Thread forming taps

In one aspect, thread forming taps are described herein. In some embodiments a thread forming tap comprises a shank disposed at a first end adapted to engage a tool holder and an elongated working portion disposed at a second end. The working portion comprises at least one helical thread and a plurality of longitudinally-extending linear grooves. The longitudinally-extending linear grooves intersect the helical thread forming a plurality of lobes, wherein adjacent lobes differ from one another in relief type and/or relief rate.

FIELD

The present invention relates to threading tools and, in particular, to thread forming taps for use in cold forming applications.

BACKGROUND

Thread forming taps and tools employing the same are generally known. Forming taps permit the formation of internal threads in a workpiece through application of compressive force to interior surfaces. Moreover, forming taps can achieve thread formation with high quality surface finish without the generation of chips and can provide stronger internal threads with improved gaging as compared to cutting tools. Forming taps and associated thread forming tools can further provide improved tool life, reduced occurrence of breakage, and reduced machine downtime as compared to corresponding cutting tools.

Forming taps can be used with a variety of materials, in particular materials having relatively low tensile strengths, such as aluminum, copper, brass, zinc, and low carbon steels. Forming taps may additionally be employed in the formation of internal threads in both through-hole and blind-hole threading applications. As demands of thread forming applications continue to evolve, new tapping architectures and tap designs may be required to overcome limitations of prior architectures and designs.

SUMMARY

In one aspect, thread forming taps are described herein comprising a plurality of lobes disposed on a helical thread, wherein adjacent lobes differ in relief type and/or relief rate. For example, a thread-forming tap (hereinafter a “forming tap” or a “tap”) described herein defines a longitudinal axis, a first end and a second end disposed axially away from the first end. A shank is disposed at the first end and is adapted to engage a tool holder. An elongated working portion is disposed at the second end, the working portion comprising at least one helical thread and a plurality of longitudinally-extending linear grooves. The longitudinally-extending linear grooves intersect the helical thread forming a plurality of lobes, wherein adjacent lobes differ from one another in at least one of relief type and relief rate.

In another aspect, a thread-forming tap described herein defines a longitudinal axis, a first end, and a second end disposed axially away from the first end. A shank is disposed at the first end and is adapted to engage a tool holder. An elongated working portion is disposed at the second end, the working portion comprising at least one helical thread and a plurality of lobes disposed on the at least one helical thread about the longitudinal axis. Adjacent lobes differ from one another in at least one of relief type and relief rate.

In a further aspect, thread-forming tools are described herein. A thread-forming tool comprises a tool holder and a thread forming tap coupled to the tool holder. The thread forming tap defines a longitudinal axis, a first end and a second end disposed axially away from the first end. A shank disposed at the first end engages the tool holder and an elongated working portion is disposed at the second end. The elongated working portion comprises at least one thread disposed helically about the working portion and a plurality of longitudinally-extending linear grooves intersecting the helical thread. Intersection of the linear grooves with the helical thread forms a plurality of lobes, wherein adjacent lobes differ from one another in at least one of relief type and relief rate.

DETAILED DESCRIPTION

Embodiments described herein can be understood more readily by reference to the following detailed description and examples and their previous and following descriptions. Elements and apparatus described herein, however, are not limited to the specific embodiments presented in the detailed description. It should be recognized that these embodiments are merely illustrative of the principles of the present invention. Numerous modifications and adaptations will be readily apparent to those of skill in the art without departing from the spirit and scope of the invention.

Referring now toFIGS. 1-3, there is illustrated a forming tap, generally designated as reference number10, in accordance with one embodiment described herein. As provided inFIGS. 1 and 2, the forming tap (10) defines a longitudinal axis (A-A), a first end (20), and a second end (30) disposed axially away from the first end (20). The tap (10) comprises a shank (40) disposed at the first end (20) adapted to engage a tool holder (not shown) and an elongated working portion (50) disposed at the second end (30). The elongated working portion (50) comprises at least one thread, generally (60), disposed helically about the working portion (50) and can comprise a plurality of longitudinally-extending linear grooves (70) along the longitudinal axis (A-A). The linear grooves (70) intersect the helical thread, forming a plurality of lobes (61). Adjacent lobes (61) differ from one another in relief type and/or relief rate.

The linear grooves and plurality of lobes can be arranged or configured in any manner not inconsistent with the objectives of the present invention. For example, in some cases, a tap may have no longitudinally-extending linear grooves, one linear groove, or a plurality of linear grooves. In embodiments comprising a plurality of longitudinally-extending linear grooves, such grooves can be arranged generally axisymmetrically about the longitudinal axis. In other cases, the linear grooves are arranged asymmetrically about the longitudinal axis. The lobes can be individually selected to have zero relief (fully concentric lobe), con-eccentric relief, or eccentric relief. As understood by one of skill in the art, con-eccentric relief is a combination of concentric and eccentric relief. In some embodiments, for example, a first third of the land has a concentric margin, while the remaining two thirds of the land has eccentric relief. Further, lobes with an eccentric relief can exhibit the same or different relief rates.

For the purposes of the present disclosure and illustrated inFIG. 3, relief types are expressed relative to a virtual circle (80) defined by the outermost edges of the thread (60) in a helical cross-section of the working portion (50). The term “zero relief” as used herein indicates a lobe that is fully concentric to and/or cocircular with the virtual circle. The term “con-eccentric relief” as used herein indicates a relief comprising a portion less than the entirety of the relief that is concentric to and/or cocircular with the virtual circle. This portion is a “concentric margin,” as such term is used herein. Portions of the land not within the concentric margin are eccentric portions. Concentric margins as described herein can subtend an angle θ1as seen inFIG. 3. The angle θ1can have any value not inconsistent with the objectives of the present disclosure. For example, a value of θ1can be selected from Table 1.

TABLE IValue of θ1(degrees)0-100.5-101-102-104-100-60-83-7
An “eccentric relief” indicates a relief not comprising a line or are concentric to and/or cocircular with the virtual circle. Lobes comprising an eccentric relief can exhibit any shape or form not inconsistent with the objectives of the present disclosure. For example, the eccentric relief can comprise an apex (63). An apex (63) of an eccentric relief can comprise a single point which intersects and/or lies along the virtual circle, or an apex can comprise a curved portion which is neither concentric to nor cocircular with the virtual circle. Lobes (61) comprising an eccentric relief and/or an eccentric portion define a “relief rate,” or a curved shape in a radial direction towards the longitudinal axis away from the apex along the periphery of the thread.FIG. 4illustrates various non-limiting relief rates of eccentric reliefs as described herein.

In some cases, adjacent lobes (61) define an alternating pattern of relief type and/or relief rate. For example, in the embodiment ofFIG. 3, lobes having con-eccentric reliefs alternate with lobes having eccentric reliefs. In such cases, the lobes of con-eccentric relief can define lands having a concentric margin (62) central thereto and lobes of eccentric relief defining apexes (63) central thereto. In certain other embodiments, adjacent lobes form an alternating pattern of first eccentric reliefs having a first eccentric relief rate and second eccentric reliefs having a second eccentric relief rate, the first and second relief rates being different from one another.

Forming taps (10) described herein can comprise any number of lobes (61) not inconsistent with the objectives of the present invention when viewed as a cross-section, as inFIG. 3. In some cases, forming taps (10) described herein can comprise an even number of lobes (61). For example, the cross-section can comprise at least 4 lobes (61), at least 6 lobes (61), or at least 8 lobes (61). In certain other cases, forming taps (10) described herein can comprise an odd number of lobes (61). For example, the cross-section can comprise at least 5 lobes (61), at least 7 lobes (61), or at least 9 lobes (61). Taps can further comprise a number of linear grooves (70) corresponding to the number of lobes (61). For example, a cross-section comprising 6 lobes (61) can also comprise 6 grooves (70).

As illustrated inFIGS. 5A and 5B, forming taps (10) can further comprise at least one coolant or lubricant channel (90). The coolant channel (90) can have any configuration not inconsistent with the objectives of the present invention. In some cases, as illustrated inFIG. 5A, the coolant channel (90) is entirely collinear with the longitudinal axis (A-A) and terminates in at least one axial coolant hole (91) at the second end (30) of the tap (10). In certain other cases, as inFIG. 5B, the coolant channel (90) is collinear with the longitudinal axis (A-A) along a substantial length thereof and terminates in at least two radial coolant holes (92) in at least two of the linear grooves (70). In some embodiments, a forming tap (10) can comprise a plurality of coolant holes (not shown) parallel to the longitudinal axis (A-A) and terminating in one or more axial or radial holes along the second end or in a plurality of radial grooves.

The working portion (50) of a forming tap (10) described herein can have any suitable exterior or peripheral shape or configuration. For example, in some cases, the helical thread (60) can define an entry taper at the second end (30). Any desired entry taper configuration can be employed. For example, the helical thread (60) can have an entry taper having a length (in number of thread pitches) selected from Table II:

TABLE IILength of taper (pitches)1-101-1.52.5-33-55-88-10
A thread pitch is the distance from one point on a thread to an adjacent corresponding point on the thread in an axial direction measured parallel to the longitudinal axis. Lobes (61) disposed within an entry taper on the forming tap (10) described herein can comprise corresponding relief type and/or relief rate to the non-tapered lobes spaced distal from the second end (30). In some cases, lobes (61) disposed within an entry taper on the forming tap (10) described herein can comprise different relief type and/or relief rate to the non-tapered lobes spaced distal from the second end (30).

In another aspect, thread-forming tools are described herein. A thread-forming tool comprises a tool holder and a thread forming tap coupled to the tool holder. The thread forming tap defines a longitudinal axis, a first end and a second end disposed axially away from the first end. A shank disposed at the first end engages the tool holder and an elongated working portion is disposed at the second end. The elongated working portion comprises at least one thread disposed helically about the working portion and a plurality of longitudinally-extending linear grooves intersecting the helical thread. Intersection of the linear grooves with the helical thread forms a plurality of lobes, wherein adjacent lobes differ from one another in at least one of relief type and relief rate. For example, lobes of the forming tap described herein can be independently selected to have zero relief, con-eccentric relief, or eccentric relief. Further, lobes with an eccentric relief can exhibit the same or different relief rates. Further, the forming tap of the forming tool can have any architecture and/or properties described hereinabove.