Method for individual measurement of the temperature of a preform

The invention claimed is: 1. A method for measuring the temperature of a preform in an installation for manufacturing containers by forming preforms made of a thermoplastic material comprising: moving the preforms continuously in a line along a production path using a device; heating the preforms in a station which is passed through by the production path; contactlessly measuring the temperature of a part of the preforms using a device comprising a sensor which sensor measures the temperature of the preforms running continuously over a measurement section of the production path, the device and sensor thereof remaining spaced a distance from the preforms without making contact therewith as they move along the production path; wherein the measurement device is equipped with a convergent optical device which allows an image of the sensor to be projected in a measurement direction Y in a zone for measuring the temperature of each of the preforms, the measurement zone having a section of dimensions smaller than the outer diameter of the part of the preform to be measured in order to individually and successively measure the temperature of each preform. 2. The method as claimed in claim 1 , wherein the response time needed for the measurement device to supply a temperature measurement is less than the exposure time during which the part to be measured of a running preform cuts the measurement zone. 3. The method as claimed in claim 1 , wherein the parts to be measured of two adjacent preforms are separated in the running direction by an interval P of a width greater than the dimensions of the section of the measurement zone. 4. The method as claimed in claim 1 , wherein the measurement direction Y is oriented toward the measurement section by forming, with the direction of movement of the preforms, an angle such that when a preform leaves the measurement zone and before the next preform enters into the measurement zone, the measurement zone remains within the interval P for a time greater than or equal to the response time of the measurement device. 5. The method as claimed in claim 1 , wherein the measurement direction Y is oriented toward the measurement section orthogonally to the direction of movement of the preforms in order to obtain a maximum exposure time in the measurement zone of the part to be measured of each preform. 6. The method as claimed in any one of the preceding claims claim 1 , wherein the preforms run in a rectilinear direction all along the measurement section. 7. An installation for implementing the method as claimed in claim 1 , comprising: the device for conveying the preforms in a line along a production path; the station for heating the preforms which is passed through by the production path; the device for contactlessly measuring the temperature of a part of the preforms comprising a sensor which is capable of measuring the temperature of the preforms running continuously over a measurement section of the production path; wherein the measurement device is equipped with a convergent optical device which allows an image of the sensor to be projected in a measurement direction Y in a measurement zone situated on the measurement section of the production path. 8. The installation as claimed in claim 1 , wherein the measurement device is arranged in proximity to the measurement section, the measurement direction being orthogonal to the direction of movement of the preforms over the measurement section. 9. The installation as claimed in claim 7 , wherein the measurement section is arranged in the heating station. 10. The installation as claimed in claim 7 , wherein the measurement section is arranged downstream and/or upstream of the heating station. 11. The method as claimed in claim 2 , wherein the parts to be measured of two adjacent preforms are separated in the running direction by an interval P of a width greater than the dimensions of the section of the measurement zone. 12. The method as claimed in claim 2 , wherein the preforms run in a rectilinear direction all along the measurement section. 13. The method as claimed in claim 3 , wherein the preforms run in a rectilinear direction all along the measurement section. 14. The method as claimed in claim 4 , wherein the preforms run in a rectilinear direction all along the measurement section. 15. An installation for implementing the method as claimed in claim 2 , comprising: the device for conveying the preforms in a line along a production path; the station for heating the preforms which is passed through by the production path; the device for contactlessly measuring the temperature of a part of the preforms comprising a sensor which is capable of measuring the temperature of the preforms running continuously over a measurement section of the production path; wherein the measurement device is equipped with a convergent optical device which allows an image of the sensor to be projected in a measurement direction Y in a measurement zone situated on the measurement section of the production path. 16. An installation for implementing the method as claimed in claim 3 , comprising: the device for conveying the preforms in a line along a production path; the station for heating the preforms which is passed through by the production path; the device for contactlessly measuring the temperature of a part of the preforms comprising a sensor which is capable of measuring the temperature of the preforms running continuously over a measurement section of the production path; wherein the measurement device is equipped with a convergent optical device which allows an image of the sensor to be projected in a measurement direction Y in a measurement zone situated on the measurement section of the production path. 17. An installation for implementing the method as claimed in claim 4 , comprising: the device for conveying the preforms in a line along a production path; the station for heating the preforms which is passed through by the production path; the device for contactlessly measuring the temperature of a part of the preforms comprising a sensor which is capable of measuring the temperature of the preforms running continuously over a measurement section of the production path; wherein the measurement device is equipped with a convergent optical device which allows an image of the sensor to be projected in a measurement direction Y in a measurement zone situated on the measurement section of the production path. 18. An installation for implementing the method as claimed in claim 5 , comprising: the device for conveying the preforms in a line along a production path; the station for heating the preforms which is passed through by the production path; the device for contactlessly measuring the temperature of a part of the preforms comprising a sensor which is capable of measuring the temperature of the preforms running continuously over a measurement section of the production path; wherein the measurement device is equipped with a convergent optical device which allows an image of the sensor to be projected in a measurement direction Y in a measurement zone situated on the measurement section of the production path. 19. The installation as claimed in claim 8 , wherein the measurement section is arranged in the heating station. 20. The installation as claimed in claim 8 , wherein the measurement section is arranged downstream and/or upstream of the heating station.