019 and PCR 2019:14 v2.0.1. Primary data for manufacturing processes (A1–A3) were collected directly from Vig Metal’s production facility and are representative of the period from 1 August 2024 to 1 August 2025. Secondary data were sourced from Ecoinvent v3.10 and implemented using SimaPro v9.6.0.1. Data quality was evaluated in terms of geographical, technological, and temporal representativeness and rated from fair to very good depending on the life cycle stage.
Data quality assessment
Process nameSource typeSourceReference yearData categoryShare of primary data, of GWP-GHG results for A1-A3
Manufacturing of productCollected dataEcoinvent2025Primary data2.2%
Transport of raw materials to manufacturing site Collected dataEcoinvent2025Primary data0.5%
Total share of primary data, of GWP-GHG results for A1-A32.7%
The share of primary data is calculated based on GWP-GHG results. It is a simplified indicator for data quality that supports the use of more primary data to increase the representativeness of and comparability between EPDs. Note that the indicator does not capture all relevant aspects of data quality and is not comparable across product categories.
Comment on the data sources and other information in the tableThe table shows the share of primary data used for the calculation of GWP-GHG results in Modules A1–A3. Primary data have been collected for electricity consumption in manufacturing and transport of raw materials to the production site, with background processes modelled using Ecoinvent v3.10 datasets. Based on the contribution of these processes to total GWP-GHG impacts, the overall share of primary data amounts to 2.9%, serving as a simplified indicator of data quality in accordance with EN 15804.
Electricity data
Electricity used in the manufacturing process in A3 (A5 for services)
Type of electricity mixResidual electricity mix on the market
Energy sourcesHydro0%
Wind0%
Solar56%
Biomass0%
Geothermal0%
Waste0%
Nuclear0%
Natural gas9%
Coal28%
Oil0%
Peat0%
Other7%
GWP-GHG intensity (kg CO2 eq./kWh)0.51 kg CO2 eq./kWh
Method used to calculate residual electricity mixElectricity consumption is modelled using the dataset “Electricity, medium voltage {TR} | market for electricity, medium voltage | EN15804, U”. Due to the unavailability of a residual electricity mix dataset in the background database, renewable electricity sources are conservatively substituted with fossil-based electricity datasets. This approach ensures a conservative estimation of environmental impacts and avoids potential underestimation of the GWP-GHG indicator.

System boundary

Description of the system boundarye) Cradle to gate with options (A1-A3 and additional modules). The additional modules may be A4 and/or A5.
Excluded modulesYes, there is an excluded module, or there are excluded modules
Justification for the omission of modulesModule A5 (Construction and installation process) and B modules (Use stage) are not declared because the product is a semi-finished aluminium foil supplied at the factory gate. The installation, construction, and use stages are highly dependent on the specific application, project conditions, and downstream processing performed by the customer. Therefore, no generic and representative installation or use-stage scenarios can be defined in accordance with EN 15804:2012+A2:2019 and PCR 2019:14.

Declared modules

Product stageConstruction process stageUse stageEnd of life stageBeyond product life cycle
Raw material supplyTransportManufacturingTransport to siteConstruction installationUseMaintenanceRepairReplacementRefurbishmentOperational energy useOperational water useDe-construction demolitionTransportWaste processingDisposalReuse-Recovery-Recycling-potential
ModuleA1A2A3A4A5B1B2B3B4B5B6B7C1C2C3C4D
Modules declaredXXXXNDNDNDNDNDNDNDNDXXXXX
GeographyGlobalGlobalRepublic of TürkiyeGlobalN/AN/AN/AN/AN/AN/AN/AN/AGlobalGlobalGlobalGlobalGlobal
Share of specific data2.7%--------------
Variation - products1%--------------
Variation - sites0%--------------
DisclaimerThe share of specific/primary data and both variations (products and sites) refer to GWP-GHG results only.

Description of the process flow diagram(s)

The process flow diagram illustrates the cradle-to-gate with options system boundary for the production of cold rolled aluminium coil. It starts with raw material supply (A1), including primary aluminium, secondary aluminium scrap and alloying elements, followed by transport of raw materials to the manufacturing site (A2). The manufacturing stage (A3) comprises melting, continuous casting, cold rolling, annealing, finishing operations (such as trimming, slitting and surface treatment) and packaging. Downstream processes include transport to the construction site (A4) and end-of-life stages, covering de-construction (C1), transport to waste processing (C2), waste processing for recycling (C3) and final disposal (C4). Module D represents the potential benefits from aluminium recycling at the end of life.

Process flow diagram(s) related images

Default scenario

Name of the default scenarioBaseline end-of-life scenario (95% recycling / 5% landfill)
Description of the default scenarioThe default scenario represents the baseline end-of-life situation for cold rolled aluminium coil in accordance with EN 15804:2012+A2:2019 and PCR 2019:14 v2.0.1. It is assumed that 95 % of the aluminium coil is collected, recovered, and recycled at the end of its service life, while the remaining 5 % is disposed of in landfill (based on European Aluminium circular economy data and industry practice as described by European Aluminium). Transport of end-of-life aluminium to waste treatment facilities is assumed to occur by road over an average distance of 80 km. Recycling processes and disposal are modelled using generic datasets from the Ecoinvent v3.10 database, in line with European Aluminium Association recovery rate data. The potential benefits and burdens associated with recycling are reported in Module D in accordance with the requirements of EN 15804.

Module A4: Transport to the building site

Explanatory name of the default scenario in module A4Transport to site
Brief description of the default scenario in module A4Road and sea transport of aluminium coils from Türkiye to construction markets
Description of the default scenario in module A4Module A4 covers the transport of cold rolled aluminium coils from Vig Metal’s manufacturing facility in Türkiye to the construction site. Products are transported by road from Türkiye to Vig Metal Switzerland. After arrival in Switzerland, it is assumed that 90% of the products are distributed within Europe by road transport, while 10% are exported outside Europe by sea transport. Road transport is modelled using Euro 6 trucks with an average capacity utilisation of 50%, and sea transport is modelled using container ships. The transport distances and vehicle assumptions are defined in accordance with EN 15804:2012+A2:2019 and PCR 2019:14 v2.0.1.
Module A4 informationValueUnit
Distance
4520
km
Capacity utilization (including empty returns)
50
%
Bulk density of transported products
1400
kg/m3
Volume capacity utilization factor
(factor: =1 or <1 or ≥1 for compressed or
nested packaged products)
<1
%
Road Vehicle TypeTruck Euro 6 (28–32 t / 22 t payload)
N/A
Seaway Vehicle TypeContainer ship (5000 to 200000 dwt payload capacity)
N/A
Transport distance (ship)6300
km

Module C: End-of-life

Explanatory name of the default scenario in module CEnd-of-life scenario
Brief description of the default scenario in module CEnd-of-life with 95% recycling and 5% landfill
Description of the default scenario in module CThe default scenario represents the baseline end-of-life situation for cold rolled aluminium coil in accordance with EN 15804:2012+A2:2019 and PCR 2019:14 v2.0.1. It is assumed that 95% of the aluminium coil is collected and recycled at the end of its service life, while the remaining 5% is disposed of in landfill, based on European Aluminium circular economy data and industry practice as reported by European Aluminium. Deconstruction is assumed to be performed manually and is therefore considered to have no associated environmental impacts (Module C1). Transport to waste treatment facilities is assumed to take place by road over an average distance of 80 km (Module C2). Waste processing and recycling operations (Module C3) and final disposal (Module C4) are modelled using generic datasets from the Ecoinvent v3.10 database, in line with European Aluminium Association recovery rate data.
Module C informationValueUnit
Transport by roadLorry 16-32 metric ton
N/A
Distance (km)80
km
ElectricityElectricity, medium voltage {GLO}| market group for electricity, medium voltage | EN15804, S
N/A
Electricity (kWh)0.0022
kWh

Module D: Beyond product life cycle

Explanatory name of the default scenario in module DRecycling benefits
Brief description of the default scenario in module DEnvironmental benefits from recycling of aluminium at end of life
Description of the default scenario in module DModule D accounts for the potential environmental benefits and loads from the recycling of aluminium scrap at the end of the product’s life cycle. The net amount of aluminium scrap leaving the product system after end-of-life treatment is assumed to be recycled and substituted with primary aluminium production. Recycling benefits are calculated in accordance with EN 15804:2012+A2:2019 and PCR 2019:14 v2.0.1, considering a baseline end-of-life scenario with a 95% recycling rate.

Additional scenario 1

Name of the additional scenarioEnd-of-life scenario – 100% landfill
Description of the additional scenarioThe 100% landfill scenario represents an alternative end-of-life situation for cold rolled aluminium coil in accordance with EN 15804:2012+A2:2019 and PCR 2019:14 v2.0.1. It is assumed that 100% of the aluminium coil is disposed of in landfill at the end of its service life, with no collection, recovery, or recycling taking place. This scenario reflects a conservative end-of-life assumption where no circular economy benefits are achieved. Transport of end-of-life aluminium to waste treatment facilities is assumed to occur by road over an average distance of 80 km. Disposal processes are modelled using generic landfill treatment datasets from the Ecoinvent v3.10 database, consistent with European Aluminium Association end-of-life modelling practices. As no recycling occurs in this scenario, no potential benefits or burdens are reported in Module D.

Module A4: Transport to the building site

Description of the additional scenario in module A4The default scenario represents the baseline transport situation for cold rolled aluminium coil in accordance with EN 15804:2012+A2:2019 and PCR 2019:14 v2.0.1. Products are transported from the manufacturing facility in Kütahya, Türkiye, to Vig Metal Switzerland by road transport. After arrival, it is assumed that 90% of the products are distributed within Europe by road, while 10% are transported outside Europe by sea. Transport modelling is based on average transport distances, vehicle types, load factors, and fuel consumption data defined in the LCA study.
Module A4 informationValueUnit
Distance
4520
km
Capacity utilization (including empty returns)
50
%
Bulk density of transported products
1400
kg/m3
Volume capacity utilization factor
(factor: =1 or <1 or ≥1 for compressed or
nested packaged products)
<1
%
Road Vehicle TypeTruck Euro 6 (28–32 t / 22 t payload)
N/A
Seaway Vehicle TypeContainer ship (5000 to 200000 dwt payload capacity)
N/A
Transport distance (ship)6300
km

Module C: End-of-life

Description of the additional scenario in module CThe 100% landfill scenario represents an alternative end-of-life situation for cold rolled aluminium coil in accordance with EN 15804:2012+A2:2019 and PCR 2019:14 v2.0.1. It is assumed that 100% of the aluminium coil is disposed of in landfill at the end of its service life, with no collection, recovery, or recycling taking place. This scenario reflects a conservative end-of-life assumption where no circular economy benefits are achieved. Deconstruction is assumed to be performed manually and is therefore considered to have no associated environmental impacts (Module C1). Transport to waste treatment facilities is assumed to take place by road over an average distance of 80 km (Module C2). Waste processing operations prior to disposal (Module C3) and final disposal in landfill (Module C4) are modelled using generic datasets from the Ecoinvent v3.10 database, consistent with European Aluminium Association end-of-life modelling practices. As no recycling occurs in this scenario, no recycling credits or benefits are reported in Module D.
Module C informationValueUnit
Transport by roadLorry 16-32 metric ton
N/A
Distance (km)80
km
ElectricityElectricity, medium voltage {GLO}| market group for electricity, medium voltage | EN15804, S
N/A
Electricity (kWh)0.0022
kWh

Module D: Beyond product life cycle

Description of the additional scenario in module DModule D accounts for the potential environmental benefits and loads from recycling of aluminium scrap at the end of the product’s life cycle. In the 100% landfill scenario, no aluminium scrap leaving the product system after end-of-life treatment of cold rolled aluminium coil is assumed to be recycled or substituted with primary aluminium production. Therefore, no recycling benefits are calculated in accordance with EN 15804:2012+A2:2019 and PCR 2019:14 v2.0.1, considering an end-of-life scenario with a 0% recycling rate and 100% landfill disposal.

Additional scenario 2

Name of the additional scenarioRecycling benefits (100% recycling)
Description of the additional scenarioEnvironmental benefits from full recycling of aluminium at end of life

Module A4: Transport to the building site

Description of the additional scenario in module A4Module D accounts for the potential environmental benefits and loads from recycling of aluminium scrap at the end of the product’s life cycle. The amount of aluminium scrap leaving the product system after end-of-life treatment of cold rolled aluminium coil is assumed to be fully recycled and substituted with primary aluminium production. Recycling benefits are calculated in accordance with EN 15804:2012+A2:2019 and PCR 2019:14 v2.0.1, considering an end-of-life scenario with a 100% recycling rate.
Module A4 informationValueUnit
Distance
4520
km
Capacity utilization (including empty returns)
50
%
Bulk density of transported products
1400
kg/m3
Volume capacity utilization factor
(factor: =1 or <1 or ≥1 for compressed or
nested packaged products)
<1
%
Road Vehicle TypeTruck Euro 6 (28–32 t / 22 t payload)
N/A
Seaway Vehicle TypeContainer ship (5000 to 200000 dwt payload capacity)
N/A
Transport distance (ship)6300
km

Module C: End-of-life

Description of the additional scenario in module CThe 100% recycling scenario represents an alternative end-of-life situation for cold rolled aluminium coil in accordance with EN 15804:2012+A2:2019 and PCR 2019:14 v2.0.1. It is assumed that 100% of the aluminium coil is collected and recycled at the end of its service life, with no material being disposed of in landfill, based on European Aluminium circular economy data and industry practice as reported by European Aluminium. Deconstruction is assumed to be performed manually and is therefore considered to have no associated environmental impacts (Module C1). Transport to waste treatment facilities is assumed to take place by road over an average distance of 80 km (Module C2). Waste processing and recycling operations (Module C3) are modelled using generic datasets from the Ecoinvent v3.10 database, in line with European Aluminium Association recovery rate data. Final disposal in landfill (Module C4) is not applicable in this scenario.
Module C informationValueUnit
Transport by roadLorry 16-32 metric ton
N/A
Distance (km)80
km
ElectricityElectricity, medium voltage {GLO}| market group for electricity, medium voltage | EN15804, S
N/A
Electricity (kWh)0.0022
kWh

Module D: Beyond product life cycle

Description of the additional scenario in module DModule D accounts for the potential environmental benefits and loads from the recycling of aluminium scrap at the end of the product’s life cycle. The amount of aluminium scrap leaving the product system after end-of-life treatment of cold rolled aluminium coil is assumed to be fully recycled and substituted with primary aluminium production. Recycling benefits are calculated in accordance with EN 15804:2012+A2:2019 and PCR 2019:14 v2.0.1, considering an end-of-life scenario with a 100% recycling rate.

Environmental performance

The estimated impact results are only relative statements, which do not indicate the endpoints of the impact categories, exceeding threshold values, safety margins and/or risks.

Mandatory environmental performance indicators according to EN 15804

Impact categoryIndicatorUnitA1-A3A4A5B1B2B3B4B5B6B7C1C2C3C4D
Climate change - totalGWP-totalkg CO2 eq.1.02E+14.92E-1NDNDNDNDNDNDNDND0.00E+01.53E-21.63E-31.30E-3-5.99E-2
Climate change - fossilGWP-fossilkg CO2 eq.9.83E+04.88E-1NDNDNDNDNDNDNDND0.00E+01.52E-21.59E-31.28E-3-5.95E-2
Climate change - biogenicGWP-biogenickg CO2 eq.1.18E-13.58E-3NDNDNDNDNDNDNDND0.00E+01.11E-43.25E-52.20E-5-3.33E-4
Climate change - land use and land-use changeGWP-luluckg CO2 eq.1.89E-11.63E-4NDNDNDNDNDNDNDND0.00E+05.07E-62.14E-61.59E-6-8.00E-5
Ozone depletionODPkg CFC-11 eq.7.24E-89.64E-9NDNDNDNDNDNDNDND0.00E+03.00E-109.96E-122.29E-11-2.30E-10
AcidificationAPmol H+ eq.7.48E-21.02E-3NDNDNDNDNDNDNDND0.00E+03.17E-57.74E-67.37E-6-3.85E-4
Eutrophication aquatic freshwaterEP-freshwaterkg P eq.3.05E-43.81E-6NDNDNDNDNDNDNDND0.00E+01.19E-78.88E-82.23E-8-1.84E-6
Eutrophication aquatic marineEP-marinekg N eq.9.17E-32.38E-4NDNDNDNDNDNDNDND0.00E+07.41E-61.43E-63.09E-6-6.09E-5
Eutrophication terrestrialEP-terrestrialmol N eq.1.03E-12.63E-3NDNDNDNDNDNDNDND0.00E+08.20E-51.56E-52.78E-5-6.78E-4
Photochemical ozone formationPOCPkg NMVOC eq.3.75E-21.69E-3NDNDNDNDNDNDNDND0.00E+05.26E-54.63E-68.72E-6-2.06E-4
Depletion of abiotic resources - minerals and metalsADP-minerals&metals1kg Sb eq.1.54E-51.59E-6NDNDNDNDNDNDNDND0.00E+04.94E-81.45E-93.29E-9-2.56E-7
Depletion of abiotic resources - fossil fuelsADP-fossil1MJ, net calorific value1.00E+26.87E+0NDNDNDNDNDNDNDND0.00E+02.14E-12.05E-22.16E-2-5.53E-1
Water useWDP1m3 world eq. deprived4.26E+03.87E-2NDNDNDNDNDNDNDND0.00E+01.21E-32.00E-4-8.21E-3-9.40E-3
AcronymsGWP-fossil = Global Warming Potential fossil fuels; GWP-biogenic = Global Warming Potential biogenic; GWP-luluc = Global Warming Potential land use and land use change; ODP = Depletion potential of the stratospheric ozone layer; AP = Acidification potential, Accumulated Exceedance; EP-freshwater = Eutrophication potential, fraction of nutrients reaching freshwater end compartment; EP-marine = Eutrophication potential, fraction of nutrients reaching marine end compartment; EP-terrestrial = Eutrophication potential, Accumulated Exceedance; POCP = Formation potential of tropospheric ozone; ADP-minerals&metals = Abiotic depletion potential for non-fossil resources; ADP-fossil = Abiotic depletion for fossil resources potential; WDP = Water (user) deprivation potential, deprivation-weighted water consumption
General disclaimerThe results of the end-of-life stage (modules C1-C4) should be considered when using the results of the product stage (modules A1-A3/A1-A5 for services).
Disclaimer 1The results of this environmental impact indicator shall be used with care as the uncertainties of these results are high or as there is limited experience with the indicator

Additional mandatory environmental performance indicators

Impact categoryIndicatorUnitA1-A3A4A5B1B2B3B4B5B6B7C1C2C3C4D
Climate change - GWP-GHGGWP-GHG1kg CO2 eq.1.02E+14.92E-1NDNDNDNDNDNDNDND0.00E+01.53E-21.63E-31.30E-3-5.99E-2
AcronymsGWP-GHG = Global warming potential greenhouse gas.
General disclaimerThe results of the end-of-life stage (modules C1-C4) should be considered when using the results of the product stage (modules A1-A3/A1-A5 for services).
Disclaimer 1The GWP-GHG indicator is termed GWP-IOBC/GHG in the ILCD+EPD+ data format. The indicator accounts for all greenhouse gases except biogenic carbon dioxide uptake and emissions and biogenic carbon stored in the product. As such, the indicator is identical to GWP-total except that the CF for biogenic CO2 is set to zero.

Additional voluntary environmental performance indicators according to EN 15804

Impact categoryIndicatorUnitA1-A3A4A5B1B2B3B4B5B6B7C1C2C3C4D
Particulate matter emissionsPMDisease incidence1.03E-63.58E-8NDNDNDNDNDNDNDND0.00E+01.11E-96.84E-111.33E-10-4.90E-9
Ionizing radiation - human healthIRP1kBq U235 eq.3.79E-13.17E-3NDNDNDNDNDNDNDND0.00E+09.87E-58.25E-51.81E-5-2.26E-4
Eco-toxicity - freshwaterETP-fw2CTUe2.08E+11.50E+0NDNDNDNDNDNDNDND0.00E+04.67E-23.58E-38.81E+0-1.33E-1
Human toxicity - cancer effectsHTP-c2CTUh4.56E-83.50E-9NDNDNDNDNDNDNDND0.00E+01.09E-101.86E-127.37E-12-1.24E-10
Human toxicity - non-cancer effectsHTP-nc2CTUh1.70E-78.60E-9NDNDNDNDNDNDNDND0.00E+02.68E-101.88E-114.03E-10-8.88E-10
Land-use related impacts/soil qualitySQP2Dimensionless3.31E+14.15E+0NDNDNDNDNDNDNDND0.00E+01.29E-13.05E-33.30E-2-1.12E-1
AcronymsPM = Potential incidence of disease due to particulate matter emissions; IRP = Potential human exposure efficiency relative to U235; ETP-fw = Potential comparative toxic unit for ecosystems; HTP-c = Potential comparative toxic unit for humans; HTP-nc = Potential comparative toxic unit for humans; SQP = Potential soil quality index.
General disclaimerThe results of the end-of-life stage (modules C1-C4) should be considered when using the results of the product stage (modules A1-A3/A1-A5 for services).
Disclaimer 1This impact category deals mainly with the eventual impact of low dose ionizing radiation on human health of the nuclear fuel cycle. It does not consider effects due to possible nuclear accidents, occupational exposure nor due to radioactive waste disposal in underground facilities. Potential ionizing radiation from the soil, from radon and from some construction materials is also not measured by this indicator.
Disclaimer 2The results of this environmental impact indicator shall be used with care as the uncertainties of these results are high or as there is limited experience with the indicator.

Resource use indicators according to EN 15804

IndicatorUnitA1-A3A4A5B1B2B3B4B5B6B7C1C2C3C4D
PEREMJ, net calorific value7.14E+11.18E-1NDNDNDNDNDNDNDND0.00E+03.67E-32.48E-36.39E-4-3.51E-2
PERMMJ, net calorific value0.00E+00.00E+0NDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+00.00E+0
PERTMJ, net calorific value7.14E+11.18E-1NDNDNDNDNDNDNDND0.00E+03.67E-32.48E-36.39E-4-3.51E-2
PENREMJ, net calorific value1.06E+27.30E+0NDNDNDNDNDNDNDND0.00E+02.27E-12.18E-22.30E-2-5.90E-1
PENRMMJ, net calorific value0.00E+00.00E+0NDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+00.00E+0
PENRTMJ, net calorific value1.06E+27.30E+0NDNDNDNDNDNDNDND0.00E+02.27E-12.18E-22.30E-2-5.90E-1
SMkg2.76E-30.00E+0NDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+02.62E-3
RSFMJ, net calorific value0.00E+00.00E+0NDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+00.00E+0
NRSFMJ, net calorific value0.00E+00.00E+0NDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+00.00E+0
FWm34.37E-16.24E-3NDNDNDNDNDNDNDND0.00E+01.94E-41.17E-45.19E-5-2.37E-3
AcronymsPERE = Use of renewable primary energy excluding renewable primary energy resources used as raw materials; PERM = Use of renewable primary energy resources used as raw materials; PERT = Total use of renewable primary energy resources; PENRE = Use of non-renewable primary energy excluding non-renewable primary energy resources used as raw materials; PENRM = Use of non-renewable primary energy resources used as raw materials; PENRT = Total use of non-renewable primary energy re-sources; SM = Use of secondary material; RSF = Use of renewable secondary fuels; NRSF = Use of non-renewable secondary fuels; FW = Use of net fresh water.
General disclaimerThe results of the end-of-life stage (modules C1-C4) should be considered when using the results of the product stage (modules A1-A3/A1-A5 for services).

Waste indicators according to EN 15804

IndicatorUnitA1-A3A4A5B1B2B3B4B5B6B7C1C2C3C4D
HWDkg3.26E+01.45E-2NDNDNDNDNDNDNDND0.00E+03.12E-41.38E-41.63E-4-1.20E-2
NHWDkg1.34E+13.07E-1NDNDNDNDNDNDNDND0.00E+00.00E+00.00E+05.00E-20.00E+0
RWDkg2.01E-43.21E-6NDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+00.00E+0
AcronymsHWD = Hazardous waste disposed; NHWD = Non-hazardous waste disposed; RWD = Radioactive waste disposed.
General disclaimerThe results of the end-of-life stage (modules C1-C4) should be considered when using the results of the product stage (modules A1-A3/A1-A5 for services).

Output flow indicators according to EN 15804

IndicatorUnitA1-A3A4A5B1B2B3B4B5B6B7C1C2C3C4D
CRUkg0.00E+00.00E+0NDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+00.00E+0
MFRkg5.91E-37.56E-5NDNDNDNDNDNDNDND0.00E+01.62E-69.50E-13.61E-7-1.95E-5
MERkg2.94E-66.41E-7NDNDNDNDNDNDNDND0.00E+01.38E-89.60E-101.56E-9-2.30E-8
EEEMJ, net calorific value7.92E-31.71E-3NDNDNDNDNDNDNDND0.00E+03.68E-51.98E-51.09E-4-3.07E-5
EETMJ, net calorific value7.48E-32.48E-3NDNDNDNDNDNDNDND0.00E+05.32E-51.02E-68.70E-6-3.55E-5
AcronymsCRU = Components for re-use; MFR = Materials for recycling; MER = Materials for energy recovery; EEE = Exported electrical energy; EET = Exported thermal energy.
General disclaimerThe results of the end-of-life stage (modules C1-C4) should be considered when using the results of the product stage (modules A1-A3/A1-A5 for services).

Results for additional scenarios for modules A4-C4

Additional scenarioEnd-of-life scenario – 100% landfill
Results for additional scenarios for modules A4-C4
Impact categoryIndicatorUnitA1-A3A4A5B1B2B3B4B5B6B7C1C2C3C4D
Waste productionHazardous waste disposedkg3.26E+01.45E-2NDNDNDNDNDNDNDND0.00E+03.12E-41.38E-43.26E-30.00E+0
Waste production Non-hazardous waste disposed kg1.34E+13.07E-1NDNDNDNDNDNDNDND0.00E+06.59E-34.88E-31.00E+00.00E+0
Waste production Radioactive waste disposed kg2.01E-43.21E-6NDNDNDNDNDNDNDND0.00E+06.89E-85.29E-82.32E-70.00E+0
Output flows Components for re-use kg0.00E+00.00E+0NDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+00.00E+0
Output flowsMaterial for recycling kg5.91E-37.56E-5NDNDNDNDNDNDNDND0.00E+01.62E-60.00E+05.61E-30.00E+0
Output flowsMaterials for energy recovery kg2.94E-66.41E-7NDNDNDNDNDNDNDND0.00E+01.38E-80.00E+02.79E-60.00E+0
Output flows Exported energy, electricityMJ7.92E-31.71E-3NDNDNDNDNDNDNDND0.00E+03.68E-50.00E+07.52E-30.00E+0
Output flows Exported energy, thermalMJ7.48E-32.48E-3NDNDNDNDNDNDNDND0.00E+05.32E-50.00E+07.11E-30.00E+0
Acronyms
Disclaimers
General disclaimerThe results of the end-of-life stage (modules C1-C4) should be considered when using the results of the product stage (modules A1-A3/A1-A5 for services).

Results for additional scenarios for modules A4-C4

Additional scenarioRecycling benefits (100% recycling)
Results for additional scenarios for modules A4-C4
Impact categoryIndicatorUnitA1-A3A4A5B1B2B3B4B5B6B7C1C2C3C4D
Waste productionHazardous waste disposedkg3.26E+01.45E-2NDNDNDNDNDNDNDND0.00E+03.12E-41.38E-40.00E+0-1.26E-2
Waste productionNon-hazardous waste disposed kg1.34E+13.07E-1NDNDNDNDNDNDNDND0.00E+06.59E-34.88E-30.00E+0-8.21E-2
Waste productionRadioactive waste disposed kg2.01E-43.21E-6NDNDNDNDNDNDNDND0.00E+06.89E-85.29E-80.00E+0-1.42E-7
Output flowsComponents for re-use kg0.00E+00.00E+0NDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+00.00E+0
Output flowsMaterial for recycling kg5.91E-37.56E-5NDNDNDNDNDNDNDND0.00E+01.62E-65.61E-30.00E+05.61E-3
Output flowsMaterials for energy recovery kg2.94E-66.41E-7NDNDNDNDNDNDNDND0.00E+01.38E-82.79E-60.00E+02.79E-6
Output flowsExported energy, electricityMJ7.92E-31.71E-3NDNDNDNDNDNDNDND0.00E+03.68E-57.52E-30.00E+07.52E-3
Output flowsExported energy, thermalMJ7.48E-32.48E-3NDNDNDNDNDNDNDND0.00E+05.32E-57.11E-30.00E+07.11E-3
Acronyms
Disclaimers
General disclaimerThe results of the end-of-life stage (modules C1-C4) should be considered when using the results of the product stage (modules A1-A3/A1-A5 for services).

Additional environmental information

- No mass balance allocation (MBA) has been applied in the LCA model.

- Biogenic carbon content and the associated energy balance of packaging materials are accounted for within Modules A1–A3, as Module A5 (construction and installation process) is not declared.

- The energy balance has been modelled in accordance with Option A as defined in EN 15804:2012+A2:2019.- A baseline End-of-Life (EOL) scenario consisting of 95% recycling and 5% landfill is considered in the LCA. In addition, alternative EOL scenarios representing 100% recycling and 100% landfill are assessed using the scaling approach described below.

  For an EOL scenario with 100% recycling, all results reported in modules C3 and D shall be obtained by multiplying the corresponding results of the baseline scenario by a factor of 100/95, while all results in module C4 shall be set to zero.

  For an EOL scenario with 100% landfill, all results reported in module C4 shall be obtained by multiplying the corresponding results of the baseline scenario by a factor of 100/95, while all results in modules C3 and D shall be set to zero.

Information related to EPDs of multiple products

Description of how the averages have been determinedThe results are representative for 1kg product. GWP-GHG deviation between 1 kg products with different thicknesses are less than 1%.

Abbreviations

EN-European Norm (Standard)

EF-Environmental Footprint

ISO-International Organization for Standardization

ND-Not DeclaredPCRs - (Product Category Rules) 

References

ISO 14040:2006, Environmental management – Life cycle assessment – Principles and framework

ISO 14044:2006, Environmental management – Life cycle assessment – Requirements and guidelines

ISO 14025:2006, Environmental labels and declarations – Type III environmental declarations

ISO 14020:2006, Environmental labels and declarations – General principles

EN 15804:2012+A2:2019/AC:2021, Sustainability of construction works – Environmental product declarations – Core rules for the product category of construction products

General Programme Instructions (GPI) for the International EPD® System, Version 5.0.1

Product Category Rules (PCR) 2019:14, Construction Products, Version 2.0.1, The International EPD® System

Ecoinvent database v3.10

SimaPro LCA software v9.6.0.1European Aluminium Association (EAA), Aluminium Recycling and End-of-Life Recycling Rates in Europe, Brussels, Belgium, latest available data.

Version history

Version 001, 2026-01-19

Original version of the EPD

This version represents the original version of the Environmental Product Declaration (EPD). It contains the initial life cycle assessment (LCA), including defined system boundaries, assumptions, data sources, and methodological approaches applied at the time of publication. As this is the first published version of the EPD, no previous versions exist for comparison.