The present invention relates to a labelling machine for applying label sheets onto articles.
As it is generally known, the packaging of food or non-food products into respective articles, such as containers, bottles, receptacles and the like, comes along with a labelling of the articles by means of respective label sheets, in particular paper or plastic label sheets, during a labelling process run with a labelling machine.
In one common kind of labelling machine, the articles are driven by a conveying carrousel along a predetermined path, or track, which guides the articles towards an application station, at which each label sheet is put onto the respective article.
Thus, such labelling machines are used to transport, prepare and apply label sheets to containers, bottles, or articles of all sort.
Typically used with beverage bottles or vessels are tubular label sheets (commonly called “sleeve labels”), which are obtained by:
Also widespread used are gluing label sheets, which, after being cut from a web at an appropriate length, are glued by gluing means, such as a gluing roller, spray and injector system or the like, and are finally transferred to respective containers or articles.
In both cases, the label sheets are retained on a vacuum drum by suction.
In particular, a conventional vacuum drum presents an outer lateral surface having an approximately cylindrical lobed configuration; the vacuum drum normally receives, on its outer lateral surface a succession of label sheets at an input station and, after a given rotation about its axis, transfers the label sheets to the labelling machine at the application station so that they can be applied to respective articles or containers.
More specifically, the outer lateral surface of the vacuum drum comprises two or more sections, which are equally spaced angularly from each other around the vacuum drum axis, are provided with a series of ports and are adapted to cooperate in use with respective label sheets.
Each section is delimited, at the opposite angular ends, by respective damping pads, which are carried on the periphery of the vacuum drum at angularly spaced regions thereof, slightly protrude from the outer lateral surface and have the function to engage in use with the leading and the trailing end portions of the label sheets to be transferred, respectively. To this purpose, the pads are provided with a plurality of ports.
In practice, the pads define the zones of the periphery of the vacuum drum where the label sheet transfers occur.
The distance between each pad and the relative upstream pad is thus equal to the length of the label sheet to be processed.
The vacuum drum retains the label sheets, already pre-cut by a rotating knife, using suction through its ports; this suction determines a negative pressure on the label sheets, which are thus retained on the outer lateral surface of the vacuum drum. Then, in the case of gluing label sheets, each label sheet is soaked with glue by means of a gluing roller; once arrived at the application station, the label sheet is released from the vacuum drum by applying a positive pressure through the ports concerned and then stuck onto the article to be labelled.
Typically, the web is wounded on a storing reel and is brought from the reel to the vacuum drum by means of a plurality of rollers and other support units for tensioning and supporting the web when being advanced. This results in a complex system with many components which could, in certain cases, lower the overall reliability of the machine.
The vacuum drum is usually fabricated from a monolithic aluminum casting and it tends to have a structure of high complexity. The drum happens also to be very heavy to handle during fabrication.
Another drawback of this solution is seen in managing the replacement of reels, in particular the splicing of the webs of labelling material when a reel is exhausted, a process which requires an high level of complexity to be automatized.
A further drawback is seen in switching to a different product to be labelled: in this case, the web of labelling material has to be changed, and, thus, the vacuum drum has to be replaced by a new one, suitable for the new product and the new web characteristics.
An even further drawback is seen in the need of an operator passing the web around all the rollers during the splicing of the web itself prior to the activation of the labelling machine. Such a process is prone to errors with respect to the actual path of the web. Moreover, both the overall time and costs needed increase.
It is an object of the present invention to provide a labelling machine for applying label sheets onto articles, which allows to overcome at least one of the above-mentioned drawbacks in a straightforward and low-cost manner.
This object is achieved by a labelling machine as claimed in claim 1.
A non-limiting embodiment of the present invention will be described by way of example with reference to the accompanying drawings, in which:
With reference to
In particular, labelling machine 1 is adapted to apply the label sheets 2 onto respective articles 3 as the latter ones are advanced in known manner along a path P by a conveyor, preferably a carousel conveyor 4.
In the example shown, carousel conveyor 4 is mounted to rotate continuously (clockwise in
Labelling machine 1 basically comprises:
Label transfer device 7 is arranged on one side of carousel conveyor 4 and is adjacent to the latter at application station 9, so that label sheets 2 can be transferred from the label transfer device 7 itself to each one of the articles 3 advancing on the carousel conveyor 4.
Web feeding unit 5 is arranged on the opposite side of label transfer device 7 with respect to carousel conveyor 4 and is adjacent to the label transfer device 7 itself at input station 8.
With reference to
In the example shown, web 6 is formed by a series of label sheets 2 joined to each other, which have rectangular or square shapes and are obtained by cutting the web 6 itself, initially wound on one respective reel 11, by means of cutting device 10.
Web feeding unit 5 further comprises, for each reel 11, a respective feeding actuator 12 coupled in a releasable way to a leading portion 13 of the respective web 6 and which is selectively operated to move towards and away from the label transfer device 7 so as to feed the web 6 to the label transfer device 7 itself.
In the specific embodiment shown in
In practice, feeding actuators 12 are selectively operated to transfer webs 6, unwound from the respective reels 11, to input station 8 of label transfer device 7.
Each piston 15 has, at its free axial end 16, a plate 17 equipped with a plurality of ports (not shown), selectively supplied with vacuum, for retaining the leading portion 13 of the respective web 6 of labelling material during its transfer from the respective reel 11 to input station 8 of label transfer device 7.
During transfer of one web 6 to label transfer device 7, release of leading portion 13 of the web 6 itself is achieved by simply interrupting the connection of the ports of the respective plate 17 to vacuum.
With reference to
According to an important aspect of the present invention, conveyor 18 is of linear-motor type and comprises a closed-loop transfer track 19, and a plurality of label holders or carts 20 movable along track 19 by means of a magnetic-inductive interaction and apt to cooperate with the web 6 and the label sheets 2 to transfer them from input station 8 to application station 9.
In particular, carts 20 are independently controlled and moved along track 19; as illustrated in
Preferably, track 19 has a substantially triangular shape and comprises three rectilinear branches 21, 22, 23 connected with each other by three curved vertex portions 24, 25, 26.
In particular, application station 9 is arranged in correspondence of vertex 24 of track 19 and is substantially tangent to carousel conveyor 4; input station 8 is arranged in correspondence of branch 21, which is opposite to vertex 24 and is also orthogonal to axes D; cutting device 10 is arranged facing branch 22, this latter being arranged downstream of input station 8 and upstream of application station 9 following path R. In other words, branch 22 is comprised between vertices 24 and 25, branch 23 is comprised between vertices 24 and 26 and branch 21 is comprised between vertices 25 and 26.
In the preferred embodiment shown in the enclosed figures, track 19 houses a stator armature formed by a plurality of individually-excitable solenoids 27 (known per se and only schematically shown in
According to a possible alternative not shown, track 19 may be also provided with the permanent magnets and carts 20 may house the individually-excitable solenoids.
In this preferred embodiment, carts 20 have prismatic shapes and present, on their front faces 30, respective ports 31 which can be alternatively used to produce suction or a positive pressure on the respective web 6 or label sheet 2.
As shown in
With particular reference to
Label transfer device 7 also comprises a second annular rotating tank 35, connected in a known manner to a compressor (not shown), and a second rotating distributor 36, connected on one side to the tank 35 and the compressor and on another side to each cart 20 by a respective pipe 37.
Tanks 32, 35 and distributors 33, 36 are all mounted to rotate about a common vertical axis E parallel to axes A, B and C. In addition, tanks 32, 35 and distributors 33, 36 are arranged substantially in the central area delimited by track 19 and are stacked up on each other.
As visible in
As visible in
Labelling machine 1 further comprises a printing device 42 (known per se and only schematically shown) for printing given patterns or bar codes on label sheets 2, and a gluing device 43 (known per se and only schematically shown), e.g. a glue sprayer, for applying glue to label sheets 2.
In this particular preferred embodiment, printing device 42, cutting device 10, and gluing device 43 are all placed in front of branch 22 of track 19 and are arranged in series with respect to the direction of motion of carts 20 along path R; in practice, cutting device 10 is placed between the printing device 42 and gluing device 43, the printing device 42 being placed upstream of the others.
Labelling machine 1 advantageously also comprises a closed-loop service conveyor 45 arranged laterally with respect to conveyor 18 in front of branch 23 of track 19 and adapted to selectively receive carts 20 from label transfer device 7 for cleaning and/or maintenance thereof or adapted to selectively replace carts 20 with others of different type in case of switching of label format.
In particular, service conveyor 45 is of linear-motor type and comprises a closed-loop service track 46, equipped with a plurality of individually-excitable solenoids (identical to solenoids 27 and not shown).
Tracks 19 and 46 have branch 23 in common, along which carts 20 can be exchanged between the tracks 19, 46 themselves when production is stopped.
In particular (
The operation of labelling machine 1 is described hereafter starting from the condition of
In particular, in this condition, piston 15 of the feeding actuator 12 carrying the web 6 to be fed to label transfer device 7 is set in an advanced position along its axis D, in which its respective plate 17 brings the leading portion 13 of the web 6 itself into contact with one selected cart 20 of conveyor 18; pistons 15 of the other feeding actuators 12 are coupled to respective leading portions 13 of the other webs 6 and are all maintained in retracted positions along their axes D, in which their plates 17 are spaced and detached from path R followed by carts 20. As leading portion 13 of the selected web 6 contacts the selected cart 20, connection of the ports of the respective plate 17 to vacuum is cut, whilst connection of the cart 20 itself to the vacuum source is activated by opening the valve 38 on the respective pipe 34.
In this way, leading portion 13 of the selected web 6 is dragged by the above-identified cart 20 along track 19 and path R; the web 6 of labelling material is, thus, continuously unwound from the respective reel 11 and advanced towards application station 9.
Each label sheet 2 forming the web 6 in use progressively adheres at its leading and trailing portions 2a, 2b to respective carts 20, which retain the label sheet 2 itself by means of suction acting through the respective ports 31.
By proceeding along path R, web 6 is first printed at each label sheet 2 with given patterns and/or bar codes by printing device 42.
Then, the web 6 is cut into single label sheets 2 by reciprocal movement of knife 41 of cutting device 10 along axis F.
At this point, label sheets 2 are sprinkled with glue by gluing device 43. Each label sheet 2 is subsequently released from the respective pair of carts 20 at application station 9 by progressively cutting vacuum and activating positive pressure on the label sheet 2 itself.
In particular, by controlling the respective valves 38, 39 vacuum is progressively cut on each cart 20 and positive pressure is progressively activated to enable transfer of the respective label sheet 2 on the corresponding article 3 simultaneously advancing along carousel conveyor 4 and rotating on its axis A in known manner.
Carts 20, which have already released the respective label sheets 2, can conveniently be controlled to move along track 19 faster than the ones still holding label sheets 2, until reaching again input station 8.
Carts 20 that need to be replaced, cleaned or subjected to maintenance are conveniently and selectively directed to service conveyor 45 through common branch 23, by controlling solenoids 27 of tracks 19 and 46, when the production is stopped.
In this particular condition, carts 20 in use are preventively disconnected from respective pipes 34, 37 and the new or cleaned carts 20 entering track 19 need to be connected to such pipes 34, 37 prior to starting production.
When the reel 11 in use is exhausted, production can be continued by simply activating one of the other feeding actuators 12 so as to feed the leading portion 13 of the respective web 6 to a selected cart 20.
The variant of
In this case, each label sheet 2, either being part of the web 6 or being separated from the web 6 itself, is retained on a respective pair of carts 20′ by grippers 20a.
In particular, each cart 20′ is provided, on its top and bottom parts, with respective grippers 20a cooperating with the leading or trailing portion 2a, 2b of the respective label sheet 2.
Grippers 20a of carts 20′ replace suction or positive pressure used on carts 20. Grippers 20a are mounted on their respective carts 20′ in a movable way so as to release the leading or trailing portion 2a, 2b of the respective label sheet 2 at application station 9.
The variant of
In this case, label sheets 2 are electrostatically charged with a negative or positive charge—in the example shown with a negative charge—and carts 20″ are electrostatically charged with a positive or negative charge—in the example shown with a positive charge. In practice, carts 20″ and label sheets 2 are electrostatically charged with opposite charges.
In this way, each label 2, either being part of web 6 or being separated from the web 6 itself, is retained on the respective pair of carts 20″ only by means of static electricity, with no need to use suction.
In the light of the above, the present invention provides a new labelling machine 1, which significantly improves the process of applying label sheets 2 onto articles 3.
This effect is obtained by introducing a magnetic-inductive control of the label transfer device 7, wherein carts 20, 20′, 20″ can independently move along track 19, so resulting in a more time-efficient labelling process. More specifically, after releasing the label sheets 2 onto the respective articles 3, carts 20, 20′, 20″ can be accelerated conveniently while returning to the input station 8 of the label transfer device 7, where they receive again the web 6 of labelling material from the respective reel 11.
Furthermore, the web feeding unit 5 as described in this solution provides a simple and continuous supply of labelling material, overcoming some of the drawbacks above mentioned, e.g. the splicing of webs and the need for an operator passing the web around all the rollers during the splicing itself. In fact, the reels 11 are advantageously organized in a way such that when a reel 11 is exhausted, another one is ready to deliver another respective web 6 of labelling material to the carts 20, 20′, 20″ by simply activating the respective feeding actuator 12, as described above.
The introduction of the service conveyor 45, also equipped with its own inductive track 46, significantly eases the process of maintenance of carts 20, 20′, 20″″, reducing overall time consumption and costs.
Last but not least, the labelling machine according to the present invention allows a more flexible switch between different products and, thus, different label formats: in fact, when a different format of label sheet 2 has to be applied, it is sufficient to replace the old carts 20, 20′, 20″ with new appropriate carts 20, 20′, 20″ suitable for the new label sheet 2 and the new web characteristics.
Clearly, changes may be made to the labelling machine 1 as described and illustrated herein, without, however, departing from the scope of protection as defined in the accompanying claims.
Number | Date | Country | Kind |
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17305490 | May 2017 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2017/071289 | 8/24/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2018/202320 | 11/8/2018 | WO | A |
Number | Name | Date | Kind |
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3554841 | Wysocki et al. | Jan 1971 | A |
4832774 | DiFrank et al. | May 1989 | A |
Number | Date | Country |
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2889238 | Jul 2015 | EP |
2260749 | Apr 1993 | GB |
2007110199 | Oct 2007 | WO |
Entry |
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Machine Translation into English of W02007/110199A2, Klaus, published Oct. 4, 2007; 7 pages. (Year: 2007). |
International search report dated Oct. 25, 2017, 10 pages. |
Number | Date | Country | |
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20200156816 A1 | May 2020 | US |