The present invention relates to a unit for processing a web of packaging material for producing sealed packages of pourable food products.
As is known, many pourable food products, such as fruit juice, pasteurized or UHT (ultra-high-temperature processed) milk, wine, tomato sauce, etc., are sold in packages made of sterilized packaging material.
A typical example of such a package is the parallelepiped-shaped package for liquid or pourable food products known as Tetra Brik Aseptic (registered trademark), which is formed by folding and sealing a web of laminated packaging material. The packaging material has a multilayer structure comprising a layer of fibrous material, e.g. paper, covered on both sides with layers of heat-seal plastic material, e.g. polyethylene. In the case of aseptic packages for long-storage products, such as UHT milk, the packaging material also comprises a layer of oxygen-barrier material defined, for example, by an aluminium film, which is superimposed on a layer of heat-seal plastic material and is in turn covered with another layer of heat-seal plastic material eventually defining the inner face of the package contacting the food product.
As is known, such packages are made on fully automatic packaging machines, on which a continuous tube is formed from the packaging material supplied in web form.
More specifically, the web of packaging material is sterilized and then fed to a forming unit on which it is folded and sealed longitudinally to form a vertical tube. The tube is filled with the sterilized or sterile-processed food product, and is sealed by pairs of jaws and subsequently cut at equally spaced cross sections to form pillow packs, which are then folded mechanically to form the finished, e.g. substantially parallelepiped-shaped, packages.
Upstream from the forming unit, the web of packaging material may be fed through a processing unit for performing various auxiliary operations, which, when producing packages with opening devices, such as pull-off tabs, screw or hinged caps, may comprise, for example, perforation of a number of through openings or holes at predetermined points on the web, and one or more operations to fix the opening devices over the holes.
The most commonly used opening devices comprise a patch defined by a small sheet of heat-seal plastic material, and which is heat sealed over a respective hole on the side of the web eventually forming the inside of the package; and a pull-off tab applied to the opposite side of the packaging material and heat sealed to the patch. The tab and patch adhere to each other, so that, when the tab is pulled off, the portion of the patch heat sealed to it is also removed to uncover the hole.
To close the package once the tab is pulled off, the portion of the packaging material surrounding the tab is normally fitted with a frame element normally made of plastic material and supporting a removable, e.g. screw or hinged, cap for closing the respective hole.
Alternatively, closable opening devices are also known to be applied by injecting plastic material directly onto the holes in the web, as described, for example, in Patent WO 98/18609.
On known machines, the web of packaging material is fed in steps through the processing unit by a feed system comprising feed rollers controlled by a servomotor in turn controlled in response to a signal generated by an optical sensor for detecting a reference element, normally a preprinted marker such as a bar code, repeated at predetermined intervals along the web.
In the case of processing units comprising a punch station, and two heat-seal stations for applying the patches and pull-off tabs respectively, a high degree of precision is required in positioning the web, especially at the tab seal station.
That is, to ensure perfect sealing of the holes in the web, the size of the patches and tabs must be proportional to the maximum offset between the work position of the heat-seal stations and the holes themselves. The size of the tabs, however, is a critical parameter, which directly determines the size of the frames and caps applied to the tabs, and which must therefore be kept as small as possible to avoid the obvious disadvantages in using relatively large caps.
Similarly, when the processing unit comprises, in addition to the punch station, a station for injection molding closable opening devices directly onto the respective holes in the web, the portion of the web surrounding each hole must be positioned correctly inside the molding cavity, to ensure correct flow of the thermoplastic material injected into the cavity and, hence, correct sealing of the edge of the hole on both sides of the web.
A demand therefore exists within the industry for even greater precision in processing the web at each station on the unit.
It is an object of the present invention to provide a unit for processing a web of packaging material for producing sealed packages of pourable food products, and which provides for a high degree of precision in the performance of at least two successive operations on the same portion of the web.
According to the present invention, there is provided a unit for processing a web of packaging material for producing sealed packages of pourable food products, said unit comprising at least a first station for forming a number of through holes in said web; a second station for sealing said holes by applying respective opening devices by which to open the packages; a feed device for step feeding said web along a path through said first and said second station; a position sensor generating a presence signal indicating the passage, past the sensor, of reference elements on said web; and control means for controlling said feed device in response to said presence signal; characterized in that said reference elements bear a predetermined relationship with said holes in said web; said unit also comprising actuating means cooperating with said second station to move the second station in a direction parallel to said path, and activated by said control means to adjust the position of the second station as a function of said presence signal.
A preferred, non-limiting embodiment of the present invention will be described by way of example with reference to the accompanying drawings, in which:
Number 1 in
Unit 1 may be incorporated in a packaging machine (not shown) for continuously producing said packages from web 2 of packaging material. More specifically, web 2 is folded and sealed longitudinally in known manner to form a vertical tube, which is filled with the sterilized or sterile-processed food product, is sealed at equally spaced cross sections, and undergoes successive mechanical folding operations to form the finished packages.
Web 2 is fed through unit 1 along a path P, and is provided on one face with a number of optically detectable reference elements, e.g. preprinted markers conveniently including respective bar codes C (
Web 2 of packaging material has a multilayer structure, and substantially comprises a layer of fibrous material, e.g. paper, covered on both sides with respective layers of heat-seal plastic material, e.g. polyethylene. The side of web 2 eventually forming the inner face of the package and so contacting the food product also has a layer of barrier material defined, for example, by an aluminium film in turn covered on both sides with respective layers of heat-seal plastic material, e.g. polyethylene.
Unit 1 comprises a known punch station 3 (shown only schematically) located along a first vertical portion P1 of path P, and where web 2 is punched to form a number of openings or holes 4 (FIG. 4)—in the example shown, substantially ogival in shape—equally spaced along path P with a spacing equal to the length of the packaging material used to form one package, minus said production tolerances of web 2.
Unit 1 also comprises, downstream from station 3 and in series along a second horizontal portion P2 of path P, a first and a second station 5, 6 (known and only shown schematically) for respectively applying a patch 7 and a pull-off tab 8 to each hole 4 and on opposite faces of web 2.
More specifically, patches 7 are defined by small rectangular sheets of heat-seal plastic material, and are heat sealed at station 5 over respective holes 4 on the face of web 2 eventually forming the inside of the packages; and tabs 8 are also made of heat-seal plastic material, are rectangular, and are heat sealed at station 6 to respective patches 7 on the face of web 2 eventually forming the outside of the packages. More specifically, at the end of the operations performed at stations 5 and 6, each tab 8 projects outwards with respect to respective hole 4 in web 2, and is joined to respective patch 7 over a sealing area extending close to and inwards of a lateral edge of hole 4 and defining a tear portion of patch 7, which is removed when tab 8 is pulled off.
Like web 2 of packaging material, each tab 8 has a multilayer structure, and is defined by a layer of heat-seal plastic material, e.g. polyethylene, one face of which eventually adheres to respective patch 7; and by a layer of barrier material, normally aluminium, which is fixed to the layer of heat-seal plastic material on the opposite side to patch 7.
Unit 1 also comprises a feed device 10 for step feeding web 2 along path P through stations 3, 5 and 6.
More specifically, feed device 10 comprises two rollers 11, 12, which cooperate with opposite faces of web 2, define a downstream end of portion P2 of path P, and are controlled by a servomotor 13; and web 2 is guided from portion P1 to portion P2 of path P by an idle guide roller 14.
More specifically, roller 11 is controlled by servomotor 13 via a first, e.g. toothed-belt, transmission 15, and in turn controls roller 12 via a second, e.g. gear, transmission (not shown).
Feed device 10—and more specifically servomotor 13—is controlled by a control device 20 in response to a presence signal S generated by a position sensor 21, e.g. a photocell, located along path P, and indicating the passage, past sensor 21, of codes C on web 2.
More specifically, sensor 21 is located close to—in the example shown, downstream from—station 3 along path P, so that the distance between each hole 4, formed at station 3, and respective code C is unaffected by the inevitable pull on web 2 through unit 1, and detection of codes C by sensor 21 corresponds extremely accurately to detection of the respective holes 4.
Presence signal S assumes a first, e.g. high, logic level as a code C on web 2 travels past sensor 21; and a second, e.g. low, logic level in any other condition.
An important aspect of the present invention is that unit 1 also comprises an actuating device 22, which cooperates with station 6 to move it in a direction parallel to portion P2 of path P, and is activated by control device 20 to adjust the position of station 6 as a function of the presence signal S generated by sensor 21. More specifically, the above adjustment is made by sliding stationing along a guide 23 shown schematically in
With reference to
More specifically, supporting structure 25 comprises a substantially rectangular base plate 30 defining a peripheral C-shaped cavity 31 facing structural portion 28 of station 6; and a substantially prismatic, cup-shaped member 32 fixed to plate 30 so as to engage cavity 31, and having a lateral opening 33 facing station 6, and a top opening 34 closed partly by an annular disk member 35 to which motor 24 is fixed coaxially.
As shown in
Assembly 26 comprises a cam member 36 fitted to shaft 27 and housed inside cup-shaped member 32; and a tappet roller 37 fitted in rotary and axially-fixed manner to an appendix 38 of structural portion 28 of station 6, and cooperating with cam member 36.
More specifically, cam member 36 is defined by a substantially cylindrical sleeve 40, from which a substantially annular, contoured flange 41 projects radially. Flange 41 has a cam profile defined by a curved line increasing gradually in radius, and the ends of which are joined by a substantially radial break portion.
Cam member 36—or more specifically sleeve 40—is fitted coaxially, with the interposition of a bearing 42, to a cylindrical appendix 43 projecting from a bottom wall 44 (
Cam member 36 and tappet roller 37 are maintained contacting by two garter springs 45 interposed between plate 30 and structural portion 28 of station 6, and having respective axes parallel to portion P2 of path P. More specifically, each spring 45 has a first end fixed to a bracket 46 projecting from plate 30; and an opposite second end fixed to a pin 47 projecting from structural portion 28 of station 6.
With reference to
More specifically, to adjust the position of station 6 before each tab 8 is applied to a respective hole 4 in web 2, control device 20 implements the operations described below with reference to the logic block diagram in
As shown in
Control device 20 then processes presence signal S and calculates the absolute value and sign of the time T between the actual instant code C travels past sensor 21, and the expected or programmed instant in which passage should have occurred (block 51).
As a function of time T determined above and of the traveling speed of web 2, control device 20 calculates how far and in which direction cam member 36 of actuating device 22 must be rotated from its current angular position to achieve a work position of station 6 in which tab 8 is applied properly centered with respect to hole 4 (block 52). In other words, control device 20 calculates the absolute value and sign of how far station 6 must be moved by actuating device 22 for tab 8 to be heat sealed properly centered over respective hole 4.
As a function of the displacement determined above, control device 20 generates signal C5 to control motor 24 of actuating device 22 (block 53).
The advantages of unit 1 according to the present invention will be clear from the foregoing description.
In particular, detecting the actual location of each hole 4 in web 2 by means of sensor 21, and by adjusting the position of station 6 each time as a function of presence signal S generated by sensor 21, tabs 8 are applied properly centered over respective holes 4, thus ensuring optimum sealing of holes 4 and enabling a reduction in the size of tabs 8.
Clearly, changes may be made to unit 1 as described and illustrated herein without, however, departing from the scope of the accompanying Claims.
In particular, as opposed to codes C, sensor 21 may detect the passage of holes 4 themselves; in which case, sensor 21 may be located at any point, between stations 3 and 6, enabling the position of station 6 to be adjusted following detection and before station 6 is activated to apply a tab 8 over the detected hole 4.
Unit 1 may also comprise a further actuating device identical to actuating device 22 and controlled by control device 20 to adjust the position of station 5 in a direction parallel to portion P2 of path P.
Finally, different operations may be performed downstream from the punch operation; for example, the second operation may comprise injection molding closable opening devices directly onto respective holes 4 in web 2.
Number | Date | Country | Kind |
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00830479 | Jul 2000 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP01/07772 | 7/6/2001 | WO | 00 | 1/3/2003 |
Publishing Document | Publishing Date | Country | Kind |
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WO02/04296 | 1/17/2002 | WO | A |
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9818609 | May 1998 | WO |
Number | Date | Country | |
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20040038789 A1 | Feb 2004 | US |