JP3218859U - Bolt nut pair nut - Google Patents

Abstract

The present invention provides a bolt and nut combination nut which is not complicated in structure and suppresses the manufacturing cost. A set nut N1 includes a first nut 10 and a second nut 20. The first nut 10 includes a first hexagonal surface 12 having a concavo-convex portion, a second hexagonal surface 13 which is a flat surface, and a nut hole portion 14 or the like. The second nut has the same shape as the first nut 10. The six apex angles of the first hexagonal surface 12 are either recesses or projections, and the opposing apex angles and the adjacent apex angles differ in asperity. [Selected figure] Figure 1

Description

  The present invention uses the bolt nut fastening method and the bolt nut that does not naturally loosen even when the bolt nut tightens by vibration by screwing a pair of predetermined pair nuts into two bolts. It relates to a set nut.

  As shown in FIG. 8, there is a conventional method of fastening a bolt and a nut by screwing a pair of double nuts (a set of nuts) into a bolt.

  However, there is a play of a screw in the fastening portion of the bolt and nut, and even a slight vibration naturally loosens the fastening portion if it is generated in the fastening portion over time.

  In addition to the double nut method, a wedge method of holding the wedge in the rotating gap, a chuck method of holding the bolt like the drill chuck, a packing of resin such as rubber or urethane, etc. There is a method of fastening bolt and nut such as spring method which applies a flat spring to a nut and applies resistance to a bolt. However, no matter which method is adopted, temporary locking in environment where vibration occurs over time. Although the effect can be seen, these are also difficult to manufacture with cost and small diameter bolt and nut.

  In addition, among the nuts that prevent loosening, there is also a document regarding a locking nut that exerts a stable locking function even when used multiple times for attachment and detachment (for example, Patent Document 1).

Japanese Patent Application Laid-Open No. 10-286649

  Conventional bolt and nut fastening methods using double nuts naturally loosen in an environment where vibration occurs over the years. In addition, although the bolt fastening method using the locking nut described in the above-mentioned Patent Document 1 has a track record of locking, it has a complicated structure, so the manufacturing cost is lower than that of a general nut. It is expected to be higher.

  Moreover, the present condition is that the nut of 4 mm or less in diameter is not manufactured about the locking nut of the above-mentioned patent document 1. FIG.

  Therefore, a problem to be solved by the present invention is, firstly, to provide a bolt and nut fastening method that does not loosen naturally even in an environment where vibration occurs over time.

  Second, the problem to be solved by the present invention is to provide a nut assembly which is not complicated in structure and suppresses the manufacturing cost.

  A third problem to be solved by the present invention is to provide a pair of nuts that can be manufactured (manufacturable) with a complicated structure and can be applied to small nuts having a diameter of less than 4 mm.

  In order to solve the above-mentioned subject, it is the method of fastening a bolt nut by screwing a predetermined group nut through a bolt, and it has a 1st nut which constitutes a group nut from an open end of a bolt. The step of screwing the hexagonal surface in the direction opposite to the screw advancing direction, and the hexagonal surface having the uneven portion with the second nut constituting the set nut from the open end of the bolt The hexagonal shape having the uneven portion of the first nut A bolt and nut are screwed into the shape surface, and further tighten the second nut from a state in which the convex portions of the opposing hexagonal surfaces of the first nut and the second nut start to contact with each other. Provide a way to conclude.

  In order to solve the above-mentioned subject, it is a set nut used for the bolt nut fastening method, and the set nut is screwed after the 1st nut screwed first when screwing in a bolt first, and the 1st nut. A first hexagonal surface having a concavo-convex portion in contact with a nut side surface surrounding the periphery of the nut and one side of the nut side surface, and the other of the nut side surface A second hexagonal surface in contact with the side, and a nut hole penetrating the first hexagonal surface and the second hexagonal surface, the second nut being a side surface of the nut surrounding the periphery of the nut And a first hexagonal surface having an uneven portion in contact with one side of the nut side surface, a second hexagonal surface in contact with the other side of the nut side, the first hexagonal surface, and the second side. Through the hexagonal face of The six apex portions formed of the first nut and the first hexagonal surface of the first nut and the second nut are either a recess or a projection, and the six apex angles A set nut is characterized in that the combination of a recess or a projection of one of the apex angles and the opposing apex angle is different.

  In order to solve the above-mentioned subject, it is a set nut used for the bolt nut fastening method, and the set nut is screwed after the 1st nut screwed first when screwing in a bolt first, and the 1st nut. A first hexagonal surface having a concavo-convex portion in contact with a nut side surface surrounding the periphery of the nut and one side of the nut side surface, and the other of the nut side surface A second hexagonal surface in contact with the side, and a nut hole penetrating the first hexagonal surface and the second hexagonal surface, the second nut being a side surface of the nut surrounding the periphery of the nut And a first hexagonal surface having an uneven portion in contact with one side of the nut side surface, a second hexagonal surface in contact with the other side of the nut side, the first hexagonal surface, and the second side. Through the hexagonal face of The six apex portions formed of the first nut and the first hexagonal surface of the first nut and the second nut are either a recess or a projection, and the six apex angles The combination of the depressions or projections of the one apex angle and the opposing apex angle is different, and one of the six apex angles present in the first hexagonal surface of the first nut and the second nut In the present invention, there is provided a nut assembly characterized in that the extending surface from the top angle of the second to the adjacent top angle is a gentle slope.

  In order to solve the above problems, the first hexagonal surface of the first nut and the first hexagonal surface of the second nut are formed by forging (cold forging). Provide a set nut.

  The bolt and nut fastening method according to the present invention is further tightened and fastened after the convex portions of the opposing nut surfaces begin to contact with each other during screwing, so that it naturally occurs even in an environment where vibration occurs over the years. It does not loosen.

  In the set nut of the present invention, six apex angles of the first hexagonal surface having the projections and depressions of the first nut and the second nut are either a recess or a projection, Although the combination of the concave portion or the convex portion of one of the apex angles and the opposing apex angle is different, the structure is not complicated, so that the manufacturing cost can be suppressed. It is also applicable to small diameter nuts (not to prevent application to large nuts).

  In the set nut of the present invention, six apex angles of the first hexagonal surface having the projections and depressions of the first nut and the second nut are either a recess or a projection, It is characterized in that the extending surface from the apex angle of one to the adjacent apex angle is a gentle slope, but the structure is not complicated, so that the manufacturing cost can be suppressed. It is also applicable to small diameter nuts (not to prevent application to large nuts).

  Furthermore, since the first hexagonal surface having the concavo-convex portion of the first nut and the second nut is formed by forging (cold forging), the manufacturing cost can be further suppressed. .

FIG. 1 is a side view of a pair of nuts (first and second nuts). FIG. 2 is a plan view of the first nut. FIG. 3 is an enlarged sectional view of a nut hole of the first nut. FIG. 4 is a plan view of the second nut. FIG. 5 is a perspective view of a first hexagonal surface having an uneven portion. FIG. 6 is an operation state diagram showing how a corresponding set nut is screwed through a bolt. FIG. 7 is a use state diagram showing a state in which the corresponding set nut is fastened through the bolt. FIG. 8 is an explanatory view showing a conventional method of fastening a bolt and a nut by a combined nut (double nut).

  A bolt and a nut are fastened to a small object such as an eyeglass component using the assembly nut according to the present invention.

  The structure of the set nut will be described according to FIGS. 1 to 5.

  The set nut (N1) comprises a predetermined first nut (10) and a predetermined second nut (20) (FIG. 1).

  A first hexagonal surface (an irregular portion) in contact with the six side surfaces (11) surrounding the periphery of the nut and one side (the upper side shown in FIG. 1) of the side of the first nut (10) 12), the second hexagonal surface (13) in contact with the other side of the side (the lower side shown in FIG. 1), and the centers of the first hexagonal surface and the second hexagonal surface And a nut hole (14) for perforating the through hole. (Figures 1 and 2).

  Six apex portions are present in the first hexagonal surface (12) of the first nut (10). Specifically, a first apex angle (121) positioned at the top in FIG. 2, a second apex angle (122) positioned adjacent to the first apex angle in the clockwise direction, and the second apex angle A third apex angle (123) located next to the third arm in the clockwise direction, a fourth apex angle (124) located next to the third arm in the clockwise direction and the lowermost part, and the fourth apex angle The fifth apex angle (125) located next to the clockwise direction and the sixth apex angle (126) located next to the fifth apex angle in the clockwise direction (FIG. 2).

  The six apex portions of the first hexagonal surface (12) of the first nut (10) have the lowest recess in the first hexagonal surface or the first hexagonal surface. It is one of the highest peaks. In this embodiment, the first apex angle (121) is a convex portion, the second apex angle (122) is a concave portion, the third apex angle (123) is a convex portion, and the fourth apex angle (124) is a concave portion. The fifth apex angle (125) is a convex portion, and the sixth apex angle (126) is a concave portion. Conversely, the first apex angle is a concave portion, the second apex angle is a convex portion, and a third apex angle is a concave portion. The fourth apex angle may be a convex portion, the fifth apex angle may be a concave portion, and the sixth apex angle may be a convex portion (FIGS. 2 and 5).

  Among the apex angles of the first hexagonal surface (12) of the first nut (10), the combination of the concave portion or the convex portion at the opposite apex angle (for example, the first apex angle and the fourth apex angle) is different The fourth apex angle is a recess when the first apex angle is a projection, and the fourth apex angle is a projection when the first apex angle is a recess; similarly, the second apex angle is In the case of the concave portion, the fifth apex angle is a convex portion, and in the case where the third apex angle is a convex portion, the sixth apex angle is a concave portion (FIG. 2).

  An inclined surface having a gentle extension surface extending to an adjacent one of the apex angles of the first hexagonal surface (12) of the first nut (10), in the case where the first apex angle is a convex portion, The extending surface extending to the second apex angle is a gentle downward inclined surface, and the extending surface extending from the first apex angle to the sixth apex angle is a gentle downward inclined surface. Similarly, the extending surface extending from the second apex angle to the third apex angle is a gentle upward inclined surface, and the extending surface extending from the third apex angle to the fourth apex angle is a gentle downward inclined surface And the extending surface extending from the fourth apex angle to the fifth apex angle is a gentle upward inclined surface, and the extending surface extending from the fifth apex angle to the sixth apex angle is a gentle downward inclined surface It is said that (FIG. 5).

  The shape of the boundary portion where the inclined surfaces are in contact with each other is rounded (Fig. 5).

  As for the method of forming the first hexagonal surface (12), in consideration of cost, a method of forming the uneven pattern by forging (cold forging) is preferable.

  The height (H1) of the convex portion at the first apex angle (121) is the same as the pitch width (W1) of the screw groove provided on the inner peripheral surface of the nut hole (14), but the pitch of the screw groove It may be less if it does not exceed the width (W1) (FIG. 3).

  In addition, the heights of the protrusions at the third apex angle and the fifth apex angle are the same as the first apex angle (not shown).

  The recess depth (H2) at the fourth apex angle (124) is the same as the pitch width (W1) of the screw groove provided on the inner peripheral surface of the nut hole (14), but the pitch width of the screw groove If it does not exceed (W1), it may be less (Fig. 3).

  Further, the recess depth at the second apex angle and the sixth apex angle is the same as the fourth apex angle (not shown).

  In addition, the shape of the second hexagonal surface (13) of the first nut (10) is made to be an entire flat surface (flat surface without concave or convex portions) similar to a general nut in consideration of manufacturing cost. However, it does not matter whichever (FIG. 1). For example, it may be the same as the first hexagonal surface (12) in order to improve operability and the like while suppressing the manufacturing cost.

  A screw groove is provided on the inner circumferential surface of the nut hole (14), and the pitch width (W1) of the screw groove is a width corresponding to the screw pitch of the fastening bolt (FIG. 3).

  The second nut (20) has a first hexagonal shape having an uneven portion in contact with six side surfaces (21) surrounding the periphery of the nut and one side (the lower side shown in FIG. 1) of the side A second hexagonal surface (23) in contact with the surface (22) and the other side (the upper side shown in FIG. 1) of the side surface, and the first hexagonal surface and the second hexagonal surface And a nut hole (24) pierced through the center. (Figure 1).

  Six apex portions are present in the first hexagonal surface (22) of the second nut (20). Specifically, a first apex angle (221) positioned at the top in FIG. 4, a second apex angle (222) positioned adjacent to the first apex angle in the clockwise direction, and the second apex angle A third apex angle (223) located next to the clockwise direction, a fourth apex angle (224) located next to the third apex angle in the clockwise direction and the lowermost part, and the fourth apex angle A fifth apex angle (225) located next to the clockwise direction and a sixth apex angle (226) located next to the fifth apex angle in the clockwise direction (FIG. 4).

  The six apex portions of the first hexagonal surface (22) of the second nut (20) are the lowest recess in the first hexagonal surface or the most in the first hexagonal surface. It is one of the high convex parts. In this embodiment, the first apex angle (221) is a projection, the second apex angle (222) is a recess, the third apex angle (223) is a projection, and the fourth apex angle (224) is a recess. The fifth apex angle (225) is a convex portion, and the sixth apex angle (226) is a concave portion. Conversely, the first apex angle is a concave portion, the second apex angle is a convex portion, and a third apex angle is a concave portion. The fourth apex angle may be a convex portion, the fifth apex angle may be a concave portion, and the sixth apex angle may be a convex portion (FIGS. 4 and 5).

  Among the apex angles of the first hexagonal surface (22) of the second nut (20), the combination of the concave portion or the convex portion at the opposite apex angle (for example, the first apex angle and the fourth apex angle) is different The fourth apex angle is a recess when the first apex angle is a projection, and the fourth apex angle is a projection when the first apex angle is a recess; similarly, the second apex angle is In the case of the concave portion, the fifth apex angle is a convex portion, and in the case where the third apex angle is a convex portion, the sixth apex angle is a concave portion (FIG. 4).

  In the case where the first apex angle is a convex portion, the inclined surface having a gentle extension surface extending to the adjacent apex angle among the apex angles of the first hexagonal surface (22) of the second nut (20), The extending surface extending to the second apex angle is a gentle downward inclined surface, and the extending surface extending from the first apex angle to the sixth apex angle is a gentle downward inclined surface. Similarly, the extending surface extending from the second apex angle to the third apex angle is a gentle upward inclined surface, and the extending surface extending from the third apex angle to the fourth apex angle is a gentle downward inclined surface And the extending surface extending from the fourth apex angle to the fifth apex angle is a gentle upward inclined surface, and the extending surface extending from the fifth apex angle to the sixth apex angle is a gentle downward inclined surface It is said that (FIG. 5).

  As for the method of forming the first hexagonal surface (22), in consideration of cost, a method of forming the uneven pattern by forging (cold forging) is preferable.

  Regarding the height of the convex portion and the depth of the concave portion of the apex angle portion of the first hexagonal surface (22) of the second nut (20), the convex height and the concave portion of the first hexagonal surface of the first nut Like the depth, it is identical to the pitch width of the thread groove provided on the inner peripheral surface of the nut hole (not shown).

  The shape of the second hexagonal surface (23) of the second nut (20) is flat on the entire surface similar to a general nut in consideration of manufacturing costs, but it may be any plane. (Figure 1). For example, it may be the same as the first hexagonal surface (22) in order to improve operability and the like while suppressing the manufacturing cost.

  For the forming method of the first hexagonal surface (22), forging (cold forging) is preferable in consideration of cost. Preferably, the first nut and the second nut have the same shape.

  Next, a method of screwing the assembly nut through the bolt and fastening the bolt nut will be described according to FIGS. 6 and 7.

  First, the first nut (10) constituting the assembly nut (N1) is screwed from the open end of the bolt (V1), and is screwed forward. At this time, note that the first hexagonal surface (12) having the concavo-convex portion of the first nut faces in the opposite direction (the second hexagonal surface points in the direction of screwing). (Fig. 6).

  After screwing the first nut (10) to a predetermined position along the screw groove of the bolt (V1), the second nut (20) is screwed from the open end of the bolt and the open end of the bolt Join and screw up. At this time, the first hexagonal surface (22) having the uneven portion of the second nut faces the first hexagonal surface (12) of the first nut (the surfaces having the uneven portion are opposed to each other) (See Fig. 6).

  As the second nut (20) is screwed, the convex portion (for example, the first apex angle) of the first hexagonal surface of the first nut and the first hexagonal shape of the second nut are eventually obtained. The convex portion of the surface (e.g., the first apex angle) begins to touch (fit).

  Further, the second nut (20) is tightened (screwed) until it does not rotate. By the above-described fastening operation, the first hexagonal surface (12) of the first nut (10) and the first hexagonal surface (22) of the second nut are screwed and engaged while facing each other. In other words, the concave and convex surfaces of the first nut and the second nut are screwed against each other while facing each other, and the convex portions of the pair of nuts (for example, first apex angles, first apex angle and third apex angle, Since the first apex angle and the fifth apex angle are in contact with each other (fitting), they do not naturally loosen even in vibration and aging (the state of FIG. 7).

  The bolt and nut fastening method according to the present invention has industrial applicability because it is an excellent fastening method that does not naturally loosen even when it comes to vibration and aging. In addition, since the nut set according to the present invention is an excellent set nut which does not naturally loosen even when it comes to vibration and aging, it has industrial applicability.

N1 set nut 10 1st nut 11 nut side surface 12 1st hexagonal surface (with unevenness)
121 first apex angle 122 second apex angle 123 third apex angle 124 fourth apex angle 125 fifth apex angle 126 sixth apex angle 13 second hexagonal surface 14 nut hole 20 second nut 21 nut side surface 22 second Hexagon-like surface of 1 (with irregularities)
221 first apex angle 222 second apex angle 223 third apex angle 224 fourth apex angle 225 fifth apex angle 226 sixth apex angle 23 second hexagonal surface 24 nut hole V1 bolt

Claims (4)

A method of fastening a bolt and nut by screwing a predetermined pair of nuts through a bolt,
Screwing the first nut (10) constituting the set nut from the open end of the bolt (V1) in the direction opposite to the hexagonal plane (12) having the concavo-convex portion;
From the open end of the bolt, screw the second nut (20) constituting the set nut toward the hexagonal surface (12) having the concavo-convex portion with the concavo-convex portion of the first nut. Process,
Further tightening the second nut from a state in which the convex portions of the opposing hexagonal surfaces of the first nut and the second nut have come into contact with each other;
By
How to tighten bolt and nut. It is a group nut used for the bolt nut fastening method according to claim 1;
The set nut (N1) includes a first nut (10) screwed first when fastening through a bolt and a second nut (20) screwed behind the first nut.
The first nut has a nut side surface (11) surrounding the periphery of the nut, a first hexagonal surface (12) having an uneven portion in contact with one side of the nut side, and the other side of the nut side It comprises a second hexagonal surface (13) in contact and a nut hole (14) penetrating the first hexagonal surface and the second hexagonal surface.
The second nut includes a nut side surface (21) surrounding the periphery of the nut, a first hexagonal surface (22) having an uneven portion in contact with one side of the nut side, and the other side of the nut side And a nut hole (24) passing through the second hexagonal surface (23) and the first hexagonal surface and the second hexagonal surface in contact with each other.
The six apex portions present in the first hexagonal surface (12, 22) of the first nut and the second nut are either a recess or a protrusion,
A combination nut characterized in that combinations of an apex angle of one of the six apex angles and a concave portion or a convex portion of the opposing apex angle are different.   A surface extending from an apex angle of one of the six apex angles present in the first hexagonal surface (12, 22) of the first nut and the second nut to the adjacent apex angle is an inclined surface The nut set according to claim 2, characterized in that.   The pair of nuts according to claim 2 or 3, wherein the first nut or the second nut has a diameter of 0.5 mm or more and less than 4 mm.