EPD-IES-0029167:001

Polycoat RBE

Polycoat RBE coating is an emulsified rubber modified bitumen coating, which dries to form a tough, seamless, flexible vapor proof protective coating. The coating is water based and cold applied, and it is supplied as a single component product. It can be applied on damp substrates and can be used in closed or confined areas. Polycoat RBE has good adhesion to most building substrates and shows good resistance against chloride and sulphate ions.

EPD Owner	Henkel AG & Co. KGaA
Registration number	EPD-IES-0029167:001
EPD type	EPD of a single product from a manufacturer/service provider
Status	Valid
Version date	2026-05-12
Validity date	2031-05-11
Standards conformance	ISO 14025:2006, EN 15804:2012+A2:2019/AC:2021, ISO 21930:2017
Geographical scope	Global
An EPD may be updated or depublished if conditions change. This is the latest version of the EPD.

Programme	International EPD System
Address	EPD International AB Box 210 60 SE-100 31 Stockholm Sweden
Website	www.environdec.com
E-mail	support@environdec.com

CEN standard EN 15804 and ISO standard ISO 21930 serve 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 by	The 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.

Independent third-party verification of the declaration and data, according to ISO 14025:2006, via	EPD verification through an individual EPD verification EPD verification through EPD Process Certification* EPD verification through a pre-verified LCA/EPD tool
Third-party verifier	Silvia Vilčeková (SILCERT, Ltd.)
Approved by	The International EPD® System
Procedure for follow-up of data during EPD validity involves third party verifier	Yes No
*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.environdec.com.

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.

EPD Owner	Henkel AG & Co. KGaA
Contact person name	Massimo Collotta
Contact person e-mail	massimo.collotta@henkel.com
Organisation address	Germany Düsseldorf 40589 Henkelstraße 67
LCA Practitioner	Massimo Collotta, massimo.collotta@henkel.com Roman Sandor, roman.sandor@henkel.com

Description of the organisation of the EPD Owner

Henkel AG & Co. KGaA, commonly known as Henkel, is a German multinational chemical and consumer goods company headquartered in Düsseldorf, Germany. Henkel Adhesive Technologies Construction is a division of Henkel which offers, among others, a wide choice of waterproofing systems tailored to varied needs. This EPD is focused on the key components of bitumen coating. These components are mainly sold under the brand of Henkel Polybit. For more information, please visit: www.henkelpolybit.com

Organisation logo

Product name	Polycoat RBE
Product identification	Polycoat RBE is an emulsified rubber modified bitumen coating, which dries to form a tough, seamless, flexible vapor proof protective coating. Polycoat RBE conforms to the requirement of ASTM D 1227 Type III, Class 1.
Product description	Polycoat RBE coating is an emulsified rubber modified bitumen coating, which dries to form a tough, seamless, flexible vapor proof protective coating. The coating is water based and cold applied, and it is supplied as a single component product. It can be applied on damp substrates and can be used in closed or confined areas. Polycoat RBE has good adhesion to most building substrates and shows good resistance against chloride and sulphate ions.
Technical purpose of product	Polycoat RBE is used as a rubberized bitumen emulsion protective coating on the following applications/structures: concrete foundations (protective coating), freshly cast concrete structures (curing compound), sandwich constructions (dampproof membrane), and as a vapor proof barrier coating.
Manufacturing or service provision description	The raw materials for POLYCOAT RBE – UAE are stored in the production factory in silos (delivered in road tankers). After accurately measuring all required raw materials according to the recipe, the materials are sequentially added to the mixer in a defined order. The mixing process is started, ensuring consistent blending by maintaining specified mixing times and speeds to achieve the desired product characteristics. Samples are then taken from the mixed batch for QC analysis, and adjustments are made as needed based on QC feedback. Once QC approval is obtained, the product is packed into designated bags and labeled with essential information.
Material properties	Volumetric mass density: 1020 kg/m³ Volumetric mass density: 1020 kg/m³
Manufacturing site	Henkel Polybit Industry Umm Al Thuoob United Arab Emirates Umm Al Thuoob GMV5+3H6
UN CPC code	35110. Paints and varnishes and related products
Geographical scope	Global
Actual or technical lifespan	60 year(s)

Product images

Content declaration

Hazardous and toxic substances	The product does not contain any substances from the SVHC candidate list in concentrations exceeding 0.1% of its weight.

Product content

Content name	Mass, kg	Post-consumer recycled material, mass-% of product	Biogenic material, mass-% of product	Biogenic material¹, kg C/declared unit	Biogenic material kg CO₂, eq./declared unit
Organics, nonvolatiles	0.42	0	0	0	0
Inorganics	0.58	0	0	0	0
Total	1	0	0	0	0
Note 1	1 kg biogenic carbon is equivalent to 44/12 kg of CO₂

Packaging materials

Material name	Mass, kg	Mass-% (versus the product)	Biogenic material¹, kg C/declared unit	Biogenic material kg CO₂, eq./declared unit
Paper and cardboard	0.00000001	0.00000001	0.00000001	0.00000004
Wood	0.00005059	0.00014231	0.00014231	0.0005218
Plastic	0.00000152	0.00000001	0	0
Metal	0.000081	0.00022784	0	0
Total	0.00013312	0.00037017	0.00014232	0.00052184
Note 1	1 kg biogenic carbon is equivalent to 44/12 kg of CO₂

EPD based on declared or functional unit	Declared unit
Declared unit and reference flow	Polycoat RBE Mass: 1 kg
Conversion factor to mass	1
Are infrastructure or capital goods included in any upstream, core or downstream processes?	Yes No
Datasources used for this EPD	ecoinvent database (general) ecoinvent 3.11 database
LCA Software	SimaPro 9.6
Additional information about the underlying LCA-based information	Simapro 10.2
Version of the EN 15804 reference package	EF Reference Package 3.1
Characterisation methods	GWP 100,EN 15804. version: EF 3.1
Technology description including background system	Polycoat RBE is a single‑component, water‑based, emulsified rubber‑modified bitumen protective coating that dries to form a tough, seamless and flexible vapor‑proof layer. The product is manufactured by dosing and sequentially mixing raw materials according to a defined formulation, followed by quality‑control testing and packaging in 200 L drums. Production takes place at the Henkel Polybit facility in Umm Al Thuoob (UAE), which operates using 100% renewable electricity. Raw materials are supplied globally and transported to the plant before processing into the final waterproofing coating.
Scrap (recycled material) inputs contribution level	Less than 10% of the GWP-GHG results in modules A1-A3 come from scrap inputs

Data quality assessment

Description of data quality assessment and reference years	The quality of the relevant data used for the EPD in terms of its time, geography and technology representativeness using EN 15804:2012+A2:2019. The data used in this LCA study are of high quality and representative of the technologies, processes, and geographic location relevant to the production of Polycoat RBE. The Reference year is 2025.

Data quality assessment

Process name	Source type	Source	Reference year	Share of primary data, of GWP-GHG results for A1-A3
A1 module	Collected Data	Henkel System	2024	0%
A2 module	Collected Data	Henkel System	2024	10%
A3 module	Collected Data	Henkel System	2024	30%
Total share of primary data, of GWP-GHG results for A1-A3				40%
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.

Electricity data


Electricity used in the manufacturing process in A3 (A5 for services)
Type of electricity mix	Residual electricity mix on the market
Energy sources	Hydro	0%
	Wind	0%
	Solar	100%
	Biomass	0%
	Geothermal	0%
	Waste	0%
	Nuclear	0%
	Natural gas	0%
	Coal	0%
	Oil	0%
	Peat	0%
	Other	0%
GWP-GHG intensity (kg CO₂ eq./kWh)	0.05 kg CO₂ eq./kWh

Description of the system boundary	b) Cradle to gate with options, modules C1-C4, module D and with optional modules (A1-A3 + C + D and additional modules).
Excluded modules	Yes, there is an excluded module, or there are excluded modules
Justification for the omission of modules	No additional processes or raw materials are needed during the use phase of the assessed products. Therefore, modules B1 to B7 are not considered and have no impact on the environmental performance of the product.

Declared modules

	Product stage			Construction process stage		Use stage							End of life stage				Beyond product life cycle
	Raw material supply	Transport	Manufacturing	Transport to site	Construction installation	Use	Maintenance	Repair	Replacement	Refurbishment	Operational energy use	Operational water use	De-construction demolition	Transport	Waste processing	Disposal	Reuse-Recovery-Recycling-potential
Module	A1	A2	A3	A4	A5	B1	B2	B3	B4	B5	B6	B7	C1	C2	C3	C4	D
Modules declared	X	X	X	X	X	ND	ND	ND	ND	ND	ND	ND	X	X	X	X	X
Geography	Global	Global	Middle East	Global	Global	N/A	N/A	N/A	N/A	N/A	N/A	N/A	Global	Global	Global	Global	Global
Share of specific data	40%			-	-	-	-	-	-	-	-	-	-	-	-	-	-
Variation - products	0%			-	-	-	-	-	-	-	-	-	-	-	-	-	-
Variation - sites	0%			-	-	-	-	-	-	-	-	-	-	-	-	-	-
Disclaimer	The share of specific/primary data and both variations (products and sites) refer to GWP-GHG results only.

Process flow diagram(s) related images

Name of the default scenario	Polycoat RBE
Description of the default scenario	Description of system boundaries: Cradle-to-gate with modules C1-C4, module D and optional modules A4 and A5, covering the modules of extraction and processing of raw materials (A1), their transportation to the production plant (A2), the manufacturing process (A3), transport to construction site (A4), installation (A5), end of life (C1-C4) and potential benefits and loads from the reuse and recycling of the products at its end of life (D). Product stage (A1-A3): Raw material supply (A1): this module considers the extraction and processing of raw materials used for the manufacture of the products. Transport of the raw materials (A2): this module consists of the transportation of all raw materials covered by module A1, from the extraction, production, and treatment site to the factory, considering the specific distances of each material supplier. Manufacturing of products (A3): this module refers to the production process of Polycoat RBE in the production plants. The raw materials are stored at the production site and then dosed and mixed according to a defined formulation. After mixing, product samples are tested in the quality control laboratory and the finished product is filled and packed in 200 L drums before being palletized. Pallets with the ready-to-use product are stored for a short time in the factory's warehouses before being delivered to distributors. This scenario also represents the 100% Landfill additional scenario.

Name of the default scenario

Polycoat RBE

Description of the default scenario

Description of system boundaries: Cradle-to-gate with modules C1-C4, module D and optional modules A4 and A5, covering the modules of extraction and processing of raw materials (A1), their transportation to the production plant (A2), the manufacturing process (A3), transport to construction site (A4), installation (A5), end of life (C1-C4) and potential benefits and loads from the reuse and recycling of the products at its end of life (D). Product stage (A1-A3): Raw material supply (A1): this module considers the extraction and processing of raw materials used for the manufacture of the products. Transport of the raw materials (A2): this module consists of the transportation of all raw materials covered by module A1, from the extraction, production, and treatment site to the factory, considering the specific distances of each material supplier. Manufacturing of products (A3): this module refers to the production process of Polycoat RBE in the production plants. The raw materials are stored at the production site and then dosed and mixed according to a defined formulation. After mixing, product samples are tested in the quality control laboratory and the finished product is filled and packed in 200 L drums before being palletized. Pallets with the ready-to-use product are stored for a short time in the factory's warehouses before being delivered to distributors. This scenario also represents the 100% Landfill additional scenario.

Module A4: Transport to the building site

Explanatory name of the default scenario in module A4	Downstream Transport
Brief description of the default scenario in module A4	Transport from factory to customer
Description of the default scenario in module A4	The Site-to-site transportation includes the transportation of the finished, packaged Polycoat RBE from the production facility to the different customers site (A4). The transportation from the facility to customers is therefore estimated by range distances of 167.35 km based on market share of customer location.

Module A4 information	Value	Unit
Distance	167	km
Capacity utilization (including empty returns)	100	%
Bulk density of transported products	1020	kg/m³
Volume capacity utilization factor (factor: =1 or <1 or ≥1 for compressed or nested packaged products)	1	N/A
Fuel type and consumption of the vehicle	Diesel, 16-32 tons trucks with 34 L per 100 km fuel consumption,	N/A

Module A5: Installation in the building

Explanatory name of the default scenario in module A5	Installation
Brief description of the default scenario in module A5	Installation/processing of sold product
Description of the default scenario in module A5	The application of the product is performed manually. In Module A5, only material losses during installation and the end‑of‑life treatment of packaging are considered. No additional materials or auxiliary products are included beyond those already accounted for in the system.

Module A5 information	Value	Unit
Material loss	2	%

Module C: End-of-life

Explanatory name of the default scenario in module C	End of life
Brief description of the default scenario in module C	End of life stage (C)
Description of the default scenario in module C	Dismantling or demolition (C1): This module analyzes the environmental impacts associated with the deconstruction or dismantling of the bitumen coating (Polycoat RBE) on a construction site after its useful life. Module C1 includes all processes and activities used on site for the deconstruction of the bitumen coating. The consumption of energy and natural resources is negligible for deconstruction of the end of life product, as demolition of the bitumen coating is assumed to be done manually. Thus, the impacts of demolition are assumed zero. • Transport to waste treatment site (C2): this module considers a default distance of 50 km (distance assumed in most EPD studies), between the construction site where the product was installed and the waste management facility (in this case landfill). • Waste treatment (C3): this module covers the process of processing construction and demolition waste prior to disposal. For this study, no specific pre treatment is modelled and the removed product waste is considered to be disposed of directly in landfill as the most conservative scenario. • Disposal (C4): this module includes the final disposal of waste that has not been destined for recovery or treatment processes. 100% of the product waste is disposed of in landfill after its useful life. Since the product is distributed among several countries, a conservative scenario has been considered to avoid miscalculating the impact of the end of life of the assessed products.

Module C information	Value	Unit
Waste collection process, specified by type kg collected mixed with demolition waste	1	kg
Waste disposal kg to landfill	1	kg
Distance to waste manager (km)	50	km

Reference service life

Description of the default scenario in reference service life	The reference service life of the Henkel Product is 60 years.

Reference service life information	Value	Unit
Reference service life	60	year(s)

Module D: Beyond product life cycle

Explanatory name of the default scenario in module D	Module D
Brief description of the default scenario in module D	Benefits and burdens beyond the boundaries of the system
Description of the default scenario in module D	Module D, considers the benefits and burdens linked to the processes of recovery, reuse or recycling of waste from the products under study at the end of their useful life, which could be part of the life cycle of a new product. Credits of the module D are 0 due to the 100% landfill of the product.

Name of the additional scenario	Polycoat RBE (100% recycling)
Description of the additional scenario	This represents a hypothetical scenario assuming 100% recycling, meaning the entire product is considered fully recycled at the end of its life cycle. Description of system boundaries: Cradle-to-gate with modules C1-C4, module D and optional modules A4 and A5, covering the modules of extraction and processing of raw materials (A1), their transportation to the production plant (A2), the manufacturing process (A3), transport to construction site (A4), installation (A5), end of life (C1-C4) and potential benefits and loads from the reuse and recycling of the products at its end of life (D). Product stage (A1-A3): Raw material supply (A1): this module considers the extraction and processing of raw materials used for the manufacture of the products. Transport of the raw materials (A2): this module consists of the transportation of all raw materials covered by module A1, from the extraction, production, and treatment site to the factory, considering the specific distances of each material supplier. Manufacturing of products (A3): this module refers to the production process of Polycoat RBE in the production plants. The raw materials are received and stored at the production site. From the heated bitumen storage tank, bitumen is transferred to the primary mixer and emulsified with water and other formulation components to produce a stable rubber‑modified bitumen emulsion. The emulsion is then transferred to a secondary mixer for further homogenization and quality adjustment. Afterward, samples are tested in the quality control laboratory, and the finished product is filled into 200 L open‑top steel drums, labelled, palletized and packed. Pallets with the ready‑to‑use product are stored for a short time in the factory’s warehouses before being delivered to distributors.

Name of the additional scenario

Polycoat RBE (100% recycling)

Description of the additional scenario

This represents a hypothetical scenario assuming 100% recycling, meaning the entire product is considered fully recycled at the end of its life cycle. Description of system boundaries: Cradle-to-gate with modules C1-C4, module D and optional modules A4 and A5, covering the modules of extraction and processing of raw materials (A1), their transportation to the production plant (A2), the manufacturing process (A3), transport to construction site (A4), installation (A5), end of life (C1-C4) and potential benefits and loads from the reuse and recycling of the products at its end of life (D). Product stage (A1-A3): Raw material supply (A1): this module considers the extraction and processing of raw materials used for the manufacture of the products. Transport of the raw materials (A2): this module consists of the transportation of all raw materials covered by module A1, from the extraction, production, and treatment site to the factory, considering the specific distances of each material supplier. Manufacturing of products (A3): this module refers to the production process of Polycoat RBE in the production plants. The raw materials are received and stored at the production site. From the heated bitumen storage tank, bitumen is transferred to the primary mixer and emulsified with water and other formulation components to produce a stable rubber‑modified bitumen emulsion. The emulsion is then transferred to a secondary mixer for further homogenization and quality adjustment. Afterward, samples are tested in the quality control laboratory, and the finished product is filled into 200 L open‑top steel drums, labelled, palletized and packed. Pallets with the ready‑to‑use product are stored for a short time in the factory’s warehouses before being delivered to distributors.

Module A4: Transport to the building site

Description of the additional scenario in module A4	The Site-to-site transportation includes the transportation of the finished, packaged Polycoat RBE from the production facility to the different customers site (A4). The transportation from the facility to customers is therefore estimated by range distances of 167.35 km based on market share of customer location.

Module A4 information	Value	Unit
Distance	167	km
Capacity utilization (including empty returns)	100	%
Bulk density of transported products	1020	kg/m³
Volume capacity utilization factor (factor: =1 or <1 or ≥1 for compressed or nested packaged products)	1	N/A
Fuel type and consumption of the vehicle	Diesel, 16-32 tons trucks with 34 L per 100 km fuel consumption,	N/A

Module A5: Installation in the building

Description of the additional scenario in module A5	The application of the product is performed manually. In Module A5, only material losses during installation and the end‑of‑life treatment of packaging are considered. No additional materials or auxiliary products are included beyond those already accounted for in the system.

Module A5 information	Value	Unit
Material loss	2	%

Module C: End-of-life

Description of the additional scenario in module C	Dismantling or demolition (C1): This module analyzes the environmental impacts associated with the deconstruction or dismantling of the bitumen coating (Polycoat RBE) on a construction site after its useful life. Module C1 includes all processes and activities used on site for the deconstruction of the bitumen coating. The consumption of energy and natural resources is negligible for deconstruction of the end of life product, as demolition of the bitumen coating is assumed to be done manually. Thus, the impacts of demolition are assumed zero. • Transport to waste treatment site (C2): this module considers a default distance of 50 km (distance assumed in most EPD studies), between the construction site where the product was installed and the waste management facility (in this case landfill). • Waste treatment (C3): this module covers the process of processing construction and demolition waste prior to disposal. For this study, no specific pre treatment is modelled and the removed product waste is considered to be disposed of directly in landfill as the most conservative scenario. • Disposal (C4): This module covers the final disposal of any waste that is not directed to recovery or treatment processes. In the 100% recycling scenario, all product waste at end of life is assumed to be collected for recycling. Consequently, no direct landfill disposal of the product is modelled. Any potential disposal of minor recycling residues (e.g., sorting or processing rejects) is considered outside the scope of the product waste stream or assumed to be negligible. Given distribution across multiple countries, a conservative and harmonized end-of-life assumption has been applied to avoid underestimation of impacts due to differences in national waste management practices.

Description of the additional scenario in module C

Dismantling or demolition (C1): This module analyzes the environmental impacts associated with the deconstruction or dismantling of the bitumen coating (Polycoat RBE) on a construction site after its useful life. Module C1 includes all processes and activities used on site for the deconstruction of the bitumen coating. The consumption of energy and natural resources is negligible for deconstruction of the end of life product, as demolition of the bitumen coating is assumed to be done manually. Thus, the impacts of demolition are assumed zero. • Transport to waste treatment site (C2): this module considers a default distance of 50 km (distance assumed in most EPD studies), between the construction site where the product was installed and the waste management facility (in this case landfill). • Waste treatment (C3): this module covers the process of processing construction and demolition waste prior to disposal. For this study, no specific pre treatment is modelled and the removed product waste is considered to be disposed of directly in landfill as the most conservative scenario. • Disposal (C4): This module covers the final disposal of any waste that is not directed to recovery or treatment processes. In the 100% recycling scenario, all product waste at end of life is assumed to be collected for recycling. Consequently, no direct landfill disposal of the product is modelled. Any potential disposal of minor recycling residues (e.g., sorting or processing rejects) is considered outside the scope of the product waste stream or assumed to be negligible. Given distribution across multiple countries, a conservative and harmonized end-of-life assumption has been applied to avoid underestimation of impacts due to differences in national waste management practices.

Module C information	Value	Unit
Waste collection process, specified by type kg collected mixed with demolition waste	1	kg
Waste disposal kg to Recycling/Reuse	1	kg
Distance to waste manager (km)	50	km

Reference service life

Description of the additional scenario in reference service life	The reference service life of the Henkel Product is 60 years.

Reference service life information	Value	Unit
Reference service life	60	year(s)

Module D: Beyond product life cycle

Description of the additional scenario in module D	Module D, considers the benefits and burdens linked to the processes of recovery, reuse or recycling of waste from the products under study at the end of their useful life, which could be part of the life cycle of a new product. The recycling of the product fully substitutes the manufacture of an equivalent new product; therefore, the avoided burdens of modules A1–A3 are reported as credits in Module D.

Description of the additional scenario in module D

Module D, considers the benefits and burdens linked to the processes of recovery, reuse or recycling of waste from the products under study at the end of their useful life, which could be part of the life cycle of a new product. The recycling of the product fully substitutes the manufacture of an equivalent new product; therefore, the avoided burdens of modules A1–A3 are reported as credits in Module D.

Name of the additional scenario	Polycoat RBE (100% reuse)
Description of the additional scenario	This represents a hypothetical scenario assuming 100% reuse, meaning the entire product is considered fully recycled at the end of its life cycle. Description of system boundaries: Cradle-to-gate with modules C1-C4, module D and optional modules A4 and A5, covering the modules of extraction and processing of raw materials (A1), their transportation to the production plant (A2), the manufacturing process (A3), transport to construction site (A4), installation (A5), end of life (C1-C4) and potential benefits and loads from the reuse and recycling of the products at its end of life (D). Product stage (A1-A3): Raw material supply (A1): this module considers the extraction and processing of raw materials used for the manufacture of the products. Transport of the raw materials (A2): this module consists of the transportation of all raw materials covered by module A1, from the extraction, production, and treatment site to the factory, considering the specific distances of each material supplier. Manufacturing of products (A3): this module refers to the production process of Polycoat RBE in the production plants. The raw materials are received and stored at the production site, then dosed and mixed to form a stable rubber‑modified bitumen emulsion according to a defined formulation. After mixing, product samples are tested in the quality control laboratory, and the finished product is filled into 200 L open‑top steel drums, labelled and palletized. Pallets with the ready‑to‑use product are stored for a short time in the factory’s warehouses before being delivered to distributors.

Name of the additional scenario

Polycoat RBE (100% reuse)

Description of the additional scenario

This represents a hypothetical scenario assuming 100% reuse, meaning the entire product is considered fully recycled at the end of its life cycle. Description of system boundaries: Cradle-to-gate with modules C1-C4, module D and optional modules A4 and A5, covering the modules of extraction and processing of raw materials (A1), their transportation to the production plant (A2), the manufacturing process (A3), transport to construction site (A4), installation (A5), end of life (C1-C4) and potential benefits and loads from the reuse and recycling of the products at its end of life (D). Product stage (A1-A3): Raw material supply (A1): this module considers the extraction and processing of raw materials used for the manufacture of the products. Transport of the raw materials (A2): this module consists of the transportation of all raw materials covered by module A1, from the extraction, production, and treatment site to the factory, considering the specific distances of each material supplier. Manufacturing of products (A3): this module refers to the production process of Polycoat RBE in the production plants. The raw materials are received and stored at the production site, then dosed and mixed to form a stable rubber‑modified bitumen emulsion according to a defined formulation. After mixing, product samples are tested in the quality control laboratory, and the finished product is filled into 200 L open‑top steel drums, labelled and palletized. Pallets with the ready‑to‑use product are stored for a short time in the factory’s warehouses before being delivered to distributors.

Module A4: Transport to the building site

Description of the additional scenario in module A4	The Site-to-site transportation includes the transportation of the finished, packaged Polycoat RBE from the production facility to the different customers site (A4). The transportation from the facility to customers is therefore estimated by range distances of 167.35 km based on market share of customer location.

Module A4 information	Value	Unit
Distance	167	km
Capacity utilization (including empty returns)	100	%
Bulk density of transported products	1020	kg/m³
Volume capacity utilization factor (factor: =1 or <1 or ≥1 for compressed or nested packaged products)	1	N/A
Fuel type and consumption of the vehicle	Diesel, 16-32 tons trucks with 34 L per 100 km fuel consumption,	N/A

Module A5: Installation in the building

Description of the additional scenario in module A5	The application of the product is performed manually. In Module A5, only material losses during installation and the end‑of‑life treatment of packaging are considered. No additional materials or auxiliary products are included beyond those already accounted for in the system.

Module A5 information	Value	Unit
Material loss	2	%

Module C: End-of-life

Description of the additional scenario in module C	Dismantling or demolition (C1): This module analyzes the environmental impacts associated with the deconstruction or dismantling of the bitumen coating (Polycoat RBE) on a construction site after its useful life. Module C1 includes all processes and activities used on site for the deconstruction of the bitumen coating. The consumption of energy and natural resources is negligible for deconstruction of the end of life product, as demolition of the bitumen coating is assumed to be done manually. Thus, the impacts of demolition are assumed zero. • Transport to waste treatment site (C2): this module considers a default distance of 50 km (distance assumed in most EPD studies), between the construction site where the product was installed and the waste management facility (in this case landfill). • Waste treatment (C3): this module covers the process of processing construction and demolition waste prior to disposal. For this study, no specific pre treatment is modelled and the removed product waste is considered to be disposed of directly in landfill as the most conservative scenario. • Disposal (C4): This module covers the final disposal of any waste that is not directed to recovery or treatment processes. In the 100% recycling scenario, all product waste at end of life is assumed to be collected for recycling. Consequently, no direct landfill disposal of the product is modelled. Any potential disposal of minor recycling residues (e.g., sorting or processing rejects) is considered outside the scope of the product waste stream or assumed to be negligible. Given distribution across multiple countries, a conservative and harmonized end-of-life assumption has been applied to avoid underestimation of impacts due to differences in national waste management practices.

Description of the additional scenario in module C

Module C information	Value	Unit
Waste collection process, specified by type kg collected mixed with demolition waste	1	kg
Waste disposal kg to Recycling/Reuse	1	kg
Distance to waste manager (km)	50	km

Reference service life

Description of the additional scenario in reference service life	The reference service life of the Henkel Product is 60 years.

Reference service life information	Value	Unit
Reference service life	60	year(s)

Module D: Beyond product life cycle

Description of the additional scenario in module D	Module D considers the benefits and burdens linked to the processes of recovery, reuse or recycling of waste from the product under study (Polycoat RBE) at the end of its useful life, which could be part of the life cycle of a new product. The recycling of the product is modelled to substitute the manufacture of an equivalent new product; therefore, the avoided burdens of modules A1–A3 are reported as credits in Module D, consistent with the EN 15804+A2 substitution/net‑flow approach.

Description of the additional scenario in module D

Module D considers the benefits and burdens linked to the processes of recovery, reuse or recycling of waste from the product under study (Polycoat RBE) at the end of its useful life, which could be part of the life cycle of a new product. The recycling of the product is modelled to substitute the manufacture of an equivalent new product; therefore, the avoided burdens of modules A1–A3 are reported as credits in Module D, consistent with the EN 15804+A2 substitution/net‑flow approach.

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 category	Indicator	Unit	A1-A3	A4	A5	B1	B2	B3	B4	B5	B6	B7	C1	C2	C3	C4	D
Climate change - total	GWP-total	kg CO₂ eq.	8.56E-1	3.36E-2	1.01E-2	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.01E-2	0.00E+0	6.26E-3	0.00E+0
Climate change - fossil	GWP-fossil	kg CO₂ eq.	8.48E-1	3.36E-2	1.01E-2	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.01E-2	0.00E+0	6.26E-3	0.00E+0
Climate change - biogenic	GWP-biogenic	kg CO₂ eq.	7.45E-3	8.43E-6	1.14E-4	ND	ND	ND	ND	ND	ND	ND	0.00E+0	2.52E-6	0.00E+0	2.15E-6	0.00E+0
Climate change - land use and land-use change	GWP-luluc	kg CO₂ eq.	5.08E-4	1.51E-5	5.70E-6	ND	ND	ND	ND	ND	ND	ND	0.00E+0	4.54E-6	0.00E+0	3.56E-6	0.00E+0
Ozone depletion	ODP	kg CFC-11 eq.	2.01E-8	4.42E-10	3.24E-10	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.32E-10	0.00E+0	1.74E-10	0.00E+0
Acidification	AP	mol H⁺ eq.	3.77E-3	1.28E-4	4.77E-5	ND	ND	ND	ND	ND	ND	ND	0.00E+0	3.84E-5	0.00E+0	4.38E-5	0.00E+0
Eutrophication aquatic freshwater	EP-freshwater	kg P eq.	2.58E-5	4.16E-7	1.77E-7	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.25E-7	0.00E+0	6.12E-8	0.00E+0
Eutrophication aquatic marine	EP-marine	kg N eq.	7.12E-4	4.29E-5	7.86E-6	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.28E-5	0.00E+0	1.67E-5	0.00E+0
Eutrophication terrestrial	EP-terrestrial	mol N eq.	7.69E-3	4.74E-4	8.64E-5	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.42E-4	0.00E+0	1.84E-4	0.00E+0
Photochemical ozone formation	POCP	kg NMVOC eq.	4.43E-3	1.74E-4	6.52E-5	ND	ND	ND	ND	ND	ND	ND	0.00E+0	5.21E-5	0.00E+0	6.63E-5	0.00E+0
Depletion of abiotic resources - minerals and metals	ADP-minerals&metals¹	kg Sb eq.	6.99E-6	1.11E-7	8.73E-8	ND	ND	ND	ND	ND	ND	ND	0.00E+0	3.31E-8	0.00E+0	9.16E-9	0.00E+0
Depletion of abiotic resources - fossil fuels	ADP-fossil¹	MJ, net calorific value	2.17E+1	4.66E-1	3.52E-1	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.40E-1	0.00E+0	1.53E-1	0.00E+0
Water use	WDP¹	m³ world eq. deprived	3.96E-1	2.16E-3	6.54E-3	ND	ND	ND	ND	ND	ND	ND	0.00E+0	6.48E-4	0.00E+0	6.68E-3	0.00E+0
Acronyms	GWP-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 disclaimer	The 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 1	The 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 category	Indicator	Unit	A1-A3	A4	A5	B1	B2	B3	B4	B5	B6	B7	C1	C2	C3	C4	D
Climate change - GWP-GHG	GWP-GHG¹	kg CO₂ eq.	8.15E-1	3.34E-2	9.54E-3	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.00E-2	0.00E+0	6.22E-3	0.00E+0
Acronyms	GWP-GHG = Global warming potential greenhouse gas.
General disclaimer	The 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 1	The 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 category	Indicator	Unit	A1-A3	A4	A5	B1	B2	B3	B4	B5	B6	B7	C1	C2	C3	C4	D
Particulate matter emissions	PM	Disease incidence	4.92E-8	2.63E-9	5.53E-10	ND	ND	ND	ND	ND	ND	ND	0.00E+0	7.87E-10	0.00E+0	1.01E-9	0.00E+0
Ionizing radiation - human health	IRP¹	kBq U235 eq.	1.35E-2	1.46E-4	8.60E-5	ND	ND	ND	ND	ND	ND	ND	0.00E+0	4.38E-5	0.00E+0	3.56E-5	0.00E+0
Eco-toxicity - freshwater	ETP-fw²	CTUe	3.69E+0	8.55E-2	3.62E-2	ND	ND	ND	ND	ND	ND	ND	0.00E+0	2.56E-2	0.00E+0	1.11E-2	0.00E+0
Human toxicity - cancer effects	HTP-c²	CTUh	4.16E-10	5.63E-12	2.30E-12	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.69E-12	0.00E+0	1.13E-12	0.00E+0
Human toxicity - non-cancer effects	HTP-nc²	CTUh	7.84E-9	2.89E-10	8.63E-11	ND	ND	ND	ND	ND	ND	ND	0.00E+0	8.64E-11	0.00E+0	2.54E-11	0.00E+0
Land-use related impacts/soil quality	SQP²	Dimensionless	4.59E+0	2.74E-1	6.53E-2	ND	ND	ND	ND	ND	ND	ND	0.00E+0	8.21E-2	0.00E+0	3.01E-1	0.00E+0
Acronyms	PM = 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 disclaimer	The 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 1	This 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 2	The 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 voluntary environmental performance indicators

Impact category	Indicator	Unit	A1-A3	A4	A5	B1	B2	B3	B4	B5	B6	B7	C1	C2	C3	C4	D
High-Level radioactive waste	-	kg	0.00E+0	0.00E+0	0.00E+0	ND	ND	ND	ND	ND	ND	ND	0.00E+0	0.00E+0	0.00E+0	0.00E+0	0.00E+0
Intermediate/low-level radioactive waste	-	kg	0.00E+0	0.00E+0	0.00E+0	ND	ND	ND	ND	ND	ND	ND	0.00E+0	0.00E+0	0.00E+0	0.00E+0	0.00E+0
Global warming potential	(GWP 100)	kg CO2 eq	8.30E-1	3.32E-2	9.74E-3	ND	ND	ND	ND	ND	ND	ND	0.00E+0	9.93E-3	0.00E+0	6.11E-3	0.00E+0
Ozone depletion potential	(ODP)	kg CFC-11 eq	2.13E-8	4.66E-10	3.41E-10	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.39E-10	0.00E+0	1.84E-10	0.00E+0
Eutrophication potential	(EP)	kg N eq	3.83E-4	2.31E-5	4.26E-6	ND	ND	ND	ND	ND	ND	ND	0.00E+0	6.91E-6	0.00E+0	8.96E-6	0.00E+0
Acidification potetential	(AP)	kg SO2 eq	3.21E-3	1.16E-4	4.05E-5	ND	ND	ND	ND	ND	ND	ND	0.00E+0	3.47E-5	0.00E+0	3.96E-5	0.00E+0
Photochemical o0idant creation potential	(POCP)	kg O3 eq	4.27E-2	2.72E-3	4.93E-4	ND	ND	ND	ND	ND	ND	ND	0.00E+0	8.15E-4	0.00E+0	1.06E-3	0.00E+0
Acronyms
General disclaimer	The 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).

Justification for inclusion	Additional optional indicators

Resource use indicators according to EN 15804

Indicator	Unit	A1-A3	A4	A5	B1	B2	B3	B4	B5	B6	B7	C1	C2	C3	C4	D
PERE	MJ, net calorific value	8.16E-1	6.48E-3	3.45E-1	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.94E-3	0.00E+0	1.43E-3	0.00E+0
PERM	MJ, net calorific value	3.37E-1	0.00E+0	-3.37E-1	ND	ND	ND	ND	ND	ND	ND	0.00E+0	0.00E+0	0.00E+0	0.00E+0	0.00E+0
PERT	MJ, net calorific value	1.15E+0	6.48E-3	8.38E-3	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.94E-3	0.00E+0	1.43E-3	0.00E+0
PENRE	MJ, net calorific value	2.23E+1	4.96E-1	1.21E+0	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.49E-1	0.00E+0	1.63E-1	0.00E+0
PENRM	MJ, net calorific value	8.32E-1	0.00E+0	-8.32E-1	ND	ND	ND	ND	ND	ND	ND	0.00E+0	0.00E+0	0.00E+0	0.00E+0	0.00E+0
PENRT	MJ, net calorific value	2.32E+1	4.96E-1	3.75E-1	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.49E-1	0.00E+0	1.63E-1	0.00E+0
SM	kg	0.00E+0	0.00E+0	0.00E+0	ND	ND	ND	ND	ND	ND	ND	0.00E+0	0.00E+0	0.00E+0	0.00E+0	0.00E+0
RSF	MJ, net calorific value	0.00E+0	0.00E+0	0.00E+0	ND	ND	ND	ND	ND	ND	ND	0.00E+0	0.00E+0	0.00E+0	0.00E+0	0.00E+0
NRSF	MJ, net calorific value	0.00E+0	0.00E+0	0.00E+0	ND	ND	ND	ND	ND	ND	ND	0.00E+0	0.00E+0	0.00E+0	0.00E+0	0.00E+0
FW	m³	1.02E-2	6.50E-5	1.60E-4	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.95E-5	0.00E+0	1.59E-4	0.00E+0
Acronyms	PERE = 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 disclaimer	The 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

Indicator	Unit	A1-A3	A4	A5	B1	B2	B3	B4	B5	B6	B7	C1	C2	C3	C4	D
HWD	kg	4.75E-3	1.27E-5	9.88E-6	ND	ND	ND	ND	ND	ND	ND	0.00E+0	3.79E-6	0.00E+0	2.24E-6	0.00E+0
NHWD	kg	1.43E-1	2.16E-2	2.08E-2	ND	ND	ND	ND	ND	ND	ND	0.00E+0	6.48E-3	0.00E+0	1.00E+0	0.00E+0
RWD	kg	9.82E-6	9.20E-8	5.43E-8	ND	ND	ND	ND	ND	ND	ND	0.00E+0	2.75E-8	0.00E+0	2.24E-8	0.00E+0
Acronyms	HWD = Hazardous waste disposed; NHWD = Non-hazardous waste disposed; RWD = Radioactive waste disposed.
General disclaimer	The 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

Indicator	Unit	A1-A3	A4	A5	B1	B2	B3	B4	B5	B6	B7	C1	C2	C3	C4	D
CRU	kg	0.00E+0	0.00E+0	0.00E+0	ND	ND	ND	ND	ND	ND	ND	0.00E+0	0.00E+0	0.00E+0	0.00E+0	0.00E+0
MFR	kg	0.00E+0	0.00E+0	0.00E+0	ND	ND	ND	ND	ND	ND	ND	0.00E+0	0.00E+0	0.00E+0	0.00E+0	0.00E+0
MER	kg	7.68E-2	0.00E+0	0.00E+0	ND	ND	ND	ND	ND	ND	ND	0.00E+0	0.00E+0	0.00E+0	0.00E+0	0.00E+0
EEE	MJ, net calorific value	0.00E+0	0.00E+0	0.00E+0	ND	ND	ND	ND	ND	ND	ND	0.00E+0	0.00E+0	0.00E+0	0.00E+0	0.00E+0
EET	MJ, net calorific value	0.00E+0	0.00E+0	0.00E+0	ND	ND	ND	ND	ND	ND	ND	0.00E+0	0.00E+0	0.00E+0	0.00E+0	0.00E+0
Acronyms	CRU = Components for re-use; MFR = Materials for recycling; MER = Materials for energy recovery; EEE = Exported electrical energy; EET = Exported thermal energy.
General disclaimer	The 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 scenario	Polycoat RBE (100% recycling)
Description of the scenario/method	This scenario results are valid for both 100% reuse and 100% recycling scenarios.

Results for additional scenarios for modules A4-C4

Impact category	Indicator	Unit	A1-A3	A4	A5	B1	B2	B3	B4	B5	B6	B7	C1	C2	C3	C4	D
GWP-fossil	GWP-fossil	kg CO2 eq.	4.60E+4	3.36E-2	1.01E-2	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.01E-2	4.40E-3	-4.01E+0	-4.58E-1
GWP-biogenic	GWP-biogenic	kg CO2 eq.	1.09E-2	8.43E-6	2.17E-5	ND	ND	ND	ND	ND	ND	ND	0.00E+0	2.52E-6	4.89E-7	-1.09E-2	-8.80E-4
GWP-luluc	GWP-luluc	kg CO2 eq.	2.22E-3	1.51E-5	5.70E-6	ND	ND	ND	ND	ND	ND	ND	0.00E+0	4.54E-6	4.50E-7	-2.22E-3	-2.06E-4
GWP-Total	GWP-Total	kg CO2 eq.	4.61E+4	3.36E-2	1.01E-2	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.01E-2	4.40E-3	-4.02E+0	-4.59E-1
ODP	ODP	kg CFC 11 eq.	6.47E-8	4.42E-10	3.24E-10	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.32E-10	6.53E-11	-6.47E-8	-6.03E-9
AP	AP	mol H+ eq.	9.64E-2	1.28E-4	4.77E-5	ND	ND	ND	ND	ND	ND	ND	0.00E+0	3.84E-5	3.93E-5	-9.64E-2	-1.23E-3
EP-freshwater	EP-freshwater	kg P eq.	4.31E-4	3.68E-6	1.70E-6	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.10E-6	1.42E-7	-4.31E-4	-7.60E-6
EP-marine	EP-marine	kg N eq.	2.45E-2	4.35E-5	8.16E-6	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.30E-5	1.83E-5	-2.45E-2	-3.16E-4
EP-terrestrial	EP-terrestrial	mol N eq.	2.64E-1	4.74E-4	8.64E-5	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.42E-4	2.00E-4	-2.64E-1	-3.59E-3
POCP	POCP	kg NMVOC eq.	7.39E-2	1.74E-4	6.52E-5	ND	ND	ND	ND	ND	ND	ND	0.00E+0	5.21E-5	5.99E-5	-7.39E-2	-1.25E-3
ADP-minerals and metals0	ADP-minerals and metals1	kg Sb eq.	1.02E-5	1.11E-7	8.73E-8	ND	ND	ND	ND	ND	ND	ND	0.00E+0	3.31E-8	1.57E-9	-1.02E-5	-1.39E-6
ADP-fossil0	ADP-fossil1	MJ	6.04E+1	4.66E-1	3.52E-1	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.40E-1	5.73E-2	-6.04E+1	-4.04E+0
WDP0	WDP1	m3	-1.03E+0	2.16E-3	6.54E-3	ND	ND	ND	ND	ND	ND	ND	0.00E+0	6.48E-4	1.22E-4	4.61E+4	-8.21E-2
GWP-GHG	GWP-GHG	kg CO2 eq.	3.59E+4	3.34E-2	9.54E-3	ND	ND	ND	ND	ND	ND	ND	0.00E+0	1.00E-2	4.39E-3	-3.98E+0	-3.98E-1
Acronyms
Disclaimers
General disclaimer	The 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).

EN European Norm (Standard)

EPD Environmental Product Declaration

EF Environmental Footprint

GPI General Programme Instructions

ISO International Organization for Standardization

LCA Life Cycle Assessment

PCR Product Category Rules

c-PCR Complementary Product Category Rules

CEN European Committee for Standardization

CLC Co-location centre

CPC Central product classification

GHS Globally harmonized system of classification and labelling of chemicals

GRI Global Reporting Initiative

Environmental Impact Indicators (EN 15804)

GHG Greenhouse gas

GWP Global Warming Potential (kg CO₂ eq.)

GWP-fossil Global Warming Potential from fossil sources (kg CO₂ eq.)

GWP-biogenic Global Warming Potential from biogenic sources (kg CO₂ eq.)

GWP-luluc Global Warming Potential from land use and land use change (kg CO₂ eq.)

GWP-total Total Global Warming Potential (kg CO₂ eq.)

GWP-GHG Global Warming Potential for greenhouse gases (kg CO₂ eq.)

ODP Ozone Depletion Potential (kg CFC-11 eq.)

AP Acidification Potential (mol H⁺ eq.)

EP Eutrophication Potential

EP-freshwater Freshwater eutrophication potential (kg P eq.)

EP-marine Marine eutrophication potential (kg N eq.)

EP-terrestrial Terrestrial eutrophication potential (mol N eq.)

POCP Photochemical Ozone Creation Potential (kg NMVOC eq.)

ADP Abiotic Depletion Potential

ADP-minerals&metals Abiotic depletion potential for non-fossil resources (kg Sb eq.)

ADP-fossil Abiotic depletion potential for fossil resources (MJ)

WDP Water Deprivation Potential (m³)

Resource Use Indicators

PERE Use of renewable primary energy excluding renewable primary energy resources used as raw materials (MJ)

PERM Use of renewable primary energy resources used as raw materials (MJ)

PERT Total use of renewable primary energy resources (MJ)

PENRE Use of non-renewable primary energy excluding non-renewable primary energy resources used as raw materials (MJ)

PENRM Use of non-renewable primary energy resources used as raw materials (MJ)

PENRT Total use of non-renewable primary energy resources (MJ)

SM Use of secondary material (kg)

RSF Use of renewable secondary fuels (MJ)

NRSF Use of non-renewable secondary fuels (MJ)

FW Use of net fresh water (m³)

Waste Indicators

HW Hazardous Waste (disposed) (kg)

NHW Non-Hazardous Waste (disposed) (kg)

RW Radioactive Waste (disposed) (kg)

Output Flow Indicators

CFR Components for Reuse (kg)

MR Material for Recycling (kg)

MER Materials for Energy Recovery (kg)

EEE Exported Energy, Electricity (MJ)

EET Exported Energy, Thermal (MJ)

Lifecycle Stages / Modules

A1 Raw material supply

A2 Transport

A3 Manufacturing

A4 Transport to site

A5 Construction/Installation

B1 Use

B2 Maintenance

B3 Repair

B4 Replacement

B5 Refurbishment

B6 Operational energy use

B7 Operational water use

C1 Deconstruction/Demolition

C2 Transport to waste processing

C3 Waste processing

C4 Disposal

D Reuse-Recovery-Recycling potential

Other Relevant Terms

SVHC Substances of Very High Concern

EC No. European Community Number

CAS No. Chemical Abstracts Service Number

MJ Megajoule

kg Kilogram

m³ Cubic Meter

NMVOC Non-Methane Volatile Organic Compounds

Sb eq. Antimony Equivalents

P eq. Phosphorus Equivalents

N eq. Nitrogen Equivalents

CFC-11 eq. Chlorofluorocarbon-11 Equivalents

CO₂ eq. Carbon Dioxide Equivalents

kg C Kilograms of Carbon

kg CO₂ eq. Kilograms of Carbon Dioxide Equivalent

ND Not Declared

General Programme Instructions of the International EPD® System. Version 5.0.1.

Product Category Rules PCR 2019:14 Construction products, version 2.0.1 Published on 2025.04.07 valid until: 2030.04.07, based on the European standard UNI-EN 15804:2012+A2:2020.

UNI-EN ISO 14040:2006 – Environmental management – Life Cycle Assessment – Principles and framework.

UNI-EN ISO 14044:2006 – Environmental management – Life Cycle Assessment – Requirements.

UNI-EN ISO 14025:2006- Labels and environmental declarations.

ISO/TR 14047: 2003 – Environmental management – Life Cycle Assessment – LCI application examples.

ISO/TS 14048: 2003 – Environmental management – Life Cycle Assessment – Data inventory.

ISO/TR 14049: 2000 – Environmental management – Life Cycle Assessment – Examples of application of objectives and scope and inventory analysis.

UNI-EN 15804:2012+A2: Sustainability in construction. Product environmental statements. Commodity category rules for construction products.

ISO (2017): ISO 21930:2017, Sustainability in buildings and civil engineering works -- Core rules for environmental product declarations of construction products and services

Version history

001, 2026-05-12

Polycoat RBE

General information

Programme information

Product category rules

Verification

Ownership and limitation on use of EPD

Limitations

Ownership

Information about EPD Owner

Description of the organisation of the EPD Owner

Organisation logo

Product information

Product images

Content declaration

LCA information

Data quality assessment

System boundary

Declared modules

Process flow diagram(s) related images

Default scenario

Module A4: Transport to the building site

Module A5: Installation in the building

Module C: End-of-life

Reference service life

Module D: Beyond product life cycle

Additional scenario 1

Module A4: Transport to the building site

Module A5: Installation in the building

Module C: End-of-life

Reference service life

Module D: Beyond product life cycle

Additional scenario 2

Module A4: Transport to the building site

Module A5: Installation in the building

Module C: End-of-life

Reference service life

Module D: Beyond product life cycle

Environmental performance

Mandatory environmental performance indicators according to EN 15804

Additional mandatory environmental performance indicators

Additional voluntary environmental performance indicators according to EN 15804

Additional voluntary environmental performance indicators

Resource use indicators according to EN 15804

Waste indicators according to EN 15804

Output flow indicators according to EN 15804

Results for additional scenarios for modules A4-C4

Abbreviations

References

Version history