This application relates to a holesaw and pilot bit assembly for use with rotary power tools.
Two types of power tool accessories for cutting larger diameter holes in a workpiece are holesaws and self-feed drill bits. A holesaw generally includes a cup shaped cutting member formed from a flat blade with teeth that is rolled and welded into a cylindrical shape, and then welded to a round base. The holesaw may be mounted to an arbor to couple the holesaw to a rotary power tool such as a drill. A center pilot drill bit may also be received in the holesaw and/or the arbor to help drill a pilot hole to center the holesaw in a workpiece. In use, arbor, holesaw, and pilot bit are assembled and coupled to a rotary power tool such as a drill. The drill is then actuated so that the pilot drill bit enters the workpiece, followed by the holesaw. The holesaw forms a large diameter hole in the workpiece by removing a solid cylindrical plug from the workpiece. An example of a holesaw is the Milwaukee® 49-56-9130 2 9/16″ Big Hawg® Hole Cutter with Spade Pilot Bit, sold by Milwaukee Electric Tool Corp. of Brookfield, Wis.
A self-feed drill bit generally includes a shank for coupling to a rotary power tool and an integral cutting head coupled to the shank. The cutting head has a semicircular base, a semi-cylindrical wall coupled to the base having a plurality of teeth, and one or more radial cutters or blades extending from a center of the cutting head to the semi-cylindrical wall. The cutting head may be provided with a pilot bit, which may include a self-feeding threaded tip. In use, the shank is coupled to a rotary power tool such as a drill. The drill is then actuated so that the pilot bit enters the workpiece, followed by the cutting head. The cutting head forms a large diameter in the hole in the workpiece by removing tiny chips from the workpiece. An example of a self-feed drill bit is a DeWALT DW1639 2 9/16″ Self-Feed Bit sold by DeWALT Industrial Tool Co. of Towson, Md.
Holesaws are often preferred over self-feed bits for several reasons. First, holesaws are much less messy because they form a solid-plug of waste material, while self-feed bits throw small chips over a wide area around a hole. This can be important when working in an area where debris is not desired. Second, holesaws are much less expensive than self-feed bits. This is because a self-feed bit is made by solid investment casting, while a holesaw is made by bending and welding sheet metal. For example, the Milwaukee® 49-56-9130 2 9/16″ Big Hawg® Hole Cutter with Spade Pilot Bit currently retails for almost double the price of the DeWALT DW1639 2 9/16″ Self-Feed Bit. Third, self-feed bits are generally have a maximum diameter of about 4 inches, while holesaws may have a maximum diameter of 6 inches or more. Finally, self-feed bits generally require a large, high powered corded drill, while holesaws can be used with smaller, lower powered cordless drills.
Some drawbacks of holesaws include that a holesaw may be more difficult to use because it requires the user to put a large amount of axial bias on the tool to drive the holesaw through the workpiece. In addition, when used with a cordless power tool such as a cordless drill existing holesaws also have poor runtime performance (i.e., the number of holes that can be drilled on a single battery charge). Further, it can be difficult to remove a plug of waste material from the holesaw. There is a need for a holesaw that overcomes these deficiencies.
In an aspect, a holesaw assembly includes a holesaw and a pilot bit. The holesaw includes a hollow cup defining a center axis. The cup has a round base perpendicular to the center axis and a peripheral wall coupled to and extending axially forward of the base to a peripheral edge at a free end of the wall. The pilot bit is received in the holesaw along the center axis. The pilot bit has a shaft received in the base, a cutting head coupled to a front end of the shaft, and an at least partially threaded tip coupled to a front end of the cutting head. The holesaw is free of any radial cutting elements disposed inside the cup between the drill bit and the peripheral wall of the cup.
In another aspect, a holesaw assembly includes a holesaw and a pilot bit. The holesaw includes a hollow cup defining a center axis. The cup has a round base perpendicular to the center axis and a peripheral wall coupled to and extending axially forward of the base to a peripheral edge at a free end of the wall. The pilot bit is received in the holesaw along the center axis. The pilot bit has a shaft received in the base, a cutting head coupled to a front end of the shaft, and an at least partially threaded tip coupled to a front end of the cutting head. The holesaw is configured to form and remove a generally cylindrical plug of material from a workpiece.
In another aspect, a method of using a holesaw assembly includes providing a holesaw assembly that includes holesaw and a pilot bit. The holesaw has a hollow cup defining a center axis. The cup has a round base perpendicular to the center axis and a peripheral wall coupled to and extending axially forward of the base to a peripheral edge at a free end of the wall. The pilot bit is received in the holesaw along the center axis. The pilot bit has a shaft received in the base, a cutting head coupled to a front end of the shaft, and an at least partially threaded tip coupled to a front end of the cutting head. The holesaw assembly is coupled to a rotary power tool so that the power tool is configured to drive the holesaw and the pilot bit together in a rotational cutting direction. The rotary power tool is actuated to drive the pilot bit and the holesaw into a workpiece to remove a solid, generally cylindrical plug of material from the workpiece.
Implementations of these aspects may include one or more of the following features. The base may define a central opening configured to receive the shaft of the drill bit. The peripheral edge of the holesaw may include one or more cutting inserts. The cutting inserts may be composed of a hard metal such as tungsten carbide. The cutting inserts may be brazed or welded to the peripheral edge. Each cutting insert may include a cutting edge and a rake face, the rake face disposed at a hook angle relative to a line parallel to the center axis. The hook angle may be between approximately negative 10° and approximately positive 10°. The peripheral wall may define one or more slots configured to facilitate removal of a plug of material from the holesaw.
The pilot bit may comprise a spade bit. The cutting head of the spade bit may comprise a plate-like body with first and second cutting edges extending radially outward from center axis. The plate like body may have a width of approximately 7 mm to approximately 13 mm. The pilot bit may include an auger bit. The cutting head of the auger bit may include a pair of diametrically opposed radially extending cutting edges terminating in a peripheral tooth, and the shaft comprises a shank portion received in the holesaw and a fluted intermediate shaft having at least one spiral flute extending from the cutting head to the shank, the fluted intermediate shaft and the cutting head having substantially the same outer diameter. The tip may have a conical shape with a thread. A portion of the tip may be ground to form a flat. The thread may have a pitch between approximately 1.0 mm and approximately 2.5 mm.
An arbor may removably coupled to the base of the cup and configured to receive the shaft of the drill bit. The arbor may have a shank configured to be received in a power tool, an intermediate body, and a central projection configured to be received in a central opening in the holesaw. The central projection may define a bore configured to retain the shaft of the pilot bit. The intermediate body may include one or more lateral projections configured to be received in one or more lateral openings in the holesaw. Coupling the holesaw assembly to a rotary power tool may include mounting the holesaw and the pilot bit on an arbor, and coupling the arbor to the rotary power tool. The holesaw assembly may enable use in a cordless drill to have a runtime improvement of at least 90% as compared to a holesaw with a pilot bit without a threaded tip.
In another aspect, a holesaw assembly includes a holesaw having a hollow cup defining a center axis. The cup has a round base perpendicular to the center axis and a peripheral wall coupled to and extending axially forward of the base to a peripheral edge at a free end of the wall. A pilot bit is received in the holesaw along the center axis. The pilot bit has a shaft received in the base, a cutting head coupled to a front end of the shaft, and an at least partially threaded tip coupled to a front end of the cutting head. The holesaw is free of any radial cutting elements disposed inside the cup between the drill bit and the peripheral wall of the cup.
Implementations of this aspect may include one or more of the following features. The peripheral edge of the holesaw may include one or more hard metal cutting inserts. Each cutting insert may include a cutting edge and a rake face, the rake face disposed at a hook angle relative to a line parallel to the center axis, the hook angle being between approximately negative 10° and approximately positive 10°. Each cutting insert may include an outer side face offset radially outwardly from the peripheral edge of the holesaw by a first distance, and an inner side face offset radially inwardly from the peripheral edge of the holesaw by a second distance that is greater than the first distance.
The drill bit may comprise an auger bit with the threaded tip or a spade bit with the threaded tip. The cutting head may have a plate-like body with first and second side faces extending radially outward from center axis and first and second cutting edges extending radially outward from center axis. The plate like body may have a width of approximately 7 mm to approximately 13 mm. The body may include radial faces connecting radially outward edges of the first and second side faces, each of the radial faces tapering radially inwardly in a circumferential direction from the cutting edge to a trailing edge. The radial faces may taper radially inwardly to cut out regions in an axially rearward direction from the threaded tip.
The cutting head may include a pair of diametrically opposed radially extending cutting edges terminating in a peripheral tooth. The shaft may include a shank portion received in the holesaw and a fluted intermediate shaft having at least one spiral flute extending from the cutting head to the shank. The fluted intermediate shaft and the cutting head may have substantially the same outer diameter. The threaded tip may have a conical shape with a thread. A portion of the threaded tip may include at least one flat surface. The holesaw assembly enables use in a cordless drill to have a runtime improvement of at least 90% as compared to a holesaw assembly with a pilot bit having an unthreaded tip.
In another aspect, a holesaw assembly includes a holesaw with a hollow cup defining a center axis. The cup has a round base perpendicular to the center axis and a peripheral wall coupled to and extending axially forward of the base to a peripheral edge at a free end of the wall. A pilot bit is received in the holesaw along the center axis. The pilot bit has a shaft received in the base, a cutting head coupled to a front end of the shaft, and an at least partially threaded tip coupled to a front end of the cutting head. The holesaw is configured to form and remove a generally cylindrical plug of material from a workpiece.
Implementations of this aspect may include one or more of the following features. The peripheral edge of the holesaw may include one or more hard metal cutting inserts. Each cutting insert may include a cutting edge and a rake face. The rake face may be disposed at a hook angle relative to a line parallel to the center axis. The hook angle may be between approximately negative 10° and approximately positive 10°. The pilot bit may comprise an auger bit with the threaded tip or a spade bit with the threaded tip. The cutting head of the spade bit may include a plate-like body coupled to a front end of the shaft, first and second side faces extending radially outward from center axis, first and second cutting edges extending radially outward from center axis, and radial faces connecting radially outward edges of the first and second side faces. Each of the radial faces may taper radially inwardly in a circumferential direction from the cutting edge to a trailing edge of the body.
In another aspect, a holesaw assembly includes a holesaw having a hollow cup defining a center axis. The cup has a round base perpendicular to the center axis, a peripheral wall coupled to and extending axially forward of the base to a peripheral edge at a free end of the wall, and one or more hard metal cutting inserts coupled to the peripheral edge. Each cutting insert includes a cutting edge and a rake face. The rake face is disposed at a hook angle relative to a line parallel to the center axis. The hook angle is between approximately negative 10° and approximately positive 10°. A spade bit is received in the holesaw along the center axis. The spade bit has a shaft received in the base, a cutting head with a plate-like body coupled to a front end of the shaft, and an at least partially threaded tip coupled to a front end of the body. The body includes first and second side faces extending radially outward from center axis, first and second cutting edges extending radially outward from center axis, and radial faces connecting radially outward edges of the first and second side faces. Each of the radial faces taper radially inwardly in a circumferential direction from the cutting edge to a trailing edge. The holesaw assembly may enable use in a cordless drill to have a runtime improvement of at least 90% as compared to a holesaw assembly with a spade bit that has an unthreaded tip.
Advantages may include one or more of the following. The holesaw assembly may enable substantially greater runtime than existing holesaws when used with a cordless (battery operated) power tool. In addition, the holesaw assembly may be usable with the user having to place little or no axial bias on the power tool, thus reducing user fatigue. These and other advantages and features will be apparent from the description and the drawings.
Referring to
Referring also to
The peripheral wall 22 defines one or more slots 32 configured to facilitate removal of a plug of material from the holesaw 12. In the illustrated embodiment, the slots 32 are open to the edge 24 and are generally parallel to the center axis X. However, the slots 32 may be fully enclosed, may be at an angle to the center axis X, and/or may have a different curved or geometric shape. The peripheral edge 24 includes one or more cutting inserts 30. The cutting inserts 30 may be composed of a hard metal, such as tungsten carbide, and may be received in and brazed or welded to pockets 34 in the peripheral edge 24. In the illustrated embodiment, each of the slots 32 is positioned in front of one of the cutting inserts 30 in a cutting direction of rotation R of the holesaw 18.
Referring also to
Referring also to
The outer side surface 32A is angled radially outward in an axially forward direction F by an outer offset angle θA so that the outer top edge 39A is offset in a radially outward direction RO from the rim 24 of the holesaw by an outer offset distance Da. The inner side surface 32B is angled radially outward in an axially forward direction F by an inner offset angle θB so that the inner top edge 39B is offset in a radially outward direction RO from the rim 24 of the holesaw by an inner offset distance Db. The inner offset distance Db and the inner offset angle θB are greater than the outer offset distance Da and the outer offset angle θA. In one implantation, the top bevel angle β is approximately 5° to 15° (e.g., approximately 10°), the outer offset angle θA is approximately 2° to 8° (e.g., approximately 5°), the inner offset angle θB is approximately 5° to 11° (e.g., approximately 8°), the outer offset distance Da is approximately 0.4 mm to 0.8 mm (e.g., approximately 0.6 mm), and the inner offset distance Db is approximately 1.0 mm to 1.4 mm (e.g., approximately 1.2 mm). The larger offset angle θB and offset distance Da of the inner side surface 32B creates a space between the plug formed by the cutting inserts and the rim of the holesaw, which facilitates easier removal of the plug from the holesaw after a cutting operation is complete.
Referring also to
The holesaw 18 may be manufactured using the following process. First, a sheet metal blank 90 may be stamped or cut to form a rectangular blade portion 92 having the peripheral edge 24, a bottom edge 94, and lateral edges 95, 96. Next, the rectangular blade portion 92 may be rolled into a cylindrical shape and its lateral edges 95, 96 welded together along a seam 98 to form the peripheral wall 22. A similar sheet metal blank 90 may be stamped or cut to form the circular base 20 with the openings 26, 28. The bottom edge 94 of the peripheral wall 22 may then welded to the base 20. The cutting inserts 30 then may be brazed or welded to the pockets in the peripheral edge 24. Finally, the cutting inserts 30 may be ground to their desired geometry. These steps may be performed in a different order. For example, the cutting inserts may be ground to their desired geometry before they are brazed or welded to the pockets in the peripheral edge 24.
Referring again to
The cylindrical flange 44 also defines a pair of axial bores 50 disposed radially outward from the central projection 40. Axially behind the cylindrical flange 44 and surrounding the intermediate shaft 36 is an annular collar 54 with a pair of projections 52 generally parallel to the center axis X and received in and project from the axial bores 50 in the flange 44. The projections 52 are configured to be received in the peripheral openings 28 in the holesaw 12. The annular collar 54 is moveable along the intermediate shaft 36 between a front position (as shown in
Referring to
Extending axially forward of the top edge 80 along the center axis X is an at least partially threaded tip 82. The tip 82 may have a generally conical, frustroconical, or parabolic shape extending from a wide base 81 to a narrower or pointed tip 83. The tip 82 may have a diameter D at its base 81 of approximately 3 mm to approximately 7 mm, and a height H of approximately 6 mm to approximately 20 mm. One or more threads 85 wrap around the tip in the rotational direction. The threads 85 on the tip 82 may have a thread pitch P (i.e., the axial distance it takes on thread to make one complete revolution about the tip 82) of approximately 1.0 mm to approximately 2.5 mm, e.g., approximately 1.5 mm to approximately 2.0 mm. The tip 82 may be threaded along its entirety or be only partially threaded along a portion of its height H and/or circumference.
Extending along the top edge 80 and radially outward from the base 81 of the tip 82 are diametrically opposed first and second cutting edges 84, 86. The cutting edges 84, 86 intersect side edges 76, 78 at cutting points 87, 89. The cutting edges 84, 86 may be inclined at an angle β to a line A that is generally perpendicular to the center axis X. In one embodiment, angle β may be positive angle (as shown in
Referring to
Referring to
Referring to
Extending axially forward of the top edge 180 along the center axis X is an at least partially threaded tip 182. The tip 182 may have a generally conical, frustroconical, or parabolic shape extending from a wide base 181 to a narrower or pointed tip 183. The tip 182 may have a diameter D′ at its base 181 of approximately 3 mm to approximately 8 mm, and a height H′ of approximately 6 mm to approximately 20 mm. One or more threads 185 wrap around the tip in the rotational direction. The threads 185 on the tip 182 may have a thread pitch (i.e., the axial distance it takes on thread to make one complete revolution about the tip 82) of approximately 1.0 mm to approximately 2.5 mm, e.g., approximately 1.5 mm to approximately 2.0 mm. The tip 182 may be threaded along its entirety or be only partially threaded along a portion of its height H′ and/or circumference.
Extending along the top edge 180 and radially outward from the base 181 of the tip 182 are diametrically opposed first and second cutting edges 184, 186. The cutting edges 184, 186 intersect side edges 176, 178 at cutting points 187, 189. The cutting edges 184, 186 may be inclined at an angle β′ to a line A′ that is generally perpendicular to the center axis X. In the embodiment depicted, angle β′ is a positive angle so that the cutting points 187, 189 project axially forward of the base 181 of the tip 182. In other embodiments the angle β may be negative so that the cutting points 187, 189 are recessed axially behind the base 181 of the tip 182, or may be zero so that the cutting points 187, 189 are even with the base 181 of the tip 182.
As shown in
Referring to
In use, the holesaw assembly 10, 110 is assembled by retracting collar 54 of the arbor to its rear position, mounting the holesaw 12 on the arbor 14 by inserting and/or threading the central projection 40 into the central opening 26, and releasing the collar 54 to its forward position to allow the projections 52 to engage the openings 28 in the holesaw 12. Next the set screw 48 is loosened, the pilot bit 16, 16′, 116 is inserted through the central opening 26 in the holesaw 12 into the bore 44 in the arbor 14, and the set screw 48 is tightened to firmly hold the pilot bit 16, 16′, 116 in the arbor 14. The shank 34 of the arbor is coupled to a tool holder of a rotary power tool, such as a drill. The tip 82, 82′, 182 is placed against the workpiece and the drill is actuated. The threaded tip 82, 82′, 182 enters the workpiece first, drawing the holesaw assembly 10 into the workpiece, followed by the cutting edges 84, 86, 184, 186 of the pilot bit 16, 16′, 116 and the cutting inserts 30 of the holesaw 18. The cutting inserts 30 makes a circular cut to form a substantially circular hole and remove a solid, substantially cylindrical plug of material from the workpiece.
The holesaw assembly 10, including the configuration of the holesaw 12 and the pilot bits 16, 16′, 116 have been optimized for use with a cordless power tool in order to maximize power tool runtime (i.e., the number of holes that can be drilled per battery charge), while maintaining adequate speed and quality of hole formation. In certain embodiments, it has been discovered that power tool runtime can be substantially increased (even more than expected) by using a holesaw assembly having the following combination of features: a hook angle α of the cutting inserts 30 between approximately −10° and approximately +10°; a width W of the paddle 64 of the pilot bit 16 between approximately 7 mm and approximately 13 mm, and a thread pitch P of the threads 85 on the tip 82 of between approximately 1.0 mm and approximately 2.5 mm.
As shown in the below table, in an experiment, several prototype designs of 2 9/16 inch holesaws having different carbide cutting insert hook angles and pilot bits having tips with different thread pitch were compared to the Milwaukee® 49-56-9010 2 9/16″ Big Hawg® Hole Cutter. The experiments were performed using a DEWALT 60V MAX* cordless right angle drill and making holes in 2-inch thick SPF board, with no axial bias applied to the tool.
In each of the designs according to the present disclosure, the number of holes per charge unexpectedly and greatly exceeded the number of holes per charge achievable without the pilot bit with the at least partially threaded tip, e.g., by approximately 96% to approximately 162%. In addition, the inventors expected the holesaw with the more aggressive (higher) thread pitch and the more aggressive (positive) hook angle to cut faster and, therefore, to have a greater number of holes per charge. However, contrary to expectations, in this experiment, the greatest improvement was discovered with a holesaw having a negative hook angle (e.g., negative 5°) and a less aggressive (smaller) thread pitch (e.g., 1.5 mm). Moreover, it was discovered that the threaded tip that has been modified to have flats has even greater improvement.
In addition, the designs of the present disclosure also have markedly, and unexpectedly, increased drill speed (which correlates with increased cordless efficiency and runtime) as compared with existing bi-metal holesaws. For example, three diameters of holesaw assemblies having a holesaw constructed in accordance with the embodiment of
In each of the designs according to the present disclosure, the cutting speed (and thus the expected efficiency and number of holes per charge) greatly exceeded the cutting speed of a comparably sized bi-metal holesaw, e.g., by approximately 70% to approximately 93%.
Referring to
Terns of degree such as “generally,” “substantially,” “approximately,” and “about” may be used herein when describing the relative positions, sizes, dimensions, or values of various elements, components, regions, layers and/or sections. These terms mean that such relative positions, sizes, dimensions, or values are within the defined range or comparison (e.g., equal or close to equal) with sufficient precision as would be understood by one of ordinary skill in the art in the context of the various elements, components, regions, layers and/or sections being described.
Numerous modifications may be made to the exemplary implementations described above. These and other implementations are within the scope of this application.
This application is a continuation of U.S. patent application Ser. No. 15/181,986, filed Jun. 14, 2016, which claims priority, under 35 U.S.C. § 119(e), to U.S. Provisional Application No. 62/247,816, filed Oct. 29, 2015, each of which is incorporated by reference.
Number | Date | Country | |
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62247816 | Oct 2015 | US |
Number | Date | Country | |
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Parent | 15181986 | Jun 2016 | US |
Child | 16266213 | US |