All posts in category Elastomers

Polyurethane Elastomers containing Polyrotaxanes

Title: CAST-MOLDED HEAT-CURABLE POLYURETHANE ELASTOMER

Number/Link: WO2015/159875 (Japanese)

Applicant/Assignee: UBE

Publication date: 22-10-2015

“Gist”: 1-10% of a polyrotaxane is incorporated in a hot cast PU elastomer system

Why it is interesting: Polyrotaxanes are molecular systems consisting of a linear polymer which is “threated” through a number of ring-shaped molecules. The rings are prevented from ‘sliding off’ by blocking-molecules at both ends of the “thread”. In this invention polyrotaxanes based on a polycaprolactone thread and cyclodextrin rings (pref.) are incorporated in hot cast elastomer systems in amounts of 1-10% (w/w). Because cyclodextrin rings contain hydroxyl groups they react with the isocyanate incorporating the polyrotaxane in the PU polymer. The systems are said to have processing and property advantages for specific elastomer applications, in this case printer rollers – if I understand the machine translation correctly.

Schematic presentation of a polyrotaxane

PLA-PPG-PU Block Copolymers

Title: LACTIDE COPOLYMER, METHOD FOR PREPARING SAME, AND RESIN COMPOSITION COMPRISING SAME

Number/Link:US2015/0284516

Applicant/Assignee: LG Chem

Publication date: 8-10-2015 (Priority PCT/KR)

“Gist”: Polyether-polylactide block copolymers are prepared using ROP and then extended with isocyanates

Why it is interesting: Polylactic acid (PLA) is a well known renewable and biodegradable polymer often used in the form of films or sheets for disposable packaging. The polymer is however not very flexible and the films have poor mechanical properties. According to this invention both flexibility and mechanical properties can be greatly improved by making polyether-polylactide copolymers and then extending these using an isocyanate with a functionality of more than 2. The copolymers are made by ring-opening polymerization of lactide monomer using a polyether diol as a ‘macro’ initiator together with a specific catalyst. In the examples an excess L-lactide monomer is used which is reacted with a 4000 to 6000 mole weight polypropylene glycol, resulting in a block copolymer with a Mw of more than 100,000. The block copolymer is then reacted with a mixture of MDI and hexamethylenediisocyanate isocyanurate, after which the residual lactide is removed.

L-Lactide

SHSM Polyurethanes

Title: SHAPE-MEMORY-SELF-HEALING POLYMERS (SMSHPS)

Number/Link: WO2015119688

Applicant/Assignee: University of Florida

Publication date: 13-08-2015

“Gist”: Self-healing shape memory polyurethanes made by incorporation of DA adducts in-chain

Why it is interesting: According to this invention self-healing shape memory polyurethanes can be prepared by incorporating Diels-Alder (DA) adducts into the PU network such that the DA adducts do not contribute to the crosslinking. In this manner the material can be heated above Tg without breaking crosslinks thereby inhibiting permanent distortion of the memorised shape. The Tg is also chosen such that it is lower than the temperature at which the retro-DA reaction readily occurs. The DA adducts can be introduced using a DA adduct-containing diol as for example the adduct of a furfuryl alcohol and N-(2-hydroxyethyl)maleimide. The SHSM polyurethanes are said to be useful for coatings and moulded materials.

Diol containing a Diels-Alder adduct

Innovation in Polyurethanes

All posts in category Elastomers

Polyurethane Elastomers containing Polyrotaxanes

PLA-PPG-PU Block Copolymers

SHSM Polyurethanes

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