Device and method for turning selvedges on a calender

The invention claimed is: 1. A method of calendering a continuous ply of reinforcing threads, comprising: positioning a continuous ply of reinforcing threads having spaces between adjacent reinforcing threads between a continuous upper sheet of rubber and a continuous lower sheet of rubber to form an assembly comprising the continuous ply of reinforcing threads and the sheets of rubber, said sheets of rubber having a width (Ls) greater than a width (Lf) of the continuous ply of reinforcing threads, so that two lateral parts of said sheets of rubber which are not vertically aligned with the ply of reinforcing threads form selvedges, introducing the assembly formed in the preceding step into a nip of a calender comprising at least two calendering rolls, to cause the rubber to penetrate the spaces between the reinforcing threads, turning up both selvedges of at least one of the sheets of rubber on themselves such that each turned up selvedge comprises a selvedge edge portion folding each selvedge so that there is contact between portions of selvedge, wherein the step of turning up both selvedges of at least one of the sheets of rubber on themselves is performed prior to the step of introducing the assembly into the nip of the calender. 2. The method according to claim 1 , wherein a fold is formed in each respective turned up selvedge approximately halfway across the respective width thereof in the step of turning up both selvedges of at least one of the sheets of rubber on themselves. 3. The method according to claim 1 , further comprising: passing one of the sheets of rubber around one of the calendering rolls upstream of the nip of the calender, wherein the at least two calendering rolls form the nip; providing turnup means upstream of the nip, which are able to turn the lateral selvedges of at least one of the sheets of rubber up onto themselves, wherein the turnup means are formed of rotary turnup discs installed axially on each side of an equator of a calendering roll, each of the turnup discs comprising a conical surface, the generatrix of which form a given angle (.alpha.) with respect to an axis of rotation (xx′) of the turnup disc, and wherein the turnup disc is installed in such a way that a radially distal part (P) of the conical surface of the turnup disc is substantially tangential to a surface of the calendering roll without coming into contact with the surface of the calendering roll; moving the rotating turnup discs axially adjacent to each of the selvedges, so that each selvedge is lifted up by a respective turnup disc and folded over on itself towards the equator of the roll under the effect of the rotating of the turnup. 4. The method according to claim 3 , further comprising: rotationally driving the turnup discs in such a way that a tangential velocity at the radially distal part (P) of the turnup discs is directed substantially parallel to an axis (X3X3′) of the calendering roll in the direction of the equator of the roll. 5. The method according to claim 3 , further comprising: rotationally driving the turnup discs in such a way that a circumferential velocity at the radially distal part (P) of the turnup discs is greater than a circumferential velocity of the calendering roll. 6. The method according to claim 1 , further comprising: cutting the lateral selvedges downstream of the nip. 7. The method according to claim 1 , wherein the ply of reinforcing threads is made up of reinforcing threads that are parallel to one another and make a zero angle with respect to a longitudinal direction of the said ply. 8. The method according to claim 1 , wherein the step of turning up both selvedges occurs at a specific size or position of fold. 9. The method according to claim 1 , wherein each of the ply of reinforcing threads, the upper sheet of rubber, and the lower sheet of rubber is a separate layer immediately prior to introduction into the nip of the calender such that the assembly comprising the continuous ply of reinforcing threads and the sheets of rubber is formed as the separate layers travel into the nip of the calender.