To make a sterilization step appropriate in an aseptic filling apparatus. Provided is an aseptic filling apparatus including a step of sterilizing a preform and a step of sterilizing a container obtained by molding the preform, wherein assuming sterilization effects in the respective sterilization steps as X [LRV] and Y [LRV], a relationship of 5≤X+Y≤10 (where Y≥0) is established.

A container handling plant and a method for a container handling plant are shown. The container handling plant comprises at least one container handling machine for handling containers, wherein at least one container handling machine comprises a type preselection memory in which different types are preselectable for a handling to be performed by the container handling machine, at least one output device positioned at the at least one container handling machine for outputting an audio signal and/or an optical signal, and a control device configured to control the at least one output device such that the output device acoustically outputs a predetermined audio signal made of tone sequences comprising at least two different tones and/or optically outputs an optical signal, if due to the type preselected in the type preselection memory a change of a type or a refilling for the preselected type at the container handling machine is scheduled in the future at the end of a predetermined time period.

A device for providing clean air in a beverage filling plant is described. The device includes an inflow channel with at least one filter for pretreating the air sucked in via a supply-air feed. The inflow channel is adjoined by a first outflow channel with at least one filter for treating the air pretreated in the inflow channel for feeding into a filling cleanroom of the beverage filling plant. The inflow channel is adjoined by a second outflow channel for treating the air pretreated in the inflow channel for feeding into a blowing cleanroom for the blow-molding of plastic containers. A dehumidifying device for dehumidifying the pretreated air is arranged in the second outflow channel.

A bottling apparatus (1) in aseptic conditions of containers (100) made of a thermoplastic material, comprising: at least one mobile organ such as, for example, a blowing nozzle (24) that is partially located in a contamination-controlled environment (3) isolated from an external environment (4); a linear motor (6) for driving the mobile organ (24), the linear motor (6) comprising a cylindrical stator (7) and a rotor or magnetic shaft (8) integrally connected to the mobile organ (24), the separation volume between the rotor (8) and the cylindrical stator (7) being sanitisable by means of a sanitising fluid that passes through a grooved surface (14, 15, 18).

The method relates to a method for filling a container (13, 32) with carbonized liquid filling material and for closing the filled container, in which the filling material is introduced in a filling station (10, 30) by a filling head (11, 33) at defined filling pressure into the container (13, 32), wherein the filling head (11, 33) is firstly moved from an idle position, which permits supplying and inserting a container (13, 32) into the filling station (10, 30), into a working position toward the inserted container, in which an end region (16) of the filling head seals off the opening (14) of the container, the container (13, 32) is then filled, the filling head (11, 33) is moved after completion of the filling phase back out of the working position into an idle position spaced apart from the container (13, 32) and the container (13, 32) is then closed in the filling station (10, 30) using a cap (20) at least enough that filling material can no longer escape, and the container (13, 32) is then removed from the filling station (11, 33), characterized in that before the movement of the filling head (11, 33) from the working position into the idle position spaced apart from the container (13), an overpressure lying between the ambient pressure and the filling pressure is set in a pressure chamber (15) of the filling station (10, 30) surrounding the opening (14) of the inserted container (13, 32), which overpressure is selected in such a way that possible foaming up of the filling material located in the container (13, 32) is minimized enough that filling material does not escape from the container (13, 32) when the filling head (11, 33) is raised out of the working position after the filling procedure.

A bottling apparatus (200) in aseptic conditions of containers (100) made of a thermoplastic material, comprising: a stretching rod (5) partially located in a contamination-controlled environment (3) isolated from an external environment (4); a linear motor (6) comprising a cylindrical stator (7) and a rotor (8) integrally connected to the stretching rod (5); a first support (107) and a second support (207) for the rotor (8), arranged at opposite ends of the cylindrical stator (7) and integrally connected thereto, in each of the supports (107, 207) at least one passage (707, 807; 107a, 207a) being obtained to allow a sanitising fluid to pass through a separation volume (30) defined between the cylindrical stator (7) and the rotor (8).

In a carbonated drink filling method, a preform is continuously transferred and introduced into a heating furnace, heated to a temperature for molding the preform into a container, molded into the container in a molding die after the preform exits the heating furnace, conveyed in an upright position during which a coolant (F) is injected to a bottom of the container to cool the bottom. The container is filled with a carbonated drink (a) through a mouth portion of the container, and the mouth portion is then sealed. The coolant is injected in the cooling to the bottom of the container from a nozzle opening on either or both sides of a conveyance line of the container, and the nozzle opening is directed diagonally upward to the bottom of the container in such a manner that an extension of the nozzle opening intersects with the conveyance line of the container.

A liquid-containing container manufacturing method includes: a liquid blow molding step of, in a state in which a reversal panel formation part forms a convex surface projecting toward inside of a cavity, supplying a pressurized liquid into a preform placed inside a cavity, to mold the preform into a container including a reversal panel; and a headspace formation step of pressing the container by a press part to reverse the reversal panel, and thereafter releasing press by the press part to increase a volume of the container and thereby form a headspace.

A bottle is conveyed to a filling device without being sterilized by a container sterilizer, and a culture medium is filled inside the bottle by using the filling device. Then, the bottle is capped with a cap using a cap attachment device. Thereafter, whether or not bacteria survive or propagate in the culture medium in the bottle is verified.

The present invention relates to a system for the disinfection of containers in a blowing and filling system of said containers with a product, in particular a system for the internal disinfection of said containers by means of ultraviolet-C radiation LED emitters.

The invention in particular relates to a disinfection unit (6) of containers (C) or preforms (P), characterized in that it comprises a carousel (13) on which there is supported a plurality of disinfection members (8, 108), which are movable between a raised position and a lowered position, wherein said lowered position is configured so as to allow the disinfection members (8, 108) to enter said containers (C) or preforms (P) to be disinfected, wherein each of said disinfection members (8, 108) comprises a plurality of disinfection elements (20) emitting UV-C radiation or it is connected to a LASER source (102) which emits UV-C radiation or radiation in the visible-infrared field (VIR).