U.S. patent application number 10/348394 was filed with the patent office on 2003-07-17 for removable adhesive tape.
This patent application is currently assigned to 3M Innovative Properties Company. Invention is credited to Hager, Patrick J., Kreckel, Karl W., Rickert, James H..
Application Number | 20030134112 10/348394 |
Document ID | / |
Family ID | 27370090 |
Filed Date | 2003-07-17 |
United States Patent
Application |
20030134112 |
Kind Code |
A1 |
Kreckel, Karl W. ; et
al. |
July 17, 2003 |
Removable adhesive tape
Abstract
A removable adhesive tape comprising a highly extensible and
substantially inelastic backing and a layer of pressure-sensitive
adhesive. The backing has a high tensile strength, has a lengthwise
elongation at break of at least about 150% with less than about 50%
elastic recovery after stretching. The adhesive can be a normally
tacky and pressure-sensitive adhesive and is coated on at least one
surface of the film backing. The adhesive is preferably highly
extensible, does not separate from the backing during stretching,
and has higher cohesion than adhesion to any suitable substrate.
After being applied to a substrate, the adhesive tape of the
present invention becomes firmly bonded, but can be easily removed
without damaging the substrate by simply stretching it in a
direction substantially parallel, i.e., less than about 35.degree.,
to the surface of the substrate.
Inventors: |
Kreckel, Karl W.;
(Benzenbergweg, DE) ; Hager, Patrick J.;
(Woodbury, MN) ; Rickert, James H.; (Marine,
MN) |
Correspondence
Address: |
3M INNOVATIVE PROPERTIES COMPANY
PO BOX 33427
ST. PAUL
MN
55133-3427
US
|
Assignee: |
3M Innovative Properties
Company
|
Family ID: |
27370090 |
Appl. No.: |
10/348394 |
Filed: |
January 21, 2003 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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10348394 |
Jan 21, 2003 |
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09447506 |
Nov 23, 1999 |
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6527900 |
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09447506 |
Nov 23, 1999 |
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08835547 |
Apr 8, 1997 |
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5989708 |
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08835547 |
Apr 8, 1997 |
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08467359 |
Jun 6, 1995 |
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08467359 |
Jun 6, 1995 |
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08259747 |
Jun 6, 1994 |
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5516581 |
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08259747 |
Jun 6, 1994 |
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08061637 |
May 12, 1993 |
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08061637 |
May 12, 1993 |
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07802061 |
Dec 10, 1991 |
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07802061 |
Dec 10, 1991 |
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07632173 |
Dec 20, 1990 |
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Current U.S.
Class: |
428/343 ;
428/189; 428/352; 428/354 |
Current CPC
Class: |
C09J 7/24 20180101; Y10T
428/2848 20150115; Y10T 428/249983 20150401; Y10T 428/2839
20150115; Y10T 428/24752 20150115; Y10T 428/2861 20150115; Y10T
156/1147 20150115; A47G 1/175 20130101; C09J 2301/308 20200801;
Y10T 428/1303 20150115; Y10T 428/28 20150115 |
Class at
Publication: |
428/343 ;
428/354; 428/352; 428/189 |
International
Class: |
B32B 003/00; B32B
007/12; B32B 015/04 |
Claims
What is claimed is:
1. A tape comprising a highly extensible, substantially
non-recoverable backing bearing on at least one major surface
thereof a layer of pressure-sensitive adhesive, said tape being
capable of being firmly bonded to a substrate and further being
capable of being removed therefrom after only being stretched at an
angle no greater than about 35.degree. from the surface of the
substrate.
2. The tape of claim 1, wherein said backing has a Young's modulus
of at least about 2,500 psi and less than about 50,000 psi.
3. The tape of claim 1, wherein said backing has an elastic
recovery of less than about 50% after being stretched.
4. The tape of claim 1, wherein said backing has a lengthwise
elongation at break of at least about 150%.
5. The tape of claim 1, wherein said pressure-sensitive adhesive
having an adhesion value of from about 3 N/dm to about 200 N/dm at
a peel angle of 180.degree. at a peel rate of 12.7 cm/min.
6. The tape of claim 1, wherein said backing is made from a
material selected from the group consisting of polyolefins, vinyl
copolymers, olefinic copolymers, acrylic polymers and copolymers,
and combinations of the foregoing.
7. An article suitable for adhering to a surface comprising a
substrate bearing on one major surface thereof a tape according to
claim 1, wherein said tape can be removed from the surface to which
said article is adhered by causing said backing to elongate at
least about 150% of its initial length.
8. The article of claim 7, wherein said substrate bears on one
major surface thereof a means for hanging articles.
9. A closure assembly for a container comprising a tape according
to claim 1, wherein said tape can be removed from two surfaces by
causing said backing to elongate to at least about 150% of its
initial length.
10. The closure assembly of claim 9, wherein said container is a
box comprising a bottom panel, at least one side panel projecting
upwardly from said bottom panel, at least two top panels projecting
from said at least one side panel and joining to close said
container.
11. The closure assembly of claim 9, wherein said container has a
gabled-top.
12. Assembly comprising two coplanar surfaces, and a tape according
to claim 1, wherein said coplanar surfaces are joined by means of
said tape, wherein said tape can be removed from said coplanar
surfaces by causing said backing to elongate at least about 150% of
its initial length.
13. A label comprising the tape of claim 1.
14. The tape of claim 1, wherein both major surfaces of said
backing bear a layer of pressure-sensitive adhesive.
15. A closure assembly for a container comprising a tape according
to claim 14, wherein said tape can be removed from two surfaces by
causing said backing to elongate to at least about 150% of its
initial length.
16. The closure assembly of claim 15, wherein said container is a
box comprising a bottom panel, at least one side panel projecting
upwardly from said bottom panel, at least two top panels projecting
from said at least one side panel and joining to close said
container.
17. The closure assembly of claim 16, wherein said container has a
gabled-top.
18. Assembly comprising two coplanar surfaces, and a tape according
to claim 14, wherein said coplanar surfaces are joined by means of
said tape, wherein said tape can be removed from said coplanar
surfaces by causing said backing to elongate at least about 150% of
its initial length.
Description
BACKGROUND OF THE INVENTION
[0001] 1. Field of the Invention
[0002] The present invention relates to adhesive tapes, more
particularly to tapes that can be firmly adhered to a substrate and
can be removed without damaging the substrate.
[0003] 2. Discussion of the Art
[0004] Adhesive tapes, such as, for example, pressure-sensitive
adhesive tapes, are usually firmly bonded to substrates because
subsequent separation of the tapes from the substrates is neither
intended nor desired. However, there are adhesive tapes wherein the
adhesives are specifically formulated to allow clean and easy
removal from substrates after use, such as, for example, the
adhesive used for "Post-It" brand removable notes. These adhesives
usually do not exhibit a substantial level of holding power, e.g.,
greater than 4 to 6 oz./in. adhesion to standard copy paper.
Adhesives formulated to provide a substantial level of adhesion,
e.g., greater than 30 oz./in. adhesion to paper, are generally
difficult to remove without damaging the substrate.
[0005] U.S. Pat. No. 4,024,312 discloses a film backed, normally
tacky and pressure-sensitive adhesive tape which is highly
extensible and highly elastic. The tape can be easily removed from
a surface to which it has been applied by stretching it lengthwise
in a direction substantially parallel to the plane of the surface.
The film backing is formed from a composition comprising
elastomeric and thermoplastic A-B-A block copolymers, and possesses
a lengthwise elongation to break of at least about 200%, preferably
at least about 300%, and a 50% rubber modulus of not above about
2,000 lbs/sq. inch. This low rubber modulus is stated to be an
important factor in insuring easy stretchability and easy removal
of the tape at high elongations. The elasticity of the backing is
important for conformability and other purposes and the elastic
recovery from 50% stretch is preferably at least about 75%, more
preferably at least about 90%. A preferred use for this tape is the
so-called "ouchless" bandage. German (OS) 3331 016 A1 discloses
another adhesive tape for removable adhesive bonds, whereby the
tape exhibits high elasticity and low plasticity. The adhesive
strength is less than the cohesive strength, and the adhesion
capability essentially disappears as the film is being stretched.
The ratio of peel force to tear strength of the tape is about 1:2
or greater and the adhesive bond can be released by pulling the
film in the direction of the plane of the adhesive joint. The tape
is used as a load-resistant adhesive to bond to rigid solid
substrates. A separation of the adhesively bonded materials is
possible without damage to the substrate.
[0006] Both of these tapes are highly elastic and exhibit large
recoil when the stretching force is removed, in the same way a
rubber band snaps back upon removal of the stretching force. This
recoil characteristic can be dangerous, and increases the force
required to debond these tapes at low angles. Finally, these highly
elastic tapes tend to substantially recover their-original shape
when the stretching force is removed, and they are therefore not
useful for indication of tampering or for guaranteeing single uses
for hygienic purposes.
SUMMARY OF THE INVENTION
[0007] The present invention provides an easily removable,
pressure-sensitive adhesive tape comprising a highly extensible,
substantially non-recoverable backing, bearing on at least one
major surface thereof a layer of pressure-sensitive adhesive, said
tape being capable of being firmly bonded to a substrate and being
further capable of being removed therefrom after only being
stretched at an angle no greater than about 35.degree. from the
surface of the substrate.
[0008] The backing has a Young's modulus of at least about 2,500
psi, preferably at least about 3,000 psi, but less than about
50,000 psi, more preferably between about 5,000 and about 30,000
psi. The backing preferably has a high tensile strength, a
lengthwise elongation at break of at least about 150%, and low
recovery, e.g., less than about 50% elastic recovery after being
stretched, preferably less than about 30% elastic recovery.
[0009] The adhesive layer has sufficient shear strength and
adhesive holding power for the specific applications, its adhesive
holding power to any substrate preferably being less than its
cohesive strength, such that the adhesive layer will not separate
from the backing when the backing is subjected to stretching. The
adhesive layer is also preferably highly extensible.
[0010] The tape can be firmly bonded to a substrate and can then be
removed by simply stretching the tape in a direction up to an angle
of about 35.degree. from the surface of the substrate, preferably
up to about 30.degree., more preferably up to about 10.degree.
without leaving traces of adhesive residue on the substrate and
without imparting any perceptible damage to the surface of the
substrate.
[0011] This invention further provides a double coated tape
comprising a backing bearing adhesive layers on both major surfaces
thereof. The adhesive of each layer can be of equivalent or
different chemical composition, of equivalent or different adhesion
properties, of equivalent or different thickness, and coated or
laminated in the same or different manner.
[0012] The tapes of this invention can be used for several
purposes. The major uses of the tape of this invention are in the
broad categories of mounting and joining. Both of these categories
typically involve attachment of two coplanar surfaces by means of
the tape, the tape typically bearing adhesive on both major
surfaces thereof. Other uses of the tape of this invention are in
the categories of labeling and masking. Both of these categories
typically involve attachment of the tape to a single surface, the
tape typically bearing adhesive on one major surface thereof
only.
BRIEF DESCRIPTION OF THE DRAWINGS
[0013] FIG. 1a is an enlarged side view in cross-section of a tape
of the present invention with the backing being unstretched.
[0014] FIG. 1b is an enlarged side view in cross-section of a tape
of the present invention with the backing being stretched but the
adhesive still holding to the substrate.
[0015] FIG. 1c is an enlarged side view in cross-section of a tape
of the present invention with the backing being stretched and the
adhesive beginning to cease holding to the substrate.
[0016] FIG. 2 is an enlarged side view in cross-section of a tape
of the present invention having adhesive layers on both major
surfaces thereof and an adhesive-free tab.
[0017] FIG. 3A is a perspective view of a mounting hook employing
the tape of the present invention as a means for adhering to a
vertical surface.
[0018] FIG. 3B is a view in cross-section of the mounting hook of
FIG. 3A taken along line B-B of FIG. 3A.
[0019] FIG. 4 is a front view of an object, e.g., a painting,
calendar, etc. adhered to a vertical surface by means of the tape
of the present invention.
[0020] FIG. 5 is a perspective view of two packages joined together
by a double-sided tape of the present invention.
[0021] FIG. 6 is a perspective view of a package employing the tape
of the present invention as a closure.
[0022] FIG. 7 is an enlarged side view in cross-section of a tape
of the present invention having a single layer of adhesive and an
adhesive-free tab.
[0023] FIG. 8 is a perspective view of a pad of paper sheets bound
together by the tape of the present invention.
[0024] FIG. 9 is a perspective view of a box, the flaps of which
are sealed by the tape of the present invention.
[0025] FIG. 10 is a perspective view of a container that utilizes
the tape of this invention as a label.
[0026] FIG. 11 is a perspective view of a gable-top container-that
utilizes the tape of this invention as a closure.
[0027] FIG. 12 is a schematic diagram that illustrates an apparatus
for measuring peel adhesion at various angles.
[0028] FIG. 13 is a graph showing the relationship between debond
force and peel angle of the tape of the present invention.
DETAILED DESCRIPTION OF THE INVENTION
[0029] Referring to FIG. 1a, a tape 10 of this invention comprises
a backing 12 bearing on at least one major surface thereof a layer
14 of pressure-sensitive adhesive. As shown in FIG. 1a, tape 10 is
adhered to substrate 16. Materials suitable for the backing of the
tape of this invention include highly extensible polymeric sheet
materials having (1) a high tensile strength; (2) a lengthwise
elongation at break of from about 50 to about 1,200%, preferably
from about 150 to about 700%, more preferably from about 350 to
about 700%; (3) substantial inelasticity, i.e., having less than
about 50% elastic recovery after being stretched, preferably less
than about 30% elastic recovery, more preferably less than about
20% elastic recovery; and (4) a Young's modulus of at least about
2,500 psi, preferably at least about 3,000 psi, but less than about
50,000 psi, more preferably between about 5,000 and about 30,000
psi. If the Young's modulus is too high, it is very difficult to
stretch the tape sufficiently to cause clean release upon
stretching. If the Young's modulus is too low, the tape loses its
plastic character and becomes rubbery.
[0030] Representative examples of materials suitable for the
backing of the tape of this invention include polyolefins, such as
polyethylene, including high density polyethylene, low density
polyethylene, linear low density polyethylene, and linear ultra low
density polyethylene, polypropylene, and polybutylenes; vinyl
copolymers, such as polyvinyl chlorides, both plasticized and
unplasticized, and polyvinyl acetates; olefinic copolymers, such as
ethylene/methacrylate copolymers, ethylene/vinyl acetate
copolymers, acrylonitrile-butadiene-styrene copolymers, and
ethylene/propylene copolymers; acrylic polymers and copolymers; and
combinations of the foregoing. Mixtures or blends of any plastic or
plastic and elastomeric materials such as
polypropylene/polyethylene, polyurethane/polyolefin,
polyurethane/polycarbonate, polyurethane/polyester, can also be
used. Backings can be in the form of single or multi-layer films,
non-woven films, porous films, foam-like films, and combinations of
the foregoing. Backings can also be prepared from filled materials,
such as, for example, filled films, e.g., calcium carbonate filled
polyolefins. Backings are preferably selected from polyethylene and
polypropylene films, with the most preferred materials being linear
low density and ultra low density polyethylene films.
[0031] Backings can be made by any known method of film forming,
such as, for example, extrusion, co-extrusion, solvent casting,
foaming, non-woven technology, and the like. The backing can have
any thickness so long as it possesses sufficient integrity to be
processable and handleable, with thicknesses preferably ranging
from about 10 micrometers to 250 micrometers. Backings having
thicknesses lower than about 10 micrometers are not preferred for
aggressive adhesives. Backings having thicknesses higher than about
250 micrometers tend to require stretching forces for removal that
are higher than desired, thereby making removal more difficult. In
the preferred range, thinner backings tend to provide easier
removal than do thicker ones.
[0032] The adhesive of the adhesive layer can comprise any
pressure-sensitive adhesive, with the particular adhesion
properties being dependent on the use of the tape, with the
preferred adhesion properties generally ranging from about 13 N/dm
to about 200 N/dm, preferably from about 25 N/dm to about 100 N/dm,
at a peel angle of 1800, measured according to PSTC-1 and PSTC-3
and ASTM D 903-83 at a peel rate of 12.7 cm/min. Adhesives having
higher peel adhesion levels usually require backings having higher
tensile strength.
[0033] Pressure-sensitive adhesives suitable for this invention
include tackified rubber adhesives, such as natural rubber,
olefins, silicones, polyisoprene, polybutadiene, polyurethanes,
styrene-isoprene-styrene and styrene-butadiene-styrene block
copolymers, and other elastomers; and tackified or untackified
acrylic adhesives such as copolymers of isooctylacrylate and
acrylic acid, which can be polymerized by radiation, solution,
suspension, or emulsion techniques. Crosslinked adhesives are
preferred, especially those pressure-sensitive adhesives
crosslinked to give high shear strengths. The most preferred
adhesives are those that are crosslinked by radiation with or
without a chemical-crosslinking agent. Such adhesives that have
high shear strength provide low debonding force and can easily be
removed when stretched.
[0034] The thickness of the adhesive layer can range from about 25
micrometers to about 1,000 micrometers, preferably from about 50
micrometers to about 400 micrometers. In this preferred range of
thicknesses, the thicker layers tend to cause the tapes to be more
easily removable than do thinner layers. This is in contrast to
conventional methods of removal, such as removal by peeling at peel
angles of 90.degree. or higher. In general, thicker layers of
adhesive tend to cause the tapes to exhibit higher peel strength at
a peel angle of 180.degree. than do thinner layers. When the tapes
of the present invention are released by stretching at a low angle,
i.e., under 35.degree., the adhesive tends to be constrained by the
backing and substrate for a single-coated adhesive tape and by the
backing and two substrates for a double-coated adhesive tape, and
is forced to undergo significant elongation. Under these
conditions, the adhesive layer (or each adhesive layer) contracts,
which reduces its cross-sectional area. Since the cross-sectional
area, i.e., thickness times width, of a thinner layer of adhesive
is already less than that of a thicker layer of adhesive, stress,
i.e., force per unit area, is greater in the thinner layer of
adhesive than in the thicker layer of adhesive. This leads, in
effect, to a stiffening of the adhesive. Because stiffer layers
offer more resistance to deformation, the force required for
debonding is greater.
[0035] The tape of this invention can be produced by any
conventional method for preparing pressure-sensitive adhesive
tapes. For example, the adhesive can either be directly coated onto
the backing, or it can be formed as a separate layer and then later
laminated to the backing. In some cases, in order to improve
adhesion of the adhesive layer to the backing, the backing can be
pretreated prior to the coating step or the laminating step in one
or more of the following ways: corona discharge, plasma discharge,
flame treatment, electron beam irradiation, ultraviolet radiation,
acid etching, or chemical priming. Such pretreatments can be
carried out with or without reactive chemical adhesion promoters
such as hydroxyethyl acrylate or hydroxyethyl methacrylate, or
other reactive species of low molecular weight. Corona discharge
pretreatment is generally preferred if a polymeric film backing is
used.
[0036] Removing the tape from the surface of a substrate can be
carried out by simply stretching the tape in a direction up to an
angle of about 35.degree. from the surface. Removal at the
appropriate angle will result in leaving no appreciable adhesive
residues and in preventing the surface of the substrate from being
damaged.
[0037] A schematic illustration of debonding or removal by
stretching is shown in FIGS. 1a, 1b, and 1c. FIG. 1a shows a
single-coated tape of the present invention having a backing
bearing a layer of pressure-sensitive adhesive, which layer bonds
the tape to a substrate. Force F is applied in a direction
substantially parallel to the surface of the substrate. The initial
resistance to shearing stress of this type is high. When sufficient
force is applied to overcome this resistance, the backing begins to
deform. In FIG. 1b, the backing yields while the adhesive elongates
and orients, thereby undergoing elongational stiffening due to
reduced cross-sectional area. This stiffening effect then causes
stress to transfer to the interface, effecting debonding as shown
in FIG. 1c, with substantially no triaxial stress and no
filamentation in the adhesive layer.
[0038] Debonding of a highly elongated adhesive tape of this
invention at low angles is characterized by a "sharp" type of crack
propagation. Like fracture of glassy materials, a sharp crack leads
to high stress concentration at the crack front, where there is a
low volume of adhesive material (in which stress may be
dissipated). High stress concentration at the crack front leads to
what is called brittle cleavage failure of the adhesive. Such
failure typically occurs with low force (because of the low amount
of energy dissipated in the adhesive material) and is cleanly
interfacial.
[0039] In contrast, for higher peeling angles, i.e., angles greater
than 35.degree., the backing does not stretch and the adhesive is
observed to undergo filamentation and to rupture cohesively. Like
fracture of glassy materials, propagation of a "blunt" crack is
preceded by crazing. In this model, the observed filamentation of
the adhesive at higher angles serves principally as an energy
dissipation mechanism, analogous to craze fibrils found in glassy
materials. The greater the energy dissipation, the greater the
resistance to peeling and the higher the force required to peel the
tape. A larger volume of material is involved in energy
dissipation, and, as stated previously, stress is less
concentrated. The adhesive filaments rupture cohesively to leave
residue of adhesive on the surface or to cause damage to the
surface.
[0040] The tape of this invention can be used in several areas,
including the following categories:
[0041] (1) mounting applications, such as wall hangings, body side
moldings on vehicles, carrying handles, signing application, e.g.,
road signs, vehicle markings, transportation markings, and
reflective sheetings, etc.;
[0042] (2) joining applications, such as adhering two or more
containers, e.g., boxes, for later separation, e.g.;
[0043] (3) closure applications, such as container closures, e.g.,
box closures, closures for food and beverage containers, and the
like, diaper closures, surgical drape closures, etc.;
[0044] (4) removable labels, such as price tags or identification
labels on containers, etc.; and
[0045] (5) medical applications, such as bandages, etc.
[0046] The particular construction of the tape, e.g., the type of
backing, the type of adhesive compositions, and relative position
of backing and adhesive layers, are often required to be different
for each category of use. Tape constructions include single-coated
tapes and double-coated tapes. A single-coated tape is one that has
a layer of adhesive on one major surface of the backing. The tape
in FIG. 1a is a single-coated tape, as is the tape in FIG. 7. Tape
20 in FIG. 7 comprises a backing 22 bearing on one major surface
thereof a layer of adhesive 24. Layer of adhesive 24 is adhered to
a removable release liner 26. An adhesive-free tab 28 covers a
portion of adhesive layer 24 to provide for grasping tape 20 for
easy removal from substrates to which it will be subsequently
adhered. A double-coated tape is one that has a layer of adhesive
on both major surfaces of the backing. The tape in FIG. 2 is a
double-coated tape. Tape 30 in FIG. 2 comprises a backing 32
bearing on both major surfaces thereof layers of adhesive 34, 36.
Layer of adhesive 34 is adhered to a first removable release liner
38, and layer of adhesive 36 is adhered to a second removable
release liner 40. An adhesive-free tab 42 covers a portion of
adhesive layers 34 and 36 to provide for grasping tape 30 for easy
removal from substrates to which it will be subsequently adhered.
The materials for the backings and for the adhesive layers of tapes
20 and 30 can be the same as those previously described for tape
10. The adhesive-free tabs can be made from polymeric materials or
paper materials, preferably from the same materials as are useful
for preparing the backings. They may also be constructed by leaving
one end of the tape 25 uncoated with adhesive.
[0047] It is preferred that the backing be corona treated prior to
application of adhesive when the backing is a polymeric film.
Multiple backing constructions can also be used. For example, the
tape of this invention may comprise several distinct layers, and
may be made with non-woven webs, foamed polymers, or stacked or
alternating layers of elastic and plastic materials, so long as the
total construction exhibits good elongation, e.g., greater than
100%, and low elastic recovery, e.g., less than 50%. Multiple
backing tapes of this invention can comprise two or more backings,
which backings can be bonded one to another by adhesives, e.g.,
pressure-sensitive adhesives, or by laminating.
[0048] As indicated previously, because of the substantially
plastic nature of the backings, the tapes of the present invention
do not return to their original shape or size after being
stretched, and, consequently, can also be employed as
tamper-indicating tapes.
[0049] FIG. 3A and FIG. 3B show an embodiment of a tape of the
present invention in a mounting application. Hooks are commonly
used in most households to hang pictures, towels, garments,
kitchenware, tools, plants, and other articles. Conventional hooks
often require forming holes in cabinets, ceilings, walls, or
woodwork when nails, screws, pins, tacks, or other mechanical
devices ate used for adhering the hooks to these substrates. Holes
are not a problem when they are hidden by a picture, but the holes
must be filled upon removal of the picture. Picture hooks bonded by
means of conventional adhesive tapes are difficult, if not
impossible, to remove without scraping or otherwise damaging the
surface of the wall. Removable picture hooks employing tapes of the
present invention can be used to mount hooks that securely hold
pictures, wall hangings, and other decorations. By using tapes of
the present invention for mounting, such hooks can be held securely
in place during use and can be removed when desired without
damaging the surface of the substrate. As shown in FIG. 3A and FIG.
3B, mounting assembly 50 comprises a hook portion 52 and a support
54 therefor, which support is adhered to a double-coated tape 56 by
means of one of the layers 58, 60 of pressure-sensitive adhesive
that are borne by backing 62. If desired, a tab 64 can also be
provided to allow grasping of tape 56, in order to facilitate
removal of tape 56 from wall 66. Tab 64 can be formed by any known
method of producing a non-adhesive grasping area, such as by
applying a non-adhesive material onto the adhesive to render it
non-tacky. Tab 64 can be left exposed or the hook design can be
such that tab 64 is concealed by support 54. Adhesive layer 60 is
capable of firmly bonding to wood, metal, glass, and ceramic
surfaces. In order to use mounting assembly 50, a protective liner
(not shown) is peeled to expose layer 60 of adhesive, and mounting
assembly 50 is then pressed on wall 66 in the desired location. In
order to remove mounting assembly 50, tab 64 at the top of mounting
assembly 50 can be pulled in a direction parallel to wall 66. As
tape 56 stretches, it slowly releases mounting assembly 50 from the
wall. Each hook can be designed to hold loads, even in excess of 15
pounds per lineal inch, yet can be removed without leaving any
residue on the surface of the wall.
[0050] Other mounting applications for the tape of this invention
involve the use of the tape by itself without a hook-bearing
mounting assembly, as shown in FIG. 4. The tape of this invention
provides the holding power of currently available adhesive-backed
permanent mounting tapes and die cut squares along with the feature
of clean removability. The tape, by itself, can be used for
mounting of objects, e.g., body side moldings and shelves. The tape
can also be used to mount objects of lower weight, e.g., calendars,
posters, and signs. In FIG. 4, a tape 70 of this invention is shown
to be adhering a picture frame 72 to a wall 74.
[0051] Another mounting application for tapes of this invention
involves removable graphics. Graphic films, including reflective
films, currently in use employ aggressive pressure-sensitive
adhesives that give long adhesion durability; however, they are
difficult to remove from the surface of a substrate. Methods for
film removal currently in use employ heat (from a heat gun, heat
lamp, or hot water) or organic solvents or both. Removal by heat
may still leave deposits of adhesive on the substrate which must be
removed with organic solvents. Solvents and peeling action may
damage the surface by removing paint or other finishes. Solvents
require precautions for proper ventilation, fire prevention,
storage, and disposal. Some of these methods require temperatures
above a minimum temperature or with a specified temperature range.
The tape of this invention allows the use of aggressive adhesives,
but provides a much simpler and easier means of removal. The
graphic film can be removed from a substrate by stretching the
extensible layer substantially in the plane of the substrate. This
manner of removal is clean and dry, thereby avoiding environmental,
health, storage, and disposal problems associated with organic
solvents. In addition, the tapes tend to leave no adhesive residue
on the substrate or damage the substrate, e.g., remove paint. These
characteristics provide savings of both cost and time to the
user.
[0052] FIG. 5 illustrates a joining application, such as holding
two or more containers 80 and 82, e.g., boxes, securely together
for later separation. Double-coated pressure-sensitive adhesive
tape 84 having a tab 86 for grasping is preferred for this
application. When separation is desired, tab 86 is simply pulled to
stretch tape 84. This system is superior to conventional joining
systems where a double-coated tape, an adhesive layer, or glue is
used and where separation of layers joined by an aggressive
adhesive generally defaces the package.
[0053] FIG. 6 shows an easily openable container 90 utilizing the
tape 92 of this invention. Containers utilizing conventional
closures, e.g., heat seals, adhesives, and perforated cardstock or
chipboard, can be difficult to open, particularly in the absence of
a cutting tool. The act of opening often damages the container,
which in many cases is often intended to be used as a dispenser.
The tape of this invention can provide sufficient strength for
closure and can also provide means for indication of tampering.
[0054] Paper clips and staples are commonly used as fastening
devices for paper, film, and the like. Paper clips hold flat
objects, e.g., sheets of paper, together at the edge and are
limited to holding a few sheets. Paper clips may damage paper
sheets by both "embossing" the sheets and bending the surface of
the sheets where the clips are attached. When staples are used to
fasten paper sheets together, they form small holes in the sheets.
Moreover, individual sheets can be severely damaged by being torn
from the group of fastened sheets. Staples are also difficult to
remove, they are sharp, and consequently injurious, and they result
in litter, especially in the vicinity of copying machines. The
adhesive tapes of this invention can be used as substitutes for
paper clips and staples. These tapes can be attached firmly to
paper sheets, yet can be removed easily and cleanly when the tapes
are stretched. Single and double-coated tapes can be used for this
application.
[0055] The tape of this invention can be used as a fastening device
for two or more articles, such as sheets, e.g., paper, film. Two
sheets can be fastened together with a tape of the type shown in
FIG. 2 of this invention, i.e., a tape having a backing that is
coated on both major surfaces with an aggressive pressure-sensitive
adhesive. Upon removal of the tape, the damage to the sheets will
be minimal, and little residual adhesive will remain thereon. More
than two sheets can be fastened together, as shown in FIG. 8, by a
tape 100 of this invention. Tape 100 can be adhered to the back
102, sides 104, and front 106 of a pad 108 of sheets in a
length-wise manner to form a removable edge binding. When tape 100
is pulled in the direction of the arrow, it can be cleanly removed
from the surfaces to which it had been adhered.
[0056] Boxes are commonly used for storage and transportation of a
variety of items. Such boxes are usually sealed tightly to keep out
foreign objects and to minimize impact forces during
transportation. At the same time, access to the boxes must be
relatively easy at the time one desires to remove some or all of
the contents. Easily openable box seals, as shown in FIG. 9, can be
made from adhesive tapes of the present invention. These seals can
be used to securely seal a box, yet can easily be removed in order
to open the box by firmly pulling on a tab. When the tab is pulled,
the adhesive is removed from the surface of the box, and the box
can be opened without the surface thereof being damaged. When
resealing is desired, the flaps can be refolded and bonded by
another tape seal. In FIG. 9, a double-coated tape 110 having a tab
112 for grasping is used to join two flaps 114, 116 of a box 118 to
close same. A tape for box sealing can bear a layer of adhesive on
only one surface of the backing and be applied to the outside of
the box to-close same.
[0057] Adhesive-coated labels have been widely used for labeling
articles for identification, pricing, and the like. For labeling
household items such as food storage containers and recording tapes
for identification, the labels should bond well to the surface of a
substrate so that the article can be identified, and should be
easily removable at a later time when re-labeling is desired. Many
household labels that provide adequate adhesion are not easily
removable and leave behind adhesive residue on the surfaces to
which they are bonded. Labels that are easily removable often do
not provide adequate adhesion, detach during use, and render the
article unidentifiable. A single-coated tape can be used to form a
label or a mask. The tape can be removed by pulling it at an angle
of less than 35.degree. from the surface of the substrate to which
it is adhered. Labels made from tapes of the present invention have
high adhesion and can be held firmly in place during use, yet they
can be easily removed without leaving adhesive residue or damaging
the surfaces to which they are bonded, as shown in FIG. 10. The
label 120 can be removed from container 122 by pulling it in a
direction substantially tangential to the surface to which it is
bonded. Label 120 preferably has a tab 124 by means of which the
tape may be easily grasped for removal. Coupons, price tags,
advertisements, and the like can also be made from tapes of the
present invention.
[0058] Tapes of the present invention are especially suited for
tamper-indicating applications because, upon stretching, they do
not recover their original shapes. Tamper-indicating tapes of this
invention can be used in closures for over-the-counter medication,
closures for containers for foods and beverages, e.g., pull tabs
for juice cans, easy-to-open security envelopes, price tags, or UPC
code labels.
[0059] FIG. 11 shows how a tape 130 of this invention can be used
to seal a container 132 having a gabled-top.
[0060] Other uses for the tapes of this invention include abrasive,
anti-slip, and controlled release delivery. In an abrasive
application, a coated abrasive disc can be applied to a rotary
sanding device by means of the tape of this invention. This disc
would be held firmly yet would be easily removable. The tape can
also be used for adhering a removable, non-slip article, e.g.,
appliques or strips, on stairs, docks, boat decks, and bath tubs.
Again, the tape provides excellent holding power and easy removal.
Ease of removal allows cleaning and repainting. Controlled release
delivery applications include anti-fouling films, "no-pest" strips,
and transdermal drug delivery. For delivery of controlled release
materials, the tape allows fastening of the delivering substrate
with strong holding power, yet also allows easy removal for
replacement when the delivery is complete for that dose or when the
available active ingredient is exhausted. An anti-fouling film,
which releases a dose of cuprous sulfide, can be removed in much
the same way as graphic films would be removed.
[0061] The following non-limiting examples will further illustrate
the tape of the present invention and several applications
therefor.
Test Methods
[0062] 1. 90.degree. Peel Adhesion
[0063] A 25 mm by 152 mm strip of a sample of the tape is applied,
adhesive side down, to a stainless steel test panel (AISI 302 or
AISI 304). The sample of tape is rolled twice with a 4.5 kg roller
to firmly bond it to the test panel. A free end of the tape sample
is then separated by hand for a distance of about 25 mm and clamped
in a tensile testing machine in the crosshead (i.e., upper) jaws
thereof. The test panel is held fixed to a sliding trolley to keep
the peel angle constant at 90.degree. throughout the course of the
test. The tape of the sample is peeled at a rate of 305 mm/min, the
first 25 mm of peel data being discarded. The average peel force
measured over the remaining peel length is recorded.
[0064] 2. 180.degree. Peel Adhesion
[0065] The sample to be tested consists of a backing laminated to
or coated with a pressure-sensitive adhesive. A stainless steel
test panel (AISI 302 or AISI 304) at least 50 mm by 150 mm is used
as the substrate from which the sample is peeled. The last 25 mm of
the length of the panel is covered with masking tape. Strips of
tape samples 25 mm by 150 mm are adhered by way of the
pressure-sensitive adhesive to one major surface of the stainless
steel test panel such that the end of the sample overlies the
masking tape. The sample of tape is rolled twice with a 4.5 kg
roller to firmly bond it to the test panel. The major surface of
the test panel not bearing the tape sample is adhered to the
surface of an Instrumentors Inc. Model 3M90 Slip/Peel tester by
means of a double-coated tape. One end of the test sample is
separated from the masking tape by hand and peeled at a rate of 305
mm/min through a distance of 127 mm at a peel angle of 180.degree..
The initial 25 mm of peel data is discarded. The average peel force
measured over the remaining peel length is recorded.
[0066] 3. Peel Adhesion at Other Angles
[0067] A schematic diagram of an apparatus 140 for testing peel
adhesion is shown in FIG. 12. Two stainless steel test panels 142,
144 (AISI 302 or AISI 304) are placed end to end a distance of 50
mm apart. A single strip of tape 146 of the sample having
dimensions 25 mm by 254 mm is adhered to test panels 142 and 144,
bridging the 50 mm gap between them. Tape 146 is rolled twice with
a 4.5 kg roller to firmly bond it to test panels 142 and 144. Test
panels 142 and 144 are mounted in a tensile tester by means of
swivel grips 148 and 150 so that their surfaces form symmetrically
inclined planes at the peel angle desired for the test. In this
manner a continuous range of peel angles from 0.degree. to
180.degree. can be evaluated. The sample of tape 146 is mounted so
that the peeling action occurs mainly within the center line of
apparatus 140. Tape 146 is peeled simultaneously from both steel
test panels 142 and 144 by moving the crosshead (not shown) at a
rate of 305 mm/min. The average peel force measured over the course
of peeling is recorded.
[0068] 4. Stretch Force; Release Force
[0069] A double-coated tape sample is placed between two strips of
anodized aluminum (25 mm by 50 mm by 0.125 mm), leaving an
adhesive-free 25 mm tab protruding from one end of the assembly.
The assembly is rolled twice with a 4.5 kg roller to firmly bond
the sample to the aluminum strips. The assembly is mounted in a
tensile testing machine so that the aluminum strips on either side
of the sample is gripped in the lower (fixed) jaws, and the
adhesive-free tab is clamped in the upper (crosshead) jaws. The
jaws are separated at a rate of 305 mm/min, the average force
required to effect debonding by stretching is recorded.
[0070] 5. Shear Holding Power
[0071] A double-coated tape sample having the dimensions 25 mm by
25 mm is placed between two strips of anodized aluminum (25 mm by
50 mm) so that a 25 mm length of aluminum of one strip extends
beyond one end of the tape sample and a 25 mm length of aluminum of
the other strip extends beyond the other end of the tape sample.
The 25 mm extensions of the aluminum strips are used as tabs for
gripping by the jaws of a tensile testing machine. The aluminum
strip/tape sample/aluminum strip assembly is rolled twice with a
4.5 kg roller to firmly bond the sample to the aluminum strips. The
tabs of the aluminum strips are clamped in the upper and lower jaws
of a tensile testing machine, and the jaws separated at a rate of
25 mm/min. The average force required to effect separation of the
aluminum strips from the tape sample is recorded.
EXAMPLE 1
[0072] An adhesive was made by partially polymerizing 100 g of a
blend containing 90% by weight isooctylacrylate monomer and 10% by
weight acrylic acid monomer and 0.04 part per hundred
2,2-dimethoxy-2-phenyl acetophenone ("Irgacure 651") to yield a
coatable syrup having a viscosity of about 5,000 cps. To this syrup
was then added an additional 0.25 g of a blend containing 90% by
weight isooctylacrylate monomer and 10% by weight acrylic acid
monomer and 0.04 part per hundred 2,2-dimethoxy-2-phenyl
acetophenone ("Irgacure 651"), plus 0.125 g of 1,6-hexanediol
diacrylate crosslinking agent. The composition was thoroughly mixed
and coated onto a silicone-coated polyester film by means of a
knife coater adjusted to produce an adhesive thickness of about 125
mm. After the coated syrup was purged thoroughly with nitrogen gas,
it was covered with a second silicone-coated polyester film and
polymerized by means of ultraviolet radiation using a total energy
of 450 mJ/cm.sup.2. The polyester liners were removed, and one of
the exposed surfaces of the adhesive was then laminated to a 0.05
mm corona treated linear low density polyethylene film (available
from Consolidated Thermoplastics Co.) having properties as shown in
Table 1, while the other was laminated to a stainless steel panel
and tested for peel at various angles. The results are shown in
Table 2. Double-coated tapes for some tests were made simply by
laminating a second adhesive layer to the other side of a 0.05 mm
corona treated linear low density polyethylene film.
COMPARATIVE EXAMPLES A AND B
[0073] The tapes of these examples were made in the same manner as
were the tapes of Example 1, except that in one sample, Comparative
Example A, the exposed adhesive layer was laminated to a 0.05 mm
polyurethane film, in another sample, Comparative Example B, the
exposed adhesive layer was laminated to a 0.025 mm polyester film,
and in still another sample, Comparative Example C, the exposed
adhesive layer was laminated to a 0.05 mm ultralow density
polyethylene film. The films in Comparative Examples A and B had
properties as shown in Table 1. These were also tested for peel at
various angles and the results are shown in Table 2.
[0074] AS can be seen from FIG. 13, the plastic tape with linear
low density polyethylene film backing (points indicated by
.largecircle.) clearly showed a minimum debonding force at
0.degree. while the elastic tape with polyurethane backing (points
indicated by .DELTA.) showed maximum debonding force at 0.degree..
Thus, stretchable plastic tapes provide a low debonding force from
the surface of a substrate at low angles by simply stretching the
tape. Polyester is not appreciably stretchable.
1 TABLE 1 Comparative Comparative Comparative Example 1 Example A
Example B Example C (LLDPE).sup.1 (Polyurethane) (Polyester)
(ULDPE).sup.2 Elastic 28,896.0 4,619.0 445,515.0 11,773.0 Modulus
(psi) 50% Modul- 4,000.0 1860.0 35,600.0 2,352.0 us (psi) Yield
stress 1,743.0 -- 16,273.0 897.0 (psi) Yield strain 17.3 -- 6.5
13.0 (%) Tensile 7,931.0 6,157.0 28,054.0 6,484.0 strength (psi)
Elongation 748.0 434.0 132.0 545.0 (%) Recovery 5.4 94.0 -- 21.3
(%) .sup.1Linear low density polyethylene .sup.2Ultralow density
polyethylene
[0075]
2TABLE 2 Peel force (lb/in) Peel angle Linear low density (Degrees)
polyethylene Polyurethane Polyester 0 2.38 5.40 -- 5 3.82 5.06
16.05 10 -- -- 16.92 15 4.07 4.69 16.93 25 4.13 4.89 15.86 30 --
4.55 -- 35 4.29 -- 11.53 45 4.10 4.47 7.16 50 -- 4.77 -- 60 3.46 --
4.24 75 3.26 3.30 2.95 90 2.83 2.96 2.15 110 2.26 -- 2.70 130 1.99
-- 2.22 150 2.07 2.14 2.28 180 2.78 2.23 2.55
EXAMPLES 2-6
[0076] The tapes of these examples were made in the same manner as
were the tapes of Example 1, except the level of:crosslinking agent
was varied, as shown in Table 3.
3TABLE 3 Amount of Stretch crosslinking 180.degree. adhesion to
180.degree. adhesion to Dynamic shear release adhesion agent (%)
steel (N/dm) paper (N/dm) holding power (N/dm) (N/dm) 0.01 54 41.6
183 40.8 0.025 55 42.2 192 42.8 0.05 58 41.8 201 43.8 0.10 49 37.6
202 44.7 0.18 39 34.4 207 46.3 Tackified 35 42.2 180 49.1 IQA/AA*
*Tackified IQA/AA contained 90 parts isocctyl acrylate, 10 parts
acrylic acid, and 10 parts tackifier ("Foral-85"), available from
Hercules, Inc.).
[0077] The data clearly show that increasing the concentration of
crosslinking agent decreases 180.degree. peel adhesion while
increasing holding power (dynamic shear). Surprisingly, the level
of low angle debonding increases as level of crosslinking agent
increases.
EXAMPLE 7
[0078] The tape of this example was made in the same manner as was
the tape of Example 1 except that 10 parts of tackifier (a rosin
ester, "Foral 85", available from Hercules, Inc.) was also added.
The adhesion forces were measured and are set forth in Table 3. The
data show that the addition of tackifier clearly increased the
debonding force at a peel angle of 0.degree..
EXAMPLE 8
[0079] The tape of this example was made in the same manner as was
the tape of Example 1, except that the tape was coated with a
removable, repositionable adhesive on one surface of the corona
treated linear low density polyethylene film to produce a tape with
differential adhesion. This tape is especially useful for mounting
and display of light weight objects such as photographs, signs,
cards, calendars, etc., where repeated mounting is desirable.
EXAMPLE 9
[0080] The tape of this example was made by coating a linear low
density polyethylene film (0.1 mm thick) with 8.4 grains of a block
copolymer ("Kraton 1107", available from Shell Corporation),
tackified with a resin tackifier ("WINGTACK PLUS", available from
Goodyear Chemicals). A strip of this tape (0.127 cm wide by 50 cm
long) was wrapped around three 5 cm by 9 cm by 15 cm decorated
boxes of a snack food product. After being aged for 48 hours at
room temperature, the tape was removed at a peel angle of
90.degree. and the surface of the package was completely damaged,
spoiling the graphics. When the tape was removed by stretching it
at an angle of 0.degree., the tape was removed cleanly, leaving no
residual adhesive and without damaging the package or spoiling the
graphics.
EXAMPLE 10
[0081] The liner was removed from an adhesive coated vinyl film
(3650 "Scotchcal" film, available from Minnesota Mining and
Manufacturing Company, St. Paul, Minn.), and then the film was
laminated to the following extensible polymeric sheets:
polyether-polyurethane (1 mil), polyester-polyurethane (3 mil),
unoriented linear low density polyethylene (2 mil), unoriented
polypropylene (1 mil, corona side up), and unoriented polypropylene
(1 mil, corona side down). The same pressure-sensitive adhesive
used with 3650 "Scotchcal" film was then coated on the back side of
each extensible polymeric sheet, except for the polypropylene
sheets, where adhesive for transfer tape was used. The tensile
strength and average elongation to break were measured for these
assemblies. One inch wide samples of these assemblies were
laminated to steel panels and aged four days at 66.degree. C. Peel
forces were then measured for these assemblies at peel angles of
180.degree. and 7.degree.. The mode of failure was then noted. Ply
failure refers to failure between the adhesive and extensible
polymeric sheet. Film break failure refers to breaking of the
adhesive-coated vinyl film.
[0082] The results at 7.degree. peel angle show that nearly 100% of
the film was removed from the polyurethane and linear low density
polyethylene extensible polymeric sheets. In addition, these films
did not break during removal, while the 3650 "Scotchcal" film broke
easily. Therefore it appears that the extensible polymeric film
provided another unexpected advantage, namely reinforcing the
"Scotchcal" vinyl film. This property can be used to provide
enhanced durability during the lifetime of the "Scotchcal"
film.
[0083] The linear low density polyethylene extensible polymeric
film was the most desirable from the standpoint of conformability
to topography due to the plastic nature of the film, i.e., it will
readily stretch to conform to rivets, corrugation, etc. The
polyurethane films on the other hand are elastic and would not
conform upon stretching and release.
[0084] Various modifications and alterations of this invention will
become apparent to those skilled in the art without departing from
the scope and spirit of this invention, and it should be understood
that this invention is not to be unduly limited to the illustrative
embodiments set forth herein.
* * * * *