Collector pipe for a radial reactor comprising solid fillets

1 . Collector pipe ( 8 ) that is permeable to a gaseous fluid and impermeable to catalyst particles, with an approximately cylindrical shape extending along an approximately vertical axis having a first surface that can be in contact with the catalyst particles and a second surface opposite the first surface, the pipe comprising a plurality of shaped vertical wires ( 11 ) having a first face ( 12 ) that can be in contact with the catalyst particles and a second face ( 13 ) opposite the first face ( 12 ), the shaped wires ( 11 ) being integral with a plurality of horizontal support rings ( 14 ) by their second face ( 13 ), the shaped wires ( 11 ) and the support rings ( 14 ) defining a plurality of openings, characterized in that the pipe ( 8 ) further comprises a plurality of solid fillets ( 15 ), impermeable to gaseous fluid and to particles, which are integral with the first face of the shaped wires ( 11 ) and/or placed and held between two vertical wires ( 11 ), and in that the solid fillets ( 15 ) form an angle of inclination a in relation to the horizontal of between 10° and 90°. 2 . Collector pipe according to claim 1 , wherein the total surface occupied by the solid fillets ( 15 ) is between 1 and 30% of the total surface developed by the pipe, preferably between 2 and 20% of the total surface developed by the pipe. 3 . Pipe according to claim 1 , wherein each solid fillet ( 15 ) extends over a height of between 10 and 100% of the total height of the pipe. 4 . Collector pipe according to claim 1 , wherein the solid fillets ( 15 ) are placed in a zone located in the upper half of the pipe and/or in a zone located in the lower half of the pipe. 5 . Collector pipe according to claim 1 , wherein the solid fillets ( 15 ) extend from the upper end or from the lower end of the Pipe. 6 . Collector pipe according to claim 1 , wherein the solid fillets ( 15 ) cover at the same time portions of the zones located in the lower and upper halves of the pipe. 7 . Collector pipe according to claim 1 , comprising successively and alternately a solid fillet ( 15 ) extending in a zone corresponding to the upper half of the pipe and a solid fillet extending in a zone corresponding to the lower half of the pipe. 8 . Collector pipe according to claim 1 , wherein the solid fillets placed in the upper half of the pipe are arranged facing the solid fillets placed in the lower half of the pipe, and wherein the sum of the heights of the solid fillets facing one another is between 20 and 100% of the total height of the pipe. 9 . Collector pipe according to claim 1 , wherein the solid fillets are parallel to one another. 10 . Collector pipe according to claim 1 , wherein the angle of inclination is different from 90°, and wherein two solid fillets ( 15 ) meet to form a “V” or intersect to form an “X.” 11 . Reactor having radial circulation of gaseous fluid comprising: an external casing ( 2 ) defining a chamber extending along a vertical main axis and containing a reaction zone having a bed of catalyst particles; at least one input means of a feedstock; at least one output means of the effluent produced by the catalytic reaction; at least one input means of the catalyst to introduce the catalyst into the reaction zone; at least one output means of the catalyst coming out from the reaction zone; and a pipe ( 8 ) for collecting effluent according to one of the preceding claims, in communication with the output means of the effluent, placed in the reaction zone, it being understood that the solid fillets are in contact with the catalyst particles of the catalytic bed, and optionally, a cylindrical grid ( 5 ) that is permeable to gases and impermeable to catalyst particles, placed in the chamber ( 2 ) in a manner that is concentric in relation to the collector pipe ( 8 ). 12 . Reactor according to claim 11 , wherein the cylindrical grid ( 5 ) is placed between the external casing ( 2 ) and the collector pipe ( 8 ), wherein the reactor comprises an annular zone for external distribution ( 20 ) between the casing ( 2 ) and the cylindrical grid ( 5 ), an annular catalytic zone ( 21 ) between the cylindrical grid ( 5 ) and the collector pipe ( 8 ), and a collector space ( 22 ) delimited by the collector pipe ( 8 ), and wherein the first face of the wires of the collector pipe is in contact with the catalytic bed. 13 . Reactor according to claim 11 , wherein the collector pipe ( 8 ) is placed between the casing ( 2 ) and the cylindrical grid ( 5 ), wherein the reactor comprises an external annular collector zone ( 23 ) between the casing ( 2 ) and the collector pipe ( 8 ), an annular catalytic zone ( 24 ) between the cylindrical grid ( 5 ) and the collector pipe ( 8 ), and a collector space ( 25 ) delimited by the cylindrical grid ( 5 ), and wherein the first face of the wires of the collector pipe is in contact with the catalytic bed. 14 . Method for catalytic conversion of a hydrocarbon feedstock using a reactor according to claim 11 , wherein: the hydrocarbon feedstock is sent continuously in gaseous form into a catalytic bed contained in the reactor; the hydrocarbon feedstock passing radially through the catalytic bed is put in contact with the catalyst so as to produce a gaseous effluent; and said effluent is drawn off after it passes through the collector pipe. 15 . Method according to claim 13 , wherein the catalytic bed is mobile, and the catalyst is continuously sent and drawn off.