In many applications, it may be useful to quickly attach a nut to a threaded object, in order to use the nut and the threaded object to support other structures. For example, it may be useful to attach a nut to a threaded rod to quickly attach to the threaded rod to a structure and/or to suspend a load.
Some embodiments of the invention provide a push-on spring nut for attaching to a threaded object. The push-on spring nut can include a housing and a spring nut insert. The housing can include first and second side walls shaped to form a hollow tube with an internal passageway configured to receive the threaded object. The first and second side walls can each include a window. The spring nut insert can be configured to be inserted into the internal passageway of the housing and can include first and second arms. At least a part of each of the first and second arms can be configured to engage a thread on the threaded object to secure the push-on spring nut to the threaded object, when the threaded object is received in the internal passageway of the housing and between the first and second arms.
The first and second arms can be laterally flexible and can be configured to: upon insertion of the spring nut insert into the internal passageway of the housing in a first direction, flex laterally inwardly and then outwardly to snap in to the windows of the first and second side walls, to secure the spring nut insert within the internal passageway of the housing; and, during non-rotational insertion of the threaded rod into the internal passageway of the housing in the first direction, flex laterally outwardly to allow the threaded rod to pass. The housing can be configured to provide support for the spring nut insert at the first and second arms, during axial loading of the threaded object opposite the first direction, via one or more features of the windows.
Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of “including,” “comprising,” or “having” and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items. Unless specified or limited otherwise, the terms “mounted,” “connected,” “supported,” and “coupled” and variations thereof are used broadly and encompass both direct and indirect mountings, connections, supports, and couplings. Further, “connected” and “coupled” are not restricted to physical or mechanical connections or couplings.
As used herein, unless otherwise specified or limited, the term “axial” (and the like) in the context of push-on spring nuts generally refers to a direction of insertion of a threaded object, such as the axial direction of an elongate threaded rod. Similarly, the term “lateral” (and the like) in the context of push-on spring nuts generally refers to a direction that extends perpendicularly relative to the axial direction. In this regard, lateral directions or movements can include, but are not limited to, radial directions or movements.
The following discussion is presented to enable a person skilled in the art to make and use embodiments of the invention. Various modifications to the illustrated embodiments will be readily apparent to those skilled in the art, and the generic principles herein can be applied to other embodiments and applications without departing from embodiments of the invention. Thus, embodiments of the invention are not intended to be limited to embodiments shown, but are to be accorded the widest scope consistent with the principles and features disclosed herein. The following detailed description is to be read with reference to the figures, in which like elements in different figures have like reference numerals. The figures, which are not necessarily to scale, depict selected embodiments and are not intended to limit the scope of embodiments of the invention. Skilled artisans will recognize the examples provided herein have many useful alternatives and fall within the scope of embodiments of the invention.
In the discussion below, various examples describe push-on spring nuts for attaching to a structure (e.g., a threaded rod) and suspending a load. It will be understood that the attachment to a threaded rod described are presented as examples only and that the disclosed push-on spring nut can he used to attach to other devices, such as threaded fasteners or other threaded objects, or other objects generally.
Some embodiments of the invention can provide push-on spring nuts with improved retention strength as compared to conventional designs. For example, in some embodiments of the invention, resilient arms can include support portions that connect to a spring-nut base, with structure-engagement portions extending laterally outwardly from the support portions. Further, connecting portions can extend at acute angles laterally inwardly from the structure-engagement portions to thread-engagement portions that are configured to engage the thread of a threaded object. Usefully, the laterally outward extension of the structure-engagement portions can position the structure-engagement portions to engage a structure near openings through which the spring nuts are inserted, in order to secure the spring nuts to relevant structures. Additionally, the combined structure of the laterally outwardly extending structure-engagement portions and the laterally inwardly extending connecting portions can contribute to a favorable balance of forces upon axial loading of a threaded object held by a spring nut according to the invention, which can result in increasingly firm attachment of the spring nut to the threaded object as the loading on the threaded object increases.
In some embodiments, arms of a spring-nut body, such as described above, can be formed as continuous features, without discrete, free-ended projections. For example, an arm of a spring-nut body can extend continuously from a spring-nut base along a support portion, then along a connecting portion, then along a thread-engagement portion to a free end configured to engage the thread of a threaded object. This may be useful, for example, in order to simplify manufacturing of the relevant spring nut, while also potentially increasing the spring nut for a given material thickness.
In some embodiments, push-on spring nuts according to the invention can include spring-nut inserts configured as single-piece spring-nut bodies (e.g., as discussed above) and separate housings, with the housings configured to receive the spring-nut inserts and secure the spring-nut inserts (and the assembly in general) to a structure. In some embodiments, push-on spring nuts according to the invention can include single-piece spring-nut bodies that are configure for installation directly onto a structure, without the need for a separate housing.
The push-on spring nut 100 generally includes a housing 102 and a spring-nut insert 104 that is configured to be inserted into and secured within the housing 102. In some embodiments, the housing 102 can be unitarily formed from a single piece of material. In some embodiments, the housing 102 can be fabricated from a metal material (e.g., mild steel or spring steel).
In the embodiment illustrated, the housing 102 includes a base 106, a first side wall 108 and a second side wail 110, and defines a generally central axis 112, along which a central passage 102a extends axially through the housing 102 (e.g., generally vertically, from the perspective of
In the illustrated embodiment of
Generally, the first and second side walls 108, 110 are shaped to form the housing 102 into a hollow, generally rectangular tube-like structure, which defines the passage 102a and is capable of receiving the spring nut insert 104, as also described below. In other embodiments, for example, a housing for a spring nut may define a round, curved, polygonal, or other shape.
In the illustrated embodiment of the housing 102, a slot 118 extends axially along the housing 102 from the first end 114 to the second end 116. The slot 118 is generally formed between free ends of the first and second side walls 108, 110 (e.g., the ends of the first and second side wails 108, 110 not attached to the base 106). The slot 118 can, for example, allow the first and second side walls 108, 110 to flex somewhat independently of one another and/or with respect to the base 106.
Generally, the first and second side walls 108, 110 each include a window 120 disposed between the first end 114 and the second end 116. Each of the windows 120 defines a lateral cutout in the associated first or second side wall 108, 110, which generally extends axially along the respective side wall 108, 110. As also described below, the windows 120 can receive parts of the spring nut insert 104 within the housing 102, and can provide support for the spring nut insert 104 when a load is applied to the spring nut insert 104 (e.g., via a threaded rod).
In some embodiments, the housing 102 can be tapered internally, so that a size of the opening near the first end 114 is larger than a size of the opening near the second end 116. This taper can, for example, aid in manufacturing of the push-on spring nut 100, while also assisting in the insertion of a threaded rod through the housing 102. For example, due to the taper, a threaded rod or spring-nut insert can he relatively easily inserted into the first end 114, while the smaller size at the second end 116 can provide a somewhat restricted transition passage that provides additional support for a threaded rod extending therethrough.
Generally, a housing according to the invention can include any number or different configurations of structures to assist in securing the housing to other objects, such as building support structures. In the illustrated embodiment of
Generally, as also discussed below, the spring nut insert 104 is configured to be received and retained by the housing 102. Accordingly, for example, the spring nut insert 104 includes a pair of opposing arms 124 that are designed to he resiliently flexible (e.g., in axial and/or lateral directions). In some embodiments, the arms 124 can be flexible enough to allow a threaded rod to pass therethrough in one direction without the threaded rod rotating, yet can be sufficiently resilient to return to firmly engage the threaded rod and to provide sufficient strength to resist movement of the threaded rod, without buckling, when the threaded rod is loaded in an opposite direction.
In some embodiments, the flexibility and elastic resiliency of the arms 124 enables the push-on spring nut 100 to provide a restorative action, or pre-bias, during insertion of a threaded rod. For example, the arms 124 can flex laterally outwardly as a crest of a thread of a threaded rod being inserted through the spring nut 100 passes between free ends of the arms 124. For example, the arms 124 can flex in a direction extending generally perpendicular to the central axis 112 through the respective side walls 108, 110. Further, restorative action due to the resiliency of the arms 124 can subsequently return (and further bias) the arms 124 laterally inwardly (e.g., toward the central axis 112 along respective lateral directions) and into gripping engagement with the threaded rod between the passed crest and a subsequent crest of the thread.
In some embodiments, a portion of the arms of a spring nut insert can be configured to extend outside of a housing (e.g., outside of a window of the housing) while the remainder of the spring nut insert, including thread-engagement portions of the arms, are disposed within the housing. In the embodiment illustrated in
Accordingly, with the spring nut 100 assembled as shown, the arms 124 initially curve laterally outward past a lower edge 132 of the respective window 120, and then angle laterally inwardly and axially upward at the junction between the housing support portions 126 and the connecting portions 128. From these junctions, the connecting portions 128 each extend axially toward the second end 116 of the housing 102 and laterally inwardly toward the central axis 112 at an angle between zero and ninety degrees relative to the central axis 112. In other embodiments, other configurations are possible. For example, whereas the connecting portions 128 are generally planar, connecting portion in some embodiments can extend inwardly with a curved or other non-planar profile.
The thread-engaging portions 130 extend from junctions with the connecting portions 128 of the arms 124, within the internal passage 102a of the housing 102 as installed, and are generally designed to cooperate to engage and secure a threaded rod that has been inserted through the housing 102 and between threaded portions 130. Accordingly, for example, the thread-engaging portions 130 can be arranged along a generally helix-like path to conform to a standard thread type on a threaded rod.
In some embodiments, as also discussed below, the thread-engaging portions 130 can exhibit a compound geometry. For example, a first portion of each of the thread-engaging portions 130 can exhibit a first geometry (e.g., as corresponds to a first projected angle of a thread) and a second portion of each of the thread-engaging portions 130 can exhibit a second geometry (e.g., as corresponds to a second projected angle of the thread).
In some embodiments, the spring nut insert 104 can be fabricated from a unitary piece of metal material. For example, the spring nut insert 104 can be stamped from spring steel or other material in a progressive die operation. In this regard, for example, the push-on spring nut 100 can sometimes be formed as two stamped pieces, of spring steel or other material. In other embodiments, other configurations, manufacturing approaches, and materials may be used.
In some implementations, to assemble the push-on spring nut 100, the spring nut insert 104 can be axially inserted, into the first end 114 of the housing 102. In some configurations, including for the configuration illustrated in
Because the housing support portions 126 of the arms 124 are dimensioned to extend laterally past the side walls 108, 110, the connecting portions 128 can be urged into contact with ends of the side walls 108, 110 as the insert 104 is inserted. As a result, for example, as aided by the angled aspect of the angled portion 128, the arms 124 can be caused to flex laterally inwardly during the initial axial insertion of the spring nut insert 104 into the housing 102. Once the spring nut insert 104 is inserted axially far enough into the housing 102, so that that the housing support portions 126 of the arms 124 are aligned with the windows 120, the arms 124 can then resiliently spring laterally outwardly away from the central axis 112, to snap into engagement with the windows 120. In particular, in the embodiment illustrated, the housing support portions 126 can snap over the lower edges 132 of the windows 120, with the lower edges 132 of the windows thereby retaining the spring nut insert 104 within the housing 102 against axial withdrawal in the downward direction (e.g., from the perspective of
In some embodiments, the above-described snap-in assembly of the push-on spring nut 100 can enable relatively quick assembly and installation of the push-on nut spring nut 100. Further, the illustrated two-piece configuration, and other configurations, can allow for relatively efficient manufacturing of the push-on nut spring nut 100. In some embodiments, an insert can be inserted from an opposite side of a housing. For example, the insert 104 can be inserted axially downwardly from the perspective of
As illustrated in
As illustrated in
As illustrated in
In some embodiments, as illustrated in
As also discussed below, due to the engagement between the housing support portions 126 and the lower edges 132 occurring at a location that is laterally outward from the engagement of the tread-engaging portions 130 with the thread of the threaded rod 134, loading of the threaded rod 134 can generate a reaction moment that generally urges the arms 124 and, in particular, the thread-engaging portions 130, into tighter engagement with the thread of the threaded rod 134. This can generally contribute to the thread-engaging portions 130 being firmly retained in engagement with the thread of the threaded rod 134 and can help to resist, for example, laterally outward forces generated from the angled interaction with the thread on the threaded rod 134. Indeed, with appropriate design (e.g., as illustrated for the spring nut 100), increases in loading on the threaded rod 134 can tend to increase the gripping force of the engagement of the spring nut 100 with the threaded rod 134.
As illustrated in
In the embodiment illustrated, the first arm 224a is formed integrally with and extends a side of the insert base 202, via a first straight-walled support portion 218a. The first arm 224a also includes a first retaining flange 214a that extends laterally outward away from the central axis 212 from the first support portion 218a at a first end 216a of the insert first arm 224a. The first retaining flange 214a is configured to extend laterally past the first end 114 of the housing 102 (see, e.g.,
As noted above, the first arm 224a includes the support portion 218a, which is arranged substantially perpendicular to the first retaining flange 214 and extends axially between the first retaining flange 214a and a support and thread-engaging end of the first arm 224a. In particular, for example, the first arm 224a generally includes a first structure-engagement portion configured as a first housing support portion 226a that extends from the support portion 218a. The first arm 224a also includes a first angled connecting portion 228a extending from the first housing support portion 226a opposite the support portion 218a, and a first thread-engaging end 230a extending from the first connecting portion 228a opposite the housing support portion 226a. Accordingly, in the embodiment illustrated, the first housing support portion 226a defines a generally S-shaped profile that extends laterally outward at an approximately 90-degree junction between the first housing support portion 226a and the first straight-walled support portion 218a, and then laterally inward and axially upward at an acutely angled junction between the first housing support portion 226a and the first connecting portion 228a.
Correspondingly, in the embodiment illustrated, the first connecting portion 228a extends axially away from the first insert end 216a and laterally inward toward the central axis 212 at an angle between zero and ninety degrees defined between the first connecting portion 228a and the central axis 212. The first thread-engaging end 230a then extends laterally inwardly from the first connecting portion 228a, from a junction that is opposite the junction between the first connection portion 228a and the first housing support portion and in substantial axial alignment with the junction between the first housing support portion 226a and the first straight-walled support portion 218a (see, e.g.,
With the spring nut insert 200 inserted into the housing 102, the first housing support portion 226a is generally dimensioned to extend laterally outward past the lower edge 132 of the window 120. Thus, when assembled, the spring nut insert 200 can be axially secured within the housing 102 by engagement between the housing 102 and the first and second retaining flanges 214a and 214b, and between the housing 102 and the first and second housing support portions 226a and 226b.
In operation, opposite thread-engaging portions of a spring nut can be configured to engage opposite sides of a threaded object. For example, the first thread-engaging end 230a is configured to engage one side of a threaded rod (not shown in
In some embodiments, thread-engaging portions of a spring nut can be contoured to provide improved engagement with a thread of a threaded object. For example, in the embodiment illustrated in
As another example, as illustrated in
Generally, the first curved edge 238a can be configured for secure engagement with any variety of threads on a threaded rod. For example, the first curved edge 238a generally defines a radius of curvature that is designed to match a radius of curvature of a root of a thread on a standard threaded rod. Similarly, the first curved edge 238a is tapered to narrow from a perspective moving radially inwardly towards the central axis 212, in order to better engage a thread. Accordingly, for example, the first curved edge 238a can define a minimum thickness at a distal end thereof, as may be useful for penetration of the first curved edge 238a towards the root of a thread, between adjacent thread crests.
In some embodiments, implementing a tapered configuration on the first curved edge 238a can allow a relatively large material thickness to be used for the first arm 224a, which can provide additional general strength against buckling or other structural failure. In some embodiments, the tapered configuration of the first curved edge 238a can also provide structural advantages for engaging with a thread of a threaded rod. For example, as also noted above, the thinner end of the first curved edge 238a may generally enable the first curved edge 238a to engage a thread of a threaded rod closer to the root of the thread. Because the greatest amount of material on a thread to support a load is generally close to the root of a thread, tapering the first curved edge 238a to facilitate engagement of the first curved edge 238a at or near the root can allow the first curved edge 238a to engage the thread at an area of relatively thick material, thereby generally increasing a relevant thread shear area and stripping load.
In some embodiments, thread-engaging portions of a spring nut can exhibit other useful configurations, including compound angular profiles. In the embodiment illustrated, for example, the first thread-engaging end 230a defines a compound angled profile (e.g., as projected with respect to a central plane oriented perpendicularly to the central axis 212). In particular, the first thread-engaging end 230a includes a transition point disposed between the first leading edge 234a and the first trailing edge 236a, with different angular profiles on opposite sides of the transition point.
In some embodiments, one or more of the angular profiles on either side of the transition point can exhibit angles chosen to compromise between a helix angle of a thread on a threaded rod and a projected angle of a more interior point on the thread. In some embodiments, different angles on either side of the transition point can he selected from a projected angle corresponding to thread angles at the root diameter of a thread on a threaded rod, at a pitch diameter of the thread, at a major diameter of the thread, or otherwise. In the embodiment illustrated, for example, the side of the transition point closer to the first leading edge 234a approximates a projected angle relative to the pitch diameter of a relevant thread, and the side of the transition point closer to the first trailing edge 236a approximates a projected angle relative to the root of the thread. This may be a useful configuration, for example, in order to promote maximum engagement between a thread of a threaded rod and the first thread-engaging end 230a. In other embodiments, other configurations are possible. For example, the side of the transition point closer to the trailing edge 236a can exhibit an angle that is between those noted immediately above.
In some embodiments, different thread-engaging portions of a particular spring nut can be configured differently. For example, as illustrated in
When receiving a threaded rod, the general design of the spring nut insert 200 and, in particular, the angled configuration of the first and second thread-engaging ends 230a and 230b (as also discussed above), can help to compensate for differences in a projected thread angle between a thread lean-in and a projected thread angle at other locations along a thread (e.g., at a minor diameter, at a major diameter, and at a pitch diameter). In this way, for example, when a threaded rod is unloaded, the first and second leading edges 234a and 234b can be oriented somewhat askew from a thread on the threaded rod, which can allow a threaded rod to easily push through the first and second thread-engaging ends 230a and 230b (e.g., in an upward axial direction, from the illustrated perspective). Once a threaded rod is inserted and loaded, however, the first and second leading edges 234a and 234b can be deformed somewhat from their resting orientation, to be drawn into closer engagement with a thread on the threaded rod. In this regard, for example, selecting a leading-edge angle that is between the projected angles of a root diameter and a major diameter, but slightly closer to the projected angle at the root diameter, can help to bring the first and second thread-engaging ends 230a and 230b into optimal engagement with the relevant thread.
In some embodiments, other aspects of the configuration of the arms of a spring nut according to an invention can also provide improved retention with a threaded object. In some embodiments, for example, extension of a support portion of an arm laterally outwardly and extension of a connecting portion acutely inwardly from the support portion can contribute to a beneficial balance of forces upon loading of a threaded object. In the embodiment illustrated, for example, once a threaded rod that is engaged with the spring nut insert 200 is loaded, the design of the spring nut insert 200 can generally result in a balance of forces and moments that tends to bring the first and second thread-engaging ends 230a and 230b into tighter engagement with a thread in correlation with the load applied to a threaded rod. For example, as illustrated in.
Notably, because the reaction three 250 is applied to the housing support portion 226b at a location that is laterally outside of the walled support portion 218b and the thread-engaging end 230b and, thereby, is laterally outwardly offset from the vertical force 248, a first moment is induced on the second arm 224b. A second moment in an opposite direction is also induced on the second arm 224b from a horizontal component 252 of a force generated from the angled interaction of a thread of the threaded rod with the thread-engaging end 230b. With appropriate configuration with regard to the lateral positioning of the contact between the second arm 224b and the relevant housing or other support structure (e.g., as illustrated), the first moment can generally be greater in magnitude than the second moment. Accordingly, a net moment 254 can result, which can generally urge the second thread-engaging end 230b into tighter engagement with a thread as a threaded rod is increasingly loaded. In this way, for example, the more a threaded rod is loaded, the more strongly the second arm 224b is urged into engagement with the rod and the more strongly the spring nut 200 retains the rod against the load.
Similar considerations as those discussed above for the second arm 224b also apply to the first arm 224a. For simplicity of presentation, such discussion is not repeated and relevant forces and moments are not illustrated for the first arm 224a in
Similarly to the spring nut insert 200, the spring nut insert 300 includes an insert base 302, and opposing arms 324a, 324b, and defines a central axis 312 (see
Generally, the first and second arms 324a, 324b are configured similarly to the first and second arms 224a, 224b (see, e.g.,
As also noted above, spring-nut inserts according to embodiments of the invention can be used with a variety of different housings and other support structures. For example, as discussed above, in some embodiments, any of the inserts 104, 200, 300 can be used with the housing 102 of
In contrast to the housing 102, a clip 362 at one end of the housing 350 extends from the base 352 laterally across the central passage 350a. In the illustrated configuration, the clip 362 extends from the base 352 to define a gap 364 between the clip 362 and the side walls 354, 356, with pointed engagement tabs 368 extending into the gap 364 towards the side walls 354. In some arrangements, a structure (not shown) such as a conduit clamp can be inserted into the gap 364, to be engaged by the tabs 368, so that the clip 362 secures the housing 350 to the structure. A threaded object, such as a threaded rod, can then be inserted into the housing 350 and the relevant insert (not shown in
Some embodiments of the invention can be configured to be used with or without housings. Similarly, some embodiments of the invention can be configured to include single-piece spring nut bodies that directly engage a structure to attach a threaded object (e.g., rather than engaging the structure via a housing). For example.
Generally, the spring nut 400 is configured similarly to the spring nut inserts 104, 200, 300, and corresponding components between the spring nut 400 and the spring nut inserts 104, 200, 300 are generally identified in
Similarly to the spring nut inserts 200, 300, the spring nut 400 includes an insert base 402, and opposing arms 424a, 424b, and defines a central axis 412 (see
Generally, the first and second arms 424a, 424b are configured similarly to the arms 224a, 224b (see, e.g.,
In some aspects, however, the arms 424a, 424b differ from the arms 224a, 224b and the arms 324a, 324b. For example, in contrast to the arms 224a, 224b and the arms 324a, 324b, the support portions 418a, 418b of the arms 424a, 424b are relatively short, as compared to the overall axial length of the spring nut 400. This may be useful, for example, to configure the spring nut 400 for direct engagement with a structure, as also discussed below.
Also in contrast to the spring nut inserts 200, 300, a base 402 of the spring nut 400 extends perpendicularly to the central axis 412, to connect axial ends 416a, 416b of the arms 424a, 424b at an axial end of the spring nut 400. Correspondingly, an aperture 404 through the base 402 is axially aligned with curved edges 438a, 438b of the arms 424a, 424b so that, for example, a threaded rod can be inserted axially through the aperture 404 and between the curved edges 438a, 438b. Further, the base 402 includes opposing tabs 406, which extend outside of the axially projected envelope of the arms 424a, 424b.
In some embodiments, the aperture 404 can provide radial support for a threaded object inserted therethrough. For example, a radius of the aperture 404 can be sized to be relatively close to an expected radius of a relevant threaded object, so that the aperture 404 can usefully restrict radial movement of the object once the object is inserted therethrough. In some embodiments, the aperture 404 can he surrounded by a raised feature, such as an extruded, non-threaded annular flange (not shown in
As also noted above, in some configurations, the spring nut 400 can be installed directly onto a structure, in order to secure a threaded object to the structure. As illustrated in
In the illustrated configuration, however, rather than the arms 424a, 424b springing resiliently outwardly upon alignment with windows on a housing, the arms 424a, 424b spring resiliently outwardly upon clearing the aperture 446, so that the structure-engagement portions 426a, 426b are disposed to directly engage the racking angle 444 on a support side 444a thereof (see, e.g.,
In other embodiments, other configurations are possible. For example,
Generally, the spring nut 500 is configured similarly to the spring nut inserts 104, 200, 300 and the spring nut 400, and corresponding components between the spring nut 500 and the spring nut inserts 104, 200, 300 and the spring nut 400 are generally identified in
Similarly to the spring nut inserts 200, 300 and the spring nut 400, the spring nut 500 includes an insert base 502, and opposing arms 524a, 524b, and defines a central axis 512 (see
Generally, the first and second arms 524a, 524b are configured similarly to the arms 224a, 224b (see, e.g.,
In the embodiment illustrated, the arms 524a, 524b do not include internal slots similar to the slots 440a, 440b (see, e.g.,
In the illustrated embodiment, the spring nut 500 also differs from the spring nut 400 in other ways. For example, similarly to the spring nut 400, the spring nut 500 includes a base 502 that extends perpendicularly to the central axis 512, to connect axial ends 516a, 516b of the arms 524a, 524b at an axial end of the spring nut 500. Correspondingly, an aperture 504 through the base 502 is axially aligned with curved edges 538a, 538b of the arms 524a, 524b so that, for example, a threaded rod can be inserted axially through the aperture 504 and between the curved edges 538a, 538b. Further, the base 502 includes opposing tabs 506, which extend outside of the axially projected envelope of the arms 524a, 524b. In contrast to the spring nut 400, however, each of the tabs 506 includes a set of opposing legs 508 that extend laterally substantially beyond the arms 524a, 524b.
As also noted above, in some configurations, the spring nut 500 can be installed directly onto a structure, in order to secure a threaded object to the structure. As illustrated in
In some configurations, the spring nut 500 can also be installed directly onto other structures. As illustrated in
In this way, for example, the structure-engagement portions 526a, 526b and the tabs 506 can cooperate to secure the spring nut 500 within the channel 554. In this regard, for example, the relatively short length of the support portions 518a, 518b can help to minimize axial movement of the spring nut 500 relative to the strut 550, once the spring nut 500 is fully installed. Further, with the spring nut 500 thus secured, the arms 524a, 524b may still be free to flex resiliently (e.g., at the junction between the structure-engagement portions 526a, 526b and the connecting portions 528a, 528b) in order to receive and secure a threaded object (not shown in
As another example,
In some aspects, however, the spring nut 600 differs from the spring nut 500. For example, an aperture 604 in a base 602 of the spring nut 600 is surround by a raised feature configured as an extruded, non-threaded annular flange 610 that extends integrally from the base 602. Generally, the flange 610 can provide radial support for a threaded object extending through the aperture 604, such as a threaded rod (not shown in
In discuss above, certain embodiments exhibit features that are different from features of other embodiments. Generally, features described with respect to one embodiment above can be interchanged with features of other embodiments, or added as supplemental features to other embodiments. For example, a raised support feature similar to the flange 610 (see
Thus, embodiments of the invention provide a push-on spring nut for attached to a threaded object. The improved push-on spring nut can provide increased ease and safety of installation. Further, some embodiments of the invention provide a push-on spring nut including a housing and a spring nut insert, or a different single-piece body, each of which can be manufactured, respectively, from single pieces of stamped spring steel or metal. In some configurations, this can substantially simplify required manufacturing by reducing the need for secondary machining and assembly processes.
It will be appreciated by those skilled in the art that while the invention has been described above in connection with particular embodiments and examples, the invention is not necessarily so limited, and that numerous other embodiments, examples, uses, modifications and departures from the embodiments, examples and uses are intended to be encompassed by the claims attached hereto. The entire disclosure of each patent and publication cited herein is incorporated by reference, as if each such patent or publication were individually incorporated by reference herein.
Various features and advantages of the invention are set forth in the following claims.
This application claims priority to U.S. Provisional Patent Application No. 62/509,478, titled “Push-On Spring Nut” and filed on May 22, 2017, the entirety of which is incorporated herein by reference.
Number | Date | Country | |
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62509478 | May 2017 | US |