Method and installation for winding a rubber strip onto a form of revolution

The invention claimed is: 1. A method for winding a strip of rubber onto a form of revolution, the method comprising: forming a strip of a predetermined length; placing a front edge mark on a front end of the strip, and placing a rear edge mark on a rear end of the strip; driving the strip longitudinally towards the form; arranging the front end of the strip on the form; and driving the form so as to wind the strip onto the form, wherein, in a first phase of the method, the driving of the strip and the driving of the form are synchronized such that a speed of displacement of the rear edge mark and a speed of displacement of the front edge mark are substantially identical, so as not to modify the length of the strip, and wherein, in a second phase of the method, the driving of the strip and the driving of the form are controlled depending on an angular position of the form at an end of the first phase and on a position of the rear edge mark such that the speed of displacement of the rear edge mark and the speed of displacement of the front edge mark vary relative to each other, so as to compensate for a variation in the length of the strip. 2. The method according to claim 1 , wherein: the forming of the strip includes cutting a continuous web of rubber so as to form successive upstream and downstream strips, and an upstream end of the downstream strip and a downstream end of the upstream strip are marked simultaneously so that a mark applied to the upstream end of the downstream strip corresponds to a rear edge mark of the downstream strip, and so that a mark applied to the downstream end of the upstream strip corresponds to a front edge mark of the upstream strip. 3. The method according to claim 1 , wherein, in the arranging of the front end of the strip, the front end of the strip is arranged at a predetermined reference position of the form, and wherein the end of the first phase is determined by detecting the front edge mark at a predetermined detection position on the form. 4. The method according to claim 3 , wherein the predetermined detection position and the predetermined reference position are separated on the form by a predetermined angle A of between 10° and 90°. 5. The method according to claim 1 , wherein the speed of displacement of the rear edge mark, V 1 , during the first phase is determined by: V 1 =N*E 1 /(360− D ), where: N is a predetermined angular rotational speed of the form, E 1 is the length of the strip between the rear edge mark and the front edge mark, and D is an angle of a sector of the form extending between the rear edge mark and the front edge mark, D being a desired angle when an entirety of the strip has been wound onto the form. 6. The method according to claim 1 , wherein an end of the second phase corresponds to a point in time at which the form has traveled through an additional predetermined angular sector B and still needs to travel through an additional predetermined angular sector C before returning to a predetermined reference position. 7. The method according to claim 6 , where an angle corresponding to the predetermined angular sector B is between 90° and 260°. 8. The method according to claim 7 , wherein an angle corresponding to the predetermined angular sector C is between 90° and 180°. 9. The method according to claim 1 , wherein the speed of displacement of the rear edge mark, V 2 , during the second phase is determined by: V 2 =N *[ E 2 −( C*L 0 /360)/(360−Ω− C−D )], where: N is a predetermined angular rotational speed of the form, E 2 is a variable corresponding to a length of a remaining part of the strip to be wound around the form during the second phase, Ω is an angle of rotation of the form at the end of the first phase, L 0 is a neutral fiber length of the strip, and D is an angle of a sector of the form extending between the rear edge mark and the front edge mark, D being a desired angle when an entirety of the strip has been wound onto the form. 10. The method according to claim 1 , wherein, in a third phase of the method, the driving of the strip and the driving of the form are synchronized, so as to eliminate residual strain in the strip. 11. The method according to claim 1 , wherein an end of the second phase corresponds to a point in time at which the form has traveled through an additional predetermined angular sector B and still needs to travel through an additional predetermined angular sector C before returning to the predetermined reference position, wherein, in a third phase of the method, the driving of the strip and the driving of the form are synchronized so as to eliminate residual strain in the strip, and wherein a driving speed of the strip, V 3 , in the third phase is determined by: V 3 =N*L 0 /360, where N is a predetermined angular rotational speed of the form, and L 0 is a neutral fiber length of the strip. 12. The method according to claim 10 , wherein, at an end of the third phase, positions of the front edge mark and the rear edge mark are determined, and an angle of a sector separating the front edge mark and the rear edge mark is compared with the desired angle D.