The present invention relates generally to the field of rotary power tools for cutting, grinding, and polishing. More specifically, the present invention relates to an accessory, such as a tool wheel, for use with a rotary power tool.
A grinder is a type of rotary power tool generally used to remove or cut into material. For example, angle grinders are often used to clean surfaces prior to welding and to polish and remove burs from freshly made welds. Grinders operate by rotating an abrasive tool wheel, such as a wire brush, a cup brush, or an abrasive disk. Some angle grinders operate using a wire brush having braids of carbon steel or stainless steel wire emanating radially from a central hub.
One embodiment of the invention relates to a power tool accessory. The power tool accessory is adapted to be mounted to a spindle of a power tool having a power tool housing. The power tool accessory includes a hub, a working element, a bolt, and a nut. The hub includes a first surface and a second surface that is opposite to the first surface. The hub further includes an opening extending through the hub. An axis of rotation of the hub is defined through the opening. The working element is connected to the hub. The bolt includes a head having a cross-section that is greater than the opening of the hub. The bolt further includes a shaft adapted to extend through the opening of the hub. The shaft is adapted to be received on the spindle of the power tool. The nut cooperates with the bolt and includes a head and an aperture extending through the head. The head of the nut has a cross-section that is greater than the opening of the hub. The aperture of the nut is adapted to be received on the shaft of the bolt. The bolt and the nut are mounted to the hub such that when the power tool accessory is mounted to the power tool for operation, the position of the hub relative to the power tool housing is substantially the same regardless of whether the first surface or the second surface of the hub is adjacent to the power tool housing.
Another embodiment of the invention relates to an accessory for a power tool. The accessory includes a hub having a threaded aperture, a first polygonal surface, and a second polygonal surface. The threaded aperture is in a center of the hub, and a working element is attached to the hub. The threaded aperture is designed to receive a spindle of the power tool. The first polygonal surface projects laterally from a first side of the hub, and the second polygonal surface projects laterally from a second side of the hub. Preferably, each of the polygonal surfaces project approximately the same distance from the hub. The polygonal surfaces and the hub are designed to allow a fastening tool to engage either the first polygonal surface or the second polygonal surface so as to apply a torque for attaching or detaching the hub to or from the spindle. As such, the accessory is designed to allow a user to remove or install the accessory from the power tool from either side of the accessory.
Yet another embodiment of the invention relates to a method of manufacturing an accessory for a power tool, which includes several steps. One step includes providing a wheel having an aperture in a center thereof, and a working element. Another step includes providing a bolt having a threaded aperture therein and a head of the bolt. The threaded aperture is adapted to receive a spindle of the power tool. Yet another step includes providing a nut having a head and forming a sleeve. Another step includes positioning the bolt on a first side of the wheel such that the bolt extends laterally a distance from the first side of the wheel and the threaded port is aligned with the aperture of the wheel. Still another step includes positioning the nut on a second side of the wheel such that the nut extends laterally a distance from the second side of the wheel. The distance that the nut extends from the second side of the wheel is approximately the distance that the bolt extends from the first side of the wheel. Another step includes fastening the bolt to the nut.
Alternative exemplary embodiments relate to other features and combinations of features as may be generally recited in the claims.
The disclosure will become more fully understood from the following detailed description, taken in conjunction with the accompanying figures, wherein like reference numerals refer to like elements, in which:
Before turning to the figures, which illustrate the exemplary embodiments in detail, it should be understood that the present application is not limited to the details or methodology set forth in the description or illustrated in the figures. It should also be understood that the terminology is for the purpose of description only and should not be regarded as limiting.
Typically a rotary power tool, such as an angle grinder, has a drive shaft or spindle extending therefrom on which a power tool accessory, such as an abrasive tool wheel, a buffer wheel, a grinding stone, etc. is mounted. For example, the abrasive tool wheel may attach to the angle grinder drive shaft via a threaded hub provided in the center of the tool wheel. The hub includes a female connector (e.g., port, nut, etc.) fastened to and locking into the center of the tool wheel, typically including a head that extends from one side of the tool wheel. A threaded spindle or mandrel of the angle grinder may be screwed into the female connector. When the braided wire or other working element (e.g., sand paper, etc.) of the tool wheel wears out, or when a different type of tool wheel is needed, the tool wheel on the angle grinder may be replaced by unscrewing the hub of the tool wheel from the spindle.
Angle grinders and other such power tools are typically equipped with a protective guard or shield designed to separate the user from the tool wheel. A standard guard for an angle grinder may include a flange or sleeve extending partially around the working element of the tool wheel, positioned between the user and the working element. During use of the angle grinder, the guard or shield can be used to reduce the chance that debris will contact the user, and the user is less likely to inadvertently contact the operating tool wheel.
As disclosed herein, one may increase the usable life of a tool wheel or other accessory by flipping (i.e., detaching, turning over, and re-attaching) the tool wheel on the angle grinder or other such power tool, from time to time. Flipping the tool wheel reverses the direction of wear on the working element of the tool wheel, which may increase the usable life of the working element. For example, steel braids of a brush wheel may warp or bend as a result of constant use in one direction of rotation. Reversing the direction of rotation of the tool wheel may allow the braids to bend back into a straight configuration, similar to the braids of a new brush wheel. However, reversing the direction of rotation of the tool wheel may not be an option if flipping the tool wheel changes the relative position of the working element in relation to the guard, thereby affecting the interaction between the tool wheel and the guard.
According to an exemplary embodiment, an accessory (e.g., tool wheel) may be designed with a hub that extends an equal distance from either side of the tool wheel. Using this structure, flipping the tool wheel does not significantly affect the position of the tool wheel relative to the guard, spindle, or body of the power tool. As such, the tool wheel may be flipped from time to time, thereby reversing the direction of rotation of the tool wheel and potentially increasing the life of the working element. However, in other embodiments, the hub may extend unequal distances from the sides of the tool wheel.
According to another exemplary embodiment, an accessory may be designed to provide a polygonal fastening surface on each side of a hub. The polygonal fastening surface may be hexagonal, square, rectangular or otherwise shaped, to allow a fastening tool, such as wrench, to engage the fastening surface so that the accessory can be attached or detached to or from a power tool from either side of the accessory. This design may allow for versatility with different power tool configurations, and different types of fastening tools (e.g., socket wrench, open-end wrench, pliers, etc.). However, in other embodiments, the accessory may only include a fastening surface on one side of the hub.
Referring to
The motor may be an electric motor powered by any number of conventional power sources, such as battery, via a conventional power cord, a combustion engine (e.g., two-stroke), or a pneumatic motor. The guard 124 may also be adjustable. The angle grinder 110 may include a power cord, or may not include the side handle 118 in some embodiments. The axis 128 of rotation may have any number of alignments relative to the longitudinal axis 130, including parallel alignment. In other embodiments, the power tool employs any number of a variety of accessories or forms of tool wheel, such as a cup brush, an abrasive disk, a cut-off disk, a grinding stone, a polishing pad, a sanding disk, various wire brush configurations, etc. In other embodiments, other types of grinders and other types of power tools are used, such as tile and glass cutters, disk sanders, circular saws, wall chasers, concrete saws, and other power tools.
Referring to
According to an exemplary embodiment, two opposing support plates 218, 220 (e.g., a first surface, a second surface, etc.) are fastened to opposite sides of the hub 210, one support plate 218 on a first side 222 of the brush wheel 126 and another support plate 220 on a second side 224 of the brush wheel 126. The support plates 218, 220 may orient and secure the steel braids 212 relative to the hub 210 by gripping and guiding ends of the steel braids 212 radially away from the hub 210. Each of the support plates 218, 220 includes an aperture 226, 228 designed to be aligned with the aperture 214 in the center of the hub 210. Ideally, the apertures 226, 228 share the same contour as the aperture 214 of the hub 210. The support plates 218, 220 may be spot welded, projection welded, tig welded, or are otherwise fastened to the hub, such as via threaded fasteners, glue, interlocking parts, pins, and other commercially available fasteners. According to a preferred embodiment, a connector (e.g., nut, bolt, pin, linkage, etc.) may be inserted through the first supporting plate 218, the center hub 210, and the second supporting plate 220. The connector is then swaged on an end that is protruding through the second supporting plate 220, where the swaged connector is the only fastening device used. On some sizes of wheel brushes, the supporting plates are welded as described, then a connector is inserted through the assembly and swaged.
According to another exemplary embodiment, a tool wheel may be designed with a hub formed partially from a bolt and a nut. Referring again to
Referring to
The heads 410, 412 of the bolt 230 and the nut 232 are designed to be compatible with a wrench, a socket wrench, a ratchet, or another such tool. According to an exemplary embodiment, the heads 410, 412 include side surfaces that are parallel to each other. In some embodiments, the heads 410, 412 are hexagonal (i.e., hex), square, rectangular, or otherwise contoured. In still other embodiments, customized tooling may be used to move the heads (e.g., triangularly-slotted wrench).
Still referring to
Referring now to
According to an exemplary embodiment, the bolt 230 functions as a male coupling (e.g., bolt or screw) with regard to the nut 232. As such, the bolt 230 includes a male connector 420 (e.g., male end, shaft, etc.) that extends away from the head 410 and the shoulder 414. The male connector 420 of the bolt 230 may include a threaded outer surface 422 (e.g., exterior surface). Accordingly, with regard to the bolt 230, the nut 232 functions as a cooperating female coupling (e.g., nut). In some embodiments, the nut 232 includes a threaded sleeve 424 or aperture adopted to receive and cooperate with the threaded outer surface 422 of the male connector 420 of the bolt 230.
In some embodiments, neither the outer surface 422 of the male connector 420 of the bolt 230 nor the sleeve 424 in the nut 232 are threaded. For example, in other embodiments, the exterior surface of the bolt includes a series of extensions in the form of ramps or hooks extending annularly around the exterior surface. The ramps or hooks are designed to slide past oppositely oriented ramps or hooks within the port of the nut such that the ramps on the bolt and nut engage each other (e.g., catch, interlock, etc.) and lock the bolt within the nut.
Referring to
Still referring to
Heads 410, 412 of approximately the same thicknesses L1, L2 allow of the tool wheel to be flipped on the spindle, without materially altering the relative position of the working element to the power tool. For example, a tool wheel, such as the wheel brush 126, with the heads 410, 412 of the bolt 230 and nut 232 being approximately the same thickness L1, L2 may be fastened in the same position relative to the guard 124 of the angle grinder 110 (see
According to an exemplary embodiment, a fastening tool may be able to engage (e.g., grip) the bolt 230 and the nut 232, which are projecting from opposite sides of the tool wheel or other accessory. The heads include a polygonal contour (e.g., periphery, shape, exterior, etc.), which is designed to be engaged by the fastening tool. Spacing and thicknesses L1, L2 of the heads 410, 412 allows for the fastening tool to be inserted between the accessory and the powered tool, to reach the heads 410, 412. Some exemplary fastening tools include commercially-available gripping pliers, and preferably wrenches, such as open-end wrenches (i.e., spanners), box-end wrenches, tube wrenches, adjustable wrenches, socket wrenches, crowfoot wrenches, Allen, Bristol, or Torx wrenches, alligator wrenches, tap wrenches, etc.
Referring to
A significant advantage of at least one embodiment is that a fastening tool may be able to engage (e.g., grip) the bolt 724 and the nut 726, which are projecting from opposite sides of the hub 714. This provides an important and unique advantage. An accessory tool having gripping surfaces (e.g., fastening surfaces) provided on both sides of the hub makes the accessory tool far more versatile, adapted for use on a larger selection of power tools used in a wider variety of applications. According to an exemplary embodiment, the bolt 724 and the nut 726 each include a polygonal head (e.g., periphery, shape, exterior, etc.), which is designed to be engaged by the fastening tool. Spacing and thicknesses of the heads allow for the fastening tool to be inserted between the cup brush 710 and the powered tool, to reach the heads. Also a conventional wrench, such as a socket wrench, may be extended into the cup, to engage one of the heads for fastening or unfastening the cup brush 710 and spindle. Some exemplary fastening tools include commercially-available gripping pliers, and preferably wrenches, such as open-end wrenches (i.e., spanners), box-end wrenches, tube wrenches, adjustable wrenches, socket wrenches, crowfoot wrenches, Allen, Bristol, or Torx wrenches, alligator wrenches, tap wrenches, etc.
Referring to
According to an exemplary embodiment, a tool wheel for a power tool, includes a hub, a bolt, and a nut. The hub has an aperture in a center thereof and a working element coupled thereto. The bolt has a shaft and a threaded aperture therein. The threaded aperture is adapted to receive a spindle of the power tool. The nut is forming a sleeve. The shaft of the bolt is extending through the aperture of the hub and is received within the sleeve of the nut. The bolt is projecting laterally from a first side of the hub, the nut is projecting laterally from a second side of the hub. The bolt and the nut are each projecting approximately the same distance away from the hub. In addition to the above-described features in this paragraph, in another embodiment the bolt and the nut are permanently fastened together through the aperture of the hub. In addition to the above-described features in this paragraph, in yet another embodiment an end of the bolt has been swedged to form a flange contacting a surface of the nut, such that the bolt and the nut are fastened together. In addition to the above-described features in this paragraph, in still another embodiment the aperture of the hub has a non-circular periphery, and the bolt further includes a shoulder sized and contoured to fit within the aperture of the hub to limit rotation of the nut relative to the hub. In addition to the above-described features in this paragraph, in another embodiment the non-circular periphery is hexagonal. In addition to the above-described features in this paragraph, in yet another embodiment the bolt includes a threaded outer surface and the sleeve includes a threaded inner surface, and the bolt is screwed into the sleeve. In addition to the above-described features in this paragraph, in yet another embodiment the tool wheel is at least one of a brush wheel, an abrasive disk, or an cup brush, and the power tool is a grinder. In addition to the above-described features for the first embodiment described in this paragraph, in another embodiment the aperture of the hub has a non-circular periphery, and the nut further includes a shoulder sized and contoured to fit within the aperture of the hub to limit rotation of the nut relative to the hub.
The construction and arrangements of the power tool, tool wheel, and hub, as shown in the various exemplary embodiments, are illustrative only. Although only a few embodiments have been described in detail in this disclosure, many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters, mounting arrangements, use of materials, colors, configurations, etc.) without materially departing from the novel teachings and advantages of the subject matter described herein. Some elements shown as integrally formed may be constructed of multiple parts or elements, the position of elements may be reversed or otherwise varied, and the nature or number of discrete elements or positions may be altered or varied. The order or sequence of any process, logical algorithm, or method steps may be varied or re-sequenced according to alternative embodiments. Other substitutions, modifications, changes and omissions may also be made in the design, operating conditions and arrangement of the various exemplary embodiments without departing from the scope of the present invention.