Demande

TUBALLMATRIXMATRIX822MATRIX 822

Demande

Additif conducteur universel à base d'éther composé de polyol pour le polypropylène, le polyuréthane thermoplastique (TPU), le sulfure de polyphénylène (PPS) chargé, l'acrylonitrile butadiène styrène (ABS), le polycarbonate, l'ABS-polycarbonate, le polyamide (PA) et la résine polyamide renforcée par des fibres de verre (GF PA).

Peut être utilisé en combinaison avec d'autres additifs conducteurs d'électricité pour réduire leur concentration et améliorer les propriétés mécaniques/fluidité des systèmes thermoplastiques chargés et non chargés. 

Classe de matériaux
Polypropylène, polyuréthane thermoplastique (TPU), sulfure de polyphénylène (PPS) chargé, acrylonitrile butadiène styrène (ABS), polycarbonate, ABS-polycarbonate, polyamide (PA) et résine polyamide renforcée de fibres de verre.
Dosage de travail
0.2–2% en poids
Composants de base:
Éther composé de polyol
Forme
Pastille

Benefits

Conductibilité électrique

Assure une conductivité constante et uniforme à faible dosage.

Les propriétés mécaniques

Conserve les performances mécaniques essentielles d'origine

Les spécifications permanentes

Maintien la résistance spécifique quel que soit le niveau d'humidité

La réduction de rebut

Réduit le nombre de produits rejetés 



Applications industrielles

Peinture electrostatique
cliquez pour voir les cas
Peinture electrostatique

Documents
Disponible en langues :
english
TDS TUBALL MATRIX 822 ENG V05.PDF
PDF
102.40 kB
SDS TUBALL MATRIX 822 EU ENG V2-3.PDF
PDF
307.20 kB
SDS TUBALL MATRIX 822 CN ENG V1-1.PDF
PDF
307.20 kB
SDS TUBALL MATRIX 822 KR ENG V1-0.PDF
PDF
204.80 kB

Nouvelles

October 31
[💡R&D] Easy-to-process flexible thermoelectric materials with robust mechanical properties were developed by researches from National Research Council Canada and Leibniz-Institut für Polymerforschung Dresden. TUBALL–TPU nanocomposite shows ∼7-, 25-, and 250-fold improvements in stiffness, strength, and tensile toughness, respectively. These easily processed, self-supporting, and stretchable materials can be utilized for energy-harvesting modules based on the thermoelectric effect. Read the article in full here: https://pubs.acs.org/doi/full/10.1021/acsanm.3c03247 Learn more on graphene nanotube uses and applications: https://tuball.com/nanotubes-for?utm_source=facebook+&utm_medium=Post+campaign&utm_campaign=Oct+31%272023 #TEG #composites #TPU
July 13
[🤔 #Didyouknow?] The first car bumper appeared in 1897 for aesthetic purposes. In 1901, it was redesigned to protect vehicle parts and ensure road safety. Initially made of rubber, most bumpers are now made of plastic. To achieve consistent color, manufacturers prefer to use electrostatic painting for both metallic and plastic parts. To do this, first a conductive primer should be applied on plastic parts to enhance the adhesion of the paint. Graphene nanotubes enable the production of light-gray conductive primers with high transfer efficiency for use in e-painting. This leads to cost optimization and reduced basecoat consumption compared to black primers. Learn more on graphene nanotubes for automotive primers: https://tuball.com/nanotubes-for/conductive-primers?utm_source=Facebook&utm_medium=Post&utm_campaign=Did+you+know+Primer+July+23 #ElectrostaticPainting #Nanotubes #CarBumper
July 5
A signal lamp allows a miner to raise an alert and to be found in emergency situations. With graphene #nanotubes incorporated inside the #ABS case, the case of the lamp becomes anti-static, making it safe for use in hazardous areas like coal mines, where flammable gases or combustible dust can accumulate. By preventing the buildup of electrostatic charge, this modified lamp eliminates the risk of sparks and potential explosions. Learn more on electrically conductive agent for thermoplastics: https://tuball.com/nanotubes-in/thermoplastics