Crosslinkable adhesive compound comprising at least a first base polymer component having functional groups suitable for covalent crosslinking and for coordinative crosslinking, and comprising at least one covalent crosslinker and at least one coordinative crosslinker, wherein the coordinative crosslinker is present in molar excess in relation to the covalent crosslinker.

A polychromatic effects heat transfer label includes a carrier and a polychromatic effects design layer on the carrier. The polychromatic effects design layer is formulated from an ink having a polychromatic effects pigment present in a concentration of about 1 percent to about 25 percent by weight of the ink. The polychromatic effects heat transfer label is transferred from the carrier to an apparel item as a polychromatic effects feature and the polychromatic effects feature exhibits robust polychromatic effects on the item. The polychromatic effects feature exhibits no adhesion failure, no color change, no stain, and no visual change after being subjected to a Nike standard embellishment durability wash tests of an accelerated wash, 5 times at a temperature of 60° C. and an innovation standard wash, 15 times at a temperature of 60° C., and being tumbled dry after each wash and exhibits no color transfer, no abrasion and no visual change after being subjected to an AATCC standard crock test, 10 crocks with an SDLATLAS CM-5 AATCC crockmeter and an TIC crockmeter using 2″×2″ squares. Polychromatic effects heat transfer labels for transfer to plastic, carbon fiber and metal are disclosed.

A polychromatic effects heat transfer label includes a carrier and a polychromatic effects design layer on the carrier. The polychromatic effects design layer is formulated from an ink having a polychromatic effects pigment present in a concentration of about 1 percent to about 25 percent by weight of the ink. The polychromatic effects heat transfer label is transferred from the carrier to an apparel item as a polychromatic effects feature and the polychromatic effects feature exhibits robust polychromatic effects on the item. The polychromatic effects feature exhibits no adhesion failure, no color change, no stain, and no visual change after being subjected to a Nike standard embellishment durability wash tests of an accelerated wash, 5 times at a temperature of 60° C. and an innovation standard wash, 15 times at a temperature of 60° C., and being tumbled dry after each wash and exhibits no color transfer, no abrasion and no visual change after being subjected to an AATCC standard crock test, 10 crocks with an SDLATLAS CM-5 AATCC crockmeter and an TIC crockmeter using 2″×2″ squares. Polychromatic effects heat transfer labels for transfer to plastic, carbon fiber and metal are disclosed.

Disclosed are an anisotropic conductive adhesives for thermo-compression bonding containing solder conductive particles and flux aciditives and a method of connecting electronic parts using the same. The anisotropic conductive adhesives for thereto-compression bonding may include a flux activator, solder particles and polymer resin.

A tissue adhesive material that provides fast and robust adhesion even on tissue surfaces covered in bodily fluids. The tissue adhesive material is formed of a hydrophobic matrix and a plurality of bioadhesive microparticles dispersed within the hydrophobic matrix configured such that disposing the adhesive material directly on a fluid covered surface and applying pressure causes the (a) hydrophobic matrix to repel the fluid, (b) the bioadhesive particles to compress forming an adhesive layer, and (c) the bioadhesive particles to form temporary crosslinks followed by covalent crosslinks with the surface.

The disclosure discloses an adhesive tape cartridge including an adhesive tape roll. The adhesive roll winds an adhesive tape around a predetermined axis in a housing. The adhesive tape includes a base layer, a first particle-containing adhesive layer, and a second particle-containing adhesive layer. The first particle-containing adhesive layer is disposed on a first side of the base layer in a thickness direction and comprises an adhesive to which particles are added. The second particle-containing adhesive layer is disposed in contact with a surface on the first side of the first particle-containing adhesive layer in the thickness direction and comprises an adhesive to which particles of the same material as the particles are added.

The disclosure discloses an adhesive tape cartridge including an adhesive tape roll. The adhesive roll winds an adhesive tape around a predetermined axis in a housing. The adhesive tape includes a base layer, a first particle-containing adhesive layer, and a second particle-containing adhesive layer. The first particle-containing adhesive layer is disposed on a first side of the base layer in a thickness direction and comprises an adhesive to which particles are added. The second particle-containing adhesive layer is disposed in contact with a surface on the first side of the first particle-containing adhesive layer in the thickness direction and comprises an adhesive to which particles of the same material as the particles are added.

A teat opening protection patch is stuck to portions inclusive of the teat openings of livestock, and includes a laminate 1 of an elastic sheet 2 and an adhesive layer 3 laminated on one surface of the elastic sheet 2, the laminate 1 having a double-stretched tensile stress in a range of 0.1 to 5 N.

A teat opening protection patch is stuck to portions inclusive of the teat openings of livestock, and includes a laminate 1 of an elastic sheet 2 and an adhesive layer 3 laminated on one surface of the elastic sheet 2, the laminate 1 having a double-stretched tensile stress in a range of 0.1 to 5 N.

A mounting method includes: a stacking step PC1 of stacking an adhesive layer AL containing swell grains SG that swell when predetermined energy HT is applied, on a projection-formed surface WF1 of a work WF, the projection-formed surface WF1 having projections BP formed thereon; a mounting step PC4 of bringing the projections BP into contact with a support LF to attach, to the support LF, the work WF on which the adhesive layer AL is stacked; and an energy applying step PC5 of applying the energy HT to the adhesive layer AL to swell the swell grains SG, thereby making contact regions of the adhesive layer AL with the support LF larger than before swelling the swell grains SG.