Nozzle is provided for heat sealing, as well as methods of use thereof. Nozzle includes blade with leading edge and trailing edge having an opening for air to exit. Opening communicates with hot air tool through internal channel of blade and bore of attachment for nozzle. Blade may be bent to improve interposition of blade between material(s) to be seamed or sealed. Linear edges, curvilinear edges, stepped edges, or any combination thereof, define air exit opening. Nozzle directs hot air downstream from nozzle and perpendicular to nozzle's trailing edge. With blade interposed between material(s), hot air is directed parallel to direction of flow of material(s) in process flow. Hot air heats material(s) to a fusion temperature, or a thermoset to its activation temperature, provided along a forming region of seal or seam. Compressive force applied to material downstream from nozzle assists contact of melted material to form seal or seam.

A bonding and slitting device is adapted to form fin seams in absorbent articles having a front waist region, a back waist region, and a crotch region extending between the front waist region and the back waist region. The device includes a first bonding member and a second bonding member having a contact element configured to cooperate with the first bonding member to bond the front region of the chassis to the back region to define the fin seams. A slitter is configured to simultaneously act on material outboard of the bonds from both the front and back regions of the chassis.

A bonding and slitting device is adapted to form fin seams in absorbent articles having a front waist region, a back waist region, and a crotch region extending between the front waist region and the back waist region. The device includes a first bonding member and a second bonding member having a contact element configured to cooperate with the first bonding member to bond the front region of the chassis to the back region to define the fin seams. A slitter is configured to simultaneously act on material outboard of the bonds from both the front and back regions of the chassis.

A continuous reinforced cold water pipe (CWP) for an Ocean Thermal Energy Conversion (OTEC) system is formed from a sequential series of molded pipe sections, which are formed from a series of rigid frame sections and a curable material to form the continuous reinforced CWP. Each molded pipe section is formed by moving a rigid frame section into a mold, enclosing at least a portion of the rigid frame section in the curable material, and curing the curable material. As each molded pipe section is moved out of the mold, the next sequential rigid frame section, which is connected to the previous rigid frame section, is moved into the mold. The cycle is repeated as many times as required to form the continuous reinforced CWP having a desired length.

A physically crosslinked, closed cell continuous multilayer foam structure comprising at least one polypropylene/polyethylene coextruded foam layer is obtained. The multilayer foam structure is obtained by coextruding a multilayer structure comprising at least one foam composition layer, irradiating the coextruded structure with ionizing radiation, and continuously foaming the irradiated structure.

Peelable seals including porous inserts are described. An example peelable seal includes a porous insert positioned between a first sheet and a second sheet. The porous insert includes a plurality of interwoven strands and a plurality of pores adjacent the interwoven strands through which a bond is formed between the first sheet and the second sheet when heat is applied to at least one of the first sheet, the second sheet or the porous insert.

Peelable seals including porous inserts are described. An example peelable seal includes a porous insert positioned between a first sheet and a second sheet. The porous insert includes a plurality of interwoven strands and a plurality of pores adjacent the interwoven strands through which a bond is formed between the first sheet and the second sheet when heat is applied to at least one of the first sheet, the second sheet or the porous insert.

A system for halogenating olefinic-based elastomer, the system comprising a first extruder, a first kneader vessel downstream of said first extruder and in fluid communication with said first extruder, a second extruder downstream of said first kneader vessel and in fluid communication with said first kneader vessel, a second kneader vessel downstream of said second extruder and in fluid communication with said second extruder; and a third extruder downstream of said second kneader vessel and in fluid communication with said second kneader vessel.

Provided is a thermoplastic resin film laminate, which is obtained by ultrasonic welding of a thermoplastic resin film and a thermoplastic resin molded article, and which has high welding strength and excellent appearance with less welding marks. The above-described problem is solved by a thermoplastic resin film laminate which is obtained by bonding, by ultrasonic welding, a thermoplastic resin film having a thickness of 0.4 mm or less and a welding margin of a thermoplastic resin molded article having the welding margin and having a thickness of 0.5 mm or more, and wherein the height of the welding margin is 75-125% of the thickness of the thermoplastic resin film.

Provided is a thermoplastic resin film laminate, which is obtained by ultrasonic welding of a thermoplastic resin film and a thermoplastic resin molded article, and which has high welding strength and excellent appearance with less welding marks. The above-described problem is solved by a thermoplastic resin film laminate which is obtained by bonding, by ultrasonic welding, a thermoplastic resin film having a thickness of 0.4 mm or less and a welding margin of a thermoplastic resin molded article having the welding margin and having a thickness of 0.5 mm or more, and wherein the height of the welding margin is 75-125% of the thickness of the thermoplastic resin film.