The present invention provides an adhesive application device configured to apply a necessary and sufficient amount of an adhesive to a thin steel strip without causing the problem of increase in the equipment cost. The present invention also provides an apparatus for producing a laminated steel core having the adhesive application device. The present invention further provides a method for producing a laminated steel core. The adhesive application device comprises adhesive application devices (3), (4) that are integrated into a single process, wherein the adhesive application devices (3), (4) are configured to independently apply an adhesive to different locations on the same surface of a thin steel strip (2) at the same or different timings.

According to an embodiment, a winding apparatus includes a winding core and an air flow controller. The winding core winds a belt-shaped structure comprising a substrate and an edge-coating part that covers an edge of a substrate in a width direction, the edge-coating part being coated with a material liquid on a surface of the substrate. The air flow controller has a nozzle that performs at least either ejection or suction of a gas, and adjusts an air flow in the vicinity of the edge-coating part of the film of the belt-shaped structure, which is wound by a winding core.

A device for interruption-free coating of can bodies with a coating liquid comprises an inlet container for providing the coating liquid to be applied, a pressurized air source for supplying pressurized air, an application nozzle for spraying the coating liquid with an application pressure onto the container body. An intermediary container is provided, which is connected on the inlet side to the inlet container by means of the inlet pipe and which is connected on the outlet side to the application nozzle by means of an outlet pipe.

In front view of the application nozzle, all of the pressurized air flow K and adhesive flow H are made to run parallel to each other in the vertical direction. Of the pressurized air flows K from the pressurized air hole b in the pressurized air plate, the two that are located on one side of the adhesive hole opening a and from a pair in the front-to-back direction are tilted so as to approach each other. The extension lines thereof are located on the side of the adhesive bead, which results from the adhesive flow discharged from the adhesive hole opening, and have directions that converge. The respective pressurized air flows on the two side of the adhesive bead are made to flow downward while uniting in the direction of convergence. A web in which the adhesive bead is elongated while being swung in the transverse direction is formed and, near the bottom surface of the application nozzle, a non-interference space Q is formed between the adhesive bead and the fore pressurized air flow. The adhesive bead, resulting from the adhesive flow discharged from the adhesive hole opening, and the pressurized air flows do not interfere with each other and walls R of pressurized air flows are formed below the non-interference space Q and on either side of the adhesive bead.

A gluing device has a sheet guide for guiding a corrugated fiberboard; a basal part having a fixed relative position with respect to the sheet guide; a support part moveable with respect to the basal part; a glue gun for contacting and applying glue to a glued portion within a seam margin at a side edge of a corrugated fiberboard passing through the sheet guide; a first energizing mechanism for energizing the support part towards the sheet guide; a second energizing mechanism for energizing the support part away from the sheet guide; and a position adjustment mechanism arranged between the first energizing mechanism and the basal part, for steples sly adjusting the position of the support part in a direction lying in the direction of the force exerted by the first energizing mechanism, and adjusting the gap between the glue gun and the sheet guide.

Aspects of the methods and apparatuses relate to making elastic laminates, and more particularly, methods and apparatuses for applying elastic material in a curved path onto an advancing substrate. The elastic material may be in various forms, such as for example, elastic strands and/or ribbons. Apparatuses and methods disclosed herein may also provide for the application of viscous fluids, such as adhesives, in pre-determined patterns to the elastic material while being positioned on an advancing substrate.

The invention relates to a device (100) for applying a foaming reaction mixture (600) onto a top layer (500), in particular for producing a composite element, comprising at least one casting rake (200, 260) with a tubular hollow body (210), said hollow body (210) extending along a central axis (250) and having at least two outlet openings (220) for discharging the foaming reaction mixture (600). The casting rake (200, 260) and the top layer (500) can be moved relative to each other along a longitudinal axis (510). According to the invention, the central axis (250) of the at least one casting rake (200, 260) and the longitudinal axis (510) of the movement form an angle (400, 410) of <=80 DEG relative to each other.

A new and improved hot melt adhesive or other thermoplastic material dispensing system comprises two separate and independent rotary gear-type metering pumps with two separate and independent supply sources and fluid supply passageways, or two separate and independent sets of rotary gear-type metering pumps with two separate and independent supply sources and fluid supply passageways, which are able to independently output precisely metered amounts of the hot melt adhesive materials simultaneously onto a particularly substrate through suitable output devices so as to result in a multitude of different hot melt adhesive patterns and at different locations.

The invention relates to a device (100) for applying a foaming reaction mixture (600) onto a top layer (500), in particular for producing a composite element, comprising at least two casting rakes (200, 260), each of which comprises a tubular hollow body (210), said hollow body (210) extending along a central axis (250) and having at least two outlet openings (220) for discharging the foaming reaction mixture (600). The casting rakes (200, 260) and the top layer (500) can be moved relative to one another in a longitudinal axis (510), and the casting rakes (200, 260) are arranged on a receiving element (700). According to the invention, each arrangement of the casting rakes (200, 260) on the receiving element (700) has a joint (805), by means of which the casting rakes (200, 260) are movably arranged on the receiving element (700) and can be oriented at an angle (400, 410) of <=80 DEG relative to the longitudinal axis (510) of the movement.

A fluid application device having a contact nozzle assembly with a fluidic oscillator is provided. The fluid application device includes an applicator head and a nozzle assembly. The nozzle assembly includes a first conduit configured to receive a first fluid from the applicator head, a second conduit configured to receive a second fluid from the applicator head and an application conduit including a receptacle and first and second branches. The receptacle is fluidically connected with the first conduit and configured to receive the first fluid. The first and second branches are fluidically connected to the second conduit and receptacle and are configured to receive the second fluid. The nozzle assembly further includes an orifice fluidically connected to the application conduit and configured to discharge the first fluid for application onto a strand of material, and a guide slot extending from the orifice and configured to receive the strand of material.