All posts tagged TPE

Expandable Polyurethane Particles for Insulation Panels

Title: POLYURETHANE-BASED EXPANDABLE POLYMER PARTICLES

 Number/Link: WO2014/006182  (German)

Applicant/Assignee: BASF

Publication date: 9-01-2014

Gist”: Microgranules of TPU/PS copolymer containing pentane can be expanded into insulation panels using standard EPS equipment.

Why it is interesting: Contrary to polystyrene, thermoplastic polyurethane cannot be ‘imbued’ with a physical blowing agent like pentane to make steam-expandable particles. This is due a.o. to the high diffusion rate of pentane (e.g.) in TPU.  BASF have now found that by using a TPU/PS copolymer, expandable particles can be prepared which can be used in standard EPS (expandable polystyrene) equipment to make insulation panels. The TPU used is based on 4,4′-MDI, polyTHF and butanediol such that the vicat softening point is below 80°C.   The TPU, in the form of microgranules (0.5-2mm), is swollen in styrene containing dicumylperoxide, dispersed in water and heated to polymerisation.  A blowing agent like (pref) pentane is added to the dispersion as well. The resulting particles are expandable and can be used to make insulation panels of 50-150 kg/m³.

Expandable Polystyrene.

Expandable Polystyrene.

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by Gerhard Bleys on January 14, 2014  •  Permalink
Posted in Rigid Foams, Thermoplastics
Tagged , , , , , , , , , , , ,

Posted by Gerhard Bleys on January 14, 2014

https://purpatents.com/2014/01/14/expandable-polyurethane-particles-for-insulation-panels/

Thermoplastic Polyurethane with a Percisely Controlled Biodegradation Rate

Title: PROCESS FOR MAKING BIODEGRADABLE AND/OR BIOABSORBABLE POLYMERS

 Number/Link: WO2014/004334

Applicant/Assignee: Lubrizol

Publication date: 03-01-2014

Gist”: Two sets of parameters are given (and claimed) which, when iteratively adjusted, allow to independently modify the mechanical properties and biodegradation rate of a TPU.

Why it is interesting: Many biomedical materials for implants such as screws, bone plates, tissue scaffolds, pins etc need high mechanical properties but also a controlled biodegradation rate which can vary from weeks to years.  According to this case the precise control of the degradation rate is not possible with currently available bio-polymers.  The invention claims two sets of parameters one which controls the physical properties of a TPU like the molecular weight, harblock content, crystallinity etc, and another set which controls the biodegradation rate like the amount of ‘hydrolyzable units’ in the backbone, hydrophilicity ect. It is claimed that both mechanical properties and degradation rate can be independently controlled by adjusting one or more parameters of each set. In the examples TPUs are prepared from HMDI, 1,4-butane diol and poly(lactide-co-caprolactone) diols where the lactide is the hydrolyzable unit.

A poly(lactide-co-caprolactone)

A poly(lactide-co-caprolactone)

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by Gerhard Bleys on January 7, 2014  •  Permalink
Posted in Thermoplastics
Tagged , , , , , , , , , , , ,

Posted by Gerhard Bleys on January 7, 2014

https://purpatents.com/2014/01/07/thermoplastic-polyurethane-with-a-percisely-controlled-biodegradation-rate/

Thermoplastic Polyurea Elastomers

Title: MELT PROCESSIBLE POLYUREAS AND POLYUREA-URETHANES, METHOD FOR THE PRODUCTION THEREOF AND PRODUCTS MADE THEREFROM

 Number/Link: US2013/0331538

Applicant/Assignee: University of Akron

Publication date: 12-12-2013 (priority PCT)

Gist”: Polyurea is made melt-processable by incorporating hydrogen-bond accepting chain extenders (HACE)

Why it is interesting: It is well known that polyurea elastomers with a decent hardblock content (of e.g. 30-35%) are not melt-processable. Because of very strong (bi-dentate) H-bond formation in the hard domains the material will degrade sooner than flow when heated. In this invention it is proposed to incorporate a relatively small amount of HACE to disrupt the hard domain structure and reduce flow temperature.  In an example a few parts of OH-ended pentamethylenepolycarbonate with a MW of 500 to 800 was used next to the conventional 1,6-hexamethylene chain extender to drop the flow temperature by 50°C while not affecting the tensile strength. (I suppose a NH2-ended polycarbonate could have been used as well to make an all-polyurea material).

Bi-dentate H-bonds between polurea molecules (left) disrupted by a polycarbonate group (right)

Bi-dentate H-bonds between polurea molecules (left) dusrupted by a carbonate group (right)

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by Gerhard Bleys on December 17, 2013  •  Permalink
Posted in Elastomers
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Posted by Gerhard Bleys on December 17, 2013

https://purpatents.com/2013/12/17/melt-processable-polyurea-elastomers/

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