The invention relates to a rotary application head for application of liquid adhesives, especially hot melt adhesives, on strip material which is running past, and a labelling installation for applying labels to cylindrical bodies, such as bottles.
Rotary application heads for known bottle labelling installations have a rotating roller having adhesive placed two-dimensionally on certain application areas in the interior of the housing. The application areas of the rotating roller having the adhesive are then brought in contact with passing label material. In this case, the rotating roller emerges from the housing in the area of an application gap so that contact with the label material takes place immediately. Rotary application heads of this type tend to take up dirt via the adhesive covered application areas and draw it into the rotary application head.
Accordingly, it is one object of the present invention to prepare an improved rotary application head suitable for the application of adhesive to passing label material. Liquid adhesive is applied to labelling strip materials or individual labels depending on whether the printed labelling strip material is separated into single labels before passing the rotary application head or after passing the rotary application head.
The rotary application head described herein has the advantage of absolute synchronisation between the adhesive medium and the label material that is running past. Accordingly, no smearing of the adhesive with respect to the label material is possible.
In addition, a flat contact between the label material and the adhesive medium to be applied is avoided. Rather, the adhesive medium is transferred by means of a mask cylinder in a grid fashion. The adhesive medium can then flow together outside the mask cylinder through shallow recesses proximate to outlet openings on the outside of the mask cylinder. Thus, the surface areas of the label material can also be covered with adhesive.
A rotary application head that includes a rotating hollow cylinder in the fashion of a mask cylinder is known from DE 198 54 634 C1. However, the mask cylinder described in DE 198 54 634 C1 fails to emerge from the housing. The mask cylinder in DE 198 54 34 634 C1 rotates around its own axis and never emerges from the housing. Furthermore, in DE 198 54 634 C1, a compressed-air slit is associated with a slit in the housing. The slit is in the interior of the hollow cylinder or mask cylinder in the vertical cylinder. The compressed air blows out adhesive medium inserted previously into openings in the hollow cylinder or mask cylinder. Unlike the present application having a rotary application head transferring adhesive medium via contact with the strip material, the rotary application head described in DE 198 54 634 C1 is only suitable for non-contact application to passing strip material.
A rotary application head for application of liquid adhesives, especially hot melt adhesives, on passing strip material. The strip material can be labels in one embodiment. The labels provided with the adhesive can be applied to any type of product. One excellent area of application is applying the labels to cylindrical bodies, such as cans or bottles. The labels can consist of paper or other non-self-adhesive film-like material.
Another aspect of the invention relates to a labelling installation for applying labels to cylindrical bodies, such as bottles. The labelling installations include an unrolling device for label strip material. The installations also include a rotating drivable vacuum drum for supplying label strip material or individual labels and a cutting device for separating individual labels from label strip material. The labelling installations also include a rotating application head for liquid adhesive, such as hot melt adhesive, that cooperates with the vacuum drum. The labelling installations also include a carousel for passing the cylindrical body past the vacuum drum the carousel having rotating means for the cylindrical bodies that bring about a rolling of the cylindrical bodies on the vacuum drum. The labelling installations further include means for charging and discharging the cylindrical bodies onto and from the carousel. The axes of the vacuum drum, rotary application head and carousel are arranged parallel to one another.
Another form of the invention includes a rotary application head for application of liquid adhesive, such as hot melt adhesive, to a strip material which is running past, such as label strip material or individual labels. The rotary application head includes a housing with a cylindrical chamber that passes through the housing in an axially parallel application gap. Arranged coaxially in the cylindrical chamber is a vertical feed cylinder forming a cylindrical annular space in combination with the cylindrical chamber. The cylindrical annular space is interrupted by the application gap and includes at least one feed channel system running parallel to the application gap. Arranged rotatably drivably in the cylindrical annular space is a mask cylinder. The mask cylinder has outlet openings that expose in a controlled fashion the feed channel system in the feed cylinder. The feed channel system in the feed cylinder is exposed through the outlet openings during rotation towards the application gap.
In one preferred embodiment, at least one feed channel system in the feed cylinder consists of at least one axially parallel or coaxial central channel and at least one axially parallel row of radial feed holes which lead from the central channel to the surface of the feed cylinder.
In another preferred embodiment, the feed cylinder is rotatably adjustable and comprises a plurality of feed systems comprising rows of feed holes. The feed systems can be adjusted to the circumferential position of the application gap if desired. Thus, the length of the rows of feed holes of the individual feed systems can differ amongst one another. Other configurations of the sizes and shapes of the feed holes could be used in other embodiments. In one embodiment, varying the application pattern on the label material, including adapting the application of adhesive to labels of different width by adjusting the feed cylinder, can be achieved without dismantling the rotary application head. In this embodiment, the feed cylinder is preferably provided with a number of feed systems distributed uniformly over the circumference. A servomotor can make adjustments by the respective angular pitch between the feed systems, for example, controlled by means of a belt drive.
Another embodiment comprises elastically supported closure strips provided in the feed cylinder on both sides of a row of feed holes. This prevents adhesive medium emerging from the feed systems inside the mask cylinder from flowing off to the sides. Accordingly, the supplied adhesive medium is only used to expel and replace adhesive medium that is already stored in the individual outlet openings.
According to a further aspect, it is proposed that provided in the housing and/or in the feed cylinder are wiper devices running parallel to the application gap. The wiper devices act on the rotating mask cylinder before the outlet into the application gap. The effect of these wiper devices is that the mask cylinder enters into the application gap free from adhesive, particularly on the outer side, thereby reducing the uptake of dirt because the adhesive medium contained in the openings immediately reaches the label material.
Another embodiment includes a central channel connected to an exterior annular groove via a plurality of radial holes and the annular groove is connected to a housing hole that is supplied with liquid adhesive. The mask cylinder can then be shaped depending on whether the labels are to be glued (provided with adhesive) transverse to their rolling-up direction, longitudinally to their rolling-up direction, or linearly along their circumferential edges. In addition, a plurality of outlet openings, distributed non-uniformly over the circumference is constructed on the mask cylinder. In particular two axially parallel rows of outlet openings are used. Alternatively, at least two rings of outlet openings extend over the circumference of the mask cylinder or lines of outlet openings that form a closed curve when unwound are provided in the mask cylinder.
Another aspect of the invention is a labelling installation for applying labels to cylindrical bodies, such as bottles. The labelling installation includes an unrolling device for label strip material, a rotating drivable vacuum drum for supplying label strip material or individual labels, a cutting device for separating individual labels from label strip material, and a rotating application head for liquid adhesive, such as hot melt adhesive. The rotating application head cooperates with the vacuum drum. The labelling installation also includes a carousel for passing the cylindrical body past the vacuum drum with rotating means for the cylindrical bodies. The rotating means bring about a rolling of said bodies on the vacuum drum. The labelling installation also includes a means for charging and discharging the cylindrical bodies onto and from the carousel. The axes of the vacuum drum, rotary application head and carousel are arranged parallel to one another. The rotary application head comprises a housing with a cylindrical chamber that passes through the housing in an axially parallel application gap. In addition, arranged coaxially in the cylindrical chamber is a vertical feed cylinder having a cylindrical chamber forming a cylindrical annular space interrupted by the application gap. The vertical feed cylinder includes at least one feed channel system running parallel to the application gap. Moreover, arranged rotatably drivably in the cylindrical annular space is a mask cylinder with outlet openings which exposes in a controlled fashion the feed channel system in the feed cylinder by means of the outlet openings towards the application gap during rotation. Also, the rotary drives of the vacuum drum and the mask cylinder are mechanically coupled, such as via gearing. In addition, the drives of the vacuum drum and the carousel can be mechanically coupled using rotational means, such as gearing.
Preferred exemplary embodiments of the invention are shown in the drawings and are described hereinafter.
FIGS. 1A-D are subsequently described. A bottle labelling plant 11 according to the invention includes as substantial components an unrolling device 12 for label strip material L and a strip travel regulating arrangement 14 which can regulate the height position of the strip material L. The unrolling device 12 is supported by a roll retaining arm 13. The strip travel regulating arrangement 14 comprises individual deflecting rollers 15. The bottle labelling plant 11 further comprises a vacuum drum 16 on which individual axially parallel cutting edges 17, distributed on the circumference, can be seen. The vacuum drum 16 also has underpressure openings not shown in detail on its circumferential surface, which hold the strip material L or individual labels firmly on the vacuum drum 16. A cutting device 18 with a movable cutting blade 19 cooperates with the cutting edges 17 of the vacuum drum 16. By means of this cutting device 18 individual labels are separated from the strip material L and specifically in the position of the cutting edges 17 in each case.
Also shown in cooperation with the vacuum drum 16 is a rotary application head 21 which will be explained in detail later. Finally, associated with the vacuum drum 16 is a bottle carousel 22 on which are arranged individual rotationally drivable bottle carriers 23 on which cylindrical bottles B stand. The rotary movement of the bottle carousel 22 and the individual bottle carriers 23 is synchronised with respect to the vacuum drum 16 so that a rolling movement takes place between the individual bottles B and the vacuum drum 16 so that the individual labels L provided with adhesive on the rotary application head 21 can lie on the bottles B free from tensile force and adhere fixedly thereto. The vacuum drum 16 rotates clockwise and the bottle carousel 22 and the bottle carriers 23 therefore each tend to rotate counter-clockwise. A servomotor 28 connected to the rotary application head 21 via a belt drive 24 can be used in some embodiments.
In
Reference is made to the preceding description. A toothed gearing 20 is composed in detail of a gear wheel 50 connected to the vacuum cylinder 16, two intermediate wheels 51, 52 and a gear wheel 53 connected to the mask cylinder 27. Accordingly, the vacuum drum 16 and the mask cylinder 27 rotate relative to each other and therefore pass the label material L therebetween to apply liquid adhesive from the mask cylinder 27 onto each label L. Positioned on the housing 26 of the rotary application head 21 is an inlet 29 for liquid adhesive.
In
Located in an annular cylindrical space formed by the cylindrical chamber 30 with the feed cylinder 25 is the mask cylinder 27. The vacuum cylinder 16 rolls with the same circumferential speed in a clockwise fashion compared with the counterclockwise mask cylinder 27. The label material L rests on the vacuum cylinder 16 and liquid adhesive reaches the label material L via outlet openings 35 in the mask cylinder 27. Since the vacuum drum 16 and mask cylinder 27 travel past one another at the same speed, a precise rectangular application of adhesive is made onto the label material L which does not smear on the outside of the mask cylinder 27.
FIGS. 5A-C are subsequently described. The rotary application head 21 is shown here for the first time, viewed onto the outlet gap 36 in the housing 26. The outlet openings 35 in the mask cylinder 27 can be distributed over the circumference or can form a row extending in the axial direction. The cross-section illustrates, only one of the six feed channel systems 32 of the fundamentally vertical feed cylinder 25, distributed over the circumference. The feed channel system 32 is active, i.e. liquid adhesive only flows out of the feed system and is downwardly directed in the cross-section whereas the other systems shown are inactive. The servomotor 28 has a belt drive 24 that drives the feed cylinder 25 enabling adjustment between the individual feed systems which can be constructed differently.
Therefore, depending on the design of the perforation pattern in the mask cylinder 27, an efficient outflow of adhesive only takes place over the axial length of the selected feed system 32. The six feed systems 32 distributed over the circumference, which have already been identified, differ from one another in respect of the longitudinal extension of the row of holes 37 in the axial direction. Therefore, by adjusting the feed cylinders by means of the servomotor 28 without exchanging the mask cylinder 27, different adhesive application patterns can be produced which differ in particular in the axial longitudinal extension or in the active height. Changing the active feed system 32 changes the width of the label material. The servomotor 28 acts directly on a lower axle 38 of the feed cylinder via the belt drive 24. This belt drive 24 comprises a pulley 48 mounted on a shaft pin 47 of the servomotor 28 and a spline 49 mounted on the axle 38 of the feed cylinder 25. The central channel 31, which passes through the entire feed cylinder 25, is closed at the bottom by a locking screw 39. An upper cover 40 against which the feed cylinder 25 and the mask cylinder 27 directly abut delimits the housing 26. The mask cylinder 27 has a cylindrical collar 41 at the lower end on which the gear wheel 53 is pressed for speed coupling with the vacuum cylinder 16. At the bottom the housing is closed by a second cover 42.
FIGS. 7A-B are subsequently described. On the rotary application head 21 it is possible to see the inlet 29 screwed into the cover 42, which is in communication with a radial hole 44 in the cover 42. At the axle 38 of the feed cylinder 25 there is formed a circumferential groove 45 which is associated with the hole 44 for supplying liquid adhesive from the connecting piece.
From the circumferential groove 44 the adhesive passes via a plurality of circumferentially distributed radial holes 46 into the central channel 31. The locking screw 39 in the central channel 31 also helps to keep the mask cylinder 25 together.
FIGS. 8A-C are subsequently described. The rotary application head 21 is shown in cross-section, and reference should be made to the cooperation between the feed cylinder 25, especially the active feed system 32 and the mask cylinder 27 which is driven in a counter-clockwise fashion and shown in three different positions from left to right. In
FIGS. 9A-C are subsequently described. The rotary application head 21 is shown in plan view and in an axial longitudinal section. Therefore, details can be seen in the longitudinal section that approximately corresponds to the details in
The adhesive application pattern can be seen as unwinding the mask cylinder 27 which in this case must have rows of perforations extending over the entire circumference or groups of rows of perforations.
Number | Date | Country | Kind |
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102004058542.3 | Dec 2004 | DE | national |