Method of managing preforms immobilized in a heating station

The invention claimed is: 1. A method for managing of captive preforms ( 12 ) immobilized in a heating station ( 10 ) during an interruption of production, the heating station ( 10 ) forming part of an installation ( 11 ) for production of thermoplastic material containers by forming preforms heated by the heating station ( 10 ), the preforms ( 12 ) following a production stream (P) through the production installation ( 11 ), the heating station ( 10 ) including: a device ( 14 ) for conveying preforms ( 12 ) including individual supports ( 16 ) circulating in a closed circuit, each individual support ( 16 ) being intended to support a preform ( 12 ) in continuous movement along a predetermined transport path ( 18 ) forming a section of the production stream (P) from an entry point (A) to an exit point (B), a heating cavity ( 30 ) bordered by at least one row of emitters ( 32 ) of monochromatic electromagnetic radiation commanded between an extinguished state and a lit state, the heating cavity ( 30 ) being crossed by the transport path ( 18 ); the method comprising: ejecting from the production stream (P) cold captive preforms that have been immobilized before they have been exposed to the electromagnetic radiation emitted by the emitters ( 32 ) to a recycling stream ( 42 ); and rejecting from the production stream (P) hot captive preforms that have been at least partly exposed to the electromagnetic radiation emitted by the emitters ( 32 ) to a reject stream ( 38 ) separate from the recycling stream ( 42 ), wherein the cold captive preforms ( 12 ) are ejected from the production stream (P) downstream of the heating cavity ( 30 ). 2. The method as claimed in claim 1 , wherein the cold captive preforms ( 12 ) and the hot captive preforms ( 12 ) are selectively ejected from the production stream (P) by two distinct devices ( 34 , 41 ) for ejecting preforms ( 12 ). 3. The method as claimed in claim 1 , wherein the cold captive preforms ( 12 ) and the hot captive preforms ( 12 ) are ejected from the production stream (P) by a common ejector device ( 34 ). 4. The method as claimed in claim 3 , wherein the cold captive preforms ( 12 ), respectively the hot captive preforms ( 12 ), ejected by the common ejector device ( 34 ) are selectively switched to the recycling stream ( 42 ), respectively to the reject stream ( 38 ), by a sorting device ( 50 ). 5. The method as claimed in claim 1 , wherein the cold captive preforms ( 12 ) are ejected from the production stream (P) downstream of the exit point (B) of the heating station ( 10 ), for example when the preforms ( 12 ) are taken up by a transfer wheel arranged directly downstream of the heating station ( 10 ). 6. The method as claimed in claim 5 , wherein the emitters ( 32 ) of the heating cavity ( 30 ) are maintained in an extinguished state for as long as the cold captive preforms ( 12 ) circulate in the heating cavity ( 30 ). 7. The method as claimed in claim 1 , wherein at least some of the cold captive preforms ( 12 ) oriented toward the recycling stream ( 42 ) are subsequently transformed into finished containers by forming after heating. 8. The method as claimed in claim 7 , wherein the cold captive preforms ( 12 ) oriented toward the recycling stream are again introduced into the production stream (P) upstream of the heating station ( 10 ). 9. The method as claimed in claim 1 , wherein at least some of the cold captive preforms ( 12 ) oriented toward the recycling stream ( 42 ) are destroyed and the material thereof is re-used to produce new preforms ( 12 ). 10. The method as claimed in claim 1 , wherein the production installation ( 11 ) includes a forming station ( 13 ) that is arranged downstream of the heating station ( 10 ) along the production stream (P), the hot captive preforms ( 12 ) being ejected from the production stream (P) downstream of the heating station ( 10 ), for example at the level of the forming station ( 13 ). 11. A heating station ( 10 ) comprising: a device ( 14 ) for conveying preforms ( 12 ) including individual supports ( 16 ) circulating in a closed circuit, each individual support ( 16 ) being intended to support a preform ( 12 ) in continuous movement along a predetermined transport path ( 18 ) forming a section of the production stream (P) from an entry point (A) to an exit point (B); a heating cavity ( 30 ) bordered by at least one row of emitters ( 32 ) of monochromatic electromagnetic radiation commanded between an extinguished state and a lit state, the heating cavity ( 30 ) being crossed by the transport path ( 18 ); a first ejector device ( 34 ) arranged along the transport path ( 18 ) downstream of the heating cavity ( 30 ) allowing selective ejection of a preform ( 12 ) from its individual support ( 16 ) upstream of the exit point (B), the preform ( 12 ) ejected being directed toward the reject stream ( 38 ); and a second ejector device ( 41 ) arranged along the transport path ( 18 ) allowing selective ejection of a preform ( 12 ) from its individual support ( 16 ) upstream of the entry point (A), the preform ( 12 ) ejected in this way being directed toward a recycling stream ( 42 ) in the direction of the entry point (A) of the heating station ( 10 ). 12. A container production installation ( 11 ) comprising a heating station ( 10 ) having: a device ( 14 ) for conveying preforms ( 12 ) including individual supports ( 16 ) circulating in a closed circuit, each individual support ( 16 ) being intended to support a preform ( 12 ) in continuous movement along a predetermined transport path ( 18 ) forming a section of the production stream (P) from an entry point (A) to an exit point (B); a heating cavity ( 30 ) bordered by at least one row of emitters ( 32 ) of monochromatic electromagnetic radiation commanded between an extinguished state and a lit state, the heating cavity ( 30 ) being crossed by the transport path ( 18 ); and the installation ( 11 ) further comprising a common device ( 34 ) for ejecting captive preforms ( 12 ), the production installation ( 11 ) including a device ( 50 ) for selectively sorting the preforms ( 12 ) ejected by said common ejector device ( 34 ) toward a recycling stream ( 42 ) or toward a reject stream ( 38 ). 13. The method as claimed in claim 2 , wherein the cold captive preforms ( 12 ) are ejected from the production stream (P) downstream of the heating cavity ( 30 ). 14. The method as claimed in claim 3 , wherein the cold captive preforms ( 12 ) are ejected from the production stream (P) downstream of the heating cavity ( 30 ). 15. The method as claimed in claim 2 , wherein at least some of the cold captive preforms ( 12 ) oriented toward the recycling stream ( 42 ) are subsequently transformed into finished containers by forming after heating. 16. The method as claimed in claim 3 , wherein at least some of the cold captive preforms ( 12 ) oriented toward the recycling stream ( 42 ) are subsequently transformed into finished containers by forming after heating. 17. The method as claimed in claim 2 , wherein at least some of the cold captive preforms ( 12 ) oriented toward the recycling stream ( 42 ) are destroyed and the material thereof is re-used to produce new preforms ( 12 ). 18. The method as claimed in claim 2 , wherein the production installation ( 11 ) includes a forming station ( 13 ) that is arranged downstream of the heating station ( 10 ) along the production stream (P), the hot captive preforms ( 12 ) being ejected from the production stream (P) downstream of the heating station ( 10 ), for example at the level of the fo