EPD-IES-0029006:001

PE Interhol Manhole

PE Interhol Manholes are innovative underground access chambers manufactured from high-quality polyethylene (PE) for use in sewerage, wastewater, and stormwater systems. Designed to meet the requirements of EN 13598-1 and EN 13598-2, Interhol manholes ensure reliable structural performance and compliance with European standards for inspection chambers and manholes in buried drainage networks. Polyethylene as a material provides excellent resistance to chemicals, corrosion, and abrasion commonly found in wastewater environments. Its flexibility and high impact strength allow the structure to withstand ground movements, traffic loads, and varying temperature conditions without compromising integrity. This makes Interhol PE manholes particularly suitable for demanding municipal and infrastructure applications. The system is developed with a modular concept, consisting of a base element, vertical riser sections, cones, covers, and integrated sealing components. This configuration enables efficient transportation, simplified on-site assembly, and reduced installation time. The lightweight nature of PE further supports safe handling while maintaining high load-bearing capacity and watertight performance. Interhol PE manholes are produced under controlled quality and environmental management procedures, they contribute to sustainable infrastructure development, as polyethylene is fully recyclable and supports long service life with minimal environmental impact. These manholes are suitable for urban sewer networks, stormwater systems, industrial drainage, and other underground utility installations requiring durability, adaptability, and long-term operational reliability.

General information

EPD OwnerInter Construction
Registration numberEPD-IES-0029006:001
EPD typeEPD of a single product from a manufacturer/service provider
StatusValid
Version date2026-03-25
Validity date2031-03-25
Standards conformanceISO 14025:2006, EN 15804:2012+A2:2019/AC:2021
Geographical scopeEurope, Republic of North Macedonia, Global
An EPD may be updated or depublished if conditions change. This is the latest version of the EPD.

Programme information

ProgrammeInternational 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 accountabilityAna Tanevska, tanevskaanna@gmail.com, Inter Construction
Independent third-party verification of the declaration and data, according to ISO 14025:2006, via
Third-party verifierSilvia Vilčeková (SILCERT, Ltd.)
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.environdec.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 OwnerInter Construction
Contact person nameAleksandra Karaivanova
Contact person e-mailaleksandra.k@inter-construction.com.mk
Organisation addressNorth Macedonia Gevgelija 1483 Industriska Zona br.2 Prdejci, Gevgelija

Description of the organisation of the EPD Owner

Inter Construction is a leading construction and industrial company in North Macedonia, specializing in the development, manufacturing, and installation of advanced building and infrastructure systems. Established with a focus on innovation and quality, Inter Construction has expanded its portfolio to include civil engineering, infrastructure projects, and high-performance polymer-based construction solutions. The company produces a wide range of products, polyethylene (PE) and polypropylene (PP) manholes, pipes and other industrial products from its diverse portfolio. The company serves both public utilities and private industrial clients, delivering reliable, durable, and sustainable products. With a commitment to international standards and continuous growth, Inter Construction is recognized as a trusted partner in the region, contributing to modern, efficient, and environmentally responsible construction practices.

Organisation logo

Product information

Product namePE Interhol Manhole
Product identificationManhole
Product descriptionPE Interhol Manholes are innovative underground access chambers manufactured from high-quality polyethylene (PE) for use in sewerage, wastewater, and stormwater systems. Designed to meet the requirements of EN 13598-1 and EN 13598-2, Interhol manholes ensure reliable structural performance and compliance with European standards for inspection chambers and manholes in buried drainage networks. Polyethylene as a material provides excellent resistance to chemicals, corrosion, and abrasion commonly found in wastewater environments. Its flexibility and high impact strength allow the structure to withstand ground movements, traffic loads, and varying temperature conditions without compromising integrity. This makes Interhol PE manholes particularly suitable for demanding municipal and infrastructure applications. The system is developed with a modular concept, consisting of a base element, vertical riser sections, cones, covers, and integrated sealing components. This configuration enables efficient transportation, simplified on-site assembly, and reduced installation time. The lightweight nature of PE further supports safe handling while maintaining high load-bearing capacity and watertight performance. Interhol PE manholes are produced under controlled quality and environmental management procedures, they contribute to sustainable infrastructure development, as polyethylene is fully recyclable and supports long service life with minimal environmental impact. These manholes are suitable for urban sewer networks, stormwater systems, industrial drainage, and other underground utility installations requiring durability, adaptability, and long-term operational reliability.
Product information from external sourceswww.inter-construction.com.mk
Technical purpose of productThe role of the PE Interhol manhole is to control the right working of sewer systems. It provides access points of inspection, maintenance and cleaning.
Manufacturing or service provision descriptionManholes are produced using rotomoulding technology. This process ensures strong product perfectly shaped for underground use.
Material propertiesVolumetric mass density: 940 kg/m3
Volumetric mass density:
940 kg/m3
Manufacturing siteGevgelija North Macedonia Gevgelija 1480
UN CPC code36950. Builders' ware of plastics n.e.c.
Geographical scopeEurope, Republic of North Macedonia, Global
Geographical scope descriptionModules A1 and A2 – Global Modules A3 – North Macedonia Modules C1-C4 & D – Europe

Product images

Content declaration

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
PE0.84000
Masterbatch0.11000
EPDM0.05000
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
No packaging materials declared000
Total000
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 flowProduct 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 3.11 database Other database ecoinvent 3.12 database
LCA SoftwareOpenLCA OpenLCA 2.5.0
Version of the EN 15804 reference packageEF Reference Package 3.1
Characterisation methodsEnvironmental Footprint (EF) 3.1
Technology description including background systemPE Interhol Manhole is designed for underground sewage and drainage systems. It is produced from polyethylene (PE) material which provide excellent chemical resistance, durability, and long-term structural performance in buried applications. The product is manufactured using rotomoulding technology, where the polyethylene material is heated and rotated within a mould. The process is optimized for efficient material use, and any production scraps generated during manufacturing are collected and internally recycled where possible. The background system is modelled using the ecoinvent 3.12 database. The end-of-life (EoL) stage follows a mixed waste treatment scenario based on European statistics reported by Plastics Europe (2024).
Scrap (recycled material) inputs contribution levelLess 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 yearsThe share of primary data is calculated based on the contribution to GWP-GHG results for modules A1–A3 in accordance with EN 15804+A2. Site-specific data are applied for the manufacturing processes at the production facility (e.g. electricity and fuel consumption), while upstream processes such as raw material production are modelled using generic datasets from the ecoinvent 3.12 database. Transport processes are conservatively considered to consist of 50% primary and 50% secondary data, reflecting the use of company-specific transport distances combined with generic background datasets for transport modelling. Due to the dominant contribution of polyethylene raw material production to the overall environmental impact of the product, the impact-weighted share of primary data remains limited compared to the total environmental impact of modules A1–A3.
Data quality assessment
Process nameSource typeSourceReference yearData categoryShare of primary data, of GWP-GHG results for A1-A3
ManufacturingPrimaryProduction facility2025Specific26.5%
Raw MaterialsSecondaryecoinvent 3.12 database2024Generic0%
TransportSecondary (50% primary considered)ecoinvent 3.12 database2024Generic6.4%
Total share of primary data, of GWP-GHG results for A1-A332.9%
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 mixResidual electricity mix on the market
Energy sourcesHydro14%
Wind1%
Solar10%
Biomass0%
Geothermal0%
Waste0%
Nuclear0%
Natural gas15%
Coal60%
Oil0%
Peat0%
Other0%
GWP-GHG intensity (kg CO2 eq./kWh)0.5 kg CO2 eq./kWh
Method used to calculate residual electricity mixThe residual electricity mix was calculated based on the 2025 energy balance data provided by the State Statistical Office of North Macedonia. The calculation follows the requirements of PCR 2019:14 2.0.1. In the absence of a specific 'Residual Mix' certificate from the national regulator, the national consumption mix was used as a conservative proxy for the market residual mix.

System boundary

Description of the system boundarya) Cradle to gate with modules C1-C4 and module D (A1-A3 + C + D).
Excluded modulesYes, there is an excluded module, or there are excluded modules
Justification for the omission of modulesModules related to use stage B1 – B7 and installation A4 – A5 are marked as ND (Not declared) because the applicable PCR classify these life stages as optional.

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 declaredXXXNDNDNDNDNDNDNDNDNDXXXXX
GeographyGlobalGlobalRepublic of North MacedoniaN/AN/AN/AN/AN/AN/AN/AN/AN/AEuropeEuropeEuropeEuropeEurope
Share of specific data32.9%--------------
Variation - products0%--------------
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)

Allocation: Electricity, water and auxiliary materials were allocated to the declared unit based on annual production data using mass-based allocation. Cut-off criteria: Capital goods such as production machinery, tools and knives, internal transport equipment were excluded from the system boundary due to lack of specific data and their negligible contribution to the overall environmental impacts. The applied cut-off criteria are in accordance with EN15804+A2, ensuring that at least 95% of the total mass and energy flows relevant to the declared product are included in the LCA.

Process flow diagram(s) related images

Default scenario

Name of the default scenarioEnd-of-Life scenario for PE Interhol Manholes
Description of the default scenarioThis scenario covers complete end-of-life cycle of the product including the removal, transportation and its final destination through a combination of recycling, incineration with energy recovery and landfill.

Module C: End-of-life

Explanatory name of the default scenario in module CWaste Treatment
Brief description of the default scenario in module C17.4% Recycling, 52.2% Incineration with Energy recovery and 30.4% Landfill.
Description of the default scenario in module CAt the end of service life the manhole is removed from the ground using standard excavation machinery and collected as mixed plastic construction waste (Module C1). The waste is transported 50 km by lorry to a waste treatment facility (Module C2). In the treatment facility the plastic components are mechanically sorted and shredded. A share is directed to mechanical recycling, while the remaining material is treated via municipal waste incineration with energy recovery or disposed to landfill (Module C3–C4). The distribution of waste routes follows average European plastic waste management statistics (Plastics Europe, 2024): 17.4% recycling, 52.2% incineration with energy recovery and 30.4% landfill. These shares are applied to the declared unit and correspond to the modelled end-of-life datasets. The European scenario is considered representative since the product is intended for international markets and no specific national statistics for plastic construction waste management are available. Benefits beyond the system boundary from material recycling and energy recovery are reported in Module D.
Module C informationValueUnit
Collected as mixed construction waste1
kg
Material for recycling0.17
kg
Material for energy recovery0.52
kg
Non - hazardous waste to landfill0.31
kg
Transportation to waste treatment50
kg

Module D: Beyond product life cycle

Explanatory name of the default scenario in module DRecovery and Recycling
Brief description of the default scenario in module DCredits for avoided production of primary PE, electricity and thermal energy.
Description of the default scenario in module DThe plastic saved through recycling, replaces the need for new, raw plastic production. The energy produced from burning the waste replaces electricity from the local grid and heat from natural gas. These avoided impacts are credited to the product resulting in the negative values shown in the results.
Module D informationValueUnit
Avoided PE0.17
kg
Avoided Electricity2.40
MJ
Avoided Thermal Energy4.80
MJ

Additional scenario 1

Name of the additional scenarioAdditional End-of-Life scenario: 100% Landfill scenario
Description of the additional scenarioIn the 100% Landfill scenario, the PE Interhol products are disposed of in municipal solid waste facilities with zero material or energy recovery. The inert polyethylene remains physically stable, permanently exiting the product loop and necessitating virgin feedstock for future production.

Module C: End-of-life

Description of the additional scenario in module CThe product is collected as mixed construction waste at the end of its service life and transported to a municipal solid waste facility. 100% of the PE Interhol material is disposed of in a landfill without further processing.

Module D: Beyond product life cycle

Description of the additional scenario in module DBecause the material is entirely landfilled, there is no material recovery, secondary product generation, or energy recovery. Therefore, no benefits or loads beyond the system boundary are declared for this scenario.

Additional scenario 2

Name of the additional scenarioAdditional End-of-life scenario: 100% Recycling scenario
Description of the additional scenarioIn the 100% Recycling scenario, the PE Interhol products are collected at the end of their service life and mechanically reprocessed. The recovered polyethylene is converted into secondary granulate, keeping the material within the product loop and avoiding the extraction and production of primary virgin feedstock.

Module C: End-of-life

Description of the additional scenario in module CThe product is collected separately at the end of its service life and transported to a specialized recycling facility. 100% of the PE Interhol material undergoes mechanical shredding and reprocessing to produce secondary polyethylene granulate.

Module D: Beyond product life cycle

Description of the additional scenario in module DThe secondary polyethylene granulate recovered from the product successfully substitutes the production of primary (virgin) fossil-based polyethylene feedstock, providing material recovery benefits.

Additional scenario 3

Name of the additional scenarioAdditional end-of-life scenario: 100% Incineration scenario
Description of the additional scenarioIn the 100% Incineration scenario, the PE Interhol products are routed to a waste-to-energy plant at the end of their service life. The polyethylene is combusted to generate thermal and electrical energy, recovering energy value from the polymer while the physical material permanently exits the product loop.

Module C: End-of-life

Description of the additional scenario in module CThe product is collected at the end of its service life and transported to a municipal waste incineration plant. 100% of the PE Interhol material is incinerated in a facility equipped with energy recovery technology.

Module D: Beyond product life cycle

Description of the additional scenario in module DThe incineration of the polyethylene material generates thermal and electrical energy. This exported energy provides benefits by substituting the equivalent production of thermal energy and electricity from the regional grid.

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.3.78E+0NDNDNDNDNDNDNDNDND1.91E-49.95E-39.95E-31.77E-3-7.63E-2
Climate change - fossilGWP-fossilkg CO2 eq.3.77E+0NDNDNDNDNDNDNDNDND1.91E-49.94E-39.94E-31.77E-3-5.90E-2
Climate change - biogenicGWP-biogenickg CO2 eq.0.00E+0NDNDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+00.00E+0
Climate change - land use and land-use changeGWP-luluckg CO2 eq.1.47E-3NDNDNDNDNDNDNDNDND1.93E-82.91E-62.91E-67.31E-7-2.03E-4
Ozone depletionODPkg CFC-11 eq.1.92E-7NDNDNDNDNDNDNDNDND2.94E-121.48E-101.48E-102.39E-11-3.43E-10
AcidificationAPmol H+ eq.1.90E-2NDNDNDNDNDNDNDNDND1.71E-65.85E-55.85E-51.45E-5-2.41E-4
Eutrophication aquatic freshwaterEP-freshwaterkg P eq.1.55E-3NDNDNDNDNDNDNDNDND6.14E-97.43E-77.43E-71.98E-7-3.60E-5
Eutrophication aquatic marineEP-marinekg N eq.4.74E-3NDNDNDNDNDNDNDNDND8.01E-72.48E-52.48E-56.30E-6-3.47E-5
Eutrophication terrestrialEP-terrestrialmol N eq.4.80E-2NDNDNDNDNDNDNDNDND8.76E-62.70E-42.70E-46.86E-56.34E-5
Photochemical ozone formationPOCPkg NMVOC eq.2.51E-2NDNDNDNDNDNDNDNDND2.63E-68.86E-58.86E-52.07E-53.15E-5
Depletion of abiotic resources - minerals and metalsADP-minerals&metals1kg Sb eq.1.42E-5NDNDNDNDNDNDNDNDND7.11E-111.75E-81.75E-88.43E-10-5.91E-7
Depletion of abiotic resources - fossil fuelsADP-fossil1MJ, net calorific value1.08E+2NDNDNDNDNDNDNDNDND2.48E-31.36E-11.36E-12.28E-2-6.33E-1
Water useWDP1m3 world eq. deprived8.48E-1NDNDNDNDNDNDNDNDND6.22E-66.05E-46.05E-41.18E-4-2.35E-2
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.3.77E+0NDNDNDNDNDNDNDNDND1.91E-49.95E-39.95E-31.77E-3-7.25E-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 incidence1.14E-7NDNDNDNDNDNDNDNDND4.88E-111.66E-91.66E-93.84E-10-7.95E-9
Ionizing radiation - human healthIRP1kBq U235 eq.2.33E-1NDNDNDNDNDNDNDNDND1.04E-69.03E-59.03E-54.55E-5-7.27E-3
Eco-toxicity - freshwaterETP-fw2CTUe1.28E+1NDNDNDNDNDNDNDNDND2.52E-42.22E-22.22E-22.73E-3-5.92E-1
Human toxicity - cancer effectsHTP-c2CTUh7.60E-10NDNDNDNDNDNDNDNDND1.84E-141.29E-121.29E-121.87E-13-9.70E-11
Human toxicity - non-cancer effectsHTP-nc2CTUh2.64E-8NDNDNDNDNDNDNDNDND3.27E-135.68E-115.68E-114.52E-12-1.23E-9
Land-use related impacts/soil qualitySQP2Dimensionless1.07E+1NDNDNDNDNDNDNDNDND1.72E-48.30E-28.30E-25.47E-2-3.05E-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 value2.73E+0NDNDNDNDNDNDNDNDND1.56E-51.46E-31.46E-36.44E-4-1.53E-1
PERMMJ, net calorific value0.00E+0NDNDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+00.00E+0
PERTMJ, net calorific value2.73E+0NDNDNDNDNDNDNDNDND1.56E-51.46E-31.46E-36.44E-4-1.53E-1
PENREMJ, net calorific value1.08E+2NDNDNDNDNDNDNDNDND2.48E-31.36E-11.36E-12.28E-2-6.33E-1
PENRMMJ, net calorific value0.00E+0NDNDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+00.00E+0
PENRTMJ, net calorific value1.08E+2NDNDNDNDNDNDNDNDND2.48E-31.36E-11.36E-12.28E-2-6.33E-1
SMkg1.27E-1NDNDNDNDNDNDNDNDND1.41E-69.06E-59.06E-51.92E-5-2.07E-1
RSFMJ, net calorific value6.52E-2NDNDNDNDNDNDNDNDND1.43E-71.07E-51.07E-55.59E-6-9.76E-4
NRSFMJ, net calorific value0.00E+0NDNDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+00.00E+0
FWm31.95E-2NDNDNDNDNDNDNDNDND1.49E-71.48E-51.48E-52.78E-6-5.18E-4
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
HWDkg4.45E-1NDNDNDNDNDNDNDNDND8.08E-66.93E-46.93E-41.01E-4-2.73E-2
NHWDkg2.90E+1NDNDNDNDNDNDNDNDND4.02E-51.09E-21.09E-21.05E-3-2.64E-1
RWDkg5.64E-5NDNDNDNDNDNDNDNDND2.44E-102.15E-82.15E-81.10E-8-1.82E-6
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+0NDNDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+00.00E+0
MFRkg0.00E+0NDNDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+00.00E+0
MERkg1.25E-1NDNDNDNDNDNDNDNDND1.20E-67.75E-57.75E-51.74E-5-2.77E-3
EEEMJ, net calorific value3.22E-2NDNDNDNDNDNDNDNDND1.16E-79.93E-69.93E-65.09E-6-9.41E-4
EETMJ, net calorific value9.55E-3NDNDNDNDNDNDNDNDND5.50E-89.41E-69.41E-66.01E-7-1.78E-4
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 scenarioAdditional End-of-Life scenario: 100% Landfill scenario
Description of the scenario/methodThis additional scenario differs from the main environmental performance results by isolating a 100% landfill end-of-life assumption. Instead of using a mixed disposal route, it models the impacts of sending all PE Interhol products directly to municipal solid waste facilities in Module C, with zero material or energy recovery.
Results for additional scenarios for modules A4-C4
Impact categoryIndicatorUnitA1-A3A4A5B1B2B3B4B5B6B7C1C2C3C4D
Global warming potential - total (GWP-total)GWP - totalkg CO2 eq.NDNDNDNDNDNDNDNDNDNDNDND0.00E+03.30E-20.00E+0
Global warming potential - fossil fuels (GWP-fossil)GWP - fossilkg CO2 eq.NDNDNDNDNDNDNDNDNDNDNDND0.00E+03.30E-20.00E+0
Global warming potential - biogenic (GWP-biogenic)GWP - biogenickg CO2 eq.NDNDNDNDNDNDNDNDNDNDNDND0.00E+00.00E+00.00E+0
Global warming potential - land use and land use change (GWP-luluc)GWP - luluckg CO2 eq.NDNDNDNDNDNDNDNDNDNDNDND0.00E+09.60E-60.00E+0
Depletion potential of the stratospheric ozone layer (ODP)ODPkg CFC-11 eq.NDNDNDNDNDNDNDNDNDNDNDND0.00E+04.90E-100.00E+0
Acidification potential, accumulated exceedance (AP)APmol H+ eq.NDNDNDNDNDNDNDNDNDNDNDND0.00E+01.90E-40.00E+0
Eutrophication potential - freshwater (EP-freshwater)EP - freshwaterkg P eq.NDNDNDNDNDNDNDNDNDNDNDND0.00E+02.40E-60.00E+0
Eutrophication potential - marine (EP-marine)EP - marinekg N eq.NDNDNDNDNDNDNDNDNDNDNDND0.00E+08.10E-50.00E+0
Eutrophication potential - terrestrial (EP-terrestrial)EP - terrestrialmol N eq.NDNDNDNDNDNDNDNDNDNDNDND0.00E+08.90E-40.00E+0
Photochemical ozone creation potential (POCP)POCPkg NMVOC eq.NDNDNDNDNDNDNDNDNDNDNDND0.00E+02.90E-40.00E+0
Abiotic depletion potential - non-fossil resources (ADPE)ADPEkg Sb eq.NDNDNDNDNDNDNDNDNDNDNDND0.00E+05.80E-80.00E+0
Abiotic depletion potential - fossil resources (ADPF)ADPFMJ, net calorific valueNDNDNDNDNDNDNDNDNDNDNDND0.00E+04.50E-10.00E+0
Water (user) deprivation potential (WDP)WDPm3 world eq. deprivedNDNDNDNDNDNDNDNDNDNDNDND0.00E+02.00E-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 scenarioAdditional End-of-life scenario: 100% Recycling scenario
Description of the scenario/methodThis additional scenario differs from the main environmental performance results by isolating a 100% recycling end-of-life assumption. Instead of using a mixed disposal route, it models the complete collection and mechanical reprocessing of all PE Interhol products in Module C to illustrate the environmental profile of maximum material recovery.
Results for additional scenarios for modules A4-C4
Impact categoryIndicatorUnitA1-A3A4A5B1B2B3B4B5B6B7C1C2C3C4D
Global warming potential - total (GWP-total)GWP - totalkg CO2 eq.NDNDNDNDNDNDNDNDNDNDNDND1.90E-20.00E+0-3.20E-1
Global warming potential - fossil fuels (GWP-fossil)GWP - fossilkg CO2 eq.NDNDNDNDNDNDNDNDNDNDNDND1.90E-20.00E+0-3.20E-1
Global warming potential - biogenic (GWP-biogenic)GWP - biogenickg CO2 eq.NDNDNDNDNDNDNDNDNDNDNDND0.00E+00.00E+00.00E+0
Global warming potential - land use and land use change (GWP-luluc)GWP - luluckg CO2 eq.NDNDNDNDNDNDNDNDNDNDNDND5.60E-60.00E+0-1.70E-4
Depletion potential of the stratospheric ozone layer (ODP)ODPkg CFC-11 eq.NDNDNDNDNDNDNDNDNDNDNDND2.80E-100.00E+0-1.50E-8
Acidification potential, accumulated exceedance (AP)APmol H+ eq.NDNDNDNDNDNDNDNDNDNDNDND1.10E-40.00E+0-1.00E-3
Eutrophication potential - freshwater (EP-freshwater)EP - freshwaterkg P eq.NDNDNDNDNDNDNDNDNDNDNDND1.40E-60.00E+0-7.10E-5
Eutrophication potential - marine (EP-marine)EP - marinekg N eq.NDNDNDNDNDNDNDNDNDNDNDND4.70E-50.00E+0-2.10E-4
Eutrophication potential - terrestrial (EP-terrestrial)EP - terrestrialmol N eq.NDNDNDNDNDNDNDNDNDNDNDND5.20E-40.00E+0-2.20E-3
Photochemical ozone creation potential (POCP)POCPkg NMVOC eq.NDNDNDNDNDNDNDNDNDNDNDND1.70E-40.00E+0-9.50E-4
Abiotic depletion potential - non-fossil resources (ADPE)ADPEkg Sb eq.NDNDNDNDNDNDNDNDNDNDNDND3.40E-80.00E+0-7.50E-6
Abiotic depletion potential - fossil resources (ADPF)ADPFMJ, net calorific valueNDNDNDNDNDNDNDNDNDNDNDND2.60E-10.00E+0-5.00E+0
Water (user) deprivation potential (WDP)WDPm3 world eq. deprivedNDNDNDNDNDNDNDNDNDNDNDND1.20E-30.00E+0-1.70E-1
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 scenarioAdditional end-of-life scenario: 100% Incineration scenario
Description of the scenario/methodThis additional scenario differs from the main environmental performance results by isolating a 100% incineration assumption. Instead of using a mixed disposal route, it models the thermal treatment of all PE Interhol products in Module C, illustrating the environmental profile of routing the entire product to a waste-to-energy facility.
Results for additional scenarios for modules A4-C4
Impact categoryIndicatorUnitA1-A3A4A5B1B2B3B4B5B6B7C1C2C3C4D
Global warming potential - total (GWP-total)GWP - totalkg CO2 eq.NDNDNDNDNDNDNDNDNDNDNDND5.70E-20.00E+0-3.90E+0
Global warming potential - fossil fuels (GWP-fossil)GWP - fossilkg CO2 eq.NDNDNDNDNDNDNDNDNDNDNDND5.70E-20.00E+0-3.90E+0
Global warming potential - biogenic (GWP-biogenic)GWP - biogenickg CO2 eq.NDNDNDNDNDNDNDNDNDNDNDND0.00E+00.00E+00.00E+0
Global warming potential - land use and land use change (GWP-luluc)GWP - luluckg CO2 eq.NDNDNDNDNDNDNDNDNDNDNDND1.70E-50.00E+0-9.30E-4
Depletion potential of the stratospheric ozone layer (ODP)ODPkg CFC-11 eq.NDNDNDNDNDNDNDNDNDNDNDND8.50E-100.00E+0-7.50E-8
Acidification potential, accumulated exceedance (AP)APmol H+ eq.NDNDNDNDNDNDNDNDNDNDNDND3.40E-40.00E+0-1.10E-2
Eutrophication potential - freshwater (EP-freshwater)EP - freshwaterkg P eq.NDNDNDNDNDNDNDNDNDNDNDND4.30E-60.00E+0-7.30E-4
Eutrophication potential - marine (EP-marine)EP - marinekg N eq.NDNDNDNDNDNDNDNDNDNDNDND1.40E-40.00E+0-2.40E-3
Eutrophication potential - terrestrial (EP-terrestrial)EP - terrestrialmol N eq.NDNDNDNDNDNDNDNDNDNDNDND1.60E-30.00E+0-2.50E-2
Photochemical ozone creation potential (POCP)POCPkg NMVOC eq.NDNDNDNDNDNDNDNDNDNDNDND5.10E-40.00E+0-1.30E-2
Abiotic depletion potential - non-fossil resources (ADPE)ADPEkg Sb eq.NDNDNDNDNDNDNDNDNDNDNDND1.00E-70.00E+0-1.80E-5
Abiotic depletion potential - fossil resources (ADPF)ADPFMJ, net calorific valueNDNDNDNDNDNDNDNDNDNDNDND7.80E-10.00E+0-7.60E+1
Water (user) deprivation potential (WDP)WDPm3 world eq. deprivedNDNDNDNDNDNDNDNDNDNDNDND3.50E-30.00E+0-6.60E-1
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

Inter Construction is strongly committed to sustainable production and a circular economy approach. The company always tries to work on minimizing its effects on the environment by reducing its use of energy and water and by increasing efficiency on all its production lines. Modern production methods, such as effective scheduling and monitoring and controlling machines by using legitimate software, help to use a maximum amount of energy and produce high-quality products.

The polyethylene (PE) manholes produced by Inter Construction are made with a focus on durability, long-life and recyclability. All throughout their production process, Inter Construction maintains a focus on minimizing their wastes while any generated during production is repurposed by them or given to partners for recycling. In such a manner, all materials are utilized to their fullest potential, thereby maintaining principles associated with achieving a circular economy.

At the end of a product life cycle, PE components can be recycled in a clean, efficient process that will be able to reuse them for something new, such as manholes or other plastic components, thereby having a positive impact on the environment through a circular process that Inter Construction emphasizes through its products and strategies.

Additional social and economic information

This EPD does not declare additional social or economic information.

Abbreviations

Abbreviation

General Abbreviations

EN - European Norm (Standard)

EF - Environmental Footprint

GPI - General Programme Instructions

CEN - European Committee for Standardization

CPC - Central product classification

SVHC - Substances of Very High Concern

ND - Not Declared

PE - Polyethylene

EPD - Environmental Product Declaration

PCR - Product Category Rules

ISO - International Organization for Standardization

LCA - Life Cycle Assessment

EPDM - Ethylene Propylene Diene Monomer

GWP - Climate change

GWP – luluc - land use and land use change

ODP - Ozone depletion

AP - Acidification

EP - Eutrophication

POCP - Photochemical ozone formation

ADPE - Abiotic resource use, minerals & metals

APDF - Abiotic resource use, fossils

WDP - Water use

PM - Particulate matter formation

IRP - Ionising radiation: human health

ETP – fw - Exotoxicity freshwater

HTP – c - Human toxicity: carcinogenic

HTP – nc - Human toxicity: non carcinogenic

SQP - Land use

Life – Cycle Stages

A1 - Raw Material supply

A2 - Transport

A3 - Manufacturing

A4 - Transport

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

C3 - Waste processing

C4 - Disposal

D - Reuse, recovery, recycling potential

Other

NM - North Macedonia

EU - Europe

GLO - Global

References

ISO 14025:2006 Environmental labels and declarations - Type III environmental declarations

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

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

PCR 2019:14 Construction Products, Version 2.0.1 (Valid until 2030-04-07)

General Programe Instructions of the International EPD System, Version 5.0.1

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

Plastics Europe 2024

Version history

Version 001, 2026-03-25

Original version of the EPD