A protective flowable or spreadable composition. The protective composition optionally and preferably features a base material according to various embodiments and aerogel, dispersed in an acrylic dispersion. Preferably the protective composition further comprises one or more of chopped glass fibers and titanium dioxide. Water or an aqueous solution is preferably added to determine the degree of viscosity, for example to apply the composition in flowable form (paint, sprayable material, coating and so forth) or in spreadable form.

A protective flowable or spreadable composition. The protective composition optionally and preferably features a base material according to various embodiments and aerogel, dispersed in an acrylic dispersion. Preferably the protective composition further comprises one or more of chopped glass fibers and titanium dioxide. Water or an aqueous solution is preferably added to determine the degree of viscosity, for example to apply the composition in flowable form (paint, sprayable material, coating and so forth) or in spreadable form.

The present invention provides a compound represented by general formula (A1) or (A2):

R.sup.1(PE.sup.1-Y).sub.nPE.sup.2-X(SiR.sup.a.sub.kR.sup.b.sub.lR.sup.c.sub.m).sub.(A1)

(R.sup.c.sub.mR.sup.b.sub.lR.sup.a.sub.kSi).sub.X(PE.sup.1-Y).sub.nPE.sup.2-X(SiR.sup.a.sub.kR.sup.b.sub.lR.sup.c.sub.m).sub.(A2)

wherein each of symbols is as defined in the description.

Disclosed is a thermal insulation coating composition including: a polymer resin; an aerogel; and an amphiphilic compound including specific functional groups and having a weight average molecular weight of about 200 to about 5000. A thermal insulation coating layer obtained from the thermal insulation coating composition is also provided.

Disclosed is a thermal insulation coating composition including: a polymer resin; an aerogel; and an amphiphilic compound including specific functional groups and having a weight average molecular weight of about 200 to about 5000. A thermal insulation coating layer obtained from the thermal insulation coating composition is also provided.

A wearable device system includes one or more sensors coupled to a wearable device structure that includes first and second outer surfaces, an interior, a first end and a second end. The wearable device structure has a unique user ID. The sensors acquiring user information selected from of at least one of, a user's activities, behaviors, habit information, health parameters, medical monitoring and user monitoring. The wearable device has a power source coupled to a charging device of the wearable device. A base station is configured to be coupled to the wearable device and has a corresponding charging device for charging or recharging the power source of the wearable device.

A laminate is formed by laminating a substrate and a support plate through an adhesive layer and a release layer. The release layer is formed by applying a composition containing a reactive polysilsesquioxane and a crosslinkable group-containing siloxane onto the surface of the support plate or the surface of the substrate and heating the composition to polymerize the reactive polysilsesquioxane and the crosslinkable group-containing siloxane.

A laminate is formed by laminating a substrate and a support plate through an adhesive layer and a release layer. The release layer is formed by applying a composition containing a reactive polysilsesquioxane and a crosslinkable group-containing siloxane onto the surface of the support plate or the surface of the substrate and heating the composition to polymerize the reactive polysilsesquioxane and the crosslinkable group-containing siloxane.

Disclosed herein is a hydrophobic cable, particularly a cable for medical devices having a hydrophobic surface. The hydrophobic cable includes a conductive unit arranged in a longitudinal direction of the cable, an insulating sheath coated onto an outer portion of the conductive unit and made of a PVC material, and a coating film formed outside the insulating sheath. Here, the coating film may be formed by curing a coating solution including at least one monomer selected from the group consisting of a silane compound and a siloxane compound.

Disclosed herein is a hydrophobic cable, particularly a cable for medical devices having a hydrophobic surface. The hydrophobic cable includes a conductive unit arranged in a longitudinal direction of the cable, an insulating sheath coated onto an outer portion of the conductive unit and made of a PVC material, and a coating film formed outside the insulating sheath. Here, the coating film may be formed by curing a coating solution including at least one monomer selected from the group consisting of a silane compound and a siloxane compound.