A method and a device are disclosed for making thin plastic films having two or more layers, which are subdivided and separated in the form of tubular bags for portioned reception of different products, wherein the plastic films are provided with welding seams running substantially transversely to the longitudinal direction with predetermined spacing between one another to form bag-like containers, and the containers are separated from one another by a cutting or separating process, the method being characterized by the steps: a) welding the films with predetermined spacing by means of an ultrasound welding process, maintaining a defined, film-dependent distance between a processing tool and a counter tool while welding; and b) separating the tubular bags welded in this way by means of a mechanical cutting process, with or without reduced ultrasound excitation at the point of the respective weld seams.

The ultrasound welding device, for welding flexible packages is disclosed. The device includes: a power generator to generate a sinusoidal electric signal at a predetermined frequency; a transducer operatively associated with the power generator to transform the electric signal generated by the latter into mechanical vibrations having the same frequency as the electric signal; a sonotrode associated with the transducer and structured to amplify and transmit the mechanical vibrations generated by the transducer to a welding surface defined on the same; and a contrast element provided with a contrast surface arranged to engage the welding surface of the sonotrode during the welding operations. The transducer and sonotrode are engaged so as to amplify and transmit the vibrations generated by the transducer to the welding surface of the sonotrode without an amplifier or similar device.

According to one embodiment a packaging method is provided in which a tube is supplied in a forward movement direction. The method includes a folding step in which the tube is acted on in a manner that is transverse to the forward movement direction, folding part of the tube in a folding direction, and a sealing and cutting step after which a tube closed at one end and a package closed and separated from the tube are obtained. During the folding step the tube is held transversely, and a tear is generated in the folding direction between the acted on and held parts of the tube. The tube is sealed on both sides of the tear and cut at the height of the tear. Packaging machines for carrying out the method are also disclosed. Suitable.

A shippable bundled product including a plurality of paper product rolls each individually packaged by a first package material and arranged relative to one another so as to form a bundle. The bundle is packaged by a second package material. The second package material has a shrinkage factor relative to the bundle of less than zero and the bundle has a size of 18 in.×14 in.×8 in.

The procedure of the invention consists in manufacturing and/or transforming flexible containers in vertical filling and sealing machines that manufacture or process English fold, stable bottom or pad type containers, by generating and sealing flaps at the top and/or bottom of the lateral sides of the previous pre-container (6a) or subsequent pre-container (6b) arranged in the vertical machine.

Impact bodies (2; 3) installed in the vertical machine are used, which, when operated, hit, push and fold at least part of at least one side or lateral side on at least another part of another side or contiguous side, thus generating at least any one of the flaps such as: the plus flaps (11; 12; 13), triangular body flaps (14) manipulated triangular body flaps (15) the flap folded on itself (15a) or the strip flap (15b).

Subsequently, the flaps are sealed, by means of a sealing mode like that of a resistance, in order to keep the generated flap permanently stable.

Another object of the invention, devices that are installed in the vertical machine that facilitate the optimal generation of the flaps, such as: the Rammer body (19) intended to widen and stretch the wrapper or sheet of the bottom part or/and of the lower support side of the pre-container (6a), or Pressing platform or drawer unit (22) intended to push and crush the upper part of the pre-container (6b) against the underside of the clamp (1a), causing the pre-container (6b) to expand three-dimensionally in a cubic shape.

The new machines of the invention will have at least one impact body (2; 3) or/and at least one device (19; 20; 21; 22) of the invention.

The invention also protects different packaging models, such as mixed packaging: one half of the pad type and the other half of the English fold type.

A sealing device for forming a transversal seal to a tetrahedral packaging container is provided. The sealing device comprises a sealing element and an imprint ruler arranged at a longitudinal distance from the sealing element. The sealing element is configured to provide a top transversal seal to a packaging container while the imprint ruler is configured to provide a transversal imprint to the same packaging container.

Provided is a wound body formed by winding a long sheet. The wound body is supportable by a support shaft. The support shaft includes a cylindrical outer peripheral part that includes a first projection located at a proximal end and a second projection located at a distal end, and includes an inner peripheral part that includes a first recess part located at the one end and recessing outward in the radial direction and a second recess part located to extend from the one end to the other end and recessing outward in the radial direction. A recessing amount of the second recess part is smaller than that of the first recess part. The support shaft and the core body are integrally rotatable around the central axis by engagement of the first projection with the first recess part in a state where the core body is mounted on the outer periphery of the support shaft. The circumferential position of the first projection around the central axis is aligned with the circumferential position of the first recess part around the central axis by engagement of the second projection with the second recess part when the core body is mounted on the outer periphery of the support shaft.

A packaging apparatus for small piece goods, the use of the packaging apparatus, and a method for producing a blister tube are provided. The packaging apparatus includes a packaging material guiding device for providing a shaped packaging material web suitable for receiving small piece goods, a longitudinal joining device which is arranged downstream of the packaging material guiding device and a transverse joining device which is arranged downstream of the packaging material guiding device. The transverse joining device joins the shaped packaging material web together at predetermined intervals transversely to the direction of travel to form a transverse joining area. The transverse joining device includes two joiners, which have a plurality of embossers that are individually movable transversely to the direction of travel and have an embosser stop area which cooperate such that elevations that are palpable are formed by the embossers in the transverse joining area.

A reusable container system and method for reducing the use of plastic is disclosed herein. In one embodiment, a reusable container includes: a reusable bottle; a lid attachable to the reusable bottle that enables access removing and inserting single-use replaceable sealed bag or pouch; an inner single-use replaceable sealed bag or pouch that holds a liquid, viscous, or gel material inside the reusable bottle; a sprayer or pump attachable to the reusable bottle; and a dip tube with a leading edge that pierces the inner bag upon assembly of the above listed components. The liquid material is accessed for dispensing through the dip tube without contaminating the reusable bottle.

A method for testing a tubular bag machine, the tubular bag machine having multiple electronic drive units controlled independently by a drive control system for driving functional elements of the packing machine in a cycle time-synchronous manner during predefined motion sequences, one drive unit being a transverse sealing unit comprising a motor and two transverse sealing jaws for transversely sealing a film tube, the drive torque being measured using a drive controller, and the position of the drive motor measured using a position sensor, by removing the film tube from the sealing zone between the transverse sealing jaws, closing the jaws according to a predefined target torque stored in the drive control system; measuring the actual position of the drive motor at the target torque; and comparing the measured actual position to a target position stored in the drive control system and associated with the predefined target torque.