An electronic device includes a fascia manufactured from a shape memory polymer. One or more thermal elements can be disposed adjacent to the fascia or integrated into the fascia. One or more processors can be operable with the one or more thermal elements to detect deformation along at least a portion of the fascia and cause the one or more thermal elements to selectively apply heat to the shape memory polymer along at least a portion of the fascia to reverse at least some of the deformation.

An electronic device includes a fascia manufactured from a shape memory polymer. One or more thermal elements can be disposed adjacent to the fascia or integrated into the fascia. One or more processors can be operable with the one or more thermal elements to detect deformation along at least a portion of the fascia and cause the one or more thermal elements to selectively apply heat to the shape memory polymer along at least a portion of the fascia to reverse at least some of the deformation.

A soap recycling assembly for recycling soap pieces into soap bars includes a housing that defines an internal space. A power module and a heater are coupled to the housing and are positioned in the internal space. The heater is selectively operationally couplable to the power module. A first recess is positioned in a top of the housing. A plurality of legs is pivotally coupled to a bottom of the housing. The legs are positioned to reversibly pivot from a stowed configuration to a deployed configuration, wherein the legs are positioned substantially perpendicular to the bottom. The first recess is configured to insert soap pieces. The power module is positioned to couple to the heater to heat the soap pieces to a melt. The power module is positioned to decouple from the heater wherein the melt solidifies to a bar of soap.

A soap recycling assembly for recycling soap pieces into soap bars includes a housing that defines an internal space. A power module and a heater are coupled to the housing and are positioned in the internal space. The heater is selectively operationally couplable to the power module. A first recess is positioned in a top of the housing. A plurality of legs is pivotally coupled to a bottom of the housing. The legs are positioned to reversibly pivot from a stowed configuration to a deployed configuration, wherein the legs are positioned substantially perpendicular to the bottom. The first recess is configured to insert soap pieces. The power module is positioned to couple to the heater to heat the soap pieces to a melt. The power module is positioned to decouple from the heater wherein the melt solidifies to a bar of soap.

A process for manufacturing a non-degumming, seamless and surface-laminated basketball, comprising the steps of: step 1: wrapping the inner bladder by threads, thereby shaping the carcass; step 2: preparing the uncured foamed middle bladder; step 3: preparing the half-finished PU surface-laminated ball; step 4: placing the half-finished leather ball obtained from step 3 into a curing mold; subsequently, curing under low temperature and low pressure via the thermal cross-linking method, thereby forming the cured PU foamed basketball; Step 5: testing the air-holding performance of the PU foamed basketball being cured under a low temperature and mounting the air nozzle, thereby obtaining the finished basketball; by means of the present invention, the prior curing process of the middle bladder and related downstream process can be saved.

A process for manufacturing a non-degumming, seamless and surface-laminated basketball, comprising the steps of: step 1: wrapping the inner bladder by threads, thereby shaping the carcass; step 2: preparing the uncured foamed middle bladder; step 3: preparing the half-finished PU surface-laminated ball; step 4: placing the half-finished leather ball obtained from step 3 into a curing mold; subsequently, curing under low temperature and low pressure via the thermal cross-linking method, thereby forming the cured PU foamed basketball; Step 5: testing the air-holding performance of the PU foamed basketball being cured under a low temperature and mounting the air nozzle, thereby obtaining the finished basketball; by means of the present invention, the prior curing process of the middle bladder and related downstream process can be saved.

In a method for processing a fiber compound structure, an unhardened fiber layer is arranged on a surface section of the fiber compound structure. A pressure cushion is arranged above the surface section. The pressure cushion has a pressure cap and a pressure-tight cap mat pressure-tightly connected to a circumferential border of the pressure cap such that the cap mat limits a pressure area together with the pressure cap. An overpressure in the pressure area is generated. The pressure cushion is pressed onto the fiber compound structure such that the overpressure presses the cap mat against the fiber layer while supporting the fiber compound structure on a side of the fiber compound structure that is opposed to the surface section. The fiber layer is hardened

In a method for processing a fiber compound structure, an unhardened fiber layer is arranged on a surface section of the fiber compound structure. A pressure cushion is arranged above the surface section. The pressure cushion has a pressure cap and a pressure-tight cap mat pressure-tightly connected to a circumferential border of the pressure cap such that the cap mat limits a pressure area together with the pressure cap. An overpressure in the pressure area is generated. The pressure cushion is pressed onto the fiber compound structure such that the overpressure presses the cap mat against the fiber layer while supporting the fiber compound structure on a side of the fiber compound structure that is opposed to the surface section. The fiber layer is hardened

The present invention is directed to a system and method for making hollow foam balls and other molded objects. A mold is provided that is moveable between an open position and a closed position. A raw material is loaded into a plurality of molding cavities of the mold when the mold is in its open position, and a first alternating electric field is applied across the mold to heat the raw material in the molding cavities and thereby form a plurality of molded pieces. The mold is then moved from its open position to its closed position whereby a first group of molded pieces is aligned with a second group of molded pieces. A second alternating electric field is applied across the mold to heat bond the first group of molded pieces with the second group of molded pieces and thereby form a plurality of molded objects. Finally, the mold is moved from its closed position to its open position to enable unloading of the molded objects from the mold.

The present invention is directed to a system and method for making hollow foam balls and other molded objects. A mold is provided that is moveable between an open position and a closed position. A raw material is loaded into a plurality of molding cavities of the mold when the mold is in its open position, and a first alternating electric field is applied across the mold to heat the raw material in the molding cavities and thereby form a plurality of molded pieces. The mold is then moved from its open position to its closed position whereby a first group of molded pieces is aligned with a second group of molded pieces. A second alternating electric field is applied across the mold to heat bond the first group of molded pieces with the second group of molded pieces and thereby form a plurality of molded objects. Finally, the mold is moved from its closed position to its open position to enable unloading of the molded objects from the mold.