A pouch machine vertical sealer capable of fusing a pouch film web to form a plurality of spaced vertical seals along a length of the film web to form pouches. The pouch machine vertical sealer includes a sealer wheel rotatable about a vertical axis of rotation and defines a film web path about a periphery of the sealer wheel. The vertical sealer further includes a plurality of vertical sealer land assemblies spaced apart about the periphery of the sealer wheel. Each vertical sealer land assembly includes an impulse heater such that contact between the film web and each impulse heater of the plurality of vertical sealer land assemblies forms the spaced apart vertical seals along the length of the film web.

A pouch machine vertical sealer capable of fusing a pouch film web to form a plurality of spaced vertical seals along a length of the film web to form pouches. The pouch machine vertical sealer includes a sealer wheel rotatable about a vertical axis of rotation and defines a film web path about a periphery of the sealer wheel. The vertical sealer further includes a plurality of vertical sealer land assemblies spaced apart about the periphery of the sealer wheel. Each vertical sealer land assembly includes an impulse heater such that contact between the film web and each impulse heater of the plurality of vertical sealer land assemblies forms the spaced apart vertical seals along the length of the film web.

A cross seal device 100 is provided. The device 100 comprising a cross sealing table X having a cross sealing station (A) and a toggle assembly (B). The cross sealing station (A) comprising a front seal assembly (1) and a rear seal assembly (2) configured to engage and disengage by controlled oscillation of first pair of C shaped actuator levers (6c, 6d) and second pair of C shaped actuator levers (6a, 6b) via sealing drive shaft (5) of toggle assembly B. The cross sealing station (A) performs horizontal reciprocating action for sealing. The cross sealing device 100 further comprising Cross Sealing Up Down control assembly C which controls vertical reciprocating movement of cross sealing table X employing Stripping System D to ensure no PIS (Product in Seal) and improves packaging capacity.

A cross seal device 100 is provided. The device 100 comprising a cross sealing table X having a cross sealing station (A) and a toggle assembly (B). The cross sealing station (A) comprising a front seal assembly (1) and a rear seal assembly (2) configured to engage and disengage by controlled oscillation of first pair of C shaped actuator levers (6c, 6d) and second pair of C shaped actuator levers (6a, 6b) via sealing drive shaft (5) of toggle assembly B. The cross sealing station (A) performs horizontal reciprocating action for sealing. The cross sealing device 100 further comprising Cross Sealing Up Down control assembly C which controls vertical reciprocating movement of cross sealing table X employing Stripping System D to ensure no PIS (Product in Seal) and improves packaging capacity.

The horizontal packaging apparatus comprises: a conveying line of products along a conveying direction; infeeding means of a continuous sheet; a forming device mounted on a support surface and comprising folding means for folding the continuous sheet to form a tubular wrapping; advancement means of the continuous sheet configured to advance the continuous sheet along an advancement direction concordant with the conveying direction of the products; pulling means arranged consecutively to the outfeed section of the forming device to bilaterally abut the facing end flaps of the lower portions of the tubular wrapping folded back beneath the products and advance the tubular wrapping wrapped around the products beyond the forming device. The reciprocal position between the support surface of the forming device and the pulling means is adjustable and variable to vary and adjust a distance between the outfeed section of the forming device and the pulling means.

The horizontal packaging apparatus comprises: a conveying line of products along a conveying direction; infeeding means of a continuous sheet; a forming device mounted on a support surface and comprising folding means for folding the continuous sheet to form a tubular wrapping; advancement means of the continuous sheet configured to advance the continuous sheet along an advancement direction concordant with the conveying direction of the products; pulling means arranged consecutively to the outfeed section of the forming device to bilaterally abut the facing end flaps of the lower portions of the tubular wrapping folded back beneath the products and advance the tubular wrapping wrapped around the products beyond the forming device. The reciprocal position between the support surface of the forming device and the pulling means is adjustable and variable to vary and adjust a distance between the outfeed section of the forming device and the pulling means.

A drug supply apparatus of the present disclosure includes a drug supply unit configured to supply a drug to a drug delivery position; a downstream conveying unit configured to convey a strip-shaped first drug packaging paper, folded in half in advance along its longitudinal direction and configured to receive a drug at the drug delivery position; and an upstream conveying unit configured to convey a strip-shaped second drug packaging paper, folded in half in advance along its longitudinal direction. In the apparatus, the upstream conveying unit conveys the second drug packaging paper toward the first drug packaging paper in such a way that the downstream end part of the second drug packaging paper holds in its inside the upstream end part of the first drug packaging paper, and the ridge line of the second drug packaging paper overlaps the ridge line of the first drug packaging paper.

A drug supply apparatus of the present disclosure includes a drug supply unit configured to supply a drug to a drug delivery position; a downstream conveying unit configured to convey a strip-shaped first drug packaging paper, folded in half in advance along its longitudinal direction and configured to receive a drug at the drug delivery position; and an upstream conveying unit configured to convey a strip-shaped second drug packaging paper, folded in half in advance along its longitudinal direction. In the apparatus, the upstream conveying unit conveys the second drug packaging paper toward the first drug packaging paper in such a way that the downstream end part of the second drug packaging paper holds in its inside the upstream end part of the first drug packaging paper, and the ridge line of the second drug packaging paper overlaps the ridge line of the first drug packaging paper.

An example system comprises a water-soluble unit dose article comprising a water-soluble fibrous non-woven sheet and a granular laundry detergent. The water-soluble fibrous non-woven sheet is shaped to form a partially sealed internal compartment and has an air permeability comprised between 5 m.sup.3/m.sup.2/min and 200 m.sup.3/m.sup.2/min. The granular laundry detergent is comprised within said internal compartment and comprises a plurality of particles, wherein the plurality of particles comprises zeolite particles. The system comprises sealing jaws, wherein at least one of the sealing jaws is a heated sealing jaw, wherein a bottom seal of the internal compartment is sandwiched between the jaws. The jaws comprise a non-stick coating in contact with the bottom seal and a first dust extraction conduct to direct a gas flow away from an area surrounding a top section of the sealing jaws or away from a bottom section of the internal compartment.

An example system comprises a water-soluble unit dose article comprising a water-soluble fibrous non-woven sheet and a granular laundry detergent. The water-soluble fibrous non-woven sheet is shaped to form a partially sealed internal compartment and has an air permeability comprised between 5 m.sup.3/m.sup.2/min and 200 m.sup.3/m.sup.2/min. The granular laundry detergent is comprised within said internal compartment and comprises a plurality of particles, wherein the plurality of particles comprises zeolite particles. The system comprises sealing jaws, wherein at least one of the sealing jaws is a heated sealing jaw, wherein a bottom seal of the internal compartment is sandwiched between the jaws. The jaws comprise a non-stick coating in contact with the bottom seal and a first dust extraction conduct to direct a gas flow away from an area surrounding a top section of the sealing jaws or away from a bottom section of the internal compartment.