Method for inspecting an elongated element

The invention claimed is: 1. A method for inspecting cylinder-shaped elongated elements for smoking articles, comprising the following steps: selecting a working plane passing through a longitudinal axis of a first elongated element and considering a first half-space and a second half-space arranged on opposite parts with respect to the working plane; in an operating step of the inspection method, projecting on an external face of the first elongated element a first stripe of light from the first half-space and obtaining a first three-dimensional light trace on an inspection portion of the external face, projecting a second stripe of light from the second half-space on the inspection portion and obtaining a second three-dimensional light trace; processing a first view of the first elongated element, the first view being obtained by framing the first elongated element from the first half-space and identifying in the first view a respective first curved line; processing a second view of the first elongated element, the second view being obtained by framing the first elongated element from the second half-space, and identifying in the second view a respective second curved line; reconstructing a first closed curved section profile of the first elongated element by processing the first identified curved line and the second identified curved line; comparing the reconstructed first closed curved profile with an ideal closed section profile, to identify possible deformations of the reconstructed first closed curved profile with respect to the ideal section profile; wherein an ideal elongated element is arranged in a reference position alongside the first elongated element, arranged in a first position, such that the longitudinal axis of the first elongated element and a longitudinal axis of the ideal elongated element are arranged in the working plane; inspecting simultaneously the first elongated element and the ideal elongated element by the first stripe of light and the second stripe of light; obtaining from the projection of the first stripe of light a first three-dimensional light trace on an external face of the ideal elongated element and obtaining from the projection of the second stripe of light a second three-dimensional light trace on the external face of the ideal elongated element; framing simultaneously from the first half-space the first elongated element and the ideal elongated element so as to process the first view to identify additionally a first curved line of the ideal elongated element by a processing device; framing simultaneously from the second half-space the first elongated element and the ideal elongated element such as to process the second view to identify additionally a second curved line of the ideal elongated element by the processing device; reconstructing a closed curved section profile of the ideal elongated element by processing the first identified curved line and the second identified curved line by the processing device; monitoring the reconstructed closed curved profile of the ideal elongated element generating a warning by the processing device if the reconstructed closed curved profile of the ideal elongated element is different from an ideal section profile. 2. The method according to claim 1 , wherein reconstructing the first closed curved profile ( 12 ) includes the following steps: arranging facing each other the first identified curved line and the second identified curved line; applying a first geometric transformation to the first identified curved line and to the second identified curved line arranged facing each other to calculate the first closed curved section profile from the perspectively corrected first curved line and from the perspectively corrected second line. 3. The method according to claim 2 , and further including the following steps: inspecting simultaneously the first elongated element and a second elongated element by the first stripe of light and the second stripe of light, wherein the first elongated element and the second elongated element are arranged alongside one another respectively in the first position and in a second position such that the longitudinal axis of the first elongated element and a longitudinal axis of the second elongated element are arranged in the working plane; obtaining from the projection of the first stripe of light a first three-dimensional light trace on an external face of the second elongated element and obtaining from the projection of the second stripe of light a second three-dimensional light trace on said external face; framing simultaneously from the first half-space the first elongated element and the second elongated element so as to process the first view to identify additionally a first curved line of the second elongated element; framing simultaneously from the second half-space the first elongated element and the second elongated element such as to process the second view to identify additionally a second curved line of the second elongated element; reconstructing a second closed curved section profile of the second elongated element by processing the first identified curved line and the second identified curved line and comparing the second reconstructed closed curved profile with the ideal section profile, to identify in addition possible deformations of the second reconstructed closed curved profile with respect to the ideal section profile. 4. The method according to claim 3 , and including the step of providing the ideal elongated element, the first elongated element and the second elongated element arranged alongside one another; wherein the method further includes the step of simultaneously framing, both in the first view and in the second view, the first elongated element arranged in the first position, the second elongated element arranged in the second position and the ideal elongated element arranged in the reference position. 5. The method according to claim 2 , and further including the step of calculating in a calibration step, preceding the operating step, the first geometric transformation applied during the operating step, wherein calculating the first geometric transformation includes the following steps: using an ideal elongated element and arranging the ideal elongated element instead of the first elongated element in the first position. 6. The method according to claim 5 , wherein calculating the first geometric transformation further includes also the following steps: processing the first view of the ideal elongated element framed from the first half-space to define a first curved line of the ideal elongated element; processing a second view of the ideal elongated element framed from the second half-space to define a second curved line of the ideal elongated element; identifying the processing mode capable of geometrically transforming the first identified curved line and the second identified curved line reconstructing the ideal section profile and selecting said processing mode as the first geometric transformation associated with the first position. 7. The method according to claim 6 further including the following steps: calculating in the calibration step the first geometric transformation associated with the first position and in addition a second geometric transformation associated with the second position, using the ideal elongated element and arranging the latter instead of the second elongated element; inspecting in the operating step the first elongated element and the second elongated element by applying respectively the first geometric transformation to the first elongated element and the second geometric transformation to the second elongated element. 8. The method according to claim 5 , and