The present disclosure generally relates to cutting apparatuses and, more particularly relates to cutting apparatuses configured to cut tow fibers, or bundles thereof, and other materials.
Cutting apparatuses are used in the manufacture of many products, such as consumer products. Different materials used in consumer products require various cutting equipment and cutting methods. The cutting equipment and methods are, at times, tailored to specific cutting operations for various materials.
Various cleaning articles, or portions thereof, are one type of consumer product that may require one or more cutting operations during their manufacture. These cleaning articles may be used for dusting and light cleaning, for example, or for other purposes. Cleaning articles, such as disposable dusters, have been developed which have limited re-usability. These disposable dusters may comprise brush portions made of synthetic fiber bundles, called tow fibers, attached to one or more layers of material, such as one or more layers of a nonwoven material. In other instances, the tow fibers may be attached to a rigid material or plate. The disposable cleaning article may be used for one job (e.g., several square meters of surface) and discarded, or may be restored and re-used for more jobs and then discarded.
It is desired in a disposable cleaning article to have tow fibers that are fluffy and somewhat separated from each other on their distal fiber ends or free fiber ends. Current cutting technologies, however, tend to “weld” or join together free fibers ends of the tow fibers leading to an aesthetically unpleasing look and feel and also may somewhat limit cleaning ability. Furthermore, such welding of the free fibers ends of the tow fibers may somewhat reduce the effectiveness of the tow fibers in picking up dust and dirt. What is needed are cutting devices for consumer products, such as disposable dusters, and other products, that produce a cleaner and sharper cut and reduce welding of fibers at their free fiber ends. Also needed are methods of cutting materials, such as tow fibers, that reduce welding of the fibers at their free fiber ends.
In one form, the present disclosure is directed, in part, to a cutting apparatus that may comprise a drive shaft having a longitudinal axis, a drum configured to orbit the longitudinal axis when driven by the drive shaft, a first actuator, and a cutting assembly joined to the drum and configured to orbit about the longitudinal axis with the drum. The cutting assembly may comprise a second actuator operably engaged with a portion of the cutting assembly, and a cutting device driven by the second actuator. The second actuator may be configured to rotate the cutting device at least 1,500 revolutions per minute (or other speeds disclosed herein) during cutting of an article. The first actuator may be operably engaged with a portion of the cutting assembly and may be configured to reciprocate the cutting device in directions substantially parallel to the longitudinal axis as the cutting assembly orbits the longitudinal axis.
In another form, the present disclosure is directed, in part, to a cutting apparatus that may comprise a drive shaft having a longitudinal axis, a drum configured to orbit the longitudinal axis when driven by the drive shaft, and a barrel cam positioned at least partially intermediate the drive shaft and a portion of the drum. The barrel cam may comprise a track that forms a path that surrounds the longitudinal axis. The drum and the drive shaft may rotate relative to the barrel cam. The barrel cam may be fixed and not rotatable. The cutting apparatus may further comprise a cutting assembly joined to the drum and configured to orbit about the longitudinal axis with the drum. The cutting assembly may comprise a rack comprising a first end and a second end. The rack may extend in a direction parallel to, substantially parallel to, or transverse to the longitudinal axis between the first end and the second end. The cutting assembly may further comprise a compounding gear assembly that may comprise a plurality of gears comprising a first gear operably engaged with the rack. The first gear may be configured to travel at least partially intermediate the first end and the second end of the rack. The compounding gear assembly may further comprise a cutting device driven by the plurality of gears. The cutting device may rotate at least 8-15 times per each rotation of the first gear. The cutting assembly may further comprise a cam follower at least partially engaged with the track and configured to orbit about the longitudinal axis within the path of the track. The cam follower may be configured to move the first gear at least partially intermediate the first end and the second end of the rack when the cutting assembly is orbiting about the longitudinal axis to cause the cutting device to translate substantially parallel to the longitudinal axis.
The above-mentioned and other features and advantages of the present disclosure, and the manner of attaining them, will become more apparent and the disclosure itself will be better understood by reference to the following description of non-limiting embodiments of the disclosure taken in conjunction with the accompanying drawings, wherein:
Various non-limiting embodiments of the present disclosure will now be described to provide an overall understanding of the principles of the structure, function, manufacture, and use of the cutting apparatuses and methods for cutting tow fibers, bundles thereof, and/or other materials or bundles thereof disclosed herein. One or more examples of these non-limiting embodiments are illustrated in the accompanying drawings. Those of ordinary skill in the art will understand that the cutting apparatuses and methods for cutting tow fibers, bundles thereof, and/or other materials or bundles thereof described herein and illustrated in the accompanying drawings are non-limiting example embodiments and that the scope of the various non-limiting embodiments of the present disclosure are defined solely by the claims. The features illustrated or described in connection with one non-limiting embodiment may be combined with the features of other non-limiting embodiments. Such modifications and variations are intended to be included within the scope of the present disclosure.
The terms “joined,” “attached,” “mounted,” “engaged,” or “engaged with” encompass configurations wherein an element is directly secured to another element by affixing the element directly to the other element, and configurations wherein an element is indirectly secured to another element by affixing the element to intermediate member(s) which in turn are affixed to the other element.
The term “nonwoven” or “nonwoven material” refers herein to a material made from continuous (long) filaments (fibers) and/or discontinuous (short) filaments (fibers) by processes such as spunbonding, meltblowing, carding, and the like. Nonwovens do not have a woven or knitted filament pattern.
The term “machine direction” (MD) is used herein to refer to the primary direction of material, strip of substrate, or article flow through a process.
The term “cross direction” (CD) is used herein to refer to a direction that is generally perpendicular to the machine direction.
The present disclosure is directed to cutting and/or shearing apparatuses and methods of cutting and/or shearing. The terms cutting and shearing are used interchangeably herein, unless otherwise indicated. The cutting apparatuses may be used to cut any suitable material or materials, such as nonwoven materials, woven materials, natural fibers, synthetic fibers, cotton fibers, pulp fibers, tow fibers, other fibers, fibrous materials, laminates, and/or other materials, for example. The methods of cutting may also be used in cutting any suitable materials, such as nonwoven materials, woven materials, tow fibers, bundles of various types of fibers, and/or other materials, for example. The apparatuses and methods of the present disclosure may be used to cut one or more materials at a time or a single material at a time. If more than one material is cut at a time, the more than one materials may be the same or different.
The tow fibers referred to herein may be synthetic fibers or any other tow fibers as known to those of skill in the art. “Tow” generally refers to fibers comprising synthetic polymers including polyester, polypropylene, polyethylene, and cellulose materials including cellulose acetate and mixtures thereof manufactured such that the individual fibers are relatively long strands manufactured in bundles. The bundle fibers may be defined as any fibers having distinct end points and at least about 1 cm in length.
Frequently, in high speed consumer product manufacturing, a strip of a substrate is conveyed through a line in a machine direction or generally in a machine direction. Components may be added to the strip of the substrate or taken away from the strip of the substrate as the strip of the substrate moves in the machine direction. In some instances, the strip of substrate may be processed as they move in the machine direction, other than through the addition or removal of components. The strip of substrate may comprise one material or two or more materials that are joined together (i.e., a laminate). The strip of substrate may comprise any of the materials discussed herein in relation to the materials being cut or may comprise other materials, adhesives, lotions, oils, etc.
It is often necessary to cut the strip of the substrate into individual consumer products, or portions thereof, such as disposable dusters. This can be accomplished using a cutting apparatus comprising one or more cutting assemblies, such as the cutting apparatus comprising one or more cutting assemblies of the present disclosure. The cutting may occur in the cross-direction, or substantially in the cross direction (e.g., +/−30 degrees from the cross-direction), or may occur in other directions. After cutting, the consumer products, or portions thereof, may be moved in the machine direction, or other direction, on a conveyor or other device for further processing or packaging.
The cutting assemblies of the present disclosure are illustrated, as an example, as being part of a larger cutting apparatus. It will be understood, however, that the cutting assemblies of the present disclosure may be used in other cutting operations independent of the illustrated cutting apparatus and either with other cutting apparatuses or independently of another cutting apparatuses.
Some related art cutting assemblies for consumer products, or other fibrous products, have a tendency to weld or join free fiber ends of the fibers being cut together during cutting, especially tow fibers or bundles thereof, for example. The welding may occur due to slow cutting blade rotational speeds and/or due to the high pressures required to force a portion of a cutting blade through the material being cut and against a smooth anvil. In other instances, the welding may occur because the fibers are cut using crush cut methods, such as die cutting, for example. In these instances, as the fibers are crushed, they may be welded together. The cutting apparatuses and cutting assemblies of the present disclosure, however, provide less welding of free fiber ends, such as free fibers end of tow fibers, due to the unique configuration of the cutting apparatuses and cutting assemblies and the particular methods used for the cutting operation of the present disclosure. Furthermore, the cutting devices or blades of the present disclosure achieve speeds much higher than conventional cutting devices allowing for a much cleaner and more distinct cut that reduces free fiber end welding.
In an embodiment, referring to
The transfer heads 26 may each comprise a transfer surface defining one or more fluid ports 27 therein. The transfer surfaces are portions of the transfer heads 26 that contact and convey the strip of substrates and the articles (post-cutting). The fluid ports 27 may be arranged in any suitable pattern. The fluid ports 27 allow a fluid pressure (positive or negative) generated by the fluid movement system 24 to be applied to portions of a strip of substrate or to one or more articles or consumer products, or portions thereof, positioned on the transfer surfaces. Prior to cutting, portions of the strip of substrate extends between the transfer heads 26 so that cutting may occur intermediate the transfer heads 26. Referring to
As discussed above, the fluid movement system 24 may be used to provide fluid flow to portions of, or all of, one or more of the fluid ports 27 in the transfer heads 26. The fluid movement system 24 may provide a positive fluid pressure and/or a negative fluid pressure to portions of, or all of, the one or more transfer heads 26 using fluid movement devices, such as fluid pumps (not illustrated). Fluid pumps are generally known to those of skill in the art and will not be discussed herein for brevity. In an embodiment, the fluid movement system 24 may provide a positive fluid pressure to some of the transfer heads 26, or portions thereof, for “blow off” of the cut articles positioned thereon and may provide a negative fluid pressure to some other transfer heads 26, or portions thereof, to maintain the articles or the strip of the substrate on the transfer heads 26. In some embodiments, the fluid movement system 24 may provide a positive fluid pressure to certain fluid ports 27 in a particular transfer head 26 and may provide a negative fluid pressure to other certain fluid ports 27 in the same transfer head 26 at a discharge point of the rotation of the cutting apparatus 10. As an example, a trailing portion (trailing with respect to the rotation of the transfer head) of a transfer head 26 may receive a negative fluid pressure from the fluid movement system 24, while a leading portion (leading with respect to the rotation of the transfer head) of the same transfer head 26 may receive a positive fluid pressure from the fluid movement system 24. This may be useful when the cut article on the transfer head 26 is being transferred off of the cutting assembly 10 or discharged because control of the trailing portion of article may be maintained while the leading portion of the article is blown off of the transfer head 26. After the leading portion of the article is blown off, fluid ports in the trailing portion of the transfer head 26 may then receive a positive fluid pressure from the fluid movement system 24 to aid in full article transfer. Such fluid movement system features in combination with transfer heads may provide for higher speed and more reliable article transfer. Example fluid movement systems in combination with transfer heads are disclosed in U.S. patent application Ser. No. 13/447,568, entitled FLUID SYSTEMS AND METHODS FOR TRANSFERRING DISCRETE ARTICLES.
In an embodiment, referring to
In another embodiment, the barrel cam 32 and the cam follower 48 may not be provided and instead an actuator, such as a linear actuator, may be used to reciprocate the carriage generally across (generally in the direction of the longitudinal axis 16) the drum 22 such that the cutting device 50 may cut the strip of the substrate as the strip of substrate is rotated by the drum 22. The actuator may be a piston-type assembly comprising a housing and a piston that is operably engaged with a portion of the carriage such that the piston may reciprocate the carriage in directions generally along the longitudinal axis 16 when expanded and retracted relative to the housing using pneumatics or hydraulics, for example.
In an embodiment, referring to
In an embodiment, the cutting assemblies 28 may each comprise a support member 42 that is configured to be engaged with portions of the drum 22 and/or to the rotating plates 20 to attach the cutting assemblies 28 to the drum 22 and cause them to rotate with the drum 22. The cutting assemblies 28 are configured to move in directions parallel to, substantially parallel to, or transverse to the longitudinal axis 16 as the drum 22 orbits about the longitudinal axis 16. In various embodiments, each of the cutting assemblies 28 may be the same or different on the cutting apparatus 10. Referring generally to
In an embodiment, each of the cam followers 48 of the cutting assembly 28 is configured to be at least partially engaged with the track 34 in the barrel cam 32. The cam followers 48 may be mounted at any suitable location on the carriage. The cam followers 48 may each comprise one or more rollers or low coefficient of friction materials of suitable shapes to engage the track 34, for example. In one embodiment, the cam followers 48 may comprise a roller or other member that is coated with a low coefficient of friction material. Owing to the engagement of the cam followers 48 and the track 34, the portion of the cutting assembly comprising a cutting device 50 (e.g., the carriage) may reciprocate at least partially about the support member 42 to cut the strip of substrate or other material.
The cutting assembly 28 may comprise a rack 52, such as a linear gear or a generally linear gear with a somewhat arcuate portion that can be formed with or attached to the support member 42. The rack 52 may be linear or non-linear (e.g., comprises an arcuate portion) depending on the desired cutting path of the cutting member 50 and possibly depending on whether the one or more guides 44 and the support member 42 are linear or non-linear. The rack 52 may comprise a plurality of teeth configured to meshingly engage the teeth of another gear. The rack 52 may be mounted intermediate two of the guides 44 or at another location on the support member 42. The rack 52 may comprise a first end 54 and a second end 56. The rack 52, the support member 42, and/or the guides 44 may be positioned parallel to the longitudinal axis 16, substantially perpendicular to the longitudinal axis 16 (e.g., +/−30 degrees, 20 degrees, 10 degrees, 5 degrees, 3 degrees, 2 degrees, or 1 degree from the longitudinal axis 16), or transverse to the longitudinal axis 16.
In an embodiment, the rack 52 may operably engaged with a portion of a rotary speed changing assembly, such as a single gear, or a compounding gear assembly 57, for example. The compounding gear assembly 57 may comprise a plurality of gears comprising a first gear 58 operably engaged with the rack 52, wherein the first gear is configured to travel at least partially intermediate the first end 54 and the second end 56 of the rack 52. Referring to
In an embodiment, the at least one first gear 58, when meshingly engaged with the rack 52 and reciprocated at least partially intermediate the first and second ends 54, 56 of the rack 52, causes the second gear 60 to rotate and the cutting device 50 to directly or indirectly rotate. The first gear 58 and the second gear 60 are both non-rotatably fixed to a first drive shaft 68. As the first gear 58 is reciprocated along at least a portion of the rack 52, thereby rotating the first gear 58, the first drive shaft 68 is rotated, thereby causing the second gear 60 to rotate. The second gear 60 is meshingly engaged with the third gear 62 and causes the third gear 62 to rotate when the second gear 60 is rotated. The third gear 62 and the fourth gear 64 are non-rotatably fixed to a second drive shaft 70. As the third gear 62 is rotated by the second gear 60, the fourth gear 64 is rotated owing to its fixed relationship to the second drive shaft 70. The fourth gear 64 is meshingly engaged with the fifth gear 66. As a result, when the fourth gear 64 is rotated, the fifth gear 66 rotates. The fifth gear 66 is non-rotatably fixed to a third drive shaft 72. The third drive shaft 72 is also non-rotatably fixed to the cutting device 50 (either directly or indirectly). As a result, when the fifth gear 66 is rotated by the fourth gear 64, the cutting device 50 is rotated or driven in the direction indicated by the arrows in
The rotational speed of the cutting device 50 may be at least 5 times faster, at least 10 times faster, at least 15 times faster, at least 20 times faster, about 5 to about 40 times faster, about 8 to about 25 times faster, about 8 to about 20 times faster, or about 8 to about 15 times faster, specifically reciting all 0.1 increments within the above-referenced ranges and all ranges formed therein or thereby, than the rotational speed of the first gear 58 owing to the compounding gear assembly 57. The rotational speed of the cutting device 50 may be at least 800 revolutions per minute, at least 1,000 revolutions per minute, at least 1,250 revolutions per minute, at least 1,500 revolutions per minute, at least 1,750 revolutions per minute, at least 2,000 revolutions per minute, or in the range of about 750 revolutions per minute to about 3,500 revolutions per minute, about 1,000 revolutions per minute to about 3,000 revolutions per minute, about 1,500 revolutions per minute to about 3,000 revolutions per minute, about 2,000 revolutions per minute to about 3,000 revolutions per minute, owing to the compounding gear assembly 57, specifically reciting all 1 revolution per minute increments within the specified ranges and all ranges formed therein or thereby. The rotational speed of the cutting device 50 may be proportional to the path of the track 34 in the barrel cam 32 owing to the cam follower's 48 engagement with the track 34. Alternatively, the rotational speed of the cutting device 50 may be proportional to how quickly the actuator or the linear actuator moves the carriage relative to the support member 42 or the rack 52. The rotational speed of the cutting device 50 may be varied by changing the path of the track 34 in the barrel cam 32 or by changing the compounding gear assembly 57 (e.g., using smaller or larger gears in one or more of the gears). Alternatively, the rotational speed of the cutting device 50 may be varied by changing the speed of the actuator or the linear actuator moving the carriage.
In an embodiment, the rotational speed of the cutting device 50 may vary along the length of the rack 52 or along the length of the rack 52 where the carriage is being reciprocated (i.e., vary along the path of the carriage). The rotational speed of the cutting device 50 may increase until the cutting device 50 is at a position relative to the support member 42 where it will engage an article to be cut, then the rotational speed may remain constant or substantially constant (e.g., +/−20 revolutions per minute) during cutting, and then the rotational speed may decrease post-cutting. In other embodiments, the rotational speed of the cutting device 50 may be constant or variable during cutting and/or pre and/or post cutting. In still another embodiment, the rotational speed may be constant or substantially constant throughout a full stroke of the cutting device 50.
Instead of using the first gear 58 and the rack 52 to drive the compounding gear assembly 57 and thereby the cutting device 50, an actuator, such as a motor 55, for example, may be used instead. The motor 55 may be operably engaged with a drive shaft. The drive shaft may be engaged with the cutting device 50 directly such that the rotation of the drive shaft rotates the cutting device 50 (1:1 rotational speed ratio between the drive shaft of the motor 55 and the cutting device 50). In other embodiments, the actuator may be operably engaged with a drive shaft (such as drive shaft 68) of the compounding gear assembly 57 or other speed increasing or changing assembly such that one rotation of the drive shaft (e.g., 68) causes the cutting device 50 to rotate at least 5 times, at least 10 times, or even at least 15 times, for example. In such an embodiment, the first gear 58 may not be provided and the actuator may be directly or indirectly operably engaged with the drive shaft 68 or other drive shaft to drive the compounding gear assembly 57 and thereby the cutting device 50. In still other embodiments, the first gear 58 may be driven directly or indirectly by the actuator.
The cutting device 50 may comprise a blade, such as a hardened steel blade. The blade may also comprise other material suitable for cutting as will be recognized by those of skill in the art. The blade may be circular or non-circular and may or may not be faceted. The blade may have a Rockwell C scale hardness of about 40 to about 70 or about 50 to about 60, specifically reciting all whole integers within the specified ranges and all ranges formed therein or thereby. Referring to
In an embodiment, again referring to
In an embodiment, referring to
A sled 96 may extend from or be attached to the second plate 90 or the first plate 88. The sled 96 may comprise a first bar 98, a second bar 100, and a third bar 102 disposed at least partially intermediate the first and second bars 98 and 100. The first and second bars 98 and 100 may be a unitary structure or two or more structures joined together. The third bar 102 may be biased towards the second bar 100 using a spring 84 or other biasing device. Alternatively, the cutting device 50 may be biased toward the third bar 102. The third bar 102 may comprise the cutting device-contacting member 82 or the cutting device contacting member 82 may be attached to the third bar 102 using any suitable attachment techniques. A cutting device-contacting member may also be positioned on the first bar 98 or on the second bar 100 depending on a desired configuration and what edge portions of the cutting device 50 should be contacted by a portion of a cutting device-contacting member.
In an embodiment, the sled 96 may also comprise one or more retaining members 106 configured to hold the strip of substrate to the transfer surfaces of the transfer heads 26 during cutting or shearing. Stated another way, the retaining members 106 may be aligned with the nip 86 or cutting point to essentially hold the strip of substrate while the cut takes place. Any suitable number of retaining members 106 may be provided. If two retaining members 106 are provided, a first retaining member 106 may engage and move or roll over a first transfer surface of a first transfer head 26 and a second retaining member 106 may engage and move or roll over a second transfer surface of a second transfer head 26, while the cutting device 50 cuts the strip of substrate intermediate the first and second transfer heads 26. The retaining members 106 may comprise rollers comprising a plastic, a rubber, or other material. The retaining members 106 may instead comprise low coefficient of friction materials that can easy slide over portions of the strip of substrates. The retaining members 106 may be rotatably mounted or otherwise mounted to a support 108 positioned on a top portion of the sled 96 and biased toward a surface 104 of the sled 96. The support 108 may be pivotably attached to a projection 110 on the sled 96. The projection 110 may have a pin 112 extending from a first side of the projection 110 to a second side of the projection 110 or an aperture in the first side of the projection 110 to an aperture in the second side of the projection 110. The support 108 may pivot about the pin 112 in the directions indicated by arrows “A” in
In one form, a method of cutting or shearing one or more tow fibers or layers thereof or other materials mentioned herein may comprise rotating a drum comprising a cutting assembly comprising a cutting device about a longitudinal axis of a drive shaft, reciprocally moving a portion of the cutting assembly comprising the cutting device in a direction parallel to or transverse to the longitudinal axis as the cutting assembly is rotated about the longitudinal axis, rotating the cutting device at least 1,000 times per minute, at least 1,500 times per minute, or at least 2,000 times per minute (or other speeds as disclosed herein), and cutting or shearing the tow fibers and/or other materials with the cutting device. The method may further comprise biasing a cutting device-contacting member against an edge portion of the cutting device during the cutting or shearing step. The method may further comprise using a nip created between a portion of the cutting device-contacting member and a portion of the edge portion of the cutting device to shear or cut the tow fibers and/or the other material. The method may further comprise sharpening the edge portion of the cutting device using the cutting device-contacting member during the rotating the cutting device step. The method may further comprise rotating the cutting device at a substantially constant rotational speed during the cutting or shearing step. The drum may comprise a transfer head and the cutting assembly may comprise a retaining member. The method may further comprise retaining the tow fibers and/or other materials to the transfer head during the cutting or shearing step using the retaining member. The method may further comprise rotating the cutting device at a first rotational speed while not cutting or shearing the tow fibers and/or other materials and rotating the cutting device at a second, different rotational speed while cutting or shearing the tow fibers or other materials. The second, different rotational speed may be greater than the first rotational speed or less than the first rotational speed.
In another form, a method of shearing or cutting a material, such as one or more nonwoven materials and/or one or more tow fibers or layers of tow fibers is provided. The method may comprise rotating a drum comprising a cutting assembly comprising a cutting device about a longitudinal axis of a drive shaft, reciprocally moving a portion of the cutting assembly comprising the cutting device in a direction parallel to, generally parallel to, or transverse to the longitudinal axis as the cutting assembly is rotated about the longitudinal axis, rotating the cutting device at least 1,000 revolutions per minute, at least 1,500 revolutions per minute, or at least 2,000 revolutions per minute (or other speeds disclosed herein), biasing a cutting device-contacting member against an edge portion of the cutting device, cutting or shearing the material in a nip created between a portion of the cutting device-contacting member and a portion of the edge portion of the cutting device. The cutting nor shearing the material step may comprise cutting or shearing one or more nonwoven materials and one or more tow fibers or layers of tow fibers. The edge portion of the cutting device may comprise a substantially flat portion and an opposing edge portion of the cutting device may comprise a beveled portion. The method may comprise sharpening the cutting device using the cutting-device contacting member. The method may comprise rotating the cutting device at a constant, substantially constant, or variable rotational speed during the cutting or shearing step. The drum may comprise a transfer head. The cutting assembly may comprise a retaining member. The method may comprise retaining the material to the transfer head during the cutting or shearing step using the retaining member. The method may comprise rotating the cutting device at a first rotational speed while not shearing or cutting the material and rotating the cutting device at a second, different rotational speed while shearing or cutting the material.
In another form, a method of cutting or shearing materials, such as one or more nonwovens and one or more tow fibers or layers of tow fibers, may comprise rotating a cutting device at least 1,000 times per minute, at least 1,500 times per minute, or at least 2,000 times per minute (or other speeds disclosed herein), biasing a cutting device-contacting member against an edge portion of the cutting device, and shearing or cutting the materials in a nip formed at least partially intermediate the cutting device and the cutting device-contacting member. The method may further comprise sharpening the edge portion of the cutting device using the cutting device-contacting member during the rotating step, and rotating the cutting device at a constant, substantially constant, or variable rotational speed during the shearing or cutting step.
In another form, a method of cutting or shearing materials, such as one or more nonwoven materials and one or more tow fibers or layers of tow fibers, may comprise rotating a cutting device at least 1,000 times per minute, at least 1,500 times per minute, or at least 2,000 times per minute (or other speeds disclosed herein) and cutting or shearing the materials.
In another form, a method of cutting or shearing a strip of dusters may comprise rotating a cutting device at least 1,000 times per minute, at least 1,500 times per minute, or at least 2,000 times per minute (or other speeds disclosed herein) and cutting or shearing the material.
The dimensions and values disclosed herein are not to be understood as being strictly limited to the exact numerical values recited. Instead, unless otherwise specified, each such dimension is intended to mean both the recited value and a functionally equivalent range surrounding that value. For example, a dimension disclosed as “40 mm” is intended to mean “about 40 mm.”
Every document cited herein, including any cross referenced or related patent or application, is hereby incorporated herein by reference in its entirety unless expressly excluded or otherwise limited. The citation of any document is not an admission that it is prior art with respect to any invention disclosed or claimed herein or that it alone, or in any combination with any other reference or references, teaches, suggests or discloses any such invention. Further, to the extent that any meaning or definition of a term in this document conflicts with any meaning or definition of the same term in a document incorporated by reference, the meaning or definition assigned to that term in this document shall govern.
While particular embodiments of the present disclosure have been illustrated and described, those of skill in the art will recognize that various other changes and modifications can be made without departing from the spirit and scope of the invention. It is therefore intended to cover in the appended claims all such changes and modifications that are within the scope of this invention.
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