A joining apparatus includes a fusing mechanism part that joins two thermoplastic sheet-like materials by fusing, a sticking mechanism part that sticks an adhesive tape along a joined portion of the sheet-like materials, a workbench having a placement surface on which the fusing mechanism part and the sticking mechanism part are disposed side by side, the placement surface allowing the sheet-like materials in an unfolded state to be placed thereon, and a guide that allows an end portion to be joined of one of the sheet-like materials and an end portion to be joined of the other sheet-like material to overlap each other while aligned along a plane intersecting the placement surface, each of the end portions to be joined of the sheet-like materials being placed on the placement surface, and to feed the overlapping end portions to be joined. The fusing mechanism part fuses and joins the end portions.

A form-fill-seal machine 100 has a pull-down belt mechanism 23, a vertical sealing mechanism 2, and a controller 29. The pull-down belt mechanism conveys a cylindrical film Fm. The vertical sealing mechanism applies pressure and ultrasonic oscillation to the cylindrical film which is conveyed by the pull-down belt mechanism, and seals the cylindrical film. The controller controls the pull-down belt mechanism, and the pressure and the amplitude of the ultrasonic oscillation applied to the cylindrical film by the vertical sealing mechanism. The controller applies pressure and ultrasonic oscillation to the cylindrical film immediately before reaching a first point in time when the cylindrical film begins to be conveyed. The controller changes at least one of the pressure and the amplitude of the ultrasonic oscillation applied to the film according to the speed of the film in a time period after reaching the first point in time.

Apparatus for shaping a segment of material includes a forming member having a curved sidewall shaped complementary to a desired shape of the segment of material, and a conforming member having an applicator side and an engagement side disposed for engagement with the curved sidewall of the forming member. The conforming member includes a plurality of attachment regions disposed on the applicator side. Each attachment region is adapted to hold the segment of material on the conforming member. Engagement of the conforming member with the forming member causes the attachment regions to move from a first shape profile to a second shape profile, the second shape profile being the desired shape of the segment of material.

The present invention provides a manufacturing system of a packaging bag with excellent manufacturing efficiency. According to the present invention, provided is a manufacturing system of a packaging bag, including: a film supply device; a conveying device; a bottom insertion device; a bottom sealing device; a transverse sealing device; and a cutoff device, wherein the film supply device supplies a front surface long film and a back surface long film facing each other, the conveying device is configured to convey the front surface long film and the back surface long film, the bottom insertion device, the bottom sealing device, the transverse sealing device, and the cutoff device are arranged in this order along a conveyance direction, the bottom insertion device is configured to start inserting a bottom long film between the front surface long film and the back surface long film at an insertion start position and to complete insertion of the bottom long film at an insertion completion position downstream from the insertion start position, the bottom sealing device is configured to weld the bottom long film to the front surface long film and to the back surface long film, the transverse sealing device forms a transverse seal portion extending in a direction perpendicular to the conveyance direction so as to weld the front surface long film and the back surface long film to each other, and the cutoff device cuts off the front surface long film, the back surface long film, and the bottom long film along the transverse seal portion.

A method and apparatus for constructing a tubular assembly (24) comprising an inner portion (21) and a further portion (22) surrounding the inner portion, the further portion being formed from a strip (50) of material comprising two opposed longitudinal marginal side portions (53). The apparatus (100) comprises an assembly station (106) having a wall (122). The apparatus (100) comprises means for advancing the inner portion (21) along a first path (111) extending past the wall, and means for advancing the strip (50) along a second path (112) and causing the strip to encircle the wall and thereby wrap about and surround the inner portion (21). The two marginal side portions (53) are disposed in overlapping relation on the side of the wall opposed to the first path (111). The apparatus (100) further comprises a system (131) for affixing the two longitudinal marginal side portions (53) together in overlapping relation to assemble the strip (50) into a tubular configuration about the inner portion (21), whereby the strip in the tubular configuration provides the further portion (22).

The technology relates to a heat sealing system (400). For instance, the heat sealing system may include a sealer assembly (800) including a pair of heat sealing bars (830, 840) configured to generate heat seals. The heat sealing system may also include a positioning (900) assembly including a platform (910) and a motor (952). The sealer assembly may be mounted to the positioning assembly, and the motor may be configured to move the sealer assembly towards and away from an edge of a table (1600).

The present invention relates to a method for splicing an upstream section and a downstream section of a multi-layered laminated sheet material wherein each section of the material comprises at least three layers each having first and second surfaces and wherein the at least three layers comprise first and second outer layers and at least one inner layer located between the first and second outer layers, comprising the steps of a) splicing together the upstream and downstream sections of both the first and second outer layers with a splicing material; b) removing the first outer layer from the multi-layered laminated sheet material to expose a surface of an inner layer; c) splicing the upstream and downstream sections of the exposed inner layer with a splicing material; and d) applying a replacement first outer layer to the exposed surface of the inner layer. A spliced multi-layered laminated sheet material produced according to the method is also provided. Also provided is an apparatus for splicing two sections of a multi-layered laminated sheet material wherein each section of the material comprises at least three layers each having first and second surfaces and wherein the at least three layers comprise two outer layers and at least one inner layer located between the two outer layers, the apparatus comprising: a first splicer configured to apply a splicing material to the two outer layers of the multi-layered laminated sheet material, a delaminator configured to remove a first outer layer, a second splicer located downstream of the delaminator configured to apply a splicing material to the exposed inner layer and an applicator located downstream of the second splicer configured to reapply an outer layer to the exposed inner layer.