CA1204998A - Laminated tape - Google Patents

Abstract

ABSTRACT OF THE DISCLOSURE
A laminated tape for manufacturing figures of desired shape comprising a first film layer of a relatively soft and flexible material capable of being cut by an elongated cutting ridge of a cutting die and a second film layer disposed in face-to-face relationship with respect to the first film layer for supporting the first film layer. The first film layer is constructed of a material having tensile strength of no greater than about 1000 pounds per square inch.

Description

~2~39~3 T;tle: Laminated Tape 1 BACKGROUND O~ T~l~ INVENTION
lhe present invention relates generally to a laminated t~pe and more particularly to a laminated tape usable in connection witb the manufacture of figures or characters of desired shape or the stencils for such figures or characters. The present invention also relates to a method of using such laminated tape in the manufacture of such figures or characters and application of the same to the desired medium.
Various devices and techniques presently exist in the prior art for cutting letters or figures of other shapes and transferring the same to a desired medium. Prior art also exists in which a laminated tape includes a top layer adapted to transmit a cutting force from a cutting die to a cuttable intermediate layer and a bottom base layer. Such a laminated tape is described in the Massari Patent No. 3,558,425. The laminated tape described in this patent includes an upper, relatively thin `and highly flexible carrier layer which stretches and serves to transmit the cutting force of a cutting die to an intermediate layer.
miS intermediate layer is positioned below the upper layer and is a highly inflexible and hard material such as cellulose acetate which is susceptible of being cut by the cutting forces transmitted through the upper layer. A bottom layer of this laminated tape consists of a relatively hard material. Although the lan~nated tape of the above-mentioned Massari patent is satisfactory in many respects, its usefulness is limited because of the relatively high cutting force needed to cut the intermediate layer. Ihis high cutting force is a direct result of the highly inflexible and hard intermediate layer required in the Massari laminated tape structure. me high cutting forces in turn necessitate the use of generally hard cutting materials such as steel, thus dramatically increasing the cost of the cutting equip~ent and thereby limiting the potential use of the laminated tape. Accordingly, a need has existed, and continues to exist, for a laminated tape structure 4~9~

1 having a cuttable layer with the toughness and strength to resist tearing, etc. during manufacture or use as well as being soft and flexible enough to dramatically reduce the cutting forces needed to manufacture the figure of desired shape. Such a laminated tape would eliminate the necessity for relatively hard cutting materials such as steel and thereby significantly reduce the cost of the cutting equipment and increase the use of the laminated tape.
SUMMAR~ OF THE INVENTION
Ihe present invention relates to a laminated tape for manufacturiog figures or characters of a desired shape having a first film layer comprised of a relatively soft and flexible material. This material has proper~ies which enable it to be cut by a cutting die in which the cutting force is significantly less than the forces which havP
; heretofore been required in the prior art. A second film layer i9 disposed adjacent to the first layer to carry and provide support for tbe first layer during the cutting process. In the preferred embodiment, the first layer includes an adhesive material on the surface adjacent to the second layer so that the figures or characters, after they are cut, can be removed and applied to the desired medium.
Although the structure of the laminated film of the present invention is similar in some respects to the laminated tape structure described in the Massari patent mentioned above, the composition and physical characteristics of the first layer susceptible of being cut is dramatically different. In fact, the physical characteristics of the cuttable first layer of the present invention are virtually opposite that of the cuttable layer in the Massari structure. For example, the Massari intermediate layer is defined as being hard, brittle and highly inflexible. In contrast, the cuttable first layer of the present invention is a very soft, elastic and highly flexible material. In the preferred embodiment, it has been found that a first film layer constructed of a polyurethane material provides the desired physical characteristics.

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1 In one embodiment of the present inventioQ, a third or transfer film layer is disposed adjacent to the second layer on the side opposite that of the first layer. This third layer can be constructed of a variety of materials; however, it includes one surface which has a relatively low tack adhesive. Preferably, this surface is adjacent to the second layer. The function of this third or transfer layer i8 to facilitate the separation of the cut figures from the background portion of the first layer and to appropriately position said figures for placement on the desired medium.
In a second embodiment of the present invention, this third or transfer layer is not supplied adjacent to the second layer, but is supplied separately and preferably in roll form. Similar to the third layer supplied adjacent to the second layer, this material supplied in roll form includes one surface with a relatively low tack adhesive for facilitating the removal of the cut figures or characters from the first layer and for positioning the same with respect to the desired medium.
In a still further embodiment of the present invention, this third layer is disposed adjacent the first layer on the side opposite the second layer so that the cutting force of the cutting dies is transmitted through this third layer before cutting the ~igures from the first layer.
The method of using the laminated tape of the present invention includes cutting the figure of desired shape in the first layer of the tape, placing a length of the third layer or transfer tape over the cut figures, removing the cut figures from the first layer and applying the same to the desired medium.
Accordingly, a primary object of the present invention is to provide a laminated tape for manufacturing figures of desired shape in which the cuttable layer i 8 a material which reguires dramatically less cutting force than the laminated tape structures of the prior art.
Anotber object of the present invention is to provide an improved laminated tape for manufactu}ing figures of desired shape in ~LZ~ 98 1 which the layer susceptible of being cut is a soft and highly flexible material such as a polyurethane.
A further object of the present invention is to provide an improved laminated tape having a fisst cutable layer and a second support layer and which further includes a third layer provided either adjacent to the support layer or supplied separately tG facilitate the removal of the cut figures from the flrst layer and to position the same with respect to the desired medium.
A still further object of the present invention is to provide an improved method for manufacturing figures of desired shape from a laminated film and applying the same to a desired medium.
Another object of the present invention is to provide an improved laminated tape having a soft and highly flexible layer and usable in the manufacture of stencils.
These and other objects of the present invention will become apparent with reference to the drawings, the description of the preferred embodiment and the appended claims.
DESCRIPTION OF THE DRAWrLNGS
Figure 1 is a sectional view showing one embcdiment of the laminated tape of the present invention.
Figure 2 is a sectional view showin~ an alternate embodiment of the laminated tape of the present invention.
Figure 3 is a sectional view showing a further alternate embodiment of the laminated tape of the present invention.
Figure 4 is a sectional view showing a fur~her alternate embodiment of the laminated tape of the present lnvention.
Figure 5 is a sectional view of one embodiment of tbe transfer tape usable with the laminated tape illustrated in Figure 1.
Figure 6 is a pictorial ~iew showing the laminated tape with the characters ha~ing been cut from the top layer.

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l Figure 6a i5 a pictorial view showing the transfer tape in posit~on to remoye the cut-out characters ~ro~ t~e laminated tape.

Figure 7 is a pictorial vie~ showing the cut out figures after having been transferred to tbe transfer tape.
Figure 8 is a pictorial view showing the method of applying the cut out figures to the desired medium.
Figure 9 is an elevational view, partially in section, showing the mechanism for applying the cutting force to the laminated tape.
Figure 10 is a pictorial view of the cutting die in the form o a lettering chip.
Figure 11 is a sectional view of a portion oE the lettering chip as viewed along the section line 11-11 of Figure 10.
DESCRIPTION OF THE PREFERRED EMBODIMENT
Reference is first made to Figures 1-4 showing various embodiments of the laminated tape of the present inventlon. Although these embodiments illustrate various combinations of laminated structures, they all include a first film layer 10 comprised of a relatively soft and highly flexible material capable of being cut by a cutting ridge of a cutting die. Each of these embodiments also includes a second film layer 11 funceioning to support or carry the first layer 10. This second layer ll is not cut during the cutting procedure. Each of the embodiments of Figures 1-4 also includes a third film layer functioning as a transfer tape to transfer the cut out figures from the first layer 10 to a desired medium. In the embodiment of Figure 2, this third layer is designated by the reference numeral 12, whereas in the embodiments of Figures 3 and 4, this third layer is designated by the reference numeral 13. With respect to the embodiment of Figure l, the third layer is supplied separately from the roll of transfer tape 22 illustrated in Figure 5. The transfer tape itself is designated by the reference numeral 14.
As will be described in greater detail below, the first layer lO

~204~8 1 of each of the embodiments illustrated in Figures 1-4 is capable of being cut by an elongated cutting ridge of a cutting die. In general, the phy~ical characteristics of this first layer 10 i8 thst it is a relatively soft and flexible material. Although it is contemplated that various types of synthetic polymers such as epoxys, acrylics, vinyls and polyesters may be formulated so that they exhibit the desired physical characteristics of tbe first layer 1~, the first layer 10 of the preferred embodiment is constructed of a low energy, cuttable polyurethane. It has been found, through testing nd experimentation, that a first layer constructed of such a polyurethane provides the desired physical properties of softness and flexibility and provides material whish is capable of being cut at dramatically lower cutting forces than is needed in prior art devicefi.
One of the primary advantages of the softness and flexibility of the first layer 10 is that it is cuttable with a relatively low force by a cutting ridge of a cutting die. Tha particular magnitude of this cutting force is one par~meter which has been used by the inventor to define the desired characteristics of the first layer 10. A second parameter used is that of tensile strength, na~ely, the ~orca needed to fracture a piece of the material by pulling two ends of the material in opposite directions. During the development of the present invention, a test was devised to determine the forca needed to cut through a particular layer of material. This test waQ performed using a Model QC
Electronic Tensile Tester manufactured by m wing-Albert Instr~ment Company of Philadelphia, Pennsylvania. This device was provided with a 500 pound load cell and a compression fixture to enable a compression cutting force to be exerted. A cutting die similar to the lettering chip 29 illustrated in Figure 10 was also utilized. Such cutting die included a continuous cutting rid8e 35 of finite length. As illustrated in Figure 11~ the generally wedge shaped continuous cutting ridge 35 includes a ~Z04~

l cutting point or edge 39 and a pair of side surfaces disposed at an included angle "~" with respect to each other of approximately fifty degrees (50).
In the test apparatus, the lettering chip 29 and cutting ridge 35 was constructed of a high impact molded plastic designated as Plexiglass DR
~,'f~`l' 61K and manufactured by Rohm & Haas Company of Philadelphia, Pennsylvania. A urethane pad of Hardness 61-64 Shore C was provided to resist the cutting force. The testing device further included means for applying and recording a given force to the cutting die.
- Samples of various materials and polymer formulations were then inserted into the compression test fixture between the cutting ridge of the cutting die and the urethane pad and a cutting force was applied until the material had been cut. The force at which a 100~ cut occurred was recorded aod a force per linear inch of the cutting ridge was calculated. As a result of these force tests, it was determined that to obtain the advantages of the present invention and to exhibit the necessary and desired characteristics of softness and flexibility, the first film layer 10 had to be constructed of a material which could be cut by a cutting force of no greater than about 250 pounds per linear inch of cutting ridge. It is also contemplated that the first layer 10 should be at least about one mil (0.001 inches) thick. Materials greater than the above thickness which require a cutting force greater than 250 pounds per linear inch, such as the cellulose acetate and materials having similar properties disclosed in the Massari Patent No. 3,558,425, do not provide the desired benefits since those materials require significantly different and more expensive types of cutting apparatus to cut the first layer 10. When the above test was applied to a piece of cellulose acetate 0.95 mil (0.00095 inches) thick, the testi~g apparatus wbich had a maximum loacl capability of 500 pounds, could not cut the sample. Thus, the cutting forre needed for this sample of cellulose`
acetate was substantially greater than 500 po~mds per linear inch.
Obviously, cellulose acetate or similar material with a thickness greater ~ ~ Q ~ ~ ~ ~

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1 than one mil tO.001 inch~ would require still greate~ cutting forces.
Preferably, the first film layer 10 is construc~ed of a material which can be cut by a cuttin~ force of between about 125 and 175 pounds per linear inch of cutting ridge.
The inventor has also determined that the tensile strength of a particular muterial i9 generally linearly related to the cutting force determined in the test described above. Tensile strength of a mAterial is conventionally determined by The American Society for Te~ting and Materials (ASTM) test D882. In this test, stress i~ applied to a material in a pulling fushion until it bre~ks. Tensile strength i8 calculated by dividing the maximum load ~force) by the original cross-sectional area of the sample. The result is expressed in pounds per square inch.
Tensile strength determinations were made on various material~
and formulations which confirmed the generally linear relutionship between tensile strength and cutting force. While this generally linear ; relationship is expected to vary somewhat for different kinds and formulation~ of material, it was determined that the tensile strength of the ~aterial from which the first layer is constructed should be no greater than about 1000 pounds per square inch and preferubly no greater .. . . . . . . . .. ..
tfian about 50Q pQunds-pe~ sq~are inch. Tensile st~ength deter~inations conducted with respect to a sample of cellulose acetate 0.~5 ~ils (O.OQ035 inc~es) th~c~ resulted in a tens~le strength DE absut lO,Q00 p.s.i.
Accordingly, to achieve the benefits and advantages of the presen~ invention, the first layer 10 which is cuttable must be constructed of a material which is relatively soft and flexible und capable of being cut by an elongated cutting ridge of a cutting die.
Further, the material of the first layer 10 should have a tensile strength of no greater than 1000 pounds per square inch. The material should also be ~uch that a cutting force of no more thun about 250 pounds lZ~98 1 per linear inch of the cutting ridge will cut the first layer 10.
Preferably the first layer 10 should also be at le~st one mil (0.001 inch) thick.
As indicated above, the first film layer 10 of the preferred embodiment is a urethane film formed by reacting an isocyanate monomer witb one o~ more polyols. Specifically, the isocyanate monomer is a hexamethylene diisocyanate having an isocyanate equivalent weight of about 190. The preferred polyols include a polymeric vinyl ester acrylic copolymer ~0% solids) with a hydroxyl equivalent weight of about 400; a hydroxyl functional acrylic copolymer with a hydroxyl ea~ivalent weight of about 300; a saturated polyester resin with a hydroxyl equivalent weight of about 1135; DB castor oil havin~ a hydroxyl value of about 164, and a polyoxypropylene polyether having a hyroxyl equivalent weight of about 125. A catalyst such as organo tin and pigments are also added in the preferred system. Preferably, the index or ratio of isocyanate equivalence to hydroxyl equivalence is about 0.7 to 0.9 with the optimum being about 0.8.
With reference again to Figures 1-4, a second layer 11 is disposed adjacent to and in face-to-face relationship with one surface of the first layer 10. The physical properties of this second layer 11 are not as important as the proper~ies of the first layer 10 since its primary function is to provide support for and carry the first layer 10 during the cutting procedure. Accordingly, the second layer 11 can be constructed of a variety of materials such as materials having a paper base or polymer films such as polyesters or polyethylenes. Also, in general, the second layer 11 should be relatively hard and inflexible compared to the first layer 10 and should also be relatively non-elastic, to preclude the laminated film from being stretched and deformed prior or subsequent to the cutting procedure. In comparison to the first layer 10, the second layer 11 should have ~ tensile strength greater than 1000 ~z~9~

1 pounds per square inch. Also, the second layer 11 should not be capable of being cut by a cutting ridge at cutting forces less than 250 pounds per linear inch.

As illustrated, the lower surface of the first layer 10 which is adjacent to the second layer 11 is provided with an adhesive coating 15.
The corresponding surface of the second layer 11 is provided with a release liner or coating 16 to permit portions of the first layer 10 to be removed or stripped from the second layer 11 when desired. Following removal, as will be described in greater detail below, these portions of the first layer 10 are positioned onto the desired medium and retained in such position by the adhesive coating 15. Accordingly, the adhesive coating 15 should be quite aggressive. In the preferred embodiment, the adhesive 15 is a generally available hot melt acryl;c or water base adhesive. The specific tack or aggressiveness of the adhesive is measured by a peel test which involves placing a one-half inch wide strip - of material backed with the particular adhesive in question on a substrate consisting of 1000 H Vellum drafting stock. After applying the strip witb a four pound roller and waiting fifteen minutes, one end of the strip is then gripped and peeled back at 180. The force needed to accomplish ~this peel is indicative of the tack or aggressiveness of the adhesive. Using this test, the preferred tack of the adhesive 15 should be ~bout 50-100 grams per 1/2 inch for a low tack application and about 200-250 grams per 1/2 inch high tack application. The low tack is used primarily when preparing stencils, whereas the high tack is used when the adherence is inteDded to be permanent.
The release coating 16 can also consist of a variety of materials. In the preferred embodiment, however, the coating 16 is a silicone coating applied to the top surface of the second or support layer 11.
Each of the embodiments illustrated in Figures 1-4 also includes an associated third or transfer film layer. The primary function of this 1 third layer is to facilitate the tran3fer of the cut-out figures, or the stencil as the case may be, to the desired medium. In the embodiment of Figure 2, this third or transfer layer is illustrated by the reference numeral 12 and i9 disposed adjacent to the side of the first layer 10 opposite that of the second layer 11. In this particular embodiment, the third layer 12 must be constructed of a generally flexible, hard and elastic material which enables it to be stretched without being cu.
during application of the cutting force. In Figure 2, the third layer 12 is utilized to transmit the cutting force of the cutting die to the first layer 10 to cut the first layer 10 into the desired characters or figures. The material from which the third layer 12 in Figure 2 i8 constructed is a material such as a polyester or polyethylene. Although this layer 1~ of Figure 2 can be constructed of a variety of materials3 it must have the necessary flexibility, elAsticity and toughness to prevent it from being cut by a cutting force of less th~n 250 pounds per linear inch in accordance with the cutting force test previously described.
In the embodiment of ~igure 2, the surfaca of the third layer 12 adjacent to the first layer 10 is provided with a low tack adhesive layer 17 to facilitate removal of portions of the first layer 10 from the second layer 11. In such embodiment, the first layer 10 is provided with a release coatin~ or surface 18 to allow removal of the ~hird layer 12 after the cut-out figures have been secured to the desired medium. ~le adhesive coating 17 can be any common low tack adhesive ~uch as, for example only, those having a vinyl, acrylic or urethane base. The release coating 18 can be any common release coatin~ such as silicone, teflon or fluorocarbons, or can in some cases be nothing more than the top surface of the first layer 10. In the preferred embodiment, the adfiesiye 17 has a tack of less than ahout fifty grams per one~half inch as measured by the test described above.

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l In the embodiments of Figures 3 and 4, the third layer or transfer tape i8 design~ted by the reference num~ral 13. In th~se embodiments, the third layer 13 is dispos~d adjacent to the surface of the second layer 11 opposite that of the first layer 10 and remains in this position during tbe cutting procedure. As will be described in greater detail below, after the cutting procedure, the third layer transfer tape 13 is removed and placed adjacent the first layer 10 to transfer the cut-out figures from the first layer 10 to the desired medium. The third layer or transfer tape 13 illustrated in Figures 3 and 4 can be constructed of a variety of materials since its only function, in these particular embodiments, is to facilitate the trans~er of tbe cut-out characters from the first layer 10 to the desired medium.
Preferably, however, the third layer 13 in the embodiments of Figures 3 and 4 is constructed of a polyester, polypropylene, acetate, polyethylene or paper base material.
Similar to the third or transfer layer 12 of Figure 2, the third layer 13 of Figures 3 and 4 is provided with a low tack adhesive coating 20. This coating 20 has generally the same characteristics and tack as the coating 17 of Figure 2 and performæ the same function of facilitating removal of cut-out portions of the first layer 10 from th* second layer 11. In the embodiment of Figure 3 a release liner or coating 19 is provided on the surface of the second layer 11 adjacent to the third layer 13, while in the embodiment of Figure 4, the release characteristics are inherent in the second layer 11 itself.
In the embodiment illustrated in Figure 1, the third layer or transfer tape is provided rom a separate spool 22 as shown in Figure 5 and designated by the reference numeral 14. When using the laminated tape of Figure 1 and the third layer or transfer tape 14 of Figure 5, the transfer tape 14 is utilized in the samP manner as the transfer tape 13 in Figures 3 and 4 after the cutting procedure has been completed. Also, similar to the third layer or transfer tape 13 of Figures 3 and 41 the l sole purpose of the transfer tape 14 i8 to assist in transferring the cut-out figures from the first layer 10 to the desired medium.
Accordingly, it can be constructed of the same material as the third layer 13 of Figures 3 and 4. ~he transfer tape 14 in Figure 5 is also provided with a low tack adhesive 21. Ihis adhesive has generally the same characteristics and tack as the adhesive coating 17 of Figure 2 and the adhesive coating 20 of Figures 3 and 4 and performs the same function of facilitating removal of cut-out portions o~ the first layer 10 from the second layer 11.
In the cutting procedure associated with the laminated tape of the present invention, the first layer 10 of Figures 1-4 is cut by a cutting die in the form of the lettering chip 29 illustrated in Figure 10. As shown in Figure 10, and also in Figure 11, the cutting die includes a generally wedge-shaped, continuous cutting ridge 35 having a continuous cutting point or edge 39 (Figure 11). In the preferred embod-iment, this lettering chip 29 is constructed of a high impact molded plastic material such as Plexiglass DR 61K ~anufactured by Rohm & ~aas Com?any of Philadelphia, Pennsylvania. It is contemplated, however, that different types of materials can also be used. The lettering chip 29 includes a tab 38 to facilitate handling the chip 29 and a plurality of alignment indicia 36 to facilitate proper alignment of the character or figure 35 to be cut.
Figure 9 illustrates one embodiment of a means for applying a cutting force to the lettering chip 29. A structure of this type is known in the art. In general, however, it includes a pair of support rails 34 (only one of which is illustrated in Figure 9) and a generally wedge shaped force generating segment rotatably mounted near its pointed end to a roller member 32 adapted for rolling movement along the support rails 34. The upper, curved surface of the wedge-shaped segment 30 includes a pad 31. This pad may be constructed of a rubber or plastic material with some resiliency. In the preferred embodiment, the pad is a ~L2a~

1 urethane pad having a hardness of approximately 61-64 Shore C. The device illustrated in Figure 9 also includes a pair of chip alignment members 28, 28 and a cutting force resisting means 26. As shown, the cutting die or lettering chip 29 is positioned within the alignment and retaining tabs 28, 28 and the segment 30 is caused to roll against the bottom surface of the lettering chip 29 containing the cutting ridge 35 by moving the roller 32 from one end of the support rails 34 to tbe other. During the cutting procedure, the laminated tape comprising at least the first layer 10 and the second layer 11 is disposed between the urethane pad 31 and the bottom surface of the lettering chip 29. Then, as the roller segment 30 is rolled from one end to the other, the cutting force is applied between the urethane pad 31 and the lettering chip 29.
This cut~ing force is sufficient to cut only the first layer 10, while lea~ing the second layer 11 uncut.
It should be noted that in Figure 9 the laminated tape being cut is similar to that of Figure l. If the laminated tape of Figure 2 is cut, the cutting force applied to the cutting ridge 35 is transmitted through the third layer 12 (Figure 2) to the first layer 10 which is then cut. If the embodiment of Figures 3 and 4 is cut, the cutting ridge 35 cuts only the first layer 10 without cutting either the second layer ll or the third layer 13.
After tbe cutting procedure, the laminated tape is then removed from the cutting apparatus and the cut-out figures or characters from the first layer 10 are transferred to the desired medium. This transfer procedure is illustrated best in Figures 6, 6a, 7 and 8. Figure 6 shows a section of the laminated tape of Figure 1 with-the letters or characters having been cut-out. To transfer the cut-out letters to the desired medium, the portion of the layer 10, except for the cut-out letters, is first removed from the base or second layer 11. This is accomplished by separating the layers 10 and 11 at a corner and then pulling the layer 10 off. When this is completed, the figures 24 remain on the layer 11 as illustrated in ~g4~

l the lower half of ~igure 6a. A strlp of the third layer of transfer tape 14 (Figure 5) is then cut and placed onto the top surface of the rP~Inlng cut-out figures 24 as illustrated in Figure 6a with the low tack adhesive 21 in engagement with the top layer lO of the cut-out figures 24. After having been placed onto the cut-out figures 24 of the first layer 10, the transfer tape 14 is peeled back to remove the figures 24 from the second layer 11. Although the adhesive 21 on the transfer layer 1~ is a relatively low tack adhesive, it is sufficient to remove the cut-out figures 24 because of the release layer 16 on the layer ll. If the laminated tape of Figure 2 is used, the third layer 12 is simply peeled back in the same manner so as to remove the cut-out figures 24 from the layer 11. If the laminated tape of either Figures 3 or 4 is used, the transfer tape 13 must first be removed from the lower surface OI the layer ll and then used to remove the cut-out flgures 24 in the manner described above.

Following the removal of the cut-out letters or figures 24, the resulting transfer tape 14 includes only the cut-out letters 24 as shown in Figure 7. As illustrated, tbe cut-out figures 24 are aligned on the tape 14 with their adhesive side facing outwardly. To apply these cut-out characters 24 to the desired medium, the transfer tape 14 is simply aligned in the desired position as illustrated in Figure 8 and placed down in that position so that the bottom surface of the cut-out letters 24 which contain the aggressive adhesive 15 secures to the desired medium 25. The transfer tape 14 which contains the relatively low tack adhesive is then removed, thereby leaving the cut-out letters 24 properly positioned on the desired medium 25.
Although the description of the preferred embodiment has been quite specific, it is contemplated that various changes could be made without deviating from the spirit of the present invention. AccordinglyJ
it is intended that the scope of the invention be dictated by the alaims rather than by the description of the preferred embodiment.

Claims (23)

1. A laminated tape for manufacturing figures of desired shape comprising:
a first film layer comprising a relatively soft and flexible material capable of being cut by an elongated cutting ridge of a cutting die defining the figure of desired shape, said first film layer having a top and a bottom face and being constructed of a material having a tensile strength of no greater than about 1000 pounds per square inch; and a second film layer disposed in face-to-face relationship with respect to the bottom face of said first film layer for supporting said first film layer.

2. The laminated tape of claim 1 wherein said first film layer is constructed of a material having a tensile strength of no greater than about 500 pounds per square inch.

3. The laminated tape of claim 1 wherein said first film layer is constructed of a urethane material.

4. The laminated tape of claim 3 wherein said urethane material of said first film layer has an isocyanate to hydroxyl equivalency ratio of between about 0.7 and 0.9,

5. The laminated tape of claim 4 wherein said urethane material of said first film layer has an isocyanate to hydroxyl equivalency ratio of about 0.8.

6. The laminated tape of claim 1 wherein said first film layer includes a first adhesive coating on its face disposed adjacent to said second film layer.

7, The laminated tape of claim 6 wherein said first film layer includes a face exposed directly to said cutting die.

8. The laminated tape of claim 7 including a third film layer disposed adjacent to said second film layer on the face of said second film layer opposite said first film layer, said third film layer including a second adhesive coating on its face disposed adjacent to said second film layer.

9. The laminated tape of claim 8 wherein said third film layer is removable from said second film layer for positioning onto said first film layer with said second adhesive coating in engagement with the top face of said first film layer.

10. The laminated tape of claim 1 consisting only of said first film layer and said second film layer.

11. A laminated tape usable in an apparatus for manufacturing figures of desired shape wherein said apparatus includes a cutting die having an elongated plastic cutting ridge defining said figure of desired shape, a plastic or rubber cutting pad and a means for exerting a cutting force against said pad or said cutting die with said laminated tape disposed therebetween said laminated tape comprising:
a first film layer comprising a relatively soft and flexible material capable of being cut by said elongated cutting ridge, said first film layer having a top and bottom face, being at least 0.001 inches thick and being constructed of a material capable of being cut by said cutting ridge with a cutting force of no more than about 250 pounds per linear inch of said cutting ridge; and a second film layer disposed in face-to-face relationship with respect to the bottom face of said first film layer for supporting said first film layer.

12. The laminated tape of claim 11 wherein said plastic cutting ridge has a generally triangular cross-sectional shape.

13. The laminated tape of claim 12 wherein said cutting ridge is constructed of an acrylic plastic and said pad is constructed of a polyurethane.

14. The laminated tape of claim 11 wherein said first film layer is constructed of a material capable of being cut by said cutting ridge with a cutting force of between about 125 and 175 pounds per linear inch of cutting ridge.

15. The laminated tape of claim 11 wherein said first film layer is constructed of a urethane material.

16. The laminated tape of claim 15 wherein said urethane material of said first film layer has an isocyanate to hydroxyl equivalency ratio of between about 0.7 to 0.9.

17. The laminated tape of claim 16 wherein said urethane material of said first film layer has an isocyanate to hydroxyl equivalency ratio of about 0.8.

18. The laminated tape of claim 11 wherein said first film layer includes a first adhesive coating on its face disposed adjacent to said second film layer.

19. The laminated tape of claim 18 wherein said first film layer includes a face exposed directly to said cutting die.

20. The laminated tape of claim 19 including a third film layer disposed adjacent to said second film layer on the face of said second film layer opposite said first film layer, said third film layer including a second adhesive coating on its face disposed adjacent to said second film layer.

21. The laminated tape of claim 20 wherein said third film layer is removable from said second film layer for positioning onto said first film layer with said second adhesive coating in engagement with the top face of said first film layer.

22. A tape combination for manufacturing figures of desired shape comprising the laminated tape of claim 11 and a supply of a third film layer, separate from said laminated tape, said third film layer including an adhesive coating and being positionable into engagement with the top face of said first film layer with said adhesive coating in engagement with the top face of said first film layer.

23. A method of manufacturing figures of desired shape from a laminated tape and applying the same to a desired medium, said method comprising the steps of:
cutting at least one figure of desired shape from at least the uppermost layer of a segment of laminated tape;
removing the uppermost layer from the segment of laminated tape except for that portion comprising the cut-out figures;
placing a segment of adhesive backed transfer tape onto the cut-out figures;
removing the cut-out figures from the laminated tape via the transfer tape;
positioning the transfer tape with cut-out figures disposed thereon with respect to the desired medium; and transferring the cut-out figures from the transfer tape to the desired medium.