Method and machine for producing containers by injecting a liquid inside successive preforms

The invention claimed is: 1. A method for producing containers from successive initial preforms made of a thermoplastic material, the method comprising the steps of: feeding successive initial preforms to a heating station, heating the successive initial preforms in the heating station resulting in successive heated preforms, feeding the successive heated preforms to a forming station, injecting an incompressible liquid into each of the successive heated preforms shaping each of the successive heated preforms into containers and filling the containers with the incompressible liquid in the forming station, defining at least one stress parameter correlated to an internal stress of the thermoplastic material and defining a range of acceptable values for the at least one stress parameter, analyzing each of the successive heated preforms, the analyzing step further comprising the steps of: determining a determined value of the at least one stress parameter for each of the successive heated preforms, the determined value being determined prior to the injection of an incompressible liquid into each of the successive heated preforms, comparing the determined value to the range of acceptable values and identifying when the determined value is outside of the range of acceptable values for a given preform, emitting an output signal when the determined value is outside the range of acceptable values. 2. The method according to claim 1 , wherein the at least one stress parameter is the maximal circumferential dispersion of the internal stress of the thermoplastic material, measured along a height of the successive initial preforms and the successive heated preforms analyzed in the analyzing step. 3. A method for producing containers from successive initial preforms made of a thermoplastic material, the method comprising the steps of: feeding successive initial preforms to a heating station, heating the successive initial preforms in the heating station resulting in successive heated preforms, feeding the successive heated preforms to a forming station, injecting an incompressible liquid into each of the successive heated preforms shaping each of the successive heated preforms into containers and filling the containers with the incompressible liquid in the forming station, defining at least one stress parameter correlated to an internal stress of the thermoplastic material and defining a range of acceptable values for the at least one stress parameter, analyzing each of the successive initial preforms and each of the successive heated preforms, the analyzing step further comprising the steps of: determining a determined value of the at least one stress parameter for each of the successive initial preforms and each of the successive heating preforms, wherein the step of determining the determined value of the at least one stress parameter is performed on each of the successive initial preforms and each of the successive heated preforms prior to the injection of an incompressible liquid into each of the successive heated preforms, comparing the determined value to the range of acceptable values and identifying when the determined value is outside of the range of acceptable values for a given preform, emitting an output signal when the determined value is outside the range of acceptable values. 4. The method according to claim 3 , wherein the determining step is performed by acquiring at least an image of each of the successive initial preforms and at least an image of each of the successive heated preforms and the step of comparing is performed by comparing the acquired images to at least a reference image of a reference heated preform having an acceptable maximal lateral flexion value. 5. The method according to claim 4 , wherein each of the successive heated preforms is moved in rotation at least during the determining step, the determining step being performed by acquiring a plurality of images of each of the successive heated preforms at different angular positions of each of the successive heated preforms and by processing the acquired plurality of images in order to identify at least one acquired image corresponding to the maximal lateral flexion of each of the successive heated preforms, the step of comparing being performed by comparing the at least one identified acquired image to the reference image. 6. The method according to claim 3 , wherein the at least one stress parameter is at least one of a variation of height and an exterior diameter of a body of each of the successive initial preforms and each of the successive heated preforms, the determining step including measuring at least one of the height and the exterior diameter of a body of each of the successive initial preforms preforms, measuring at least one of the height and the exterior diameter of a body of each of the successive heated preforms and a determining a variation of the at least one of the height and the exterior diameter. 7. The method according to claim 3 , wherein the at least one stress parameter is an internal stress intensity of the thermoplastic material of each of the successive initial preforms and each of the successive heated preforms. 8. The method according to claim 7 , wherein the step of determining the determined value includes exposing each of the successive initial preforms to a circularly polarized light and by acquiring through a second crossed circular polarizer an acquired interference image of incident polarized light passed through each of the successive initial preforms and the step of comparing is performed by comparing the acquired interference image to a reference interference image of a polarized light passed through at least one reference preform, the at least one reference preform having a reference stress parameter value in or at an extreme of the range of acceptable values. 9. The method according to claim 3 , wherein the step of injecting the incompressible liquid into the given preform is not performed when the output signal has been emitted in connection with the given preform. 10. The method according to claim 3 , wherein the output signal is one of an audible and visible alarm signal. 11. The method according to claim 3 performed on a machine for forming successive containers comprising a heating station configured to produce the successive heated preforms from the successive initial preforms and a forming station, the forming station including an injection head configured to inject an incompressible liquid in the successive heated preforms to form the successive containers, and an analyzing device configured to carry out the analyzing step. 12. The method according to claim 11 , wherein the analyzing device of the machine comprises at least an upstream optical device located upstream the heating station and a downstream optical device located between the heating station and the forming station, both the upstream optical device and the downstream optical device being arranged to respectively acquire at least one image of each of the successive initial and heated preforms, the analyzing device being configured to determine a maximal lateral flexion value of each of the successive heated preforms. 13. The method according to claim 3 , wherein the upstream optical device comprises an interferometer device having a source of circularly polarized light and a device configured to acquire through a second crossed polarizer an interference image of the polarized light passed through each of the successive initial preforms. 14. A method for producing containers from successive initial preforms made of a thermoplastic material, the method