Content uploaded by Orhan Atacan
Author content
All content in this area was uploaded by Orhan Atacan on Nov 02, 2020
Content may be subject to copyright.
www.mitasenergy.com
ENVIRONMENTAL
PRODUCT
DECLARATION
In accordance with ISO 14025 and EN 15804:2012+A2:2019 for
GFRP Composite Poles
from
MİTAŞ Composites
Programme: EPD Turkey, a fully aligned regional
programme www.epdturkey.org
The International EPD® System
www.environdec.com
Programme operator:
EPD Turkey:
SÜRATAM – Turkish Centre for
Sustainable Production Research &
Design
Nef 09 B Blok No:7/15
34415 Kağıthane/Istanbul, TURKEY
EPD International AB
EPD registration number: S-P-01917
Publication date: 21.09.2020
Validity date: 20.09.2025
Geographical scope: Global
2
Programme
EPD Turkey, a fully aligned
regional programme
SÜRATAM – Turkish Centre for Sustainable
Production Research & Design
Nef 09 B Blok No:7/15
34415 Kağıthane/Istanbul, TURKEY
www.epdturkey.org
info@epdturkey.org
The International EPD® System
EPD International AB
Box 210 60
SE-100 31 Stockholm
Sweden
www.environdec.com
info@environdec.com
Programme Information
Product Category Rules (PCR): 2019:14 Version 1.0, 2019-12-20, Construction Products and CPC 54
Construction Services, EN 15804:2012 + A2:2019 Sustainability of Construction Works
Independent third-party verification of the declaration and data, according to ISO 14025:2006:
EPD process certification X EPD verification
Third party verifier: Vladimír Kočí, PhD
Approved by: The International EPD® System
Procedure for follow-up of data during EPD validity involves third party verifier:
Yes X X No
The EPD owner has the sole ownership, liability, and responsibility for the EPD. EPDs within the same product
category but from different programmes may not be comparable. EPDs of construction products may not be
comparable if they do not comply with EN 15804.
3
Company
Information
Mitaş Composites Plastic Industry and Trade Inc. operates in its modern factory located in ASO 2nd Industrial
Zone in Ankara, Turkey. Commissioned in 2018 by Mitaş Energy and incorporated in 2019 to provide services to
all its customers by working on innovative composite products with its experienced staff in design, production
and assembly, and its environmentally friendly technologies, R&D capability and quality laboratories.
Our production facility uses filament winding method up to 12 m length and 1000 mm dimensions in its high-
quality and capacity computer-aided machines. Also, all the supporting operations from winding until the end
product can be done by the CNC machines within the facility. The facility is capable of using not only glass but
also advanced fibers like carbon and aramid together with polyester and epoxy resins. In the facility there is
also a pultrusion line which enables to produce any kind of cross sections (I, U, L, O, etc.) up to 1000x300 mm
continuously.
MİTAŞ Composites will continue to provide services to all its customers by working on innovative composite
products with its experienced staff in design, production and assembly, environmentally friendly technology,
R&D and quality laboratory.
The company has ISO 9001 Quality Management System, ISO 14001 Environmental Management System, ISO
45001 Occupational Health & Safety Management System Certifications.
4
Product name GFRP Composite Poles
Product identification Glass fibre reinforced polyester
resin matrix composite poles
UN CPC code 36310
Geographical scope Global
Our products can be classfied as follows:
- GFRP Composite poles
- GFRP Composite tubes
- GFRP Composite pipes
- GFRP Composite masts
- GFRP Composite profiles
Product
Information
*In the scope of this report, only the products composed of fiberglass fibres are considered.
Products Content : %25-40 Polyester Resine, %50-70 Glass Fiber, %1-3 other chemicals.
LOW WEIGHT ECO FRIENDLY ELECTRICALLY SLOW BURNING
NON-CONDUCTIVE
HEIGHT MECHANICAL UV PROTECTION WIDE RANGE EASY TRANSPORT
RESISTANCE OF COLORS AND ASSEMBLY
5
Filament Winding
Filament winding is a method of controlled winding
of the impregnated fibers on the desired pattern,
angle and thickness over a rotating mold, which
was coated with a release agent. After the product
is cured on the mold, it is removed from the mold
by a special machine. With this production method,
it is possible to obtain very strong and high-quality
products as the reinforcement ratio is high. In
addition, products with properties such as UV
resistance, hardness and fire resistance can be
developed with glass fibre additions to the resin
Composite products up to 12 m in length and 800 mm
in diameter are possible to produce with filament
winding method by its high-quality and capacity
computer-aided machines. Not only glass but also
advanced fibers like carbon and aramid together
with polyester or epoxy resin as the matrix are used
during the winding. Poles, pipes, towers, masts and
special products manufactured using winding method
by Mitaş Composite are compatible with the below
properties. The values are minimum required. The
tests are performed according to relevant EN ISO or
ASTM standards.
Properties Unit Test Method Polyester & Glass Fiber
Mechanical
Tensile Modulus- (longitudinal) GPa EN ISO 527-4 7
Tensile Strength- (longitudinal) MPa EN ISO 527-4 110
Bending Strength- (longitudinal) MPa EN ISO 14125 200
Bending Modulus- (longitudinal) GPa EN ISO 14125 11
Physical
Barcol Hardness - ASTM D2583 45
Flammability
Flammability Classification - UL 94 V0
Technical Properties
6
Pultrusion
Profiles with any cross sections up to
1000 mm width and 200 mm height
are possible with pultrusion method in
any requested color. Standard profiles
for linear pultrusion, which include L,
U, Box, Pipe and sheet sections are
compatible with the below properties.
The properties are minimum required
values for pultrusion profiles. The tests
are performed according to EN ISO or
ASTM standards.
Properties Unit Test Method E23 E17
Mechanical
Modulus of Elasticity GPa Annex D, EN 13706-2 23 17
Tensile Modulus- (longitudinal) GPa EN ISO 527-4 17 23
Tensile Modulus- transverse GPa EN ISO 527-4 7 5
Tensile Strength- (longitudinal) MPa EN ISO 527-4 240 170
Tensile Strength- transverse MPa EN ISO 527-4 50 30
Bending Strength- (longitudinal) MPa EN ISO 14125 240 170
Bending Strength- transverse MPa EN ISO 14125 100 70
Shear Strength- (longitudial) MPa EN ISO 14130 25 15
Physical
Barcol Hardness - ASTM D2583 45 45
Flammability
Flammability Classification - UL 94 V0 V0
Technical Properties
7
Declared unit 1 kg of glass fibre reinforced unsaturated polyester composite poles
Time Representativeness 2019
Database(s) and LCA Software Used TLCID ver. 1.0 (Turkish Lifecycle Inventory Database),
Ecoinvent 3.6, SimaPro 9.1
The inventory for the LCA study is based on the 2019 production figures for composite poles by Mitaş
Composites production plants in Ankara, Turkey.
LCA Information
System Boundary
A1
Raw Material
A2
Transport
Filament Winding
Winding
Curing
Demoulding
Sizing and shaving
Pultrusion
Material Feed
Mandrel setting
Resin preparation
Profile production
A3
Manufacturing
A4
Transport
A5
Assembly
C1
De-Construction
C2
Transport
C3
Waste
Processing
C4
Disposal
D
Benefits and
Loads
or
8
A1: Raw Material Supply
Production starts with raw materials. Raw material supply includes raw material extraction/preparation and
pre-treatment processes before production.
A2: Transportation
Transport is relevant for delivery of raw materials and other materials to the plant and the transport of
materials within the plant. Transport of raw materials to production site is taken as the weight average values
for transport from raw materials supplier in 2019.
A3: Manufacturing
Composites poles can be produced with 2 production technology as filament winding and pultrusion. Both
Manufacturings starts with the preparation of resin and fibres. In filament winding, production continues with
winding to mould in filament winding. After the curing process, the product is separated from the mould and
sized. In pultrusion, production continues with mandrel setting. After preparation resin mix, profile production
is started. The final products are quality checked and packaged for delivery.
A4: Transport From the Gate to the Site
Transport of final product to construction site is taken as the weight average values for transport to customers
in 2019.
Upstream
Core
Downstream
Other Environmental
Information
Raw Material Supply
Transport
Manufacturing
Transport
Construction Installation
Use
Maintenance
Repair
Replacement
Refurbishment
Operational Energy Use
Operational Water Use
Deconstruction, demolition
Transport
Waste Processing
Disposal
Future reuse, recycling or
energy recovery potentials
A1 A2 A3 A4 A5 B1 B2 B3 B4 B5 B6 B7 C1 C2 C3 C4 D
XXXXXMND MND MND MND MND MND MND XXXX X
Description of the system boundary (X = Included in LCA, MND= Module Not Declerated)
This EPD’s system boundary is cradle to gate with options, modules C1-C4 and module D. A4 Transport to
site and A5 Assembly stages were added as optional.
Description of System Boundary
9
The results of the LCA with the indicators as per EPD requirement are
given in the LCA result tables. All energy calculations were obtained
using Cumulative Energy Demand (LHV) methodology, while fresh
water use is calculated with selected inventory flows in SimaPro
according to the PCR.
There are no co-products in the production. Hence, there is no need
for co-product allocation.
Energy comsumptions and transports datasets were allocated
based on the production figures in 2019 and weighted averaged of
environmental impacts for the composite poles were presented.
Accordingly, hazardous and non-hazardous waste amounts were also
allocated from 2019 total waste arisings.
Composite utility poles are theoretically outlasting/lifetime products.
However, when they are scrapped or discarded, it is disposed as
per Waste Management Plan of Mitaş Composites in accordance
with laws and regulations. In accordance with the Turkish Waste
Regulation, solid wastes with code 07 02 14 are sent to a licensed
waste disposal company by licensed vehicles and disposed properly.
These wastes are disintegrated in RDF (refuse-derived fuel) units in
the waste disposal company and blended with other wastes and sent
to incineration in the cement plant as additional fuel.
No substances included in the Candidate List of Substances of Very High Concern for authorization under
the REACH regulations are present in composite poles, either above the threshold for registration with the
European Chemicals Agency or above 0.1 % (wt/wt).
More Information
A5: Assembly
This stage includes the installation of composite poles
in the construction site. For installing 1 composite pole
(average weight assumed as 40-50 kg), 20 minutes
installation time is assumed by using a mobile crane
with 92 kW engine. Also, while composite poles
are installation, some auxiliary materials may be
used such as metal plate, bolt or concrete. In this
declaration, 1 kg auxiliary metals using is assumed
for 1 composite pole.
C1 : Deconstruction and Demolition
For demolition 1 composite pole (average weight
assumed as 40-50 kg), 20 minutes installation time is
assumed by using a mobile crane with 92 kW engine.
C2 : Transport
This stage includes the transportation of the discarded
conductors to final disposal. Average distance from
demolition site to waste processing site for final
disposal is assumed to be 100 km.
C3 : Waste Processing
If the wastes are going to landfill or to be incinerated,
there is no need for any waste process.
C4 : Disposal
Disposal is the final stage of product life. Composite
poles may dispose with any disposal scenario after
construction and demolition as their final fate and
modelled as such for this EPD. It is assumed that 25%
of the wastes used as inert filler, 25% of the wastes
sent to the incineration and rest of the wastes send
to the landfill.
D : Benefits and Loads
In this stage, incineration and inert filler benefits
were calculated specified in the disposal stage.
10
LCA Results
11
Environmentals Impacts for 1 kg of GFRP Composite Poles Manufactured by Filament Winding
Impact
Category Unit A1-A3 A4 A5 C1 C2 C3 C4 D
GWP - Fossil kg CO2 eq 9.98 0.204 0.393 0.216 0.009 0 0.037 -0.009
GWP - Biogenic kg CO2 eq -245E-3 132E-6 1.10E-3 650E-6 6.60E-6 0 103E-3 -7.47E-6
GWP - Luluc kg CO2 eq 106E-3 53.5E-6 3.22E-3 1.92E-3 2.65E-6 0 2.65E-6 -5.40E-6
GWP - Total kg CO2 eq 9.8 0.204 0.398 0.219 0.009 0 0.139 -0.009
ODP kg CFC-11 eq 910E-9 47.6E-9 15.5E-9 8.20E-9 2.14E-9 0 1.80E-9 -1.82E-9
AP mol H+ eq 40.6E-3 993E-6 2.29E-3 1.27E-3 38.2E-6 0 107E-6 -91.0E-6
EP - Freshwater kg PO4 eq 2.98E-3 12.6E-6 349E-6 196E-6 643E-9 0 3.62E-6 1.39E-6
EP - Marine kg N eq 8.37E-3 305E-6 402E-6 218E-6 11.6E-6 0 180E-6 27.6E-6
EP - Terrestrial mol N eq 83.8E-3 3.35E-3 3.66E-3 1.96E-3 127E-6 0 493E-6 304E-6
POCP kg NMVOC 38.8E-3 1.01E-3 1.07E-3 547E-6 40.8E-6 0 150E-6 -85.0E-6
ADPE kg Sb eq 326E-6 2.93E-6 1.01E-6 266E-9 155E-9 0 81.8E-9 -227E-9
ADPF MJ 151 3.12 4.44 2.45 0.141 0 0.139 -0.133
WDP m3 depriv. 2.36 0.009 0.160 0.093 459E-6 0 0.003 -0.012
PM disease inc. 258E-9 15.7E-9 11.5E-9 4.98E-9 822E-12 0 1.27E-9 -891E-12
IR kBq U-235 eq 0.311 0.016 0.005 0.002 0.001 0 0.001 -0.001
ETP - FW CTUe 125 2.36 4.00 1.49 0.113 0 0.590 -0.139
HTTP - C CTUh 6.42E-9 56.4E-12 346E-12 28.1E-12 2.77E-12 0 65.2E-12 -6.82E-12
HTTP - NC CTUh 164E-9 2.79E-9 6.21E-9 1.54E-9 128E-12 0 456E-12 -142E-12
SQP Pt 41.3 3.08 1.12 0.596 0.162 0 0.244 -0.283
Acronyms GWP-total: Climate change, GWP-fossil: Climate change- fossil, GWP-biogenic: Climate change - biogenic, GWP-luluc: Climate change - land use
and transformation, ODP: Ozone layer depletion, AP: Acidification terrestrial and freshwater, EP-freshwater: Eutrophication freshwater, EP-marine:
Eutrophication marine, EP-terrestrial: Eutrophication terrestrial, POCP: Photochemical oxidation, ADPE: Abiotic depletion - elements, ADPF: Abiotic
depletion - fossil resources, WDP: Water scarcity, PM: Respiratory inorganics - particulate matter, IR: Ionising radiation, ETP-FW: Ecotoxicity
freshwater, HTP-c: Cancer human health effects, HTP-nc: Non-cancer human health effects, SQP: Land use related impacts, soil quality.
Legend A1: Raw Material Supply, A2: Transport, A3: Manufacturing, A1-A3: Sum of A1, A2, and A3, A4: Transport to Site, A5: Installation, C1: De-Construction,
C2: Waste Transport, C3: Waste Processing, C4: Disposal, D: Benefits and Loads Beyond the System Boundary.
12
Resource Use for 1 kg of GFRP Composite Poles Manufactured by Filament Winding
Impact
Category Unit A1-A3 A4 A5 C1 C2 C3 C4 D
PERE MJ 11.1 0.035 0.789 0.453 0.002 0 0.004 -0.003
PERM MJ 0 0000000
PERT MJ 11.1 0.035 0.789 0.453 0.002 0 0.004 -0.003
PENRE MJ 151 3.12 4.44 2.45 0.141 0 0.139 -0.133
PENRM MJ 0 0000000
PENRT MJ 151 3.12 4.44 2.45 0.141 0 0.139 -0.133
SM kg 0 0000000
RSF MJ 0 0000000
NRSF MJ 0 0000000
FW m353.9E-3 584E-6 1.79E-3 886E-6 29.4E-6 0 396E-6 -882E-6
Waste & Output Flows for 1 kg of GFRP Composite Poles Manufactured by Filament Winding
Impact
Category Unit A1-A3 A4 A5 C1 C2 C3 C4 D
HWD kg 0.120 0 0 0 0 0 0 0
NHWD kg 1.060000000
RWD kg 0 0000000
CRU kg 0 0000000
MFR kg 0 0000000
MER kg 0.289 0 0 0 0 0 0 0
EE (Electrical) MJ 0 0000000
EE (Thermal) MJ 0 0000000
Acronyms PERE: Use of renewable primary energy excluding resources used as raw materials, PERM: Use of renewable primary energy resources used as raw
materials, PERT: Total use of renewable primary energy, PENRE: Use of non-renewable primary energy excluding 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, SM: Secondary
material, RSF: Renewable secondary fuels, NRSF: Non-renewable secondary fuels, FW: Net use of fresh water, HWD: Hazardous waste disposed,
NHWD: Non-hazardous waste disposed, RWD: Radioactive waste disposed, CRU: Components for reuse, MFR: Material for recycling, MER: Materials
for energy recovery, EE (Electrical): Exported energy electrical, EE (Thermal): Exported energy, Thermal.
Legend A1: Raw Material Supply, A2: Transport, A3: Manufacturing, A1-A3: Sum of A1, A2, and A3, A4: Transport to Site, A5: Installation, C1: De-Construction,
C2: Waste Transport, C3: Waste Processing, C4: Disposal, D: Benefits and Loads Beyond the System Boundary.
Result per funtional declared unit
Biogenic Carbon Content Unit A1-A3
Biogenic carbon content in product kg C 0
Biogenic carbon content in packaging kg C 0.05
Note: It was assumed 50% of the wood packaging material is biogenic carbon.
13
Environmentals Impacts for GFRP Composite Poles Manufactured by Pultrusion
Impact
Category Unit A1-A3 A4 A5 C1 C2 C3 C4 D
GWP - Fossil kg CO2 eq 9.62 0.030 0.393 0.216 0.009 0 0.039 -0.009
GWP - Biogenic kg CO2 eq -45.1E-3 21.6E-6 1.10E-3 650E-6 6.60E-6 0 79.8E-3 -7.47E-6
GWP - Luluc kg CO2 eq 97.6E-3 8.68E-6 3.22E-3 1.92E-3 2.65E-6 0 2.20E-6 -5.40E-6
GWP - Total kg CO2 eq 9.67 0.030 0.398 0.219 0.009 0 0.119 -0.009
ODP kg CFC-11 eq 877E-9 6.99E-9 15.5E-9 8.20E-9 2.14E-9 0 1.61E-9 -1.82E-9
AP mol H+ eq 38.0E-3 125E-6 2.29E-3 1.27E-3 38.2E-6 0 95.4E-6 -91.0E-6
EP - Freshwater kg PO4 eq 2.86E-3 2.10E-6 349E-6 196E-6 643E-9 0 2.93E-6 1.39E-6
EP - Marine kg N eq 7.77E-3 38.0E-6 402E-6 218E-6 11.6E-6 0 147E-6 27.6E-6
EP - Terrestrial mol N eq 77.1E-3 415E-6 3.66E-3 1.96E-3 127E-6 0 444E-6 304E-6
POCP kg NMVOC 35.8E-3 134E-6 1.07E-3 547E-6 40.8E-6 0 133E-6 -85.0E-6
ADPE kg Sb eq 134E-6 507E-9 1.01E-6 266E-9 155E-9 0 68.6E-9 -227E-9
ADPF MJ 146 0.462 4.44 2.45 0.141 0 0.124 -0.133
WDP m3 depriv. 2.23 0.002 0.160 0.093 459E-6 0 0.003 -0.012
PM disease inc. 234E-9 2.69E-9 11.5E-9 4.98E-9 822E-12 0 1.14E-9 -891E-12
IR kBq U-235 eq 0.283 0.002 0.005 0.002 0.001 0 0.001 -0.001
ETP - FW CTUe 96.8 0.368 4.00 1.49 0.113 0 0.472 -0.139
HTTP - C CTUh 5.79E-9 9.07E-12 346E-12 28.1E-12 2.77E-12 0 59.6E-12 -6.82E-12
HTTP - NC CTUh 148E-9 419E-12 6.21E-9 1.54E-9 128E-12 0 374E-12 -142E-12
SQP Pt 22.8 0.530 1.12 0.596 0.162 0 0.218 -0.283
Acronyms GWP-total: Climate change, GWP-fossil: Climate change- fossil, GWP-biogenic: Climate change - biogenic, GWP-luluc: Climate change - land use
and transformation, ODP: Ozone layer depletion, AP: Acidification terrestrial and freshwater, EP-freshwater: Eutrophication freshwater, EP-marine:
Eutrophication marine, EP-terrestrial: Eutrophication terrestrial, POCP: Photochemical oxidation, ADPE: Abiotic depletion - elements, ADPF: Abiotic
depletion - fossil resources, WDP: Water scarcity, PM: Respiratory inorganics - particulate matter, IR: Ionising radiation, ETP-FW: Ecotoxicity freshwater,
HTP-c: Cancer human health effects, HTP-nc: Non-cancer human health effects, SQP: Land use related impacts, soil quality.
Legend A1: Raw Material Supply, A2: Transport, A3: Manufacturing, A1-A3: Sum of A1, A2, and A3, A4: Transport to Site, A5: Installation, C1: De-Construction,
C2: Waste Transport, C3: Waste Processing, C4: Disposal, D: Benefits and Loads Beyond the System Boundary.
14
Resource Use for 1 kg of GFRP Composite Poles Manufactured by Pultrusion
Impact
Category Unit A1-A3 A4 A5 C1 C2 C3 C4 D
PERE MJ 8.28 0.006 0.789 0.453 0.002 0 0.003 -0.003
PERM MJ 0 0000000
PERT MJ 8.28 0.006 0.789 0.453 0.002 0 0.003 -0.003
PENRE MJ 146 0.462 4.44 2.45 0.141 0 0.124 -0.133
PENRM MJ 0 0000000
PENRT MJ 146 0.462 4.44 2.45 0.141 0 0.124 -0.133
SM kg 0 0000000
RSF MJ 0 0000000
NRSF MJ 0 0000000
FW m348.2E-3 96.3E-6 1.79E-3 886E-6 29.4E-6 0 354E-6 -882E-6
Waste & Output Flows for GFRP Composite Poles Manufactured by Pultrusion
Impact
Category Unit A1-A3 A4 A5 C1 C2 C3 C4 D
HWD kg 0.120 0 0 0 0 0 0 0
NHWD kg 1.060000000
RWD kg 0 0000000
CRU kg 0 0000000
MFR kg 0 0000000
MER kg 0.289 0 0 0 0 0 0 0
EE (Electrical) MJ 0 0000000
EE (Thermal) MJ 0 0000000
Acronyms PERE: Use of renewable primary energy excluding resources used as raw materials, PERM: Use of renewable primary energy resources
used as raw materials, PERT: Total use of renewable primary energy, PENRE: Use of non-renewable primary energy excluding 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, SM: Secondary material, RSF: Renewable secondary fuels, NRSF: Non-renewable secondary fuels, FW: Net use of
fresh water, HWD: Hazardous waste disposed, NHWD: Non-hazardous waste disposed, RWD: Radioactive waste disposed, CRU:
Components for reuse, MFR: Material for recycling, MER: Materials for energy recovery, EE (Electrical): Exported energy electrical, EE
(Thermal): Exported energy, Thermal.
Legend A1: Raw Material Supply, A2: Transport, A3: Manufacturing, A1-A3: Sum of A1, A2, and A3, A4: Transport to Site, A5: Installation, C1: De-Construction,
C2: Waste Transport, C3: Waste Processing, C4: Disposal, D: Benefits and Loads Beyond the System Boundary.
Result per funtional declared unit
Biogenic Carbon Content Unit A1-A3
Biogenic carbon content in product kg C 0
Biogenic carbon content in packaging kg C 0
Note: It was assumed 50% of the wood packaging material is biogenic carbon.
15
/GPI/ General Programme Instructions of the International EPD® System. Version 3.0.
/ISO 9001:2015/ Quality management systems - Requirements
/ISO 14001/ Enviroment Management System- Requirements
/ISO 45001/ Occupational Health and Safety- Requirements
/ISO 14020:2000/ Environmental labels and declarations — General principles
/EN 15804:2012+A2:2019/ Sustainability of construction works - Environmental Product Declarations — Core
rules for the product category of construction products
/ISO 14025/ DIN EN ISO 14025:2009-11: Environmental labels and declarations - Type III environmental
declarations — Principles and procedures
/ISO 14040/44/ DIN EN ISO 14040:2006-10, Environmental management - Life cycle assessment - Principles
and framework (ISO14040:2006) and Requirements and guidelines (ISO 14044:2006)
/PCR for Construction Products and CPC 54 Construction Services/ Prepared by IVL Swedish Environmental
Research Institute, Swedish Environmental Protection Agency, SP Trä, Swedish Wood Preservation Institute,
Swedisol, SCDA, Svenskt Limträ AB, SSAB, The International EPD System, 2019:14 Version 1.1 DATE 2019-12-20
/The International EPD® System/ The International EPD® System is a programme for type III environmental
declarations, maintaining a system to verify and register EPD®s as well as keeping a library of EPD®s and
PCRs in accordance with ISO 14025. www.environdec.com
/Ecoinvent / Ecoinvent Centre, www.ecoinvent.org
/SimaPro/ SimaPro LCA Software, Pré Consultants, the Netherlands, www.pre-sustainability.com
/TLCID/ Turkish Life Cycle Inventory Database, Turkish Center for Sustainable Production Research and
Design (SURATAM), www.suratam.org
References
16
Programme
EPD registered through fully aligned
regional programme:
EPD Turkey:
www.epdturkey.org
The International EPD® System
www.environdec.com
Programme
operator
EPD Turkey:
SÜRATAM – Turkish Centre for Sustainable
Production Research & Design
Nef 09 B Blok No:7/15,
34415 Kağıthane / Istanbul, TURKEY
www.epdturkey.org
info@epdturkey.org
EPD International AB
Box 210 60
SE-100 31 Stockholm, Sweden
www.environdec.com
info@environdec.com
Owner of the
declaration Mitaş Kompozit Plastik Sanayi ve Tic. A.Ş.
ASO 2.OSB Alcı OSB Mh. 2001.Cad. No:16
06930 Sincan / ANKARA, Turkey
Contact: Gülcan Çetin
Team Leader, Quality
Phone: (+90) 312 296 23 59
Fax: (+90) 312 296 29 99
www.mitascomposites.com
info@mitascomposites.com
LCA practitioner Turkey:
Lalegül Sok. No:7/18 Kağıthane
34415 4. Levent – Istanbul, Turkey
+90 212 281 13 33
United Kingdom:
4 Clear Water Place
Oxford OX2 7NL, UK
0 800 722 0185
www.metsims.com
info@metsims.com
3rd party verifier
Vladimír Kocí, PhD
LCA Studio
Šárecká 5,16000
Prague 6 - Czech Republic
www.lcastudio.cz
Contact Information
17
Mitaş Kompozit Plastik Sanayi ve Ticaret A.Ş.
ASO 2.OSB Alcı OSB Mah. 2001. Cad. No: 16 06930 Sincan,
Ankara/ TURKEY
P:+90 312 296 25 48 • F:+90 312 296 29 99
www.mitascomposites.com • info@mitascomposites.com