A device for coating material with resin and subsequently laying the material saturated with the resin onto a surface, the device comprising a vessel for retaining the resin, the vessel having a slot sized and configured so that the material is passable through the slot after being coated with resin retained in the vessel, and a first and a second roller being arranged on either side of the slot or behind the slot.

A system for circulating a sealer is provided. The system includes a circulation line, in which a sealer is circulated and a first circulation valve which is disposed in the circulation line and configured to control the circulated sealer. A supply line is branched from a front end of the first circulation valve and an applying gun which is disposed in the supply line, receives a sealer, and controls the sealer discharged to the outside through a nozzle.

A coating apparatus, a method of recycling a coating liquid by utilization of the same and a method for cleaning the same are provided. The coating apparatus includes a supply device, a coater device and a recycling device. The supply device includes a liquid inlet, a liquid outlet and a coating liquid supply unit connected with the liquid inlet. The coater device includes a coating liquid nozzle including a receiving opening connected with the liquid outlet of the supply device, a coating opening and an exhaust opening. The recycling device includes a recycled liquid outlet and at least one recycling inlet including a supply process recycling inlet which is connected with the exhaust opening of the coating liquid nozzle, and the recycled liquid outlet is connected with the liquid inlet of the supply device.

Methods for storing and moving adhesive particulate to an adhesive melter are disclosed. An interior space of a supply hopper is filled with adhesive particulate. A transfer pump is actuated to generate a vacuum at an inlet of the transfer pump to actuate removal of the adhesive particulate from the supply hopper. A consistent minimized depth of the adhesive particulate located directly above the inlet is maintained with a shroud located within the interior space of the supply hopper. In addition, adhesive particulate can be received in an interior space of a container. An open space is maintained within the interior space of the container proximate the pump inlet, where the open space entrains gas to be drawn by the transfer pump. The transfer pump can be actuated to generate a vacuum at the pump inlet to cause removal of the adhesive particulate from the container.

The purpose is to provide a discharge system that adopts an optimal structure for connecting a discharging device to a refilling device in a substantially aligned fashion by moving the discharging device. A discharge system includes a discharging device, a refilling device, a discharge-side coupler, a refill-side coupler, and a manipulator. The discharge-side coupler is connectable to the refill-side coupler by relatively moving the discharge-side coupler in an axial line N direction of the refill-side coupler and fluid can be refilled from the refilling device side to the discharging device side. A coupling position between the manipulator and the discharging device reaches on the axial line N when connecting the refill-side coupler and the discharge-side coupler.

A coating system and a method for using such a system comprising a vessel, a flexible container within the vessel, and a coating apparatus. The flexible container includes an outlet port, wherein the flexible container is configured to contract in response to an increase in pressure within the vessel. The flexible container is configured to output a coating composition through the outlet port in response to contraction. The coating apparatus is configured to receive the coating composition from the outlet port and in some embodiments, deliver the coating composition to a wafer surface.

Provided is an accumulator which can surely discharge a collected fluid material in a first-in first-out manner without causing stagnation of the fluid material. The accumulator includes a housing having a temporarily accumulating space configured to change an inner volume thereof in an axial direction. The housing includes a supply port and a discharge port formed at positions spaced apart from each other in the axial direction and communicating with the temporarily accumulating space. The housing also includes a flow passage for uniformly supplying a fluid material into the temporarily accumulating space through the supply port.

Techniques herein include a bladder-based dispense system using an elongate bladder configured to selectively expand and contract to assist with dispense actions. This dispense system compensates for filter-lag, which often accompanies fluid filtering for microfabrication. This dispense system also provides a high-purity and high precision dispense unit. A meniscus sensor monitors a position of a meniscus of process fluid at a nozzle. The elongate bladder unit is used to maintain a position of the meniscus at a particular location by selectively expanding or contracting the bladder, thereby moving or holding a meniscus position. Expansion of the elongate bladder is also used for a suck-back action after completing a dispense action.

Techniques herein include a bladder-based dispense system using an elongate bladder configured to selectively expand and contract to assist with dispense actions. This dispense system compensates for filter-lag, which often accompanies fluid filtering for microfabrication. This dispense system also provides a high-purity and high precision dispense unit. A process fluid filter is located downstream from a process fluid source as well as a system valve. Downstream from the process fluid filter there are no valves. Dispense actions can be initiated and stop while the system valve is open by using the elongate bladder. The elongate bladder can be expanded to stop or pause a dispense action, and then be contracted to assist with a dispense action.

A bulk adhesive transfer system for transferring adhesive particulate to a melter includes a bulk supply and a transfer device, which may define a hopper of the melter, a mobile bin, and/or a buffer unit. The transfer device is configured to receive unmelted adhesive particulate from the bulk supply and then be selectively docked with the melter to transfer the adhesive particulate to the melter. The bulk adhesive transfer system may also include a knife gate valve device, which includes a plurality of ports that sequentially open and close to control flow of the adhesive particulate towards the melter. The bulk adhesive transfer system simplifies refilling operations for a melter while enabling continuous operation of the melter, even when the transfer device is undocked for removal from the melter.