Method for controlling a conveyor for hollow bodies through a heating station and associated conveyor

The invention claimed is: 1. A method for controlling a conveyor ( 20 ) of hollow bodies ( 12 ) through a heating station ( 14 ) for an installation ( 10 ) for producing containers of thermoplastic material, comprising: a heating tunnel ( 18 ) defining a heating path; the conveyor ( 20 ) comprising at least one moving track ( 22 ), each of the at least one moving track forming one closed circuit, the conveyor further comprising a plurality of shuttles ( 24 ) associated with said at least one moving track, each of the shuttles of the associated plurality of shuttles being structured to travel along said at least one moving track ( 22 ) and to carry at least one hollow body ( 12 ), each shuttle ( 24 ) being controlled individually in movement along the closed circuit, independently from the other shuttles of the plurality of shuttles, the at least one moving track ( 22 ) having a heating section ( 22 B) for the conveying of the hollow bodies ( 12 ) along the heating path; an input device ( 32 ) for the hollow bodies ( 12 ) to be heated that brings the hollow bodies ( 12 ) to a loading section ( 22 A) of the at least one moving track ( 22 ) for their loading on the shuttles ( 24 ), two successive shuttles ( 24 ) traveling with a first determined input separation (E 1 ) on the loading section ( 22 A); an output device ( 38 ) for the hot hollow bodies ( 12 ) that recovers the hollow bodies ( 12 ) carried on the shuttles ( 24 ) that travel on an off-loading section ( 22 C) of the at least one moving track ( 22 ); wherein the two successive shuttles ( 24 ) traveling on the off-loading section ( 22 C) are spaced by a determined output separation (E 3 ) that is different from the first input separation (E 1 ). 2. The method according to claim 1 , wherein, at least from their entry on the heating section ( 22 B), the shuttles ( 24 ) are controlled so that the separation between the two successive shuttles ( 24 ) is reduced relative to said first input separation (E 1 ). 3. The method according to claim 2 , wherein the separation between the two successive shuttles ( 24 ) remains reduced relative to said first input separation (E 1 ) as long as they are traveling on the heating section ( 22 B). 4. The method according to claim 3 , wherein the separation between the two successive shuttles remains equal to a second constant separation (E 2 ) as long as they are traveling on the heating section ( 22 B). 5. The method according to claim 4 , wherein the output separation (E 3 ) is greater than the second separation (E 2 ) for heating. 6. The conveyor ( 20 ) for using the method according to claim 1 , wherein each shuttle ( 24 ) comprises a first support element ( 26 A) for a first hollow body ( 12 ) and a second support element ( 26 B) for a second hollow body ( 12 ), each shuttle ( 24 ) thus being able to carry simultaneously two hollow bodies ( 12 ), the first and second support elements ( 26 A, 26 B) for each shuttle ( 24 ) being mounted to move on said shuttle ( 24 ) between an extended position in which the first and second support elements ( 26 A, 26 B) are separated by said first input separation (E 1 ) in the direction of movement of the shuttle ( 24 ), and a close position in which the support elements ( 26 A, 26 B) are brought close to one another in the direction of movement of this shuttle ( 24 ). 7. The conveyor ( 20 ) according to claim 6 , wherein each shuttle ( 24 ) comprises an arm ( 50 ) that defines an axis of orientation, each end of said arm ( 50 ) comprising one of the first and second support elements ( 26 A, 26 B) for its respective shuttle, said arm ( 50 ) being mounted to move in rotation relative to the shuttle ( 24 ) around a main axis between an upright position corresponding to the direction of movement of the shuttle ( 24 ), and an oblique position that is inclined relative to the upright position. 8. The conveyor ( 20 ) according to claim 7 , further comprising an actuator that is able to control wherein the arm ( 50 ) between its upright position and its oblique position. 9. The conveyor ( 20 ) according to claim 8 , wherein the actuator is able to be actuated by an actuating element carried by one of the adjacent shuttles ( 24 ). 10. The conveyor ( 20 ) for using the method according to claim 2 , wherein each shuttle ( 24 ) comprises a first support element ( 26 A) for a first hollow body ( 12 ) and a second support element ( 26 B) for a second hollow body ( 12 ), each shuttle ( 24 ) thus being able to carry simultaneously two hollow bodies ( 12 ), the support elements ( 26 A, 26 B) for each shuttle ( 24 ) being mounted to move on said shuttle ( 24 ) between an extended position in which the support elements ( 26 A, 26 B) are separated by said first input separation (E 1 ) in the direction of movement of the shuttle ( 24 ), and a close position in which the support elements ( 26 A, 26 B) are brought close to one another in the direction of movement of this shuttle ( 24 ). 11. The conveyor ( 20 ) for using the method according to claim 3 , wherein each shuttle ( 24 ) comprises a first support element ( 26 A) for a first hollow body ( 12 ) and a second support element ( 26 B) for a second hollow body ( 12 ), each shuttle ( 24 ) thus being able to carry simultaneously two hollow bodies ( 12 ), the support elements ( 26 A, 26 B) for each shuttle ( 24 ) being mounted to move on said shuttle ( 24 ) between an extended position in which the support elements ( 26 A, 26 B) are separated by said first input separation (E 1 ) in the direction of movement of the shuttle ( 24 ), and a close position in which the support elements ( 26 A, 26 B) are brought close to one another in the direction of movement of this shuttle ( 24 ). 12. The conveyor ( 20 ) for using the method according to claim 4 , wherein each shuttle ( 24 ) comprises a first support element ( 26 A) for a first hollow body ( 12 ) and a second support element ( 26 B) for a second hollow body ( 12 ), each shuttle ( 24 ) thus being able to carry simultaneously two hollow bodies ( 12 ), the support elements ( 26 A, 26 B) for each shuttle ( 24 ) being mounted to move on said shuttle ( 24 ) between an extended position in which the support elements ( 26 A, 26 B) are separated by said first input separation (E 1 ) in the direction of movement of the shuttle ( 24 ), and a close position in which the support elements ( 26 A, 26 B) are brought close to one another in the direction of movement of this shuttle ( 24 ). 13. The conveyor ( 20 ) for using the method according to claim 5 , wherein each shuttle ( 24 ) comprises a first support element ( 26 A) for a first hollow body ( 12 ) and a second support element ( 26 B) for a second hollow body ( 12 ), each shuttle ( 24 ) thus being able to carry simultaneously two hollow bodies ( 12 ), the support elements ( 26 A, 26 B) for each shuttle ( 24 ) being mounted to move on said shuttle ( 24 ) between an extended position in which the support elements ( 26 A, 26 B) are separated by said first input separation (E 1 ) in the direction of movement of the shuttle ( 24 ), and a close position in which the support elements ( 26 A, 26 B) are brought close to one another in the direction of movement of this shuttle ( 24 ).