Self-Locking Threaded Connecting Device
Background of the Invention
1. Field of the Invention
The present invention relates to self-locking threads and threaded connections, and
more particularly to self-locking threaded connection devices that may be discrete fasteners
intended to secure two or more work pieces together and comprised of a combination of a
threaded bolt, cylinder, stud, shank or screw mated with a complimentary threaded nut or
hole, or that also may be an integral part of some other device, such as the threads on the end of the arm that screws into the threaded complimentary hole in the torso of a toy soldier.
2. Description of the Related Art
Locking threaded fasteners and threaded connecting devices of a wide variety of
types are available which reduce the tendency of male, generally cylindrical, threaded components from altering their position in relation to their corresponding female threaded component, thereby reducing the tendency of such threaded fasteners and threaded
connecting devices to loosen and come apart in response to vibration, expansion, contraction and other movement. Many such fasteners function in this regard by increasing friction between the otherwise mated threads of the male and female components or between the fastener and the parts joined by the fastener. Examples include: lock washers, tooth washers, blind thread bores filled with resilient inserts such as disclosed in U.S. Pat. No. 5,078,562 issued to DeHaitre on January 7, 1992, and screw thread profiles that jam or deform when tightened such as disclosed in U.S. Pat. No. 5,242,252 issued to Harle on September 7, 1993. Other such fasteners and connections function by increasing the friction between the engaging surfaces of the head of the male component and work piece, or between the female component and work piece such as disclosed in U.S. Pat. No. 4,290,469 issued to Nakae on September 22, 1981. In all such arrangements, the increased friction makes rotation more difficult between the male and female components, thereby preventing inadvertent release or loosening of the male and female components. A drawback of all these approaches is that the male and female components can loosen at any axial pressure or tension less than that required to strip the male component out of the
female component. Since the threads in each case fall away in the direction of axial pressure or tension, a portion of such pressure or tension is translated into a rotational force tending
to loosen the components. Also, fasteners using these approaches generally require high or
increased torque to install, or mar the joint surface, or are not reusable, or require greater loads to be effective than is desirable to apply to some joints. Self-locking accessories such as cotter pins, lock wires, and nut assemblies comprising a first working nut and a second locking nut part as disclosed in U.S. Pat. No. 5,154,560 issued to Copito on October 13, 1992, have the drawback of requiring additional installation effort.
Therefore, there is a need for threads, threaded fasteners, and threaded devices: (i) that will not come loose under loads equal or less than the fastener supports, (ii) that can be easily installed using conventional tools, (iii) that employ torque values appreciably closer to those torque values only necessary to clamp together the workpieces (as opposed to requiring higher torque values to provide increased resistance against loosening), and (iv)
that can be installed as easily as standard fasteners. The present invention addresses these drawbacks in known prior threaded fasteners and threaded devices and meets these needs
with a novel thread design which can be forged, rolled, stamped, or otherwise applied to threaded fasteners and threaded devices using conventional techniques. Improved threaded fasteners and threaded devices may therefore be manufactured at close to the cost of traditional locking threaded fasteners and devices.
Brief Description of the Drawings
Figure 1A is a side view of the invention in an assembled state.
Figure IB is a bottom view of the invention in an assembled state showing the flexible thread projections of the female component interacting with the thread recesses of
the male component.
Figure 2 A is a side view of adjacent thread rotations of the invention in an
assembled state and showing one flexible thread projection in an unlocked state as applied
to male and female fastening components.
Figure 2B is a side view of adjacent rotations of the invention in an assembled state increased in size to show details of one flexible thread projection of the female component meshed with a recess of the male component.
Figure 3 A is a top view of the female fastening component's flexible thread according to a preferred embodiment of the present invention.
Figure 3B is a side view of the female fastening component's flexible thread according to a preferred embodiment of the present invention.
Figure 3C is a bottom view of the female fastening component with its flexible thread according to a preferred embodiment of the present invention.
Figure 3D is a half cut away side view of the female fastening component with its
flexible thread according to a preferred embodiment of the present invention.
Figure 4 A is a side view of adjacent rotations of an alternative embodiment of the
invention in an assembled and unlocked state, where the recesses are located at the root of the recess locking thread, and extending into the core of the male fastening component
between adjacent thread rotations of the male component, and the projections are located on the crest of the internal flexible thread segment.
Figure 4B is a side view of adjacent rotations of an alternative embodiment of the present invention in an assembled and unlocked state as applied to male and female fastening components where the projections of the flexible thread segment press axially against the recesses of the male thread..
Reference Numerals in the Drawings 11— male component
12 — female component
21 ~ female component's flexible thread segment
22 ~ projections of the flexible thread segment
25 ~ voids in flexible thread segment
26 ~ positioning tabs of the flexible thread segment
31 - recess locking thread
32 ~ recesses of the recess locking thread
Detailed Description of the Preferred Embodiment
Figure 1A shows a side view of a self-locking threaded connection, in an assembled
state, comprising a male component (11) having a first novelly formed thread (31)
(hereafter referred to as the "recess locking thread") and a female component (12) having applied to it a second novelly formed thread (31) (hereafter referred to as the "projection
locking thread," more fully shown in Figure 2A). The projection locking thread is aligned
on the female component so that its flexible projections (22) press up against the thread of
the male component. The projection locking thread is either attached to the female
component in a manner that enables its projections to flex axially or radially, or the
projections are formed in a manner that enables them to flex axially or radially. The female component is typically a threaded nut, bore, or hole. The male component is typically a threaded bolt, cylinder, stud, shank or screw. The projection locking thread and the recess locking thread are designed to work together so that, as the male component is being screwed into or out of the female component, the two threads engage each other in a novel manner (hereafter referred to as "meshing") and thereby lock. In the drawings, dashed lines indicate that a feature appears only intermittently from the given perspective.
Figure IB shows an end view of the self-locking threaded connection of Figure 1A
in a meshed state. Meshing occurs when any of the projections (22) of the flexible thread
segment (21) align with any of the recesses (32) of the recess locking thread (31). When
such alignment occurs, the tension pressing the female's internal flexible thread segment's
projections up against the male's thread (21) forces the aligned projection into the corresponding aligned recess thereby meshing the threads. Once meshed, sufficient additional higher torque in either the loosening or tightening direction unmeshes the threads. The sides of the projections and recesses have a gentle enough slope so that torque can urge the projections to slide up and out of the recesses, and thereby unmesh the threads.
When the torque is sufficient to overcome the friction between the faces of the engaged projections and recesses and to overcome the tension pressing the female's internal flexible
thread segment up against the recess locking thread (in addition to overcoming friction
between the female's standard thread and the male's thread as with standard thread configurations), the threads unmesh and the fastener is in an unlocked state until a
projection and a recess again align and mesh. In Figures 1A and IB, the flexible thread segment (21) flexes perpendicularly to the axis of the fastener.
Figures 2A is a side view of one projection of the flexible thread segment in an unlocked state. In Figure 2B, the projection appearing in Figure 2A is shown in greater
detail and is meshed with a recess of the recess locking thread. In the drawings, dashed lines indicate that a feature appears only intermittently from a given perspective.
Traditional threaded fasteners subjected to dynamic loads, stress reversals or vibration are susceptible to loosening. Tightening such fasteners develops axial tensile stress
that creates frictional resistance to loosening between mated threads and between bolt and
nut surfaces bearing against the joined materials. This same tensile stress in the bolt also encourages the mating threads to slip due to the "downward" slope of their helix angle. In
the current invention, for the mating threads to slip even as vibration reduces resistance, the axial tensile stress must also lift or force the flexible thread segment's projections out of the male thread's recesses and to overcome any remaining friction. To push or lift a projection out of a recess, the loosening torque resulting from tensile stress must be great enough to overcome the natural spring return action pushing the flexible thread segment's projections into the male thread's projections. To ensure that the loosening torque is less than these
resistive forces, the combination of the flexible thread segment's projection tension, the
slope of the sides of the recesses, and the shape of the projections are in combination
engineered to create sufficient resistance to prevent inadvertently loosening of the fastener.
In alternative embodiments, the faces of the recesses and projections can be formed so that the projections dig into the recesses when torque is applied in either the tightening or loosening directions. Iii such embodiments, the fasteners cannot be either further tightened or loosened once meshing occurs without damaging the projection or the recess. When the female component is used with a traditional bolt or other male component without recesses, the flexible thread segment presses up against the males thread creating additional resistance to loosening. When the flexible thread is engineered to press with sufficient force against the thread of the male, the additional resistance prevents inadvertent loosening in the same manner as prevailing torque nuts such as those with nylon inserts.
Figure 3A is a bottom view and Figure 3B is a side view of the female component's
flexible thread segment (21 of Figure IB). In the preferred embodiment, the female's flexible thread segment is not solid from its root to its crest for its full length. A series of voids in
the flexible thread segment (25), formed extending from the thread crest toward the thread
root, facilitate each projection (22) independently meshing fully with any recess (32 in Figure IB) when they align irrespective of the meshing state and position of the other
projections and recesses. In the preferred embodiment, the individual projections align
radially with the recesses, but the projections as a whole do not need to be arranged
symmetrically with the recesses. In the preferred embodiment there are a prime number of
recesses on each thread rotation, seventeen, and six projections on the flexible thread
segment. The flexible thread segment can be attached to the female component (12) in any
manner so long as the flexible thread segment always rotates with the female component and cannot rotate independently of the female component. In the preferred, embodiment positioning tabs (26 of Figure 3A and 3C) prevent the flexible thread segment from rotating
in relation to the rest of the female component (12) and position the flexible thread segment so that it's projections continue in the helix path formed by the standard thread of the thread of the female component.
Figure 4 A is a side view of adjacent rotations of an alternative embodiment of the
invention in an assembled and unlocked state. The recesses (32) are located at the root and
extend into the male component's (11) core between adjacent thread rotations of the recess
locking thread (31).
Figure 4B is a side view of adjacent rotations of an alternative embodiment of the present invention in an assembled and unlocked state where the projections of the internal
flexible thread segment press axially against the recesses of the male thread. In the embodiment shown, the recesses (32) and the projections are on the following flanks. In
alternative embodiments they can be on the leading flanks.
While the present invention has been described with reference to certain preferred
embodiments, those skilled in the art will recognize that various modifications may be provided. For example, there are many other embodiments having a variety of configurations for the shape, angle and size of the projections and recesses. The recesses can be located in the center of the thread flank instead of at or near the root. Instead of
recesses on the external thread, projections on the external thread can be used to mesh with the projections of the flexible thread segment. The flexible thread segment can be more or less than one full rotation. These and other variations upon, and modifications to, the preferred embodiment are provided for by the present invention which is only limited by the following claims..