An apparatus for reheating and conditioning an elongate preform for forming a blow molded container, said apparatus comprising: a receiver including an elongate annular non-cylindrical inner surface portion, wherein the surface portion defines a cavity and is adapted to engage with an elongate outer surface of an elongate preform to transfer heat thereto by conduction from said surface portion, wherein the surface portion includes a three-dimensional relief to provide substantially non-uniform contact between the receiver and the elongate preform; and means for heating said receiver.

Container made of a plastic material, provided with a base including a standing ring forming a support flange and a diaphragm extending from the standing ring to a central portion, the diaphragm being capable of standing in an outwardly-inclined position, the diaphragm connecting to the standing ring at an outer junction forming an outer articulation of the diaphragm with respect to the standing ring; the diaphragm connecting to the central portion at an inner junction forming an inner articulation of the diaphragm with respect to the central portion; the diaphragm being invertible with respect to the standing ring to an inwardly-inclined position; the central portion having a thickness greater than the diaphragm, the central portion having an annular section of greater thickness adjacent to the inner junction, the central portion having a central recess thinner than the annular section and protruding upwardly from an inner edge of the annular section.

Disclosed is a method and a system for producing an ampoule filled with a medical liquid. A preform is produced by plastic injection moulding that is then inhomogeneously heated and blown to form an ampoule body. Further disclosed is an ampoule produced by means of stretching and blowing, which comprises a connector with a break-off part in which the predetermined breaking point is aligned with the septum of the connector.

The present invention relates to a method for manufacturing containers from thermoplastic materials by blow moulding or extrusion blow moulding a preform that has been pre-heated in a furnace then placed in a mould consisting of two half-moulds that define a moulding cavity, said preform being blown into the mould, optionally with a pre-blowing step. Said steps of heating the preforms, pre-blowing and blowing are controlled by a control unit on the basis of various control parameters such as the temperature in the furnace, the blowing pressure in the mould and/or the pre-blowing pressure and/or the pre-blowing flow rate and/or the speed of the stretching rod, for example. Said method is characterised in that it comprises at least the following steps: i) measuring the wall thickness of said containers at at least two different heights upon exiting the mould; ii) comparing the thickness measurements with setpoint values determined for each height of the containers; iii) if the difference between the thickness measurements and the determined setpoint values is greater than a determined threshold, modifying at least one of the control parameters, said modified control parameter(s) being selected at least by calculating the theoretical effects of the variation for each parameter on the thicknesses, then selecting the parameter or parameters that cause the smallest difference between the measured thickness values and the theoretical thickness values; iv) steps i) to iii) are repeated until the differences between the thickness measurements and the determined setpoint values are below said determined threshold.

Container made of a plastic material, provided with a base including a standing ring forming a support flange and a diaphragm extending from the standing ring to a central portion, the diaphragm being capable of standing in an outwardly-inclined position, the diaphragm connecting to the standing ring at an outer junction forming an outer articulation of the diaphragm with respect to the standing ring; the diaphragm connecting to the central portion at an inner junction forming an inner articulation of the diaphragm with respect to the central portion; the diaphragm being invertible with respect to the standing ring to an inwardly-inclined position; the central portion having a thickness greater than the diaphragm, the central portion having an annular section of greater thickness adjacent to the inner junction, the central portion having a central recess thinner than the annular section and protruding upwardly from an inner edge of the annular section.

An oven for preforms and in particular a preform rotation system heats portions of the preform in a preferential manner. An oven (1) for blowing or stretch-blowing preforms (P) to provide containers (C) with oval section includes a path (2) for the preforms (P), transfer system (3) of the preforms (P) from a transport system upstream of the oven (1) and a transfer system (4) of the heated preforms (P) from the oven (1) to a downstream transport. Mandrels (9) are slidingly carried along the path (2), the mandrels temporarily engage with the preforms (P) to conduct the preforms along the path (2). The oven (1) includes at least one first heating module (10) and at least one second heating module (10). The oven (1) includes elements (22, 25) for rotating the preforms (P) by 180, the elements being in median position of the second heating module (10).

Method for heating a preform (1) comprising: introducing the preform (1) into a heating apparatus (5) comprising an array of infrared emitters (50) arranged in multiple columns (Cj) and multiple rows (Ri), orienting angularly the preform at an input angular position by rotating the preform around the longitudinal axis; setting power levels of the infrared emitters (50) so as to divide the array of infrared emitters (50) into subsets of columns (SCn), each subset of columns (SCn) generating heat at a different power level from an adjacent subset of columns (SCn); and heating the preform (1) with the array of infrared emitters (50) while translating the preform (1) in a direction parallel to the rows (Ri) of the array at a translation speed, and simultaneously rotating said preform (1) around its longitudinal axis (A1) in front of said infrared emitters (50) at a rotation speed.

A method for producing containers made of thermoplastic material from preforms. In example embodiments, the method includes comparing a thickness measurement with a stored thickness setpoint, by use of a control unit, and modifying an electrical power of at least two rows of radiation sources while keeping the sum of the electrical powers being supplied to all rows of radiation sources the same, by use of the control unit, if the measured thickness is different from the thickness setpoint. A computer program product and data processing device using the method is also disclosed.

Provided is a thermal treatment unit for preforms that includes an element for blocking radiation toward the neck of the preforms. The unit can include a first wall having a first heating element and a second wall having a second heating element, a first grip and move system for gripping and moving preforms on a first row, a second grip and move system for gripping and moving preforms on a second row. The unit also includes a blocking element extending between the first and second rows to block radiation emitted by the first heating element and the second heating element toward the second grip and move system and toward the first grip and move system, respectively.

Provided is a method for heating a succession of preforms. The method includes heating a body of a first preform using two heating elements that each heat a heated area of the body. The method includes determining a target heating temperature for each heated area according to the container to be produced, measuring the temperature of one of the heated areas of the body upon completion of the heating step, and modifying the heating power of the heating element corresponding to the heated area of the body if the measured temperature of the heated area is different from the target heating temperature. The method further includes heating the body of the other preforms of the succession of preforms with the modified heating power.