All posts tagged dispersions

Hybrid Polymer Polyols

Title: HYBRID PHD/PMPO POLYOLS FOR POLYURETHANE FOAM APPLICATIONS

Number/Link: WO2013090325 (=US20130158142)

Applicant/Assignee: Bayer

Publication date: 20-06-2013

“Gist”: A hybrid SAN-PHD filled polyol allows for higher solids content and lower viscosity.

Why it is interesting: “Filled polyols” (i.e. polyols containing dispersed particles) are well known in polyurethane technology and are available in three types depending on the type of particles dispersed. “PIPA” polyols contain polyurethane particles, “PHD” polyols contain polyurea (“polyharnstoff”) particles and “polymer polyols” contain SAN (styrene-acrylonitrile) particles. The polyol in which the particles are dispersed is called the ‘base polyol’. The current invention teaches the preparation of a hybrid filled polyol by using PIPA or PHD polyol as (optionally part of) the base polyol to produce a SAN polymer polyol. The hybrid polymer polyol reportedly has has a lower viscosity at higher solids content and foams produced with it are claimed to have improved fire and VOC properties.

SAN

Rigid Polyurethane Foam Containing Expandable Particles

Title: Highly Insulating Polyurethane Foam and Method for Manufacturing Same

Number/Link:US2013/0150470

Applicant/Assignee: Cheil Industries

Publication date: 13-06-2013 (priority PCT/KR)

“Gist”: Rigid foams comprising thermally expandable particles which penetrate cell walls and which are covered with an infrared absorbing filler show improved insulation properties.

Why it is interesting: The invention claims to improve insulation properties of rigid foams by including about 5% (on the total resin) of organic thermally expandable particles with a diameter of about 5 μm before expansion and of about 50 μm after expansion. A filler chosen from carbon black, graphite, carbon nanotubes and the like is added as well. After the foam is formed the expanded particles penetrate the cell walls, are supposedly covered with the filler and are believed to reduce the radiation component of the thermal conductivity. Foam properties given in the examples show a density of about 35 kg/m³ with a thermal conductivity of about 0.0160 kcal/m.h.ºC (or about 0.019 W/m.K if I converted this correctly).

fig 2 form the patent. Large circles are expanded particles, smaal circles is filler.

Fig 2 form the patent: large circles are the expanded particles, the small circles represent the filler.

Aqueous Polyurethane Dispersion with Integrated Nanoparticles

Title: AQUEOUS DISPERSIONS OF POLYURETHANE AND NANOPARTICLES

Number/Link: WO2013/059106

Applicant/Assignee: Bayer

Publication date: 25-04-2013

“Gist”: Amino-functional inorganic nanoparticles are reacted with residual isocyanate groups of a PUD-forming polyurethane prepolymer and subsequently dispersed in water.

Why it is interesting: A water-dispersible polyurethane prepolymer is made from isocyanate, polyol and chain extender in which polyol and/or chain extender comprise ionic or potentially ionic groups. The prepolymer is produced with a surplus of isocyanate which is subsequently reacted with amino-functional inorganic nanoparticles. The nanoparticles consist of e.g. metal oxides which were reacted with a “bridging compound” comprising an isocyanate-reactive group (NH2 or OH) and a particle-reactive group e.g. a halogen or silane group. The polyurethane with covalently integrated nanoparticles can then be dispersed in water using a known process. The resulting PUD has a high shelf-life and can be used in coatings, adhesives, films etc. with improved properties.

Polyurethane dispersion and film made from it. (Wikimedia)

Innovation in Polyurethanes

All posts tagged dispersions

Hybrid Polymer Polyols

Rigid Polyurethane Foam Containing Expandable Particles

Aqueous Polyurethane Dispersion with Integrated Nanoparticles

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