An apparatus for accurately coating discrete patches of coating on a moving substrate is described. The coating system applies coating to a moving substrate using a coating distribution device. A flow pump pumps the coating from a reservoir into the coating distributing device where a portion of the coating is deposited and the remainder is allowed to returned back to the reservoir. The coating distribution device selectively meters a portion of the coating it receives from the flow pump onto the substrate at a variable rate. When the coating distribution device transitions from metering to not metering and to reverse metering, it induces a vacuum in the coating distribution device. The induced vacuum causes a portion of the coating being distributed onto the substrate to flow in reverse quickly breaking the deposition of the coating.

Nozzle assemblies and methods of bonding fabric by jetting an adhesive are disclosed. A method of bonding fabrics with an adhesive includes receiving the adhesive from an adhesive supply into a nozzle assembly. The nozzle assembly has a valve seat, a valve stem configured to slidably move towards and away from the valve seat, and a plurality of outlet channels. The method further includes jetting the adhesive from the plurality of outlet channels onto a first fabric and applying a second fabric to the first fabric to adhere the first and second fabrics to each other.

An adhesive dispensing system and method of dispensing liquid material are disclosed. The adhesive dispensing system includes an adhesive dispensing module receiving hot melt adhesive through the inlet at a low pressure and rapidly developing high pressure at an outlet to thereby jet the hot melt adhesive therefrom. The system also includes a pressure container containing a supply of hot melt adhesive and configured to melt or maintain a heated temperature of the hot melt adhesive. A low pressure liquid passageway communicates between the adhesive dispensing module and the pressure container. The system also includes a pressurized air source in fluid communication with the adhesive dispensing module to operate the adhesive dispensing module by moving a piston to generate high pressure at the outlet of a nozzle for jetting hot melt adhesive as a discrete volume toward a substrate.

Coating apparatuses and methods are provided for direct coatings with various shapes. The coating apparatus includes a die body with one or more bores. One or more cams are pivotally mounted within the bores and have one or more recessed areas formed into the respective peripheral surfaces thereof. The one or more cams are rotatable within the die body to dynamically, independently vary the width or shape of the respectively dispensed one or more fluid coatings.

A coating apparatus includes: a coating manifold for supplying a coating liquid to a base material; a supply channel for supplying the coating liquid to the coating manifold; and a connection channel connecting the supply channel to the coating manifold. The connection channel includes at least one branch portion, and the at least one branch portion branches into two branch channels that are equal to each other in channel distance.

A suck-back type coating gun unit characterized in that a needle, which is formed into a single body with a movable valve body of a valve mechanism, is provided, and a cam-type valve driving mechanism, which includes a cam that is at its cam surface in contact with the tip end of the needle, is provided. In this suck-back type coating gun unit, a cam-type valve driving mechanism that makes stroke motions is configured in which the rotational operation of the cam body is converted into a stroke operation to make a valve ON and OFF operation of the hot melt coating gun unit, so that the ON operation is made by the ridge portion of the cam body and the OFF operation is made by the valley portion of the cam body,

[PROBLEM] To improve distribution of adhesive and gas.

[SOLUTION] A nozzle (1) includes a pattern shim (13) having a plurality of first slits (23) and a plurality of second slits (24), an adhesive shim (12) having a plurality of first holes (33), a gas shim (14), a head body (11) having an adhesive outlet (52) and an adhesive distribution groove (51) communicating with the adhesive outlet, and a face plate (15). Adhesive ejection ports are formed at openings of the plurality of first slits, and gas discharge ports are formed at openings of a plurality of second slits in such a manner that the gas discharge ports are located on both sides of each of the adhesive ejection ports. The plurality of first holes (33) communicate with the adhesive distribution groove (51). The plurality of first holes (33) are formed in such a manner that distances of the first holes (33) from the corresponding discharge ejection ports (6) become shorter as distances of the corresponding first holes from the adhesive outlet (52) become longer.

A drench system includes a rotating mount to rotate a workpiece, a showerhead to dispense a fluid onto the workpiece; and a tray to collect the fluid and recirculate the fluid to the shower. A method of repairing or remanufacturing a coating includes abrading a surface to at least partially remove a portion of a coating to leave an abraded surface; applying a sol-gel over the abraded surface; applying a corrosion resistant primer onto the sol-gel; and applying an erosion coating onto the corrosion resistant primer.

[PROBLEM] To improve distribution of adhesive and gas.

[SOLUTION] A nozzle (1) includes a pattern shim (13) having a plurality of first slits (23) and a plurality of second slits (24), an adhesive shim (12) having a plurality of first holes (33), a gas shim (14), a head body (11) having an adhesive outlet (52) and an adhesive distribution groove (51) communicating with the adhesive outlet, and a face plate (15). Adhesive ejection ports are formed at openings of the plurality of first slits, and gas discharge ports are formed at openings of a plurality of second slits in such a manner that the gas discharge ports are located on both sides of each of the adhesive ejection ports. The plurality of first holes (33) communicate with the adhesive distribution groove (51). The plurality of first holes (33) are formed in such a manner that distances of the first holes (33) from the corresponding discharge ejection ports (6) become shorter as distances of the corresponding first holes from the adhesive outlet (52) become longer.

A robotic placement machine including a base operably connected to the Y axis actuator and the X axis actuator, a first Z axis actuator coupled to the first end of the base, the first Z axis actuator capable of moving up and down a first Z axis, a second Z axis actuator coupled to the second end of the base, the second Z axis actuator capable of moving up and down a second Z axis, and a pick and place plate operably connected to the first Z axis actuator and the second Z axis actuator, wherein the first Z axis actuator and the second Z axis actuator are each capable of moving independently of each other to tilt the pick and place plate is provided. Furthermore, a system comprising a first machine, second machine, and third machine to eliminate air bubbles when bonding two substrates is also provided. A method of optical bonding is further provided.