The invention relates to a method and apparatus for manufacturing a tape, in particular although not exclusively, a method and apparatus for manufacturing a reclose tape having an adhesive stripe.

Products are frequently provided in packaging which can be opened to provide access to the product. If the product is perishable, for example if it is a food stuff, it may be desirable to reclose the packaging in order to keep the product fresh. For example, pasta, rice or chocolate is often provided in a flexible filmic bag. It is known to provide an adhesive reseal label or tape which is releasably adhered to the outside of the bag and which can be used to reclose, or reseal, the bag. The label or tape can be peeled away from the bag and adhered to a folded down part of the bag to reclose it. It is known to provide the label or tape with a non-adhesive, or dry, fingerlift in order to make it easier for the user to peel the label or tape away from the bag.

In one previously considered arrangement, a reclose tape is provided which has a longitudinally extending adhesive layer and a coextensive dry fingerlift along the edge of the tape. The reclose tape is typically manufactured by laminating two layers together with an overlap. With conventional manufacturing techniques, it can be difficult to manufacture narrow reclose tapes to high tolerances.

It is therefore desirable to provide an improved method and apparatus for

manufacturing adhesive tapes.

According to an aspect there is provided a method of manufacturing an adhesive tape, comprising: a tape slitting operation in which, using a tape slitting head, a web having a plurality of transversely spaced adhesive stripes is slit into a plurality of adhesive tapes which each have an adhesive stripe; and controlling the tape slitting such that the web is slit in register with the adhesive stripes by monitoring the transverse position of at least a part of at least one adhesive stripe and adjusting the relative transverse position between the tape slitting head and the web in response thereto. The adhesive tape may be slit into a plurality of adhesive tapes which each have a single adhesive stripe. The adhesive tape may be slit into a plurality of adhesive tapes which each have an adhesive stripe and one or two non-adhesive edges. The adhesive tape may be a reclose tape (alternatively referred to as a reseal tape). The relative transverse position between the tape slitting head and the web may be periodically or continually automatically adjusted. The web may be drawn or fed in the web direction. The web may be subject to the tape slitting operation as it is drawn (or fed) through the tape slitting head. The web may be continuously slit. The method may be a continuous process.

The adhesive tape, such as a reclose/reseal tape, may comprise a longitudinally extending adhesive stripe, such as a reseal (or reclose) adhesive stripe, and at least one longitudinally extending non-adhesive edge region forming a fingerlift. The adhesive stripe may be coextensive with the reclose tape. The adhesive stripe may be continuous in the length (or web) direction, or it may be discontinuous or patterned. For example, the adhesive stripe could be a "dotted" stripe, a zig-zag stripe, or a hatched stripe. The reclose tape may comprise first and second longitudinally extending non-adhesive edge regions forming first and second fingerlifts. The longitudinally extending adhesive stripe may be located substantially centrally. The or each fingerlift may be adhesive free or deadened. The web substrate may form the base layer of the adhesive tape.

The width of each adhesive stripe may be 50mm or less, 40mm or less, 30mm or less, 20mm or less, 15mm or less, 10mm, or 5mm or less. The width of each adhesive stripe may be between 1 -50mm, 2 -40mm, 3-30mm, 2-20mm, 4-10mm, or 5-8mm. The width of each tape may be 50mm or less, 40mm or less, 30mm or less, 20mm or less, 15mm or less, or 10mm or less. The width of each tape may be between 1-60mm, 2- 50mm, 3-40mm, 2-30mm, 4-20mm, or 5-10mm.

Tape slitting may be carried out in the web direction in line (i.e. in the same direction) or parallel to the adhesive stripes. Tape slitting in (transverse) register with the plurality of adhesive stripes means that the transverse locations of the transversely spaced slitting lines (which extend in the web direction) have a fixed relationship to the transversely spaced adhesive stripes (which extend in the web direction). The plurality of transversely spaced adhesive stripes may be located side-by-side across the web direction. There may be gaps, or spaces, between adjacent adhesive stripes. The transverse spacing between the adhesive stripes may be greater than the width of the adhesive stripes. The transverse spacing (centreline to centreline) between the adhesive stripes may be uniform. The transverse spacing between the adhesive stripes may be the same as the width of the adhesive tape. The adhesive stripes may longitudinally and continuously extend in the web direction. The adhesive stripes may be formed by discrete stripes of adhesive. The adhesive stripes may be formed by printing or coating stripes of a deadening layer over a continuous layer of adhesive.

The web may be a filmic substrate. The web may be a slittable substrate. The web may be made from a material such as mono-oriented polypropylene (MOPP), polypropylene (PP), bi-oriented polypropylene (BOPP), polyethylene terephthalate (PET), polyethylene (PE) or paper. The web may be clear or transparent.

The transverse position of the edge of at least one adhesive stripe may be monitored. The width of an adhesive stripe could be monitored, or multiple edges of one or more adhesive stripes could be monitored. The adhesive stripes may have luminescent or photoluminescent properties. The adhesive may therefore be considered to be a luminescent or a photoluminescent adhesive. The adhesive stripes may have fluorescent properties. This may mean that when irradiated with certain types of radiation visible light is emitted. Controlling the tape slitting may comprise irradiating at least a part of at least one adhesive stripe with radiation. The adhesive stripes may have ultra-violet photoluminescent properties. The adhesive may be considered to be an ultra-violet adhesive. Controlling the tape slitting may comprise irradiating at least a part of at least one adhesive stripe with ultra-violet radiation. The transverse position of at least a part of at least one adhesive stripe may be optically monitored. In other embodiments, the adhesive may be sensitive to other types of radiation. For example, the adhesive could have photoluminescent properties such that when irradiated with infra-red radiation it emits radiation that can be detected.

Adjusting the relative transverse (cross-web direction) position between the tape slitting head and the web may comprise transversely moving the tape slitting head. This may keep the slitting in register with the adhesive stripes. The tape slitting head may be used to guide the tape slitting. The web may be slit at positions in between adjacent adhesive stripes such that each adhesive tape comprises a central adhesive region or stripe disposed between non-adhesive edge regions.

The slitting head may comprise a plurality of transversely spaced slitting elements. The tape slitting elements may comprise blades or knives or lasers, for example. The transverse spacing (centre-to-centre) between the tape slitting elements may be fixed during use. It may be possible to adjust the transverse positions of the tape slitting elements during set-up. The transverse spacing between the plurality of tape slitting elements may substantially correspond to the transverse spacing between the plurality of adhesive stripes. The transverse spacing between the plurality of tape slitting elements may substantially correspond to the width of the adhesive tape. The method may further comprise rewinding each adhesive tape onto a reel. The adhesive tapes may be self-wound. The adhesive tapes may be traverse wound.

The method may further comprise applying onto a web a plurality of transversely spaced adhesive stripes. The width of the adhesive stripes may be uniform. The transverse spacing may be uniform. The transverse spacing may be greater than the width of the adhesive stripes. The transverse spacing may be the same as the width of the adhesive tape. The adhesive stripes may be applied in register with one another. Therefore, the relative transverse positioning between the plurality of adhesive stripes may be constant or fixed in the web direction (but not necessarily fixed with respect to the web). The adhesive stripes may be applied using a coating cylinder. The adhesive stripes may be applied using a gravure coating process. All of the plurality of adhesive stripes may be applied with a single coating cylinder. The adhesive stripes may be applied using a reverse gravure coating process. Of course, any suitable coating technique could be used including three roll reverse. The web may be drawn or fed in the web direction. Each adhesive stripe may be continuous (in the web direction) or may be discontinuous (e.g. a "dotted" adhesive stripe), or may be patterned (e.g. a zigzag or a hatched stripe). The adhesive stripes may be stripes of a clear adhesive. The adhesive stripes may be stripes of a pressure-sensitive adhesive. The adhesive stripes may be stripes of a reseal adhesive. The method may further comprise applying a release coating onto the opposite side of the web to the side to which the adhesive stripes are applied. The release coating may be a silicone release coating and/or may be continuous.

The method may further comprise printing, such as printing a print pattern, onto a web. The print pattern may comprise one or more printed datums. The register between the adhesive stripes and the print may not be automatically controlled. The web may be printed using one or more printing cylinders, which may include a gravure printing cylinder. The web may be printed using a gravure printing process. The web subject to the tape slitting operation may be a narrower web of the web to which the print and/or adhesive stripes are applied to.

The method may further comprise a primary slitting operation, which is carried out prior to the tape slitting operation, in which, using a primary slitting head, a web having a plurality of transversely spaced adhesive stripes is slit into a plurality of narrower webs which each have a plurality of transversely spaced adhesive stripes, wherein each narrower web is subsequently subject to the tape slitting operation. The web may be drawn or fed in the web direction. The web may be subject to the primary slitting operation as it is drawn (or fed) through the primary slitting head. The web may be continuously slit.

The method may further comprise controlling the primary slitting by monitoring the transverse position of at least one datum and adjusting the relative transverse position between the primary slitting head and the web in response thereto. The datum may comprises a printed marker or line on the web, or the edge of the web. The datum may comprise a part of at least one adhesive stripe. The transverse position of at least one datum may be optically monitored. Primary slitting may be carried out in the web direction. Primary slitting may slit the web in register (i.e. a fixed transverse

relationship) with the datum, which could be the adhesive stripes or a printed layer, for example. The relative transverse position between the primary slitting head and the web may be periodically or continually automatically adjusted.

Adjusting the relative transverse (cross-web direction) position between the primary slitting head and the web may comprise transversely moving the primary slitting head with respect to the web. This may keep the slitting in register with the adhesive stripes or the datum, such as a printed datum.

The primary slitting head may comprise a plurality of transversely spaced primary slitting elements. The primary slitting elements may comprise blades or knives or lasers, for example. The transverse spacing between the primary slitting elements may be fixed during use. It may be possible to adjust the transverse positions of the primary slitting elements during set-up. The transverse spacing between the plurality of primary slitting elements may substantially correspond to the width of the narrow web.

The method may further comprise rewinding each narrower web onto a reel. The webs may be self-wound. In other embodiments the narrower webs may be applied onto a backing sheet or structure before winding. There is also disclosed an apparatus for manufacturing an adhesive tape, the apparatus comprising one or more tape slitting stations, each comprising: a tape slitter comprising a tape slitting head through which a web having a plurality of transversely spaced adhesive stripes can be drawn so as to slit the web into a plurality of adhesive tapes which each have an adhesive stripe; and a tape slitting controller arranged to control the tape slitting such that the web is slit in register with the adhesive stripes, the tape slitting controller comprising: an adhesive stripe monitor arranged to monitor the transverse position of at least a part of at least one adhesive stripe; and a tape slitting adjuster arranged to adjust the relative transverse position between the tape slitting head and the web based on the monitored transverse position.

The adhesive stripe monitor may be arranged to monitor the transverse position of the edge of at least one adhesive stripe. The adhesive stripes may have photoluminescent properties. The adhesive stripes may have fluorescent properties. The tape slitting controller may further comprise a radiation source arranged to irradiate at least a part of at least one adhesive stripe with radiation. The adhesive stripes may have ultraviolet photoluminescent properties. The tape slitting controller may further comprise an ultra-violet radiation source arranged to irradiate at least a part of at least one adhesive stripe with ultra-violet radiation. The adhesive stripe monitor may comprise an optical monitor arranged to optically monitor the transverse position of at least a part of at least one adhesive stripe.

The tape slitting adjuster may be arranged to transversely move the tape slitting head based on the monitored transverse position. The tape slitter may be arranged to slit the web at positions in between adjacent adhesive stripes such that each adhesive tape comprises a central adhesive region disposed in between non-adhesive edge regions.

The tape slitting head may comprise a plurality of transversely spaced slitting elements. The tape slitting elements may comprise blades or knives. The transverse spacing between the tape slitting elements may be fixed. The transverse spacing between the plurality of tape slitting elements may substantially correspond to the transverse spacing between the plurality of adhesive stripes. The tape slitting station may further comprise a plurality of rewinders each for rewinding one of the plurality of adhesive tapes onto a reel.

The apparatus may further comprise a coating station for applying onto a web a plurality of transversely spaced adhesive stripes. The coating station may be arranged to apply the adhesive stripes in register with one another. The coating station may comprise an adhesive coating cylinder for applying the adhesive stripes. The coating station may comprise a gravure cylinder for applying the adhesive stripes. The coating station may be arranged to apply a release coating onto the opposite side of the web to the side to which the coating station is arranged to apply adhesive stripes onto. The coating station may comprise a release coating cylinder for applying the release coating. The apparatus may further comprise a printing station for printing onto a web. The apparatus may be arranged such that the register between the adhesive stripes and the print is not automatically controlled. The apparatus may further comprise a primary slitting station comprising: a primary slitter comprising a primary slitting head through which a web having a plurality of transversely spaced adhesive stripes can be drawn so as to slit the web into a plurality of narrower webs which each have a plurality of transversely spaced adhesive stripes. The primary slitting station may further comprise a primary slitting controller arranged to control the primary slitting, the primary slitting controller comprising: a datum monitor arranged to monitor the transverse position of at least one datum; and a primary slitting adjuster arranged to adjust the relative transverse position between the primary slitting head and the web based on the monitored transverse position.

The datum may comprise a printed marker or line on the web. The datum may comprise a part of at least one adhesive stripe. The datum monitor may comprise an optical monitor arranged to optically monitor the transverse position of at least one datum.

The primary slitting adjuster may be arranged to transversely move the primary slitting head based on the monitored transverse position.

The primary slitting head may comprises a plurality of transversely spaced primary slitting elements. The primary slitting elements may comprise blades or knives. The transverse spacing between the primary slitting elements may fixed.

The primary slitting station may further comprise a plurality of rewinders each for rewinding one of the plurality of narrower webs onto a reel.

There may be a plurality of tape slitting stations.

According to an aspect there is provided a method of manufacturing a web or tape, comprising: a slitting operation in which, using a slitting head, a web is slit into a plurality narrower webs or tapes; and controlling the slitting by: irradiating a datum having luminescent properties with radiation, optically monitoring the transverse position of the datum, and adjusting the relative transverse position between the slitting head and the web in response thereto.

The datum may be a printed datum, such as a printed line. The printed datum may be printed with an ink having luminescent properties such as photoluminescent or fluorescent properties. The ink may have ultra-violet photoluminescent properties. The printed datum line may be continuous or discontinuous. The printed datum may be part of a printed pattern on the web and may therefore be in register with the printed pattern. Slitting may therefore be carried out in register with the printed pattern.

The datum may be at least a part of an adhesive region or stripe. The transverse position of the edge of at least one adhesive region or stripe may be monitored. The adhesive may have luminescent properties such as photoluminescent or fluorescent properties. The ink may have ultra-violet photoluminescent properties.

The method may comprise irradiating the datum (such as a printed datum or adhesive datum) with ultra-violet radiation.

The method may comprise adjusting the relative transverse position between the slitting head and the web comprises transversely moving the slitting head.

According to another aspect there is provided an apparatus for manufacturing a web or tape, comprising: a slitter comprising a slitting head through which a web can be drawn so as to slit the web into a plurality narrower webs or tapes; and a slitting controller arranged to control the slitting, the slitting controller comprising: a radiation source arranged to irradiate a datum having luminescent properties with radiation, an optical monitor arranged to optically monitor the transverse position of the datum, and a slitting adjuster arranged to adjust the relative transverse position between the slitting head and the web based on the monitored transverse position.

The invention may comprise any combination of the features and/or limitations referred to herein, except combinations of such features as are mutually exclusive. Embodiments of the invention will now be described, by way of example, with reference to the accompanying drawings, in which: Figure 1 schematically shows product packaging having a strip of reclose tape applied to the outside;

Figure 2 schematically shows a cross-sectional view of the reclose tape of Figure 1 ; Figure 3 schematically shows a manufacturing apparatus for manufacturing a reel of reclose tape;

Figure 4 schematically shows the printing station of Figure 3; Figure 5 schematically shows the coating station of Figure 3;

Figure 6 schematically shows a plan view of a printed and coated web; Figure 7 schematically shows the primary slitting station of Figure 3;

Figure 8 schematically shows the primary slitter of Figure 7; Figure 9 schematically shows a plan view of the primary slitting operation; Figure 10 schematically shows the tape slitting station of Figure 3; Figure 1 1 schematically shows the tape slitter of Figure 10; and Figure 12 schematically shows a plan view of the tape slitting operation.

Figure 1 shows product packaging 1 in the form of a bag 2 containing a food product, such as pasta or rice, for example. The bag 2 is made from a filmic substrate and is manufactured and filled using a conventional vertical form film process. The bag 2 is provided with an elongate strip of reclose tape 10 (sometimes referred to as reseal tape) which is releasably adhered to the outer surface of the bag 2. A user can open the bag 2 to form an opening 4 such that the product can be removed from the bag 2. In order to close the bag 2, the reclose tape 10 is peeled away from the outer surface of the bag 2, the top 6 of the bag 2 is folded or rolled down and the reclose tape is readhered over the folded down top 6 of the bag 2 so as to keep the bag 2 closed. This prevents the product from falling out of an open bag, and also helps to maintain the freshness of the product.

The strip of reclose tape 10 is an elongate strip of tape and is applied to the outside of the bag 2 from a self-wound reel of reclose tape during the packaging process. The tape 10 may be applied continuously or discrete lengths may be repeated applied during the manufacturing process. Referring to Figure 2, the strip of reclose tape 10 comprises a base film layer 12 which in this embodiment is a clear (i.e. transparent) mono-oriented polypropylene (MOPP) film. It should be appreciated that other suitable materials could be used for the base layer, for example, the base layer 12 could be polypropylene (PP), bi-oriented polypropylene (BOPP), polyethylene terephthalate (PET), polyethylene (PE) or paper. The base layer 12 may be a single layer or a laminate. The lower surface of the base layer 12 is printed with a print layer 14 which may be a pattern, a continuous colour, or text, for example. The print layer 14 is viewable from the upper side of the base layer 12. A clear (i.e. transparent) adhesive stripe 16 is provided on the lower surface of the print layer 14 and extends in the same direction as the tape. The adhesive forming the adhesive stripe 16 is a pressure sensitive reseal adhesive and has ultra-violet photoluminescent (fluorescent) properties. This means that when the adhesive stripe 16 is irradiated with ultra-violet light, it radiates visible light which can be seen by a person or a camera. The adhesive may be a rubber or acrylic based adhesive and may either be a hot melt, emulsion, or a solvent based adhesive. The adhesive stripe 16 is elongate and coextensive with the base layer 12 and is narrower than the width of the base layer 12. In this embodiment the width of the base layer 12 is 10mm and the width of the adhesive stripe 16 is 5mm. The adhesive stripe 16 is continuous in the length direction, but in other embodiments the adhesive stripe 16 could be broken in the length direction. In this embodiment, the adhesive stripe 16 is located centrally with respect to the base layer 12 and therefore the underside of the base layer 12/print layer 14 has dry, or non-adhesive, edge regions 20, 22 that are elongate and extend along the entire length of the reclose tape 10, each having a width of 2.5mm. It should be appreciated that other suitable dimensions could be chosen. The dry-edge regions 20, 22 provide a fingerlift on each side of the reclose tape 10 along the entire length of the tape 10. In use, this allows a user to easily grasp the reclose tape 10 such that it can be peeled away from the packaging. It is important to control the location of the adhesive stripe 16 with respect to the base layer 12 so that the fingerlifts 20, 22 have the appropriate width. For example, if the adhesive stripe 16 is too close to one side of the base layer 12 then one of the fingerlifts 20, 22 will be too small, and the other will be too large. Although it has been described that the reclose tape 10 has two fingerlifts 20, 22, one each side of the adhesive stripe 16, in other embodiments only one fingerlift may be provided. The upper surface of the base layer 12 is provided with a silicone release layer 18 which allows the reclose tape 10 to be supplied as a self-wound reel (i.e. without a release liner). In other embodiments, a the tape 10 may be supplied on a backing

sheet/release liner.

A method and apparatus for manufacturing a self-wound reel of reclose tape (or reseal) from which lengths of reclose tape 10 can be cut will now be described.

Referring to Figure 3, in this embodiment there are four main separate stages in the manufacture of a self-wound reel of reclose tape. The manufacturing stages are as follows and will be described in detail below:

(A) a printing station 34 in which a wide web 24 of mono-oriented polypropylene, which forms the base layer 12, is printed with a print layer 14;

(B) a coating station 46 in which a plurality of transversely spaced adhesive

stripes 18 (either continuous or discontinuous adhesive stripes) extending in the web direction are applied to the lower surface of the printed web 26, and in which the upper surface of the printed web 26 is coated with a release layer 18;

(C) a primary slitting station 62 in which the printed and coated wide web 28 is slit in the web direction into a number of narrower webs 30; and (D) a number of tape slitting stations 80 in which a narrower printed and coated web 30 is slitted and wound into a number of reels of reclose tapes 32.

As shown in Figure 4, the printing station 34 comprises a reel holder 36 onto which a wide web 24 of mono-oriented polypropylene can be loaded, first and second printing stages 38, 40, a guide roller 42 and a rewinder 44. The printing station 34 is arranged to draw the web 24 from the reel holder 36 through the first printing stage 38, over the guide roller 42, through the second printing stage 40 and the rewinder 44 is arranged to rewind the printed web 26 onto a reel. In this embodiment, the web 24 has a width of approximately 1000mm, but it should be appreciated that the web may have any suitable width. The first and second printing stages 38, 40 are gravure printing stages and each comprise a gravure printing cylinder, an ink fountain, an impression roller, and a doctor blade (not shown). In use, the gravure printing cylinder picks up ink from the ink fountain, and the doctor blade scrapes off any excess ink so that ink only resides in the engraved (patterned) areas of the printing cylinder. The gravure printing cylinder then applies the ink to the web 24. In this embodiment there are two printing stages 38, 40. The first printing stage 38 prints a continuous colour, for example red, whilst the second printing stage 40 prints a continuous pattern as well as 16

transversely and uniformly spaced datum lines 15 (the purpose of these lines will be described below). The printed datum lines 15 continuously extend in the web direction, and are spaced across the web (i.e. transversely). It should be appreciated that in other embodiments there may be a different number of printing stages, and any suitable printing technique could be used, for example, offset printing. As shown in Figure 5, the coating station 46 comprises a reel holder 48 onto which the printed web 26 can be loaded, a release application stage 50, an adhesive application stage 52 and a rewinder 54. The coating station 46 is arranged to draw the web 26 from the reel holder 48 through the release application stage 50, through the adhesive application stage 52 and the rewinder 54 is arranged to rewind the printed web 26 onto a reel. The release application stage 50 is a gravure coating stage comprising a gravure release coating cylinder, a release coating fountain, an impression roller, and a doctor blade (not shown). The release application stage 50 is arranged to apply a continuous layer 18 of a release coating (such as a silicone release coating) to the entire width and length of the web 26. Accordingly, the gravure release coating cylinder has an engraved pattern around its entire circumference and of a width that corresponds to that of the web 26. In use, the gravure release coating cylinder picks up release coating from the release coating fountain, and the doctor blade scrapes off any excess release coating so that release coating only resides in the engraved area of the release coating cylinder. The gravure release coating cylinder then applies the release coating to the web 26. A continuous release coating is applied across the entire width and length of the web 26.

The adhesive application stage 52, like the release application stage 50, is a gravure coating stage comprising a gravure adhesive coating cylinder, an adhesive coating fountain, an impression roller, and a doctor blade (not shown). The adhesive application stage 52 is arranged to apply a plurality of transversely spaced adhesive stripes 16 to the web 26 over the print layer 14 (i.e. on the opposing side to the side the release coating 18 is applied to). The adhesive used to form all of the adhesive stripes 16 is clear (i.e. transparent) and has ultra-violet photoluminescent properties. The gravure adhesive coating cylinder has an engraved pattern in the form of a plurality of circumferentially extending rings that are spaced from one another across the axial (or transverse) direction of the cylinder. If the adhesive stripes 16 are to be discontinuous along their length (e.g. a "dotted" stripe), each engraved pattern may be a number of circumferentially extending recesses that are circumferentially spaced from one another. If the adhesive stripes 16 are to be patterned, the engraved pattern on the cylinders will correspond to this (e.g. zip-zag shaped or hatched shape). In use, the gravure adhesive coating cylinder picks up the ultra-violet photoluminescent adhesive from the adhesive coating fountain, and the doctor blade scrapes off any excess release coating so that adhesive only resides in the engraved areas (i.e. the rings) of the adhesive coating cylinder. The gravure adhesive coating cylinder then applies a plurality of transversely spaced continuous adhesive stripes 16 to the web 26.

However, in other embodiments the adhesive stripes 16 could be discontinuous. The adhesive stripes 16 extend in the web direction, and are spaced across the web (i.e. transversely). In this embodiment the adhesive application stage 52 is arranged to apply 90 transversely spaced adhesive stripes in 15 groups. Each adhesive stripe has a width of 5mm, and within each group of stripes, there is a 5mm gap between adjacent adhesive stripes 16. Within each group, the transverse distance, or spacing, between the longitudinal centrelines of adjacent adhesive stripes 16 is therefore 10mm. As shown in Figure 6, the adhesive application stage 52 is arranged such that a group of six adhesive stripes 16 is applied between each pair of adjacent printed datum lines 15. In this embodiment, the coating stage 46 does not continuously and automatically attempt to maintain register (i.e. transverse alignment) between the print layer 14 and the pattern of adhesive stripes 16. Since transverse register between the adhesive stripes 16 and the print 14 is not controlled, the relative transverse position between the pattern of adhesive stripes 16 and the print layer 14 (i.e. including the printed datum lines) may change (or "wander") along the length of the web. It should be appreciated that in other embodiments the adhesive stripes 16 may be applied in register with the print layer 14. The relative transverse position between the printed web 26 and the adhesive coating cylinder may be actively controlled to ensure that there is a fixed positional relationship between the pattern of adhesive stripes 16 and the print layer 14. This could be done by monitoring the transverse position of one or more printed datum lines, and transversely moving the web 26 or the adhesive coating cylinder to maintain register (transverse alignment) between the pattern of adhesive stripes 16 and the print layer 14. This would result in a fixed positional relationship between the adhesive stripes 16 and the printed datum line 15 (and hence the entire print 14).

Although it has been described that the release coating and adhesive stripes are applied by a gravure coating process in which the gravure coating cylinder rotates in the same direction as the direction of travel of the web, in other embodiments the coating process may be a reverse gravure coating process or a reverse three roll process. Further, other suitable coating processes could be used.

Referring now to Figure 7, the primary slitting station 56 comprises a reel holder 58 onto which the printed coated web 28 can be loaded, a guide roller 60, a primary slitter 62, a primary slitting controller 64, and 15 rewinders 66 (only five are shown for the purposes of clarity). The primary slitting station 56 is arranged to draw the printed coated web 28 through the primary slitter 62 which performs a primary slitting operation to slit the web 28 into 15 narrower webs 30 which are each rewound by a rewinder 66 onto a reel. The primary slitter 62 comprises a primary slitting head 68 and a planten roll 70. As shown in Figure 8, the slitting head 68 comprises a plurality, in this case 16 primary slitting elements 72 in the form of circular knives that act against the planten roll 70 (only four are shown in Figure 8). The primary slitting elements 72 are transversely uniformly spaced from one another and are fixed relative to one another, by attachment to a beam 73, for example. It may be possible to finely adjust the transverse spacing of the primary slitting elements 72 manually. The primary slitting elements 72 are spaced across the width of the web 28 and the transverse spacing between the centreline of each primary slitting element 72 corresponds to the width of each narrow web 30, and also the transverse spacing between adjacent printed datum lines 15. In this embodiment, the primary slitting elements 72 are spaced by 65mm. As the web 28 is drawn through the primary slitter 62 between the primary slitting elements 72 and the planten roll 70, the web 28 is slit in the web direction into 15 ' narrower webs 30 (each having a width of 65mm), with each narrower web 30 having six transversely spaced continuously extending adhesive stripes 16. As will be described below, the primary slitting head 68 is moveable in the transverse direction with respect to the web 28 which allows the transverse positions at which the web 28 is slit to be adjusted.

The primary slitting controller 64 comprises an optical datum monitor 74 in the form of a camera, a primary slitting adjuster 76 which can adjust the transverse position of the primary slitting head 68 relative to the web 28, and a control unit 78 which is connected to the monitor 74 and adjuster 76. The primary slitting controller 64 is arranged to automatically control the primary slitting operation such that the web 28 is slit into 15 narrower webs 30 in register with the print layer 14. This ensures that the web 28 is slit at the desired transverse positions. Slitting in register with the print layer means that a predetermined and fixed positional relationship is maintained between the slitting positions and the print layer. In this embodiment, the web 28 is slit along lines that are parallel to and transversely spaced from the datum lines 15. However, in other embodiments the web 28 may be slit along the datum lines 15. Since the web 28 is slit along lines spaced from the datum lines 15, each narrower web 30 slit from the wider web has a printed datum line 15 that extends in the web direction.

With reference to Figure 9, in use, with the web 28 being drawn in the web direction W, the optical datum monitor 74 visually monitors the transverse position of one of the datum lines 15 printed on the web 28. Based on the monitored position, the control unit 78 causes the primary slitting adjuster 76 to automatically adjust the transverse position of the primary slitting head 68 (if necessary) to ensure that the slitting elements 72 are aligned next to the datum lines 15 (i.e. so the slitting elements 72 are slightly transversely spaced from the datum lines 15). The web 30 is therefore slit along lines spaced from the datum lines 15. The primary slitting controller 64 continuously monitors the transverse position of the datum line 15 and adjusts the relative position between the primary slitting head 68 to ensure that the web 28 is slit in register with (although not along) the datum lines 15, and therefore the print layer as a whole.

Although not described in detail, there is some wastage at the edges of the web 28 that is disposed of.

In another embodiment, the printed datum lines 15 have luminescent properties, such as ultra-violet fluorescent properties. This may mean that the printed datum lines 15 are not visible to the human eye. In such an arrangement, the primary slitting controller 64 further comprise a source or radiation which is arranged to irradiate at least a part of at least one photoluminescent datum line 15 with radiation, such as ultra-violet radiation. This causes the datum line 15 to emit radiation, such as visible light, that can be monitored. As for the arrangement described above, the optical datum monitor 74 monitors the transverse position of the datum 15 and the control unit 78 causes the primary slitting adjuster 76 to automatically adjust the transverse position of the primary slitting head 68 (if necessary) to ensure that the slitting elements 72 are aligned next to the datum lines 15, such that the web 28 is slit along lines spaced from the datum lines 15. Again, this ensures that the web 28 is slit in register with the datum lines 15, and therefore the print layer as a whole.

In this embodiment there are 15 tape slitting stations 80, one for each narrower web 30. Referring now to Figure 10, each tape slitting station 80 comprises a reel holder 82 onto which one of the narrower webs 30 can be loaded, a guide roller 84, a tape slitter 86, a tape slitting controller 88, and six traverse rewinders 90. The tape slitting station 80 is arranged to draw the narrower web 30 through the tape slitter 86 which performs a tape slitting operation to slit the web 30 into six narrower reclose tapes 32 which are each traverse rewound by a rewinder 90 onto a reel. Each reclose tape 32 has a single central adhesive stripe 16 which extends in the web direction and two dry- edge fingerlifts 20, 22 which also extend in the web direction (Figure 2). The tape slitter 86 comprises a tape slitting head 92 and two guide rollers 94. As shown in

Figure 11 , the tape slitting head 92 comprises a plurality, in this case seven tape slitting elements 96 in the form of razor blades (only five are shown in Figure 1 1 ). The tape slitting elements 96 are transversely uniformly spaced from one another and are fixed relative to one another by attachment to a beam 98. It may be possible to manually finely adjust the transverse spacing of the tape slitting elements 92. The tape slitting elements 96 are spaced across the width of the web 30 and the transverse spacing between the centreline of each tape slitting element 96 corresponds to the width of each reclose tape 32, and also to the transverse centreline spacing between adjacent adhesive stripes 16. In this embodiment, the tape slitting elements 96 are spaced by 10mm. As the narrow web 30 is drawn through the tape slitter 86 between the tape slitting elements 96 and the guide rollers 96, the web 30 is slit in the web direction at transverse positions in between adjacent adhesive stripes 16 into six reclose tapes 32 (each having a width of 10mm ). Each reclose tape has a single continuous adhesive stripe 16 and two dry-edge fingerlifts 20, 22. As will be described below, the tape slitting head 92 is moveable in the transverse direction with respect to the web 30 which allows the transverse positions at which the web 30 is slit to be adjusted.

The tape slitting controller 88 comprises an optical adhesive stripe monitor 100 in the form of a camera, a tape slitting adjuster 102 which can adjust the transverse position of the tape slitting head 92 relative to the web 30, and a control unit 104 which is connected to the monitor 100 and adjuster 102. The tape slitting controller 88 also comprises a radiation source 106, in the form of a ultra-violet lamp, which is arranged to irradiate the surface of the web 30, in particular at least one adhesive stripe 16, with ultra-violet light. The tape slitting controller 88 is arranged to automatically control the tape slitting operation such that the web 30 is slit into six reclose tapes 32 in register (i.e. in transverse alignment) with the adhesive stripes 16. This ensures that the web 30 is slit at the desired transverse positions. In this embodiment the tape stilling controller 88 is arranged to control the tape slitting operation such that the web 30 is slit at the mid-point between each pair of adjacent adhesive stripe 16, such that the web 30 is slit into reclose tapes 32 having a central adhesive region 16 and two dry-edge fingerlift regions 20, 22. Slitting in register with the adhesive stripes means that a predetermined and fixed positional relationship is maintained between the slitting positions and the pattern of adhesive stripes 16. It is not necessary that the web 30 slit along lines coincident with the edges of adhesive stripes 16, but in some embodiments this may be the case.

With reference to Figure 12, in use, the ultra-violet light source 106 irradiates the surface of the web 30, in particular at least one of the adhesive stripes 16 which has ultra-violet photoluminescent properties. Since the adhesive stripes 16 have ultraviolet photoluminescent properties, in response to irradiation by ultra-violet light, the adhesive stripes 16 emit visible light and therefore the pattern of the adhesive stripes 16 can be visually observed. In particular, it is possible to clearly identify the edge of at least one adhesive stripes 16. With the web 30 being drawn in the web direction W, the optical adhesive stripe monitor 100 visually monitors the transverse position of the edge of one of the adhesive stripes 16, which is possible because it is emitting visible light. Based on the monitored position, the control unit 104 causes the tape slitting adjuster 102 to automatically adjust the transverse position of the tape slitting head 92 (if necessary) to ensure that the tape slitting elements 96 are transversely aligned with the mid-point between adjacent adhesive stripes 16, along which it is desired to slit the web 30. The tape slitting controller 86 continuously monitors the position of the edge of the at least one adhesive stripe 16 and adjusts the relative position between the tape slitting head 92 and the web 30 to ensure that the web 30 is slit in register with the adhesive stripes. Although not described in detail, there is some wastage at the edges of the web 30 that is disposed of. The tape slitting operation results in six reclose tapes 16, each having a width of 10mm, with a central adhesive stripe 16 having a width of 5mm, and two dry-edge fingerlifts 20, 22 having a width of 2.5mm each (Figure 2). The reclose tapes 32 are traverse wound into a self-would reel of tape.

In this embodiment, slitting in register with the adhesive stripes 16 ensures that the adhesive stripe 16 is centrally located on each reclose tape 32, and therefore the widths of the dry-edge fingerlifts 20, 22 are equal. Since the above described embodiment the tape 32 is of a relatively narrow width of 10mm, and the widths of the fingerlifts 20, 22 is 2.5mm, it is important that the tape slitting is carried out in register with the adhesive stripes 16. For example, a 1.5mm error between the desired slitting locations and the actual slitting locations would cause the fingerlifts 20, 22 to have sizes of 0.5mm and 4.5mm which would have a drastic impact on the quality of the product. Therefore, slitting in transverse register with the adhesive 16 ensures a high- quality end product. Further, the use of a photoluminesceni adhesive for the adhesive stripes 16 means that the adhesive can be clear, whilst allowing it to be irradiated with radiation so that it can be viewed and used as a datum to guide the tape slitting operation. The use of a clear adhesive may improve the appearance of the product. In addition, tape slitting in register with the adhesive stripes by monitoring the transverse position of at least one adhesive stripe means that it is not necessary to control the transverse register between the print layer and the adhesive layer. This may result in a simpler manufacturing process and therefore a reduced manufacturing cost. However, it should be appreciated that in other embodiments it may be desirable to control the register between the print layer and the adhesive stripes.

It has been described that the primary slitting is carried out in register with the printed datum lines (i.e. the print layer) as opposed to in register with the adhesive stripes. This may be possible due to the narrower webs having a larger width than the tapes. The primary slitting operation is therefore less susceptible to small errors in the relative positioning between the slitting head and the web. Of course, in some embodiments the primary slitting operation (where present) may be carried out in register with the adhesive stripes as opposed to in register with the print layer. Although it has been described that the primary slitting controller is arranged to control the primary slitting by transversely moving the primary slitting head relative to the web, it should be appreciated that the relative transverse position between the primary slitting head and the web could be achieved in other ways. For example, the web could be moved transversely with respect to the primary slitting head. Similarly, as opposed to moving the tape slitting head relative to the web, the relative transverse position between the tape slitting head and the web could be adjusted by transversely moving the web relative to the tape slitting head. It has been described that the manufacturing process includes printing, coating, primary slitting and tape slitting, and that there are corresponding stations for carrying out each process. However, it may be the case that in some embodiments not all processes are carried out, or the processes could be combined or carried out at different manufacturing sites. For example, in one embodiment there may only be a tape slitting station which slits a web into a plurality of tapes. In such an embodiment the web may not be printed (i.e. it could be clear), and it may be pre-supplied with the release and adhesive coating. In other embodiments, the web may be printed at one site, adhesive and release coatings could be supplied at another site, and then the web may be slit into tapes in a tape slitting operation, without the need for primary slitting.

In the foregoing description a method and apparatus for manufacturing a reclose tape has been described. However, it should be appreciated that the method and apparatus may be suitable for manufacturing other types of tape. For example, it may be used to manufacture a permanent adhesive tape having one or more longitudinally extending dry-edges. Such a tape could be used for a variety of applications, for example it could be applied to packaging and used to tear through, or off, packaging to open it.

It should be appreciated that the dimensions given are only exemplary and other suitable dimensions could be chosen. The original web may have any suitable width and may be slit directly into a suitable number of tapes having any appropriate width, or into any number of narrower webs, again having any suitable width. Further, the width of the adhesive stripes and the spacing between them may be chosen depending on the application. The spacing and width chosen for the adhesive stripes, together with the transverse position at which slitting occurs will determine the size (or width) and number of dry fingerlift edges.