GaBi Solutions

Extension database XXII: Carbon Composites

Process nameCountryTypeData source

Braiding (12k; max. lay-up rate)
12k roving; fiber angle ~75°; core diameter: ~150mm; carbon fiber remaining on the bobbins 5%;
individual production process, at plant;
-

GLOu-soFraunhofer

Braiding (12k; min. lay-up rate)
12k roving; fiber angle ~45°; core diameter: ~30mm; carbon fiber remaining on the bobbins 5%;
individual production process, at plant;
-

GLOu-soFraunhofer

Braiding (24k; max. lay-up rate)
24k roving; fiber angle ~75°; core diameter: ~150mm; carbon fiber remaining on the bobbins 5%;
individual production process, at plant;
-

GLOu-soFraunhofer

Braiding (24k; min. lay up rate)
24k roving; fiber angle ~45°; core diameter: ~35mm; carbon fiber remaining on the bobbins 5%;
individual production process, at plant;
-

GLOu-soFraunhofer

Carbon fiber (CF; PAN-based; HT) - 01
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production capacity world mix. Precursor production: JP electricity mix;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled according to the global production capacity mix in the Composites-Marktbericht 2016. For the precursor production (PAN from AN) the energy consumption is modelled according to the Japanese electricity grid mix.

GLOaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 02
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production capacity world mix. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled according to the global production capacity mix in the Composites-Marktbericht 2016. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower.

GLOaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 03
Production processes with optimized use of energy: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production capacity world mix. Precursor production: JP electricity mix;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled according to the global production capacity mix in the Composites-Marktbericht 2016. For the precursor production (PAN from AN) the energy consumption is modelled according to the Japanese electricity grid mix. For the production processes an optimized use of energy is assumed.

GLOaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 04
Production processes with optimized use of energy: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production capacity world mix. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled according to the global production capacity mix in the Composites-Marktbericht 2016. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower. For the production processes an optimized use of energy is assumed.

GLOaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 05
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production US electricity mix. Precursor production: JP electricity mix;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled according to the US electricity grid mix. For the precursor production (PAN from AN) the energy consumption is modelled according to the Japanese electricity grid mix.

USaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 06
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production US electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with US electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower.

USaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 07
Production processes with optimized use of energy: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production US electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with US electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower. For the production processes an optimized use of energy is assumed.

USaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 08
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production DE electricity mix. Precursor production: JP electricity mix;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled according to the German electricity grid mix. For the precursor production (PAN from AN) the energy consumption is modelled according to the Japanese electricity grid mix.

DEaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 09
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production DE electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with German electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower.

DEaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 10
Production processes with optimized use of energy: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production DE electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with German electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower. For the production processes an optimized use of energy is assumed.

DEaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 11
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production EU-28 electricity mix. Precursor production: JP electricity mix;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled according to the European (EU-28) electricity grid mix. For the precursor production (PAN from AN) the energy consumption is modelled according to the Japanese electricity grid mix.

EU-28aggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 12
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production EU-28 electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with European (EU-28) electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower.

EU-28aggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 13
Production processes with optimized use of energy: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production EU-28 electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with European (EU-28) electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower. For the production processes an optimized use of energy is assumed.

EU-28aggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 14
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production JP electricity mix. Precursor production: JP electricity mix;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled according to the Japanese electricity grid mix. For the precursor production (PAN from AN) the energy consumption is modelled according to the Japanese electricity grid mix.

JPaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 15
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production JP electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with Japanese electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower.

JPaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 16
Production processes with optimized use of energy: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production JP electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with Japanese electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower. For the production processes an optimized use of energy is assumed.

JPaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 17
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production CN electricity mix. Precursor production: JP electricity mix;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled according to the Chinese electricity grid mix. For the precursor production (PAN from AN) the energy consumption is modelled according to the Japanese electricity grid mix.

CNaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 18
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production CN electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with Chinese electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower.

CNaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 19
Production processes with optimized use of energy: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production CN electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with Chinese electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower. For the production processes an optimized use of energy is assumed.

CNaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 20
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production TW electricity mix. Precursor production: JP electricity mix;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled according to the Taiwanese electricity grid mix. For the precursor production (PAN from AN) the energy consumption is modelled according to the Japanese electricity grid mix.

TWaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 23
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production HU electricity mix. Precursor production: JP electricity mix;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled according to the Hungarian electricity grid mix. For the precursor production (PAN from AN) the energy consumption is modelled according to the Japanese electricity grid mix.

HUaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 24
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production HU electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with Hungarian electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower.

HUaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 25
Production processes with optimized use of energy: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production HU electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with Hungarian electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower. For the production processes an optimized use of energy is assumed.

HUaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 26
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production KR electricity mix. Precursor production: JP electricity mix;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled according to the South Korean electricity grid mix. For the precursor production (PAN from AN) the energy consumption is modelled according to the Japanese electricity grid mix.

KRaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 29
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production FR electricity mix. Precursor production: JP electricity mix;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled according to the French electricity grid mix. For the precursor production (PAN from AN) the energy consumption is modelled according to the Japanese electricity grid mix.

FRaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 30
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production FR electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with French electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower.

FRaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 31
Production processes with optimized use of energy: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production FR electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with French electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower. For the production processes an optimized use of energy is assumed.

FRaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 32
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production GB electricity mix. Precursor production: JP electricity mix;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled according to the Great Britain electricity grid mix. For the precursor production (PAN from AN) the energy consumption is modelled according to the Japanese electricity grid mix.

GBaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 33
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production GB electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with Great Britain electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower.

GBaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 34
Production processes with optimized use of energy: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production GB electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with Great Britain electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower. For the production processes an optimized use of energy is assumed.

GBaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 35
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production ES electricity mix. Precursor production: JP electricity mix;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled according to the Spanish electricity grid mix. For the precursor production (PAN from AN) the energy consumption is modelled according to the Japanese electricity grid mix.

ESaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 36
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production ES electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with Spanish electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower.

ESaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 37
Production processes with optimized use of energy: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production ES electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with Spanish electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower. For the production processes an optimized use of energy is assumed.

ESaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 38
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production BR electricity mix. Precursor production: JP electricity mix;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled according to the Brazilian electricity grid mix. For the precursor production (PAN from AN) the energy consumption is modelled according to the Japanese electricity grid mix.

BRaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 39
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production BR electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with Brazilian electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower.

BRaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 40
Production processes with optimized use of energy: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production BR electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with Brazilian electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower. For the production processes an optimized use of energy is assumed.

BRaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 44
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production CA electricity mix. Precursor production: JP electricity mix;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled according to the Canadian electricity grid mix. For the precursor production (PAN from AN) the energy consumption is modelled according to the Japanese electricity grid mix.

CAaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 45
Production processes: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production CA electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with Canadian electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower.

CAaggFraunhofer

Carbon fiber (CF; PAN-based; HT) - 46
Production processes with optimized use of energy: spinning, stabilization, carbonization, surface treatment, sizing. CF production: CF production CA electricity from hydropower. Precursor production: JP electricity from hydropower;
production mix, at plant;
CF = carbon fiber, PAN = polyacrylonitrile, HT = high tensity, AN = acrylonitrile. For the carbon fiber production (CF from PAN) the energy consumption is modelled with Canadian electricity from hydropower. For the precursor production (PAN from AN) the energy consumption is modelled with Japanese electricity from hydropower. For the production processes an optimized use of energy is assumed.

CAaggFraunhofer

Carbon fiber fabric (125g/m²; bindered)
Fiber areal weight: 125 g/m²; 5% epoxy binder;
individual production process, at plant;
-

GLOu-soFraunhofer

Carbon fiber fabric (125g/m²; not bindered)
Fiber areal weight: 125 g/m²; not bindered;
individual production process, at plant;
-

GLOu-soFraunhofer

Carbon fiber fabric (250g/m²; bindered)
Fiber areal weight: 250 g/m²; 5% epoxy binder;
individual production process, at plant;
-

GLOu-soFraunhofer

Carbon fiber fabric (250g/m²; not bindered)
Fiber areal weight: 250 g/m²; not bindered;
individual production process, at plant;
-

GLOu-soFraunhofer

Carbon fiber Non-Crimp-Fabric (NCF) (250g/m²; bindered)
Fiber areal weight: 250 g/m²; 5% epoxy binder; 1.6% sewing thread;
individual production process, at plant;
-

GLOu-soFraunhofer

Carbon fiber Non-Crimp-Fabric (NCF) (250g/m²; not bindered)
Fiber areal weight: 250 g/m²; not bindered; 1.6% sewing thread;
individual production process, at plant;
-

GLOu-soFraunhofer

Carbon fiber Non-Crimp-Fabric (NCF) (500g/m²; bindered)
Fiber areal weight: 500 g/m²; 5% epoxy binder; 1.6% sewing thread;
individual production process, at plant;
-

GLOu-soFraunhofer

Carbon fiber Non-Crimp-Fabric (NCF) (500g/m²; not bindered)
Fiber areal weight: 500 g/m²; not bindered; 1.6% sewing thread;
individual production process, at plant;
-

GLOu-soFraunhofer

Carbon fiber organo sheet PA6 (electric heated; average cuttings)
Electric heated heating press; fiber volume content: 50%; matrix: PA6; average organo sheet cuttings (40%);
individual production process, at plant;
-

GLOu-soFraunhofer

Carbon fiber organo sheet PA6 (electric heated; low cuttings)
Electric heated heating press; fiber volume content: 50%; matrix: PA6; low organo sheet cuttings (20%);
individual production process, at plant;
-

GLOu-soFraunhofer

Carbon fiber organo sheet PA6 (oil heated; average cuttings)
Electric heated heating press; fiber volume content: 50%; matrix: PA6; low organo sheet cuttings (20%);
individual production process, at plant;
-

GLOu-soFraunhofer

Carbon fiber organo sheet PA6 (oil heated; low cuttings)
Oil heated heating press; fiber volume content: 50%; matrix: PA6; average organo sheet cuttings (40%);
individual production process, at plant;
-

GLOu-soFraunhofer

Carbon fiber organo sheet PP (electric heated; average cuttings)
Oil heated heating press; fiber volume content: 50%; matrix: PA6; low organo sheet cuttings (20%);
individual production process, at plant;
-

GLOu-soFraunhofer

Carbon fiber organo sheet PP (electric heated; low cuttings)
Electric heated heating press; fiber volume content: 50%; matrix: PP; low organo sheet cuttings (20%);
individual production process, at plant;
-

GLOu-soFraunhofer

Carbon fiber organo sheet PP (oil heated; average cuttings)
Oil heated heating press; fiber volume content: 50%; matrix: PP; average organo sheet cuttings (40%);
individual production process, at plant;
-

GLOu-soFraunhofer

Carbon fiber organo sheet PP (oil heated; low cuttings)
Oil heated heating press; fiber volume content: 50%; matrix: PP; low organo sheet cuttings (20%);
individual production process, at plant;
-

GLOu-soFraunhofer

Carbon fiber reinforced plastic part - 47 - (CFRP. CF: GLO, P: DE)
Thermosetting polymer. Matrix EP. Fiber: CF. Fiber volume content 50%. Production processes: bindered non-crimp fabric (NCF), press forming, resin transfer moulding RTM, finish; low preform cuttings (20%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 48 - (CFRP. CF: GLO-Hydro, P: DE-Wind)
Thermosetting polymer. Matrix EP. Fiber: CF. Fiber volume content 50%. Production processes: bindered non-crimp fabric (NCF), press forming, resin transfer moulding RTM, finish; low preform cuttings (20%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 49 - (CFRP. Optimized energy use, CF: GLO, P: DE)
Thermosetting polymer. Matrix EP. Fiber: CF. Fiber volume content 50%. Production processes: bindered non-crimp fabric (NCF), press forming, resin transfer moulding RTM, finish; low preform cuttings (20%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 50 - (CFRP. Optimized energy use, CF: GLO-Hydro, P: DE-Wind)
Thermosetting polymer. Matrix EP. Fiber: CF. Fiber volume content 50%. Production processes: bindered non-crimp fabric (NCF), press forming, resin transfer moulding RTM, finish; low preform cuttings (20%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 51 - (CFRP. CF: GLO, P: DE)
Thermosetting polymer. Matrix EP. Fiber: CF. Fiber volume content 50%. Production processes: bindered non-crimp fabric (NCF), press forming, resin transfer molding RTM, finish; average preform cuttings (40%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 52 - (CFRP; CF: GLO-Hydro, P: DE-Wind)
Thermosetting polymer. Matrix EP. Fiber: CF. Fiber volume content 50%. Production processes: bindered non-crimp fabric (NCF), press forming, resin transfer molding RTM, finish; average preform cuttings (40%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 53 - (CFRP; Optimized energy use, CF: GLO, P: DE)
Thermosetting polymer. Matrix EP. Fiber: CF. Fiber volume content 50%. Production processes: bindered non-crimp fabric (NCF), press forming, resin transfer molding RTM, finish; average preform cuttings (40%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 54 - (CFRP; Optimized energy use, CF: GLO-Hydro, P: DE-Wind)
Thermosetting polymer. Matrix EP. Fiber: CF. Fiber volume content 50%. Production processes: bindered non-crimp fabric (NCF), press forming, resin transfer molding RTM, finish; average preform cuttings (40%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 55 - (CFRP; CF: GLO, P: DE)
Thermosetting polymer. Matrix EP. Fiber: CF. Fiber volume content 50%. Production processes: bindered non-crimp fabric (NCF), press forming, resin transfer molding RTM, finish; high preform cuttings (60%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 56 - (CFRP; CF: GLO-Hydro, P: DE-Wind)
Thermosetting polymer. Matrix EP. Fiber: CF. Fiber volume content 50%. Production processes: bindered non-crimp fabric (NCF), press forming, resin transfer molding RTM, finish; high preform cuttings (60%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 57 - (CFRP; Optimized energy use, CF: GLO, P: DE)
Thermosetting polymer. Matrix EP. Fiber: CF. Fiber volume content 50%. Production processes: bindered non-crimp fabric (NCF), press forming, resin transfer molding RTM, finish; high preform cuttings (60%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 58 - (CFRP; Optimized energy use, CF: GLO-Hydro, P: DE-Wind)
Thermosetting polymer. Matrix EP. Fiber: CF. Fiber volume content 50%. Production processes: bindered non-crimp fabric (NCF), press forming, resin transfer molding RTM, finish; high preform cuttings (60%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 59 - (CFRP; CF: GLO, P: DE)
Thermosetting polymer. Matrix EP. Fiber: CF. Fiber volume content 50%. Production processes: braiding, resin transfer molding RTM, finish; low preform cuttings (5%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 60 - (CFRP; CF: GLO-Hydro, P: DE-Wind)
Thermosetting polymer. Matrix EP. Fiber: CF. Fiber volume content 50%. Production processes: braiding, resin transfer molding RTM, finish; low preform cuttings (5%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 61 - (CFRP; Optimized energy use, CF: GLO, P: DE)
Thermosetting polymer. Matrix EP. Fiber: CF. Fiber volume content 50%. Production processes: braiding, resin transfer molding RTM, finish; low preform cuttings (5%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 62 - (CFRP; Optimized energy use, CF: GLO-Hydro, P: DE-Wind)
Thermosetting polymer. Matrix EP. Fiber: CF. Fiber volume content 50%. Production processes: braiding, resin transfer molding RTM, finish; low preform cuttings (5%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 63 - (CFRP; CF: GLO, P: DE)
Thermosetting polymer. Matrix EP. Fiber: CF. Fiber volume content 50%. Production processes: pultrusion, finish; low carbon fiber remainings on the bobbins (5%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precursor production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 64 - (CFRP; CF: GLO-Hydro, P: DE-Wind)
Thermosetting polymer. Matrix EP. Fiber: CF. Fiber volume content 50%. Production processes: pultrusion, finish; low carbon fiber remainings on the bobbins (5%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precursor production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 65 - (CFRP; Optimized energy use, CF: GLO, P: DE)
Thermosetting polymer. Matrix EP. Fiber: CF. Fiber volume content 50%. Production processes: pultrusion, finish; low carbon fiber remainings on the bobbins (5%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precursor production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 66 - (CFRP; Optimized energy use, CF: GLO-Hydro, P: DE-Wind)
Thermosetting polymer. Matrix EP. Fiber: CF. Fiber volume content 50%. Production processes: pultrusion, finish; low carbon fiber remainings on the bobbins (5%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precursor production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 67 - (CFRP; CF: GLO, P: DE)
Thermosetting polymer. Matrix PU. Fiber: CF. Fiber volume content 50%. Production processes: pultrusion, finish; low carbon fiber remainings on the bobbins (5%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 68 - (CFRP; CF: GLO-Hydro, P: DE-Wind)
Thermosetting polymer. Matrix PU. Fiber: CF. Fiber volume content 50%. Production processes: pultrusion, finish; low carbon fiber remainings on the bobbins (5%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 69 - (CFRP; Optimized energy use, CF: GLO, P: DE)
Thermosetting polymer. Matrix PU. Fiber: CF. Fiber volume content 50%. Production processes: pultrusion, finish; low carbon fiber remainings on the bobbins (5%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 70 - (CFRP; Optimized energy use, CF: GLO-Hydro, P: DE-Wind)
Thermosetting polymer. Matrix PU. Fiber: CF. Fiber volume content 50%. Production processes: pultrusion, finish; low carbon fiber remainings on the bobbins (5%);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 71 - (CFRP; CF: GLO, P: DE)
Thermoplastic polymer. Matrix PA6. Fiber: CF. Fiber volume content 47%. Production processes: fabric production, organo sheet production, thermoplastic forming, finish; low organo sheet cuttings (20 %);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 72 - (CFRP; CF: GLO-Hydro, P: DE-Wind)
Thermoplastic polymer. Matrix PA6. Fiber: CF. Fiber volume content 47%. Production processes: fabric production, organo sheet production, thermoplastic forming, finish; low organo sheet cuttings (20 %);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 73 - (CFRP; Optimized energy use, CF: GLO, P: DE)
Thermoplastic polymer. Matrix PA6. Fiber: CF. Fiber volume content 47%. Production processes: fabric production, organo sheet production, thermoplastic forming, finish; low organo sheet cuttings (20 %);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 74 - (CFRP; Optimized energy use, CF: GLO-Hydro, P: DE-Wind)
Thermoplastic polymer. Matrix PA6. Fiber: CF. Fiber volume content 47%. Production processes: fabric production, organo sheet production, thermoplastic forming, finish; low organo sheet cuttings (20 %);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 75 - (CFRP; CF: GLO, P: DE)
Thermoplastic polymer. Matrix PA6. Fiber: CF. Fiber volume content 47%. Production processes: fabric production, organo sheet production, thermoplastic forming, finish; average organo sheet cuttings (40 %);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 76 - (CFRP; CF: GLO-Hydro, P: DE-Wind)
Thermoplastic polymer. Matrix PA6. Fiber: CF. Fiber volume content 47%. Production processes: fabric production, organ sheet production, thermoplastic forming, finish; average organo sheet cuttings (40 %);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 77 - (CFRP; Optimized energy use, CF: GLO, P: DE)
Thermoplastic polymer. Matrix PA6. Fiber: CF. Fiber volume content 47%. Production processes: fabric production, organo sheet production, thermoplastic forming, finish; average organo sheet cuttings (40 %);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 78 - (CFRP; Optimized energy use, CF: GLO-Hydro, P: DE-Wind)
Thermoplastic polymer. Matrix PA6. Fiber: CF. Fiber volume content 47%. Production processes: fabric production, organo sheet production, thermoplastic forming, finish; average organo sheet cuttings (40 %);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 79 - (CFRP; CF: GLO, P: DE)
Thermoplastic polymer. Matrix PA6. Fiber: CF. Fiber volume content 47%. Production processes: fabric production, organo sheet production, thermoplastic forming, finish; high organo sheet cuttings (60 %);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 80 - (CFRP; CF: GLO-Hydro, P: DE-Wind)
Thermoplastic polymer. Matrix PA6. Fiber: CF. Fiber volume content 47%. Production processes: fabric production, organo sheet production, thermoplastic forming, finish; high organo sheet cuttings (60 %);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 81 - (CFRP; Optimized energy use, CF: GLO, P: DE)
Thermoplastic polymer. Matrix PA6. Fiber: CF. Fiber volume content 47%. Production processes: fabric production, organo sheet production, thermoplastic forming, finish; high organo sheet cuttings (60 %);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 82 - (CFRP; Optimized energy use, CF: GLO-Hydro, P: DE-Wind)
Thermoplastic polymer. Matrix PA6. Fiber: CF. Fiber volume content 47%. Production processes: fabric production, organo sheet production, thermoplastic forming, finish; high organo sheet cuttings (60 %);
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 83 - (CFRP; CF: GLO, P: DE)
Thermoplastic polymer. Matrix PA6. Fiber: CF. Fiber volume content 47%. Production processes: fabric production, organo sheet production; no cutting waste;
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 84 - (CFRP; CF: GLO-Hydro, P: DE-Wind)
Thermoplastic polymer. Matrix PA6. Fiber: CF. Fiber volume content 47%. Production processes: fabric production, organo sheet production; no cutting waste;
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 85 - (CFRP; Optimized energy use, CF: GLO, P: DE)
Thermoplastic polymer. Matrix PA6. Fiber: CF. Fiber volume content 47%. Production processes: fabric production, organo sheet production; no cutting waste;
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber reinforced plastic part - 86 - (CFRP; Optimized energy use, CF: GLO-Hydro, P: DE-Wind)
Thermoplastic polymer. Matrix PA6. Fiber: CF. Fiber volume content 47%. Production processes: fabric production, organo sheet production; no cutting waste;
production mix, at plant;
CF = carbon fiber production, P = processing, GLO = carbon fiber production capacity world mix and precursor production JP electricity grid mix, GLO-Hydro = carbon fiber production US electricity from hydropower and precuror production from JP electricity from hydropower, DE = DE electricity grid mix, DE-Wind = DE electricity from windpower.

DEaggFraunhofer

Carbon fiber thermoplastic tape PA6 (electric heated)
Electric heated heating press; fiber volume content: 50%; matrix: PA6;
individual production process, at plant;
-

GLOu-soFraunhofer

Carbon fiber thermoplastic tape PA6 (oil heated)
Oil heated heating press; fiber volume content: 50%; matrix: PA6;
individual production process, at plant;
-

GLOu-soFraunhofer

Carbon fiber thermoplastic tape PP (electric heated)
Electric heated heating press; fiber volume content: 50%; matrix: PP;
individual production process, at plant;
-

GLOu-soFraunhofer

Carbon fiber thermoplastic tape PP (oil heated)
Oil heated heating press; fiber volume content: 50%; matrix: PP;
individual production process, at plant;
-

GLOu-soFraunhofer

CFRP milling (average cuttings)
Average cuttings 10%;
individual production process, at plant;
-

GLOu-soFraunhofer

CFRP milling (high cuttings)
High cuttings 20%;
individual production process, at plant;
-

GLOu-soFraunhofer

CFRP milling (low cuttings)
Low cuttings 5%;
individual production process, at plant;
-

GLOu-soFraunhofer

Consolidation of carbon fiber thermoplastic sheets PA6 (electric heated)
Electric heated press; Matrix PA6;
individual production process, at plant;
-

GLOu-soFraunhofer

Consolidation of carbon fiber thermoplastic sheets PA6 (oil heated)
Oil heated press; Matrix PA6;
individual production process, at plant;
-

GLOu-soFraunhofer

Consolidation of carbon fiber thermoplastic sheets PP (electric heated)
Electric heated press; Matrix PP;
individual production process, at plant;
-

GLOu-soFraunhofer

Consolidation of carbon fiber thermoplastic sheets PP (oil heated)
Oil heated press; Matrix PP;
individual production process, at plant;
-

GLOu-soFraunhofer

Forming of carbon fiber thermoplastic sheets PA6: Infrared Heating and press forming (large parts)
Part geometry 1.5m²; thickness 2mm; Matrix PA6;
individual production process, at plant;
-

GLOu-soFraunhofer

Forming of carbon fiber thermoplastic sheets PA6: Infrared heating and press forming (small parts)
Part geometry 0.5m²; thickness 2mm; Matrix PA6;
individual production process, at plant;
-

GLOu-soFraunhofer

Forming of carbon fiber thermoplastic sheets PP: Infrared heating and press forming (large parts)
Part geometry 1.5m²; thickness 2mm; Matrix PP;
individual production process, at plant;
-

GLOu-soFraunhofer

Forming of carbon fiber thermoplastic sheets PP: Infrared heating and press forming (small parts)
Part geometry 0.5m²; thickness 2mm; Matrix PP;
individual production process, at plant;
-

GLOu-soFraunhofer

Injection device (high pressure; curing time 10min; large and thick parts)
High pressure; curing time 10min; large and thick parts;
individual production process, at plant;
-

GLOu-soFraunhofer

Injection device (high pressure; curing time 10min; small and thin parts)
High pressure; curing time 10min; small and thin parts;
individual production process, at plant;
-

GLOu-soFraunhofer

Injection device (high pressure; curing time 5min; large and thick parts)
High pressure; curing time 5min; large and thick parts;
individual production process, at plant;
-

GLOu-soFraunhofer

Injection device (high pressure; curing time 5min; small and thin parts)
High pressure; curing time 5min; small and thin parts;
individual production process, at plant;
-

GLOu-soFraunhofer

Injection device (low pressure)
Low pressure;
individual production process, at plant;
-

GLOu-soFraunhofer

NCF Preforming: Infrared (IR) heating and press forming (large parts, average cuttings)
Part size: ~1.5m²; theoretical preform thickness: 1.5mm; average preform cuttings (40%);
individual production process, at plant;
-

GLOu-soFraunhofer

NCF Preforming: Infrared (IR) heating and press forming (large parts; high cuttings)
Part size: ~1.5m²; theoretical preform thickness: 1.5mm; high preform cuttings (60%);
individual production process, at plant;
-

GLOu-soFraunhofer

NCF Preforming: Infrared (IR) heating and press forming (large parts; low cuttings)
Part size: ~1.5m²; theoretical preform thickness: 1.5mm; low preform cuttings (20%);
individual production process, at plant;
-

GLOu-soFraunhofer

NCF Preforming: Infrared (IR) heating and press forming (small parts; average cuttings)
Part size: ~0.5m²; theoretical preform thickness: 1mm; average preform cuttings (40%);
individual production process, at plant;
-

GLOu-soFraunhofer

NCF Preforming: Infrared (IR) heating and press forming (small parts; high cuttings)
Part size: ~0.5m²; theoretical preform thickness: 1mm; high preform cuttings (60%);
individual production process, at plant;
-

GLOu-soFraunhofer

NCF Preforming: Infrared (IR) heating and press forming (small parts; low cuttings)
Part size: ~0.5m²; theoretical preform thickness: 1mm; low preform cuttings (20%);
individual production process, at plant;
-

GLOu-soFraunhofer

Pultrusion (55% FVC; epoxy; open bath impregnation)
Open bath pultrusion; fiber volume content: 55%; cutting waste matrix: 7.5%; carbon fiber remaining on the bobbins: 5%;
individual production process, at plant;
-

GLOu-soFraunhofer

Pultrusion (55% FVC; PU, polyurethane; low pressure injection)
Closed pultrusion; fiiber volume content: 55%; carbon fiber remaining on the bobbins: 5%; injection device is not included and has to be modelled separately;
individual production process, at plant;
-

GLOu-soFraunhofer

Pultrusion (65% FVC; epoxy; open bath impregnation)
Open bath pultrusion; fiber volume content: 65%; cutting waste matrix: 7.5%; carbon fiber remaining on the bobbins: 5%;
individual production process, at plant;
-

GLOu-soFraunhofer

Pultrusion (65% FVC; PU, polyurethane; low pressure injection)
Closed pultrusion; fiber volume content: 65%; carbon fiber remaining on the bobbins: 5% ; injection device is not included and has to be modelled separately;
individual production process, at plant;
-

GLOu-soFraunhofer

Resin Transfer Molding (RTM) (curing time 10min; large and thick part)
Injection and curing time 10min; part geometry 1.5m²; thickness 3mm; injection device is not included and has to be modelled separately;
individual production process, at plant;
-

GLOu-soFraunhofer

Resin Transfer Molding (RTM) (curing time 10min; small and thin part)
Injection and curing time 10min; part geometry 0.5m²; thickness 2mm; injection device is not included and has to be modelled separately;
individual production process, at plant;
-

GLOu-soFraunhofer

Resin Transfer Molding (RTM) (curing time 5min, large and thick part)
Injection and curing time 5min; part geometry 1.5m²; thickness 3mm; injection device is not included and has to be modelled separately;
individual production process, at plant;
-

GLOu-soFraunhofer

Resin Transfer Molding (RTM) (curing time 5min; small and thin part)
Injection and curing time 5min; part geometry 0.5m²; thickness 2mm; injection device is not included and has to be modelled separately;
individual production process, at plant;
-

GLOu-soFraunhofer

Thermoplastic Automated Tape Laying (ATL) (small tape; large part)
Tape width: 50mm; part geometry ~ 1.5m²; low cuttings (5%);
individual production process, at plant;
-

GLOu-soFraunhofer

Thermoplastic Automated Tape Laying (ATL) (small tape; small part)
Tape width: 50mm; part geometry ~ 0.5m²; low cuttings (5%);
individual production process, at plant;
-

GLOu-soFraunhofer

Thermoplastic Automated Tape Laying (ATL) (wide tape; large part)
Tape width: 150mm; part geometry ~ 1.5m²; low cuttings (5%);
individual production process, at plant;
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GLOu-soFraunhofer

Thermoplastic Automated Tape Laying (ATL) (wide tape; small part)
Tape width: 150mm; part geometry ~ 0.5m²; low cuttings (5%);
individual production process, at plant;
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GLOu-soFraunhofer