The present invention concerns the provision of a novel glue application apparatus for controllably depositing glue on the mating surfaces of door components in a manner that provides adequate glue coverage while preventing the deposition of excessive amounts of glue. The glue application apparatus includes multiple glue dispensers having uniquely configured glue dispensing nozzles that are uniquely positioned at various angles to accommodate mating surfaces of different profiles.

A method for a system having a plurality of primary fluid sources and a fluid output with a common pump includes halting pumping of a first fluid, isolating the common pump from the fluid output and the primary fluid sources, connecting an inlet of the common pump to a solvent source and a compressed air source, and an outlet of the common pump to a waste fluid dump, filling the common pump with a first purge volume of solvent, cycling the common pump in a flush mode, operating the common pump in a timed flow mode, and connecting an inlet of the common pump to a second primary fluid source, and an outlet of the common pump to the output line, and starting pumping of a second fluid from the second primary fluid source through the output line.

Disclosed is an electrostatic coating apparatus comprising: an atomizing head cleaning flow path (13) which is disposed at a coating machine (3) and through which a cleaning fluid for cleaning a rotary atomizing head (6) and a front end of a feed tube (8C) of a cartridge (8) flows; a cleaning fluid flow path (14) connecting a cleaning fluid supply source (15) with the atomizing head cleaning flow path (13); a cleaning fluid valve (16) disposed in the cleaning fluid flow path (14) and configured to open and close the cleaning fluid flow path (14); a discharge air flow path (17) connected to the atomizing head cleaning flow path (13) and through which the discharge air flows; a cleaning fluid discharge flow path (20) connected to the cleaning fluid flow path (14) at a connection point (D) located between the atomizing head cleaning flow path (13) and the cleaning fluid valve (16); a discharge air switching valve (21) disposed in the atomizing head cleaning flow path (13) and configured to open and close the atomizing head cleaning flow path (13); and a cleaning fluid discharge valve (22) disposed in the cleaning fluid discharge flow path (20) and configured to open and close the cleaning fluid discharge flow path (20).

A spray gun cleaning assembly includes an aerosol can and a connecting assembly connecting the aerosol can to a spray gun for cleaning the spray gun. The connector assembly includes a first threaded connector threadedly coupled to the aerosol can; and a second threaded connector threadedly connected to the spray gun. An elongated tube is connected at opposite ends to the first and second threaded connectors. A shut-off valve assembly is operatively coupled to the elongated tube for opening and closing the connecting assembly for providing pressurized air or cleaning fluid to the spray gun.

A slit nozzle is moved by a nozzle lifting/lowering mechanism and a nozzle sliding mechanism relative to substrates held in a substantially horizontal attitude by spin chucks. A development liquid is discharged on each substrate from a discharge port of the slit nozzle such that development processing for the substrate is performed. After the development liquid is discharged, the slit nozzle is moved to a waiting position excluding positions over the substrates held by the spin chucks. In waiting pods provided at the waiting positions, cleaning processing for the slit nozzle is performed by a cleaning liquid with gas bubbles mixed therein.

An off-line cleaning apparatus for a painting machine (6) mainly comprises a body (16), and a solvent tank (1), a solvent pipe (2) a compressed air pipe (3), a main cleaning pipe (4), and a test pipe (11) arranged inside the body (16). The solvent tank (1) communicates with the main cleaning pipe (4) via the solvent pipe (2) in which a conveying pump (10) is provided. The compressed air pipe (3) communicates with the main cleaning pipe (4) so as to introduce compressed air into the main cleaning pipe (4). The main cleaning pipe (4) is provided with first branch cleaning pipes (4.1) and a second branch cleaning pipe (4.2). On the basis of the above-described structures, the off-line cleaning apparatus is able to thoroughly clean mixer pipes (5) and the painting machine (6), and ensures painting quality of vehicle bumpers.

Method of cleaning a plasma coating torch utilizing at least one nozzle mounted so as to be directed at the plasma coating torch in order to subject an external surface of the plasma coating torch to a cleaning agent that removes spray material particles which have adhered to the external surface of the plasma coating torch during coating with the plasma coating torch, and such that the cleaning agent exiting the at least one nozzle and being directed toward the external surface and directly changing to a gaseous state from either a solid state or a liquid state.

Cleaning fixtures for a component(s) are disclosed. The cleaning fixtures may include a first and second component recess configured to receive a first and second component, respectively. Each component recess may be defined between a first and second member of the cleaning fixture. The cleaning fixture may also include a first solvent conduit in fluid communication with the first component recess, and a second solvent conduit in fluid communication with the second component recess. The first and second solvent conduit may include physical characteristic(s) configured to control delivery of solvent into the respective component recess at desired fluid parameter(s). The cleaning fixture may also include a first gas conduit in fluid communication with the first component recess, and a second gas conduit in fluid communication with the second component recess. Each of the first and second gas conduit may deliver a pressurized gas to the respective component recess.

A nozzle cleaning device is capable of uniformly cleaning a nozzle from a front end of the nozzle to an upper part thereof. The nozzle cleaning device includes a storage tank, a liquid discharging portion and an overflow discharging portion. The storage tank has a cylindrical inner peripheral surface and is configured to store therein a cleaning liquid that cleans a nozzle used in a substrate process. The liquid discharging portion is configured to discharge the cleaning liquid into the storage tank toward a position eccentric with respect to a central axis of the cylindrical inner peripheral surface to store the cleaning liquid within the storage tank and configured to form a vortex flow of the cleaning liquid revolving within the storage tank. The overflow discharging portion is configured to discharge the cleaning liquid that overflows the storage tank.

Cleaning fixtures for a component(s) are disclosed. The cleaning fixtures may include a first and second component recess configured to receive a first and second component, respectively. Each component recess may be defined between a first and second member of the cleaning fixture. The cleaning fixture may also include a first solvent conduit in fluid communication with the first component recess, and a second solvent conduit in fluid communication with the second component recess. The first and second solvent conduit may include physical characteristic(s) configured to control delivery of solvent into the respective component recess at desired fluid parameter(s). The cleaning fixture may also include a first gas conduit in fluid communication with the first component recess, and a second gas conduit in fluid communication with the second component recess. Each of the first and second gas conduit may deliver a pressurized gas to the respective component recess.