The present invention relates to bead foams made of thermoplastic polyurethane and polystyrene produced moldings, to processes for the production of the bead foams and moldings, and also to the use of the moldings for shoe intermediate soles, shoe insoles, shoe combisoles, or cushioning elements for shoes.

The present invention relates to bead foams made of thermoplastic polyurethane and polystyrene produced moldings, to processes for the production of the bead foams and moldings, and also to the use of the moldings for shoe intermediate soles, shoe insoles, shoe combisoles, or cushioning elements for shoes.

Low-density thermoplastic expandable microspheres are disclosed. Various low-density structures, in particular, sandwich panels, based on foam prepared from the low-density microspheres, are also disclosed. Process of preparing low-density polymeric microspheres, per se, and the corresponding low-density structures, based on the microsphere foam, are also disclosed.

Low-density thermoplastic expandable microspheres are disclosed. Various low-density structures, in particular, sandwich panels, based on foam prepared from the low-density microspheres, are also disclosed. Process of preparing low-density polymeric microspheres, per se, and the corresponding low-density structures, based on the microsphere foam, are also disclosed.

A process for forming voided latex particles is improved by combining swelling and polymerization of an outer shell into a single step. The process includes contacting multi-stage emulsion polymer particles comprising a core, at least one intermediate shell, with a swelling agent, and polymerizing an outer shell after said contacting with swelling agent wherein the core and the at least one intermediate shell are contacted with swelling agent in the presence of less than 0.5% monomer based on the weight of the multi-stage emulsion polymer particles, and substantially all of the swelling occurs during polymerization of the outer shell.

Disclosed are porous elements that include sintered polymeric particles. The polymeric particles can be formed of a thermoplastic composition that includes a polyarylene sulfide. The polymeric particles sintered to form the porous elements have a very narrow size distribution. The porous elements can maintain their functionality and morphology even when utilized in high temperature applications.

Disclosed are porous elements that include sintered polymeric particles. The polymeric particles can be formed of a thermoplastic composition that includes a polyarylene sulfide. The polymeric particles sintered to form the porous elements have a very narrow size distribution. The porous elements can maintain their functionality and morphology even when utilized in high temperature applications.

A polymer composition can be used for selective absorbing sintering, SAS, or selective inhibition sintering, SIS. The polymer has open mesopores and the cumulative pore volume distribution of the mesopores, measured to DIN 66134, is at least 0.01 cm.sup.3/g.

Disclosed are a three-dimensional porous structure, a method of preparing the same, and applications thereof. The method includes coating a coating material including coal ash on a surface of a combustible organic particle to form a core-shell particle, wherein the core-shell particle includes a combustible organic particle core, and a coating shell covering at least a portion of the combustible organic particle surface; mixing a plurality of the core-shell particles with an organic or inorganic binder to form a three-dimensional structure in which the core-shell particles are bonded to each other; and performing thermal treatment of the three-dimensional structure, wherein in the thermal treatment of the three-dimensional structure, at least portion of the combustible organic particle in the core-shell particle is removed away, thereby forming a hollow inside the particle core, and forming a number of fine pores in the coating shell.

Disclosed are a three-dimensional porous structure, a method of preparing the same, and applications thereof. The method includes coating a coating material including coal ash on a surface of a combustible organic particle to form a core-shell particle, wherein the core-shell particle includes a combustible organic particle core, and a coating shell covering at least a portion of the combustible organic particle surface; mixing a plurality of the core-shell particles with an organic or inorganic binder to form a three-dimensional structure in which the core-shell particles are bonded to each other; and performing thermal treatment of the three-dimensional structure, wherein in the thermal treatment of the three-dimensional structure, at least portion of the combustible organic particle in the core-shell particle is removed away, thereby forming a hollow inside the particle core, and forming a number of fine pores in the coating shell.