U.S. patent application number 11/225732 was filed with the patent office on 2006-01-19 for segmented sheeting and methods of making and using same.
This patent application is currently assigned to 3M Innovative Properties Company. Invention is credited to Eugene H. Carlson, James C. Coderre, Christopher L. Harvey, James E. Lasch, David W. Meitz, Colleen C. Nagel.
Application Number | 20060011287 11/225732 |
Document ID | / |
Family ID | 26869720 |
Filed Date | 2006-01-19 |
United States Patent
Application |
20060011287 |
Kind Code |
A1 |
Carlson; Eugene H. ; et
al. |
January 19, 2006 |
Segmented sheeting and methods of making and using same
Abstract
The present invention provides a new sheeting article that may
suitably include: a carrier having a first major surface and a
second major surface; and a plurality of discrete segments of a
sheeting (e.g., a retroreflective sheeting), wherein the sheeting
has a first major viewing surface and a second major opposing
surface, and the first major viewing surface of the sheeting is
preferably removably attached to the second major surface of the
carrier. Preferably, the first major surface of the carrier
comprises a release surface, the second major opposing surface of
the sheeting comprises an adhesive, the article is provided in the
form of a roll, and the adhesive surface of the sheeting is
adjacent the release surface of an adjacent layer of the roll. In a
presently preferred embodiment the present invention provides novel
easy-to-use truck conspicuity sheeting.
Inventors: |
Carlson; Eugene H.; (Apple
Valley, MN) ; Coderre; James C.; (Lake Elmo, MN)
; Harvey; Christopher L.; (St. Paul, MN) ; Lasch;
James E.; (Oakdale, MN) ; Meitz; David W.;
(St. Paul, MN) ; Nagel; Colleen C.; (Arden Hills,
MN) |
Correspondence
Address: |
3M INNOVATIVE PROPERTIES COMPANY
PO BOX 33427
ST. PAUL
MN
55133-3427
US
|
Assignee: |
3M Innovative Properties
Company
|
Family ID: |
26869720 |
Appl. No.: |
11/225732 |
Filed: |
September 13, 2005 |
Related U.S. Patent Documents
|
|
|
|
|
|
Application
Number |
Filing Date |
Patent Number |
|
|
10606911 |
Jun 26, 2003 |
|
|
|
11225732 |
Sep 13, 2005 |
|
|
|
09740215 |
Dec 18, 2000 |
6958179 |
|
|
10606911 |
Jun 26, 2003 |
|
|
|
60173953 |
Dec 30, 1999 |
|
|
|
Current U.S.
Class: |
156/230 ;
156/233; 156/235 |
Current CPC
Class: |
Y10T 156/1028 20150115;
Y10T 428/1467 20150115; Y10T 428/24 20150115; B44C 1/105 20130101;
Y10T 428/1429 20150115; C09J 2301/162 20200801; Y10T 428/1471
20150115; C09J 7/29 20180101; Y10T 156/1077 20150115; Y10T 428/1481
20150115; Y10T 156/1052 20150115; Y10T 156/1033 20150115; G02B 5/12
20130101; Y10T 428/14 20150115; Y10T 428/1486 20150115; Y10T 428/15
20150115; Y10T 428/1476 20150115; Y10S 428/913 20130101; Y10T
428/2839 20150115 |
Class at
Publication: |
156/230 ;
156/233; 156/235 |
International
Class: |
B44C 1/165 20060101
B44C001/165; B44C 1/17 20060101 B44C001/17 |
Claims
1. A method of applying a retroreflective article comprising a
plurality of discrete segments of retroreflective sheeting to a
flexible substrate, comprising the steps of: providing an elongate
strip of an article having (i) a carrier with a first major surface
and a second major surface and (ii) the plurality of discrete
segments of retroreflective sheeting having a first major viewing
surface and a second major opposing adhesive surface protected by a
release surface, wherein the first major viewing surface of the
discrete segments of retroreflective sheeting is attached to the
second major surface of the carrier; exposing the second major
opposing adhesive surface of the sheeting; and applying the
adhesive surface of the plurality of discrete segments of
retroreflective sheeting to the flexible substrate to thereby
adhere the plurality of discrete segments of retroreflective
sheeting to the substrate, the discrete segments of retroreflective
sheeting being spaced apart from one another on the flexible
substrate a distance sufficient to prevent contact between adjacent
segments when the substrate is bent a predetermined distance.
2. The method of claim 1, wherein exposing the second major surface
of the plurality of discrete segments of retroreflective sheeting
comprises unrolling a roll containing the plurality of discrete
segments of retroreflective sheeting.
3. The method of claim 1, wherein the exposing the second major
surface comprises removing a release liner prior to applying the
retroreflective article.
4. The method of claim 1, further comprising the additional step
of: removing the carrier from the applied article to thereby expose
the first major viewing surface of the sheeting.
5. The method of claim 4, wherein the carrier is extensible and
permits the article to be positioned along an irregular surface of
a substrate or along a curved path.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application is a continuation of U.S. patent
application Ser. No. 10/606,911, filed Jun. 26, 2003 which is a
divisional of U.S. patent application Ser. No. 09/740,215, filed
Dec. 18, 2000, now allowed and published as 02-0012761-A1, which
claims priority from Provisional Patent Application No. 60/173,953,
filed Dec. 30, 1999.
FIELD OF THE INVENTION
[0002] This invention relates to segmented sheeting, including
segmented retroreflective-type sheeting suitable for use on a wide
variety of substrates, including rigid or flexible substrates.
BACKGROUND
[0003] Retroreflective sheeting has long been used to improve the
night time visibility (or "conspicuity") of articles and vehicles.
This sheeting, which was first developed by Minnesota Mining and
Manufacturing Company, St. Paul, Minn. ("3M"), has greatly improved
the night time visibility of trucks and has helped prevent
countless dangerous accidents.
[0004] In certain parts of the world this life-saving sheeting is
now mandated by local or national governmental bodies. Often the
local governmental body will pass regulations that specify, for
example, precisely how much of a truck length should be delineated
with the sheeting, as well as other requirements. For example, in
the United States a regulation specifies sheeting shape, mounting
requirements and even provides a spacing allowance between
retroreflective segments. Other jurisdictions have different
regulations. Unfortunately, however, the applier may not correctly
apply the sheeting, for example by miscalculating the spacing
requirements for their particular jurisdiction. In such cases the
delineation will have to be corrected, often at considerable cost.
generally more common and less costly "rigid-type" of
retroreflective sheeting could be used. Unfortunately, however, the
flexible nature of the canvas siding does not work well with the
more rigid-types of sheeting and the user is left to use a more
costly "flexible-type" of sheeting.
[0005] From the foregoing, it will be appreciated that what is
needed in the art is improved sheeting for article and vehicle
conspicuity programs. Such sheeting and methods for preparing and
using the same are disclosed and claimed herein.
SUMMARY
[0006] In one embodiment, the present invention provides a new
sheeting article that comprises a carrier having a first major
surface and a second major surface; and a plurality of discrete
segments of a sheeting (e.g., a retroreflective sheeting), wherein
the sheeting has a first major viewing surface and a second major
opposing surface, and the first major viewing surface of the
sheeting is attached, preferably "removably" attached, to the
second major surface of the carrier.
[0007] In another embodiment, the present invention provides a new
sheeting article that comprises a carrier having a first major
surface and a second major surface; a plurality of discrete
segments of a first retroreflective sheeting; and a plurality of
discrete segments of a second retroreflective sheeting, wherein the
sheeting has a first major viewing surface and a second major
opposing surface, and the first major viewing surface of the
sheeting is attached to the second major surface of the carrier. In
a preferred embodiment, the first retroreflective sheeting segments
are spaced along a major length of the article and at least a
portion of the second retroreflective sheeting segments are
interspersed therebetween.
[0008] In yet another embodiment, the present invention provides a
new sheeting article that comprises a carrier having a first major
surface and a second major adhesive surface; and a plurality of
discrete segments of sheeting (e.g., a retroreflective sheeting),
wherein the sheeting has a first major viewing surface, a second
major opposing surface, and a periphery, the first major viewing
surface of the sheeting is attached to the second major adhesive
surface of the carrier, and the carrier extends beyond the
periphery of the discrete segments of retroreflective sheeting.
[0009] In a presently preferred embodiment the present invention
provides novel, easy-to-use truck conspicuity sheeting.
[0010] The present invention also provides novel methods of making
and using the above articles.
[0011] One such preferred method includes the steps of providing an
elongate strip of a carrier having a first major surface and a
second major surface; providing an elongate strip of a
retroreflective sheeting, wherein the sheeting has a first major
viewing surface and a second major opposing surface (preferably an
adhesive surface); cutting the elongate strip of retroreflective
sheeting into smaller discrete segments; and attaching, preferably
"removably" attaching, the first major viewing surface of the
sheeting to the second major surface of the carrier.
[0012] Another method includes the steps of providing an elongate
strip of a retroreflective sheeting on a release liner, wherein the
sheeting has a first major viewing surface and a second major
opposing adhesive surface protected by the liner; cutting the
elongate strip of retroreflective sheeting into smaller discrete
segments on the liner; stretching the liner in at least one
direction to separate segments; and attaching, preferably
"removably" attaching, the first major viewing surface of the
sheeting to a second major surface of an elongate strip of a
carrier having a first major surface and a second major
surface.
[0013] Another method includes the steps of providing an elongate
strip of a retroreflective sheeting on a release liner, wherein the
sheeting has a first major viewing surface and a second major
opposing adhesive surface protected by the liner; cutting the
elongate strip of retroreflective sheeting into smaller discrete
segments on the liner; removing selected portions of the sheeting
to separate the remaining segments; and attaching the first major
viewing surface of the sheeting to the second major surface of an
elongate strip of a carrier having a first major surface and a
second major surface.
[0014] One method of using the above articles includes the steps of
providing an elongate strip of a conspicuity article having (i) a
carrier with a first major surface and a second major surface and
(ii) a plurality of discrete segments of a retroreflective sheeting
having a first major viewing surface and a second major opposing
adhesive surface protected by a release surface, wherein the first
major viewing surface of the sheeting is attached, preferably
"removably" attached, to the second major surface of the carrier;
exposing the second major opposing adhesive surface of the
sheeting; and applying the adhesive surface of the sheeting to a
surface of a vehicle to thereby adhere the sheeting to the vehicle.
In a preferred embodiment the method includes an additional step of
removing the carrier from the applied article to thereby expose the
first major viewing surface of the sheeting
BRIEF DESCRIPTION OF THE DRAWINGS
[0015] The present invention will be further explained with
reference to the appended Figures, wherein like structure is
referred to by like numerals throughout the several views.
[0016] FIG. 1a shows a top view of one embodiment of the segmented
sheeting of the present invention; FIG. 1b is a cross-sectional
view of the segmented sheeting of FIG. 1a, taken along line
1b-1b.
[0017] FIGS. 2a and 2b show alternative cross-sectional views of
the segmented sheeting of the present invention and further
illustrate alternative liners for use therewith.
[0018] FIGS. 3a-3g show top views of alternative segmented sheeting
of the present invention, wherein the sheeting portion comprises an
exemplary variety of shapes, patterns and/or spacing
therebetween.
[0019] FIG. 4 shows a top view of an alternative embodiment of the
segmented sheeting of the present invention having two carrier
strips rather than a single carrier.
[0020] FIG. 5a shows a top view of another embodiment of the
segmented sheeting of the present invention wherein the carrier is
segmented; FIG. 5b is a cross-sectional view of the segmented
sheeting of FIG. 5a, taken along line 5b-5b.
[0021] FIG. 6 shows a top view of another embodiment of the
segmented sheeting of the present invention wherein the sheeting
portion is further segmented along the lengthwise axis.
[0022] FIG. 7a shows a top view of another embodiment of the
segmented sheeting of the present invention wherein the carrier
extends beyond the edges of the sheeting segments;
[0023] FIG. 7b is a cross-sectional view of the segmented sheeting
of FIG. 7a, taken along line 7b-7b.
[0024] FIGS. 8a-8g schematically illustrate alternative
manufacturing processes of the present invention.
[0025] FIG. 9 is a graph illustrating correlation between
predictive data and measured data for segmented sheeting in a
wrinkle failure mode.
[0026] FIGS. 10-13 are diagrammatic views illustrating various
failure modes.
[0027] These figures, which are idealized, are not to scale and are
intended to be merely illustrative and non-limiting.
DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS
[0028] The present invention provides retroreflective sheeting
articles (and methods of making and using such articles) that solve
one or more of the unmet needs noted above.
[0029] In one embodiment, the present invention relates to
retroreflective truck conspicuity sheeting having a carrier. The
carrier preferably facilitates the placement and/or orientation of
retroreflective segments on a substrate. For example, the articles
of the present invention may be easily adapted for use on flexible
substrates such as canvas truck sides. As used herein,
retroreflectivity includes any article that provides a reflected
beam back toward the source for angles of incidence that are not
normal to a viewing surface of the article. Thus, a retroreflective
article can be any suitable type of article including, for example,
prismatic, encapsulated beads, embedded beads, and enclosed type
retroreflective articles.
[0030] FIG. 1a shows a top view of one embodiment of a segmented
sheeting article 10 of the present invention. FIG. 1b is a
cross-sectional view of the segmented sheeting of FIG. 1a, taken
along line 1b-1b. As shown, segmented sheeting article 10 includes
a carrier 14 having a first major surface 16 and a second major
surface 18. Sheeting article 10 further includes a plurality of
sheeting segments, typically retroreflective sheeting segments 12
(12a, 12b, 12c) or "pieces" attached to the carrier. Sheeting
segments 12 (12a, 12b, 12c) typically comprise a sheeting viewing
surface 20 (typically a retroreflective backing) and an adhesive
layer 22. Sheeting segments 12 are discrete and may optionally be
separated from adjacent segments by a gap 13. Segments 12a, 12b,
12c, etc. may be the same or different. For example, 12a and 12c
could be of a first type and 12b of a second type of sheeting. This
construction may be used to provide an article with, for example,
alternating red and white colors.
[0031] In one embodiment, first major surface 16 comprises an
optional release coating. Suitable such release coatings include
low adhesion backsize (LABs) such as are common in the pressure
sensitive adhesive tape industry. When the carrier 14 comprises an
optional release surface or coating, the sheeting article 10 may be
conveniently provided in the form of a pad or roll and adhesive
layer 22 placed in contact with the optional release surface or
coating of an adjacent carrier, e.g., when adjacent layers of a
roll are placed in contact.
[0032] FIGS. 2a and 2b show alternative cross-sectional views of
the segmented sheeting of the present invention and further
illustrate alternative liners for use therewith. In FIG. 2a,
segmented sheeting 30 is provided with a separate "continuous"
release liner 24a. The function of the release liner is to protect
the adhesive layer 22 prior to its use against a substrate. In use,
release liner 24a would be removed (e.g., peeled off) to expose
adhesive 22 prior to application of the article to a substrate. In
FIG. 2b, segmented sheeting 32 is provided with a separate
"segmented" release liner 24b. As described above, the liner pieces
would be removed prior to application of the article to a
substrate.
[0033] FIGS. 3a-3g show top views of alternative segmented sheeting
of the present invention, wherein the sheeting portion comprises an
exemplary variety of shapes, patterns and/or spacing
therebetween.
[0034] The article of FIG. 3a is similar to that shown in FIG. 1a,
however, the gap 13 between adjacent segments 12 is smaller. It is
within the scope of the present invention to have no gap between
adjacent segments. However, for use on flexible substrates, e.g.,
canvas truck sides, the presence of a gap is preferred. Such gaps
allow greater flexibility in the resultant truck side, particularly
when the sheeting is of a more rigid-type of sheeting. As will be
illustrated in greater detail later, some of the embodiments that
employ gaps are utilized without generating waste, known as
material weed.
[0035] The article of FIG. 3b illustrates segments 12 having
"diamond" shapes. One method of producing such shapes is to cut
square or rectangular shapes from a strip (thereby not wasting any
sheeting) and rotate the segments 45 degrees when attaching them to
the carrier.
[0036] The article of FIG. 3c illustrates segments 12 having
"circular" shapes.
[0037] The article of FIG. 3d illustrates segments 12 having
"irregular" shapes such as might constitute a logo or message.
[0038] The article of FIG. 3e illustrates an article 34e having a
large number of small segments 12 having "rectangular" shapes. One
method of producing such an article is to (1) "kiss" cut (a "kiss"
cut is a partial cut that does not extend through all layers) a
retroreflective strip on a stretchable liner into a pattern of
small rectangles, (2) stretch the strip (either lengthwise or
widthwise or both) to separate the segments, and then (3) attach
the separated segments to a carrier. This method can be utilized
with any other "packable" pattern, i.e., any other pattern than
packs together and can be cut from a sheet with minimal or no
waste.
[0039] FIG. 3f illustrates an article 34f having a plurality of
discrete segments 12 which combined reveal a message or
graphic.
[0040] The article of FIG. 3g illustrates segments 12 having
"chevron" shapes.
[0041] FIG. 4 shows a top view of an alternative embodiment of a
segmented sheeting article 36 of the present invention. As shown,
segmented sheeting article 36 includes two carriers 14 (14a, 14b)
along each edge of the article. Sheeting article 36 further
includes a plurality of sheeting segments 12 or "pieces" (typically
retroreflective sheeting segments) attached to the carriers.
[0042] FIG. 5a shows a top view of another embodiment of a
segmented sheeting article 37 of the present invention. FIG. 5b is
a cross-sectional view of the segmented sheeting of FIG. 5a, taken
along line 5b-5b. As shown, segmented sheeting article 37 includes
a plurality of segmented carrier pieces 14. Sheeting article 37
further includes a plurality of sheeting segments 12 (typically
retroreflective sheeting segments) attached to the carrier. If
desired, the carrier may be permanently attached to the sheeting
segments, e.g., by use of a permanent adhesive, bonding, sonic
welding, riveting, sewing, or other methods. The carrier pieces in
such cases remain attached to the article after it has been applied
to a substrate and are not subsequently removed. Sheeting segments
12 typically comprise a retroreflective surface 20 and an adhesive
layer 22. Sheeting segments 12 are discrete and may optionally and
preferably be separated from adjacent segments by a gap 13. If
desired, an optional release liner 24a (or a segmented release
liner, not shown) may be used.
[0043] FIG. 6 shows a top view of another embodiment of the
segmented sheeting 38 of the present invention, wherein the
sheeting portion 12 is further segmented into three smaller pieces
(12a, 12b, and 12c). The embodiments shown in FIG. 6 illustrate an
article where separations exist between adjacent segments 12,
however, it is within the scope of this invention that smaller gaps
or no gaps be present therebetween. Also, it is within the scope of
this invention that gaps exist between pieces 12a, 12b and/or
12c.
[0044] One feature of the sheeting of FIG. 6 is that increased
flexibility can be achieved by providing cut lines 11. In most
preferred embodiments of the present invention, the cut lines 11 do
not substantially adversely affect the performance properties of
the sheeting. For example, when segment 12 comprises a sealed
prismatic or beaded retroreflective sheeting, it may be preferable
to seal the edges of the segment pieces to avoid subsequent loss of
performance of the sheeting. Such edge sealing may not be necessary
in the case of retroreflective sheeting that utilizes a reflective
coating layer rather than an air interface.
[0045] FIG. 7a shows a top view of another embodiment of the
segmented sheeting 39 of the present invention wherein the carrier
15 extends beyond the edges of the sheeting portion. FIG. 7b is a
cross-sectional view of the segmented sheeting of FIG. 7a, taken
along line 7b-7b. In this embodiment, carrier 15 is shown having a
backing layer 17 and an adhesive layer 19. The extension of carrier
15 beyond the edges of the sheeting portion 12 allows the carrier
to be used, if desired, to secure the article to a substrate or to
seal the sheeting from the surrounding environment. Consequently,
in this embodiment there is no requirement that portion 12 comprise
its own adhesive layer, though such a layer may be utilized if
desired.
[0046] FIG. 8a schematically illustrates one manufacturing process
40 of the present invention. In this process a roll 42 of sheeting
44 (typically retroreflective sheeting) (shown on an optional
release liner) is unwound and passed through a cutting apparatus 48
to form a segment 50 of sheeting. The segment 50 is then positioned
against a carrier 52 and attached thereto. In preferred embodiments
of this process, the carrier comprises an adhesive surface 56 that
secures the segment thereto. In preferred embodiments the segments
(50, 50b, 50c, etc.) are positioned along the carrier with gaps 58
therebetween. In most preferred embodiments, the carrier 52 with
attached segments 50 is then wound up to form a roll 60 of
segmented sheeting. If desired, an optional liner (not shown) may
be used to cover and protect the optional adhesive surface of the
segment. Alternatively, the carrier 52 may comprise a release
surface 54 and itself function as a liner.
[0047] FIG. 8b schematically illustrates another manufacturing
process 70 of the present invention. For simplicity, illustration
of removal of the release liners is omitted in FIG. 8b, however
such steps are indeed performed. In this process a first roll 72a
of sheeting 74a (typically retroreflective sheeting) is unwound and
passed through a cutting apparatus 78a to form a segment of
sheeting 80a. The segment 80a is then positioned against a carrier
82 and attached thereto. A second roll 72b of sheeting 74b is
unwound and passed through a second cutting apparatus 78b to form a
segment of sheeting 80b. The segment 80b is then positioned against
a carrier 82 and attached thereto, typically between segments of
the first sheeting 74a. In preferred embodiments the segments are
positioned along the carrier with gaps therebetween. The two
sheetings (74a, 74b) may be the same or different. In one
embodiment the two sheetings have different retroreflective
properties (e.g., different optical properties) or different colors
and the two sheetings are alternated along the carrier. In most
preferred embodiments the carrier 82 with attached segments 80a and
80b is then wound up to form a roll 90 of segmented sheeting. If
desired, an optional liner (not shown) may be used to cover and
protect the optional adhesive surface of the segment.
Alternatively, the carrier 82 may comprise a release surface 84 and
itself function as a liner.
[0048] FIG. 8c schematically illustrates another manufacturing
process 90 of the present invention. In this embodiment sheeting 91
is provided in the form of a plurality of cut and sealed
retroreflective segments with adhesive and an adhesive carrier.
Sheeting 91 is provided to drive rolls 92a and 92b, which draw
sheeting 91 therethrough. At point 94, the adhesive carrier is
stripped from sheeting 91 and spooled upon roll 96. Then, an
adhesive liner 98 with release surface 100 is brought into contact
with sheeting 91 at rollers 102a and 102b. An elongate carrier 104,
having adhesive surface 106, is brought into contact with sheeting
91 at rollers 102a and 102b. The resulting product 108 includes an
elongate carrier, a plurality of sheeting segments and an adhesive
liner. As will be appreciated by those skilled in the art, the
relative spacing between the various segments can be accurately
controlled by varying the rotational speed of rollers 102a and 102b
with respect to rollers 92a and 92b.
[0049] FIG. 8d schematically illustrates another manufacturing
process 110 of the present invention. This embodiment is similar to
that illustrated in FIG. 8c and like elements are numbered
similarly. Sheeting 91 is provided in the form of a plurality of
cut and sealed retroreflective segments disposed upon adhesive and
an adhesive carrier. Sheeting 91 is provided to drive rolls 92a and
92b, which draw sheeting 91 therethrough. At point 94, the adhesive
carrier is stripped from sheeting 91 and spooled upon roll 96.
Individual sheeting segments are then provided to one of a
plurality of lines 111, 113 based upon selective operation of
actuator 112. Although a pair of lines 111, 113 are illustrated,
those skilled in the art will appreciate that any suitable number
of lines may be used. In each line, an adhesive liner 98a, 98b with
release surface 100a, 100b is brought into contact with sheeting 91
at rollers 102a, 102b and 114a, 114b. Elongate carrier 104a, 104b,
having adhesive surface 106a, 106b is brought into contact with
sheeting 91. The resulting products 108a and 108b include an
elongate carrier, a plurality of sheeting segments and an adhesive
liner. This embodiment provides a pair of finished product rolls
from the same stock of segmented sheeting, which finished rolls may
have the same spacing between adjacent segments, or different
spacing depending upon the relative speeds of rollers 102a, 102b,
114a, and 114b.
[0050] FIG. 8e schematically illustrates another manufacturing
process 120 of the present invention. In this embodiment sheeting
segments 122 are provided to rollers 124a and 124b along with
carrier 126 (with adhesive surface 127) and adhesive liner 128
(with release surface 129). The various components are pinched
together by rollers 124a and 124b to form intermediate product 130.
At rollers 132a and 132b, a number of discontinuities are generated
in the elongate carrier 126. Such discontinuities may take any
suitable shape, but are preferably slots. One method of generating
slots in carrier 126 includes using a roller 132b that includes a
number of cutters 136. This is preferable because the function of a
roller opposing roller 132a and the function of cutting slots are
combined. However, those skilled in the art will appreciate that
the various functions can separated as desired. FIG. 8g is a
perspective view of the preferred roller 132b illustrating cutters
136. FIG. 8f is a top view of finished product 138 illustrating
discontinuities 140 extending across the width of product 138
between segments 122.
[0051] Suitable and preferred materials and methods of assembly and
use of the articles of the present invention are as follows.
[0052] Suitable articles of the present invention comprise a
carrier having a first major surface and a second major surface.
Preferred carriers are generally elongated strips. More preferred
carriers for use in the present invention are typically provided in
the form of a roll.
[0053] Suitable carriers include film and sheet backing materials.
A particularly preferred carrier includes a polymeric film backing
material. For example, suitable carriers include those polymeric
backing films that have the strength to support the attached
sheeting segments during the manufacturing process and/or during
subsequent application of the article to a substrate. For certain
embodiments (e.g., where the carrier is designed to be removed
after application of the sheeting to a substrate), the carrier
preferably has a sufficient tensile strength to permit the carrier
to be easily peeled away from the attached sheeting. Alternatively,
the carrier may be made of a suitable material that may be removed
from the sheeting (e.g., after application of the sheeting to a
substrate) by dissolving the carrier away.
[0054] In more preferred embodiments, the carrier has an adhesive
surface, e.g., for attaching the sheeting segments to the carrier.
Typically this adhesive will be a pressure sensitive adhesive
("PSA"), however, other suitable types of adhesives (e.g.,
non-tacky adhesives such as are disclosed in U.S. Pat. Nos.
6,004,670; 5,912,059; 5,908,695; and 5,888,335) may be used if
desired.
[0055] Suitable PSAs include those that provide the requisite
adhesion to the sheeting segments. Preferably the PSA provides
suitable adhesive strength to support the sheeting segments during
the manufacturing process and/or during the application of the
sheeting segments to a substrate. Suitable PSAs include those
described, for example, in U.S. Pat. Nos. 5,861,211; 5,905,099;
5,820,988; 5,804,610; 5,639,530; 5,584,962; 5,580,417; 5,453,320;
5,391,015; 5,334,686; 4,985,488; 4,946,742; and 4,248,748. In cases
where the carrier is designed to remain attached to the applied
article, the PSA preferably is selected with long term durability
in mind. In cases where the carrier is intended to be removed
(e.g., peeled off) after the article is applied to the substrate
the choice of adhesive or the amount of adhesive used (e.g.,
coating weight, coating pattern or coating texture) should
preferably be adjusted so that the carrier can be easily peeled
off. In other words, preferably the force of adhesion to the
sheeting segment and/or to the substrate is not such that the
removal of the carrier causes either the sheeting segments to
release from the substrate or makes removal of the carrier from the
substrate too difficult.
[0056] Other suitable PSAs, e.g., for use when producing an article
having a removable carrier, include water dispersible PSAs such as
are described in U.S. Pat. Nos. 3,865,770; 4,413,080; 4,569,960;
5,125,995; 5,270,111; 5,380,779; 5,397,614 and 5,460,880. This type
of adhesive is particularly suited for use with water dissolving
carrier backings, as previously described. In cases where both the
carrier backing and adhesive layer are dissolvable, e.g., with
water, the carrier can be simply washed off from the substrate
without the need to peel the carrier off.
[0057] It is within the scope of the present invention to use
alternative attachment means. Suitable other means include
"non-tacky adhesive systems" (such as are disclosed in the
aforementioned patents), and/or the direct lamination to suitable
polymer surfaces. With proper selection of the non-tacky adhesive
system or lamination method the carrier to sheeting adhesion force
may be suitably adjusted.
[0058] It is also within the scope of the present invention to use
alternative "permanent" attachment means. Suitable "permanent"
types of attachment include sonic welding methods, lamination
methods (e.g., heat lamination), etc. For example, the carrier may
be sonically welded to the sheeting using lines, spots, etc. It is
recognized that the "permanence" of the attachment, however, may be
varied, for example, by varying the number or size of the
welds.
[0059] Suitable carriers, in addition to positioning and supporting
a plurality of sheeting segments, are preferably also somewhat
extensible. As has been previously described, the articles of the
present invention typically comprise a carrier and a plurality of
sheeting segments attached thereto. In some cases the sheeting
segments may not themselves be very extensible. Segmented articles
having low extensible sheeting segments may be effectively
extensible primarily or only at the gaps between the segments.
Consequently, preferred carriers are extensible and allow the
article to be positioned along an irregular surface, e.g., bent
around obstacles, bent around curves and/or corners, stretched over
rivets, stretched over pre-existing fold lines in a flexible
substrate, etc. Most preferably the carrier maintains its original
shape (e.g., a straight lengthwise shape) during application of the
article along a straight substrate, yet can be extensibly stretched
by the applier when desired, e.g., to go around a wheel-well of a
vehicle. In some embodiments, however, very extensible carriers are
used, such as that of Example 1, Run 9 set forth below, where the
degree of carrier extensibility facilitates "steering" or otherwise
directing application of the retroreflective segments in non-linear
applications. For example, if the segments are to be applied in an
"S" pattern, the extensible carrier can be stretched and turned
during application in order to generate the appropriate curves for
the pattern.
[0060] In alternative embodiments, e.g., where the carrier is
designed to remain attached to the article, the carrier is
preferably constructed using suitable ultraviolet ("UV") light
absorbers and/or other adjuvants. Preferred adjuvants help provide
long-term durability to the carrier and/or underlying article. The
carrier may also provide one or more feature to the article such as
scratch resistance, dew resistance, mold and organism resistance,
dirt resistance, graffiti resistance, etc. For example, the carrier
may be constructed using Scotchlite Premium Protective Overlay
Film, which comprises an ethylene tetrafluoroethylene film with an
acrylate adhesive layer and which provides several of the above
mentioned features. Carriers such as Prespace Tape sold by 3M under
the trade designation SCPS-2, and Premask Tape sold by 3M under the
trade designation SCPM-3 can also be used.
[0061] In more preferred embodiments, the carrier has a release
surface. The release surface facilitates the unwinding of the
carrier when it is provided in the form of a roll and/or
facilitates the unwinding of the article (without unintended
detachment of sheeting segments) when the article is in the form of
a roll.
[0062] Suitable release surfaces include low adhesion backsize
("LAB") coatings such as are known in the adhesive tape arts.
Suitable LABs include typical silicone release coating materials
such as are used on the liner component provided with a graphic
article commercially available from 3M under the trade designation
"3M Scotchlite Premium Protective Overlay Film Series 1160."
Suitable LABs are also disclosed in U.S. Pat. Nos. 5,817,376;
5,962,546; 5,858,545.
[0063] Suitable articles of the present invention comprise a
plurality of discrete segments of a sheeting, e.g.,
retroreflective, reflective or non-reflective sheeting. Suitable
such sheeting has a first major viewing surface and a second major
opposing surface. In preferred embodiments the first major viewing
surface of the sheeting is removably attached to the second major
surface of the carrier.
[0064] Suitable retroreflective sheeting includes "beaded-type"
retroreflective sheeting (e.g., exposed lens, enclosed lens, and
encapsulated lens sheeting) and "prismatic-type" or
"cube-corner-type" sheeting (e.g., encapsulated prismatic-type and
metalized prismatic sheeting). Suitable types of retroreflective
sheeting are described in ASTM D 4956-94 entitled "Standard
Specification for Retroreflective Sheeting for Traffic Control".
Brightness or retroreflectivity of the sheeting may be expressed as
the Coefficient of Retroreflection, R.sub.a. This is measured in
units of candelas/lux/square meter and is determined using ASTM E
810-94.
[0065] The retroreflective sheeting may be a flexible-type sheeting
or a more rigid-type sheeting. An advantage of the articles of the
present invention is that rigid-types of sheeting or less
extensible types of sheeting can be used, even on flexible
substrates such as are found on canvas-sided trucks.
[0066] Illustrative examples of exposed lens retroreflective
sheeting are disclosed in U.S. Pat. Nos. 2,326,634; 2,354,018;
2,354,048; 2,354,049; 2,379,702; and 2,379,741. Illustrative
examples of enclosed lens retroreflective sheeting are disclosed in
U.S. Pat. Nos. 2,407,680; 3,551,025; 3,795,435; 4,530,859;
4,588,258; 4,664,966; 4,775,219; 4,950,525; 5,064,272; and
5,882,771. Illustrative examples of encapsulated lens
retroreflective sheeting are disclosed in U.S. Pat. Nos. 3,190,178;
4,025,159; 4,663,213; 5,069,964; 5,605,761; 5,714,223; 5,812,316;
and 5,784,198. Illustrative examples of encapsulated prismatic-type
retroreflective sheeting are disclosed in U.S. Pat. Nos. 5,138,488;
5,450,235; 5,614,286; 5,706,132; 5,714,223; and 5,754,338.
Illustrative examples of other prismatic-type retroreflective
sheeting are disclosed in U.S. Pat. Nos. 5,914,812; 5,491,586;
5,642,222; 5,376,431.
[0067] When encapsulated-type sheeting is used it is preferred that
the segments be formed in such a way that the edges of the segments
are sealed to prevent moisture and/or dirt contamination. This can
be done in a variety of ways as is well appreciated in the art. For
example, when such sheeting is manufactured a seal-line can be
provided in the sheeting and the segments may be cut from the
sheeting by cutting through the seal-lines. Also, the sheeting can
be cut and the edges sealed in a later step by, for example, using
a sealing material along the unsealed edges. Also alternatively, in
certain embodiments of the present invention, the carrier itself
may extend beyond the edge of the sheeting and be used to form
sealed pockets (i.e., the carrier and the substrate together form a
pocket), with the sheeting being contained therein.
[0068] Preferred sheeting for use in the present invention
comprises an adhesive surface. The choice of adhesive is dictated
by many factors, for example, the type of substrate to which the
sheeting is to be adhered. In preferred embodiments the adhesive
will be a PSA. Most preferably the adhesive provides durability for
the intended life of the sheeting article. In addition to the
adhesives disclosed in the aforementioned patents, some
representative patents related to PSAs include: U.S. Pat. Nos.
5,861,211; 5,905,099; 5,820,988; 5,804,610; 5,639,530; 5,584,962;
5,580,417; 5,453,320; 5,391,015; 5,334,686; 4,985,488; 4,946,742;
and 4,248,748.
[0069] Suitable retroreflective sheeting can be provided in a
variety of colors, shapes, and/or have a variety of optical
properties. In certain preferred embodiments of the present
invention sheeting segments of more than one color or more than one
optical property may be employed. For example, a carrier might
comprise a plurality of "red" retroreflective sheeting segments
spaced there along and with large gaps between the red sheeting
segments. The large gaps, or portions of the large gaps, can then
be filled with a different (e.g., a "white") retroreflective
sheeting. The resultant article will comprise, for example,
alternating red and white sheeting. Alternatively, segments having
more than one retroreflective optical property (e.g., narrower or
broader entrance and/or observation angularity) may be used along a
carrier. For example, alternating segments that exhibit a
particular preferred entrance angularity direction or plane (e.g.,
left, right, up, down, horizontal, vertical) and fluorescent
properties may be positioned along the carrier to create a
conspicuity article.
[0070] In preferred embodiments of the present invention the
selection of adhesives and release surfaces are chosen to
facilitate manufacture, handling and/or use of the article. For
example, in certain embodiments the sheeting segments are designed
to be removably attached to the carrier. In these embodiments the
term "removably attached" means that the carrier is designed to be
temporarily attached to the sheeting. For example, the sheeting
segments are preferably well enough attached to the carrier that
they remain attached during manufacture and handling of the
article. However, in these embodiments the carrier is preferably
designed to be peeled off of the sheeting without damaging the
sheeting or causing the sheeting segments to be prematurely removed
from the substrate to which they are applied. Also in this
embodiment, preferably the carrier is designed to easily be peeled
off of the substrate to which the article is applied. In more
preferred embodiments (e.g., where the carrier and the sheeting
each comprise a PSA and the carrier comprises a release surface),
the PSAs are chosen such that the carrier and sheeting can be
peeled off of the underlying layers of the roll without causing
sheeting segments to separate from the adhesive surface of the
carrier, and when the sheeting and carrier are applied to a
substrate the adhesion of the sheeting to the substrate is high
enough that the carrier can be peeled away from the sheeting
without causing segments of the sheeting to separate from the
substrate.
[0071] It is contemplated that this effect can be achieved in a
variety of ways. For example, the selection and use of suitable low
adhesion coatings (e.g., on the carrier or release liner or
optionally on the viewing surface of the sheeting) can help adjust
the adhesion properties. Also, the choice of adhesive, coating
weight of the adhesive, or texture of the adhesive can be chosen to
accomplish this end.
[0072] It is contemplated that articles of the present invention
may be provided in a variety of forms. For example, for truck
conspicuity purposes the articles conveniently may be provided as
long strips which may be fan folded, stacked (e.g., in a pad), in
roll form or packaged in some other manner. A preferred form is as
a roll.
[0073] Suitable articles may include liners to protect the surfaces
of the article. For example, a release liner may be used to protect
an adhesive surface (e.g., a tacky adhesive surface) prior to its
application against a substrate. Alternatively, the article itself
may comprise a suitable release surface (e.g., on the carrier) such
that when the article is provided in a pad or roll form the
adhesive surfaces can be protected. This embodiment has a couple of
advantages. First, it avoids the need for a separate liner, thus
saving cost. Second, the user doesn't have to handle a separate
liner or provide for its disposal.
[0074] The features of the present invention are useful in the
manufacture or use of a variety of articles. One such preferred
article is a vehicle conspicuity article (e.g., an article for use
on a car, truck, boat, railroad car, plane, trailer, ground
handling equipment, farm equipment, bicycle, motorcycle, etc.).
Other uses include barrel wrap conspicuity articles (e.g., for use
on barrels), traffic cone and tube conspicuity articles, barrier
conspicuity articles (such as for use of roadways), flexible
signage, helmets (e.g., bicycle helmets), backpacks, and apparel
(e.g., safety vests and jackets).
[0075] For use as a vehicle conspicuity article the article is
preferably provided in a form acceptable to the respective
governing body. One regulation of particular note is the United
Nations "Agreement Concerning The Adoption Of Uniform Technical
Prescriptions For Wheeled Vehicles, Equipment And Parts Which Can
Be Fitted And/Or Used On Wheeled Vehicles And The Conditions For
Reciprocal Recognition Of Approvals Granted On The Basis Of These
Prescriptions (Rev. 2/Add. 103; E/ECE/324; E/ECE/Trans/505)". This
document provides, among other things, for various specifications
for conspicuity sheeting. Preferred sheeting of the present
invention meets or exceeds these specifications.
[0076] Additional embodiments of the present invention were
realized upon detailed analysis of common failures of
retroreflective sheeting adhered to a flexible substrate such as
canvas. The purpose of the analysis was to determine advantageous
properties for mounting retroreflective sheeting to a canvas
substrate. As described above, canvas flexes easily especially when
used as a side of a truck. When flexed, the canvas bends. If the
position of the segment is such that free bending of the canvas at
the gap between segments does not occur then the retroreflective
sheeting disposed thereon is forced to react. Retroreflective
sheetings are typically laminate structures. The retroreflective
sheeting-laminate will react based upon its material(s), layer
thickness(es), position and distribution of materials within the
laminate, and the ability of the adhesive to withstand applied
loads. In general, the retroreflective laminate can fail in any of
four modes.
[0077] The first mode of failure is illustrated in FIGS. 10A and
10B, and occurs when the bending of the canvas puts the first major
surface of the segment in tension and initiates a crack in the
first major surface. In FIG. 10A, the substrate 200 and segment 202
are flat. In FIG. 10B, substrate 200 has been bent, and cracks 204
in segment 202 are formed. Such cracking can occur after many
flexes or as a brittle failure on a single flex. Proper choice of
material flexibility for the intended use environment can avoid
this failure mode.
[0078] The second failure mode is illustrated in FIG. 11 and occurs
when an edge, such as edge 206 of segment 202 lifts, or otherwise
begins to peel back. This failure mode generally occurs when
segment edge 206 is located upon a portion of substrate 200 that is
bent. Segment 202 reacts applying a bending moment on the adhesive.
One of the manners in which this failure mode is remedied is by
choosing an adhesive that is specially adapted for the substrate.
One adhesive that works particularly well with canvas is a PSA as
described in U.S. Pat. No. 5,861,211. Although this adhesive is
particularly suited for canvas, those skilled in the art will
appreciate that any suitable adhesive can be used. However, even
the best adhesive can only withstand a finite bending moment from a
before it fails. Thus a second manner in which this failure mode is
remedied is by choosing laminates with small bending rigidities. It
is instructive to consider a simple, idealized case where the edge
is bent to a constant curvature. The moment applied to the adhesive
is approximated to be proportional to the rigidity of segment 202
and inversely proportional to the radius of the circle. For example
empirical evidence indicates that the PSA as described in U.S. Pat.
No. 5,861,211 at 70 degrees Celsius can withstand a bending moment,
M, from a segment up to about 6.times.10.sup.-3N*m before it
de-bonds from a test canvas, Verseidag Indutex/German, type
Duraskin 12 B129835. 3M # 981 retroreflective sheeting, a typical
rigid, sealed "prismatic-type" sheeting has a bending rigidity, D,
of about 6.times.10.sup.-5N*m.sup.2. Thus the radius to which the a
segment of 3M #981 and the PSA as described in U.S. Pat. No.
5,861,211 will withstand bending without edge-lift at 70 degrees
Celsius is
D/M=6.times.10.sup.-5N*m.sup.2/6.times.10.sup.-3N*m=1.times.10.sup.-2
m=10 mm. Adhesives that can withstand higher moments before failure
and/or use of less rigid segments would allow said segment to bend
to smaller radii before failing.
[0079] The third mode of failure is illustrated in FIG. 12 and
occurs when a jet of high pressure, fast flowing water 208 impinges
upon any edge of segment 202. It is believed that this failure mode
is also related to the adhesive. This type of failure is believed
not related to mechanical reactions, laminate properties, or any
width-length combination that would be unique to segments describe
here. Segments from thin and flexible to thick and stiff adhered to
canvas with an adhesive particularly suited for canvas seem not to
fail when exposure to a high pressure jet of water.
[0080] The fourth failure mode is illustrated in FIGS. 13A and 13B.
This failure mode occurs when the retroreflective segment 202 is
placed in compression, for example when the substrate 200 (such as
canvas) to which segment 202 adheres is flexed so as to bend
segment 202 around an inside arc. In this situation, a portion of
the retroreflective overlay segment 202 may buckle as illustrated
at wrinkle 210. The buckled portion 210 then lifts from substrate
200. A number of segments 202 made of five distinct laminates, each
laminate tested with widths between 13 mm and 50 mm and lengths
between 13 mm and 150 mm, were adhered to the test canvas Duraskin
12 B129835 and the constructions bent over various inside radii to
determine the minimum length that avoided wrinkling. Material
properties of and the five laminates relevant to the discussion
that follows are listed in Tables 1. TABLE-US-00001 TABLE 1a
Material Modulus .times. 10.sup.-8/Pa Poisson's ratio Glassy
thermoplastic.sup.1,2 6.9 0.3 semi-crystalline thermoplastic.sup.1
21 0.4 Thermoplastic elastomer.sup.2 0.21 0.5 .sup.1Materials used
in the rigid cube corner films. .sup.2Materials used in the
flexible cube corner films
[0081] TABLE-US-00002 TABLE 1b Laminate constructions, most
flexible to most rigid 1 3.8 mil glassy thermoplastic film 2
Sealed, most flexible cube corner film 3 Vapor coated,
semi-flexible cube corner film 4 Vapor coated, rigid cube corner
film 5 Sealed, rigid cube corner film
The test strips had widths W, lengths L, and were spaced apart by a
distance .delta.. The first observation was that if the distance
between the segment ends was too small, the ends butted up against
each other or slide one on top of the other as the canvas was
flexed. It appeared that the smallest .delta. that kept the ends
from butting was approximately: .delta. min .apprxeq. ( t / 2 R )
.times. L Equation .times. .times. 1 ##EQU1## where t was the
laminate thickness. (The term in brackets is the strain at the
first major surface of the segment.) The equations below provide
further details of this term.
[0082] The second observation was that, longer segment lengths
failed at larger radii than shorter segments while for a given
segment length, a more rigid segment would fail at smaller radius
than a less rigid segment. Using shorter lengths, more rigidity, or
limiting the radius above a certain size all served to attenuate
the likelihood of this wrinkle failure mode. Table 2 list minimum
lengths that were observed to avoid this failure mode for segment
of the five test laminate constructions bent around a 6.4 mm
radius. TABLE-US-00003 TABLE 2 Laminate constructions, most
flexible minimum length to to most rigid avoid wrinkles 1 3.8 mil
glassy thermoplastic film 51 mm 2 Sealed, most flexible cube corner
film 51 mm 3 Vapor coated, semi-flexible cube corner film 64 mm 4
Vapor coated, rigid cube corner film 64 mm 5 Sealed, rigid cube
corner film 83 mm
[0083] The following derivations are useful for analytically
predicting segment failure by wrinkling. The derivations apply
strictly to elastic materials. Laminates are assumed to be made up
of isotropic laminae. Applied loads, deformations, and reactions
are illustrated in one dimension only. When an initially flat
laminate bends along one axis into a radius, R, the surface to the
inside of the cylinder formed compresses while the outside surface
is placed in tension. For a segment that might be made of a single
layer of material (e.g. laminate construction #1) the plane midway
between the surfaces is neutral since it is in neither compression
nor tension. The strains, .delta., at the surfaces of the layer are
as follows: = t / 2 R .times. .times. for .times. .times. an
.times. .times. initially .times. .times. flat .times. .times.
single .times. .times. layer , Equation .times. .times. 2 .times. a
##EQU2##
[0084] Retroreflective sheetings are laminates where the neutral
axis is a more complex function of the position in and moduli of
the materials that make up the laminate. For the case of a
laminate, the numerator of EQN. 2a is the distance, y.sub.n, of the
first major surface to the neutral axis. The plane of the neutral
axis, like the mid-plane of the single layer, is in neither
compression nor tension when the laminate is flexed. In such case,
the first major surface reacts with the strain expressed in EQN.
2b: = y n R .times. .times. for .times. .times. an .times. .times.
initially .times. .times. flat .times. .times. laminate , Equation
.times. .times. 2 .times. b ##EQU3## The total compressive stress
on the laminate, P.sub.comp, can be found using EQN. 3.
P.sub.comp=.epsilon..times.A, Equation 3 where A is the extensional
stiffness of the laminate. For a segment of one material layer, A =
( Et ( 1 - v 2 ) ) . Equation .times. .times. 4 .times. a ##EQU4##
where E is the modulus, and v is Poisson's ratio. For the case of a
laminate comprised of `N` laminae, as we discuss here, A is
calculated as the sum of modulus of the individual laminae weighted
by its respective thickness, where i denotes the i-th lamina. For
the lamina containing the first major surface, i=1. E.sub.i,
t.sub.i, and v.sub.i are the modulus, thickness, and Poisson's
ratio respectively, of the i-th lamina. A = i = 1 N .times. E i
.times. t i ( 1 - v i 2 ) , Equation .times. .times. 4 .times. b
##EQU5##
[0085] The neutral axis is located a depth y.sub.n from the first
major surface of the laminate where one can calculate y.sub.n from
EQN. 4c. y n = 1 2 .times. i = 1 N .times. { E ( 1 - v i 2 )
.function. [ ( j = 1 i .times. t j ) 2 - ( k = 0 i - 1 .times. t k
) 2 ] } i = 1 N .times. E i .times. t i ( 1 - v i 2 ) , .times.
where .times. .times. t 0 = 0. Equation .times. .times. 4 .times. c
##EQU6##
[0086] The units of P.sub.comp and A are in force per length. A
segment whether comprised of a single layer or a laminate will flex
without wrinkling if P.sub.comp is below a critical threshold,
P.sub.cr. If P.sub.comp is greater than P.sub.cr, then the segment
wrinkles in response to the compressive load. The critical
threshold, P.sub.cr is a proportional to the ratio of the bending
rigidity of the segment to the square of its length or: P cr
.ident. k .times. .times. D L 2 . Equation .times. .times. 5
##EQU7## D is the bending rigidity of the retroreflective laminate.
For a single layer segment, D = E .times. .times. I / W ( 1 - v 2 )
, Equation .times. .times. 6 .times. a ##EQU8## where I is the
moment of inertia for the layer, I=t.sup.3W/12. For the case of a
laminate D is calculated as the sum over all laminae of the product
of modulus of the individual laminae to the cube of the distance
that laminae is from the neutral axis. A straightforward algorithm
to calculate rigidity is: D = 1 3 .times. i = 1 N .times. E i ( 1 -
v i 2 ) .times. ( z i 3 - z i + 1 3 ) . , Equation .times. .times.
6 .times. b ##EQU9## where z.sub.i is the distance from mid-plane
of the laminate to the interface between the i-th and (i-th+1)
laminae. For example: z.sub.0 is the distance from the mid-plane to
the first major surface; Z.sub.N is the distance from the mid-plane
to the second major surface. Note, z.sub.0-z.sub.1 equals t.sub.1,
z.sub.1-z.sub.2=t.sub.1 and so on; z.sub.0-z.sub.N is the thickness
of the laminate.
[0087] The proportionality, k, between the left side and right side
of EQN. 5 depends on edge constraints, and other factors that add
complexity. We derive an empirical relationship based on
experiments with the five laminate constructions. Combining EQNS. 2
and 3 and setting EQN. 5, the critical compressive load, to less
than EQN. 2, the compressive load of the bent segment, yields an
expression that defines the longest segment length that avoids
wrinkle failure. L max .ltoreq. [ k .function. ( D A ) .times. ( R
y n ) ] 1 / 2 . Equation .times. .times. 7 ##EQU10## For the case
of a single lamina (D/A)=t.sup.2/12, y.sub.n=(t/2), and EQN. 7
reduces to: L max .ltoreq. [ k .times. t 2 .times. R 12 .times. ( t
2 ) ] 1 / 2 = [ ( k 6 ) .times. Rt ] 1 / 2 = [ k ' .times. Rt ] 1 /
2 . Equation .times. .times. 8 ##EQU11##
[0088] When the laminae of a laminate are composed of materials
with similar moduli, the simpler EQN. 8 is essentially identical to
the more rigorous EQN. 7. In what follows we will use the more
rigorous EQN. 7. Table 3 lists the laminate properties of the
constructions first shown in Table 2. TABLE-US-00004 TABLE 3
Neutral Stiffness * 10.sup.-4 Rigidity * 10.sup.4 axis,
Construction A/(N/m) D/(N*m) y.sub.n/mm 1 3.8 mil glassy 0.97 0.76
0.048 thermoplastic film 2 Sealed, most flexible 1.1 1.8 0.12 cube
corner film 3 Vapor coated, semi- 1.5 5.4 0.13 flexible cube corner
film 4 Vapor coated, 2.3 9.8 0.13 rigid cube corner film 5 Sealed,
rigid cube 2.6 24 0.20 corner film
[0089] Table 4, shown below, combines the results listed first in
Table 2 and the values calculated as suggested from EQN. 7.
TABLE-US-00005 TABLE 4 Minimum length/mm to (D/A *
(R/y.sub.n)).sup.1/2/mm Construction avoid wrinkles, L.sub.min R =
6.4 mm 1 51 0.33 2 51 0.30 3 64 0.43 4 64 0.46 5 83 0.56
[0090] FIG. 9 shows a plot of (D/A*(R/y.sub.n)).sup.1/2 vs.
L.sub.min for laminates of the study adhered to the test canvas
substrate and bent around a mandrel having a radius of 6.4 mm. A
linear regression fit is shown, as well as the equation and R.sup.2
values. Using the regression fit shown in FIG. 9, a generalization
about the minimum segment length that avoids the
compression-wrinkling failure for a laminate-segment of specific
stiffness and rigidity if forced to bend when a canvas is flexed
can now be made. Specifically, where the conditions of EQN. 11 are
met, wrinkling is generally avoided. L min / mm .ltoreq. 120
.times. ( D A ) 1 / 2 .times. ( R y n ) 1 / 2 + 12 .times. .times.
.times. R 2 = 0.95 Equation .times. .times. 11 ##EQU12##
[0091] The properties of the article relate to the final article,
i.e., the article as used on the substrate. For example, if the
carrier is meant to be removed from the final article as used on
the substrate, then the carrier is not included in the calculations
for the article.
[0092] The present invention has now been described with reference
to several embodiments thereof. The foregoing detailed description
and examples have been given for clarity of understanding only; no
unnecessary limitations are to be understood therefrom. It will be
apparent to those skilled in the art that many changes can be made
in the embodiments described without departing from the scope and
spirit of this invention. Thus, the scope of the present invention
should not be limited to the exact details and structures described
herein, but rather by the structures described by the language of
the claims, and the equivalents of those structures.
[0093] For use on vehicles having flexible sides (e.g.,
canvas-sided truck), it has been found that preferred sheeting
segments have a length sufficient to accommodate any required
homologation marking, more preferably have a length of at least 12
mm, most preferably at least 24 mm and optimally at least 48 mm. A
suitable sheeting segment may be up to several feet long, if
desired. Sheeting width is typically between about 30 mm and about
120 mm, more preferably between about 40 and about 100 mm. The gap
size between adjacent segments may be regulated by a governmental
body. Often the preferred gap size is that which meets the
applicable regulation. For example, in the United States a
preferred gap size is equal to the length of the shortest adjacent
segment. In Europe, the gap size is preferably equal to one-half
the length of the shortest adjacent segment.
[0094] Notwithstanding the above regulations, on canvas substrates
the segment size and gap size are preferably chosen based upon the
physical properties of the substrate. Free bending is facilitated
when the sheeting segments are shorter. Also, the preferred gap
size is somewhat dependant on the thickness of the substrate, with
preferred minimum gap size being at least 2-4 times the thickness
of the substrate. For a typical 50 mm long segment on a 0.53 mm
thick canvas truck-side, the gap size is preferably at least about
4 mm. Larger gaps may be utilized, if desired.
[0095] The articles of the present invention can be made in a
variety of ways. One preferred method comprises the steps of: (1)
providing an elongate strip of a carrier having a first major
surface and a second major surface; (2) providing an elongate strip
of a retroreflective sheeting, wherein the sheeting has a first
major viewing surface and a second major opposing surface
(preferably an adhesive surface); (3) cutting the strip of
retroreflective sheeting into discrete segments; and (4) attaching
the first major viewing surface of the sheeting to the second major
surface of the carrier. If desired more than one type of sheeting
can be attached to the carrier. This may be done, for example, by
sequentially attaching segments of a first sheeting type along the
carrier and attaching segments of a second or subsequent type of
sheeting in gaps between the first type of sheeting.
[0096] It may be desirable to rotate a sheeting segment prior to
attaching it to the carrier. This may be done, for example, to
conserve material. A diamond pattern can be cut with minimal waste
from a strip of sheeting when cut as rectangles and then rotated 45
degrees. Also, a sheeting having a particular angularity (e.g.,
leftward) can be cut into squares and rotated 90 degrees, 180
degrees and 270 degrees to provide upward, rightward and downward
angularity.
[0097] In another process a strip of sheeting can be provided on a
stretchable liner, "kiss-cut" through the sheeting to the depth of
the liner to form a plurality of segments on the liner; and
stretched in one or more directions (e.g., lengthwise or widthwise,
etc.) to separate the segments. A carrier can then be laminated to
the separated segments (and the liner optionally removed) to
provide a segmented sheeting article. This method generally
includes the steps of: providing an elongate strip of a
retroreflective sheeting on a release liner, wherein the sheeting
has a first major viewing surface and a second major opposing
adhesive surface protected by the liner; cutting (e.g.,
"kiss-cutting") the elongate strip of retroreflective sheeting into
smaller discrete segments on the liner; stretching the liner in at
least one direction (e.g., lengthwise or widthwise, etc.) to
separate segments; and attaching, preferably "removably" attaching,
the first major viewing surface of the sheeting to a second major
surface of an elongate strip of a carrier having a first major
surface and the second major surface
[0098] In another process a strip of sheeting can be provided on a
liner, "kiss-cut" to the depth of the liner to form a plurality of
segments on the liner; and pieces of the sheeting removed to
separate the remaining segments. A carrier can then be laminated to
the separated segments (and the liner optionally removed) to
provide a segmented sheeting article. In the event that the removed
sheeting is not reused or reusable, this process is presently less
preferred due to the resultant waste of the removed sheeting. This
method generally includes the steps of: providing an elongate strip
of a retroreflective sheeting on a release liner, wherein the
sheeting has a first major viewing surface and a second major
opposing adhesive surface protected by the liner; cutting (e.g.,
"kiss-cutting") the elongate strip of retroreflective sheeting into
smaller discrete segments on the liner; removing selected portions
of the sheeting to separate the remaining segments; and attaching
the first major viewing surface of the sheeting to the second major
surface of an elongate strip of a carrier having a first major
surface and a second major surface.
[0099] Several methods may be employed when applying the
retroreflective conspicuity article to a vehicle. One preferred
process involves the steps of: (1) providing an elongate strip of a
conspicuity article having a carrier having a first major surface
and a second major surface and a plurality of discrete segments of
a retroreflective sheeting, wherein the sheeting has a first major
viewing surface and a second major opposing adhesive surface, and
wherein the first major viewing surface of the sheeting is
removably attached to the second major surface of the carrier; (2)
exposing the second major opposing adhesive surface of the
sheeting; (3) applying the adhesive surface of the sheeting to a
surface of a vehicle to thereby adhere the sheeting to the vehicle.
The applying step may optionally include the step of stretching the
carrier to position the sheeting segments in desired position
(e.g., around a corner, over a fold line in a canvas truck siding,
over a rivet, etc.). Gaps in the article may also be shortened,
when desired, by simply pushing the segments closer together.
[0100] In preferred embodiments the carrier is then removed to
expose the viewing surface of the sheeting. This may be done, for
example, by peeling the carrier off.
[0101] If desired, the above process may be performed multiple
times along a substrate, e.g., to cause more than one type of
sheeting to be adhered to the substrate. For example, a first
application can provide a segmented article to be applied having
large gaps between segments. A second application of a segmented
article can be performed along the same line, thereby placing a
second sheeting in a portion of the gaps.
[0102] A further advantage of the segmented articles of the present
invention is that damaged segments may be easily repaired or
replaced without having to cut the applied article.
[0103] The following examples are offered to aid in understanding
of the present invention and are not to be construed as limiting
the scope thereof. These examples are offered to further illustrate
the various specific and preferred embodiments and techniques and
to further explain certain features and advantages. It should be
understood, however, that many variations and modifications may be
made while remaining within the scope of the present invention.
Unless otherwise indicated, all parts and percentages are by
weight.
EXAMPLES
Example 1
[0104] Conspicuity Articles [0105] (A) The following
retroreflective sheeting materials were cut to the size and shape
noted and used to construct various conspicuity articles: [0106]
(A1) 3M # 970 retroreflective sheeting--55 mm.times.55 mm square
segments. [0107] (A2) 3M # 983 retroreflective sheeting--55
mm.times.55 mm square segments. [0108] (A3) 3M # 981
retroreflective sheeting--55 mm.times.55 mm square segments. [0109]
(A4) 3M # 981 retroreflective sheeting--14 mm.times.55 mm
rectangular segments. [0110] (A5) Sheeting available from Reflexite
Corporation of Avon, Connecticut sold under the trade designation
"VC 104 Patt WH Curtain Grade Sheeting." Metalized, 50 mm.times.50
mm square segments. [0111] (A6) Sheeting available from Stimsonite
Corporation of Parsippany, N.J. sold under the trade designation
"4500 Sheeting." Metalized 52 mm.times.52 mm square segments.
[0112] (B) As a test substrate the following canvas was used:
[0113] (B1) Verseidag Indutex/German, type Duraskin 12 B129835,
Color #070 blue.
[0114] The thickness of this canvas was about 0.53 mm. [0115] (C)
The following materials were used as an illustrative carriers:
[0116] (C1) 3M product # TPM-5 ECF film. This is a polyethylene
film with a low tack adhesive on one side and a silicone release
coating on the opposite side. The thickness of this material is
about 0.14 mm. [0117] (C2) 3M polyethylene Type 3112 tape. This is
a low density polyethylene with low-tack adhesive on one side and a
thickness of about 0.08 mm. [0118] (D) The following material was
used as an illustrative release liner: [0119] (D1) A Co-poly
release liner film (about 0.085 mm thick) that comprises a
propylene copolymer and is coated with a silicone polymer. Suitable
liners are commercially provided with the aforementioned 3M #981
sheeting.
Example 1 Run 1
[0120] A conspicuity sheeting article was constructed according to
FIG. 2a, wherein carrier 16 comprises the aforementioned carrier
(C1) having a width equal to sheeting 12; sheeting 12 comprises 3M
# 981 retroreflective sheeting--55 mm.times.55 mm square segments;
and liner 24a comprises the aforementioned liner (D1). Gaps between
segments were between about 20 and 30 mm. In one embodiment
alternating segments were rotated 90 degrees to give a tiling
effect.
Example 1, Run 2
[0121] A conspicuity sheeting article was constructed according to
FIG. 2a, wherein carrier 16 comprises the aforementioned carrier
(C1) having a width equal to sheeting 12; sheeting 12 comprises 3M
# 970 retroreflective sheeting--55 mm.times.55 mm square segments;
and liner 24a comprises the aforementioned liner (D1). Gaps between
segments were between about 20 and 30 mm.
Example 1, Run 3
[0122] A conspicuity sheeting article was constructed according to
FIG. 2a, wherein carrier 16 comprises the aforementioned carrier
(C1) having a width equal to sheeting 12; sheeting 12 comprises 3M
# 983 retroreflective sheeting--55 mm.times.55 mm square segments;
and liner 24a comprises the aforementioned liner (D1). Gaps between
segments were between about 20 and 30 mm.
Example 1, Run 4
[0123] A conspicuity sheeting article was constructed according to
FIG. 2a, wherein carrier 16 comprises the aforementioned carrier
(C1) having a width equal to sheeting 12; sheeting 12 comprises
Reflexite, VC 104 Patt WH Curtain Grade Sheeting. Metallized, 50
mm.times.50 mm square segments; and liner 24a comprises the
aforementioned liner (D1). Gaps between segments were between about
20 and 30 mm.
Example 1, Run 5
[0124] A conspicuity sheeting article was constructed according to
FIG. 2a, wherein carrier 16 comprises the aforementioned carrier
(C1) having a width equal to sheeting 12; sheeting 12 comprises
Stimsonite, 4500 Sheeting. Metallized 52 mm.times.52 mm square
segments; and liner 24a comprises the aforementioned liner (D1).
Gaps between segments were between about 20 and 30 mm.
Example 1, Run 6
[0125] A conspicuity sheeting article was constructed according to
FIG. 7a, wherein carrier 16 comprises the aforementioned carrier
(C1) having a 65 mm width; sheeting 12 comprises 3M # 983
retroreflective sheeting--55 mm.times.55 mm square segments; and
liner 24a comprises the aforementioned liner (D1). Gaps between
segments were between about 20 and 30 mm. In this embodiment
carrier extends past the sheeting segments and provides additional
adhesion to a substrate.
Example 1, Run 7
[0126] A conspicuity sheeting article is constructed according to
FIG. 2a, wherein carrier 16 comprises the aforementioned carrier
(C1) having a width of 55 mm; sheeting 12 comprises 3M # 981
retroreflective sheeting--14 mm.times.55 mm rectangular segments;
and liner 24a comprises the aforementioned liner (D1). Gaps between
segments are suitably between about 4 and 7 mm.
Example 1, Run 8
[0127] A conspicuity sheeting article was constructed according to
FIG. 2a, wherein carrier 16 comprises the aforementioned carrier
(C1) having a width equal to sheeting 12; sheeting 12 comprises 3M
# 981 retroreflective sheeting--55 mm.times.55 mm square segments
(cut to provide red or white color segments); and liner 24a
comprises the aforementioned liner (D1). Gaps between segments were
between about 20 and 30 mm and alternating segments were colored
either red or white.
Example 1, Run 9
[0128] A conspicuity sheeting article was constructed according to
FIG. 2a, wherein carrier 16 comprises the aforementioned carrier
(C2) having a width equal to sheeting 12; sheeting 12 comprises 3M
# 981 retroreflective sheeting--55 mm.times.55 mm square segments;
and liner 24a comprises the aforementioned liner (D1). Gaps between
segments were between about 20 and 30 mm. In one embodiment
alternating segments were rotated 90 degrees to give a tiling
effect.
[0129] The present invention has now been described with reference
to several embodiments thereof. The foregoing detailed description
and examples have been given for clarity of understanding only; no
unnecessary limitations are to be understood therefrom. It will be
apparent to those skilled in the art that many changes can be made
in the embodiments described without departing from the scope and
spirit of this invention. Thus, the scope of the present invention
should not be limited to the exact details and structures described
herein, but rather by the structures described by the language of
the claims, and the equivalents of those structures.
[0130] Unless otherwise indicated herein or during examination, for
purposes of both examination and construction of the appended
claims: a claim written in a "Product-by-process" format shall be
examined and construed as not being limited to products prepared by
the particular process set forth in the claim; a claim that uses
the term "means for" shall be examined and construed as being
within the meaning of section 112(6); and claims that do not use
the term "means for" shall be examined and construed as not being
within the meaning of section 112(6); and the steps of a method
claim may be performed in any order and are not to be limited to
the order presented.
[0131] The section headings in this document are inserted for
convenience only and shall not constitute a part hereof. The
present invention may be suitably practiced in the absence of any
element not specifically described above.
* * * * *