Method for cooling heated molds from a machine for molding containers

The invention claimed is: 1. Method for cooling heated molds from a machine ( 10 ) for molding containers from thermoplastic material by stretch blow molding hot preforms by means of at least one pressurized fluid, with said rotary-type machine ( 10 ) comprising at least molding units ( 12 ), each comprising at least one mold and that are arranged on the periphery of a carousel ( 14 ) that can be driven in rotation around an axis (O) of rotation of the machine, with each molding unit ( 12 ) comprising at least a blow-molding device ( 20 ) integrating a stretching rod ( 22 ), a heating element ( 34 ) associated with the mold ( 18 ) of the unit for heating it, with said mold ( 18 ) comprising at least two half-molds ( 24 ) that each comprise an inner molding face ( 30 ) and that are respectively mounted on movable supports ( 26 ) around an axis (A) between at least one open position and one closed position of the unit, in which said inner faces ( 30 ) of said at least two attached half-molds ( 24 ) delimit together at least a portion of a cavity ( 16 ) for molding the container, wherein said cooling method comprises, for cooling said molds ( 18 ), introducing, selectively, at least one cooling fluid into a volume inside the molding cavity ( 16 ) of some of the molding units ( 12 ) when the selected molding units are in a closed position such that, after the carousel ( 14 ) is stopped to immobilize them at least during said cooling step, the molding units ( 12 ) are in a predetermined cooling zone, and wherein the cooling fluid is delivered at a lower pressure than a pressure of the pressurized fluid for blow molding. 2. Method according to claim 1 , wherein the cooling zone corresponds to an angular sector that is centered on the axis (O) of rotation of the machine ( 10 ) and that has an angle (β 1 ; β 2 ) whose value is less than or equal to (360°−α) with an angle (α) that corresponds to the angular sector in which said molding units ( 12 ) are in the open position. 3. Method according to claim 1 , wherein the cooling zone corresponds to an angular sector that is centered on the axis (O) of rotation of the machine ( 10 ) and that has an angle (˜2) whose value is less than or equal to 180°. 4. Method according to claim 1 , wherein the introduction of the cooling fluid during the cooling step is carried out in molding units ( 12 ) that are locked in the closed position by a lock ( 40 ) that comprises each of said molding units ( 12 ) of the machine ( 10 ). 5. Method according to claim 1 , wherein the cooling fluid is introduced inside the molding cavity ( 16 ) by at least one stretching rod ( 22 ). 6. Method according to claim 5 , wherein the stretching rod ( 22 ) is moved axially inside the molding cavity ( 16 ) during said cooling step to carry out an axial flushing of the molding cavity ( 16 ). 7. Method according to claim 5 , wherein the stretching rod ( 22 ) is driven selectively in rotation to carry out a circular flushing of the molding cavity ( 16 ) by means of said cooling fluid. 8. Method according to claim 1 , wherein at least a portion of cooling fluid is introduced inside the molding cavity ( 16 ) by the mold bottom ( 28 ) having a vent ( 44 ), said mold bottom ( 28 ) for demolding the bottom equipping the molding units ( 12 ) of said machine. 9. Method according to claim 1 , wherein the cooling fluid is introduced intermittently during the cooling step according to at least one sequence that comprises at least one introduction of said fluid during a predetermined duration (d) followed by an interval (t) during which said introduction is interrupted. 10. Method according to claim 1 , further comprising at least one step for measuring temperature for determining the temperature of the cooled molds ( 18 ) and wherein said cooling step is repeated in said molding units ( 12 ) until said temperature of the molds ( 18 ) is less than or equal to a predetermined target temperature (Tc). 11. Method according to claim 2 , wherein the cooling zone corresponds to an angular sector that is centered on the axis (O) of rotation of the machine ( 10 ) and that has an angle (β 2 ) whose value is less than or equal to 180°. 12. Method according to claim 2 , wherein the introduction of the cooling fluid during the cooling step is carried out in molding units ( 12 ) that are locked in the closed position by a lock ( 40 ) that comprises each of said molding units ( 12 ) of the machine ( 10 ). 13. Method according to claim 1 , wherein the introduction of cooling fluid depending on the cooling step is carried out simultaneously on all of the molding units ( 12 ) that are in said cooling zone. 14. Method according to claim 1 , wherein the introduction of cooling fluid depending on the cooling step is carried out simultaneously on only some of the molding units ( 12 ) that are in said cooling zone. 15. Method according to claim 13 , wherein the cooling zone corresponds to an angular sector that is centered on the axis (O) of rotation of the machine ( 10 ) and that has an angle (β 1 ; β 2 ) whose value is less than or equal to (360°−α) with an angle (α) that corresponds to the angular sector in which said molding units ( 12 ) are in the open position. 16. Method according to claim 14 , wherein the cooling zone corresponds to an angular sector that is centered on the axis (O) of rotation of the machine ( 10 ) and that has an angle (β 1 ; β 2 ) whose value is less than or equal to (360°−α) with an angle (α) that corresponds to the angular sector in which said molding units ( 12 ) are in the open position. 17. Method according to claim 13 , wherein the cooling zone corresponds to an angular sector that is centered on the axis (O) of rotation of the machine ( 10 ) and that has an angle (β 2 ) whose value is less than or equal to 180°. 18. Method according to claim 14 , wherein the cooling zone corresponds to an angular sector that is centered on the axis (O) of rotation of the machine ( 10 ) and that has an angle (β 2 ) whose value is less than or equal to 180°. 19. Method according to claim 13 , wherein the introduction of the cooling fluid during the cooling step is carried out in molding units ( 12 ) that are locked in the closed position by a lock ( 40 ) that comprises each of said molding units ( 12 ) of the machine ( 10 ). 20. Method according to claim 14 , wherein the introduction of the cooling fluid during the cooling step is carried out in molding units ( 12 ) that are locked in the closed position by a lock ( 40 ) that comprises each of said molding units ( 12 ) of the machine ( 10 ).