Method and Device for Producing and Filling Sacks

Abstract

The invention relates to a method and a device for producing and filling sacks comprising at least four longitudinal seams. According to prior art, the production of said sacks generally involves the longitudinal welding of a flat film to form a tubular section. The tubular section is cut into individual tubular pieces, which are provided with additional longitudinal weld seams. Both the transport of the individual tubular pieces and the subsequent introduction of the latter into a sack forming and filling process are complex. The devices used in this process are expensive and prone to faults. The aim of the invention is to provide a more cost-effective method for producing and filling sacks. To achieve this, the material that forms the sacks is supplied from an unwinding device (2, 3, 5) in the form of a tubular material (4) to a sack forming device (1) and the tubular material (4) is provided with longitudinal seams (29) in the sack forming device (1), said seams extending over a large part of the sacks (27).

Description

The invention relates to a method for producing and filling sacks according to the preamble of claim 1 and a device for producing and filing sacks according to the preamble of claim 13.

Sacks are produced inter alia by so-called “Form, Fill and Seal” machines (referred to as FFS machines in the following).

These machines, which are shown inter alia in the patent specifications DE 199 33 486, EP 534 062, DE 44 23 964, DE 199 20 478 and DE 199 36 660, have unwinding devices, on which tubes are stored. The tube is unwound by these unwinding devices and separated into tube pieces. Usually, tube bottoms are formed, filling material is filled in the resulting sack and the sack is sealed in the additional work steps. The type of sack formation and filling shown in the afore-mentioned documents forms a part of the contents disclosed in this document. The same applies to the definitions of the term “Form, Fill and Seal” machines (FFS) provided in these documents and also to the transport of the film tubes, film sections and sacks into these machines. Usually bulk materials are filled using these machines.

As a rule, for the purpose of processing on the FFS machines, film tubes are formed by blown film extrusion, the format of the film tubes (here their circumference) corresponding to that of the formed sack. However, as a result of this approach, it is necessary to carry out expensive format changes at the extrusion systems with relative frequency in order to be able to realize different sack formats. Furthermore, the formats required for the sack formation, are relatively small and can be produced in a relatively uneconomic manner. Blown film extrusion systems of a larger format produce the same film at lower costs per unit of area.

Therefore, many a time attempts are made to produce initially very broad film webs by flat film extrusion or by blown film extrusion on systems of a large format, wherein usually blown film extrusion systems were preferred likewise primarily for reasons of economy. The resulting film tubes or film webs of large format were then processed further into flat film webs by cutting them in accordance with the format.

Subsequently, one of these laid flat film webs was folded together into a tube and joined by a longitudinal weld seam to form a tube. However, the use of the machines described is primarily limited to industrial applications, such as the bagging of dyes, plastic granulate, fertilizers and other bulk materials.

Consumer goods sold by retail are usually transported and distributed in sacks of a higher quality. It is thus known, for example, to produce side-gusseted bags or side-gusseted sacks from tube pieces, which are formed from several film sections. The edges of the respective film sections are usually heat-sealed to one another for this purpose. This procedure is carried out between welding jaws, which arrest the material to be heat-sealed during the welding process.

Tube pieces are usually produced in this way, the length of which corresponds to that of the sacks formed subsequently. In other cases, directly after production, the tube pieces formed are provided with the length of the sack formed subsequently and supplied individually to the sack-forming and filling devices. This type of forming high-quality sacks is well known, for example, in the field of pet foods. Here, emphasis is laid on side-gusseted sacks, which have edge seams on each of their outer folds. These sacks are rumored to have greater stability and a better appearance, in particular. These sacks are usually produced by initially producing a tube by the longitudinal welding of a flat film. This tube is separated into individual tube pieces and is provided with additional longitudinal weld seams.

However, both the transport of the individual tube pieces and the subsequent introduction of the latter into a sack-forming and filling process are complex. This usually takes place using rotary feeders or other suction devices, which grasp the tube pieces individually and supply them to the sack-forming device. Such suction devices are expensive and prone to faults.

It is therefore the object of the present invention to suggest a more cost-effective method for producing and filling sacks according to the preamble of claim 1.

This object is achieved

• • by supplying the material that forms the sacks in the form of a tubular material from an unwinding device to a sack-forming device, and
  • by providing the tubular material in the sack-forming device with longitudinal seams, which extend at least over a large part of the sacks.

The term “seams” or “longitudinal seams” in this context is meant to connote a generic term for joining seams and all other seams, which also include the edge seams. It is not the function of the edge seams, in particular, to hold together the joining points of flat films like joining seams. The function of the edge seams consists in the described stabilization of the sack, which supports particularly the formation of an approximately cuboid shape in its filled state and thus facilitates the stacking of such sacks.

In order to now process the tubular material into sacks, it is advantageous to initially form sack bottoms using transverse welds. Transverse welds can be formed with particular ease on the material that is still tubular since this material can be grasped at different points by grippers or pliers or similar holding means.

For the same reason, it is recommended to also form longitudinal seams before the material is separated into individual tube pieces. The formation of the longitudinal seams can precede the formation of the transverse weld seams. In addition, the tubular material can be provided before or after the formation of the longitudinal seams, with diagonal welds, which form so-called corner welds on the sacks formed subsequently. Said corner welds further increase the stability of the sacks.

In an advantageous improved development of the invention, the sacks are also filled in the sack-forming device. A tube piece, which is held using holding means for the purpose of forming longitudinal seams or transverse seams, can be supplied by the same or additional holding means to a filling device. The time-consuming processes of depositing, storing and again gathering the tube pieces are thus omitted. Holding means designed advantageously as grippers carry out the transportation through the sack-forming device. The grippers can be present in pairs in each case, wherein they engage around the tube pieces laterally in the region of the upper edge. It may be necessary to deliver the tube piece from one pair of grippers to another. For this purpose, transfer positions are provided at which both the pairs of grippers hold the tube piece temporarily. The transport of the tube pieces or the sacks takes place in the horizontal direction at least for the first half of their path, i.e. in every movement of the tube pieces or the sacks the horizontal distance exceeds the vertical distance.

In the sack-forming device, the tubular material can be provided with longitudinal seams during the stop phases of the intermittent transport. Basically, longitudinal seams can also be applied during the transport of the tubular material. However, in the previous case, the longitudinal seams can be formed over different periods of time, which are indeed limited upwards by the reciprocal cycle speed, but are variable in other respects. If the longitudinal seams are formed, for example, using welds, then the weld time can be selected, for example, as a function of the material thickness.

Additional exemplary embodiments of the invention are specified in the present description and the claims. The figures underlying the present description show:

FIG. 1: a device for producing and filling sacks, with which device the method according to the invention can be performed.

FIG. 2: a cross-section of a tubular material, which was provided with longitudinal seams according to the inventive method.

FIG. 3: a cross-section of another tubular material, which was provided with longitudinal seams according to the inventive method.

This device 1 comprises a supporting arm 2, on which lies a roll 3 of tubular film 4. The tubular film 4 has side gussets that are not illustrated. The transport rollers 5, which can also be driven partially, ensure a usually continuous unwinding of the tubular film 4. The lever 9, which is provided with a load by a piston-cylinder unit 10 and which carries a deflecting roller 6 and is frequently referred to as dancer device when taken as a whole, and the transport roller 7, 8 and the pair of feed rollers 15 altogether ensure in a manner known per se that the tubular film 4 is moved further on its route of transport in a cyclically intermittent manner. In its further course, the tubular film 4 passes through a station 28 for applying longitudinal seams. Longitudinal seams are applied to the outer edges of the side gussets of the tubular film 4 in a manner that is not illustrated in detail, the working length of the station 28 being at least of the length of the sacks formed subsequently. The longitudinal seams are usually produced by applying the welds during the stop phases of the intermittent transport. The tubular film 4 provided with longitudinal seams is conveyed using additional transport rollers 8 to a corner weld station 11 and a cooling station 12.

Using the pair of feed rollers 15, the tubular film 4 is pushed through the welding jaws of a cross welding station 13 and through a cross cutting station 16. The tools of the cross welding station 13 and the cross cutting station 16 can be moved toward and away from the tubular film 4 in a manner that is not described in detail here, for example, using a parallelogram arrangement 14, in planes that are orthogonal to the feed direction of the tubular film 4. After the grippers 17 have grasped the tubular film 4, a tube piece 18 is cut off in the cross cutting station 16 from the tubular film 4 above the grippers 17. Simultaneously, in the cross welding station 13, a cross weld is added to the tubular film above its cut edge. This cross weld represents the bottom of the tube piece 18 to be formed in the next work cycle of the device 1. The cross-weld is the preferred, though not the only option for creating the bottoms. Additional joining techniques, such as for example, gluing are also feasible.

The grippers 17 convey the tube piece 18 to a transfer point at which additional grippers 19 grasp the tube piece 18 and transport it to a filling station 20. There the tube piece 18 is transferred to stationary grippers 21 and opened by the suction devices 22 so as to enable the filling material which is led by the filling pipe 23 to enter into the tube piece 18. In doing so, the tube piece 18 lies with its lower end on a conveyor belt 24 so as to prevent it 18 from being loaded excessively along its longitudinal edges during the filling process. Additional grippers 25 convey the filled tube piece to the head seam welding station 26 in which the tube piece 18 is sealed with a head weld seam and it thus forms a finished sack 27. It is also possible to use other joining techniques to seal the head region of the tube piece 18. The finished sack is guided out of the device 1 by the conveyor belt 24.

FIGS. 2 and 3 show cross-sections of tubular materials 4, which were provided with longitudinal seams according to the inventive method. The material 4 shown in FIG. 2 is usually produced as a tubular film and is wound up into a roll 3 after being provided with side gussets 30. The tubular material 4 is provided with edge seams 29 on its outer edges 31 in the station 28 for the application of longitudinal seams. The tubular material 4 shown in FIG. 3 differs from that 4 shown in FIG. 2 in terms of a longitudinal seam 32, with which both the edge regions of a flat film are joined to one another for the purpose of forming a tube. As a rule, this joining process is carried out by heat-sealing. However, other joining techniques such as sealing or the application of adhesives or hot melt adhesives are also used in practice. After such a formation of a tubular material 4, which can likewise be provided with side gussets 30, the tubular material 4 is wound up into a roll.

LIST OF REFERENCE SYMBOLS

• 1 Device for producing and filling sacks
• 2 Supporting arm
• 3 Roll
• 4 Film
• 5 Transport roller
• 6 Deflecting roller
• 7 Transport roller
• 8 Transport roller
• 9 Lever
• 10 Piston-cylinder unit
• 11 Corner weld station
• 12 Cooling station
• 13 Cross-welding station
• 14 Parallelogram arrangement
• 15 Pair of feed rollers
• 16 Cross-cutting station
• 17 Gripper
• 18 Tube piece
• 19 Gripper
• 20 Filling station
• 21 Stationary gripper
• 22 Suction device
• 23 Filling pipe
• 24 Conveyor belt
• 25 Gripper
• 26 Head seam welding station
• 27 Sack
• 28 Station for applying longitudinal seams
• 29 Edge seams
• 30 Side gussets
• 31 Outer edges
• 32 Longitudinal seam

Claims

1. Method for producing and filling sacks (27), wherein: the material that forms the sacks is supplied in the form of a tubular material (4) from an unwinding device (2, 3, 5) to a sack-forming device (1), the tubular material is separated into individual tube pieces (18) in the sack-forming device and the tube pieces (18) or the sacks (27) are transported by grippers (17, 19, 25) during at least one part of their path in the sack-forming device (1), said sacks comprising at least four longitudinal seams (29), characterized in that the tubular material (4) is provided in the sack-forming device (1) with longitudinal seams (29), which extend at least over a large part of the sacks (27), while the tubular material (4) is still in the laid-flat state.

2. Method according to claim 1, characterized in that the sack-forming device (1) carries out the formation of the sacks by forming sack bottoms in the tubular material (4) by cross-welds.

3. Method according to claim 1, characterized in that the longitudinal seams (29) are formed before the tubular material (4) is separated into individual tube pieces (18).

4. Method according to claim 1, characterized in that sack-forming device (1) also carries out the filling of the sacks (27) by filling the sacks (27) with filling material.

5. Method according to the claim 1, characterized in that the grippers (17, 19, 25) engage around the tube pieces (18) or the sacks (27) in the region of their outer edges (31), the tube piece (18) or the sack (27) hanging down.

6. Method according to claim 1, characterized in that the tube pieces (18) or the sacks (27) are transported horizontally at least for one half of their path.

7. Method according to claim 1, characterized in that the tubular material (4) in the sack-forming device (1) is provided with longitudinal seams (29) during the stop phases of the intermittent transport.

8. Method according to claim 1, characterized in that the longitudinal seams (29) are cooled before the sack (27) is filled.

9. Method according to claim 1, characterized in that even before the application of longitudinal seams (29) in the sack-forming device (1), the tubular material (4) has at least one longitudinal weld (32), using which at least one flat film web is joined to form tubular material.

10. Method according to claim 1, characterized in that the tubular material (4) is a side-gusseted tube and that the weld seams are applied on the outer folds of the side-gusseted tube.

11. Method according to claim 1, characterized in that the tubular material (4) is provided with diagonal welds, before it (4) is provided with longitudinal seams (29).

12. Device (1) for manufacturing and filling sacks (27) comprising an unwinding device (2, 3, 5), from which the material (4) that forms the sacks, is supplied in the form of tubular material (4) to a sack-forming device (1), comprising a cross-cutting station, in which the tubular material (4) can be separated into tube pieces, and comprising holding means, using which the sacks or the tube pieces can be transported during at least one part of their path in the sack-forming device, said sacks comprising at least four longitudinal seams, said device being characterized in that a longitudinal weld device (28) is provided, which provides the tubular material (4) in the sack-forming device (1) with longitudinal seams, which extend over at least a large part of the sacks (27), while the tubular material (4) or the tube pieces (18) are still in the laid-flat state.

13. Device (1) according to the claim 1, characterized by a dancer device (6, 9, 10) between the unwinding device (2, 3, 5) and the longitudinal welding device (28).

14. Device (1) according to claim 12, characterized by a cooling device (12) for the longitudinal seams, which has a length of at least 30 cm in the transport direction of the tubular material (4).

15. Device (1) according to claim 1, characterized by a cooling device (12) for the longitudinal seams, which has a length of at least 45 cm in the transport direction of the tubular material (4).