An adapter device for suctioning air out of plastic bags of a type typically used for containing fallen leaves and other yard waste for disposal comprises a screen that surrounds a space that is connectable in fluid flow relation with the suction end of the vacuum hose, a shield positioned around the screen that is capable of preventing a plastic bag from being sucked by vacuum to the screen. The mouth of the shield is sized for blocking leaves or other yard waste matted in the bag from being sucked to the screen while allowing air in the bag to flow to the screen.

An adapter device for suctioning air out of plastic bags of a type typically used for containing fallen leaves and other yard waste for disposal comprises a screen that surrounds a space that is connectable in fluid flow relation with the suction end of the vacuum hose, a shield positioned around the screen that is capable of preventing a plastic bag from being sucked by vacuum to the screen. The mouth of the shield is sized for blocking leaves or other yard waste matted in the bag from being sucked to the screen while allowing air in the bag to flow to the screen.

The technology described herein generally relates to an automated packaging apparatus and system that packages loose particles into a conical container as well as the final folded packages. More specifically, loose plant matter, such as crumbled dried leaves, are supplied to successive paper cones. The apparatus packs the crumbled leaves into the cones, closes the wide top portion of the cone into a precise shape, and then runs a quality control check to ensure that the final filled cone meets preset specifications.

The technology described herein generally relates to an automated packaging apparatus and system that packages loose particles into a conical container as well as the final folded packages. More specifically, loose plant matter, such as crumbled dried leaves, are supplied to successive paper cones. The apparatus packs the crumbled leaves into the cones, closes the wide top portion of the cone into a precise shape, and then runs a quality control check to ensure that the final filled cone meets preset specifications.

The technology described herein generally relates to particular form of folded package and the method of forming that folded package. More particularly, using a folding tip and the application of vacuum pressure to a paper cone it is possible to achieve the formation of properly folded packages that may further include a core that is deposited axially along the length of the package.

The technology described herein generally relates to particular form of folded package and the method of forming that folded package. More particularly, using a folding tip and the application of vacuum pressure to a paper cone it is possible to achieve the formation of properly folded packages that may further include a core that is deposited axially along the length of the package.

A fill packaging machine includes a vertical sealing means for folding a packaging film at its central part and continuously forming a vertical sealed portion at its side edge part to shape into a cylinder, and a lateral sealing means for forming lateral sealed portions in a direction perpendicular to the longitudinal direction of the packaging film. An easy separable sealed portion is continuously formed in the side edge part of the packaging film by the first vertical sealed portion forming section, and a vertical sealed portion having a partial non-sealed portion of a bottle mouth type is formed on the easy separable sealed portion by the second vertical sealed portion forming section. The first vertical sealed portion forming section is a pair of heat sealing rolls or heat sealing plates, a surface of at least one of which is made from an elastic material softer than a metal.

An apparatus configured to provide portioned instances of a compressible material includes a channel assembly, a gas source, a cutting assembly, and a discharge assembly. The channel assembly holds a bulk instance of the material extending through upper and lower channels of a continuous channel. The gas source supplies gas to compress the bulk instance. The cutting assembly moves in relation to the channel assembly to isolate the upper and lower channels, severing upper and lower material portions of the bulk instance. The discharge assembly directs gas to impinge on a lower face of the cutting assembly to discharge the lower material portion as a portioned instance. The channel assembly may be moveable, where operation of the gas source, cutting assembly, and/or discharge assembly are based on moving the channel assembly between various positions. The gas supply may be controlled based on a determined property of the portioned instance.

A filling machine (1) includes a dosing station (3) comprising a supporting element (5) and a dosing unit (10) having a dosing cylinder (12) and a piston (13), for filling bodies (101) of capsule (100) with a product (P) picked-up from a tank (4); the supporting element (5) is movable between a lowered picking position (B), in which the dosing unit (10) is inserted in the tank (4) and a dosing position (C) in which the dosing unit (10) faces a body (101); the piston (13) is movable between a first internal position (D) to form a dosing chamber (15) suitable for picking up and retaining a dose (PI) of product (P), a second internal position (E) to reduce a volume of the dosing chamber (15) and compress the dose (PI) and an external position (F) to push the dose (PI) from the dosing cylinder (12) into a body (101).

A filling machine (1) includes a dosing station (3) comprising a supporting element (5) and a dosing unit (10) having a dosing cylinder (12) and a piston (13), for filling bodies (101) of capsule (100) with a product (P) picked-up from a tank (4); the supporting element (5) is movable between a lowered picking position (B), in which the dosing unit (10) is inserted in the tank (4) and a dosing position (C) in which the dosing unit (10) faces a body (101); the piston (13) is movable between a first internal position (D) to form a dosing chamber (15) suitable for picking up and retaining a dose (PI) of product (P), a second internal position (E) to reduce a volume of the dosing chamber (15) and compress the dose (PI) and an external position (F) to push the dose (PI) from the dosing cylinder (12) into a body (101).