EPD-IES-0027222:003

Hot Rolled sheet manufactured from steel scrap by T A 2000

TYASA produces different types of hot-rolled sheet according to the following steel grades: Drawing Grade Commercial Grade Structural Grade High-strength Low-Alloy Steel Grade On the other hand, tension-leveling is a process that seeks to correct shape problems, such as waves or warps, in steel sheets by gently stretching them with specialized equipment. It is important to mention that hot-rolled sheet coils, sheets, and strips can be delivered tension-leveled and with trimmed edges, allowing for efficient use of material and reducing waste and sub-processes. Hot rolled sheet is manufactured by TYASA in coils, sheets, and strips, as follows: Hot-rolled steel coils/sheets/strips.

General information

EPD OwnerT A 2000, S.A. de C.V.
Registration numberEPD-IES-0027222:003
EPD typeEPD of multiple products based on the average results of the product group
StatusValid
Initial version date2025-12-19
Validity date2030-12-18
Standards conformanceISO 14025:2006, EN 15804:2012+A2:2019/AC:2021
LicenseeEPD Mexico
Geographical scopeGlobal
An EPD may be updated or depublished if conditions change. This is the latest version of the EPD.

Programme information

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

Product category rules

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

Verification

LCA accountabilityDulce Alejandra Zaragoza Ayala, dzaragoza@cadis.earth, T A 2000, S.A. de C.V.
Independent third-party verification of the declaration and data, according to ISO 14025:2006, via
Third-party verifierFrancisco Jesús Campo Rámila (IK Ingeniería S.L.)
Approved byInternational EPD System
Procedure for follow-up of data during EPD validity involves third party verifier
*EPD Process Certification involves an accredited certification body certifying and periodically auditing the EPD process and conducting external and independent verification of EPDs that are regularly published. More information can be found in the General Programme Instructions on www.envrondec.com.

Ownership and limitation on use of EPD

Limitations

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

Ownership

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

Information about EPD Owner

EPD OwnerT A 2000, S.A. de C.V.
Contact person nameGuadalupe Román Hernández
Contact person e-mailgroman@ta42.com
Organisation addressMexico Orizaba 94450 Carretera Federal México-Veracruz Km. 321, s/n, interior 2, Ixtaczoquitlán, Veracruz. 94450 Ixtaczoquitlán, Veracruz

Description of the organisation of the EPD Owner

T A 2000 has more than 30 years of experience in the manufacture of steel. Innovation and optimization in production processes have driven the company to renew and diversify its product catalog. In 2016 a cutting-edge technology has been implemented in T A 2000’s steelmaking plant: an electric arc furnace (EAF) QUANTUM. The EAF QUANTUM, based on an optimized preheating and melting concept, delivers minimum conversion costs, maximized output, and environmental compliance. T A 2000’s value proposal is to offer its customers quality steel. T A 2000 has been granted with ISO 9001:2015 certification and above all the company focuses on offering an unparalleled service, characterized by competitive delivery times and optimal business conditions for the growth of its clients. T A 2000 is permanently committed to offering the market a dynamic, competitive and quality option. So that, the company have distribution centers in: Orizaba, Mérida; Arriaga, Silao and a commercial office in Mexico City.

Organisation images

Organisation logo

Product information

Product nameHot Rolled sheet manufactured from steel scrap by T A 2000
Product identification412
Product descriptionTYASA produces different types of hot-rolled sheet according to the following steel grades: Drawing Grade Commercial Grade Structural Grade High-strength Low-Alloy Steel Grade On the other hand, tension-leveling is a process that seeks to correct shape problems, such as waves or warps, in steel sheets by gently stretching them with specialized equipment. It is important to mention that hot-rolled sheet coils, sheets, and strips can be delivered tension-leveled and with trimmed edges, allowing for efficient use of material and reducing waste and sub-processes. Hot rolled sheet is manufactured by TYASA in coils, sheets, and strips, as follows: Hot-rolled steel coils/sheets/strips.
Product information from external sourceshttps://tyasa.com/
Technical purpose of productHot Rolled sheet, which is roughened at high temperatures, achieves specific dimensions and properties.
Manufacturing or service provision descriptionThe production of Hot Rolled Sheet by TYASA begins with the reception, weighing, and storage of steel scrap, which is preheated and subsequently melted in a Quantum electric arc furnace (EAF). Once molten, the steel is refined through the addition of ferroalloys and undergoes a vacuum degassing process to remove dissolved gases and impurities that could affect the material quality. The molten steel is solidified on rollers to form a continuous strip, which then passes through a mill to adjust its thickness (CASTRIP® process). The solidified strip is then processed in a hot rolling mill, where its thickness is further adjusted to meet specifications. Afterwards, the rolled steel is cooled under controlled conditions and coiled, resulting in a hot-rolled coil that is not sold but used as raw material for final products. This coil undergoes a tension-leveling process, where internal stresses that could cause tearing during a subsequent rolling operation to reduce thickness are eliminated. Finally, a shear cuts the sheet to the desired dimensions, and the processed material is recoiled. Depending on the final product specifications, two types of products can be obtained: Tension leveled hot-rolled coil and Tension leveled hot rolled floor plate coil, which includes an additional surface treatment to provide slip resistance. To produce tension leveled hot rolled cut-to-length sheets and tension leveled floor plate cut-tolength sheets, the corresponding coils are processed in the cutting line. On the other hand, to produce Hot rolled strips, the hot-rolled coil is fed into the slitter line, where it is longitudinally trimmed to reduce its width and achieve the desired dimensions.
Material propertiesVolumetric mass density: 7850 kg/m3
Volumetric mass density:
7850 kg/m3
Manufacturing siteT A 2000 S.A. ORIZABA Mexico Veracruz 94450 Carretera Federal México-Veracruz Km. 321, s/n, interior 2, Ixtaczoquitlán
UN CPC code412. Products of iron or steel
Geographical scopeGlobal
Geographical scope descriptionThe raw materials are produced in several continents.

Product images

Technical characteristics and performance

Technical performance

Product nameType of steelApplicable regulations
Hot Rolled Sheet/Coil/Strip SAE J403 1008G1008SAE J403
Hot Rolled Sheet/Coil/Strip Commercial Steel (CS) Type A, BCommercial Steel TA & TBASTM A1011
Hot Rolled Sheet/Coil/Strip Commercial Steel (CS) Type A, B & DCommercial Steel TA, TB & TDASTM A1039
Hot Rolled Sheet/Coil/Strip Drawing Steel (DS) Type A, BDrawing SteelASTM A1011
Hot Rolled Sheet/Coil/Strip Drawing Steel (DS) Type A, B, DDrawing Steel TA, TBASTM A1039
Hot Rolled Sheet/Coil/Strip Structural Steel (SS) 55, 50, 36 Type 1 and 33Structural SteelASTM A1011
Hot Rolled Sheet/Coil/Strip High-Strength Low-Alloy Steel (HSLAS) 50, 55, 60HSLAS 50, 55 60 Class 1, 2ASTM A1011
Hot Rolled Sheet/Coil/Strip High-Strength Low-Alloy Steel (HSLAS) 50, 55, 60HSLAS 50, 55 60 Class 1, 2ASTM A1039
Hot Rolled Sheet/Coil/Strip Steel Floor PlatesPattern 2ASTM A786

Content declaration

Content declaration of multiple productsThis EPD covers multiple products. The content declaration corresponds to a representative average, calculated based on the production-weighted contributions of each included product.
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
Scrap steel918.5495.2800
Dolomitic lime37.2800
Steelmaking lime35.4900
Others8.6900
Total100095.2800
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
kraft0.0110.0010
wood0.6110.0610
steel0.0770.0080
plastic0.0020.00020
Total0.7010.07020
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 flow1000 kg of Hot Rolled Sheet manufactured from steel scrap during the year 2022 by TYASA at the Ixtaczoquitlán plant, used by various industrial sector Mass: 1000 kg
Conversion factor to mass1
Are infrastructure or capital goods included in any upstream, core or downstream processes?
Datasources used for this EPDecoinvent database (general) ecoinvent 3.10 database
LCA SoftwareSimaPro SimaPro 9.6
Version of the EN 15804 reference packageEF Reference Package 3.1
Characterisation methodsGlobal Warming Potential,GWP100 , EN 15804. Version: EF 3.1, February 2023. Acidification potential, AP, accumulated exceedence, EN 15804.Version: February 2023. Eutrophication potential (EP) Version 2.0 of the default list of indicators (valid from 2022-03-29). Photochemical ozone creation potential (POCP), POCP, LOTOSEUROS applied in ReCiPe, EN 15804. Version: February 2023. Ozone depletion potential (ODP), EN 15804. Version: February 2023. Abiotic depletion potential (ADP) for minerals and metals (non-fossil resources), ADP minerals & metals, EN 15804. Version: February 2023. Abiotic depletion potential (ADP) for fossil resources, ADP fossil resources, EN 15804. Version: August 2021. Water deprivation potential (WDP), (Available water remaining (AWARE) method), EN 15804.
Technology description including background systemHot-rolled steel sheet manufactured by TYASA is produced using steel scrap as the primary raw material. The product is supplied in coils, sheets, and strips, and is available in various steel grades, including drawing, commercial, structural, and high-strength low-alloy grades. The manufacturing process starts with the reception, preparation, and melting of steel scrap in an electric arc furnace (EAF). The molten steel is subsequently refined, degassed, and cast into a continuous strip through the CASTRIP® process. This strip is then hot-rolled to the specified thickness, cooled under controlled conditions, and coiled to produce the hot-rolled coil that serves as feedstock for downstream processing. Depending on the final product specifications, the coil may undergo a tension-leveling process to relieve internal stresses and improve flatness. The material can then be cut to length or slit to obtain sheets or strips with the required dimensions.
Scrap (recycled material) inputs contribution levelMore than 10% of the GWP-GHG results in modules A1-A3 come from scrap inputs
Scrap (recycled material) inputs data
Material scrap nameMaterial scrap value
Scrap steel316, kg CO2 eq./tonne
The share of the total scrap input that was assumed to come with an environmental burden100%

Data quality assessment

Description of data quality assessment and reference yearsDirect data obtained from T A 2000 S.A. de C.V. is representative for 2022. According to ISO 14044, data validity verified during the collection process to provide evidence that the quality criteria required for the intended application are met. The data quality level and criteria used were based on the Product Category Rules (GPI 5.0.1, section A.5.4), the EN 15804:2012+A2:2019/AC:2021 standard (Annex E), and the PCR Construction Products v2.0.1, section 4.6.5.Data quality assessment was carried out using the following quality levels: very good, good, fair, poor, and very poor.
Data quality assessment
Process nameSource typeSourceReference yearData categoryShare of primary data, of GWP-GHG results for A1-A3
Extraction and processing of raw materials required for the manufacturing of productsCollected dataEPD owner2022Primary data99%
Generation and distribution of electricity, based on the regional average of the consumption area.Collected dataEPD owner2022Primary data1%
Total share of primary data, of GWP-GHG results for A1-A3100%
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 mixSpecific electricity mix as generated, or purchased from an electricity supplier, demonstrated by a contractual instrument
Energy sourcesHydro13.75%
Wind5.11%
Solar4.26%
Biomass0%
Geothermal1.02%
Waste0%
Nuclear3.43%
Natural gas67.39%
Coal4.45%
Oil0.58%
Peat0%
Other0.01%
GWP-GHG intensity (kg CO2 eq./kWh)0.41 kg CO2 eq./kWh

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 modulesA4, A5 and B module: 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
GeographyGlobalGlobalMexicoN/AN/AN/AN/AN/AN/AN/AN/AN/AMexicoMexicoMexicoMexicoMexico
Share of specific data90%--------------
Variation - products10%--------------
Variation - sites0%--------------
DisclaimerThe share of specific/primary data and both variations (products and sites) refer to GWP-GHG results only.

Process flow diagram(s) related images

Default scenario

Name of the default scenarioEnd of life default scenario
Description of the default scenarioIn this study, the end-of-life treatment was modelled based on a scenario in which 98% of the steel is recovered and recycled, while the remaining 2% is sent to landfill.

Module C: End-of-life

Explanatory name of the default scenario in module CRecycling and landfill
Brief description of the default scenario in module CDemolition of 1 tonne of steel, 98% steel recycled and 2% landfilled disposed
Module C informationValueUnit
C1) Demolition/deconstruction of steel1.1
kWh
C2) Transport (for products/materials not to be incinerated)80
km
C3) Loading and unloading at sorting facility1.8
kWh
C3) Mechanical sorting2.2
kWh
C3) Fragging of steel7.4
kWh
C4) Compacting inert construction waste for landfills1.6
kWh

Module D: Beyond product life cycle

Explanatory name of the default scenario in module DResource recovery stage
Brief description of the default scenario in module DBenefits from substituting virgin steel with recycled scrap, avoiding related impacts
Module D informationValueUnit
Amount of scrap content existing the system.98
%
Amount of scrap or recycled material contained in the product beyond the system boundary.92
%

Additional scenario 1

Name of the additional scenarioEnd-of-life scenario: 100% recycling
Description of the additional scenarioIn this alternative escenario, the end-of-life treatment was modelled based on a scenario in which 100% of the steel is recovered and recycled.

Module C: End-of-life

Description of the additional scenario in module C100% steel recycling: loading and unloading at a sorting facility, and mechanical sorting and fragmentation.
Module C informationValueUnit
C1) Demolition/deconstruction of steel1.1
kWh
C2) Transport (for products/materials not to be incinerated)80
km
C3) Loading and unloading at sorting facility1.8
kWh
C3) Mechanical sorting2.2
kWh
C3) Fragging of steel7.4
kWh

Module D: Beyond product life cycle

Description of the additional scenario in module DModule D does not present an alternative scenario.

Additional scenario 2

Name of the additional scenarioEnd-of-life scenario: 100% landfill
Description of the additional scenarioIn this alternative scenario, the end-of-life treatment was modelled assuming that 100% of the steel is sent to landfill.

Module C: End-of-life

Description of the additional scenario in module C100% landfilled after demolition, including compaction of inert construction waste at landfill.
Module C informationValueUnit
C1)Demolition/deconstruction of steel1.1
kWh
C2)Transport (for products/materials not to be incinerated)80
km
C4)Compacting of inert construction waste for landfills1.6
kWh

Module D: Beyond product life cycle

Description of the additional scenario in module DModule D does not present an alternative scenario.

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.8.09E+2NDNDNDNDNDNDNDNDND3.72E-11.22E+13.94E+01.08E-2-1.11E+2
Climate change - fossilGWP-fossilkg CO2 eq.8.09E+2NDNDNDNDNDNDNDNDND3.72E-11.22E+13.94E+01.08E-2-1.11E+2
Climate change - biogenicGWP-biogenickg CO2 eq.1.47E-1NDNDNDNDNDNDNDNDND1.60E-55.83E-41.74E-44.66E-7-6.75E-3
Climate change - land use and land-use changeGWP-luluckg CO2 eq.1.62E-1NDNDNDNDNDNDNDNDND1.28E-53.99E-41.14E-43.72E-7-1.16E-2
Ozone depletionODPkg CFC-11 eq.1.41E-5NDNDNDNDNDNDNDNDND5.85E-91.78E-77.11E-81.70E-10-2.43E-7
AcidificationAPmol H+ eq.3.05E+0NDNDNDNDNDNDNDNDND3.48E-34.62E-23.01E-21.01E-4-3.49E-1
Eutrophication aquatic freshwaterEP-freshwaterkg P eq.9.43E-3NDNDNDNDNDNDNDNDND3.51E-72.96E-51.05E-51.02E-8-3.67E-3
Eutrophication aquatic marineEP-marinekg N eq.1.07E+0NDNDNDNDNDNDNDNDND1.63E-31.89E-21.37E-24.75E-5-7.07E-2
Eutrophication terrestrialEP-terrestrialmol N eq.1.17E+1NDNDNDNDNDNDNDNDND1.79E-22.07E-11.51E-15.21E-4-8.27E-1
Photochemical ozone formationPOCPkg NMVOC eq.3.90E+0NDNDNDNDNDNDNDNDND5.33E-36.71E-24.56E-21.55E-4-2.84E-1
Depletion of abiotic resources - minerals and metalsADP-minerals&metals1kg Sb eq.1.71E-4NDNDNDNDNDNDNDNDND1.55E-87.26E-71.38E-74.52E-10-1.61E-5
Depletion of abiotic resources - fossil fuelsADP-fossil1MJ, net calorific value1.17E+4NDNDNDNDNDNDNDNDND4.90E+01.65E+25.48E+11.42E-1-1.03E+3
Water useWDP1m3 world eq. deprived1.06E+2NDNDNDNDNDNDNDNDND3.86E-31.49E-11.10E-11.12E-4-6.79E+0
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.8.09E+2NDNDNDNDNDNDNDNDND3.72E-11.22E+13.94E+01.08E-2-1.11E+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 incidence9.48E-5NDNDNDNDNDNDNDNDND9.98E-88.50E-78.20E-72.90E-9-9.76E-6
Ionizing radiation - human healthIRP1kBq U235 eq.1.84E+1NDNDNDNDNDNDNDNDND4.38E-41.12E-25.24E-21.27E-5-2.38E-1
Eco-toxicity - freshwaterETP-fw2CTUe3.83E+3NDNDNDNDNDNDNDNDND1.69E-11.07E+11.54E+04.93E-3-4.00E+3
Human toxicity - cancer effectsHTP-c2CTUh1.16E-5NDNDNDNDNDNDNDNDND3.69E-108.12E-84.21E-91.07E-11-2.39E-7
Human toxicity - non-cancer effectsHTP-nc2CTUh3.37E-6NDNDNDNDNDNDNDNDND2.59E-111.03E-92.41E-107.54E-13-1.14E-5
Land-use related impacts/soil qualitySQP2Dimensionless3.49E+2NDNDNDNDNDNDNDNDND1.04E-26.58E-11.78E-13.02E-4-1.15E+2
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 value8.77E+2NDNDNDNDNDNDNDNDND1.10E-22.68E-17.20E+03.19E-4-1.05E+1
PERMMJ, net calorific value1.17E+1NDNDNDNDNDNDNDNDND0.00E+00.00E+0-4.46E+00.00E+00.00E+0
PERTMJ, net calorific value8.89E+2NDNDNDNDNDNDNDNDND1.10E-22.68E-12.74E+03.19E-4-1.05E+1
PENREMJ, net calorific value1.25E+4NDNDNDNDNDNDNDNDND5.20E+01.75E+21.22E+21.51E-1-1.10E+3
PENRMMJ, net calorific value1.67E+2NDNDNDNDNDNDNDNDND0.00E+00.00E+0-6.34E+10.00E+00.00E+0
PENRTMJ, net calorific value1.27E+4NDNDNDNDNDNDNDNDND5.20E+01.75E+25.88E+11.51E-1-1.10E+3
SMkg9.19E+2NDNDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+00.00E+0
RSFMJ, net calorific value0.00E+0NDNDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+00.00E+0
NRSFMJ, net calorific value0.00E+0NDNDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+00.00E+0
FWm32.98E+0NDNDNDNDNDNDNDNDND1.54E-46.16E-32.85E-34.47E-6-1.78E-1
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
HWDkg6.07E-2NDNDNDNDNDNDNDNDND3.36E-51.13E-33.32E-49.77E-7-1.19E-2
NHWDkg7.74E+0NDNDNDNDNDNDNDNDND1.43E-46.92E-31.93E-34.16E-6-6.88E-1
RWDkg8.39E-3NDNDNDNDNDNDNDNDND2.50E-75.81E-62.09E-57.28E-9-1.51E-4
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
MFRkg2.03E+0NDNDNDNDNDNDNDNDND0.00E+00.00E+09.80E+20.00E+00.00E+0
MERkg0.00E+0NDNDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+00.00E+0
EEEMJ, net calorific value0.00E+0NDNDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+00.00E+0
EETMJ, net calorific value0.00E+0NDNDNDNDNDNDNDNDND0.00E+00.00E+00.00E+00.00E+00.00E+0
AcronymsCRU = Components for re-use; MFR = Materials for recycling; MER = Materials for energy recovery; EEE = Exported electrical energy; EET = Exported thermal energy.
General disclaimerThe results of the end-of-life stage (modules C1-C4) should be considered when using the results of the product stage (modules A1-A3/A1-A5 for services).

Results for additional scenarios for modules A4-C4

Additional scenarioEnd-of-life scenario: 100% recycling
Description of the scenario/methodIn this alternative scenario, the end-of-life treatment was modelled assuming that 100% of the steel is recovered and recycled.
Results for additional scenarios for modules A4-C4
Impact categoryIndicatorUnitA1-A3A4A5B1B2B3B4B5B6B7C1C2C3C4D
Climate change - totalGWP-totalkg CO2 eq.NDNDNDNDNDNDNDNDNDND3.72E-11.22E+14.02E+0NDND
Climate change - fossilGWP-fossilkg CO2 eq.NDNDNDNDNDNDNDNDNDND3.72E-11.22E+14.02E+0NDND
Climate change - biogenicGWP-biogenickg CO2 eq.NDNDNDNDNDNDNDNDNDND1.60E-55.83E-41.78E-4NDND
Climate change - land use and land-use changeGWP-luluckg CO2 eq.NDNDNDNDNDNDNDNDNDND1.28E-53.99E-41.16E-4NDND
Ozone depletionODPkg CFC-11 eq.NDNDNDNDNDNDNDNDNDND5.85E-91.78E-77.25E-8NDND
AcidificationAPmol H+ eq.NDNDNDNDNDNDNDNDNDND3.48E-34.62E-23.08E-2NDND
Eutrophication aquatic freshwaterEP-freshwaterkg P eq.NDNDNDNDNDNDNDNDNDND3.51E-72.96E-51.07E-5NDND
Eutrophication aquatic marineEP-marinekg N eq.NDNDNDNDNDNDNDNDNDND1.63E-31.89E-21.40E-2NDND
Eutrophication terrestrialEP-terrestrialmol N eq.NDNDNDNDNDNDNDNDNDND1.79E-22.07E-11.54E-1NDND
Photochemical ozone formationPOCPkg NMVOC eq.NDNDNDNDNDNDNDNDNDND5.33E-36.71E-24.66E-2NDND
Depletion of abiotic resources - minerals and metalsADP-minerals&metals1kg Sb eq.NDNDNDNDNDNDNDNDNDND1.55E-87.26E-71.41E-7NDND
Depletion of abiotic resources - fossil fuelsADP-fossil1MJ, net calorific valueNDNDNDNDNDNDNDNDNDND4.90E+01.65E+25.59E+1NDND
Water useWDP1m3 world eq. deprivedNDNDNDNDNDNDNDNDNDND3.86E-31.49E-11.12E-1NDND
Acronyms
Disclaimers1 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.
General disclaimerThe results of the end-of-life stage (modules C1-C4) should be considered when using the results of the product stage (modules A1-A3/A1-A5 for services).

Results for additional scenarios for modules A4-C4

Additional scenarioEnd-of-life scenario: 100% landfill
Description of the scenario/methodIn this alternative scenario, the end-of-life treatment was modelled assuming that 100% of the steel is sent to landfill.
Results for additional scenarios for modules A4-C4
Impact categoryIndicatorUnitA1-A3A4A5B1B2B3B4B5B6B7C1C2C3C4D
Climate change - totalGWP-totalkg CO2 eq.NDNDNDNDNDNDNDNDNDND3.72E-11.22E+1ND5.41E-1ND
Climate change - fossilGWP-fossilkg CO2 eq.NDNDNDNDNDNDNDNDNDND3.72E-11.22E+1ND5.41E-1ND
Climate change - biogenicGWP-biogenickg CO2 eq.NDNDNDNDNDNDNDNDNDND1.60E-55.83E-4ND2.33E-5ND
Climate change - land use and land-use changeGWP-luluckg CO2 eq.NDNDNDNDNDNDNDNDNDND1.28E-53.99E-4ND1.86E-5ND
Ozone depletionODPkg CFC-11 eq.NDNDNDNDNDNDNDNDNDND5.85E-91.78E-7ND8.51E-9ND
AcidificationAPmol H+ eq.NDNDNDNDNDNDNDNDNDND3.48E-34.62E-2ND5.06E-3ND
Eutrophication aquatic freshwaterEP-freshwaterkg P eq.NDNDNDNDNDNDNDNDNDND3.51E-72.96E-5ND5.11E-7ND
Eutrophication aquatic marineEP-marinekg N eq.NDNDNDNDNDNDNDNDNDND1.63E-31.89E-2ND2.38E-3ND
Eutrophication terrestrialEP-terrestrialmol N eq.NDNDNDNDNDNDNDNDNDND1.79E-22.07E-1ND2.61E-2ND
Photochemical ozone formationPOCPkg NMVOC eq.NDNDNDNDNDNDNDNDNDND5.33E-36.71E-2ND7.75E-3ND
Depletion of abiotic resources - minerals and metalsADP-minerals&metals1kg Sb eq.NDNDNDNDNDNDNDNDNDND1.55E-87.26E-7ND2.26E-8ND
Depletion of abiotic resources - fossil fuelsADP-fossil1MJ, net calorific valueNDNDNDNDNDNDNDNDNDND4.90E+01.65E+2ND7.12E+0ND
Water useWDP1m3 world eq. deprivedNDNDNDNDNDNDNDNDNDND3.86E-31.49E-1ND5.62E-3ND
Acronyms
DisclaimersThe 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
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

Tyasa has an Implementation Plan for the Environmental Management System for ISO 14001 with a progress of 75%, led by the Management Systems Department.

Information related to EPDs of multiple products

Description of how the averages have been determinedThe average value was determined by considering the included products and applying a weighting based on their respective production volumes.

Abbreviations

CADIS Centre for Life Cycle Assessment and Sustainable Design

CENACE National Center for Energy Control

EAF Electric arc furnace

EPD Environmental Product Declaration

GHG Greenhouse gases

GPI General Programme Instructions

GWP Global Warming Potential

LCA Life Cycle Assessment

PCR Product Category Rules

References

BIEE. (2023). Base de Indicadores de Eficiencia Energética de México. Obtained from https://www.biee-conuee.net/site/index.php

Coto, G., Rosa, E., Solano, A., & Zaragoza, D. (2025), Life Cycle Assessment of Hot Rolled sheet manufactured from steel scrap by T A 2000, Center for Life Cycle Assessment and Sustainable Design – CADIS.

European Committee for Standardization. (2019). Sustainability of construction works — Environmental product declarations — Core rules for the product category of construction products (EN 15804:2012+A2:2019). CEN.

Frischknecht Rolf. (2007). Implementation of Life Cycle Impact Assessment Methods. Ecoinvent report No. 3.

Huijbregts, M. A., Steinmann, Z. J., Elshout, P. M., Stam, G., Verones, F., Vieira, M. D., . . . van Zelm, R. (2017). ReCiPe 2016 v1.1. A harmonized life cycle impact assessment method at midpoint and endpoint level Report I: Characterization. Bilthoven, The Netherlands:National Institute for Public Health and the Environment.

IMNC. (2008). NMX-SAA-14040-IMNC Gestión ambiental - Análisis de ciclo de vida - Principios y marco de referencia. México, D.F.: IMNC.

ISO 14020. (2000). Environmental Labels and Declarations — General Principles.

ISO 14025. (2006). Type III Environmental Declarations.

ISO 14044. (2006). Environmental management - Life cycle assessment - Requirements and guidelines.

Mexican Institute of Steel Construction. (n.d.). Structural steel: The green construction material par excellence. https://www.imca.org.mx/newsletters/news14.php

PCR 2019:14 Construction Products V 2.0.1. (2025-06-05). EPD System. Obtained from https://www.environdec.com/

PCR 2019:14 Construction Products V 2.0.1. (2025-06-05). EPD System. Obtenido de https://www.environdec.com/

PRé Consultants. (2010). Data base manual. Methods library. Retrieved abril 20, 2010, from http://www.pre.nl/download/manuals/DatabaseManualMethods.pdf

PRé Sustainability. (2021). SimaPro database manual. Methods library.

The International EPD System (2025). General Programme Instructions for The International EPD System. Version 5.0.1 Published on 2025-02-27.

Version history

Version 001, 2025-12-22Original version of the EPDVersion 002, 2025-12-22 Corrected editorial mistakes.Version 003, 2026-01-13Corrected editorial mistakes.