1. Field of the Invention
The present invention relates to the field of hardware tool bits, and more particularly, the present invention relates to a device for removing damaged fasteners still embedded or otherwise engaged with a workpiece.
2. Description of the Prior Art
The use of fasteners, such as screws, bolts, and other threaded joining devices continues to increase. However, the more a fastener is used, the more likely that its head becomes rounded off, or the fastener is broken, or otherwise rendered useless. At that point, the fasteners must be removed, and/or the workpiece replaced or abandoned.
A myriad of screw removing bits exist. Generally, the bits are typical in that each utilizes a rotating tool shaft, such as the shaft of a screw driver, either manually or power-driven. The second end of the bit is configured to impart rotational torque to the fastener while the latter is still held fast by the workpiece.
The second end of the bit mimics the end of a standard drill bit. Several broken bolt extractors feature a left-handed cutting edge. For example, U.S. Pat. No. 4,777,850 discloses two such edges. However, such devices still require considerable power to impart the rotational torque necessary to “bite” into the fastener to begin left-handed extraction.
U.S. Pat. No. 6,595,730 B2 awarded to Bergamo on Jul. 22, 2003 discloses a bit for removing damaged screws. This device is designed to engage the exterior surface of the fasteners and not interior surfaces of the fastener. As such, “purchase” of the fastener by the device is relegated to that exterior surface.
Another example of a prior art extraction device is the tool disclosed in German patent DE 19526631 A1. The tool depicts two cutting edges that drill a hole in a “frozen” screw/bolt or rivet when rotated in a first direction. The two cutting edges also are suitable for loosening the same fastener after drilling the hole in the fastener thereby providing a single tool that performs two functions to reduce the extraction time to remove a fastener from a workpiece. The problem with this tool is that a recess must be present in the fastener to better facilitate removal from the workpiece. The German tool cannot be used to remove a fastener having a slotted surface configuration unless the fastener includes a recess with a depth sufficient to allow the two cutting edges to insert therein. Otherwise, the slotted head fastener would be damaged during removal.
A need exists in the art for a broken bolt or broken screw extraction device to facilitate easier removal of fasteners held tight by a workpiece. The device should be able to be utilized with hand-actuated handles or with electrically activated (including battery operated) tools. The device should engage as much of the interior surface of a wayward fastener so as to decrease the likelihood of a spin off of the device from the fastener while concomitantly increasing the likelihood of extraction of the fastener with minimal force required.
It is an object of the present invention to provide a broken bolt or broken screw remover that overcomes many of the disadvantages of the prior art.
It is a further object of the present invention to provide a broken bolt/screw remover bit that requires only low levels of torque to extract a fastener. A feature of the invention is that the bit has a pair of generally radially projecting cutting edges, with each of the cutting edges defining an angle with respect to the axis of the remover and a periphery of a frusto-conical surface. The cutting edges may be linear or curved. Each of these surfaces forms an acute angle with respect to the axis of the bit. An advantage of the invention is that the different cutting edge angles enhance the bite of the bit into interior surfaces of the fastener. The cutting edges can contain serrations running substantially perpendicular to the longitudinal axis of the cutting edge to provide additional purchase of the fastener. Also the serrations may form an acute or an obtuse angle with the cutting edge. The serrations allow the bit to effectively extract wayward fasteners at bit rotation speeds of as low as 0.25 RPM to as high as typical RPM values of commercially available electric screw drivers and power tools. Hand-actuated screw drivers, by comparison, are typically turned one quarter turn per wrist roll such that 30 RPM is typical for a non-powered hand tool.
Yet another object of the present invention is to provide a broken bolt/screw remover which also has drilling function. A feature of the invention is that it comprises a left-handed countersink drill bit containing serrations which extend from a cutting edge of the bit. An advantage of the invention is that the drilling feature of the remover causes more interior surfaces of the fastener to be made available to the cutting edges and the serrations, so as to assure simultaneous withdrawal of the remover with the fastener attached to the bit while leaving the threaded cavity in the workpiece intact.
Still another object of the present invention is to provide a step drill with fastener remover capabilities. A feature of an embodiment of the invention is a plurality of generally longitudinally-extending serrations interposed between axially spaced steps in the drill bit. These serrations extend in a left hand cutting fashion from a cutting edge of the bit. An advantage of the invention is that this embodiment can be utilized to extract fasteners having a myriad of different shank diameters.
Briefly, the invention provides a bit for removing a broken fastener having a direction of engagement, said bit comprising an elongated shaft with a longitudinal axis, said shaft having a first end, and a second end, said first end terminating in a drilling tip; a plurality of linear or nonlinear cutting edges extending radially from said tip, with each of the cutting edges defining a frusto-conical surface with serrations thereon, said cutting edges configured to cut into the fastener when the bit is rotated in a direction opposite to the fastener's direction of engagement; and said second end of the shaft configured to be received by a tool which provides rotational torque.
The foregoing invention and its advantages may be readily appreciated from the following detailed description of the invention, when read in conjunction with the accompanying drawing in which:
aa is an elevational view of the invented bit, in accordance with features of the present invention;
ab is a top view of
ac is an elevational view of
ba is an elevational view of the invented bit with serrated regions, in accordance with features of the present invention;
bb is a top view of
bc is an expanded view of the invented bit with serrated regions depicted in
ba, in accordance with features of the present invention;
ca is an elevational view of an alternate invented bit with serrated regions, in accordance with features of the present invention;
cb is a top view of
cc is an elevational view of an alternate invented bit with serrated regions, in accordance with features of the present invention;
cd is a top view of
da is a detailed view of the serrated regions depicted in
db is a detailed view of an alternate configuration of the serrated regions depicted in
a is an elevational view of an easy out bit further defining a left handed drill bit with serration portions, in accordance with features of the present invention;
b is an expanded view of the cutting edge of
a is a side view of a step drill bit with cutting threads, in accordance with features of the present invention;
b is a side view of an alternate step drill bit with serration portions, in accordance with features of the present invention;
c is a top view of
a is a perspective view of an alternative fastener extraction device, in accordance with features of the present invention;
b is a top view of
a is a modified spade flat, in accordance with features of the present invention;
b is an alternate modified spade flat, in accordance with features of the present invention;
a is an elevational view of a modification of the invented bit, in accordance with features of the present invention;
b is a top view of
a is an elevation view of a extraction tool depicting non-linear cutting surfaces, in accordance with features of the present invention;
b is an exploded view of
a is a top view of an alternate embodiment of the invented bit taken along the line 1bb-1bb of
b is a top view of an alternate embodiment of the invented bit taken along the line 1bb-1bb of
c is a top view of an alternate embodiment of the invented bit taken along the line 1bb-1bb of
d is a top view of an alternate embodiment of the invented bit taken along the line 1bb-1bb of
e is a top view of an alternate embodiment of the invented bit taken along the line 1bb-1bb of
f is a top view of an alternate embodiment of the invented bit taken along the line 1bb-1bb of
a is a side view of an alternate embodiment of the invented bit in accordance with features of the present invention;
b is a top view of an alternate embodiment of the invented bit of taken along the line 13b-13b of
The present invention provides a bit configuration and various bit/threaded configurations on a single device to allow for easier fastener extraction. More specifically, the present invention provides a bit for removing a broken fastener having a direction of engagement, said bit comprising: (a) an elongated shaft with a longitudinal axis, said shaft having a first end, and a second end, said first end terminating in a tip region; (b) a plurality of non-cutting edges and of nonlinear cuffing edges extending from said tip region, said cutting edges configured to cut into the fastener when the bit is rotated in a direction opposite to the fastener's direction of engagement, and said cutting edges and said non-cutting edges alternating with each-other; (c) a plurality of frusto-conical traction surfaces each extending from one said cutting edge to a non-cutting edge, wherein one or more of said surfaces comprise a plurality of serrations; and (d) said second end of the shaft configured to be received by a tool which provides rotational torque. In an embodiment of the invention, the tip defines the tip of a drill-bit.
aa provides salient features of the invented bit, the bit designated generally as numeral 10. As with any typical bit, the bit generally comprises a shaft 12 with a first end 13 terminating in a tip 19. While the tip 19 is depicted as generally pointed, standard split tips also can be utilized such that cutting surfaces 14 are not coplanarly aligned with each other or with the tip. This split point configuration minimizes and even prevents “walk out” of the bit from the workpiece. As such, the configuration serves as a means for maintaining the bit on the fastener during rotational motion of the bit.
A second end 65 of the bit is configured to be received by a tool which imparts rotating torque, including but not limited to a chuck, or collet (or some other means for imparting torque). As such, a cross section of the second end can be circular, hexagonal, polygonal or any convenient shape to facilitate the tip being acted upon with rotational torque.
The bit typically comprises two longitudinally extending notches 16, each of the notches terminated on one side with a leading or cutting edge 14. The other side of the notch is bounded by a non-cutting edge 17. Both the cutting edge 14 and the non-cutting edge extend from a point proximal to the axis, α, to the bit periphery. One or more notches are acceptable, but, for the sake of specificity, the following discussion will focus on two-notched configurations. In a two-notch embodiment, two frusto-conically-shaped regions, diametrically opposed to each other, are presented. One or both of the regions contain serrations as defined infra. The cutting edge 14 faces in a counter-clock-wise direction for extracting a fastener with a clockwise direction of engagement and conversely for a counterclockwise fastener. Between the cutting edge and the non-cutting edge is a biting or traction-enhancing surface 18 which can be described as a section of a frusto-conically-shaped region. The biting surface 18 is bound by the cutting edge 14 and non-cutting edge 17. In one embodiment of the invention, as shown in
The cutting edge 14 defines an angle β to the longitudinal axis a of the bit.
Surprisingly and unexpectedly, the inventor has found that the difference in the cutting edge angles facilitates greater bite into the shank of the broken fastener. The first angle ρ can differ from the second angle γ by as much as 50 percent. For example, whereas the first angle is 45 degrees, the second angle γ is 30 degrees. Ideally, the sum of the angles is such that any remaining slot of a broken fastener can simultaneously contact at least portions of each of the cutting edges 14 and 14b. While the cutting edges depicted in
As an alternative to the bit having a straight cutting edge 14a as depicted in
Surprisingly, and unexpectedly, the inventors found that engagement between the removal device and the broken fastener is enhanced if the teeth 15 on the traction surfaces 18 are axially asymmetric. This can be accomplished by a variety of means. In embodiments depicted in
In the embodiment depicted in
The inventors have found that having one cutting edge serrated, and the immediate next cutting edge smooth enhances “bite” of that smooth cutting edge into the fastener for easier extraction from the workpiece. This alternating serrated/smooth cutting edge configuration provides a double action whereby the serrated edge roughens the topography of the fastener surface, thereby serving as a means for enhancing purchase of the smooth cutting surface with the fastener.
A plurality of cutting edges on the same bit can be serrated (even on adjacent edges as opposed to a smooth edge intermediate two serrated edges), with one configuration having edges biting into the fastener at different axial locations from each other. The inventive feature of varying the angle of attack of the edges (e.g., the angles βγ and γ, discussed supra) will minimize the possibility of adjacent serrated edges destroying the carcass of the fastener before the bit can anchor into the carcass for removal.
There are many possible variations in the configuration of the serrations. For instance, a possible embodiment is where serrations are provided on two cutting edges that are at the same angle with respect to the bit axis, with the serrations defining two sets of teeth 15 with separated by gaps 11.
Furthermore, it should be noted that the invented bits need not terminate into a sharp apex. Rather, bits terminating in rounded or blunted apexes are suitable for fasteners having particularly large-diameter shanks or for fasteners where a central cavity has been fashioned during a previous attempt to extract the fastener.
a depicts an embodiment of the invented broken fastener remover, designated as numeral 20, which comprises a standard “easy out” configuration (whereby the easy out defines a tapering, left handed spiral). This embodiment comprises a plurality of left-handed cutting surfaces 22 terminating in a drill tip 28. The tip 28 can have the configuration described in
Also, the fastener remover bit 20 with the easy out configuration can include a plurality of serrations 24 extending from the cutting edge(s) 22 of the bit 20. These cutting edges 22 define helical regions extending circumferentially along the periphery of the bit 20 and generally parallel to the longitudinal axis .alpha. of the bit. The serrations can exist along one or more than one of the cutting edges 14 of the bit. A salient feature of this embodiment is that the left hand serrations 24 extend parallel to the longitudinal axis .alpha. of the bit. These serrations bite in to the recess of the screw head.
a and 3b depict a fastener removal bit designated as numerals 30 and 73, respectively. This removal bit 30 has a first end 31 adapted to be received by a rotating handle or chuck, or collet (not shown). A second end 32 of the removal bit 30 terminates in a bit configuration 39 similar to that depicted in
In
b depicts an alternative step bit 73, wherein the steps 34 are configured to comprise counter-clockwise cutting edges 74 and biting surfaces 78. More specifically, the bit 73 has a first end that terminates in a tip 72 with two or more notches 71 extending longitudinally along the shaft 31 from the tip, said notches separated by a plurality of cutting edges 74, said edges 74 arranged on biting surfaces 78 which are positioned along the axis and successively radially displaced further from the axis in a direction from the first end to the second end. The cutting edges 74 are configured to cut into the fastener in progressive radial steps when the bit is rotated in a direction opposite to the fastener's direction of engagement at the same time as the cutting edges cut azimuthally into the fastener. Depending regions of biting surfaces 78 comprise a plurality of teeth 76, each of said teeth defining one cutting edge 74 adapted to bite the fastener in a direction along the longitudinal axis of the fastener. Thus each of the steps 34 constitutes a hole saw that bites into the fastener as the bit advances into the fastener.
a depicts another bit, designated generally as numeral 44 and
The invented screw/bolt remover configuration can be integrally molded with other typical tool bits. For example, and as depicted in
In
In
In
As with the embodiments depicted in
The spade flat depicts a ¼″ size. However, this is for example only. Rather, a myriad of spade flat sizes are suitable, depending on the diameter of the residual fastener head 58 or shank remaining.
Another embodiment of a spade flat is depicted in
It should be noted that the above described embodiments all depict left handed cutting configurations. However, if left handed fasteners are to be removed, then the herein disclosed embodiments with right handed cutting configurations would be utilized.
It should be further noted that the opposed cutting edges in each of the above-disclosed embodiments generally are configured at angles to the longitudinal axis of the respective bit which are either identical to each other, or different from each other, on the same bit.
As mentioned supra, the cutting edges 14 and non-cutting edges 17 of the bit can be curved (i.e., nonlinear), as depicted in
a is a perspective view of an embodiment of the invented extractor bit with curved cutting edges (
a, 7b, and 8 depict an embodiment wherein the cutting edges 14a, 14b and the corresponding non-cutting edges 17a, 17b are not at the same angle with respect to the axis a of the bit. As shown in
The notches 82, 84 are shaped and reminiscent of the flutes of left hand drill bits. While the flutes of the illustrated embodiment extend generally along a straight line and longitudinally and parallel to the longitudinal axis of the bit, curved flutes are also suitable variants. Such flutes define an extended helix or spiral along a longitudinally extending section of the periphery of the bit and about its circumference. These curved flutes are further defined by serrations along their edges or rims which face in a direction the bit is to be rotated to extract fasteners. (See
Curved flutes and curved cutting edges 14 are also shown also in
Optionally, instead of, or in addition to the serrations extending across the fastener engaging surfaces 24, 26, serrations 36 also are provided which extend along interior wall portions 33, 35 of the notches 32, 34 from the corresponding cutting edges 14a, 14b (See dotted lines in
As with the cutting and non-cutting edges of the other embodiments in this invention, the regions between the cutting edges 14 and the non-cutting edges 17 define a frusto-conical surface 18 of the bit such that this surface lies intermediate the cutting and respective non-cutting edge. Although
Also, where serrations are provided on the curved cutting edges 14 as shown in
a is a perspective view of an extractor bit with curved cutting edges, only one of which, edge 14a is visible.
c depicts another embodiment of the curved cutting edges of the presently invented bit. It features a convex curved cutting edge 14 together with pointed protuberances 95, configured as spikes, extending parallel to the axis of the bit along the notch surfaces 16 (See
In
e and 10f depict yet another embodiment of the curved cutting edges of the presently invented bit. In
a is and 13b present a side and a top view, respectively, of an alternate embodiment of the teeth on the traction surfaces of the presently invented bit. The teeth 15 on the traction surface 18 in the present embodiment define spiral sections such that the distance r from the tip 21 to a point p on a tooth 15 decreases as the distance between p and the cutting edge 14 increases. Preferably, the pitch of the spiral defined by the teeth 15 should be the same as that of the screw-thread of the fastener being extracted. As shown in
The features depicted in
Also, the invented bits can be configured to include a means for preventing the bits from dislodging from broken fasteners once engagement with said fasteners occurs. In this regard, “finders” may be installed. These are accessories associated with, and co-axial to, the shanks of the bits and in slidable communication therewith. Generally configured as cylinders, sleeves, chucks, or collets, the finders are adapted to slide over the periphery of a fastener which is held fast in a work piece. As such, the finders maintain the bit in a position coaxial to the longitudinal axis of the fastener to assure adequate embedding of the bit into the fastener. The finder also prevents jumping or skipping of the bit from the fastener to adjacent surfaces of the workpiece, thus preventing marring or scuffing of said workpiece.
Another addition to the invented device is the positioning of a collar or radial projection about the circumference of the device. The collar or projection would be positioned intermediate the first and second end of the device and serve as a means for preventing penetration of the device into the fastener beyond the distance defined by the tip 19 of the device and the position of the collar.
While the invention has been described in the foregoing with reference to details of the illustrated embodiment, these details are not intended to limit the scope of the invention as defined in the appended claims.
This patent application is a Divisional of U.S. patent application Ser. No. 11/985,099 filed on Nov. 14, 2007, which is a Continuation in Part of U.S. Utility patent application Ser. No. 11/255,424 filed on Oct. 22, 2005, now abandoned, which is a Continuation in Part of U.S. Utility patent application Ser. No. 10/831,391 filed on Apr. 23, 2004, which issued as U.S. Pat. No. 6,978,697, which claims the benefit of U.S. Provisional Patent Application No. 60/465,506 filed on Apr. 25, 2003, all of which are incorporated herein by reference.
Number | Date | Country | |
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60465506 | Apr 2003 | US |
Number | Date | Country | |
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Parent | 11985099 | Nov 2007 | US |
Child | 13478844 | US |
Number | Date | Country | |
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Parent | 11255424 | Oct 2005 | US |
Child | 11985099 | US | |
Parent | 10831391 | Apr 2004 | US |
Child | 11255424 | US |