JP3150631U - Locking nut - Google Patents

Abstract

There is provided a nut having a function of surely preventing loosening while the tightening torque can be made constant accurately. A first nut body 2 having a screw hole 21 at a central portion and a second nut body 3 having a screw hole at a central portion, and a lower portion of the first nut body 2 with respect to the center of the screw hole 21. A circular eccentric portion 22 is formed to be eccentric and projecting, and a positioning and fracture protrusion 23 that projects when a predetermined tightening torque is applied to the lower portion of the eccentric portion 22. A circular recessed portion 32 in which the eccentric portion 22 can be fitted is formed on the upper surface of the second nut body 3 with respect to the center of the screw hole, and the protrusion 23 is inserted into the bottom surface of the recessed portion 32 to allow the insertion. An engagement hole 33 for integrally connecting the two nut 3 and the first nut body 2 so as to be usable as one nut is provided. [Selection] Figure 1

Description

  The present invention relates to a locking nut having a locking function while maintaining a constant tightening torque.

Conventionally, as a nut for achieving a constant tightening torque, for example, a cylindrical fracture portion having a constant thickness by providing inner and outer annular grooves on the outer peripheral surface and the inner peripheral surface in an intermediate portion of a nut body having a screw hole. Is formed, and the strength of the rupture portion is set such that the rupture portion is ruptured when a predetermined tightening torque is applied to the rupture portion.
JP-B 47-43429

  However, the conventional nut fracture structure described above has a problem that the processing of the annular groove on the inner peripheral surface is particularly complicated and cannot be mass-produced. Further, the loosening prevention action also varies depending on the breaking state of the broken portion.

  Accordingly, an object of the present invention is to provide a locking nut that has a reliable locking function while being able to accurately fix the tightening torque.

  In order to solve the above problem, the present invention comprises a first nut body having a first screw hole in the center and a second nut body having a second screw hole in the center, and is formed at the lower portion of the first nut body. A circular eccentric portion is formed so as to be eccentric with respect to the center of the first screw hole, and a circular shape in which the eccentric portion can be fitted to the upper surface of the second nut body with respect to the center of the second screw hole. A recessed portion is formed, and the eccentric portion is inserted into the recessed portion. On the other hand, the center of the first and second screw holes is normally maintained between the recessed portion and the eccentric portion. The first and second nut bodies can be used as a single nut, and the concave portion and the eccentric portion are integrated, and a coupling means is provided to cancel the integration when a predetermined tightening torque is applied between the two. It is characterized by being.

  Further, in the invention according to claim 2 of the present application, as a coupling means in claim 1, a positioning and breaking projection is provided on the lower part of the eccentric portion of the first nut body, while the recessed portion in the second nut body is provided. An engaging hole is formed on the bottom surface of the first member to allow the first nut body and the second nut body to be integrated into a set state that can be used as a single nut. The rupture strength of the projection is set so that the projection ruptures with respect to the eccentric portion when a predetermined tightening torque is applied. After the projection ruptures, the tightening action and the eccentric force by rotation of only one nut body are set. It is configured to prevent loosening by the eccentric action in the radial direction due to the abutment of the recessed portion of the portion against the inner wall.

  Further, in the invention described in claim 3 of the present application, as a coupling means in claim 1, the lower part of the eccentric portion in the first nut body and the bottom surface of the recessed portion in the second nut body are locally welded, and At the time of welding, the rupture strength of the welded part is set so that the welded part breaks when a predetermined tightening torque is applied to the welded part. It is configured to prevent loosening by a tightening action by rotation and a radial eccentric action by abutting the circular recessed part of the eccentric part against the inner wall.

  According to the present invention, with the above-described configuration, for example, when the first nut body is appropriately tightened and tightened with the tightening tool in a state where the second nut body is positioned inside the bolt, When a predetermined tightening torque is applied, the integration of the first and second nut bodies by the coupling means is eliminated, and the second nut body can be securely and accurately tightened with the predetermined tightening torque. In addition, after the integration by the coupling means is canceled, the double nut effect due to the tightening action, that is, the first nut body and the first nut body is rotated by rotating only the first nut body with the second nut body fixed. The close contact effect with the two-nut body is generated, and the eccentric portion abuts against the inner wall of the recessed portion, so that the locking action can be exerted strongly by the eccentric operation in the radial direction.

  In addition, as a coupling means, a positioning and breaking projection is provided below the eccentric portion of the first nut body, while the first nut body is allowed to be inserted into the bottom surface of the recessed portion of the second nut body. An engagement hole that integrates the second nut body into a set state that can be used as one nut is formed, and when the fastening portion is tightened with a predetermined tightening torque, the projection portion is against the eccentric portion. Set the breaking strength of the protrusion so that it breaks, and after the protrusion breaks, the tightening action by rotation of only one nut body and the eccentric action in the radial direction by the abutment of the eccentric part against the inner wall of the recessed part In addition to the above-described effects, it is possible to easily set the breaking strength due to the protrusions, thereby securely and accurately fastening with a predetermined tightening torque. Preferred because the door can be.

  Further, as a coupling means, the lower portion of the eccentric portion of the first nut body and the bottom surface of the recessed portion of the second nut body are locally welded, and a predetermined tightening torque is applied to the weld portion during the welding. Set the rupture strength of the welded part so that the welded part breaks when applied, and after the welded part breaks, the tightening action by rotation of only one nut body and the impact of the eccentric part against the inner wall of the recessed part If it is configured to prevent loosening by the eccentric action in the radial direction due to the above, in addition to the above-described locking prevention effect, it is easy and easy to integrate the two while suppressing the complication of the shape of the first and second nut bodies. This is so good.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  1 to 4 show a locking nut according to the present invention. The nut 1 has a hexagonal columnar first nut body 2 having a screw hole 21 at the center and a screw hole 31 at the center. And a hexagonal second nut body 3 having a planar shape larger than that of the first nut body 2 and having a small thickness. A circular eccentric portion 22 is formed at the lower portion of the first nut body 2 with respect to the center O of the screw hole 21, that is, with the eccentric shaft O ′ as a center, and is positioned and broken at the lower portion of the eccentric portion 22. A plurality of projections 23... 23 are projected (three in the figure). On the other hand, a circular recessed portion 32 into which the eccentric portion 22 can be fitted is formed on the upper surface of the second nut body 3 so as to be eccentric with respect to the center O of the screw hole 31, that is, with respect to the eccentric shaft O ′. There are a plurality of engagement holes 33... 33 that allow the projection 23 to be inserted into the bottom surface of the insertion portion 32 and integrally couple the second nut body 3 and the first nut body 2 into a set state that can be used as one nut. Is formed.

  When fastening using the locking nut 1 in which the first and second nut bodies 2 and 3 are integrated, when the predetermined tightening torque is applied to the protrusions 33... 33, the protrusions 23. In contrast, the breaking strength of the projections 23... 23 is set so as to break. As a result, after the protrusions 23... 23 are broken, a double nut effect due to the retightening action due to the rotation of only the first nut body 2, that is, an adhesion effect between the first nut body 2 and the second nut body 3 occurs. The portion 22 abuts against the inner wall of the recessed portion 32, and the locking nut 1 is configured to be surely locked against a mounting bolt (not shown) by its eccentricity in the radial direction.

  On the other hand, when manufacturing the nut 1, first, a first nut blank (not shown) having a center hole in which the screw machining is omitted, an eccentric portion 22 eccentric to the center hole, and fracture protrusions 23. ) Is formed by forging, and a second nut blank (not shown) having a center hole in a state where screw machining is omitted, a recessed portion 32 eccentric to the center hole, and engagement holes 33. Formed by molding.

  Next, the protrusions 23... 23 are fitted into the engagement holes 33... 33 and the eccentric part 22 is fitted into the recess 32, thereby integrally connecting the first nut body 2 and the second nut body 3. Thereafter, tapping is performed simultaneously on the central hole portions of the first nut body 2 and the second nut body 3 to form continuous common screw holes 21 and screw holes 31. As a result, the first nut body 2 and the second nut body 3 have continuous common screw holes 21 and 31, and an integrally coupled locking nut 1 that can be used as one nut is formed. In addition, in FIG. 1, the code | symbol 24 is the recessed part for tap escape provided in the 1st blank side, when tapping a 1st blank and a 2nd blank (not shown).

  Next, the operation of the locking nut configured as described above will be described.

  For example, when the nut 1 is screwed into a mounting bolt (not shown) and an appropriate member is screwed to the support member, first, a hexagon socket wrench (not shown) is provided on the outer periphery of the first nut body 2 of the locking nut 1. Fit. Next, in this state, the screw hole 31 of the other second nut body 3 is aligned with the screw tip of a bolt (not shown), and then the wrench is rotated to screw the locking nut 1 into the bolt. Then, the second nut body 3 comes into contact with the member as appropriate by the screwing, and when a predetermined tightening torque is applied to the protrusions 23... 23 by further tightening, the protrusions 23. As a result, the tightening torque by the nut 1 can always be fixed and fixed. In addition, after the protrusions 23... 23 are broken, only the first nut body 2 is further rotated while the second nut body 3 is appropriately fixed to the member. Only the first nut body 2 has a double nut effect due to retightening by rotation, that is, an adhesion effect between the first nut body 2 and the second nut body, and the eccentric portion 22 of the first nut body 2 is connected to the second nut. Abutting on the inner wall of the recessed portion 32 of the body 3, the locking action of the second nut body 3 can be exerted strongly by the eccentric action in the radial direction. In that case, since the recessed part 24 for tap escape is formed in the contact | abutting part with the 2nd nut body 3 of the 1st nut body 2, the retightening action | operation is performed more effectively by this recessed part 24. Become.

  In the above-described embodiment, the first nut body 2 is appropriately rotated by a wrench and fastened by the second nut body 3. Conversely, the second nut body 3 is appropriately rotated by a wrench and fastened by the first nut body 2. You may make it do. Further, in the above-described embodiment, the planar shapes of the first and second nut bodies 2 and 3 are both hexagonal shapes, but are not limited to hexagonal shapes, and any polygonal shape that can be rotated with a wrench as appropriate. Good. Furthermore, the nut body on the fastening side may not be a polygon but may be a planar circular shape, for example.

  Further, the number of the protrusions 23 and the recessed portions 33 is not limited as long as the positioning of the first and second nut bodies 2 and 3 at the time of setting and the tightening torque at the time of breaking can be set. Is not to be done. Further, in the above-described embodiment, as the coupling means for the first and second nut bodies 2 and 3, the protruding portion 23 is provided on the eccentric portion 22 of the first nut body 2, and the recessed portion of the second nut body 3 is provided. An engagement hole 33 is formed in 32 so that molding by the forging machine can be easily performed. The coupling means is not limited to such a structure. For example, an engagement hole may be formed in the eccentric portion 22 and a protrusion may be provided in the recessed portion 32.

  Further, FIG. 5 shows another coupling means for the first and second nut bodies 2 and 3. The lower portion of the eccentric portion 22 in the first nut body 2 and the bottom surface of the recessed portion 32 in the second nut body 3 are shown. The welded portion 25 is welded so that the welded portion is broken when a predetermined tightening torque is applied to the welded portions 25... 25 at the time of welding locally at a plurality of locations (three locations in the figure). The breaking strength is set. Then, after the welded portions 25... 25 are broken, the loosening is prevented by the tightening action by rotation of only one nut body and the eccentric action in the radial direction by the abutment of the eccentric portion 22 against the inner wall of the recessed portion 32. It is composed. It should be noted that when welding a plurality of parts locally, it is preferable to provide three welding protrusions on the bottom of the eccentric part 22 or the bottom surface of the recessed part 32. In addition, since it is fundamentally the same structure as the locking nut 1 mentioned above except the welding parts 25 ... 25 which are coupling means, the same code | symbol is attached | subjected and the detailed description is abbreviate | omitted.

  Even in such a configuration, in addition to the above-described locking prevention effect, the first and second nut bodies 2 and 3 can be easily integrated by welding while suppressing the complexity of the shapes. Yes. In this case, as in the case described above, the first and second nut blanks are preliminarily molded by a forging machine, and then both are integrated by local welding at a plurality of locations, and then common to both. The first and second nut bodies 2 and 3 may be formed by performing tapping.

  It is a longitudinal cross-sectional view of the locking nut according to the present invention.   It is a top view of the nut.   It is explanatory drawing which decomposed | disassembled the nut into two.   It is an explanatory view of the locking action of the nut.   It is a longitudinal cross-sectional view of the locking nut using another another coupling means.

DESCRIPTION OF SYMBOLS 1 Nut 2 1st nut body 21 Screw hole 22 Extrusion part 23 Breaking protrusion part 3 2nd nut body 31 Screw hole 32 Recessed part 33 Engagement hole

Claims (3)

  It consists of a first nut body having a first screw hole at the center and a second nut body having a second screw hole at the center, and is eccentric to the center of the first screw hole at the bottom of the first nut body. A circular eccentric portion is formed so as to protrude, and a circular recess portion into which the eccentric portion can be fitted is formed on the upper surface of the second nut body so as to be eccentric with respect to the center of the second screw hole. The center portion of the first and second screw holes is normally maintained between the recessed portion and the eccentric portion while the first and second nut bodies are connected to one A locking nut that integrates the recessed portion and the eccentric portion so that it can be used as a nut, and is provided with a coupling means that eliminates the integration when a predetermined tightening torque is applied between them. .   As a coupling means, a positioning and breaking projection is projected below the eccentric portion of the first nut body, while the first nut body is allowed to be inserted into the bottom surface of the recessed portion of the second nut body. An engagement hole that integrates the second nut body into a set state that can be used as one nut is formed, and when the fastening portion is tightened, a predetermined tightening torque is applied to the projection portion with respect to the eccentric portion. The breaking strength of the protrusion is set so that it breaks, and after the protrusion is broken, the tightening action by rotation of only one nut body and the deviation in the radial direction due to the contact of the recessed portion of the eccentric portion with the inner wall The locking nut according to claim 1, wherein the locking nut is configured to prevent locking by a core action.   As a coupling means, the lower part of the eccentric part in the first nut body and the bottom surface of the recessed part in the second nut body were locally welded, and a predetermined tightening torque was applied to the welded part during the welding. The fracture strength of the welded part is set so that the welded part breaks, and after the welded part breaks, the tightening action by rotation of only one nut body and the inner wall of the circular recessed part of the eccentric part 2. The locking nut according to claim 1, wherein the locking nut is configured to be locked by a radial eccentric action caused by abutment.

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