Burner nozzle, burner and a surface treatment device

The invention claimed is: 1. A burner nozzle ( 100 ) that comprises: a nozzle body ( 102 ) that includes a slit ( 106 ), a line passage ( 104 ) to the slit opening in an outlet face surface ( 150 ); a plurality of channels ( 112 , 114 ) connected to the slit ( 106 ), characterized in that a group of first channels ( 112 ) is connected to a source of oxidizing substance ( 120 ), and a group of second channels ( 114 ) is connected to a fuel source ( 122 ); each of the first channels ( 112 ) and second channels ( 114 ) have a circumferential passage ( 110 ) to the slit at a non-zero distance from the outlet face surface ( 150 ); each of the first channels ( 112 ) and second channels ( 114 ) is formed to output a directed tubular flow towards a side wall of the slit ( 106 ), or towards one or more circumferential passages ( 110 ) in a side wall of the slit ( 106 ). 2. A burner nozzle ( 100 ) according to claim 1 , characterized in that circumferential passages of the first channels ( 112 ) and circumferential passages of the second channels ( 114 ) are arranged to the length of the slit ( 106 ) in pairs wherein the distance from the outlet face surface ( 150 ) to a circumferential passage of the first channel ( 112 ) of the pair is the same as the distance from the outlet face surface ( 150 ) to a circumferential passage of the second channel ( 114 ) of the pair; and the first channel ( 112 ) and the second channel ( 114 ) of the pair are directed opposite to each other to output a directed tubular flow directly against a directed tubular flow of the opposite channel of the pair. 3. A burner nozzle ( 100 ) according to claim 1 , characterized in that circumferential passages of the first channels ( 112 ) and circumferential passages of the second channels ( 114 ) are arranged into pairs wherein the distance from the outlet face surface ( 150 ) to a circumferential passage of the first channel ( 112 ) of the pair is the same as the distance from the outlet face surface ( 150 ) to a circumferential passage of the second channel ( 114 ) of the pair, and the circumferential passages of the pairs are in opposite positions in opposite sides of the slit ( 106 ); and the first channel ( 112 ), the second channel ( 114 ), or both of the first and second channels ( 112 , 114 ) of the pair is configured to output into the slit ( 106 ) a directed tubular flow, wherein the direction of the tubular flow forms an obtuse or acute angle with the direction of the depth of the slit ( 106 ). 4. A burner nozzle ( 100 ) according to claim 1 , characterized in that circumferential passages of the first channels ( 112 ) and circumferential passages of the second channels ( 114 ) are arranged into pairs wherein the distance from the outlet face surface ( 150 ) to a circumferential passage of the first channel ( 112 ) of the pair is different from the distance from the outlet face surface ( 150 ) to a circumferential passage of the second channel ( 114 ) of the pair, and the circumferential passages of the pairs are in opposite positions along the length of the slit ( 106 ); and the first channel ( 112 ), the second channel ( 114 ), or both of the first and second channels ( 112 , 114 ) of the pair is configured to output into the slit a directed tubular flow, wherein the direction of the tubular flow forms a right, obtuse or acute angle with the direction of the depth of the slit. 5. A burner nozzle ( 100 ) according to claim 1 , characterized in that circumferential passages of the first channels ( 112 ) and circumferential passages of the second channels ( 114 ) are arranged to the length of the slit ( 106 ) in pairs wherein the distance from the outlet face surface ( 150 ) to a circumferential passage of the first channel ( 112 ) of the pair is the same as the distance from the outlet face surface ( 150 ) to a circumferential passage of the second channel ( 114 ) of the pair; and the first channels ( 112 ) and second channels ( 114 ) are arranged to interdigitated positions in the opposite sides of the slit ( 106 ) to output a directed tubular flow against opposite side walls of the slit ( 106 ). 6. A burner nozzle ( 100 ) according to claim 1 , characterized in that circumferential passages of the first channels ( 112 ) and circumferential passages of the second channels ( 114 ) are arranged to the length of the slit ( 106 ) in pairs wherein the distance from the outlet face surface ( 150 ) to a circumferential passage of the first channel ( 112 ) of the pair is the same as the distance from the outlet face surface ( 150 ) to a circumferential passage of the second channel ( 114 ) of the pair; and the first channels ( 112 ) and second channels ( 114 ) are arranged to interdigitated positions in one side of the slit ( 106 ) to output a directed tubular flow against the opposite side wall of the slit ( 106 ). 7. A burner nozzle ( 100 ) according to claim 1 , characterized in that circumferential passages of the first channels are provided by a first piece of porous material ( 700 ), a surface ( 702 ) of the first piece of porous material ( 700 ) forming a part of a first side wall ( 702 , 704 ) of the slit ( 706 ); circumferential passages of the second channels are provided by a second piece of porous material ( 710 ), a surface ( 712 ) of the second piece of porous material ( 710 ) forming a part of a second side wall ( 712 , 714 ) of the slit ( 706 ). 8. A burner nozzle ( 100 ) according to claim 7 , characterized in that the surface ( 702 ) of the first piece of porous material part is directly opposite to the surface ( 712 ) of the second piece of porous material, or that the surface ( 702 ) of the first piece of porous material part and the surface ( 712 ) of the second piece of porous material form an acute angle, the vertex of the acute angle coinciding with the end of the slit ( 706 ). 9. A burner nozzle ( 100 ) according to claim 1 , characterized in that the source of oxidizing substance ( 120 ) is connected to a first elongate gas space ( 124 ) that extends essentially to the length of the slit ( 106 ), and is connected to inlets of the first channels ( 112 ). 10. A burner nozzle ( 100 ) according to claim 9 , characterized in that the first elongate gas space ( 124 ) or the second elongate gas space ( 130 ) is offset from the slit ( 106 ) in a direction perpendicular to the slit ( 106 ). 11. A burner nozzle ( 100 ) according to claim 10 , characterized in that the first elongate gas space ( 124 ) and the second elongate gas space ( 130 ) are equally offset from the slit ( 106 ). 12. A burner nozzle ( 100 ) according to claim 9 , characterized in that the first elongate gas space ( 124 ) or the second elongate gas space ( 130 ) has a linear form. 13. A burner nozzle ( 100 ) according to claim 1 , characterized in that the fuel source ( 122 ) is connected to a second elongate gas space ( 130 ) that extends essentially to the length of the slit ( 106 ), and is connected to inlets of the second channels ( 114 ). 14. A burner nozzle ( 100 ) according to claim 1 , characterized in that the circumferential passages of the group of first channels ( 112 ) have the same distance to the outlet face surface ( 150 ); the distance from the outlet face surface ( 150 ) to the circumferential passages of the group of first channels ( 112 ) is at least five times the distance from the closed, bottom end of the slit ( 106 ) to the circumferential passages of the group of first channels ( 112 ). 15. A burner nozzle ( 100 ) according to claim 1 , characterized in that the circumferential passages of the group of second channels ( 1