U.S. patent application number 11/244575 was filed with the patent office on 2007-04-12 for scouring web and method of making.
Invention is credited to Ana Claudia Rueda Nery Barboza, Thomas E. Haskett, Jeffrey M. Mailand.
Application Number | 20070079462 11/244575 |
Document ID | / |
Family ID | 37909900 |
Filed Date | 2007-04-12 |
United States Patent
Application |
20070079462 |
Kind Code |
A1 |
Haskett; Thomas E. ; et
al. |
April 12, 2007 |
Scouring web and method of making
Abstract
The present invention relates to a scouring web and a method of
making a scouring web. The scouring web comprises a plurality of
metal fibers and a plurality of polymeric fibers. The metal fibers
and polymeric fibers are combined and a portion of the polymeric
fibers secures the metal fibers and polymeric fibers together to
form the web.
Inventors: |
Haskett; Thomas E.;
(Oakdale, MN) ; Barboza; Ana Claudia Rueda Nery;
(Campinas, BR) ; Mailand; Jeffrey M.; (Hudson,
WI) |
Correspondence
Address: |
3M INNOVATIVE PROPERTIES COMPANY
PO BOX 33427
ST. PAUL
MN
55133-3427
US
|
Family ID: |
37909900 |
Appl. No.: |
11/244575 |
Filed: |
October 6, 2005 |
Current U.S.
Class: |
15/229.11 ;
15/118; 15/229.12; 15/229.13; 15/244.3 |
Current CPC
Class: |
A47L 13/04 20130101;
B24D 11/003 20130101; A47L 17/08 20130101 |
Class at
Publication: |
015/229.11 ;
015/229.12; 015/229.13; 015/118; 015/244.3 |
International
Class: |
A47L 13/00 20060101
A47L013/00 |
Claims
1. A scouring web comprising: a plurality of metal fibers; and a
plurality of polymeric fibers; wherein the metal fibers and
polymeric fibers are combined and a portion of the polymeric fiber
secures the metal fibers and polymeric fibers together to form the
web.
2. The scouring web of claim 1, wherein the polymeric fiber is a
multicomponent fiber.
3. The scouring web of claim 2, wherein the polymeric fiber has a
first portion having a first melting point and the second portion
of having a second melting point lower than the first melting
point.
4. The scouring web of claim 2, wherein the polymeric fiber
comprises a polymeric core surrounded by a sheath.
5. The scouring web of claim 4, wherein the polymeric core is
polyester and the polymeric sheath is copolyester.
6. The scouring web of claim 1, wherein the web comprises at least
50% (wt.) metal fibers.
7. The scouring web of claim 1, wherein the web comprises at least
75% (wt.) metal fibers.
8. The scouring web of claim 1, wherein the web comprises 85% to
90% (wt.) metal fibers.
9. The scouring web of claim 1, further comprising a binder
extending along at least a portion of a surface of the web.
10. The scouring web of claim 9, wherein the binder comprises
discrete strands along the surface of the web.
11. The scouring web of claim 9, wherein the binder covers an
entire surface of the web.
12. The scouring web of claim 1, further comprising a support layer
attached to the web.
13. The scouring web of claim 12, wherein the support layer is a
water-absorbent material.
14. The scouring web of claim 1, wherein the metal fibers are
selected from the group consisting of steel, stainless steel,
copper, brass and bronze.
15. A scouring web comprising: a plurality of metal fibers; and a
plurality of polymeric fibers having a first portion and a second
portion; wherein the metal fibers and polymeric fibers are combined
and the second portion of the polymeric fibers secures the metal
fibers and polymeric fibers together to form the web.
16. A scouring web consisting essentially of: a plurality of metal
fibers; and a plurality of polymeric fibers.
17. A scouring article comprising: a support layer; a web
comprising metal fibers and polymeric fibers, wherein a portion of
the polymeric fibers secures the metal fibers and polymeric fibers
together to form the web; wherein the web is secured to the support
layer.
18. The scouring article of claim 17, further comprising a binding
layer on at least a portion of a surface of the web for attaching
the support layer to the surface of the web.
19. The scouring article of claim 17, wherein the binding layer
comprises discrete strands on the surface of the web.
20. The scouring article of claim 17, wherein the binding layer
comprises a film layer on the entire surface of the web.
21. The scouring article of claim 17, wherein the support layer is
selected from the group consisting of sponges, paper, knitted
fabric, woven fabric, nonwoven material, foamed polyurethane and
other foamed synthetic and natural materials.
22. The scouring article of claim 17, wherein the polymeric fibers
comprise a polymeric core surrounded by a polymeric sheath, wherein
the polymeric sheath has a melting point lower than the polymeric
core.
23. The scouring article of claim 17, wherein the web comprises at
least 75% (wt.) metal fibers.
24. The scouring article of claim 17, further comprising a
substrate attached to the support layer.
25. A scouring article comprising: a support layer having a first
surface and a second surface; a web having a first surface and a
second surface, the web comprising metal fibers and polymeric
fibers, wherein a portion of the polymeric fibers secures the metal
fibers and polymeric fibers together to form the web, and wherein
the web comprises at least 75% (wt.) metal fibers; a substrate
having a first surface and a second surface; wherein the first
surface of the support layer is attached to the second surface of
the web, and wherein the first surface of the substrate is attached
to the second surface of the support layer.
26. The scouring article of claim 25, wherein the web is corrugated
with a series of folds extending in a first direction.
27. The scouring article of claim 25, further comprising a binding
layer between the first surface of the substrate and the second
surface of the support layer.
28. The scouring article of claim 27, wherein the binding layer
comprises discrete strands of binder extend in a second direction
perpendicular to the first direction of the folds in the web.
Description
BACKGROUND
[0001] The present invention relates to a scouring web. In
particular, the present invention relates to a web comprising a
blend of metal fibers and polymeric fibers.
[0002] Metal wool pads, such as steel wool pads, have been used for
a variety of household and industrial applications that require
scouring or abrading a surface. Metal wool pads are typically made
of steel wool strands that are skived from a metal block, which
have been matted or felted together, or intertwined or interwoven
into a mass of filaments. Steel wool strands are used because a low
cost scouring pad can be provided to consumers.
[0003] One typical application for steel wool pads is in the
household for scouring articles like pots and pans. The hardness of
the metal and the sharp edges provide the scouring action and
polishes the metal surfaces of the pots and pans. Steel wool pads
may be provided with soap or detergent to further aid in cleaning
surfaces. Another typical application for steel wool pads is
performing light sanding on wood surfaces such as during wood floor
refinishing.
[0004] In spite of the practical applications, metal wool and in
particular steel wool pads have a number of undesirable
characteristics. One problem associated with steel wool pads in
particular is that the metal oxidizes and rusts. A rusted steel
wool pad looks undesirable to a user for cleaning. When using a
steel wool pad for sanding wood surfaces, if a splinter from the
steel wool pad remains on the surface and a water-based finish is
used, the splinter will rust and be trapped in the finish leaving
undesirable rust stains.
[0005] Use of other metals besides steel have been attempted to
avoid the problem of the metal rusting. However, metals such as
stainless steel, which does not rust, are significantly more
expensive than steel. Therefore, metal pads with metals such as
stainless steel have been too expensive to make practical as a
consumer product.
[0006] The other significant problem associated with metal wool
pads is the tendency of the pads to shed metal fibers or splinters.
The sharpness of the metal fibers makes the pad uncomfortable to
hold. If contact is made with the metal wool pad, the splinters may
enter the skin of the user and result in a metal sliver, which
causes an abrasion and potential inflammation. Therefore, many
consumers will hold a sponge or other soft cloth material against
their hand to prevent the metal wool pad from contacting their
hand. Attempts have been made to attach a substrate to the metal
wool pad. However, the same problems persist: splinters still
result on the surface and the steel wool rusts.
[0007] What is desired is an article having the scouring and
polishing properties of steel wool but does not rust and has
minimal splinters. Such a product must be low cost to make it
practical for use as a consumer product for such things as scouring
household materials like pots and pans or as an abrasive on wood
surfaces or the like.
SUMMARY
[0008] The present invention provides a scouring article that may
use metal materials like stainless steel that do not rust in a
quantity to result in a low-cost scouring article. The scouring
article of the present invention may be made with metal fibers that
emit minimal splinters and in some embodiments may be provided with
a support layer for ease in handling.
[0009] The present invention relates to a scouring web. The
scouring web comprises a plurality of metal fibers and a plurality
of polymeric fibers. The metal fibers and polymeric fibers are
combined and a portion of the polymeric fibers secures the metal
fibers and polymeric fibers together to form the web.
[0010] In another embodiment, the scouring web comprises a
plurality of metal fibers and a plurality of polymeric fibers
having a first portion and a second portion. The metal fibers and
polymeric fibers are combined and the second portion of the
polymeric fibers secures the metal fibers and polymeric fibers
together to form the web.
[0011] In another embodiment, the scouring web consists essentially
of a plurality of metal fibers and a plurality of polymeric
fibers.
[0012] In an alternative embodiment a scouring article is
disclosed. The scouring article comprises a support layer, and a
web comprising metal fibers and polymeric fibers, wherein a portion
of the polymeric fibers secures the metal fibers and polymeric
fibers together to form the web. The web is secured to the support
layer.
[0013] An alternative scouring article comprises a support layer
having a first surface and a second surface and a web having a
first surface and a second surface and comprising metal fibers and
polymeric fibers. A portion of the polymeric fibers secures the
metal fibers and polymeric fibers together to form the web, and the
web comprises at least 75% (wt.) metal fibers. The scouring article
further comprises a substrate having a first surface and a second
surface. The first surface of the support layer is attached to the
second surface of the web, and the first surface of the substrate
is attached to the second surface of the support layer.
BRIEF DESCRIPTION OF THE DRAWINGS
[0014] FIG. 1a is a perspective view of a metal web of the present
invention.
[0015] FIG. 1b is an enlarged view of the metal web of FIG. 1a.
[0016] FIG. 2 is a perspective view of a scouring article having
the metal web attached to a support layer.
[0017] FIG. 3 is a cross-sectional view of the scouring article of
FIG. 2.
[0018] FIG. 4 is a cross-sectional view of an alternative scouring
article.
[0019] FIG. 5 is a cross-sectional view of an alternative scouring
article.
[0020] FIG. 6 is a side view of an exemplary process of making the
scouring article of FIG. 2.
[0021] While the above-identified drawings and figures set forth
embodiments of the invention, other embodiments are also
contemplated, as noted in the discussion. In all cases, this
disclosure presents the invention by way of representation and not
limitation. It should be understood that numerous other
modifications and embodiments can be devised by those skilled in
the art, which fall within the scope and spirit of this invention.
The figures may not be drawn to scale.
DETAILED DESCRIPTION
[0022] FIG. 1a is a perspective view of a web 100 of the present
invention, and FIG. 1b is an enlarged view of the metal web 100 of
FIG. 1a. The web 100 comprises metal fibers 102 and polymeric
fibers 104. The metal fibers 102 and polymeric fibers 104 are
blended together so that the web 100 has a random distribution of
the metal fibers and polymeric fibers 104. Typically, the web 100
includes at least 50% (wt.) of metal fibers 102. The web 100 may
include at least 75% (wt.) metal fibers 102 or at least 85% (wt.)
metal fibers 102.
[0023] The metal fibers 102 can include any type of metal fibers
such as but not limited to steel, stainless steel, copper, brass,
or bronze. The metal fibers 102 are cut and are typically at least
0.5 inches (1.27 cm) long and have a thickness from 25 to 90
microns. Preferably, stainless steel is used because it is harder
than other metal fibers like copper and bronze and is more
corrosions resistant than steel wool.
[0024] The polymeric fibers 104 may be a single component fiber or
a multi component fiber. Regardless, the polymeric fibers 104
include a portion that is capable of securing with the other fibers
(metal or polymeric) to hold the fibers together and form the web.
A single component fiber may be made from polypropylene. In such a
case, the polymeric fiber is heated to a point that the polymeric
fiber begins to melt. The fiber then attaches to other fibers
(polymeric or melt) and upon cooling, solidifies and secures the
fibers to form the web.
[0025] A multicomponent fiber is a fiber having at least two
discrete portions. A multicomponent fiber is shown in FIG. 1b. One
portion of the fiber 104 remains in tact and another portion of the
fiber secures the polymeric fibers 104 and metal fibers 102
together to form a web. One type of multicomponent fiber is a
core/sheath fiber and is shown in FIG. 1b. Reference will be made
in the description to a core/sheath multicomponent fiber. However,
it is understood that other types of multicompnent fibers are
available.
[0026] The polymeric fibers 104 include a core 106 and a sheath 108
covering at least a portion of the core 106 prior to processing. It
is understood that the sheath 108, prior to processing, may cover
the entire core or only a portion of the core. The core 106 may be
comprised of such materials as polypropylene or polyester. The
sheath 108 may be comprised of such materials as copolyester or
polyethylene. The core 106 has a first melting point and the sheath
108 has a second melting point. The second melting point of the
sheath is lower than the first melting point of the core. During
processing, the sheath with the second melting point will melt,
while the core remains intact. Then, the material of the sheath
will resolidify to secure the web together.
[0027] Typically, the polymeric fibers 104 are at least 1 inch
(2.54 cm) long and have a denier of at least 2. Preferably, the
polymeric fibers 104 are 1.5 inches (3.81 cm) long and have a
denier of 12. One polymeric fiber 104 including a core and a sheath
is Celbond.RTM. fibers 254, available from KoSa Co. of Wichita,
Kans. where the sheath 108 has a melting point of 110.degree.
C.
[0028] Other multicomponent polymeric fibers are within the scope
of the present inventions. Other multi-component fibers may consist
of a layered structure where one layer has a first melting point
and another layer has a second melting point lower than the first
melting point. In such an arrangement, the layer with the second
melting point will melt and resolidify to secure the web together.
Also, a polymeric fiber with a core and an adhesive surrounding at
least a portion of the core, resulting in a fiber with tack, may be
used as the polymeric fiber. In such a case, the adhesive exterior
of the polymeric fiber secures the web together.
[0029] Under processing, the sheath 108 of the polymeric fibers 104
melts and upon cooling reforms in a solid state to secure with the
metal fibers 102 and other polymeric fibers 104. During melting,
the sheath 108 tends to collect at junction points where metal
fibers 102 and polymeric fibers 104 intersect. Therefore, as shown
in FIG. 1b, a portion of the polymeric fiber 104, and in this
embodiment the sheath 108 secures the metal fibers 102 and
polymeric fibers 104 to form the web 100. By including a polymeric
fiber 104 having a portion capable of securing with the other
polymeric fibers 104 and the metal fibers 102, there is not a need
for a separate binder to form the web 100.
[0030] The reconfigured sheath 108 of the polymeric fiber 104 will
typically contact and attach portions of metal fibers 102 and other
polymeric fibers 104 in contact with that particular polymeric
fiber 104. Therefore, the entire surface of the metal fibers 102
will not be covered or in contact with the sheath 108 of the
polymeric fiber 104. These exposed portions of the metal fibers 102
are then accessible for scouring, abrading, or otherwise contacting
a working surface.
[0031] However, a portion of the metal fiber 102 is covered with
the reconfigured sheath 108 of the polymeric fibers 104. Therefore,
these portions covered will be "soft" to the touch of the user so
that overall the web has less piercing impact on the hand of a user
as compared to a purely metal web.
[0032] Additionally, the polymeric fibers 104 being distributed
throughout the metal fibers 102 and randomly contacting and
attaching the metal fibers 102 helps minimize portions of the metal
fibers 102 from breaking free from the web 100. As can be seen in
FIG. 1b, a single metal fiber 102 may have several contact points
with the polymeric fiber 104 to assist with anchoring the metal
fiber 102 to the web. Therefore, web 100 of the present invention
sheds less metallic splinters as compared to a purely metal
web.
[0033] By blending the metal fibers 102 with polymeric fibers 104,
the overall need for metal fibers within the web is minimized. In
other words, the polymeric fibers 104 dilute the metal fibers 102,
and overall less metal fibers 102 are used in the web 100.
Typically, stainless steel has been a preferred material because of
its scouring and polishing ability and because it does not rust.
However, stainless steel is relatively expensive compared to steel
for example. The web 100 of the present invention allows for
incorporation of stainless steel into a low cost web because the
amount of metal (stainless steel) is diluted by the polymeric
fibers.
[0034] The web 100 of the present invention may be used as a
generally planar article as shown in FIG. 1. However, it is common
to corrugate webs to help enhance the scouring of the web. It is
within the scope of the present invention that the web 100 may be
corrugated or have other three dimensional geometric patterns, such
as circles, diamonds, rectangles, and squares.
[0035] The web 100 of the present invention may be used alone or in
combination with various support layers and substrates. If used
alone, further processing may be required to provide structural
integrity to the web 100. For example, the web 100 may be coated
with a binder resin over a single surface or may be coated with a
binder resin on a portion of a surface of the web 100. The web 100
may be needlepunched, also known as needletacked, to provide
structural integrity to the web 100.
[0036] In addition to metal fibers 102 and polymeric fibers 104,
additional fibers may be included in the web such as but not
limited to staple fibers such as polyester and nylon, or ceramic
fibers, carbon fibers, or natural fibers. The web 100 may also be
preloaded with detergent, soap, bleach, perfumes, colorants,
antibacterial or antifungal chemicals or other known types of
materials.
[0037] FIG. 2 is a perspective view of a scouring article 200
having a metal web 202, similar to that shown and described in FIG.
1a and FIG. 1b, attached to a support layer 204. Although the web
202 is similar in structure and composition as that shown and
described in FIG. 1a and FIG. 1b, the web 202 of FIG. 2 is
corrugated.
[0038] The web 202 is attached to the support layer 204 through any
known attaching mechanism such as, but not limited to,
needletacking, hydroentangling, heat bonding, ultrasonic bonding,
and binding through adhesive, or any combination thereof depending
on the substrate. A binding layer may include a coating of adhesive
covering the entire support layer 204 or a portion of it. A binding
layer may include discrete strands of binder 208, such as that
shown in FIG. 2. Examples of binding layers between the web 202 and
the support layer 204 are disclosed in U.S. patent application Ser.
No. 10/093,792, filed on Mar. 8, 2002, which is herein incorporated
by reference.
[0039] The discrete strands of binder 208 are typically parallel
strands that extend along the web 202 in a direction perpendicular
to the corrugation of the web 202, as shown in FIG. 2. Therefore,
the discrete strands of binder 208 prevent the corrugation of the
web 202 from pulling apart and also secure the web 202 to the
support layer 204. The discrete strands of binder 208 are
preferably made of a material that will attach the web 202 and the
support layer 204 together and will bend and flex with the scouring
article 200. In a preferred embodiment, the discrete strands of
binder 208 are propylene (7C50 available from DOW Chemical of
Midland, Mich.). The discrete strands of binder 208 may be
polypropylene or polyester.
[0040] The side of the web 202 opposite the support layer 204 is
the exposed surface of the web 202 for scouring. When the discrete
strands of binder 208 are included, the open spaces between the
discrete strands of binder 208 allow for fluid to pass from the
support layer 204 to the web 202 and vice versa. When the scouring
article is used for cleaning, water along with soap or detergent
may easily pass from the support layer 204 to the web 202. For such
applications, the support layer 204 or the web 202 may be preloaded
with a soap or detergent to assist with cleaning.
[0041] The support layer 204 used to support the web 202 may be any
material, which will aid in holding and touching the support layer
204 and minimizing skin contact directly with the web 202. The
support layer 204 is preferably flexible. Suitable substrates
include, but are not limited to, sponges, woven, nonwoven, paper,
foamed polyurethane and other foamed synthetic and natural
materials and other such materials.
[0042] Typically, the support layer 204 and the web 202 are of the
same size and shape as shown in FIG. 2. However, any shape, size,
or configuration of the support layer 204 and web 202 may be used.
For example, the web 202 may extend beyond the support layer 204 or
may wrap around a portion of the support layer 204 and therefore
cover more than one surface of the support layer 204. In another
example, the web 202 may cover two or more surfaces of the support
layer 204.
[0043] The scouring article 200 shown in FIG. 2 is intended to be
held in a user's hand. Therefore, a shape and size that is
ergonomically appropriate for hand-held use is preferred. For
example, a circular scouring article may have a diameter of 4
inches (10.2 cm). The overall thickness is dependent on the support
layer used. If a water absorbent, sponge-like backing is used,
typically the scouring article will have a thickness of less than 3
inches (7.6 cm). In another example, the scouring article may be
generally rectangular with a width of at least three inches and a
length of at least 4 inches (10.2 cm).
[0044] The scouring article 200 may be configured to secure to a
handle. Additionally, the scouring article 200 may be configured to
secure to a handle that delivers soap or a detergent to the support
layer 204 and therefore to the web 202 and working surface.
[0045] FIG. 3 is a cross-sectional view of the scouring article of
FIG. 2. As shown, the scouring article 200 includes the web 202
that is corrugated and the support layer 204. The web 202 is
attached to the support layer 204 with a binding layer that
comprises discrete strands of binder 208. FIG. 3 clearly shows that
the discrete strands of binder 208 cover discrete segments between
the web 202 and support layer 204. Therefore, open space exists
that would easily allow water or other fluid to pass from the
support layer 204 to the web 202 and therefore to the working
surface. The water or other fluid may carry soap or detergent that
also can be delivered to the working surface.
[0046] FIG. 4 is a cross-sectional view of an alternative scouring
article 300. The scouring article 300 includes a web 302, a support
layer 304 attached to the web 302, and a substrate 310 attached to
the support layer 304 by a binding layer comprising discrete
strands of binder 308. The web 302 is substantially similar to the
web 100 shown and described in FIG. 1. However, the web 302 is
preferably corrugated.
[0047] The support layer 304 supports the web 302 and provides
structural strength and reinforcement to the web 302. The support
layer 304 is attached to the web 302 by any known attachment
mechanisms and in this embodiment is attached to the web 302 by
needletacking. The support layer 304 is corrugated along with the
web 302 (as will be discussed with reference to FIG. 6) and
therefore has the same corrugation pattern as the web 302. The
support layer 304 may be any known material that will attach to and
support the web 302 such as, but not limited to, foam, woven,
nonwoven material, film, foamed polyurethane and other foamed
synthetic and natural materials. For the construction shown in the
embodiment of FIG. 4, preferably the support layer 304 is a thin,
flexible nonwoven. The side of the web 302 opposite the support
layer 304 is exposed for scouring.
[0048] The substrate 310 is attached to the support layer 304 on
the side of the support layer 304 opposite the web 302. The
substrate 310 can be any material such as foam, woven or nonwoven
material, foamed polyurethane and other foamed synthetic and
natural materials. In this embodiment, a binding layer comprising
discrete strands of binder 308 attaches the substrate 310 to the
support layer 304. The discrete strands of binder 308 are typically
spaced from one another and extend in a direction perpendicular to
the folded direction of the corrugation, as shown in FIG. 4. The
discrete strands of binder 308 are typically flexible to provide
flexibility to the overall scouring article 300.
[0049] FIG. 5 is a cross-sectional view of an alternative scouring
article 400. The scouring article 400 includes a web 402, a support
layer 404 attached to the web 402, and discrete strands of binder
408. The web 402 is substantially similar to the web 100 shown and
described in FIG. 1. However, the web 402 is preferably
corrugated.
[0050] The support layer 404 supports the web 402 and provides
structural strength and reinforcement to the web 402. In this
embodiment, the support layer 404 is attached to the web 402 by a
binding layer 406. The binding layer 406 in this embodiment is an
adhesive coating over substantially the entire surface of the
support layer 404. The support layer 404 is corrugated in the same
pattern as the corrugation of the web 402. The support layer 404
may be any known material that will attach to and support the web
402 such as, but not limited to, foam, woven and nonwoven material,
foamed polyurethane and other foamed synthetic and natural
materials. For the construction shown in the embodiment of FIG. 5,
preferably the support layer 404 is a thin, flexible nonwoven.
[0051] In this embodiment, discrete strands of binder 408 are
attached to the web 402 on the side of the web 402 opposite the
support layer 404. The discrete strands of binder 408 are typically
spaced from one another and extend in a direction perpendicular to
the folded direction of the corrugation, as shown in FIG. 5. The
discrete strands of binder 408 are typically flexible to provide
flexibility to the overall scouring article 400.
[0052] It is the exposed surface of the web 402 that is used for
scouring. Although the scouring article 400 shown in FIG. 5
includes a support layer 404 on one surface and discrete strands of
binder 408 on an opposite side, the discrete strands of binder 408
do not cover the entire surface of the web 402. The portions of the
web 402 exposed through the gaps in the discrete strands of binder
408 are used for scouring. The density and width of the discrete
strands of binder 408 determine the amount of web 402 exposed for
scouring. The discrete strands of binder 402 assist with
reinforcing the web 402 and further securing the metal fibers 102
within the web 402 to prevent splintering.
[0053] FIGS. 4 and 5 show alternative constructions of a scouring
article. As with the scouring article 200 shown and described in
FIG. 2, the scouring articles of FIGS. 4 and 5 can be of any size
or shape. The scouring articles may be designed for hand-held use
and therefore the portion contacting a user's hand can be of a
material comfortable for touching. The scouring article may be
designed for use with a handled tool.
[0054] For any of the scouring articles described, the support
layers or substrates, if included, may be preloaded with detergent,
soap, bleach, perfumes, antibacterial or antifungal chemicals. The
scouring articles may be firm and relatively rigid or may be
relatively flexible.
[0055] The scouring articles described have at least one side of
the web, similar to the web shown and described in FIG. 1a and FIG.
1b, exposed for scouring. The overall construction of the scouring
article may be any combination of a web attached to a support
layer. Any know attachment mechanism such as, but not limited to,
needletacking, hydroentangling, or binding with adhesive. The
binding layer may comprise an adhesive coating covering a portion
or the entire substrate or the binding layer may be discrete
strands of binder, or a combination thereof. Also, the portion of
the polymeric fiber securing the web together may extend to the
support layer to attach the web to the support layer. The
particular attachment mechanism will depend on the support layer
utilized, the concentration of polymeric fibers, and the end use
application. Any one of these mechanisms or any combination of
these mechanisms may be used to attach the web to the support layer
and to attach the substrate, if included.
[0056] The support layer may be any known type of material such as
foam, woven, nonwoven, paper, foamed polyurethane and other foamed
synthetic and natural materials other similar material. Optionally,
the scouring article may include additional substrate layers which
may be any know type of material.
[0057] To scour a surface, a user may use a web similar in
construction to the web shown and described in FIG. 1a and FIG. 1b
and contact the surface to be scoured with the web. Additionally, a
scouring article may be used, such as shown in FIGS. 2-5, which
includes an exposed web surface for contacting a surface to be
scoured. In such a web or scouring article, the user may hold the
web or scouring article or may attach it to a handled tool.
[0058] The present invention may be used to scour or abrade any
number of surfaces. Particularly, the present invention may be used
to scour or abrade surfaces that are accommodating to steel wool
pads or other such metal pads. Such surfaces include, but are not
limited to metal and wood surfaces. One particular application of
the web and scouring article of the present invention includes
scouring metal pots, pans, and other kitchenware. In such an
instance, the web and scouring article of the present invention
scours and removes debris from the surface and polishes the metal.
Another application of the web and scouring article of the present
invention includes abrading and finishing wood surfaces during
refinishing. Preferably, the metal fibers included in the web will
not rust.
[0059] There are a number of suitable ways of making a web and a
scouring article in accordance with the present invention. The web
such as the web 100 shown in FIG. 1 may be formed using chopped
metal fibers and polymeric fibers, which include a core and a
sheath, on a "Rando Webber" machine (commercially available from
Rando Machine Company, New York) or may be formed by other
conventional processes. After the web is formed, the web may be
needletacked to give added structural strength to the web. The web
may then be heated to melt the sheath and then cooled to solidify
the sheath of the polymeric fibers to form the web. It is
understood that the same processing may occur in the event a single
or other multicomponent fiber is used.
[0060] A method of making a scouring article, such as the scouring
article 200 shown in FIG. 2, is generally shown in U.S. patent
application Ser. No. 10/093,792, filed on Mar. 8, 2002, herein
incorporated by reference. FIG. 6 is a side view of an exemplary
process of making the scouring article of FIG. 1 and FIG. 2. FIG. 6
generally comprises forming a scouring article 200 by extruding a
binding layer 208 between the web 100 and the support layer 204.
The supplied web 100 may be a web formed from chopped metal fibers
and polymeric fibers on a Rando Webber machine. The web 100 may be
needletacked.
[0061] The method of making the scouring article shown in FIG. 6,
is performed by providing first and second corrugating members or
rollers 26, 27 each having an axis and including a plurality of
circumferentially spaced generally axially extending ridges 28
around and defining its periphery, with spaces between the ridges
28 adapted to receive portions of the ridges 28 of the other
corrugating member, 26 or 27, in meshing relationship with the web
100 between the meshed ridges 28. The corrugating members 26 and 27
are mounted in axially parallel relationship with portions of the
ridges 28 meshing generally in the manner of gear teeth; at least
one of the corrugating members 26 or 27 is rotated; and the web 100
is fed between the meshed portions of the ridges 28 of the
corrugating members 26 and 27 to generally corrugate the web 100 to
form a corrugated web 202. The corrugated web 202 is retained along
the periphery of the second corrugating member 27 after it has
moved past the meshed portions of the ridges 28.
[0062] The first and second corrugating rollers 26, 27 are
preferably heated. The heat from the corrugating rollers serves to
melt the sheath of the polymeric fibers in the web. Alternatively,
a heat source may be included in the processing prior to the
corrugating rollers 26, 27 after the web is formed.
[0063] A binding layer, which in this embodiment are discrete
strands of binder 208, is extruded from a die 24 into a nip formed
between the second corrugating member 27 and a cooling roller 25
while simultaneously supplying the support layer 204 into the nip
formed between the second corrugating member 27 and the cooling
roller 25 along the surface of cooling roller 25. It is understood
that the die 24 can extrude a continuous stream of binder so that
the binder layer covers the entire support layer surface or can
extrude a plurality of discrete strands of binder. The discrete
strands of binder 208 are deposited between the support layer 204
and the corrugated web 202 and bond the support layer 204 to the
corrugated web 202.
[0064] The scouring article 200 is carried partially around the
cooling roller 25 to complete cooling. The scouring article 200 is
then converted into sizes and shapes for use.
[0065] It is understood that other arrangements of making a
scouring article, such as those shown in FIG. 4 and 5 are within
the scope of the present invention. Also, it is understood that
various materials for the support layer and binding layer may be
used.
[0066] Although specific embodiments of this invention have been
shown and described herein, it is understood that these embodiments
are merely illustrative of the many possible specific arrangements
that can be devised in application of the principles of the
invention. Numerous and varied other arrangements can be devised in
accordance with these principles by those of ordinary skill in the
art without departing from the spirit and scope of the invention.
Thus, the scope of the present invention should not be limited to
the structures described in this application, but only by the
structures described by the language of the claims and the
equivalents of those structures.
EXAMPLES
Example 1
[0067] A stainless steel loose fiber web was prepared in the
following manner. A tow of stainless steel fiber ("Fine" stainless
steel fiber, Product No. 161050, available from Global Metal
Technologies, Palatine, Ill.), having an average diameter of 50
microns, was chopped into 0.5 inch (1.27 cm) length fibers by hand
using a pair of scissors. The stainless steel fibers were then
combined with a polyester/copolyester bicomponent binder fiber
(Celbond.RTM. Type 254, 12 denier, cut length 1.5 inches, available
from KoSa, Charlotte, N.C.) in an 85:15 weight ratio (stainless
steel fiber:bicomponent fiber). A 200 gsm (grams per square meter)
lofty nonwoven web approximately 15 mm (millimeters) thick was
prepared from the fiber blend using an air lay machine available
under the trade designation "RANDO WEBBER" from Rando Machine
Corporation, Macedon, N.Y. The loose fiber web was then
needletacked to consolidate the web to improve its handling
strength for further processing by using a conventional
needletacking apparatus (commercially available under the trade
designation "DILO" from Dilo of Germany, with type #15x18x36x3.5 RB
barbed needles (commercially available from Foster Needle Company,
Inc. of Manitowoc, Wis.)) to provide about 15 punches per square
centimeter. The barbed needles were punched through the full
thickness of the web. After needletacking the web was about 5 mm
thick.
[0068] The loose fiber web was then processed using the method and
equipment illustrated in FIG. 6. The web was fed into the nip
between first and second intermeshing corrugation rolls 26, 27,
which were machined with axially parallel ridges spaced such that
there were approximately 4 ridges per centimeter with a groove
between each ridge. The corrugation rolls were heated to
295.degree. F. (146.degree. C.) and the nip pressure was 150 pli.
The patterned web was shaped such that there were raised regions or
peaks and anchor portions that formed valleys along the nonwoven
web, each raised region or peak being about 1.5 mm high and each
anchor portion being about 2 mm wide. After passing through the
corrugation rolls 26, 27, the corrugated web traveled along the
surface corrugation roll 27 to the nip point between the second
corrugation roll 27 and the chill roll 25. The corrugated web was
then cooled by passing the web over chill roll 25. The temperature
of chill roll 25 was about 50.degree. F. (10.degree. C.) and the
nip pressure was about 150 pli. After corrugating, the web was
approximately 2 mm thick. The web was then wound into master rolls
for converting.
Example 2
[0069] A stainless steel loose fiber web was prepared in the
following manner. A tow of stainless steel fiber ("Fine" stainless
steel fiber, Product No. 161050, available from Global Metal
Technologies, Palatine, Ill.), having an average diameter of 50
microns, was chopped into 0.5 inch (1.27 cm) length fibers by hand
using a pair of scissors. The stainless steel fibers were then
combined with a polyester/copolyester bicomponent binder fiber
(Celbond.RTM. Type 254, 12 denier, cut length 1.5 inches, available
from KoSa, Charlotte, N.C.) and a 25 denier polyester staple fiber
(product 694P available from Wellmann, Fort Mill, S.C.) at a weight
ratio of 85:8:7 (stainless steel fiber:bicomponent fiber: polyester
fiber). A 200 gsm lofty nonwoven web approximately 15 mm thick was
prepared from the fiber blend using an air lay machine available
under the trade designation "RANDO WEBBER" from Rando Machine
Corporation, Macedon, N.Y. The loose fiber web was then
needletacked to consolidate the web to improve its handling
strength for further processing by using a conventional
needletacking apparatus (commercially available under the trade
designation "DILO" from Dilo of Germany, with type #15x18x36x3.5 RB
barbed needles (commercially available from Foster Needle Company,
Inc. of Manitowoc, Wis.)) to provide about 15 punches per square
centimeter. The barbed needles were punched through the full
thickness of the web. After needletacking the web was about 5 mm
thick.
[0070] The loose fiber web was then processed using the method and
equipment illustrated in FIG. 6. The web was fed into the nip
between first and second intermeshing corrugation rolls 26, 27,
which were machined with axially parallel ridges spaced such that
there were approximately 4 ridges per centimeter with a groove
between each ridge. The corrugation rolls 26, 27 were heated to
295.degree. F. (146.degree. C.) and the nip pressure was 150 pli.
The patterned web was shaped such that there were raised regions or
peaks and anchor portions that formed valleys along the nonwoven
web, each raised region or peak being about 1.5 mm high and each
anchor portion being about 2 mm wide. After passing through the
corrugation rollers 26, 27, the corrugated web traveled along the
surface of corrugation roll 27 to the nip point between the second
corrugation 27 roll and the chill roll 25. The corrugated web was
then cooled by passing the web over chill roll 25. The temperature
of chill roll 25 was about 50.degree. F. (10.degree. C.) and the
nip pressure was about 150 pli. After corrugating, the web was
approximately 2 mm thick. The web was then wound into master rolls
for converting.
Example 3
[0071] A stainless steel loose fiber web was prepared in the
following manner. A tow of stainless steel fiber ("Fine" stainless
steel fiber, Product No. 161050, available from Global Metal
Technologies, Palatine, Ill.), having an average diameter of 50
microns, was chopped into 0.5 inch (1.27 cm) length fibers by hand
using a pair of scissors. The stainless steel fibers were then
combined with a polyester/copolyester bicomponent binder fiber
(Celbond.RTM. Type 254, 12 denier, cut length 1.5 inches, available
from KoSa, Charlotte, N.C.) in an 85:15 weight ratio (stainless
steel fiber:bicomponent fiber). A 200 gsm lofty nonwoven web
approximately 15 mm thick was prepared from the fiber blend using
an air lay machine available under the trade designation "RANDO
WEBBER" from Rando Machine Corporation, Macedon, N.Y. To improve
handling strength, the resulting web was attached to a 10 gsm nylon
spun-bond nonwoven backing (available from Cerex Advance Fabrics,
Cantonment, Fla.) using a conventional needletacking apparatus
(commercially available under the trade designation "DILO" from
Dilo of Germany, with type #15x18x36x3.5 RB barbed needles
(commercially available from Foster Needle Company, Inc. of
Manitowoc, Wis.)) to provide about 15 punches per square
centimeter. The barbed needles were punched through the full
thickness of the web. After needletacking the web was about 5 mm
thick.
[0072] The loose fiber web, with the nylon spun-bond nonwoven
backing attached was then processed using the method and equipment
illustrated in FIG. 6. The web was fed into the nip (stainless
steel fiber web side down) between first and second intermeshing
corrugation rolls 26, 27, which were machined with axially parallel
ridges spaced such that there were approximately 4 ridges per
centimeter with a groove between each ridge. The corrugation rolls
26, 27 were heated to 295.degree. F. (146.degree. C.) and the nip
pressure was 150 pli. The patterned web was shaped such that there
were raised regions or peaks and anchor portions that formed
valleys along the nonwoven web, each raised region or peak being
about 1.5 mm high and each anchor portion being about 2.0 mm wide.
After passing through the nip point, the corrugated web traveled
along the surface of corrugation roll 27 to the nip point between
the second corrugation roll 27 and the chill roll 25. The
corrugated web was then laminated/bonded to 0.5 inch thick
polyurethane foam (indicated by reference number 204) by extruding
polypropylene 208 (7C50 polypropylene resin, available from Dow
Chemical Company, Midland, Mich.) filaments onto the anchor
portions of the corrugated web just prior to the nip point as the
polyurethane foam was fed into the nip point from feed roll. The
polypropylene was extruded through 0.83 mm diameter orifices to
result in about 3.5 filaments per centimeter at a basis weight of
about 55 gsm of web. The corrugated web was then cooled by passing
the web over chill roll 25. The temperature of chill roll 25 was
about 50.degree. F. (10.degree. C.) and the nip pressure was about
150 pli. After corrugating, the web was approximately 2 mm thick.
The web was then wound into master rolls for converting.
Example 4
[0073] A stainless steel loose fiber web was prepared in the
following manner. A tow of stainless steel fiber ("Fine" stainless
steel fiber, Product No. 161050, available from Global Metal
Technologies, Palatine, Ill.), having an average diameter of 50
microns, was chopped into 0.5 inch (1.27 cm) length fibers by hand
using a pair of scissors. The stainless steel fibers were then
combined with a polyester/copolyester bicomponent binder fiber
(Celbond.RTM. Type 254, 12 denier, cut length 1.5 inches, available
from KoSa, Charlotte, N.C.) in a 85:15 weight ratio (stainless
steel fiber:bicomponent fiber). A 200 gsm lofty nonwoven web
approximately 5 mm thick was prepared from the fiber blend using an
air lay machine available under the trade designation "RANDO
WEBBER" from Rando Machine Corporation, Macedon, N.Y. A blend
(50:50 weight ratio) of 25 denier polyester fiber (Wellman 694P
available from Wellman Inc. of Fort Mill, S.C.) and a
polyester/copolyester bicomponent binder fiber (Celbond.RTM. Type
254, 12 denier, cut length 1.5 inches, available from KoSa,
Charlotte, N.C.) was carded using conventional carding equipment
and then passed through an oven at 305.degree. F. (152.degree. C.)
to prepare a 100 gsm thermal bonded web. The stainless steel loose
fiber web and the thermal bonded web were then needletacked
together using a conventional needletacking apparatus (commercially
available under the trade designation "DILO" from Dilo of Germany,
with type #15x18x36x3.5 RB barbed needles (commercially available
from Foster Needle Company, Inc. of Manitowoc, Wis.)) to provide
about 15 punches per square centimeter. The barbed needles were
punched through the full thickness of the web. After needletacking
the web was about 5 mm thick.
[0074] The loose fiber web was then processed using the method and
equipment illustrated in FIG. 6. The web was fed into the nip
(stainless steel fiber web side down) between first and second
intermeshing corrugation rolls 26, 27 which were machined with
axially parallel ridges spaced such that there were approximately 4
ridges per centimeter with a groove between each ridge. The
corrugation rolls 26, 27 were heated to 295.degree. F. (146.degree.
C.) and the nip pressure was 150 pli. The patterned web was shaped
such that there were raised regions or peaks and anchor portions
that formed valleys along the nonwoven web, each raised region or
peak being about 1.5 mm high and each anchor portion being about 2
mm wide. After passing through the corrugation rolls 26, 27, the
corrugated web traveled along the surface of corrugation roll 27 to
the nip point between the second corrugation roll 27 and the chill
roll 25. The corrugated web was then cooled by passing the web over
chill roll 25. The temperature of chill roll 25 was about
50.degree. F. (10.degree. C.) and the nip pressure is about 150
pli. After corrugating, the web was approximately 2 mm thick. The
web was then wound into master rolls for converting.
Example 5
[0075] A loose fiber web was prepared in a manner identical to
Example 2.
[0076] The loose fiber web was then processed using the method and
equipment illustrated in FIG. 6. The web was fed into the nip
(stainless steel fiber web side down) between first and second
intermeshing corrugation rolls 26, 27, which were machined with
axially parallel ridges spaced such that there were approximately 4
ridges per centimeter with a groove between each ridge. The
corrugation rolls 26, 27 were heated to 295.degree. F. and the nip
pressure was 150 pli. The patterned web was shaped such that there
were raised regions or peaks and anchor portions that formed
valleys along the nonwoven web, each raised region or peak being
about 1.5 mm high and each anchor portion being about 2 mm wide.
After passing through the corrugation rolls 26, 27, the corrugated
web traveled along the surface of corrugation roll 27 to the nip
point between the second corrugation roll 27 and the chill roll 25.
Polypropylene 28 (7C50 Polypropylene Resin, available from Dow
Chemical Company, Midland, Mich.) filaments were then extruded onto
the anchor portions of the corrugated web just prior to the nip
point. The polypropylene was extruded through 0.83 mm diameter
orifices to result in about 3.5 filaments per centimeter at a basis
weight of about 55 gsm of web. The corrugated web was then cooled
by passing the web over chill roll 25. The temperature of chill
roll 25 was about 50.degree. F. (10.degree. C.) and the nip
pressure was about 150 pli. After corrugating the web was
approximately 2 mm thick. The web was then wound into master rolls
for converting.
* * * * *