The present invention relates to a method and apparatus for packaging articles.
It is known to package articles by wrapping them in flexible sheet material such as, for example, highly stretched synthetic plastics film. An article, or a group of articles, is typically enclosed between two sheets of material or a folded single sheet and the material is heat sealed at overlapping edges.
A continuous process for wrapping articles in material of this kind is described in international patent application WO 90109316 which discloses a longitudinal wrapping machine whereby articles are wrapped by winding a continuous web of wrapping material around the articles in a direction generally transverse to their direction of movement along the machine. This results in the articles being wrapped by a helical continuous web of material. The machine has an upstream conveyor that is separated from a downstream conveyor by a rotary ring-type web applicator whose rotary axis is generally parallel to the longitudinal axis of the conveyors. The articles are fed to the applicator by the upstream conveyor and as they pass through the ring of the applicator at a predetermined speed it rotates and dispenses the wrapping material. As a result, the articles are wrapped by a continuous helical band of material. The wrapped articles pass to the downstream conveyor which carries them to a cutting station. A longitudinal web of material disposed on the conveyors passes through the applicator and is transported under the articles at the same rate. This web serves to bridge the gap between the upstream and downstream conveyors and thus supports the articles as they pass continuously between them.
The machine referred to above has been used successfully in commercial applications but is relatively complex. There is a desire to simplify the machine and to improve its versatility.
According to a first aspect of the present invention there is provided packaging apparatus for helically wrapping articles comprising a wrapping material applicator, a first conveyor for transporting unwrapped articles towards said applicator and a second conveyor for transporting articles that have been helically wrapped with flexible sheet material by the applicator, the first and second conveyors being spaced apart, the wrapping material applicator being disposed between said first and second conveyors and which serves, in use, to pass the wrapping material between the spaced apart first and second conveyors so as to wind it around and wrap an article disposed in the space between the conveyors, the applicator comprising a rotary member and a fixed guide member, the rotary member being rotatable relative to and supported in rotation by the guide member, at least one reel shaft for supporting a reel of wrapping material mounted on the rotary member, a plurality of rotary tensioning rollers supported on the rotary member and for applying tension to the wrapping material, a drive member for driving the rotary member in rotation relative to the guide member, and a transmission device between the rotary member and the guide member for
converting the relative movement of the rotary member and guide member into rotation of the tensioning rollers.
The invention provides for compact packaging apparatus with reduced components compared to conventional designs. It allows tension to be applied to the wrapping material (re-stretch) prior to it being wrapped around the article and without the need for separate drives with speed controllers. The wrapping material provides not only a protective cover against e.g, dust or the like but also gives structural support to the articles.
The drive member preferably engages with a surface of the rotary member so as to drive it in rotation. The rotary member may be in the form of an annulus with an inner surface for driving engagement with the drive member. The inner surface is preferably a toothed surface for engagement with a tooth wheel of the drive member.
The guide member ideally comprises an annular guide surface on which the rotary member is supported in rotation. The guide surface is a cam surface that is engaged with at least one cam follower mounted on the rotary member. The cam surface may be an annular rib that engages with corresponding recesses in the cam follower. The cam follower may be in the form of a roller with a recess therein.
The guide member ideally has a surface that is drivingly connected to the transmission member so as to enable driving of the tension rollers in rotation at different rotary speeds so as to apply a stretch or tension to the wrapping material.
The transmission device is preferably in the form of a gear train that preferably includes gear wheels attached to the tensioning rollers. The surface of the guide member is preferably an annular, toothed surface that meshes with toothed gear wheels of the tension rollers. There may be an idler gear between the gear wheel of the rollers. Ideally there are provided a plurality of apertures in the rotary ring that offer alternative locations for the idler gear. Preferably there is a first gear wheel connected to a first tensioning roller and a second gear wheel connected to a second tensioning roller, the first gear wheel being in engagement with the annular toothed surface of the guide member and the idler gear wheel being disposed between the first and second gear wheels. The first and second gear wheels are preferably of different sizes to allow for differential angular velocities so as to apply tension to the wrapping material in use.
The annular, toothed surface is preferably adjacent to the cam surface.
An idler roller may be provided adjacent to the reel shaft and in use the wrapping material is passed over the idler roller. The idler roller is ideally connected to the reel shaft by an endless loop belt so as to maintain them at the same angular velocity.
Preferably there is a plurality of reel shafts spaced around the rotary member.
There may be further provided a reel of wrapping material for laying a band of wrapping material under the articles to be wrapped.
According to a second aspect of the present invention there is provided packaging apparatus for helically wrapping articles comprising a wrapping material applicator, a first conveyor for transporting unwrapped articles towards said applicator and a second conveyor for transporting articles that have been helically wrapped with flexible sheet material by the applicator, the first and second conveyors being spaced apart, the wrapping material applicator being disposed between said first and second conveyors and which serves, in use, to pass the wrapping material between the spaced apart first and second conveyors so as to wrap an article disposed in the space between the conveyors, at least one reel shaft for supporting a reel of wrapping material mounted on the rotary member, and at least one idler roller adjacent to the reel shaft for guiding the wrapping material as it is unwound from the reel, wherein there is provided endless loop elongate flexible transmission element around reel shaft and idler roller that ensure that the roller and shaft rotate at substantially the same angular velocity.
This aspect of the invention ensures that a constant tension is applied to the reel of wrapping material as it is unwound from the reel regardless of the amount of material on the reel.
According to a third aspect of the present invention there is provided a method for packaging articles using a wrapping material applicator that is disposed between first and second conveyors, comprising the steps of conveying articles to be wrapped towards the applicator, the applicator having a rotary member that supports at least one reel of wrapping material and a plurality of tensioning rollers, rotating the rotary member of the applicator and supporting the rotation on a guide member, the wrapping material being wrapped around the articles and drawn from the reel by the articles as the rotary member rotates, using the relative rotation of the rotary member and the guide member to drive rotation of tensioning rollers so as to apply a stretch to the wrapping material before it contacts the articles.
The articles are wrapped continuously as they are moved by the conveyors in a direction substantially parallel to a rotary axis of the applicator.
Specific embodiments of the present invention will now be described, by way of example only, with reference to the accompanying drawings in which:
a) and (b) are schematic sectioned views of cutter members of the cutting station of
a) and (b) are schematic sectioned views of an alternative embodiment of the cutters for the cutting station shown in spaced apart and cutting positions;
Referring now to
The upstream and downstream conveyors 11, 12 are both arranged in two adjacent sections and a cutting station 18 is interposed between adjacent sections 12a, 12b of the downstream conveyor 12. Here the individual articles are separated by cutting through the wrapping material in the space between adjacent articles 10.
Further bands of wrapping material 19, 20 are drawn from a pair of reels 21, 22 disposed above and below the upstream conveyor 11. A lower one of the further bands 19 is unwound from a reel 21 under the upstream conveyor 11, emerges between the adjacent sections 11a, 11b of the upstream conveyor and is transported under articles 10 across the gap 15 to the downstream conveyor 12. This lower band 19 serves to facilitate the transfer of each article 10 across the gap 15 from the upstream to the downstream conveyors by providing a continuously running surface that moves with the conveyors. An upper band 20 is dispensed from a reel 22 disposed above the upstream conveyor 11 so as to overlie a top surface of the articles 10. Both the upper and lower bands 20, 19 may move in adhesion with the articles 10 and may be of the same or similar material to that of the main wrapping material film 16. It will be appreciated that as the articles 10 are wrapped by the applicator 13, the helical bands 16 also wrap around the upper and lower bands 20, 19 and in the process turn up or down around the article any exposed side edges of the bands. The completed wrapped article will thus have external helical wraps containing both the article 10 and the sheets of the upper and lower bands 20, 19 of wrapping material.
In operation the articles 10, the upper and lower bands 20, 19 of wrapping material and the conveyors 11, 12 all translate at effectively the same linear speed even if the downstream conveyor 12 is driven at a slightly faster speed than the upstream conveyor 11 as can be advantageous.
As the articles 10 are sitting on the lower band 19 of wrapping material there is no external force to disturb the spacing between adjacent articles. The weight of the articles 10 on the band 19 can serve as the sole agency for drawing the material through the machine as at least the downstream conveyor 12 is driven and the consequent tension in the band 19 between the conveyors 11, 12 can be enough to convey the articles successfully across the gap 15. In practice, a bracket or other form of support surface may be used to span the gap 15 and support the band 19 as it passes across the gap 15 as described in PCT/GB90/00266.
An upper conveyor 46 on the downstream side provides support for the packaged articles as they exit the wrapping applicator. It serves to prevent the packs from being twisted over on account of the forces applied by the applicator and serves to pull the wrapped articles through the apparatus.
Turning now to
In addition to the cam surface 27, the guide ring 23 also defines an annular toothed surface 32 on its outer periphery. This toothed surface 32, seen most clearly in
The reels 17 of the helical wrapping material 16 are each mounted on a shaft 38 that is rotatably supported on a respective bracket 39 extending radially from, and fixed to, the periphery of the rotary ring 14. The shafts 38 are arranged at equi-angular intervals around the front face of the ring 14 and each extends in a direction parallel to the rotary axis of the ring 14. The wrapping material 16 that is unwound from each reel 17 passes around a series of three rollers positioned in close proximity to the shaft 38 and extending in parallel thereto. One of such rollers operates as an idler roller 40 that guides the direction of the unwound material and is rotatably mounted on the bracket 39 at a location spaced from the shaft 38 whilst the other two rollers are the tensioning rollers 36, 37 referred to above and that are rotatably supported on the front face of the rotary ring 14 with a small spacing therebetween, radially inwardly of the guide roller 40. A first of the tensioning rollers is a feed roller 36 and the other is an applicator roller 37. Both rollers 36, 37 are covered with a suitable friction coating or texturing that may be applied by laser deposition or other coating techniques, etching or knurling or the like to provide asperities on the roller surface that serve to grip the wrapping material as it passes over the rollers.
Each of the tensioning rollers 36,37 has a reduced diameter at one end so as to define a drive shaft 41 that passes through an aperture 42 in the rotary ring 14. On the rear face of the rotary ring, corresponding gear wheels 33, 35 are mounted on each of the shafts 41 in a fixed relationship. The gear wheel 33 associated with the applicator roller 37 is disposed in a fixed radial location such that its teeth mesh with those defined on the toothed periphery 32 of the guide ring 23. The gear wheel 35 associated with the feed roller 36 is circumferentially spaced from the applicator gear 33 and is disposed at a fixed radial location such that its teeth are clear of those 32 defined on the outer periphery of the guide ring 23. Interposed between the applicator and feed gears 33, 35, in a meshing relationship, is an idler gear 34 that is mounted to the rear of the rotary ring 14 but which can be selectively disposed at one of three radial locations provided by three apertures in the ring (these are labelled as location A, B and C in
As can be best seen in
As the articles 10 pass the rotary ring applicator 14 the wrapping film material 16 is helically wound around them and the upper and lower bands 20, 19. The wrapped train of articles then passes the cutter station 18 where the helical wrapping film 16 is severed to leave individual packs of wrapped articles. The cutter station 18 comprises a frame 44 on which there is supported a heated horizontal wire that is moved in a vertical direction to heat and sever the wrapping material 16. The wrapping film naturally shrinks around the articles to provide for a self-contained wrapped package.
An alternative cutting station configuration is shown in
In an alternative cutter embodiment shown in
In an alternative embodiment shown in
A further alternative arrangement of the connection between each of the reel shafts 38 and idler rollers 40 is illustrated in
It is to be understood that the belt tensioning arrangement described above and illustrated in
The wrapping film is typically in the region of 7 to 9 microns thick.
The invention has many advantages compared to existing designs. In particular, the provision of the guide ring advantageously supports the rotation of the rotary ring and also enables the movement of the rotary ring to be used in driving the tensioning rollers. By using a gear train as the transmission between the guide ring and the rotary ring the requirement for differential drive speed or tensioning arrangements for those rollers can be eliminated.
The invention provides for a packaging method that ensures that there is no significant waste wrapping material.
It has been established in tests that for a pack of 350 mm by 350 mm in section, 3 reels, 40 rpm rotary ring speed, 20% overlap in wrap and conveyor running at 12 m, per minute can achieve around 35 ppm
The apparatus obviates the need for a separate heat shrink oven that would be unsuitable for certain types of heat sensitive articles (e.g. aerosols)
The apparatus has a relatively small size compared to existing designs.
It is to be appreciated that lower film band 19 is not essential if a low friction plate or bracket is used to bridge the gap 15 and the friction characteristics of the conveyor belts are high enough to enable the articles to be transported across the gap between upstream and downstream conveyors.
Moreover, it is to be appreciated that the upper film band 20 is not essential and is generally only to be used where the article have sharp edges or other protrusions that have a tendency to pierce the helical wrapping film.
The present invention has the advantage that there is no need to alter the machine set-up for different size and shapes of articles. Generally prior art machines use a different width film for different width products.
The provision of a belt or any other flexible endless loop transmission element between the reel shaft and the idler roller allows for a constant tension to be applied to the film as it unwinds form the reel regardless of the amount of material left on the reel.
The apparatus is designed to use thin pre-stretched film with folded edges to give strapping resistance to the pack. The helical wrapping film obviates the need for other packing elements such as boxes, trays etc.
On all the conveyors the texture of the belts is designed to optimise the friction between the articles and the belt surface.
It is to be appreciated that the wrapping apparatus may have applications outside of packaging of articles with synthetic plastics film. For example, the same invention could be used to wrap any elongate flexible material such as a textile, fibres, strips of material, metal composite bands or the like to an article to create any sort of structural component.
Number | Date | Country | Kind |
---|---|---|---|
0424754.0 | Nov 2004 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/GB2005/004307 | 11/9/2005 | WO | 00 | 5/10/2007 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2006/051281 | 5/18/2006 | WO | A |
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0936141 | Aug 1999 | EP |
Number | Date | Country | |
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20080184676 A1 | Aug 2008 | US |