A device (30) for serial treatment of hollow bodies including: a transport member (32); a treatment rod (38) mounted slidably relative to the transport member (32); controlled elements for moving each treatment rod (38) between a retracted position and an extended position in which the treatment rod (38) is intended for being inserted axially into the transported hollow body; wherein the controlled elements consist of an electric actuator (42) controlled by an electronic control unit (44) for stopping the treatment rod (38) in the extended position thereof. A method for serial treatment of preforms using the treatment device is also described.

A method of heating plastic blanks for molding comprises, for each blank in a sequence of blanks of different types, determining a heating requirement corresponding to characteristics of the blank a molding process to be applied and heating each blank according to its heating requirement. A microwave field is generated having a defined heating rate, and the blank is placed in the microwave field for a period of time equal to the heating duration, such that the heating duration and the heating rate correspond to the heating requirement.

A plastic bottle manufacturing device (50) includes a preform heating part (52) that includes a plurality of heating bodies (65), a blow-molding part (54) that molds a plastic bottle (20) by blow-molding a preform (10), and a preform temperature measuring part (53) that measures temperatures of the preform (10) at a plurality of measurement points (P) in a longitudinal direction of the preform (10). The plurality of measurement points (P) are provided in correspondence with the plurality of heating bodies (65). A control unit (70) controls an output of each heating body (65) based on an optimal temperature distribution at each measurement point (P) of the preform (10) that has been predetermined and an actually measured temperature distribution at each measurement point (P) of the preform (10).

An oven (10) for the heat treatment of preforms and a method for operating an air-cooling device (42) fitted to such an oven includes controlling elements (58) to vary the cooling air flow rate onto the body (18) and bottom (20) of the preforms (12) along the heating path.

A method for producing a multipack of containers includes heating a preform, cooling at least part of the preform, the at least part of the preform defining a cooled region, and producing a first container from the preform. The container has a reinforced wall portion formed from the cooled region. The method continues with applying adhesive to the reinforced wall portion, thereby forming an adhesive point and fixing a second container to the adhesive point.

A method for manufacturing a resin container includes: performing injection molding on a resin preform; adjusting a temperature of the preform manufactured in the performing injection molding; and performing blow molding on the temperature-adjusted preform to manufacture the resin container. In the performing injection molding, injection molds are opened after completion of filling and pressure holding of a resin material, and the preform is taken out without being cooled in the injection molds after the completion of filling and pressure holding. In addition, in the adjusting the temperature, a refrigerant is introduced into the preform to cool the preform.

A temperature adjustment mold capable of performing local temperature adjustment in an axial direction from the inside of a preform while restricting shrinkage and deformation of the preform, for adjusting a temperature of an injection-molded bottomed resin-made preform includes a rod portion inserted into the preform and extending in the axial direction of the preform. The rod portion includes an annular projection portion that protrudes in a radial direction of the rod portion and contacts an inner peripheral surface of the preform. The rod portion contacts a bottom portion of the preform to restrict shrinkage in the axial direction of the preform. The projection portion restricts shrinkage in a radial direction of the preform, conducts heat between the rod portion and the preform, and adjusts a temperature at a predetermined part in an axial direction of the preform.

A temperature adjustment mold for adjusting a temperature of a preform that is injection-molded, has a bottomed shape, and is made of resin includes one or more adjusting portions that face a part of an outer peripheral surface of a body portion of the preform and locally heat a predetermined portion in a circumferential direction of the preform. The adjusting portion is disposed such that a gap is formed in the circumferential direction, and an attachment position is adjustable in the circumferential direction.

The invention relates to a device for heating preform bodies or flat or preformed semi-finished products from thermoplastic material (3), comprising at least one base body (1.0, 2.0), on the surface of which at least a first layer or coating is formed, which comprises at least one electric heating resistor in the form of a flat, geometrically arranged conductor loop. The base body also has contact elements, by which the at least one heating resistor can be connected to a power source, wherein, as a result of the geometrically arranged conductor loop(s), a defined temperature profile can be generated, which can be transmitted contactlessly to the preform body or the semi-finished product by an outer contact layer formed on the first layer or coating, by contact the surface of a preform body or semi-finished product and/or by using convection or thermal radiation. During a transmission of the defined temperature profile, the preform body or the semi-finished product is arranged at a distance to the contact layer(s).

A method and device for producing an optimized neck contour on preforms below the neck which is optimal for subsequent stretch blow molding. The geometry has a significantly thinner wall thickness than the neck itself. The preform can only be produced in the injection molding tool, when axial channels are used on the point or the vanes produce the thin points on the preform during injection molding. The thin-walled geometry on the preform can be produced outside of the mold during post-cooling by embossing. The preform is then removed in a cooled receiving sleeve and is cooled in the body by intensive contact cooling while no cooling contact is made with the preform neck due to the initial position of the embossing element. Due to the reheating of the neck they can be mechanically deformed into a new geometry advantageous for blow molding and thus wall thickness can be influenced.