GUTTER CENTERED DIE-CUT FOR IMPROVED SEPARATION OF ADHESIVE SIGNAGE

Abstract
A process for cutting column and row gutters on multilayer signage media into individualized signage cards includes placing pre-die-cut slits at predetermined locations within the column gutters to assist a cutter in cutting completely through the multilayer signage media.
Description
BACKGROUND

The present disclosure relates to a process of cutting adhesive signage for store shelving, and more particularly, to an improved method for cutting sheets of multilayer substrates into individualized signage members.


A general background for marketing signage for in-store shelving can be found in U.S. Pat. No. 8,302,338, but the current process being used to create adhesive signage for store shelving involves a multilayer adhesive substrate that includes a very robust polymer carrier along with paper and adhesives that make the substrate difficult to cut.


Multilayer substrates currently used are fully backed media consisting of five layers: 1) a top printable paper; 2) a permanent adhesive; 3) a polymer carrier; 4) a pressure sensitive adhesive; and 5) a release liner. The multilayer adhesive substrates add needed strength and can be cut into predetermined sized cards for store shelving through cutting column and row gutters on the substrates, but gutter cutting issues can be experienced when any of the materials or cutting equipment varies from their optimal nominal states, for example, thicker carrier, thicker paper, more adhesive, dulling blades, blade spacing, etc. In addition, cutting difficulties can be experienced when in-line column secondary cuts are made into the substrates through primary orthogonal cuts already made in the substrates because stress concentration points are encountered at locations where the secondary cuts cross the primary cuts creating stress concentration points that are difficult to cut cleanly. As a result of the heretofore-mentioned cutting difficulties, some cards can remain adhered to the adjacent gutter after the cutting operation leaving the gutter not fully separated from a card which can lead to machine jams.


Obviously, there is a need for an improved process for cutting polymer lined fully backed adhesive signage stock for store shelving while simultaneously ensuring that a card where a secondary cut is initiated separates from an adjacent card.


SUMMARY

Accordingly, an answer to this need is disclosed herein that incorporates a two-step cutting method to ensure that the polymer carrier is slit and the cards are separated from column gutters effectively prior to being transported into a collection tray. A pre-die-cut slit is first placed at the bottom of each card creating a stress concentration point in the column gutter in order to back up a blade initiated portion of the cut. A blade cut is then initiated into gutter columns of the polymer carrier and If the blade fails to initiate a clean cut at the bottom of a card, the pre-die-cut slit will ensure that there is still a full separation of the card and gutter at the pre-die-cuts. Without this pre-die-cut system of slits, the gutter cut initiation will be at risk as media and cutting parameters migrate away from nominal and as stress concentration points are encountered. And with the pre-die-cut slit arrangement, the gutter cut initiation and card/gutter separation is ensured.





BRIEF DESCRIPTION OF THE DRAWINGS

Various of the above-mentioned and further features and advantages will be apparent to those skilled in the art from the specific article or methods described in the example(s) below, and the claims. Thus, they will be better understood from this description of these specific embodiment(s), including the drawing figures (which are approximately to scale) wherein:



FIG. 1 is a plan view of a card collection system;



FIG. 2 is a plan view of a polymer lined fully backed adhesive signage media containing column and row gutter placements therein;



FIGS. 3A is side view of a cutter with a blade that has been moved into a groove and cutting position within a mating member and in FIG. 3B the cutting blade has been moved into a non-cutting position with respect to the mating member;



FIG. 4 is side views of a cutter with a stationary positioned rotary blade inserted into a groove and cutting position in a stationary positioned rotary mating member; and



FIG. 5 is a plan view of a polymer lined fully backed adhesive signage media containing column and row gutter placements with pre-die cut slit placements therein at secondary cut stress concentration points.





DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

For a general understanding of the features of the disclosure, reference is made to the drawings. In the drawings, like reference numerals have been used throughout to identify identical elements.


In FIG. 1 a card collection system 10 is shown in which card images printed on substrate 110 are outputted from a printer 12 onto a conveyor 14 positioned lengthwise and forwarded into an articulating slitter 30 that is movable between cutting and non-cutting positions. In the cutting position slitter 30 places slits 32 across a portion of card sheets 110 and conveyor 15 conveys the sheets into a second stationary cutter 40 which then cuts the card sheets into individual cards 114 and forwards them into a collection station 60.



FIG. 2 is a schematic top view illustration of multilayer substrate 110 that includes paper 112, adhesives (not shown) and a polymer carrier 113 and release liner (not shown). Cutting multilayer substrate 110 into multiple cards for placement onto store shelving is sometimes met with cutting issues when blades of the cutting equipment varies from their optimal nominal states due to thicker polymer carrier, thicker paper, more adhesive, dulling blades or blade spacing. Substrate 110 includes orthogonal row gutters 125 for access by articulable first cutter 30 and in-line column gutters 130 to be accessed by stationary second cutter 40. Die cuts 120 are placed at the leading and trailing edges of the substrate in order for the slitter blades of the first cutters to cut strips up to the point of the die cuts 120 and this will facilitate a clean cut. As shown in FIG. 3A, conventional cutter 30 includes a rotary blade 34 that has been moved into a groove in stationary rotating member 36 for engagement with substrate 110 of FIG. 2 orthogonal to a lengthwise dimension of the substrate and is lifted away from the substrate as shown in FIG. 3B after slitting gutter 125. A second conventional cutter 40 in FIG. 4 includes a stationary rotating blade 42 positioned to extend into a groove in mating member 44 in order to cut through the bottom of the substrate 110 in-line with a lengthwise dimension of the substrate and the resulting separate cards 114 from the cutting are then forwarded into separate bins at collection station 60. Blade 42 is met with enhanced resistance when in-line column gutter cutting is initiated in non-rigid, flexible and unsupported polymer carrier 113 and release liner portion of the substrate where a previous orthogonal cut has been made preventing cards 114 from completely separating at the blade entry point. Occasionally, this results in some cards remaining adhered to or not fully separated from the adjacent gutter after the secondary cutting operation and if delivered to the collection station in this state jams can be created in separate bins of the collection station.


To counter the heretofore-mentioned gutter cutting issues and in accordance with the present disclosure, FIG. 5 is shown that includes placing pre-die-cut slits 220 at projected difficult to cut points in substrate 110 in the bottom of the substrate to create a pre-arranged stress concentration point needed to ensure that polymer carrier 113 of substrate 220 is completely slit by stationary cutter 40 and the cards cut from the substrate are removed effectively from each other prior to being transported to the collection tray 60. By placing pre-die-cut slits 220 at the bottom of each card in the ⅛″ gutter and creating a stress concentration point, difficulty in cutting at the flexible polymer carrier/release liner flexible unsupported points created where the in-line cuts intersect with previous orthogonal cuts is addressed while the blade 42 initiated portion of the cut is simultaneously backed up by the pre-die-cut slits thereby ensuring that if the gutter blade fails to initiate a clean cut at the bottom of the card, the pre-die-cut slit will ensure that there is still a full separation between each card and gutter at the pre-die-cut. Pre-die-cut slits 220 in substrate 110 are preferably positioned to extend through an upper end of one card and into a bottom portion of another card above it. The pre-die-cut slits will create a stress concentration in substrate 110 to allow stationary rotary cutter 40 to consistently cut the cards from bottom to top lengthwise when there is the flexible initial area in polymer carrier 113 caused by the previous gutter cut made by articulating cutter 30.


In recapitulation, a method for improved separation of individual signs cut from multilayer substrates includes placing pre-die-cut slits in gutter areas of the signs. The pre-die-cut slits compensate for cutting difficulties created at the bottom of the signs where there is a flexible unsupported polymer carrier and release liner in the signs produced by gutter cutting the signs first in a widthwise direction and then when it is subsequently necessary to cut the signs in a lengthwise direction during the second fixed rotary cutting operation. The pre-die-cut slits align with the gutter cutting operation in the lengthwise direction. This ensures that when the signs go through the gutter cutting blades the signs and adjacent gutter will separately cleanly from each other every time even if the gutter blades fail to fully cut at the bottom of the signs.


The claims, as originally presented and as they may be amended, encompass variations, alternatives, modifications, improvements, equivalents, and substantial equivalents of the embodiments and teachings disclosed herein, including those that are presently unforeseen or unappreciated, and that, for example, may arise from applicants/patentees and others. Unless specifically recited in a claim, steps or components of claims should not be implied or imported from the specification or any other claims as to any particular order, number, position, size, shape, angle, color, or material.

Claims
  • 1. A method for cleanly separating cards cut from adhesive signage for store shelving, comprising: providing multilayer substrates that include paper, a permanent adhesive layer, a polymer carrier, a pressure sensitive adhesive, a release liner and images of multiple cards;providing column gutters on said multilayer substrates;providing row gutters on said multilayer substrates;providing a cutter with articulating blades for placing cuts into said multilayer substrates through a top surface of said substrates within said row gutters;providing a stationary cutter for cutting through a bottom surface of said substrates within said column gutters to create multiple cards; andproviding pre-die-cut slits in portions of said paper, polymer carrier and release liner of said multilayer substrates within said column gutters in order to ensure that cuts from said stationary cutter completely separate said column gutters.
  • 2. The method of claim 1, wherein said pre-die-cut slits within said column gutters of said multilayer substrates extend from a portion of said polymer carrier into a portion of said paper of said multilayer substrates.
  • 3. The method of claim 2, wherein said pre-die-cut slits compensate for cutting difficulties created at said bottom surface of said multilayer substrates where flexible unsupported polymer carrier and release liner portions in said multilayer substrates are produced by gutter cutting said multilayer substrates first in a widthwise direction with said articulating blades and subsequently in a lengthwise direction with said stationary cutter.
  • 4. The method of claim 3, including conveying cards cut from said multilayer substrates to a collection station.
  • 5. The method of claim 3, wherein said pre-die-cut slits align with cuts from said stationary cutter through said bottom surface of said substrates.
  • 6. The method of claim 5, wherein said pre-die-cut slits in said multilayer substrates are between cards on said multilayer substrates.
  • 7. The method of claim 6, wherein stationary cutter includes blade initiated cuts and wherein said pre-die-cut slits within said column gutters backs up said blade initiated cuts of said stationary cutter to ensure that there is complete separation of card and gutter at said pre-die-cut slits.
  • 8. The method of claim 1, including using said pre-die-cut slits to create a stress concentration in said multilayer substrates to allow said stationary cutter to consistently cut said multilayer substrates from bottom to top lengthwise due to a flexible initial cut area within said polymer carrier resulting from said articulating cutter cut.
  • 9. The method of claim 8, including cutting said multilayer substrates with said stationary cutter in a direction orthogonal to cuts provided in said multilayer substrates by said articulating blades.
  • 10. A method for providing consistent separation of cards created from media, comprising: providing multilayer media for cutting into multiple individual cards, said multilayer media including paper, a permanent adhesive layer, a polymer carrier, a pressure sensitive adhesive, a release liner and images of multiple cards on said paper;providing column gutters and row gutters on said multilayer media;providing a first cutter for cutting said multilayer media along said row gutters;providing a second cutter for cutting said multilayer media along said column gutters;cutting only said polymer carrier and said release liner within said row gutters with said first cutter;afterwards cutting said paper and polymer carrier within said column gutters with said second cutter; andproviding pre-die-cut slits within said paper and polymer carrier of said multilayer media at predetermined locations to assist said cutting by said second cutter and thereby ensuring that said multilayer media is completely separated into multiple individual cards.
  • 11. The method of claim 10, including extending said pre-die-cut slits from a portion of said polymer carrier into a portion of said paper only.
  • 12. The method of claim 11, wherein said first cutter has articulating blades.
  • 13. The method of claim 12, wherein said second cutter has stationary blades positioned to cut through a bottom surface of said multilayer media.
  • 14. The method of claim 10, wherein said cutting of said polymer carrier and release liner with said first cutter creates a non-rigid, flexible and unsupported portion of said multilayer media, and wherein said pre-die-cut slits at said predetermined locations within said multilayer media create stress concentration within said multilayer media in order to facilitate cut initiation into said polymer carrier and release liner by said second cutter and thereby ensure consistent cuts of said non-rigid, flexible and unsupported portion of said multilayer media from bottom to top lengthwise by said second cutter.
  • 15. A process for cutting adhesive signage for store shelving, comprising: providing a multilayer substrate that includes paper, a permanent adhesive layer, a polymer carrier, a pressure sensitive adhesive and a release liner;providing column gutters and row gutters on said multilayer substrate;providing an articulating blade cutter for cutting said multilayer substrate along said row gutters;cutting said polymer carrier and said release liner without cutting said paper within said row gutters with said articulating blade cutter;providing a stationary cutter for cutting said multilayer substrate along said column gutters;cutting said paper, polymer carrier and release liner within said column gutters with said stationary cutter; andproviding pre-die-cut slits within said column gutters of said multilayer substrate at predetermined locations to assist said cutting by said stationary cutter and thereby ensuring that said multilayer substrate is completely separated into multiple individual cards.
  • 16. The process of claim 15, wherein said paper only partially covers said polymer carrier of said multilayer substrate.
  • 17. The process of claim 16, wherein cutting of said polymer carrier and release liner in non-paper areas with said stationary cutter through said pre-die-cut slits creates a flexible and unsupported polymer carrier and release liner portion of said multilayer substrate.
  • 18. The process of claim 17, wherein said pre-die-cut slits create stress concentration in said polymer carrier and release liner to facilitate initial cuts of said stationary cutter cutting through said multilayer substrate bottom to top.
  • 19. The process of claim 18, wherein said pre-die-cut slits extend from a paper portion into a paperless portion of said polymer carrier of said multilayer substrate.
  • 20. The process of claim 19, wherein said pre-die-cut slits align with cuts by said stationary cutter through said bottom surface of said multilayer substrate.
Parent Case Info

Cross-referenced and included herein by reference is commonly assigned U.S. application Ser. No. 15/358,317 Docket No. 20161075US01, filed Nov. 22, 2016, and entitled SEQUENTIAL DIE-CUT AND SLITTING FOR IMPROVED COLLATION by Douglas K. Herrmann et al.