A belt-type vacuum packaging machine (1) comprising a base frame (2) that supports a work surface (3), a conveyor belt 4 of products (P) to be vacuum packed in bags (B) inside a vacuum chamber (10), a vacuum production system (11) that communicates with the vacuum chamber (10), welding means (12) of the bags (B) adapted to be operated after the vacuum packaging of the bags (B), an operating control panel (40) and an injection system (13) for injecting a gaseous substance into each bag (B) after the vacuum packaging is performed, in which the injection system (13) comprises a supply line (15) for the gaseous substance, interception devices of the supply line and connecting means (16) of the supply line (15) connecting to a plurality of injector nozzles (14) of the gaseous substance into the bags (B). Preferably, the injector nozzles (14) are removably fixed to the conveyor belt (4) and are accommodated in the vacuum chamber (10) together with the welding means (12) during the vacuum packaging.

A pack including at least one single-use capsule or pod for a portioned beverage which has two opposite bases, and a side wall connecting the two bases defining therewith a chamber for containing an aromatic substance; the pack has a sealed container for containing the capsule or pod housed in a protective inert gas atmosphere; more specifically the sealed container copies at least in part the shape of the capsule or pod.

A process and apparatus (1) for packaging a product (P) arranged on a tray (4) is disclosed. The apparatus comprises a packaging assembly (8) configured for tightly fixing one or more film sheets to one or more trays. The packaging assembly includes a lower tool (22) defining a prefixed number of seats (23) for receiving the trays and an upper tool (21) facing the lower tool and cooperating with the upper tool to define a packaging chamber (24). The packaging assembly (8) is configured to operate at least in a first operating condition, where said packaging chamber (24) is open, and in a second operating condition, where said packaging chamber (24) is hermetically closed. First injection apertures (90) are positioned in corner regions of the seat and are configured to inject streams of gas in a direction substantially parallel to and above the flange (4c) of a tray (4) positioned in said seat. The process includes the step of activating injection of a plurality of streams of gas through said first apertures (90) in order to form a controlled atmosphere inside the tray before closing the tray with the film.

A process and apparatus can be used to vacuum skin package a product arranged on a support comprising providing a film portion above said support with the product being arranged between the support and the film portion; air tightly fixing the film portion to the support; removing at least a portion of air from a volume underneath said film portion through said at one nozzle inserted in an interspace between the film portion and the support.

A pack including at least one single-use capsule or pod for a portioned beverage which has two opposite bases, and a side wall connecting the two bases defining therewith a chamber for containing an aromatic substance; the pack has a sealed container for containing the capsule or pod housed in a protective inert gas atmosphere; more specifically the sealed container copies at least in part the shape of the capsule or pod.

Systems, methods, and apparatuses for a safe delivery system for a modified atmosphere and functional treatments into a sealed enclosure containing perishable products. The systems, methods, and apparatuses may include an injector, a top sheet dispenser, a bottom sheet dispenser, and pallet wrapper. The top sheet, bottom sheet, and wrap sheet form the sealed enclosure. The injector may create a modified atmosphere in the sealed enclosure. The injector may include a stabilizing support bar and at least one nozzle formed at a right angle to the stabilizing support bar. The nozzle may be connected to a gas source for injecting at least one gas into the sealed enclosure. The nozzle may be connected to a vacuum or controlled venting source to remove air and control the pressure within the sealed enclosure. The injection process is protected from leakage using containment devices, pads and/or aspirating covers or a closed chamber. The system includes the use of modified atmosphere and various functional substances to sanitize, condition, protect, preserve, or enhance perishable products.

The disclosure refers to a packaging device for manufacturing a packaging for a foodstuff. In particular, the packaging may include a trough-shaped lower packaging part and a top film which can be sealed together along their edges by means of a sealing tool of the packaging device. In order to improve a packaging device completely without evacuation or by evacuation in a simple and inexpensive manner with only a slight negative pressure in such a way that sufficient vapor purging is possible and at the same time cooling of the foodstuff before sealing or excessive degassing of the foodstuff does not take place, vapor can be introduced under pressure between the lower packaging part and the top film at at least one vapor entry point before sealing and can be released into the surrounding atmosphere at an outlet point from the packaging.

Disclosed are a vacuum suction nozzle for improving vacuum suction performance and a vacuum suction apparatus including the same. The nozzle includes blade portions extending from both sides thereof so as to reduce a gap occurring between the nozzle and an outer skin material for a vacuum insulation panel (VIP) or other vacuum wrapping paper when the outer skin material or vacuum wrapping paper is sealed, thereby minimizing the occurrence of a leak and thus enabling efficient vacuum suction. Further, the nozzle achieves efficient vacuum suctioning by ensuring a suction channel inside the vacuum insulation panel (VIP) or other vacuum wrapping paper through a protrusion extending to the front of the nozzle.

Disclosed is a device for gas replacement capable of reducing the amount of replacement gas, improving a gas replacement rate, and reducing the amount of split liquid. In a replacement nozzle (11) which blows the replacement gas toward a container opening portion symmetrically about a center line in the container radial direction, the space between nozzle port outermost walls is divided with a plurality of wind direction adjustment plates (16a, 16b) to generate a plurality of blowout ports. The replacement gas flow blowing along the outermost walls of the nozzle opening are so blown inward as to form an angle of 100 to 130. Moreover, the replacement gas is blown from the replacement nozzle to the range between the level lower than the end of the can opening by one third or more the height of the can neck portion and the level equal to or higher than the height of the can cover.

Provided is an oxygen-absorbing multilayer body including an oxygen-absorbing layer containing an oxygen-absorbing composition and a thermoplastic resin layer containing a thermoplastic resin (b), wherein the oxygen-absorbing composition includes at least one compound having a tetralin ring represented by Formula (1), a transition metal catalyst, and a thermoplastic resin (a). ##STR00001##