Patent Application
20150273658
The present disclosure is directed to an abrasive article and to a button for attaching an abrasive article to a back-up pad.
Abrasive articles can be quite useful for smoothing surfaces, polishing surfaces, removing material from surfaces, for cleaning surfaces, etc. Certain types of abrasive articles are configured in the shape of a wheel. During use, these abrasive wheels are rotated to create a moving surface on the abrasive wheel that can be placed in contact with another surface in order to alter a characteristic of that surface. In order to rotate an abrasive wheel, the abrasive wheel is typically mechanically coupled to a shaft of a motor via a tool holder, e.g., a chuck, that can be tightened to engage a portion of the abrasive wheel.
In response to changes in the abrasives industry, new ways to connect abrasive articles may be desirable.
Embodiments are illustrated by way of example and are not limited in the accompanying figures.
Skilled artisans appreciate that elements in the figures are illustrated for simplicity and clarity and have not necessarily been drawn to scale. For example, the dimensions of some of the elements in the figures can be exaggerated relative to other elements to help to improve understanding of embodiments of the invention. The use of the same reference symbols in different drawings indicates similar or identical items.
The following description in combination with the figures is provided to assist in understanding the teachings disclosed herein. The following discussion will focus on specific implementations and embodiments of the teachings. This focus is provided to assist in describing the teachings and should not be interpreted as a limitation on the scope or applicability of the teachings. As used herein, the terms “comprises,” “comprising,” “includes,” “including,” “has,” “having,” or any other variation thereof, are intended to cover a non-exclusive inclusion. For example, a process, method, article, or apparatus that comprises a list of features is not necessarily limited only to those features but can include other features not expressly listed or other features that are inherent to such process, method, article, or apparatus. Further, unless expressly stated to the contrary, “or” refers to an inclusive-or and not to an exclusive-or. For example, a condition A or B is satisfied by any one of the following: A is true (or present) and B is false (or not present), A is false (or not present) and B is true (or present), and both A and B are true (or present).
The use of “a” or “an” is employed to describe elements and components described herein. This is done merely for convenience and to give a general sense of the scope of the embodiments of the disclosure. This description should be read to include one or at least one and the singular also includes the plural, or vice versa, unless it is clear that it is meant otherwise. Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this disclosure belongs. The materials, methods, and examples are illustrative only and not intended to be limiting.
Referring initially to
A shank 116 can extend from the distal end 114 of the housing 110. The shank 116 can be received and clamped within a drill chuck (not shown) or some other rotating tool. Thus, as the drill chuck rotates, the shank 116 will rotate, and can cause the entire abrasive article assembly 100 to rotate. The rotating abrasive article assembly 100 can be moved across a surface to be finished in order to abrade the surface, to smooth the surface, to polish the surface, to clean the surface, etc.
In one non-limiting, exemplary embodiment the non-woven abrasive article 104 can include a support, at least one polymeric binder, and abrasive particles. In one aspect, the support can include one or more nonwoven layers. Each nonwoven layer can include a plurality of fibers. The fibers can be bonded to each other by a polymeric binder, such as one derived from a latex. The fibers can include natural fibers, inorganic fibers, such as fiberglass, synthetic fibers, such as polyester fibers, polyamide fibers, or other suitable synthetic fibers, or any combination thereof.
The abrasive particles can have a Mohs hardness of at least about 8.0, such as at least about 8.5, even at least about 9.0. In particular, the abrasive particles 108 can include superabrasive particles, such as diamond, cubic boron nitride, boron carbide, silicon carbide, or any combination thereof. The abrasive particles can have a size of between about 10 microns and about 1000 microns, such as between about 50 microns and about 500 microns, particularly between about 100 microns and about 200 microns.
The one or more polymeric binders can include a curable polymeric binder. The curable polymeric binder can include a polyurethane resin, a phenoxy resin, polyester resin, or any combination thereof. Further, the curable polymeric binder can include a blocked resin. Polymeric binder can be a strong and flexible polymeric binder in order to hold the support together during abrading while allowing the support to be flexible enough to conform to the shape of the work piece. In a particular embodiment, the polymeric binder can be located between the fibers and the abrasive particles.
In another aspect, the polymeric binder can include another polymeric binder, such as a phenolic resin, an epoxy resin, a formaldehyde-urea resin, or any combination thereof. The other polymeric binder can include a binder that bonds without significant curing and this binder can be used bond the abrasive particles to the support and to permit additionally processing of the abrasive article.
In an embodiment, the one or more polymeric binders can be formed from binder formulations that can further include components such as dispersed filler, solvents, plasticizers, chain transfer agents, catalysts, stabilizers, dispersants, curing agents, reaction mediators, or agents for influencing the fluidity of the dispersion. In addition to the above constituents, other components can also be added to the binder formulation, including, for example, anti-static agents, such as graphite, carbon black, and the like; suspending agents, such as fumed silica; anti-loading agents, such as metal stearate, including zinc, calcium, or magnesium stearate; lubricants such as wax; wetting agents; dyes; fillers; viscosity modifiers; defoamers; or any combination thereof.
In one particular embodiment, the non-woven abrasive article 104 can have an open structure. Specifically, the open structure can include voids located between the fibers. The open structure can be at least about 25% open volume, such as at least about 40% open volume, such as at least about 55% open volume. Additionally, the open structure can be not greater than about 99% open volume, such as not greater than about 95% open volume, even not greater than about 90% open volume.
In an embodiment, the non-woven abrasive article 104 can have a hardness of 20 kgf/25% compression to 90 kgf/25% compression, such as 30 kgf/25% compression to 80 kgf/25% compression, even 40 kgf/25% compression to 70 kgf/25% compression as measured by applying a force with a 25.4 mm semi-spherical probe to compress the abrasive article by 25% along the thickness direction. In a particular embodiment, the hardness can be 50 to 60 kgf/25% compression.
For example, OLP can be ≦50% OAA and ≧10% OAA, such as ≦50% OAA and ≧15% OAA, ≦50% OAA and ≧20% OAA, or ≦50% OAA and ≧25% OAA. In another aspect, OLP can be ≦45% OAA and ≧10% OAA, such as ≦45% OAA and ≧15% OAA, ≦45% OAA and ≧20% OAA, or ≦45% OAA and ≧25% OAA. OLP can be ≦40% OAA and ≧10% OAA, such as ≦40% OAA and ≧15% OAA, ≦40% OAA and ≧20% OAA, or ≦40% OAA and ≧25% OAA. OLP can be ≦35% OAA and ≧10% OAA, such as ≦35% OAA and ≧15% OAA, ≦35% OAA and ≧20% OAA, or ≦35% OAA and ≧25% OAA. OLPcan be ≦30% OAA and ≧10% OAA, such as ≦30% OAA and ≧15% OAA, ≦30% OAA and ≧20% OAA, or ≦30% OAA and ≧25% OAA.
A hub 134 can extend from the lower plate 132. The hub 134 can include a proximal end 136 and a distal end 138. In one aspect, the hub 134 is configured to fit into and engage the abrasive article 104 when the abrasive article 104 is installed over the hub 134 such that the hub 134 fits into the similarly sized and shaped central bore 126 of the abrasive article 104. The hub 134 is configured to engage the abrasive article 104, e.g., the inner wall of the central bore 126, at least partially along a height of the hub 124 in order to engage the abrasive article 104 and to prevent the abrasive article 104 from rotating relative to the hub 134.
When the hub 134 is disengaged from the back-up pad 102 and removed from the abrasive article 104, the hub 134 can include a height, HH, and the bore 126 within the abrasive article 104 can include a height, HB. In a particular aspect, HH≦0.99 HB. Moreover, HH≦0.98 HB, such as ≦0.97 HB, ≦0.96 HB, ≦0.95 HB, ≦0.94 HB, ≦0.93 HB, ≦0.92 HB, ≦0.91 HB, or ≦0.90 HB. In another aspect, HH≧0.80 HB, such as ≧0.81 HB, ≧0.82 HB, ≧0.83 HB, ≧0.84 HB, or ≧0.85 HB. HH can be within a range between and including any of the values of HH described herein.
For example, HH can be ≦0.99 HBand ≧0.80 HB, such as ≦0.99 HBand ≧0.81 HB, ≦0.99 HB and ≧0.82 HB, ≦0.99 HB and ≧0.83 HB, ≦0.99 HB and ≧0.84 HB, or ≦0.99 HB and ≧0.85 HB. HH can be ≦0.98 HB and ≧0.80 HB, such as ≦0.98 HB and ≧0.81 HB, ≦0.98 HB and ≧0.82 HB, ≦0.98 HB and ≧0.83 HB, ≦0.98 HB and ≧0.84 HB, or ≦0.98 HB and ≧0.85 HB.
In another aspect, HH can be ≦0.97 HB and ≧0.80 HB, such as ≦0.97 HB and ≧0.81 HB, ≦0.97 HB and ≧0.82 HB, ≦0.97 HB and ≧0.83 HB, ≦0.97 HB and ≧0.84 HB, or ≦0.97 HB and ≧0.85 HB. HH can be ≦0.96 HB and ≧0.80 HB, such as ≦0.96 HB and ≧0.81 HB, ≦0.96 HB and ≧0.82 HB, ≦0.96 HB and ≧0.83 HB, ≦0.96 HB and ≧0.84 HB, or ≦0.96 HB and ≧0.85 HB. HH can be ≦0.95 HB and ≧0.80 HB, such as ≦0.95 HB and ≧0.81 HB, ≦0.95 HB and ≧0.82 HB , ≦0.95 HB and ≧0.83 HB , ≦0.95 HB and ≧0.84 HB, or ≦0.95 HB and ≧0.85 HB. HH can be ≦0.94 HB and ≧0.80 HB, such as ≦0.94 HB and ≧0.81 HB, ≦0.94 HB and ≧0.82 HB, ≦0.94 HB and ≧0.83 HB, ≦0.94 HB and ≧0.84 HB, or ≦0.94 HB and ≧0.85 HB.
HH can also be ≦0.93 HB and ≧0.80 HB, such as ≦0.93 HB and ≧0.81 HB, ≦0.93 HB and ≧0.82 HB, ≦0.93 HB and ≧0.83 HB, ≦0.93 HB and ≧0.84 HB, or ≦0.93 HB and ≧0.85 HB. HH can be ≦0.92 HB and ≧0.80 HB, such as ≦0.92 HB and ≧0.81 HB, ≦0.92 HB and ≧0.82 HB, ≦0.92 HB and ≧0.83 HB, ≦0.92 HB and ≧0.84 HB, or ≦0.92 HB and ≧0.85 HB. HH can be ≦0.91 HB and ≧0.80 HB, such as ≦0.91 HB and ≧0.81 HB, ≦0.91 HB and ≧0.82 HB, ≦0.91 HB and ≧0.83 HB, ≦0.91 HB and ≧0.84 HB, or ≦0.91 HB and ≧0.85 HB. HH can be ≦0.90 HB and ≧0.80 HB, such as ≦0.90 HB and ≧0.81 HB, ≦0.90 HB and ≧0.82 HB, ≦0.90 HB and ≧0.83 HB, ≦0.90 HB and ≧0.84 HB, or ≦0.90 HB and ≧0.85 HB.
Since HH can be less than HB before the button 130 is installed through the abrasive article 104 and engaged with the back-up pad 102, when the button 130 is engaged with the back-up pad 102 and the abrasive article 104 is captured between the lower plate 132 and the proximal end 112 of the back-up pad 102, the abrasive article 104 can be compressed between the lower plate 132 of the button 130 and the proximal end 112 of the back-up pad 102 such that the height of the bore when engaged, HBE, is equal to HH.
In a particular aspect, the button 130 can be configured to apply a compressive force on the abrasive article, CF, wherein CF can be ≧5 lbs, such as ≧6 lbs, ≧7 lbs, ≧8 lbs, ≧9 lbs, or ≧10 lbs. Further, CF can be ≦50 lbs, such as ≦40 lbs, ≦30 lbs, ≦20 lbs, or ≦15 lbs. Moreover, CF can be within a range between and including any of the values of CF described herein.
For example, CF can be ≧5 lbs and ≦50 lbs, such as ≧5 lbs and ≦40 lbs, ≧5 lbs and ≦30 lbs, ≧5 lbs and ≦20 lbs, or ≧5 lbs and ≦15 lbs. CF can also be ≧6 lbs and ≦50 lbs, such as ≧6 lbs and ≦40 lbs, ≧6 lbs and ≦30 lbs, ≧6 lbs and ≦20 lbs, or ≧6 lbs and ≦15 lbs. CF can be ≧7 lbs and ≦50 lbs, such as ≧7 lbs and ≦40 lbs, ≧7 lbs and ≦30 lbs, ≧7 lbs and ≦20 lbs, or ≧7 lbs and ≦15 lbs. CF can be ≧8 lbs and ≦50 lbs, such as ≧8 lbs and ≦40 lbs, ≧8 lbs and ≦30 lbs, ≧8 lbs and ≦20 lbs, or ≧8 lbs and ≦15 lbs. CF can be ≧9 lbs and ≦50 lbs, such as ≧9 lbs and ≦40 lbs, ≧9 lbs and ≦30 lbs, ≧9 lbs and ≦20 lbs, or ≧9 lbs and ≦15 lbs. CF can be ≧10 lbs and ≦50 lbs, such as ≧10 lbs and ≦40 lbs, ≧10 lbs and ≦30 lbs, ≧10 lbs and ≦20 lbs, or ≧10 lbs and ≦15 lbs.
The hub 134 can have a cross-sectional shape, or an end shape, perpendicular to the central axis 128 that includes a convex polygon having at least three vertices. For example, the cross-sectional shape of the hub can be selected from the group of shapes including: triangle, square, pentagon, and hexagon. In another aspect, the hub 134 can have a cross-sectional shape, or end shape, perpendicular to the central axis 128 that includes a concave polygon having at least six vertices. In this aspect, the cross-sectional shape of the hub 134 can be selected from the group of shapes including: concave hexagon, concave octagon, concave decagon, and concave dodecagon. In still another aspect, the hub 134 can have a cross-sectional shape, or end shaped, perpendicular to the central axis 128 that includes a regular star polygon having at least ten vertices. The at least ten vertices can be selected from the group that includes: 10, 14, 18, 22, and 26 vertices.
In another aspect, the distal end 138 of the hub 134 includes a surface area, AHDE, and the upper surface 120 of the abrasive article 104 can also include a surface area AUSA. In this aspect, AHDE can be ≦10.0% AUSA, such as ≦7.5% AUSA, ≦5.0% AUSA, ≦4.0% AUSA, or ≦3.0% AUSA. Further, AHDE can be ≧0.5% AUSA, such as ≧0.75% AUSA, ≧1.0% AUSA, ≧1.25% AUSA, ≧1.5% AUSA, ≧1.75% AUSA, ≧2.0% AUSA, or ≧2.5% AUSA. AHDE can be within a range between and including any of the values of AHDE described herein.
For example, AHDE can be ≦10.0% AUSA and ≧0.5% AUSA, such as ≦10.0% AUSA and ≧0.75% AUSA, ≦10.0% AUSA and ≧1.0% AUSA, ≦10.0% AUSA and ≧1.5% AUSA, ≦10.0% AUSA and ≧2.0% AUSA, or ≦10.0% AUSA and ≧2.5% AUSA. AHDE can be ≦7.5% AUSA and ≧0.5% AUSA, such as ≦7.5% AUSA and ≧0.75% AUSA, ≦7.5% AUSA and ≧1.0% AUSA, ≦7.5% AUSA and ≧1.5% AUSA, ≦7.5% AUSA and ≧2.0% AUSA, or ≦7.5% AUSA and ≧2.5% AUSA. AHDE can be ≦5.0% AUSA and ≧0.5% AUSA, such as ≦5.0% AUSA and ≧0.75% AUSA, ≦5.0% AUSA and ≧1.0% AUSA, ≦5.0% AUSA and ≧1.5% AUSA, ≦5.0% AUSA and ≧2.0% AUSA, or ≦5.0% AUSA and ≧2.5% AUSA. AHDE can be ≦4.0% AUSA and ≧0.5% AUSA, such as ≦4.0% AUSA and ≧0.75% AUSA, ≦4.0% AUSA and ≧1.0% AUSA, ≦4.0% AUSA and ≧1.5% AUSA, ≦4.0% AUSA and ≧2.0% AUSA, or ≦4.0% AUSA and ≧2.5% AUSA. Moreover, AHDE can be ≦3.0% AUSA and ≧0.5% AUSA, such as ≦3.0% AUSA and ≧0.75% AUSA, ≦3.0% AUSA and ≧1.0% AUSA, ≦3.0% AUSA and ≧1.5% AUSA, ≦3.0% AUSA and ≧2.0% AUSA, or ≦3.0% AUSA and ≧2.5% AUSA.
As further depicted in
As such, if L=0.50 HP, then it takes 2 rotations of the engagement post 150 to fully engage the post 150 with the back-up pad 102. L=0.57 HP corresponds to 1.75 rotations. L=0.66 HP corresponds to 1.5 rotations. L=0.80 HP corresponds to 1.25 rotations. L=4.00 HP corresponds to 0.25 rotations. L=2.00 HP corresponds to 0.50 rotations. L=1.33 HP corresponds to 0.75 rotations. L=1.00 HP corresponds to 1.00 rotations.
L can also be within a range between and including any of the values of L described above. For example, L can be ≧0.50 HP and ≦4.00 HP, such as ≧0.50 HP and ≦2.00 HP, ≧0.50 HP and ≦1.33 HP, or ≧0.50 HP and ≦1.00 HP. L can be ≧0.57 HP and ≦4.00 HP, such as ≧0.57 HP and ≦2.00 HP, ≧0.57 HP and ≦1.33 HP, or ≧0.57 HP and ≦1.00 HP. L can be ≧0.66 HP and ≦4.00 HP, such as ≧0.66 HP and ≦2.00 HP, ≧0.66 HP and ≦1.33 HP, or ≧0.66 HP and ≦1.00 HP. L can also be ≧0.80 HP and ≦4.00 HP, such as ≧0.80 HP and ≦2.00 HP, ≧0.80 HP and ≦1.33 HP, or ≧0.80 HP and ≦1.00 HP.
In another aspect, L can be ≧0.50 HP and ≦0.80 HP, such as ≧0.50 HP and ≦0.66 HP, or ≧0.5 HP and ≦0.57 HP. In yet another aspect, L can be ≦4.00 HP and ≧1.00 HP, such as ≦4.00 HPand ≧1.33 HP, or ≦4.00 HP and ≧2.00 HP.
In this aspect, the twisted hub 504 is twisted along a height of the hub 504 so that the distal end 506 of the hub 504 is rotated with respect to a proximal end 506 of the hub by an angle, α. In a particular aspect, α can be ≧5.0°, such as ≧6.0°, ≧7.0°, ≧8.0°, ≧9.0°, or ≧10.0°. Further, α can be ≦30°, such as ≦25°, ≦20°, ≦15°, or ≦12.5°. In another aspect, α can be within a range between and including and of the values of α described herein.
For example, α can be ≧5.0°and ≦30°, such as ≧5.0°and ≦25°, ≧5.0°and ≦20°, ≧5.0°and ≦15°, or ≧5.0°and ≦12.5°. α can be ≧6.0°and ≦30°, such as ≧6.0°and ≦25°, ≧6.0°and ≦20°, ≧6.0°and ≦15°, or ≧6.0°and ≦12.5°. α can be ≧7.0°and ≦30°, such as ≧7.0°and ≦25°, ≧7.0°and ≦20°, ≧7.0°and ≦15°, or ≧7.0°and ≦12.5°. α can be ≧8.0°and ≦30°, such as ≧8.0°and ≦25°, ≧8.0°and ≦20°, ≧8.0°and ≦15°, or ≧8.0°and ≦12.5°. α can be ≧9.0°and ≦30°, such as ≧9.0°and ≦25°, ≧9.0°and ≦20°, ≧9.0°and ≦15°, or ≧9.0°and ≦12.5°. Moreover, α can be ≧10.0°and ≦30°, such as ≧10.0°and ≦25°, ≧10.0°and ≦20°, ≧10.0°and ≦15°, or ≧10.0°and ≦12.5°.
Accordingly, the hub 504 is configured to impart a force, e.g., a twisting or rotational force, on an abrasive article installed on the hub 504 during use in order to cause the abrasive article to rotate over an angle, A, with respect to the hub 504 and to move linearly toward the lower plate 502. It can be appreciated that multiple abrasive articles can be installed over the hub 504 to create a stack of like, or different, abrasive articles. The twisting of the abrasive articles, and liner motion associated therewith, can cause the abrasive articles to tighten against the lower plate.
In a particular aspect, the angle of rotation, A, can be ≦5°, such as ≦4°, ≦3°, ≦2°, or ≦1°. Further, A can be ≧0.1°, such as ≧0.25°, ≧0.5°, or ≧0.75°. A can also be within a range between and including any of the values of A described herein.
For example, A can be ≦5°and ≧0.1°, such as ≦5°and ≧0.25°, ≦5°and ≧0.5°, or ≦5°and ≧0.75°. A can be ≦4°and ≧0.1°, such as ≦4°and ≧0.25°, ≦4°and ≧0.5°, or ≦4°and ≧0.75°. A can be ≦3°and ≧0.1°, such as ≦3°and ≧0.25°, ≦3°and ≧0.5°, or ≦3°and ≧0.75°. A can be ≦2°and ≧0.1°, such as ≦2°and ≧0.25°, ≦2°and ≧0.5°, or ≦2°and ≧0.75°. A can be ≦1°and ≧0.1°, such as ≦1°and ≧0.25°, ≦1°and ≧0.5°, or ≦1°and ≧0.75°.
In a particular aspect, the button 504 can include an overall height, HBA, and D can be ≧0.25% HBA, such as ≧0.5% HBA, 0.75% HBA, or 1.0% HBA. Further, D can be ≦5.0% HBA, such as ≦4.5% HBA, ≦4.0% HBA, ≦3.5% HBA, ≦3.0% HBA, ≦2.5% HBA, or ≦2.0% HBA. D can also be within a range between and including any of the values of D described herein.
For example, D can be ≧0.25% HBA and ≦5.0% HBA, such as ≧0.25% HBA and ≦4.5% HBA, ≧0.25% HBA and ≦4.0% HBA, ≧0.25% HBA and ≦3.5% HBA, ≧0.25% HBA and ≦3.0% HBA, ≧0.25% HBA and ≦2.5% HBA, or ≧0.25% HBA and ≦2.0% HBA. D can be ≧0.5% HBA and ≦5.0% HBA, such as ≧0.5% HBA and ≦4.5% HBA, ≧0.5% HBA and ≦4.0% HBA, ≧0.5% HBA and ≦3.5% HBA, ≧0.5% HBA and ≦3.0% HBA, ≧0.5% HBA and ≦2.5% HBA, or ≧0.5% HBA and ≦2.0% HBA. D can be ≧0.75% HBA and ≦5.0% HBA, such as ≧0.75% HBA and ≦4.5% HBA, ≧0.75% HBA and ≦4.0% HBA, ≧0.75% HBA and ≦3.5% HBA, ≧0.75% HBA and ≦3.0% HBA, ≧0.75% HBA and ≦2.5% HBA, or ≧0.75% HBA and ≦2.0% HBA. D can be ≧1.0% HBA and ≦5.0% HBA, such as ≧1.0% HBA and ≦4.5% HBA, ≧1.0% HBA and ≦4.0% HBA, ≧1.0% HBA and ≦3.5% HBA, ≧1.0% HBA and ≦3.0% HBA, ≧1.0% HBA and ≦2.5% HBA, or ≧1.0% HBA and ≦2.0% HBA.
Referring now to
In a particular aspect, the hub 610 can include at least three fins, at least four fins, at least five fins, at least six fins, at least seven fins, or at least eight fins. Further, as best illustrated in
For example, βcan be ≧5.0°and ≦30°, such as ≧5.0°and ≦25°, ≧5.0°and ≦20°, ≧5.0°and ≦15°, or ≧5.0°and ≦12.5°. βcan be ≧6.0°and ≦30°, such as ≧6.0°and ≦25°, ≧6.0°and ≦20°, ≧6.0°and ≦15°, or ≧6.0°and ≦12.5°. βcan be ≧7.0°and ≦30°, such as ≧7.0°and ≦25°, ≧7.0°and ≦20°, ≧7.0°and ≦15°, or ≧7.0°and ≦12.5°. βcan be ≧8.0°and ≦30°, such as ≧8.0°and ≦25°, ≧8.0°and ≦20°, ≧8.0°and ≦15°, or ≧8.0°and ≦12.5°. βcan be ≧9.0°and ≦30°, such as ≧9.0°and ≦25°, ≧9.0°and ≦20°, ≧9.0°and ≦15°, or ≧9.0°and ≦12.5°. Moreover, βcan be ≧10.0°and ≦30°, such as ≧10.0°and ≦25°, ≧10.0°and ≦20°, ≧10.0°and ≦15°, or ≧10.0°and ≦12.5°.
When used as part of a button that includes an overall height, HBA, DP, and wherein DP can be ≧0.25% HBA, such as ≧0.5% HBA, 0.75% HBA, or 1.0% HBA. Further, DP can be ≦5.0% HBA, such as ≦4.5% HBA, ≦4.0% HBA, ≦3.5% HBA, ≦3.0% HBA, ≦2.5% HBA, or ≦2.0% HBA. In another aspect, DP can be within a range between and including any of the values associated with DP herein.
For example, DP can be ≧0.25% HBAand ≦5.0% HBA, such as ≧0.25% HBA and ≦4.5% HBA, ≧0.25% HBA and ≦4.0% HBA, ≧0.25% HBA and ≦3.5% HBA, ≧0.25% HBA and ≦3.0% HBA, ≧0.25% HBA and ≦2.5% HBA, or ≧0.25% HBA and ≦2.0% HBA. DP can be ≧0.5% HBA and ≦5.0% HBA, such as ≧0.5% HBA and ≦4.5% HBA, ≧0.5% HBA and ≦4.0% HBA, ≧0.5% HBA and ≦3.5% HBA, ≧0.5% HBA and ≦3.0% HBA, ≧0.5% HBA and ≦2.5% HBA, or ≧0.5% HBA and ≦2.0% HBA. DP can be ≧0.75% HBA and ≦5.0% HBA, such as ≧0.75% HBA and ≦4.5% HBA, ≧0.75% HBA and ≦4.0% HBA, ≧0.75% HBA and ≦3.5% HBA, ≧0.75% HBA and ≦3.0% HBA, ≧0.75% HBA and ≦2.5% HBA, or ≧0.75% HBA and ≦2.0% HBA. DP can be ≧1.0% HBA and ≦5.0% HBA, such as ≧1.0% HBA and ≦4.5% HBA, ≧1.0% HBA and ≦4.0% HBA, ≧1.0% HBA and ≦3.5% HBA, ≧1.0% HBA and ≦3.0% HBA, ≧1.0% HBA and ≦2.5% HBA, or ≧0.25% HBA and ≦2.0% HBA.
In a particular aspect, the undulations 802 are configured to impart pleats in at least one abrasive article installed on a hub extending from the lower plate 800 on a button when the button is engaged with a back-up pad.
With the configuration described herein, the button for attaching an abrasive article to a back-up pad provides a relatively user friendly way to quickly attach an abrasive article to a back-up pad. Further, as easily as the abrasive article is attached, it can be just as easily detached. The button includes an engagement post having a thread lead that allows the engagement post to be engaged with a back-up pad with fewer than 2 revolutions of the button and abrasive tool. An abrasive article (e.g., a non-woven abrasive article) may be compressed between the button and the back-up pad, in order to provide substantial gripping force on the abrasive article during use. The back-up pad can be engaged with a rotating tool holder, such as a drill chuck.
The button may be disengaged from the back-up pad, removed from the abrasive article, installed in a new abrasive article, and re-engaged with the back-up pad for further use. Alternatively, the button can be removed from the abrasive article, the abrasive article can be flipped over, the button can be re-installed in the abrasive article, and the button can be re-engaged with the back-up pad for further use of the abrasive article. As such, a previously un-used side of an abrasive article can be used and full use may be made of the abrasive article—unlike abrasive articles having buttons that are glued or otherwise fixed thereto.
The hub of a button may be formed with a twist and during use the twist may cause the abrasive article installed thereon to move to a lower plate and further increase the gripping force on the abrasive article. Multiple abrasive articles having the same or different abrasive characteristics can be installed on a single hub in any stack order desired by a user. After use, the abrasive articles can be re-stacked in any other order for further use. A lower plate of a button can be formed with undulations and these undulations can impart pleats on the working surface of the abrasive article place on the button.
The button may be formed with fins and the abrasive article may be formed with slits corresponding to the number of fins in a relatively simple and efficient cutting operating that only cuts the abrasive article without removing any of the abrasive article.
Note that not all of the activities described above in the general description or the examples, if provided, are required, that a portion of a specific activity may not be required, and that one or more further activities can be performed in addition to those described. Still further, the order in which activities are listed is not necessarily the order in which they are performed. Certain features that are, for clarity, described herein in the context of separate embodiments, can also be provided in combination in a single embodiment. Conversely, various features that are, for brevity, described in the context of a single embodiment, can also be provided separately or in any subcombination. Further, reference to values stated in ranges includes each and every value within that range.
Benefits, other advantages, and solutions to problems have been described above with regard to specific embodiments. However, the benefits, advantages, solutions to problems, and any feature(s) that can cause any benefit, advantage, or solution to occur or become more pronounced are not to be construed as a critical, required, or essential feature of any or all the claims. The specification and illustrations of the embodiments described herein are intended to provide a general understanding of the structure of the various embodiments. The specification and illustrations are not intended to serve as an exhaustive and comprehensive description of all of the elements and features of apparatus and systems that use the structures or methods described herein. Separate embodiments can also be provided in combination in a single embodiment, and conversely, various features that are, for brevity, described in the context of a single embodiment, can also be provided separately or in any subcombination. Further, reference to values stated in ranges includes each and every value within that range. Many other embodiments can be apparent to skilled artisans only after reading this specification. Other embodiments can be used and derived from the disclosure, such that a structural substitution, logical substitution, or another change can be made without departing from the scope of the disclosure.
Accordingly, the disclosure is to be regarded as illustrative rather than restrictive.
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/US13/62322 | 9/27/2013 | WO | 00 |
| Number | Date | Country | |
|---|---|---|---|
| 61706569 | Sep 2012 | US |
