A need exists for threaded fasteners that can withstand vibration cycling with minimum loss of clamping force, i.e., axial load. It is also desirable to provide a fastener having a removal torque that matches or exceeds an installation torque. Such a fastener reduces the effects of tampering.
Known self-locking fasteners that inhibit removal of a tightened nut from a threaded bolt allow the bolt to be rotated as much as 40 degrees before the nut engages so that it no longer rotates. It has been found that a ⅜″ diameter bolt with 16 threads per inch that secures two ½″ plates, so that the length of the bolt under a clamp load is 1″, loses two-thirds of its load on the plates when rotated about 12 degrees in an untightening direction. With the known self-locking fasteners, the bolt and nut may still be retaining the plates after the nut has been rotated 40 degrees in the untightening direction; however, the bolt has lost its load and no longer retains the plates tightly.
Other self-locking fastener assemblies use teeth that engage one another to limit rotational movement of the nut with respect to the bolt. The bolt engages a locking ring that has a plurality of teeth formed on a face that is normal to the longitudinal axis of the bolt. A nut that is threaded onto the bolt also includes a face having a plurality of teeth that engage the teeth of the locking ring. In known assemblies, however, the teeth in the locking ring and the teeth on the bolt are disposed at a positive rake angle in the untightening direction and in the tightening direction. That is, the apex of each tooth follows the point where the base joins the face for each tooth in both the tightening and the untightening rotational direction. Such a configuration allows the teeth of the nut to ramp over the teeth of the locking ring when one attempts to remove the nut. Such movement is undesirable.
A fastener assembly includes a threaded bolt and a locking nut assembly. The threaded bolt includes at least one longitudinal groove. The locking nut assembly includes a nut adapted to threadingly engage the bolt, a locking ring adapted to engage the bolt and the nut, and a biasing member adapted to bias the locking ring. The nut includes a threaded bore dimensioned to receive the bolt and a plurality of teeth formed on a face of the nut. The locking ring includes at least one inwardly protruding tab dimensioned to be received by the at least one longitudinal groove of the threaded bolt and a plurality of teeth formed on a face of the ring. The teeth on the face of the locking ring cooperate with the teeth on the face of the nut to inhibit removal of the nut from the bolt after the nut has been tightened.
A method for manufacturing a locking nut assembly includes the following steps: providing powdered metal into a nut mold; forming a nut; sintering the nut; providing powdered metal into a locking ring mold; forming a locking ring; and sintering the locking ring. The nut and the locking ring manufactured using this method can be similar to those described above.
A fastener assembly can also include a bolt, a biasing member, a first ring, and a locking ring. The bolt can be similar to the bolt described above. The biasing member can be similar to the biasing member described above. The first ring is also adapted to receive the bolt and has a peripheral edge that is not symmetrical about a rotational axis of the bolt. The first ring is received between the head of the bolt and the biasing member. The first ring includes at least two teeth formed on a face. The locking ring can be similar to the locking ring described above. The locking ring and the first ring cooperate with one another in a manner similar to the nut and the locking ring, which is described above.
With reference to
The nut locking assembly 12 shown in
The interlocking ring 26 includes a central opening 42 that is dimensioned to receive the bolt 10 (
The biasing member 28 includes outwardly extending fingers 52 that extend radially from a peripheral edge 54 of the biasing member 28. In the embodiment depicted, the biasing member 28 is made of an elastomeric material, such as Viton, FEP, or Santoprene®. The biasing member 28 can be dimensioned to snugly fit inside the counterbore 34 (
The self-locking characteristics of the fastener assembly will be described in more detail. The nut locking assembly 12 is threaded onto the bolt 10 with the item to be fastened interposed between the shoulder 56 of the nut 24 and the head 18 of the bolt 10 (
Each tooth 36 and 46 has a negative rake in the untightening direction, which is explained below, to form a negative rake angle α, which can be between 0°-90°, and preferably between 1°-10°. Even though the teeth 36 and 46 are depicted as having the same configurations and dimensions, the teeth 36 on the nut 24 can be shaped differently than the teeth 46 on the interlocking ring 26 and can even have a different rake angle. Providing teeth having different configurations, e.g. different rake angles, can provide relief for any debris that may gather around the teeth that might inhibit the teeth from engaging one another. As the bolt 10 is tightened, the interlocking ring 26 is rotated in a tightening rotational direction (arrow A). An apex 64, which is the outermost point of the tooth 46, follows behind a corresponding root 66, which is a point where a trailing edge 68 of the tooth intersects the face 44 of the interlocking ring 26. Likewise, as the nut 24 is tightened an apex 72 of each tooth 36 on the nut 24 follows a root 74 of the corresponding tooth 36 of a trailing edge 76 (arrow B). Each tooth 46 of the interlocking ring 26 also includes an inclined leading surface 78 and likewise each tooth 36 of the nut 24 also includes an incline leading surface 82. The biasing member 28 allows the interlocking ring 26 to rotate freely in the tightening direction without displacing material in the ring 26 or the nut 24. The interlocking ring 26 will move axially along the bolt 10 as the inclined leading surface 78 of each tooth 46 of the interlocking ring rides along the inclined surface 82 of each tooth 36 of the nut 24. After each tooth rides over a corresponding tooth, the biasing member 28 provides a constant seating pressure on the interlocking ring 26.
With reference to
The forces on the trailing edge of each tooth encourage further seating of the interlocking ring and the nut. Since the teeth are formed having a negative rake, the vector component of the force on the trailing edge that is parallel to the trailing edge points downward toward the root of the tooth because the sine of a negative angle is negative.
The removal torque of the fastener assembly can be tuned through multiple methods. A first tuning method removes some of the teeth on either the locking ring or the nut. The second method is by adjusting the total shear area of the teeth.
Due to the fact that the removal torque acts on each tooth individually, the torque can be converted into a shear force that acts on a cross-sectional area of where each tooth contacts its adjoining surface, i.e. the shear force area. For the teeth on the locking ring 26, the shear force area is the area where each tooth 36 contacts the face 48. For the teeth on the nut 24, the shear force area is the area where each tooth 36 contacts the recessed face 38.
Torque is defined by the following equation: T=F×D, where:
Because the force acting on each tooth is spread across its length, which is measured along the radius of the nut 24 or the interlocking ring 26, it can be assumed that the force acts at the center of each tooth. This causes the distance of the torque reaction to occur between the revolving axis of the nut or ring and the center of each tooth.
To determine the removal torque of a given tooth pattern, the following variables must be known:
First the maximum shear force, Fmax, is determined by the following equation:
Fmax=Nt[G(LW)]
The maximum removal torque, Tmax, can then be calculated with:
Tmax=Fmax×D
The number of teeth 36 formed on the nut 24 and the number of teeth 46 formed on the interlocking ring 26, which is controlled by the pitch, i.e. the distance between the leading edges of adjacent teeth (or the distance between the trailing edges of adjacent teeth) which is measured in degrees or radians, controls the amount of movement in the untightening rotational direction before the teeth engage one another. The greater the number of teeth either on the interlocking ring 26 or the nut 24, i.e. the smaller the pitch, the lesser the amount of rotation is allowed in the untightening rotational direction. Furthermore, the greater the number of teeth that engage one another, the more surface area is provided to counteract rotational movement in an untightening rotational direction. Accordingly, less shear force is exerted on each tooth. In the depicted embodiments, approximately forty teeth 36 are formed in the nut 24 and approximately fifty teeth 46 are formed on the interlocking ring 26, and the number of teeth may likely be a function of the diameter of the bolt 10 that is to be received by the locking nut assembly 12.
In the depicted embodiment, the pitch measures six degrees; however, the pitch can be up to about 10 degrees. For the depicted embodiment, six degrees of rotational movement in the untightenting direction is allowed before the teeth fully engage one another. A small pitch results in the bolt 12 still carrying its tensile load after one has attempted to remove the nut 24 from the bolt 12. The pitch can be lessened, especially for larger diameter fastener assemblies to allow for even less rotational movement in the untightening direction.
The components of the fastener assembly can be made from a number of different manufacturing processes. Two of these processes will be described in more detail. The nut 24 and the interlocking ring 26 can be made using a powdered metal process or a metal injection molding process. By making the nut and the interlocking ring using either of these processes, the negative rake angle for the teeth can be achieved with significantly less manufacturing costs than other known processes. For example, machining a negative rake angle would require a special cutter that is shaped like the gap between adjacent teeth (either tooth 36 or 46). Each tooth would have to be individually machined and would require the use of a special indexer and a special cutter.
For both the powdered metal process and the metal injection molding process, a powdered metal is placed into a mold, either a nut mold or an interlocking ring mold. More specifically for the metal injection molding process, a binder is typically added to the powdered metal that is placed in the mold so that the metal flows similar to a plastic injection molding process. The powdered metal and/or powdered metal and binder mixture is then compressed while restricted in the mold to form a green nut or interlocking ring. The powdered metal is then sintered below the melting point of the particular metal or alloy. The sintered nut or interlocking ring is then sized to form the corresponding teeth. In such an operation, the root of each tooth is supported while a force is applied at or near the apex of each tooth to form the negative rake angle. After the sizing operation, the sintered nut or interlocking ring is again heat treated for improved strength and hardness.
With reference to
The locking ring 26, which has been described above, can be used with the insert ring 84. Also, a biasing member 96 similar to the biasing member 28 described with reference to
The eccentric peripheral edge 90 of the insert ring 84 and the eccentric configuration of the counterbore 92 inhibits or prohibits rotation of the insert ring 84 inside the counterbore 92 as the bolt is tightened into the threaded receptacle 94. The teeth 46 of the interlocking ring 26 and the teeth 86 of the insert ring 84 cooperate with one another similar to the nut locking assembly described with reference to
As seen in
With reference to
The pin holder 116 includes a central opening 134 that is dimensioned to receive the threaded boss 124 so that the pin holder 116 is seated inside the circular channel 126. The pin holder 116 includes a plurality of axially aligned pin openings 136 that are dimensioned to receive the pins 122. Each pin 122 includes an appropriately shaped shank 138 for receipt by the pin openings 136 and a head 142 at one end of the shank. The pin openings 136 and the pin holder 116 can include a counterbore (not visible) so that the head 142 is countersunk into the pin holder 116.
The retainer ring 118 includes a central opening 144 that is dimensioned to fit around the pins 138, as more clearly seen in
With reference back to
With reference to
Internal components of the removal tool 150 are housed in the socket 152. With reference to
A pin base holder 184 supports the base of each pin 168. The pin base holder 184 includes a plurality of openings 186 dimensioned to receive the pins 168. The base pin holder 184 also includes a hexagonal peripheral edge 188 having two notches 192 that are diametrically opposed from one another and aligned with the ears 178 of the movable pin support 172. The base pin holder 184 serves a similar function as the pin holder 116 disclosed in
A pin base retainer 194 abuts the pin base holder 184 to retain the pins 168 in a similar manner to the pin retainer 114 disclosed with reference to
Outer threaded rods 202 are received by the threaded openings 182 in the movable pin support 172. The outer threaded rods 202 include and/or attach to heads 204 that contact a first shoulder 206 (
A central shoulder screw 212 connects the pin base holder 184 and the pin base retainer 194. A biasing member 214, which has a greater biasing force than the helical springs 208 and the biasing member 28 for the locking nut assembly 14, biases the pin base holder 184 and the pin base retainer 194 from a central socket shoulder 216 (
To remove the nut 24, the removal tool 150 is aligned so that the pins 168 can be received in the axial bores 144 of the nut 24. The socket 152 is then pushed towards the shoulder 56 of the nut 24 and is rotated so that the tabs 160 engage in the L-shaped notches 162 of the nut 24. When the locking ring 156 is engaged with the shoulder 56 of the nut 24, the movable pin support 172 is moved towards the pin base holder 184 and the pins 168 extend from the recessed base 38 of the nut 24 to overcome the biasing member in a similar manner to the removal tool described with reference to
With reference to
A self-locking fastener assembly has been described with reference to specific embodiments. Modifications and alterations will occur to those upon reading and understanding the preceding detailed description. The invention is not limited to only those embodiments described above. Instead, the invention is intended to cover all modifications and alterations that come within the scope of the appended claims and the equivalents thereof.
This application claims the benefit of Provisional Patent Application Ser. No. 60/555,249, filed Mar. 22, 2004 and Provisional Patent Application Ser. No. 60/568,963, filed May 7, 2004, each of which is incorporated by reference herein in its entirety.
Number | Name | Date | Kind |
---|---|---|---|
588346 | Mireault | Aug 1897 | A |
588863 | Harry | Aug 1897 | A |
666065 | Oliver | Jan 1901 | A |
961371 | Posey | Jun 1910 | A |
968171 | Lodge | Aug 1910 | A |
1057209 | Andrews | Mar 1913 | A |
1088253 | Armstrong | Feb 1914 | A |
1166736 | Bailey | Jan 1916 | A |
1246353 | Thigpen | Nov 1917 | A |
1403902 | Fields | Jan 1922 | A |
1509948 | Hall | Sep 1924 | A |
1622581 | Gunkel | Mar 1927 | A |
2152977 | Schindel | Apr 1939 | A |
2966187 | Ter Cock | Dec 1960 | A |
2997090 | Anderson | Aug 1961 | A |
3866878 | Yamamoto | Feb 1975 | A |
4971501 | Chavez | Nov 1990 | A |
6082941 | Dupont et al. | Jul 2000 | A |
6434792 | Williamson | Aug 2002 | B1 |
6976817 | Grainger | Dec 2005 | B1 |
20030152439 | Hartmann et al. | Aug 2003 | A1 |
Number | Date | Country |
---|---|---|
1 026 339 | Apr 1953 | FR |
Number | Date | Country | |
---|---|---|---|
20050207865 A1 | Sep 2005 | US |
Number | Date | Country | |
---|---|---|---|
60568963 | May 2004 | US | |
60555249 | Mar 2004 | US |