Method for determining the average filament length during a rotational atomization, and screening method based thereon during the development of a paint

1 . A method for determining the mean length of filaments formed on rotational atomization of a coating material composition, the method comprising: (1) atomization of a coating material composition by means of a rotational atomizer comprising as application element a bell cup capable of a rotation, (2) optical capture of the filaments formed on atomization as per step (1) at the bell cup edge, by means of at least one camera, and (3) digital evaluation of the optical data obtained by the optical capture as per step (2), to give the mean length of those filaments formed on atomization that are located at the edge of the bell cup. 2 . The method according to claim 1 , wherein the coating material composition used in step (1) is an aqueous basecoat material. 3 . The method according to claim 1 , wherein the coating material composition used in step (1) comprises at least one polymer employable as binder, as a component (a); at least one pigment and/or at least one filler, as a component (b); and water and/or at least one organic solvent, as a component (c). 4 . The method according to claim 3 , wherein component (b) comprises at least one effect pigment in the coating material composition. 5 . The method according to claim 1 , wherein the atomization as per step (1) is carried out at a discharge rate of the coating material composition for atomization in a range from 100 to 1000 ml/min and/or at a rotary speed of the bell cup in a range from 15,000 to 70,000 revolutions/min. 6 . The method according to claim 1 , wherein the optical capture as per step (2) takes place by the at least one camera recording 30,000 to 250,000 images of the bell cup and of the bell cup edge per second during the atomization. 7 . The method according to claim 1 , wherein the digital evaluation as per step (3) takes place by means of image analysis and/or video analysis of the optical data obtained as per step (2). 8 . The method according to claim 1 , wherein the digital evaluation as per step (3) is carried out on the basis of at least 1000 images captured as per step (2). 9 . The method according to claim 1 , wherein the digital evaluation as per step (3) comprises: (3a) smoothing of the images obtained as optical data after implementation of step (2), by means of a Gaussian filter, to remove the bell cup from the images, (3b) binarization and inverting of the images smoothed as per stage (3a), (3c) binarization of the images used in stage (3a) and addition of the images thus binarized to the inverted images from stage (3b), to give binarized images without bell cup edge, and inverting of the images thus obtained, (3d) removal of drops, fragmented filaments, and filaments not located at the bell cup edge from the images obtained as per stage (3c), to give images on which all of the located objects remaining are filaments, (3e) removal, from the images obtained as per stage (3d), of those filaments not located entirely within the images, and (3f) tapering of all filaments remaining in the images after stage (3e) to their number of pixels, addition of the number of pixels for each of the filaments, determination of the filament length of each of the filaments on the basis of the pixel size, and ascertainment of the mean filament length for the entirety of all filaments measured. 10 . The method according to claim 9 , wherein the removal as per stage (3d) is accomplished by (i) determination of the length of all hypotenuses of all objects located on the images, (ii) labeling of objects as drops and/or fragmented filaments on the images if the hypotenuse values ascertained for these objects fall below a defined value h, and elimination of these objects, and (iii) verification of the remaining objects, namely the filaments, on the basis of their position on the images, as to whether they were located at the bell cup edge, and elimination of those filaments to which this does not apply. 11 . A method for compiling and/or updating an electronic database containing mean filament lengths of atomized coating material compositions which differ from one another, the method comprising: steps (1), (2), and (3) as defined in claim 1 for a first coating material composition (i), (4A) incorporation of the mean filament length, ascertained as per step (3) for the first coating material composition (i), into an electronic database, and (5A) repetition at least once of the steps (1) to (3) and (4A) for at least one further coating material composition, different from the first coating material composition (i). 12 . The method according to claim 11 , further comprising: (3A) application of the first coating material composition (i) atomized in step (1) to a substrate, to form a film located on the substrate, and baking of this film to form a coating located on the substrate, (3B) analysis and assessment of the coating obtained after step (3A) for the incidence or nonincidence of surface defects and/or optical defects, and (3C) incorporation of the results obtained after implementation of step (3B) into the electronic database, where step (5A) comprises the repetition at least once of these steps (3A), (3B), and (3C) for the at least one further coating material composition, different from the first coating material composition (i). 13 . A method for screening coating material compositions in the development of paint formulations, the method comprising: steps (1), (2), and (3) as defined in claim 1 for a coating material composition (X1), (4B) comparison of the mean filament length, determined as per step (3) for the coating material composition (X1), with mean filament lengths of further coating material compositions, stored in an electronic database, said database being obtainable by means of a method comprising: steps (1), (2), and (3) as defined in claim 1 for a first coating material composition (i), (4A) incorporation of the mean filament length, ascertained as per step (3) for the first coating material composition (i), into an electronic database, and (5A) repetition at least once of the steps (1) to (3) and (4A) for at least one further coating material composition, different from the first coating material composition (i), (5B) checking, on the basis of the comparison as per step (4B), as to whether the mean filament length, determined as per step (3) for the coating material composition (X1), meets the condition that it is lower than at least one mean filament length stored in the database of a coating material composition (X2), which is different from the coating material composition (X1) but has a pigment content identical to that of the coating material composition (X1) or has a pigment content deviating by no more than ±10% by weight from the pigment content of the coating material composition (X1), based on the amount of pigment present in the coating material composition (X1), and which, moreover, comprises the identical pigment or pigments or the substantially identical pigment or pigments to the coating material composition (X1), (6B) selection of the coating material composition (X1) for application to a substrate, if the mean filament length determined for the coating material composition (X1) meets the condition specified in step (5B), or adaptation of at least one parameter within the formula of the coating material composition (X1) and/or of at least one method parameter when performing steps (1) to (3) of the method for screening coating material compositions, if the mean filament length determined for the coating material composition (X1) does not meet the condition specified in step (5B), (7B) repetition at least once of steps (1) to (3)