A base for a powder coating booth, including a base structure, through which the booth is intended to rest on a floor, the base structure being configured to support a powder coating compartment of the booth. The base also includes a floor, which is supported by the base structure and which is configured to delimit the bottom of the powder coating compartment. To reduce the accumulation of residual powder, the floor includes at least one oblique panel, which is inclined with respect to the horizontal and which is configured to delimit the bottom of the powder coating compartment of the booth, whereas the at least one oblique panel is porous so as to be permeable to the air and impermeable to the residual powder resulting from powder coating an article within the powder coating compartment.

A cyclone is disclosed that includes an enclosure that encloses at least a portion of the cyclone. The enclosure delimits an enclosed volume between an interior surface of the enclosure and the exterior surface of the body. The enclosure retains a gas coolant or liquid coolant in thermal exchange with the enclosed exterior surface of the cyclone. A powder coating system is disclosed that includes a spray booth and a cyclone, where ambient air is added to process air that is drawn from the spray booth into the cyclone. The ambient air may be added to the process air to cool the process air to a temperature that is lower than the process air would be if ambient air were not added, and also may be used to dilute the powder overspray entrained process air.

A cyclone is disclosed that includes an enclosure that encloses at least a portion of the cyclone. The enclosure delimits an enclosed volume between an interior surface of the enclosure and the exterior surface of the body. The enclosure retains a gas coolant or liquid coolant in thermal exchange with the enclosed exterior surface of the cyclone. A powder coating system is disclosed that includes a spray booth and a cyclone, where ambient air is added to process air that is drawn from the spray booth into the cyclone. The ambient air may be added to the process air to cool the process air to a temperature that is lower than the process air would be if ambient air were not added, and also may be used to dilute the powder overspray entrained process air.

A coating booth (101) for elements to be coated. The coating booth (101) comprises a passage between opposing vertical sides (107a, 107b, 108a, 108b) through which elements to be coated are conveyed. There is an entrance (105) at one end of the passage and an exit (106) at the other end of the passage. The coating booth (101) comprises a conveyor line (102) for supporting said elements to be coated and configured to convey said elements from the entrance (105) to the exit (106) along a straight pathway, and, a suction system. The opposing sides of the channel are symmetrical about the pathway. Sets of spray guns (103a, 104a, 103b, 104b) for spraying coating powder at the elements are positioned symmetrically either side of the straight pathway. The suction system comprises vertical suction inlets (109a, 109b) mounted opposite one another on each opposing vertical side of the passage, the suction system being configured to provide equal amounts of suction through each of the opposing vertical suction inlets (109a, 109b).

A coating booth (101) for elements to be coated. The coating booth (101) comprises a passage between opposing vertical sides (107a, 107b, 108a, 108b) through which elements to be coated are conveyed. There is an entrance (105) at one end of the passage and an exit (106) at the other end of the passage. The coating booth (101) comprises a conveyor line (102) for supporting said elements to be coated and configured to convey said elements from the entrance (105) to the exit (106) along a straight pathway, and, a suction system. The opposing sides of the channel are symmetrical about the pathway. Sets of spray guns (103a, 104a, 103b, 104b) for spraying coating powder at the elements are positioned symmetrically either side of the straight pathway. The suction system comprises vertical suction inlets (109a, 109b) mounted opposite one another on each opposing vertical side of the passage, the suction system being configured to provide equal amounts of suction through each of the opposing vertical suction inlets (109a, 109b).

A powder coating booth having a bottom surface, defining an inner space in which is insertable an element to be coated. The powder coating booth having at least one spraying device adapted to spray coating powder on said element to be coated and at least one collecting area defined in said inner space, on top of which said element to be coated passes to be coated with coating powder and in which the excess powder falls down. The powder coating booth being associated with first suction device for sucking and conveying air exiting said inner space, wherein said collecting area is associated with second suction device adapted to suck and convey said excess powder exiting said inner space.

A powder coating booth having a bottom surface, defining an inner space in which is insertable an element to be coated. The powder coating booth having at least one spraying device adapted to spray coating powder on said element to be coated and at least one collecting area defined in said inner space, on top of which said element to be coated passes to be coated with coating powder and in which the excess powder falls down. The powder coating booth being associated with first suction device for sucking and conveying air exiting said inner space, wherein said collecting area is associated with second suction device adapted to suck and convey said excess powder exiting said inner space.

A recirculating powder applicator includes an applicator body having an inlet on an upstream surface and an outlet on a downstream surface, wherein the inlet and outlet define a passage that extends transversely through the thickness of the applicator body, a powder conduit, an air inlet, an exhaust aperture located on one of the upstream or downstream surfaces, and a circulation chamber located on the interior of the applicator body. The powder conduit and air inlet are in fluid communication with the passage and the passage is in fluid communication with the circulation chamber. A method of applying powder to a substrate during a continuous process includes using a recirculating powder applicator.

A recirculating powder applicator includes an applicator body having an inlet on an upstream surface and an outlet on a downstream surface, wherein the inlet and outlet define a passage that extends transversely through the thickness of the applicator body, a powder conduit, an air inlet, an exhaust aperture located on one of the upstream or downstream surfaces, and a circulation chamber located on the interior of the applicator body. The powder conduit and air inlet are in fluid communication with the passage and the passage is in fluid communication with the circulation chamber. A method of applying powder to a substrate during a continuous process includes using a recirculating powder applicator.

A feed center for powder coating material includes a hopper, an extraction duct, and a control valve. The hopper is in fluid communication with a fluidizing pressure source. The extraction duct is in fluid communication with at least one suction source. The control valve connects the extraction duct with an extraction port of the hopper. The control valve is operable between a first position for applying suction from the at least one suction source to the hopper, and a second position providing an exterior opening in at least one of the control valve and the first extraction duct for exhausting pressurized fluid from the hopper and/or collecting at least some of the air and powder that is exhausted from the powder.