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#radicigroup
RADICIGROUP &
SUSTAINABILITY PRODUCT
VISION AND MISSION
VISION
• To be one of the leading chemical groups in the polyamide, synthetic fibres and engineering plastics production chain.
MISSION
• To promote the development of our businesses while pursuing our Group values and culture.
• To pursue our vision by valorising and optimizing our resources, establishing strategic alliances and searching for new markets, including niche markets.
• To embed sustainability into new product and application development.
THE RADICIGROUP KEY NUMBERS
• Specialty Chemicals = EUR 439 million
• Performace Plastics = EUR 360 million
• Synthetic Fibres & Nonwovens = EUR 451 million
• Other businesses = EUR 10 million
2017 SALES - consolidated for each Business Areas (Millions of Euro)
RADICIGROUP SINERGY & INTEGRATION
PRODUCTS WITH A LIMITED ENVIRONMENTAL IMPACT
AN ALL ROUND APPROACH TO SUSTAINABILITY
EnvironmentalSustainability
EconomicSustainability
LabourSustainability
Human RightsProduct
SustainabilitySocial
Sustainability
MEASUREMENT OF PRODUCT IMPACT
Life Cycle Assessment – LCA(ISO 14040 series) a methodology/tool for LIFE CYCLE ANALYSIS
A Life Cycle Assessment is defined by ISO 14040 as:“Compilation and evaluations of the inputs, outputs and potential environmental impacts of a product system throughout its life cycle”
To learn more: https://www.iso.org/standard/37456.html
LIFE CYCLE ASSESSMENT
IMPACT CATEGORY# Environmental Footprint impact category Indicators Environmental footprint impact evaluationi model
1Consumption of primary energy resources (GER
– Gross Energy Requirement)MJ Cumulative Energy Demand
2Climate change (GWP100 – Global Warming
Potential)Kg CO2 eq
Berna Model – Global Warming Potential over a 100 year
period
3Reduction in ozone layer (OD – Ozone
Depletion)
Kg CFC-11
eq
Modello EDIP model based on the ozone depletion
potentials of the World Meteorological Organisation
4 Photochemical Ozone Formation Kg NMVOC LOTOS-EUROS model
5 Acidification Mol H+eq Accumulated excess model
6 Terrestrial Eutrophication Mol N eq Accumulated excess model
8 Marine Eutrophication Kg N eq EUTREND model
9 Human Toxicity – cancer effects CTUh USEtox model
10 Human Toxicity – non cancer effects CTUh USEtox model
11 Ecotoxicity CTUe USEtox model
12 Particulate Matter/Respiratory Inorganics kg PM 2.5 eq RiskPoll model
13 Ionizing radiation CTUe Effects on human health model
14 Land Use Kg C deficit Model of organic material content of the soil
15 Water Resource Depletion m3 water eq Swiss model for environmental scarcity
16 Mineral, fossil & ren resource depletion Kg Sb eq CML 2002 model
PRODUCT ENVIRONMENTAL FOOTPRINT (PEF)OF AN ARTICLE OF CLOTHING WITH A MADE IN ITALY LABEL
HERNO MEN’S JACKET
PEF OF A MAN’S JACKET
EPD ON CIRCULAR ECONOMY
Our EPDs:Primary Grade, Recycling, Industrial Grade
Impact category Unit Total upstream core downstream
Acidification (fate not incl.) kg SO2 eq 4,52E-03 3,26E-03 2,00E-04 1,05E-03
Eutrophication kg PO4--- eq 9,45E-04 6,85E-04 9,24E-05 1,67E-04
Global warming (GWP100a) kg CO2 eq 6,81E-01 4,72E-01 4,72E-02 1,61E-01
Photochemical oxidation kg C2H4 eq 1,75E-04 1,26E-04 1,20E-05 3,68E-05
Impact category Unit Total upstream core downstreamAcidification (fate not incl.) kg SO2 eq 1,69E-02 1,51E-02 8,66E-04 9,09E-04Eutrophication kg PO4--- eq 4,21E-03 3,88E-03 1,63E-04 1,68E-04Global warming (GWP100a) kg CO2 eq 5,54E+00 5,25E+00 1,04E-01 1,84E-01Photochemical oxidation kg C2H4 eq 8,55E-04 7,89E-04 3,30E-05 3,29E-05
100% efficiency of raw materials through internal or controlled recycling
EPD ON CIRCULAR ECONOMY
0,00E+00
1,00E+00
2,00E+00
3,00E+00
4,00E+00
5,00E+00
6,00E+00
kg CO2 eq kg CO2 eq
Radilon A RV300 Heramid A GF030 /1k
GLOBAL WARMING
0,00E+00
5,00E-04
1,00E-03
1,50E-03
2,00E-03
2,50E-03
3,00E-03
3,50E-03
4,00E-03
4,50E-03
kg PO4--- eq kg PO4--- eq
Radilon A RV300 Heramid A GF030 /1k
EUTROPHICATION
PRIMARY GRADE VS INDUSTRIAL GRADETHROUGH OUR RECYCLING SERVICES
EPD ON CIRCULAR ECONOMY
MAXIMIZING UTILITY OF EXISTING MOLECULES
12,48
3,23
15,72
Energy amount necessary to produce 1 kg of polyamide polymer coming at
100% from post-industrial 30% glassfibre waste
MECHANICAL RECYCLING
Energy amount necessary to produce 1 kg of polyamide polymer coming at 50%
from post-industrial waste and at 50% from post consumer waste.
CHEMICAL RECYCLING
55
8
63
CIRCULAR ECONOMY@RADICIGROUP
What comes out from our contactswith apparel brands is the importance of synergy of the plastics & fibres areas, a strategic strong point.
FIBRES & PLASTICS SYNERGY
“100% Nylon for the eco-design of the
materials of the future”
“100% Nylon for the eco-design of the
materials of the future”
MacArthur Foundation
GRI 302-3
ENERGY INTENSITY
2015 2016 2017
GJ TOTAL PRIMARY ENERGY (GRI302-1) 6304085,825 6.178.598 6.611.640
€ TOTAL NET ADDED VALUE 183.484.576 206.279.587 258.860.287
GJ/€
TOTAL PRIMARY ENERGY (DIRECT + INDIRECT) INRELATION TO TOTAL NET ADDED VALUE
0,034 0,030 0,026
GRI 305-4
GHG EMISSIONS INTENSITY
2015 2016 2017
tCO2 eq. 530941,9307 489.829 521.637
€ TOTAL NET ADDED VALUE 183.484.576 206.279.587 258.860.287
kgCO2eq/€TOTAL EMISSIONS INTO THE ATMOSPHERE IN RELATION TO TOTAL NET ADDED VALUE
2,89 2,37 2,02
VALUE ADDED AND SUSTAINABILITY
FILIPPO SERVALLI CORPORATE MARKETING & SUSTAINABILITY DIRECTOR
www.radicigroup.com
Follow us on:
LINKEDIN: http://www.linkedin.com/company/radici-group
TWITTER: https://twitter.com/RGSustainable
SLIDESHARE: http://www.slideshare.net/RadiciGroup
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