A nozzle includes a back plate having a first inlet passage and a first discharge opening at one end of the first inlet passage, a front plate and a plurality of nozzle plates secured between the back plate and the front plate. The plurality of nozzle plates includes a first plenum plate, a second plenum plate and a discharge plate. The first plenum plate has a first plenum, the second plenum plate has a second plenum and a second plenum projection extending into the second plenum, and the discharge plate is disposed between the first plenum plate and the second plenum plate and has one or more orifices. The first plenum is disposed in fluid communication with the first inlet passage and is configured to receive a first fluid from the first inlet passage via the first discharge opening. The one or more orifices are disposed in fluid communication with the first plenum and are configured to receive the first fluid from the first plenum. The one or more orifices each include an orifice opening at an edge of the discharge plate configured to discharge the first fluid.

According to one embodiment, a system for manufacturing a polymethyl methacrylate (PMMA) prepreg includes a mechanism for continuously moving a fabric or mat and a resin application component that applies a methyl methacrylate (MMA) resin to the fabric or mat. The system also includes a press mechanism that presses the fabric or mat during the continuous movement subsequent to the application of the MMA resin to ensure that the MMA resin fully saturates the fabric or mat. The system further includes a curing oven through which the fabric or mat is continuously moved. The curing oven is maintained at a temperature of between 40 C. and 100 C. to polymerize the MMA resin and thereby form PMMA so that upon exiting the curing oven, the fabric or mat is fully impregnated with PMMA.

According to one embodiment, a coating apparatus includes a backup roll, a die disposed below the backup roll, a bending device disposed below the die, and a die pressing module provided on an upper surface of the bending device. The die includes a base module, a first body erected from a rear part of an upper surface of the base module, a second body combined with a front surface of the first body, a mount space formed between a front part of the upper surface of the base module and a lower surface of the second body, a liquid storage module for a coating liquid, a liquid passage for the coating liquid, a slit-like discharge port for the coating liquid, and a shim sandwiched between the first body and the second body.

Provided is a slot die with variable manifolds and a controlling method thereof. The slot die with the variable manifolds, which applies ink on a substrate to perform a coating process, includes: a first body having a length corresponding to a width of the substrate and having a cavity configured to accommodate the ink supplied from the outside; a second body having a length corresponding to the first body and having an discharge port, from which the ink is discharged, formed in one side thereof when the second body is coupled to the first body; a plurality of variable manifolds disposed in the cavity in a width direction of the substrate and installed so as to reciprocate in the cavity; and a plurality of manifold drivers disposed at one side of the first body and connected to the plurality of variable manifolds to allow the plurality of variable manifolds to reciprocate, respectively, wherein each of the plurality of variable manifolds is independently driven according to a state of the ink coated on the substrate and adjusts a partial discharge amount of the ink discharged from the discharge port by changing a partial volume of the cavity at an arrangement position thereof.

A mechanism for applying a predetermined pattern of material onto an elongate tubular substrate includes a first motor, an engagement member rotatable by the first motor and configured to reversibly grasp an elongate member, such that rotation of the first motor rotates the elongate member around its longitudinal axis, a fluid dispenser configured to dispense a fluid having a first, flowable state, the fluid dispenser including an elongate dispensing conduit having a distal end having an orifice, the orifice configured to be placed adjacent a surface of the elongate member, a second motor configured to move at least one of the elongate member or the elongate dispensing conduit such that the orifice changes its relative orientation along the longitudinal axis of the elongate member, and wherein the distal end of the elongate dispensing conduit is configured to apply a bias on the surface of the elongate member.

A preform coating device is provided with: a plurality of rotational holding parts that horizontally hold a preform; a conveyance part that conveys the preform by moving the plurality of rotational holding parts, the plurality of rotational holding parts being disposed at a predetermined interval along the conveyance route of the conveyance part; and a dispenser that discharges a coating liquid toward the preform. The dispenser has: a head including a mechanism for feeding the coating liquid; and a plurality of nozzles that are in fluid communication with the head and that each include a slot for discharging the coating liquid. The plurality of nozzles are disposed at a predetermined interval along the conveyance route. The interval between the plurality of nozzles is equal to the interval between the plurality of rotational holding parts.

The present invention provides a preform coating device (5) provided with: a rotating and holding part (9) that holds a preform (1) in a horizontal direction, and rotates the preform (1) about an axis (A) of the preform (1); and a dispenser (6) that has a slot (62) and discharges a coating liquid in a plane form from the slot (62) to the preform (1), wherein the discharge direction of the coating liquid is the direction of the normal to an outer peripheral surface of the preform (1).

The invention relates to a method for producing an adhesive tape, by: providing a tapelike textile carrier (2),

applying a thickener (7) and separately aqueous dispersion-based adhesive (8) to the textile carrier (2), the thickener (7) and the aqueous dispersion-based adhesive (8) coming into contact with each other once applied, then drying the dispersion-based adhesive (8).

Provided is a slot die with variable nozzles. The slot die with variable nozzles, which applies ink on a substrate to perform a coating process, includes: a first body having a cavity configured to accommodate ink supplied from the outside; a second body spaced apart from the first body in a transfer direction of a substrate or a direction opposite to the transfer direction; a shim plate coupled between the first body and the second body and having an discharge port configured to communicate with the cavity and discharge ink accommodated in the cavity toward the substrate; and a plurality of variable nozzles disposed at a lower end of the first body or the second body in a width direction of the substrate so as to be adjacent to the discharge port, wherein each of the plurality of variable nozzles is independently driven according to a state of the ink coated on the substrate and adjusts a partial discharge amount of the ink discharged from the discharge port by changing a partial area of the discharge port at an arrangement position thereof.

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