A separating stage for inertial separation of components contained in a fluid flowing through, in particular paint particles and/or paint agglomerates includes at least one separating segment, which has at least one acceleration section for the fluid on the inlet side, in which the fluid is accelerated in a through-flow direction, and a first impaction surface for components contained in the fluid is downstream of the acceleration section. A separating unit having at least one separating stage, a kit, a transport cart, a coating facility, and a method for producing a separating unit are also provided.

The present invention relates to a painting booth having a structure which sprays a paint in a painting booth, and is capable of reutilizing by withdrawing a used paint, and preventing atmospheric pollution and surrounding contamination, and is configured to include: an exhaust duct installed in an upper part of a booth; a filter plate configured by a metal net, which is installed on a front wall of the booth; a bottom filter plate installed on a bottom of the booth, and a collector collecting paint sludge which falls to the bottom.

The present invention relates to a painting booth having a structure which sprays a paint in a painting booth, and is capable of reutilizing by withdrawing a used paint, and preventing atmospheric pollution and surrounding contamination, and is configured to include: an exhaust duct installed in an upper part of a booth; a filter plate configured by a metal net, which is installed on a front wall of the booth; a bottom filter plate installed on a bottom of the booth, and a collector collecting paint sludge which falls to the bottom.

A chamber for fluid application to a piece of material (M), such as a web or strip arranged to nm in the chamber (10), has a fluid applicator (2) for fluid application to the material. It further includes an inlet (11a) through which the material is fed into the chamber (10), an outlet (11b) through which the material exits the chamber (10), an outlet passage device (15) arranged at the outlet (11b) and configured to form an outlet fluid sealing of the chamber, and an inlet passage device (16) arranged at the inlet (11a) and configured to form an inlet fluid sealing of the chamber.

A chamber for fluid application to a piece of material (M), such as a web or strip arranged to nm in the chamber (10), has a fluid applicator (2) for fluid application to the material. It further includes an inlet (11a) through which the material is fed into the chamber (10), an outlet (11b) through which the material exits the chamber (10), an outlet passage device (15) arranged at the outlet (11b) and configured to form an outlet fluid sealing of the chamber, and an inlet passage device (16) arranged at the inlet (11a) and configured to form an inlet fluid sealing of the chamber.

A wet scrubber having a body that is molded from a plastic material in combination with a nozzle insert that is removably received in the inlet of the wet scrubber and configured to optimize the speed of fluid flow entering a mixing chamber provided in the wet scrubber. Interchangeable nozzle inserts allow to optimize operation of the wet scrubber for different processes the wet scrubber is operating in conjunction with.

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 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).