SE436272B - MACHINE FOR WORKING OF PACKAGING CONTAINERS - Google Patents

Abstract

A machine for the processing of packing containers of the type used for example for milk products. Such packing containers are manufactured from a filled material tube and are first given cushion-shape. With the help of the machine in accordance with the invention they are subsequently converted to a substantially parallelepipedic shape. The machine comprises a means of transport in the form of a wheel (35) having radial holding devices (37) for the cushion-shaped semi-finished products (2). The means of transport can be rotated step-by-step so that each indiviual packing container passes around processing stations (45 - 50) placed around the periphery of the means of transport for the folding of corner lugs, sealing and shaping.

Description

8101974-7 the sealing times for the thermoplastic material, which makes it difficult to design a final folder that works at a sufficiently high speed to operate fast packaging machines.

The movement of the more or less pre-formed packaging containers stepwise through the final folder also places high demands on accuracy if it is to be possible to guarantee that each packaging container is moved to the exact correct processing position at each station.

Previously used final folders cannot process the packaging containers with sufficient accuracy and safety at the high working speeds required by modern packaging machines, and it is therefore a general desire that a faster and more precise working final folder be constructed.

An object of the present invention is therefore to provide a machine for processing packaging containers, which machine does not suffer from the disadvantages of previous constructions but operates safely and quickly. A further object of the present invention is to provide a machine of the above kind, which safely moves and controls the packaging containers between carefully fixed positions at each processing station.

A further object of the present invention is to provide a machine which is capable of carrying out a safe and accurate folding and shaping of both sealing fins and corner flaps. A further object of the present invention is - finally - to provide a final folder which, although it makes it possible to extend the processing time in each individual processing station, has a high total capacity.

These and other objects have been achieved according to the invention in that a machine of the type mentioned in the introduction is given the characteristics that means affecting the packaging containers are arranged to move a packaging container located in a fastener radially relative to the center of the drum during a part of the rotation of the transport member.

Preferred embodiments of the machine according to the invention have furthermore been given the features set forth in the subclaims. 8 * 1 01 974 '-7 This design of the machine according to the invention provides a machine for processing or final folding of packaging containers which not only allows a very high working speed but also makes it possible to increase the available processing time at each station at the same time. as the machine guarantees a safe movement of the partially processed packaging containers between carefully fixed positions at each processing station. The machine according to the invention also ensures a safe control of the packaging containers during transport between the processing stations and finally ensures that the folding in of the corner flaps takes place step by step in a well-defined and accurate manner.

A preferred embodiment of the machine according to the invention will now be described in more detail with particular reference to the accompanying drawings, which schematically show a preferred embodiment of the machine according to the invention, only the details necessary for understanding the construction and function of the machine being included in the various figures. .

Fig. 1 shows from the side a schematic view of the machine according to the invention as it is arranged at and connected to a packaging machine of conventional type.

Fig. 2 shows the main part or final folding part of the machine according to the invention in perspective. Fig. 3 mainly corresponds to Fig. 2 but shows the drive system of the final folding part. K 'K Fig. 4 is a side view of a transport means mounted on the final folding part.

Fig. 5 shows the final folding station of the machine from the side.

Fig. 6 is a perspective view of the final folding station of Fig. 5.

Figs. 7-13 show the processing and shaping of a packaging container during its passage through the machine according to the invention, Fig. 7 showing the packaging in a feeding station, Fig. 8 showing the packaging during its movement from the feeding station, Fig. 9 showing the packaging in a Fig. 10 shows the package in a binder station, Fig. 11 shows the package in a final folding station, Fig. 12 shows the package in ready-made condition after the final folding station and Fig. 13 shows the finished packaging container in a dispensing station where it is discharged from the end. - 8110197lr-7 the transport means of the substitute part.

Figure 1 schematically illustrates a preferred embodiment of the machine according to the invention. The machine is arranged at and connected to a conventional packaging machine, of which only a limited part 1 is shown in the figure. The machine according to the invention is arranged to handle and finalize packaging containers 2 delivered from the packaging machine 1 and is therefore driven synchronously with the packaging machine 1 by means of a drive shaft 3, which connects the machine according to the invention to a power take-off 4 in the packaging machine.

For the sake of clarity, the machine according to the invention can be divided into three main parts, namely an actual final wrapper part 5 in which the successive processing of disposed packaging containers takes place, a transport part 6 for transferring packaging containers 2 from the packaging machine 1 to the final wrapping part 5, and a power transfer and drive part 7 for driving the final wrapper part 5 and the transfer part 6 synchronously with the packaging machine 1. The power transfer and drive part 7 is located at the bottom of the machine and at the same time forms a foundation for the other parts. The transport part b is located between the packaging machine 1 and the final wrapping part 5, whereby under the transport part 6 there is space for a conveyor 8 mounted on top of the drive part 7, which extends at right angles to the transport part 6 and is arranged to remove pre-formed packaging containers 2 from the final wrapper part 5 for further transport to a packer which gathers a number of individual packaging containers 2 in a larger collection package in order to facilitate the further transport to the consumer.

The transport part 6 comprises a frame 9 which has two parallel, elongate side walls between which the packaging containers are transported from the packaging machine 1 to the final wrapping part 5 by means of an endless main conveyor belt 10 running around both ends of the transfer part 6, which are freely rotatably mounted between the two parallel sides of the stand 9. The breaking roller 11 is connected to a drive motor (not shown) and simultaneously serves as a breaking roller for an additional conveyor belt 12, which is designed as a receiving conveyor belt for the packaging containers discharged from the packaging machine 1. Both the receiving conveyor belt 12 and the main conveyor belt 10 comprise a plurality of parallel belts, which are arranged at mutual intervals so that atis / ... . .. .. those without tormenting intervention with each other can run over the common breaking roller ll. The main conveyor belt 10 extends substantially horizontally or slightly upwards towards the final wrapper part 5 while the receiving conveyor belt 12 is inclined in the opposite direction and more specifically extends upwards towards the packaging machine 1 at an angle to the horizontal plane which amounts to about 300. Hereby the partially formed packaging containers discharged from the packaging machine 1 to land and soften gently after a short distance of free fall by the inclined conveyor belt 12, after which they are directly transferred to the main water conveyor belt 10 for further transport towards the final wrapper part 5. At the final wrapper part At the opposite end of the main conveyor belt 10 there is a discharge conveyor belt 13 located above it, which runs in the same main direction as the main conveyor belt 10, but is located at a distance above it which substantially corresponds to or slightly exceeds the height of the packaging containers transported on the main conveyor belt 10. While the main conveyor belt 10 and the receiving conveyor belt 12 are driven at a steady, constant speed, the output conveyor belt 13 is operated at a constant speed which is twice as high as the speed of the main conveyor belt 10. By means of a carrier 14 projecting from the conveyor belt 13, the discharge conveyor belt 13 takes over the supply of the packages arriving on the main conveyor belt 10 and moves these at double speed the last distance from the main conveyor belt 10 and over to the final wrapper part 5. This results in the final wrapper part 5 in succession. the packages to be "separated" so that the space between them becomes larger than the space between the packaging containers fed along the main conveyor belt 10, which is important for the function of the final wrapper part as will be explained in more detail below.

The power transmission or drive unit 7 located below the transport part 6 extends from the lower end of the packaging machine 1 and under the actual final folding part 5. The power transmission part 7 comprises an open part shown to the left in Figure 1 in which: the drive shaft 3 runs and connects the power take-off of the packaging machine 4 with a closed distribution gearbox 15 shown on the right in Figure 1, which at the same time forms the foundation for the final vicarious part 5. The open part of the power transmission part 7 comprises two parallel sides and a bottom and has mainly three functions, namely first to prevent contact with the drive shaft 3 , secondly, to fix the final s1o19? 4-7 folding part at the correct distance from the packaging machine 1 and thirdly to serve as a collecting tray for liquid, e.g. leaking filling material from the packaging containers. The drive shaft 3 connects via suitable couplings and gearboxes (not shown) the drive motor of the packaging machine to the drive system of the final wrapper part 5 so that the final wrapper part can be automatically driven synchronously with the packaging machine. It is also possible to drive the final winder part 5 by means of a separate, not shown drive motor, which e.g. enables continued operation with the final wrapper part 5 and the transport part 6 after it has been stopped by the main packaging machine 1.

The actual main part of the machine according to the invention, "i.e. the final folding part 5, has a foundation which at the bottom comprises the previously mentioned distribution gearbox 15. On top of this there is a second gearbox which comprises an indexing gear 16, and on top of this there is another gearbox comprising an upper angular gear: 17. The drive shaft 3 extending through the power transmission part 7 is connected via a coupling to an input shaft 18 in the gearbox 15 (Fig. 3). The input shaft 18 runs horizontally in the gearbox and drives a lower angular gear 19 and a rear angular gear 20. Transmitted via the rear angular gear 20 rotation of the input shaft 18 to a similarly horizontal but at right angle mot to the input shaft lower shaft 21, which at its two ends Ä via actuating cam curves 22 converts the movement into a reciprocating pivotal movement of two pivot members 23 mounted in the gearbox. , the function of which will be described in more detail below. The rotation of the input shaft 18 is further transmitted via the aforementioned lower angular gear 19 to a distribution shaft 24 extending vertically through the end-folding part 5. 1/6 turn of an intermediate shaft 25 projecting on either side of the indexing gearbox. Via a further recess from the indexing gearbox the rotation is transmitted further via the upper angular gearbox 17 to a horizontally located upper shaft 26, which has both ends cam curves 27, the function of which is described in more detail below.

The input shaft 18 also supports a feed cam disc 28, which via a cam follower 29 drives a feed assembly 30 pivotally mounted outside the distribution gearbox. The feed assembly 30 comprises two arms, 31 extending vertically on either side of the drive shaft. is supported by two parallel shafts 32, both of which are rotatably mounted in the end of the gearbox 15. However, this shaft 32 extends with its one end into the distribution gearbox where it carries the cam follower 29. Via this shaft the feed unit 30 is driven in a reciprocating, pivoting movement. The two pivotable arms 31 carry at their upper part a input devices 33 and an output device 34, which are suspended in parallelograms in the arms 31.

The function of the two feeders 33,34 is described in the following.

The distribution gearbox 15 is designed as an oil trough and partially filled with oil, which is supplied by means of pumps not shown, the various moving parts present in the final folding part, such as shafts, angular gears, etc. To avoid oil leakage and contamination of the packaging containers treated in the final folding part 5. drive system described in connection with Figure 3 completely closed.

The machine will now be described in more detail with special reference to Figure 2, which shows the final folding part 5 itself in perspective. The figure shows how the previously described foundation consisting of the distribution gearbox 15, the indexing gear 16 and the upper angular gear 17 17 carries two rotatable transport means 35.

The two transport means 35 each comprise a centrally located, rotatable drum 36, which is rigidly connected to the extending end of the intermediate shaft 25 from the indexing gear housing 16. The two transport means 35 are mutually identical (henceforth only one will be described) and are located axially in line with each other on either side of the indexing gear 16. The task of the transport means 35 is to move the packaging containers supplied via the transport part 6 (Fig. 1) between different processing stations in the final folding part and the transport means have for this purpose a number of fasteners 37 located evenly around the drum 36, each of which comprises a fixed and a movable jaw 38 and 39 (Fig. 4), respectively, which face each other, substantially flat working surfaces. forms a space adapted to the size of the packaging container. Each fixed jaw 38 is substantially L-shaped, the longer leg of the Lzet forming said working surface which extends substantially radially relative to the drum 36 while the shorter leg extends at an angle of 900 to the working surface so that said shorter leg forms an attachment. @ t5 37 bottom 40. At the bottom there is a recess for receiving an a1o197n-7 sealing fin on the packaging containers. The fixed jaw 38 is with its shorter leg rigidly connected to the drum 36. The movable jaw 39 is pivotally mounted about a shaft 4 4 extending parallel to the center axis of the drum. More specifically, the pivotally mounted jaw 39 forms one arm of a lever 42, the second arm carries a cam follower 43 which is in constant engagement with a double cam cam 44 located centrally in the drum 36. Upon rotation of the transport member 35, the cam cam 44 will actuate the movable jaw via the cam follower 43 and the lever 42 so that it is moved between a closed position, in which the flat working surface of the jaw 39 extends parallel to the working surface of the fixed jaw 38 (longer leg) and an open position, in which the movable jaw 39 is pivoted out substantially 100 angles to the fixed jaw 38, which to be explained in more detail in the following description of the machine's function.

Distributed around the transport means 35 there are a number of processing stations, which are arranged with a mutual division corresponding to the division between the fasteners of the transport means 37. As can be seen most clearly from Figure 1, there is an input station 45 at the end of the transport part 6, followed by a folding station 46 The bending station 46 is followed by a binder station 47, a final folding station 48, a currently unused reserve station 49 and a discharge station 50. The various stations are indicated in the order in which they are reached during operation of the machine by a individual packaging container moved by means of the transport means 35. Transpo; the member 35 is thus indexed stepwise clockwise during operation in Figure 1, each movement corresponding to a rotation corresponding to the pitch angle between the different stations (600).

In addition to the various processing stations, each transport means 35 is also surrounded by a number of guide rails (Fig. 4), which are fixedly V mounted in relation to the foundation of the machine and arranged to guide and process the packaging containers moved by the transport means. Each conveyor means 35 cooperates with two different types of guide rails, namely on the one hand outer guide rails 51, which extend around the conveyor means substantially flush with the outer ends of the fasteners 37, and inner guide rails 52, which extend around the conveyor means substantially flush with the bottom surfaces of the fasteners 37 40. Both the outer and the inner guide rails are double and located on either side 81019714-'7 of the transport member 35, which is most clearly shown in figure 2. The guide rails 51, 52 are fixedly connected to sides of a frame 53 located outside the transport member 35. which in turn is rigidly connected to the foundation of the machine. The frame 53 is illustrated for the sake of clarity only by means of dotted lines in figure 2. The guide rails 51, 52 are thus fixed and therefore do not accompany the transport member 35 during its indexing movement.

The two outer guide rails 51 start at the same level as the feeding station and extend mainly from this past the folding station and further around the transport means to end at the feeding station. The distance between the two guide rails 51 and the center axis of the conveying means 35 varies insofar as the guide rails 51 are flush with the feeding station 45 closer to the center axis of the conveying means than they do during the rest of their stretching around the conveying means. More specifically, the distance between the guide rails 51 and the center axis of the conveyor is increased successively on distances between the feed station and the bending station to then decrease again so that the guide rails approach the periphery of the conveyor and run at substantially constant distances during the remaining guide rails to the discharge station. As a result, during said first stretching of the guide rails, the distance between the guide rails 51 and the bottom surfaces 40 of the fasteners 37 will be gradually increased, seen in the direction of movement of the fastener 37, from a distance less than the height of the fastener 37 to a distance equal to the bending station 46. is greater than the height of the fastener 37. The guide rails 51 then approach the height of the fastener again and then run further at this height all the way to the discharge station. The mutual distance between the two guide rails also varies. During said, first part of the stretching of the guide rails, i.e. between the feed station and the folding station, the distance between the guide rails 51 is slightly larger than the width of the fastener 37, i.e. the distance between the side surfaces of the jaws 38, 39, measured parallel to the center axis of the transport member 35. During the distance from the feeding station to the folding station, this distance is gradually reduced at the same time as the guide rails 51, as previously mentioned, increasingly move away from the center axis of the transport member 35, and the mutual distance between the guide rails 51 has been reduced so that the distance between the guide rails 51 facing surfaces mainly correspond to the distance 8101974f? 10 between the side surfaces of the jaws 38, 39. During the continued extension of the guide rails 51 around the transport member 35, the distance is gradually further reduced so that it is at a level flush with the binder station 47 slightly less than the distance between the side surfaces of the jaws 38, 39. This distance is maintained mainly during the continued extension of the guide rails 51 up to the discharge station.

The two inner guide rails 52, like the outer guide rails 51, extend around the conveying means 35 with the beginning end f level with the feeding station 45, or between it and the folding station, and the end ending located before the feeding station 50.

However, the two inner guide rails 52 are located considerably closer to the center axis of the transport member 35 and are therefore located substantially flush with the bottom surfaces 40 of the fastener 37. The guide rails 52 extend along their entire length at some distance beyond the side surfaces of the two jaws 38, 39, i.e. the distance between the surfaces of the guide rails 52 facing each other is slightly greater than the width of the jaws 38, 39. The width of the jaws 38, 39 here, as in other parts of the description and the patent claims, refers to the distance between each tray facing side surfaces, which distance mainly corresponds to the width of a treated packaging container. The height of a fastener further means the distance from the bottom surface of the fastener facing a packaging container to the outer end of the jaws 38, 39. In other words, the height of the fastener 37 corresponds mainly to the height of a machined packaging container.

The starting ends of the two guide rails 52 at the feeding station are located at a distance from the center axis of the transport member 35 which slightly falls below the distance between the bottom surface 40 of the fastener and said center axis, i.e. the guide rails 52 are located slightly "below" the bottom surface 40 of the fastener. From the feeding station 45 the distance between the two guide rails 52 and the transport member 35 is then gradually increased so that the guide rails are flush with the folding station 46 at a slightly greater distance from said center shaft. 37 bottom surface 40. The two guide rails "52 then run at some distance" above "the bottom surface 40 during their remaining stretching to the end.

Both the outer guide rails 51 and the inner guide rails 52 preferably consist of metal pipes, through which a cooling medium e.g. water, can be circulated during operation of the machine. As previously mentioned, there are around the conveying means 3É 'a number of fixedly mounted processing stations, between which the packaging containers during processing and shaping are arranged to be moved intermittently by means of the fastening means of the conveying means. During the rotation of the conveying means 35, the movable jaws 39 of the fasteners are actuated by the engagement of the cam followers 43 with the cam curve 44 between open and closed position. In the open position, the movable jaw is in a slightly outwardly pivoted position relative to the fixed jaw, which allows a packaging container to be moved to or from respective fasteners. In the closed position, the working surfaces of the two jaws are substantially parallel and located at such a distance from each other that they without difficulty hold a packaging container placed in the fastener even when the fastener is upside down, i.e. at the present lower part of the transport member 35. In order to enable said actuation of the movable jaws 39, the cam curve 44 has a varying radius along its circumference. More specifically, the cam curve has a relatively small radius during substantially half a revolution, which thereafter increases to a maximum and then gradually reduced again to the previously mentioned small radius. The portion of the cam curve during which the radius gradually decreases from said maxima to the area of smaller radius is so located that the fasteners 37 will be in an intermediate position, i.e. be partially open when they are in the folding station 46. The term "partially open" is understood to mean that the fastener does indeed retain the packaging container between the jaws but still allows some movement or correction of the position of the packaging container in the fastener if the packaging container is subjected to external forces. The different parts of the cam curve are moreover positioned so that the fasteners during the intermittent rotation of the transport means are open while they are at the input and discharge stations and closed while they are at the binder and pressing stations.

Although partially open in which the fasteners 37 are located at the folding station 461, the packaging container located in the fastener is admittedly enclosed by the two jaws 38, 39, with which the packaging container does not hold or not, but the packaging container can be moved with some resistance under the influence of.

The feeding station 45 is located flush with the feeding unit 33, which is supported by the feeding unit 30 and by means of it is movable back and forth between the feeding stations of the two conveying means 35 to enable movement of packaging containers coming from the transport part 6 along a transverse between trahsport means 35 extending chute (not shown in the drawing).

At the feeding station there is also a stop 54 mounted on the side of the stand 53, which has the shape of a plate located in the middle of the feeding device 33 which serves to limit the movement of the packaging containers and ensure that they end up in the correct position in the open fastener. is such that the distance between the input device and said abutment 54.1 corresponds to the turning position of the input device. with the width of a packaging container, which ensures a correct placement and fixing of the packaging container between the jaws of the fastener. The folding station 46 comprises a fastening plate 55 arranged above the fastening station, and two top folding plates 56 arranged on either side of the fastener (Fig. 5). Both the bottom folding plate 55 and the top folding plates 56 are supported by a support arm 57 which is freely rotatably supported on The bottom fold plate 55 and the top fold plates 56 are synchronously displaceable between an upper position and a lower position by means of the cam curve 27 mounted on the upper shaft 26 which abuts and acts on a roller 59 rotatably mounted in the bottom folding plate 55, which by means of spring means (not shown) can be pressed against the surface of the cam curve 27.

The bottom folding plate 55 has a flat working surface facing the fastener, which, the upper, inactive position of the bottom folding plate is at some distance above the outer (upper) end of the fastener so as to be substantially level with the fastener under the influence of the cam curve 27 in its operative position. 37 outer edge, ie level with the upper end surfaces of the two slopes 38, 39. In other words, the bottom folding plate 55 is movable in the radial direction of the transport member from its rest position outside the two guide rails 51 and to its active position between the guide rails and the transport center of the member. The bottom folding plate 55 is in this case between two and ten millimeters narrower than the free distance between the guide rails 51 at the same level as the folding station. This dimension is adapted to the material thickness of the processed packaging container. The reciprocating movement of the bottom folding plate 55 caused by the cam curve 27 also gives both top folding plates 56 located on either side of the fastener a corresponding movement, since these middle intermediate arms 60 are connected to the support arm 57. The two the lower fold plates 56, i.e. the end edges facing the center axis of the transport member 35 are thus moved between a rest position at a distance above the bottom surface 40 of the fastener to an active position substantially at a level flush with said bottom surface. In this case, the top folding plates 56 are arranged to co-operate with the two inner guide rails 52 serving as abutments, which in the folding station are located on either side of the fastener and are located at some distance above the bottom surface 40. Between the feeding station 45 and the folding station 46 there is a guide plate 61 which is suspended in the support arm 57 and arranged to follow in its pivoting movement when the cam curve 27 moves the bottom folding plate 55 between its upper and lower position. The guide plate 61 is located slightly outside the fasteners: 37 outer ends and has a width which substantially corresponds to the width of the bottom folding plate 55.

In the embodiment of the machine according to the invention, the adhesive station 47 is provided with a hot air unit 62, which is fixedly mounted outside the path of movement of the transport member 35.

The hot air unit 62 is of a known type and produces hot air which is supplied via pipes and nozzles to the packaging containers placed in the binder station by the transport means. More specifically, the hot air is supplied via two bottom nozzles 63, which are located at some distance outside the outer boundary surface of the fastener 37 that they extend below the partially folded bottom flaps of a packaging container fixed in the fastener, and two on either side of the inner end of the fastener 64. , which extend between the side wall of the packaging container and the packaging container: partially folded top flaps. Both the bottom nozzles 63 and the top nozzles 64 are located outside the path of movement of the transport member 35 and thus do not prevent the transport member rotation.

In another embodiment of the machine according to the inventions, the hot air unit 62 and the hot air nozzles 63, 64 can be replaced by a so-called hot air unit, i.e. an assembly for supplying thermoplastic adhesive to the packaging container. The location of the hot-melt nozzles in this case mainly corresponds to the location of the nozzles 63, 64, since the hot-melt, like the hot air, must be applied between the corner flaps of the packaging container and the wall of the packaging container against which the corner flaps are later to be folded. Hot melt aggregates of this type are well known and are not described in more detail.

The folding station 48 comprises a folding assembly 65 (Figure 5, 6) which is designed for folding or closing the packaging containers so that they obtain the desired, parallelepipedic shape with folded and fixed corner flaps. The folding assembly for this purpose comprises two side pressure devices 66 and a bottom pressure device 67, which are arranged in their active position together with the two jaws 38, 39 of the fastener and the bottom 40 of the fastener form a near end, parallelepipedal space whose inner dimensions correspond to the desired measure.

The two side pressure members 66 comprise pressure plates 68 having opposite working surfaces which are completely planar apart from grooves 69 for the inner guide rails 52. Each of the pressure plates 68 is supported by a front lever arm 70 to which the pressure plate is pivotally connected by a connecting member 71. The connecting means 71 comprise rubber bushings and are flexible so that the pressure plate 68 tends to assume a position substantially parallel to the lever 70. However, against the action of the connecting means 71, each pressure plate 68 can pivot to a flat abutment against it due to the flexibility of the connecting member 71 at the contact with the side wall of the packaging container.

Each of the two front lever arms 70 is connected via a shaft 72 mounted in the machine frame to a rear lever arm 73, which is located inside the distribution gearbox 15.

The rear lever arms 73 are connected via a conventional system of links and a knee joint structure 74 to an operating rod 75 which carries at its front end the bottom pressure device 67. The bottom pressure device 67, which like the side pressure devices 66 has a plane facing the packaging container. working surface, is thus arranged synchronously with the side pressure means 66 being brought into abutment against the packaging container by means of one of the two operating arms 23 located in the distribution gearbox 15, which are driven via the operating curves 22 by the lower shaft 2 of the machine. To prevent the final folding assembly 65 or transport means .ex. movement is hindered by foreign objects, there is a safety coupling-76 built into the drive system between the control arm 23 and the actual final folding unit 65. The safety coupling 76 is of the known type which triggers automatically at a certain load and should not need to be described further. Both the safety coupling 76 and the rest of the drive mechanism for final folding unit 65 are, as shown in particular in Figure 5, located in a bearing housing 77 mounted on the distribution gearbox 15. Outside the bearing housing there are thus only the two side pressure members 66 and the bottom pressure member 67, which at 8101974-7 Operation of the machine are arranged to be moved between an open position or rest position, in which both side pressure means and bottom pressure means are located at such a distance from the transport means 35 that a fastener 37 can pass freely between them, and an active position in which the side pressure means and the bottom pressure means pressed against a packaging container existing in the final folding position, fixed by a fastener 37.

The next processing station for a packaging container moved by means of the transport means 35 is the spare station 49, which can be used for further desired processing of the packaging container, e.g. application of reinforcing strips or ribbons, date stamping or the like.

The output station 50 is located opposite the output device 34, which is arranged to be moved synchronously with the input device 33 by means of the arms 31 of the reciprocating feed assembly. The output device 34, like the input device 33, comprises pressure plates 78, which are arranged to move the packaging container out of the fastener 37, whose movable jaw 39 in the dispensing station has been moved to its outwardly pivoted position by means of the cam curve 44. When the feed assembly 30 pivots, the pressure plate 78 moves one packaging container at a time from the fastener 37 to a slide (not shown) located next to (outside) the fastener which is arranged to move the package to the previously mentioned conveyor 8, on which the packaging containers moved away from the machine according to the invention.

When a machine according to the invention is used together with a packaging machine to form substantially parallelepiped packaging containers for liquid filling goods, the machine is placed as shown in Figure 1, i.e. next to a packaging machine and connected to it via the power transmission and drive part 7. When the actual packaging machine is started, the machine according to the invention will also be started because it is driven by means of the drive unit of the packaging machine. The packaging containers or packaging blanks coming from the actual packaging machine, which are completely filled and closed, leave the packaging machine after being separated from the tube from which they are made and are allowed to fall down on the receiving conveyor belt 12, which due to its angle towards the horizontal plane, the packaging containers softly brake and transfer them to the main conveyor belt 10, on which they are advanced at short intervals towards the final folding part 5. As an individual packaging container approaches the end of the main conveyor belt 10, the feed conveyor is taken over by the conveyor belt. at substantially twice the speed of the main conveyor belt 10. The carrier 14 of the dispensing conveyor belt 13 will engage the individual packaging container and move it from the end of the main conveyor belt 10 to the transverse feed chute, along which the feeder 33 performs si n reciprocating motion. The discharge conveyor belt 13 is in this case so synchronized with the movement of the input device 33 that it is always in one of its turning positions when a packaging container is fed to the chute.

When moving the feeder 33 to its opposite end position, the fed packaging container is pushed via the gutter to one of the fasteners 37 located in the feeding station 35 of the two transport means 35, where the packaging container is heated in the correct position by the stop 54.

The fastener 37 is dimensioned so that the packaging container 2 placed in the fastener rests with its bottom surface against the bottom 40 of the fastener while its projecting top and bottom corner flaps 79 and 80, respectively (the packaging container is upside down: in Figure 7) rest against the two inner guide rails 52 and one of the outer guide rails 51. The movable jaw 39 is in its open position at some distance from the side wall of the packaging container, and the guide plate 61 is at a distance from the packaging container = projecting sealing fin 81. Immediately before the transport means 35 is indexed again, it appears in fig. 7 visible end of the guide plate 61 to be lowered against the sealing fin 81, since the bottom plate S5 is simultaneously returned to its rest position in the folding station.

When the guide plate 61 is moved in the direction of the sealing fin 81, the transport means 35 (clockwise in Fig. 2) is indexed so that the packaging container 2 is made to slide along the guide rails 51, 52 from the feeding station in the direction of the folding station 46.

Figure 8 illustrates the packaging container and fastener in an intermediate position between these two stations, i.e. during the movement of the packaging container to the right in the figure. Due to its abutment against the sealing fin 81, the guide plate 61 has folded it down in the direction of the bottom surface 82 of the packaging container. As previously mentioned, the packaging container is not fixed firmly in the fastener until it has passed the folding station, and in the position shown in Figure 8. the movable jaw 39 is still at a distance from the side wall of the packaging container, so that the packaging container can be moved freely in the fastener and is guided by the guide rails 51,52.

As these gradually increase their radius in the area between the feeding station and the folding station, the packaging container will be lifted by the engagement between the projecting corner flaps and the guide rails so that it is at a distance from the bottom 40 of the fastener 37. At the same time the sealing fins 81 are folded backwards. direction of movement, through the contact with the guide plate 61 and the two inner guide rails 52, respectively.

When the indexing movement of the transport means 35 ceases, the packaging container is in the folding station 46. In this station the movable jaw 39 has partly come into abutment against the side of the packaging container 2, but the packaging container is not completely fixed but can still be moved in the fastener 37 (Fig. 9 ). Through the engagement between the guide rails and the corner flaps of the packaging container, the packaging container is in an upper or outer position in which its bottom surface 82 is located immediately below the working surface of the bottom folding plate 55 facing the packaging container at rest. The upper shaft 26 is now caused by the indexing gear 17 to rotate one revolution, the cam curves 27 moving both the bottom folding plate 55 and the top folding plates 56 in the direction of the center axis of the transport member 35 and back again. This movement moves the packaging container downwards until its bottom surface abuts the bottom 40 of the fastener 37 and the packaging container is again in the position in which it was placed in the fastener during feeding. Since the guide rails 51, 52 at the folding station are at a greater distance from the center axis of the transport means 35 than they did at the feeding station 45, the corner flaps 79, 80 of the packaging container will be folded upwards during this movement, i.e. in the direction away from the center axis of the conveyor. The top flaps 79, which are located at the bottom surface 40 of the fastener, are folded around the outer ends of the top folding plates 56 so that they assume an angle of substantially 450 towards the side surface of the packaging container. The two bottom corner flaps 80 are folded more strongly and extend after completion of movement mainly straight up, i.e. at 900 angles to the bottom surface 82 of the packaging container. The folding of the two bottom flaps 80 must take place while simultaneously compressing the material layers in the corner flaps, as these will later be folded down towards and fixed to the bottom surface 82 of the packaging container, over which the sealing fin 81 runs. The large number of layers of material which must be folded and compressed before the corner flaps are properly secured to the bottom surface 82 makes it necessary to compress them in this folding of the corner flaps and especially the overlying parts of the sealing fin 81 between the sides of the bottom fold plate 55 and the two outer guide rails 51. This can be done by ensuring that the clearance on either side of the bottom pressure plate is as small as possible with regard to the thickness of the material, and preferably amounts to a value corresponding to the theoretical material thickness in the corner flaps (usually between 1 and 5 mm). After both the bottom folding plate 55 and the top folding plates 56 have returned to their outer rest position, the transport means 35 is indexed once more (1/6 turn clockwise), which moves the packaging container from the folding station to the binder station 47. During this movement, the fastener 37 is moved to a position parallel to the fixed jaw 38 so that the packaging container is firmly held in the fastener. Since the distance between the two outer guide rails 51 is slightly reduced in the area between the folding station and the binder station, the two bottom flaps 80 will be folded slightly further towards each other, so that when the packaging container reaches the binder station 47, they have an angle of about 45 ° to bottom surface 82.

When the fastener 37 remains in the binder station, the packaging container 2 is in such a position that the bottom nozzles 63 of the hot air unit are in the space between the partially folded bottom corner flaps 80 and the bottom surface 82 of the packaging container 82 (Fig. 10). At the same time, the top nozzles 64 of the hot air unit 62 are located on either side of the upper end of the packaging container, facing the bottom 40 of the fastener and more specifically between the partially folded top corner flaps 79 and the free side surfaces of the packaging container. By means of the outflow holes directed by the nozzles 63, 64 towards both the corner flaps and the packaging container walls, hot air is now blown towards the surface of the packaging container material in the areas below the corner flaps which are to be used for fixing the corner flaps to the underlying packaging container wall. As a result, the thermoplastic layer on the packaging container is heated to such an extent that it softens and can serve as an adhesive when fixing the corner flaps. After heating to the softening temperature of the thermoplastic material, the packaging container is moved by means of the transport means 35 until it is in the final folding station 48. During this movement the relative position of the guide rails 51, 52 changes further so that the corner flaps when the packaging container has an angular position. which is less than 45 °. This prevents unnecessary cooling of the heated surfaces during the movement of the packaging container to the final folding station.

During the movement of the packaging container to the final folding station 48, the side presses 66 and the bottom presses 67 of the final folding assembly 65 are spaced from the path of movement of the fastener so as not to interfere with the protruding corner tabs 79, 80 of the packaging container. successively to abut against the side walls and bottom of the packaging container, respectively.

The pressure plates 68 of the side pressure devices 66 are as long as they are not affected by external forces so oriented in relation to the levers 70 that they are first brought into abutment against the side walls of the packaging container at their ends against the bottom of the packaging container, after which they are successively pivoted to the active position. are pivoted around the connecting member 71 until they become mutually parallel and abut against the free side walls of the packaging containers. By lowering the pressure plates 68 in the rest position, the stroke of the levers can be minimized, since the ends of the pressure plates located at the top flaps in the rest position have a relatively greater distance to the packaging container so that the corner flaps 79 can easily fit. The relative pressure plates 68 and bottom pressure members 67 position is illustrated in Figure 11, where the position of the printing plates 68 at the moment they first touch the side surface of the packaging container is illustrated by dotted lines.This flexible suspension of the printing plates 68 will automatically set themselves in the correct position relative to the package. When both lateral pressures and bottom presses are brought into the correct position, they together with the jaws and bottom of the fastener form a substantially closed, parallelepipedal space whose free inner dimension corresponds to the free-flowing side of the container and the deformation of the packaging container. the finished packaging desired dimensions of the container. The packaging container may remain in this position until the thermoplastic layers have solidified again and the seal has been completed.

The packaging container is then moved by re-rotating the transport member 35 l / 6 revolutions to the spare station 49 which is unused in this embodiment, such as e.g. can be used for applying reinforcing cardboard sheets to one or more of the free surfaces of the packaging container (Figure 12). Re-rotation of the conveying means 35 brings the fastener 37 with the relevant packaging container to the dispensing station 50. During the rotation from the spare station 49, the cam follower 43 of the movable jaw 39 successively extends into the portion of the cam curve 44 where the radius is largest, i.e. where the fastener opens. However, the packaging container is nevertheless retained in its position in the fastener by means of above all the two outer guide rails 51 against which the bottom of the packaging container slides during the movement to the dispensing station.

In the dispensing station (Figure 13), the pressure plates 78 of the reciprocating dispenser 34 are moved in between the two jaws 38, 39 of the fastener and slide the detached packaging container laterally out of the fastener 37 to the sliding surface (not shown) arranged outside: the conveyor means 35. along which the packaging container slides down on the conveyor 8. Preformed packaging containers are in this way discharged alternately from the two transport means 35 of the final folding part 5 and transferred to the conveyor for removal. An alternative embodiment of the machine according to the invention can be provided with a unit for application of adhesive instead of the hot air unit 62 shown in the figure. This variant is useful even if the machine according to the invention is used for final forming of packaging containers which are made of a material which is not covered with an outer thermoplastic layer. The corner flaps are fixed to the side walls of the packaging container in such cases with the help of thermoplastic glue which is applied under the corner flaps before they are pressed against the walls of the packaging container.

The design of the machine according to the invention with a rotating conveying means which moves the packaging containers between the different processing stations by indexing movement guarantees a safe movement of the packaging containers between carefully fixed positions at each processing station, which completely eliminates the risk of deformation of the packaging containers. placement of these in relation to the machining tools. Furthermore, since all the cooperating, moving members of the machine, i.e. the transport means, the various processing stations, the feed unit, etc. are driven from a common power source and are mechanically connected to each other via the drive arrangement, the synchronization between the various movements during normal operation cannot be lost. In this way, the machine can also operate at high speed without the risk of incorrect processing, which ensures a high production capacity which is further increased by the use of double transport means which alternately process incoming packaging containers. A machine for processing necking containers (2) comprising a transport means (35) in the form of an intermittently rotatable drum (36) with actuable jaws (38, 39) for moving as fasteners (37). packaging containers (2) between different processing stations (45-50) arranged around the transport member (35), which fasteners (37) are operated during the rotation (36) of the drum (36) between open and closed positions, characterized in that the packaging containers actuating means (51, 52) are arranged to move during a part of the rotation of the transport means (35) a packaging container (2) located in a fastener (37) radially relative to the center of the drum (36). 2. A machine according to claim 1, characterized in that said means (51, 52) consist of guide rails, which run along the path of movement of the fasteners (37) at varying distances from the center of the drum (36). A machine according to any one of the preceding claims, which machine, in addition to feeding and dispensing stations (45, 50) for the packaging containers (2), also comprises sequentially located processing stations (46, 47, 48) for folding corner flaps (79) associated with the packaging containers. , 80), for application or activation of adhesive and for final folding of the corner flaps abutting against the walls of the packaging container, characterized in that the fasteners (37) are in the open position while they are at the in- and the discharge stations (45, 50), in the closed position while at the binder and final folding stations (47, 48) and in a partially open position at the folding station (46). 4. A machine according to any one of the preceding claims, characterized in that two outer guide rails (51) extend substantially W substantially from the feeding station (45) and past the folding station (46), the distance between the guide rails (51 ) and the bottom surfaces (40) of the fasteners (37) are successively increased, seen in the direction of movement of the fastener, from a distance less than the height of the fastener to a distance equal to the height of the bending station (46) greater than the height of the fastener. Machine according to any one of claims 3 to 4, characterized in that the folding station (46) comprises a bottom folding plate (55) which is movable in the radial direction of the transport member (35) from a rest position outside the outer guide rails (51) to an active position between the guide rails ( 51) and the center of the transport means (35). i 8101974-7 23 6 '6. A machine according to claim 5, characterized in that the free distance between the sides of the bottom folding plate (55) and the guide rails (51) mainly corresponds to the theoretical material thickness of the corner flaps (79, 80). 2 7. A machine according to any one of claims B-6, characterized in that the folding station (46) comprises two internal guide rails (52) serving as abutments, which are arranged on either side of the fastener (37) and at some distance above its bottom surface ( 40) when the fastener is at the bending station. A machine according to claim 7, characterized in that the inner and outer guide rails (52, 51) are arranged to cooperate with and fold in the top and bottom flaps (79, 80) of a packaging container (2) then the packaging container of the bottom folding plate ( 55) moved from an upper position to a lower position. 9. A machine according to any one of claims 3-8, characterized in that the final folding station (48) comprises two cooperating side pressure devices (66) and a bottom pressure device (67), which are driven by a common drive source. 10. A machine according to claim 9, characterized in that the side pressure devices (66) are arranged to be moved to an active position in abutment against opposite side surfaces of a packaging container (2) by means of double-arm levers (70, 73), which are via intermediate links connected to an axially movable control rod (75) for the bottom pressure device (67). ll. A machine according to any one of claims 9 or 10, characterized in that the side pressure means (66) comprise pressure plates (68) which are supported by the connecting rod arms (70) via flexible connecting means (71). A machine according to claim 11, characterized in that the pressure plates (68) are so oriented relative to the lever arms (70) that when pivoting the lever arms from passive to active position they are first brought into contact with their anti-packaging conditions. facing bottom ends (82) of the holders. l3. Machine according to claim 12, characterized in that the pressure plates (68), when the lever arms (70) are continued to pivot to the active position, are arranged to pivot against the action of the flexible connecting means (71) until they become mutually parallel and abuts against the free side walls of the packaging containers (2).

Claims (1)

A machine according to any one of the preceding claims, characterized in that each fastener (37) jaws (38, 39) and the bottom (40) together with the side and 48s of the final folding station (48) bottom pressers (66, 67) in their active position enclose a parallelepipedic space, the size and shape of which correspond to the size and shape of the finished packaging container (2). A machine according to any one of the preceding claims, characterized in that it comprises axially arranged transport means (35), which are located at some distance from each other. A machine according to claim 15, characterized in that the two conveying means (35) have a reciprocating feed assembly (30) between them, which is arranged to be fed from a feed channel extending from one of the feeding stations (45) by means of a feeders (33) alternately move packaging containers (2) to the fasteners (37) of the two transport means (35) when they are located at the feeding stations (45). A machine according to claim 16, characterized in that said feeding assembly (30) comprises a dispensing device (34) for alternately dispensing finished packaging containers (2) from the fasteners (35) present in the dispensing stations (50). 37). 18. A machine according to claim 16 or 17, characterized in that the feed assembly (30) comprises two pivotable arms (31) in which both the input device (33) and the output device (34) are suspended in parallelogram. A machine according to any one of the preceding claims, characterized in that the transport means (35), the bottom folding plate (55), the side and bottom pressure devices (66, 67) and the feed assembly (30) are mechanically interconnected and driven via a common power source. A machine according to claim 1g, characterized in that the transport means (35) are supported by a common shaft (25), which is driven via an indexing gear (16) by said common power source. 81O197IP?