The present disclosure generally relates to a method and assembly for facilitating easy and professional application of labels and laminates to a substrate. More particularly, the disclosure relates to a label or laminate sheet made of large or flexible material that is configured to be aligned and manually applied to the substrate by a user in an efficient manner.
Labels and laminate sheets are well known and various types have been proposed to meet the requirements of a wide variety of label applications. For example, labels are extensively used in retail businesses for communicating product information to customers. Labels generally include a facestock layer with an adhesive side and an exposed side. The exposed side includes label indicia thereon and is opposite from the adhesive side. A liner sheet is operably attached to the adhesive side and is configured to allow a user to peal the label portion of the facestock from the liner sheet to be placed on a substrate. Similarly, a laminate sheet may include a facestock that is a generally transparent plastic material having an adhesive side that is attached to a liner sheet. The facestock is configured to be pealed from the liner such that the adhesive side can be applied to a substrate. This allows the laminate facestock to protect the substrate while allowing users to view the substrate through the laminate.
However, problems arise when a user peals the label or laminate facestock from the liner and attempts to place the facestock on the substrate. Many times the facestock fails to adhere due to inconsistent application by the user. The placing of the adhesive side to the substrate can be a challenge to the user as unwanted bubbles or ridges may be created between the facestock and the substrate. These ridges and bubbles may be unsightly and difficult to properly correct. Inconsistent application becomes more likely when the label or laminate facestock is large relative to the hands of the user and is made from a generally flexible material. The user may have a difficult time handling the facestock while placing the adhesive side against the substrate as intended. Further, the facestock becomes difficult to correctly align with the substrate in certain applications. Additionally, the facestock is difficult to handle because the laminate sheet is very thin and pliable.
Therefore, there is a need for a label or laminate sheet assembly having a facestock and liner material that can be configured to reduce inconsistent application by the user. There is also a need for an improved method of applying a label or laminate sheet to a substrate that reduces the steps necessary to accurately position and consistently apply the label or laminate to the substrate.
Accordingly, one of the primary objects of the present disclosure is to provide a label or laminate sheet assembly having a facestock and liner that is easily utilized by a user for manual application to the substrate. It is another object of the present disclosure to provide methods to remove the liner from the facestock of the assembly for the accurate placement of a label or laminate facestock material on the substrate.
A label or laminate assembly is provided as shown and described herein. The label or laminate may be a sheet assembly that is configured to apply a facestock layer to a substrate. The facestock layer may include a facestock bridge portion with an adhesive layer. A liner sheet is attached to the facestock layer and may include a strip portion having a first dimension that is configured to be removed to expose a portion of the adhesive layer under the facestock bridge portion. The facestock bridge portion is adhered to the substrate to anchor the sheet assembly to the substrate and allow the remaining liner sheet to be removed in a generally aligned manner as desired. The facestock layer may be made of a generally see-through material. Alternatively, the facestock layer may be a label. Additionally, the sheet assembly may include at least one perforation line that divides the sheet assembly into multiple sections wherein the sheet assembly includes at least one of two sections, four sections, and ten sections. The sheet assembly may include at least one die cut line within the facestock layer for separating a facestock portion and a matrix portion.
In one embodiment provided is a method of applying a facestock layer to a substrate, the method includes the steps of providing a sheet assembly having a facestock layer with a facestock bridge portion, an adhesive layer and a liner sheet with a strip portion having a first dimension. The strip portion of the liner sheet is removed from the facestock layer to expose a portion of adhesive. The sheet assembly is aligned with the substrate in a desired orientation. The facestock bridge portion is anchored to the substrate. The remaining portion of the liner sheet is removed from the facestock layer to expose the adhesive layer to the substrate. The remaining portion of the facestock layer is adhered to the substrate.
Operation of the disclosure may be better understood by reference to the following detailed description taken in connection with the following illustrations, wherein:
Reference will now be made in detail to embodiments of the present disclosure, examples of which are illustrated in the accompanying drawings. It is to be understood that other embodiments may be utilized and structural and functional changes may be made without departing from the respective scope of the disclosure. Moreover, features of the various embodiments may be combined or altered without departing from the scope of the disclosure. As such, the following description is presented by way of illustration only and should not limit in any way the various alternatives and modifications that may be made to the illustrated embodiments and still be within the spirit and scope of the disclosure.
A laminate or label sheet assembly 10 is disclosed and may be of any appropriate configuration and is not limited to that shown and described herein. It should similarly be understood that the sheet assembly 10 may be adapted to any appropriate size, including, without limitation, 8.5 inches by 11 inches, A4 size, legal size or any other size. The sheet assembly 10 may be made of any appropriate materials and colors or indicia and this disclosure is not limited in this regard.
As illustrated by
The sheet assembly 10 may also include first and second die cut lines 100, 110 through the liner sheet 40. The first die cut line 100 and the second die cut line 110 may be generally parallel to one another to define a strip portion 120 of the liner sheet 40. The strip portion 120 may include a first dimension or gap L that defines a length wherein the first dimension L is between approximately 0.032 inch to 0.4375 inch, or between about 0.0625 inch to 0.375 inch and is more particularly about 0.125 inch. See Table 1 for examples.
The first and second die cut lines 100, 110 may extend from a first edge 112 to a second edge 114 of the sheet assembly 10. In this embodiment, the die cut lines 100, 110 define the strip portion 120 having a second dimension W wherein the second dimension W is the distance between the first edge 112 and the second edge 114 of the sheet assembly. In addition to the first and second edges 112, 114, a third edge 116 may be opposite a fourth edge 118 that generally define a perimeter of the sheet assembly 10. The space between the third edge 116 and the fourth edge 118 may be defined by a third dimension Lt. The third dimension Lt represents the total length of the sheet assembly 10 and the second dimension W represents the transverse length of the total sheet assembly 10.
In one embodiment, the second dimension W may be between approximately 7 inches and 18 inches, or more narrowly between approximately 11 inches and 14 inches. The third dimension Lt may be between approximately 5 inches and 11 inches, or may be approximately 8.5 inches. Alternately, the second dimension and third dimension of the sheet assembly 10 may include dimensions that compare to standard US paper sizes including letter (8.5×11 in), legal (8.5×14 in), junior legal (5×8 in), and ledger/tabloid (11×17 in) sizes or standard international paper sizes such as A, B, and C paper sizes.
In the embodiment of
Section C includes at least one die cut line 260c through the facestock layer 220. The die cut line 260c may separate section C between a matrix portion 270c and a facestock portion 280c wherein the matrix portion 270c may be removed from the liner sheet 240 and the facestock portion 280c. Section D includes at least one die cut line 260d through the facestock layer 220. The die cut line 260d may separate section D between a matrix portion 270d and a facestock portion 280d wherein the matrix portion 270d may be removed from the liner sheet 240 and the facestock portion 280d. Section E includes at least one die cut line 260e through the facestock layer 220. The die cut line 260e may separate section E between a matrix portion 270e and a facestock portion 280e wherein the matrix portion 270e may be removed from the liner sheet 240 and the facestock portion 280e. Section F includes at least one die cut line 260f through the facestock layer 220. The die cut line 260f may separate section F between a matrix portion 270f and a facestock portion 280f wherein the matrix portion 270f may be removed from the liner sheet 240 and the facestock portion 280f. Section G includes at least one die cut line 260g through the facestock layer 220. The die cut line 260g may separate section G between a matrix portion 270g and a facestock portion 280g wherein the matrix portion 270g may be removed from the liner sheet 240 and the facestock portion 280g. Section H includes at least one die cut line 260h through the facestock layer 220. The die cut line 260h may separate section F between a matrix portion 270h and a facestock portion 280h wherein the matrix portion 270h may be removed from the liner sheet 240 and the facestock portion 280h.
The sheet assembly 200 may also include a first and second die cut line 242, 244 through the liner sheet 240. The first die cut line 242 and the second die cut line 244 may be generally parallel to one another to define a strip portion 246 of the liner sheet 240. The strip portion 246 may extend under die cut lines 260c, 260e, and 260g as well as through perforated lines 204 and 206 as illustrated by
In one embodiment, strip portion 246 may be positioned at an approximate midpoint position under sections C, E, and G such that, when the strip portion 246 is removed, it generally define two symmetric sized sides of facestock portions 280c, 280e, and 280g. Additionally, strip portion 256 may be positioned at an approximate midpoint position under sections C, E, and G such that, when the strip portion 256 is removed, it generally define two symmetric sized sides of facestock portions 280c, 280e, and 280g. Alternatively, the strip portions 246 and 256 may be located at various positions along the liner sheet 240.
The strip portion 246 may include a first dimension L that defines a length wherein the first dimension L is between approximately 0.1 inch to 0.15 inch and is more particularly about 0.125 inch. The first and second die cut lines 242, 244 may extend from the first edge 212 to the second edge 214 of the sheet assembly 200. In this embodiment, the die cut lines 242, 244 define the strip portion 246 having a second dimension W wherein the second dimension W is the distance between the first edge 212 and the second edge 214 of the sheet assembly 200. Additionally, the space between the third edge 216 and the fourth edge 218 may be defined by a third dimension Lt. The third dimension Lt represents the total length of the sheet assembly 200 as the second dimension W represents the transverse length of the total sheet assembly 200.
In one embodiment, the second dimension W may be between approximately 7 inches and 18 inches, or more narrowly between approximately 11 inches and 14 inches. The third dimension Lt may be between approximately 5 inches and 11 inches, or may be approximately 8.5 inches. Alternatively, the second dimension and third dimension of the sheet assembly 200 may include dimensions that compare to standard US paper sizes including letter (8.5×11 in), legal (8.5×14 in), junior legal (5×8 in), and ledger/tabloid (11×17 in) sizes or standard international paper sizes such as A, B, and C paper sizes.
In the embodiment of
Section I, J, K, L, M, N, O, P, Q, and R of sheet assembly 300 include similar features to sheet assembly 200 as described above. Each section of sheet assembly 300 may includes at least one die cut line 360 through the facestock layer 320. The die cut line 360 may separate the sections between a matrix portion 370 and a facestock portion 380 wherein the matrix portion 370 may be removed from the liner sheet 340 and the facestock portion 380.
The sheet assembly 300 may also include a first and second die cut lines 342, 344 through the liner sheet 340. The first die cut line 342 and the second die cut line 344 may be generally parallel to one another to define a strip portion 346 of the liner sheet 340. The strip portion 346 may extend under a plurality of die cut lines 360 of sections I, K, M, O, and Q as well as through perforated lines 304, 306, 308, and 309 as illustrated by
In one embodiment, strip portion 346 may be positioned at an approximate midpoint position under sections I, K, M, O, and Q such that, when the strip portion 346 is removed, it generally defines two symmetric sized sides of facestock portions 380 of sections I, K, M, O, and Q. Additionally, strip portion 356 may be positioned at an approximate midpoint position under sections J, L, N, P, and R such that, when the strip portion 356 is removed, it generally defines two symmetric sized sides of facestock portions 380 of sections J, L, N, P, and R. Alternatively, the strip portions 346 and 356 may be located at various positions along the liner sheet 340.
The strip portion 346 may include a first dimension L that defines a length wherein the first dimension L is between approximately 0.1 inch to 0.15 inch and is more particularly about 0.125 inch. The first and second die cut lines 342, 344 may extend from the first edge 312 to the second edge 314 of the sheet assembly 300. In this embodiment, the die cut lines 342, 344 define the strip portion 346 having a second dimension W wherein the second dimension W is the distance between the first edge 312 and the second edge 314 of the sheet assembly 300. Additionally, the space between the third edge 316 and the fourth edge 318 may be defined by a third dimension Lt. The third dimension Lt represents the total length of the sheet assembly 300 as the second dimension W represents the transverse length of the total sheet assembly 300.
In one embodiment, the second dimension W may be between approximately 7 inches and 18 inches, or more narrowly between approximately 11 inches and 14 inches. The third dimension Lt may be between approximately 5 inches and 11 inches, or may be approximately 8.5 inches. Alternately, the second dimension and third dimension of the sheet assembly 200 may include dimensions that compare to standard US paper sizes including letter (8.5×11 in), legal (8.5×14 in), junior legal (5×8 in), and ledger/tabloid (11×17 in) sizes or standard international paper sizes such as A, B, and C paper sizes.
In the embodiment of
Initially, a desired section of sheet assembly 10 of
Tables 1, 2, and 3 are provided below to disclose how the relative dimensions of the sheet assembly 10 including the configuration of the liner sheet 40, adhesive layer 30 and facestock layer 20 may utilize the facestock bridge portion 140 of various sizes relative to the sizes of the liner sheet 40 to properly anchor and apply the facestock layer 20 to a substrate.
Table 1 lists results of utilizing a sheet assembly having a facestock material 20 made of PET having a thickness of either 0.001 in or 0.002 in. The liner sheet 40 is made of paper glassined with a thickness of 0.0023 in in several examples and paper having 0.0042 in thickness with the remaining examples. In these examples, the facestock material included a modulus of elasticity of approximately 500 kg/mm2 having a density of 1.39 g/cm3. The “gap” listed is the dimension of the first length L as illustrated by
Table 2 lists results of a theoretical maximum dimension L along with correlated borderline and optimal maximum dimension L for the gap or facestock bridge portion as desired for sheet assemblies of various materials. The theoretical maximum dimension L is the dimension beyond which the weight of the facestock in the bridge portion would cause it to deflect and make contact with the sheet member SM or substrate SUB. Described is a sheet assembly having a facestock material 20 made of PET having various thicknesses including 0.001 in., 0.002 in, and 0.0005 in. The liner sheet 40 is made of paper glassined with various thicknesses including 0.0023 in, 0.00115 in, 0.0046 in. and 0.0042 in. In these examples, the facestock material included a modulus of elasticity of approximately 500 kg/mm2 having a density of 1.39 g/cm3. The “theoretical gap” listed is the dimension of the first length L as illustrated by
Eq. 1 and Eq. 2 are for a simply supported bridge portion under a distributed load:
d=(5*(L^3)*F)/(384*E*I) Eq. 1:
I=(wh^3)/12 Eq. 2:
Combining Eq.1 and Eq.2 and solving for the theoretical maximum dimension Lmax, the gap:
Lmax=(6.4*(h^2)*E*d/r)^0.25 Eq. 3:
Where: d=deflection at center (set to liner thickness for the calculations), Lmax=bridge length (or gap), F=load (weight of beam calculated from its density and volume), E=tensile modulus, I=area moment of inertia, w=width of rectangular shaped bridge portion, h=height of rectangular shaped bridge portion, r=density.
Similarly, Table 3 below describes the theoretical minimum dimension L for the gap or facestock bridge portion as desired for sheet assemblies of various materials. The theoretical minimum dimension L is the dimension below which too large of a force would need to be applied by the user to get the facestock in the bridge portion to deflect enough to make contact with the sheet member SM or substrate SUB. Described is a sheet assembly having a facestock material 20 made of PET having various thicknesses including 0.001 in. and 0.002 in. The liner sheet 40 is made of paper glassine with a thickness including 0.0023 in. and paper with a thickness including 0.0042 in. In these examples, the facestock material included a modulus of elasticity of approximately 500 kg/mm2 having a density of 1.39 g/cm3. The “theoretical minimum gap” listed is the dimension of the first length L as illustrated by
Combining Eq.1 and Eq.2 and solving for the theoretical minimum dimension Lmin, the gap:
Lmin=(12.03*d*E*w*h^3)^0.25 Eq.4:
Where: the units of 12.03 are cm2/kg. Additionally, the effective “w” dimension of the area pressed by the user's finger is estimated to be about 0.3 in.
Although the embodiments of the present invention have been illustrated in the accompanying drawings and described in the foregoing detailed description, it is to be understood that the present invention is not to be limited to just the embodiments disclosed, but that the invention described herein is capable of numerous rearrangements, modifications and substitutions without departing from the scope of the claims hereafter. The features of each embodiment described and shown herein may be combined with the features of the other embodiments described herein. The claims as follows are intended to include all modifications and alterations insofar as they come within the scope of the claims or the equivalent thereof.
This application claims priority to U.S. provisional patent application No. 62/092,306 filed on Dec. 16, 2014 titled METHOD AND APPARATUS FOR APPLYING A LABEL OR LAMINATE SHEET TO A SUBSTRATE which is incorporated by reference in its entirety.
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3535804 | Cunningham | Oct 1970 | A |
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5182152 | Ericson | Jan 1993 | A |
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Number | Date | Country | |
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20160180749 A1 | Jun 2016 | US |
Number | Date | Country | |
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62092306 | Dec 2014 | US |