In a coating device wherein a relative movement between an application nozzle located above a coated object W and the coated object is effected to apply a coating liquid P in a coating liquid reservoir of the application nozzle onto a surface of the coated object via a slit-shaped discharge port, the coating device includes: a shutter member rotatable in the coating liquid reservoir to open or close space between the coating liquid reservoir and the slit-shaped discharge port; and a gas feed regulation means for regulating the pressure on the coating liquid in the coating liquid reservoir, and is characterized in that in a state where the gas feed regulation means maintains the pressure on the coating liquid in the coating liquid reservoir to be at a given level, the shutter member is rotated to open or close space between the coating liquid reservoir and the slit-shaped discharge port.

A coating die head may comprise: a coating main body comprising a first die head and a second die head arranged separately, the first die head and the second die head being spliced to define an accommodating cavity, and opposite ends of the coating main body being respectively provided with a coating inlet and a coating outlet which are in communication with the accommodating cavity; and a turbulence assembly which defines a flow channel with a cavity wall of the accommodating cavity, the turbulence assembly being adjustably arranged in the accommodating cavity.

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.

An applicator for dispensing adhesive onto a substrate is described. The applicator includes a manifold and at least one dispensing module coupled to the manifold. The applicator may include a least one pump assembly removably mounted to the manifold. Each pump assembly can have an outlet in flow communication with the manifold, and an inlet in flow communication with the adhesive. The use of a removable, independently controllable pump assembly can provide an operator of the applicator greater flexibility during adhesive dispensing.

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 method for controlling a recirculation pump assembly is disclosed. The method includes receiving a process-dependent characteristic and determining a recirculation flow rate of adhesive that flows to the recirculation pump assembly based on the process-dependent characteristic. The method further includes determining a recirculation pump speed of the recirculation pump assembly for pumping the adhesive to a supply channel using the recirculation flow rate, and adjusting an operating speed of the recirculation pump assembly to match the recirculation pump speed. A system and storage device for performing the above method are also disclosed.

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.

In one example, an application system has a material supply system, a plurality of dispensers, a plurality of pumps, and a controller. The supply system can supply the liquified material to the pumps. The pumps can pump the liquified material to the plurality of dispensers, and the dispensers can dispense the liquified material onto a substrate. The controller can receive, for the pumps, measures of electrical current drawn by the pumps. The controller can determine an average electrical current by averaging the measures of the electrical current drawn by the pumps. The controller can generate, for each of one or more of the pumps, a metric based on the average current, wherein the metric is indicative of how soon the pump is likely to fail. Maintenance and/or replacement of the pump can then be scheduled based on the metric.

An application unit (13) comprises a rotation unit (26) and a support unit (27). The rotation unit (26) comprises a nozzle unit (28), a nozzle support part (29), a body base (30), a first supply part (31), a second supply part (32), a third supply part (33), a valve (34), and a motor (35). The nozzle support part (29) rotatably supports the nozzle unit (28) such that the central axis of the nozzle unit (28) is inclined with respect to the rotation axis of the rotation unit (26).

A method for controlling a recirculation pump assembly is disclosed. The method includes receiving a process-dependent characteristic and determining a recirculation flow rate of adhesive that flows to the recirculation pump assembly based on the process-dependent characteristic. The method further includes determining a recirculation pump speed of the recirculation pump assembly for pumping the adhesive to a supply channel using the recirculation flow rate, and adjusting an operating speed of the recirculation pump assembly to match the recirculation pump speed. A system and storage device for performing the above method are also disclosed.