KR101421971B1 - lock nut - Google Patents

Abstract

In the present invention, both ends of the coil spring are embedded in the non-threaded portion of the lock nut so as to be maintained in a state of being enlarged by the fixing means, and the fixing means is manually released by the operator's choice, By providing the lock nut with a structure in which the coil spring comes into contact with the spiral portion of the lock nut and fixes one end of the coil spring by another fixing means so that the coil spring is kept in the enlarged state, The lock nut can be loosened even if the fastened bolt and the lock nut are loosened in the case where the fastening sequence of the fastening bolt and the fastening bolt fastened to the fastening object is broken or the foreign object is introduced into the fastening object, It is possible to fasten the bolts and locknuts together by hand, It provides an operational effect that is treated with up.

Description

Lock nut

The present invention relates to a lock nut, and more particularly, to a lock nut, which can be fastened to a bolt in a state where fastening and loosening is possible, and can be made into a fastening state that is intentionally reliable and can not be loosened after fastening is established, To a lock nut which can be easily unfastened from a bolt by an intentional external force at the time of disassembly of an object joined by the bolt.

In order to prevent loosening of the lock nut from the bolt, it is necessary to use a coil spring between the bolt and the nut, a method of breaking the local part of the screw at the time of provisioning, and an insert between the screw thread part of the bolt and the screw thread part of the nut There is an intervening plan.

The method of breaking a part of the thread and the method of interposing the insert serve as a stopper part in the unwinding direction only in the western part, so that when the stopper part is broken by the small external force, the nut can be easily released to the bolt. It can not be applied to fixed devices such as bridges, railway rails, nuclear power plants, and switchboards where stability is a top priority.

However, since the entire inner circumferential surface of the coil spring fixed to the nut is in contact with the spiral portion of the bolt in a state in which the coil spring is interposed, the bridge having the highest mechanical stability, the rail rail, the nuclear power plant, Device.

 A conventional lock nut having a spiral coil spring interposed between a bolt and a nut is disclosed in Korean Patent No. 10-701782 and No. 10-701643.

The lock nut described above is provided with a screw thread engaging with the bolt on the inner circumferential surface of the nut on the upstream side in the fastening direction and having an inner diameter larger than the inner diameter of the screw thread so that the helical coil spring is inscribed And the sagging is included on the downstream side in the fastening direction.

The non-threaded portion of the lock nut includes an upstream end step portion and a downstream end step portion in a clamping direction in a diametrical direction so as to prevent the helical coil spring, which is internally engaged with the threaded portion, from being detached from the lock nut.

In the lock nut, a concave portion is formed on the surface of the downstream stepped portion exposed in the central axial direction of the bolt, and the concave portion is inserted into the downstream bent portion bent in the radially outward direction from the downstream end of the helical coil spring And the upstream end of the helical coil spring is inscribed in the non-threaded portion to be spaced apart from the upstream end step portion by a predetermined distance in the direction of the central axis of the bolt.

Further, the helical coil spring has an inner circumferential surface which can be fastened to the spiral portion of the bolt.

The conventional lock nut constructed as described above is operated as follows.

When the bolt is inserted into the lock nut and turned in the tightening direction, the screw is first fastened to the stud. In this state, when the bolt is continuously rotated in the tightening direction, the screw thread of the bolt and the helical coil spring are fastened together, The spiral coil spring of the bolt is brought into surface contact with the spiral coil spring so that the spiral coil spring is twisted in the tightening direction so that the downstream bending portion of the helical coil spring is fixed to the recess, The tip of the spiral portion of the bolt smoothly passes through the spiral coil spring and when the turning of the bolt in the tightening direction is stopped, the spiral coil spring of the spiral diameter is diametrically reduced and resiliently resilient with the spiral portion of the bolt So that it is circumscribed and fastened.

In this state, the helical coil spring resiliently tightens the spiral portion of the bolt, so that the lock nut is not released from the bolt by any unintentional external force.

However, in the conventional lock nut, for example, when the nut is loosened in the bolt for maintenance, when the nut is turned in the non-tightening direction, the downstream bent portion of the helical coil spring is fixed to the recess, The helical coil spring is reduced in diameter to make it difficult to turn the nut in the non-tightening direction.

When the lock nut is turned in the non-tightening direction by a large force, the downstream bending portion of the helical coil spring is cut off and separated from the helical coil spring, and the helical coil spring, which is separated from the downstream bent portion, The non-threaded portion remains without being detached from the stud, so that the threaded portion is elastically pressed against the spiral portion of the bolt so that the lock nut can not be loosened from the bolt without damaging the lock nut .

In order to solve this problem, the upstream end of the spiral coil spring is bent outwardly in the radial direction as the downstream end to form an upstream bend, and a slot is formed in the non-threaded portion facing the upstream bend in the radial direction And the downstream bending portion of the helical coil spring is fixed to the recess portion when the lock nut is rotated in the non-tightening state in a state where the upstream bending portion is positioned in the elongated hole, the spiral coil spring is entirely reduced in diameter, It may be proposed that the bent portion is deformed in the non-tightening direction along the inner circumferential surface of the non-threaded portion so as to be hung on the side wall of the long hole so that the helical coil spring is entirely enlarged.

However, such a proposal is such that when the upstream bending portion is deformed in the non-tightening direction along the inner circumferential surface of the non-threaded portion so as to be hung on the side wall of the slot, both ends of the helical coil spring are connected to the upstream bending portion and the downstream bending portion So that the upstream bending portion side can be enlarged, but the downstream bending portion side is still reduced in diameter, which has a problem that it is difficult to unlock the locknut with the bolt.

In order to solve this problem, when only the upstream end side of the helical coil spring is made larger than the other part of the helical coil spring and the lock nut is turned in the non-tightening direction, the upstream end of the helical- So as to prevent the bolt from being tightened.

However, this prevention proposal has a problem in that the upstream end side of the helical coil spring is larger in diameter than other portions of the helical coil spring, so that the other portions of the helical coil spring are spaced radially inward In order to solve this problem, if the thickness of the spiral coil spring is made thinner, the elasticity of the bolt can be increased by the elasticity of the bolt, There is a problem that the force of tightening the spiral portion is smaller than that of the conventional one, and a reliable release preventing function can not be provided.

In addition, when the spiral coil spring is enlarged and reduced in diameter during the tightening of the locknut, and when the locknut is tightened by the tightening and presenting, it is repeatedly shrunk, and the bridge with the highest mechanical stability, the railroad rail, the nuclear power plant, , There is a possibility that a safety accident may occur.

A locknut for solving such a problem has been proposed in the patent registration No. 10-1151721 filed by the present applicant.

In the lock nut proposed in the patent registration, the downstream bending portion of the helical coil spring becomes a stopping point when the nut is used, and the helical coil spring is entirely enlarged, And the spiral coil spring is entirely moved in its entirety, so that the fastening of the nut can be facilitated without damaging the elastic tightening force, and the fastening coil spring can be easily prevented from being unfastened by an unintentional external force The nut can be easily unfastened only by the intentional external force, and this action can be made without increasing the manufacturing cost, and the nut can be made disposable so as to prevent the safety accident in advance. have.

However, when the object to be fastened is fastened by bolts and nuts, it is necessary to loosen the fastened bolts and nuts in the case where the object to be fastened is misaligned, the fastening order of the bolt and nut is wrong, There is a problem that wasteful use of resources is required because many locknuts can not be used and must be discarded.

In order to overcome such a problem, it is proposed to press the upstream bending portion of the coil spring by the tool through the hole formed in the nut to enlarge the coil spring. However, the operator may hold the tool with one hand and press the upstream bending portion It requires a work environment in which a bolt or a nut must be tightened with the other hand at the same time as pressurization, thereby causing a problem that the worker is treated as a dangerous and cumbersome work during a high-altitude work.

A lock nut for solving such a problem has been proposed in the patent registration No. 10-1178129 filed by the present applicant.

The lock nut proposed in the patent registration is characterized in that the lower end of the helical coil spring is bent and fixed to the nut and the upstream end of the helical coil spring is connected to a detachable primary stopper for maintaining the bulged state of the helical coil spring, A secondary stopper that can fix a downstream end of the helical coil spring that is shrunk when the nut is rotated in the direction of disengagement is provided in the nut so that the downstream bending portion of the helical coil spring becomes a step , The spiral coil spring is made to be wholly enlarged, the downstream bending portion is released at the point of the tightening of the nut, and the upstream bending portion is a point of the stepping so that the helical coil spring is entirely enlarged, It is possible to facilitate the fastening of the nut and to easily Im not being released, and may allow the nut only by the intentional external force easily release fasteners.

However, in the conventional lock nut, the first and second stoppers require punching and drilling of the non-threaded portion of the nut, the pin must be detachable to the drilled through hole, and the spiral coil spring There is a problem that the manufacturing cost of the lock nut is increased because the downstream end needs to be configured to come out of the recessed portion of the nut by a constant external force.

The present invention has a problem in solving the above-mentioned problems.

In the present invention, both ends of the coil spring are embedded in the non-threaded portion of the lock nut so as to be maintained in a state of being enlarged by the fixing means, and the fixing means is manually released by the operator's choice, And the other end of the coil spring is fixed by the other fixing means so that the coil spring is maintained in the enlarged state.

According to the present invention, there is provided a bolt and a lock nut which are fastened in the case where an object to be fastened is incorrectly set, a fastening order of the bolt and the lock nut is wrong, It is possible to reduce the waste of resources by making it possible to unlock the locknut and enable the operator to fasten the bolt and the lock nut to each other with only one hand so that the operator can easily and safely work As shown in Fig.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a conceptual view of a fastening state of a helical coil spring according to an embodiment of the present invention,
Fig. 2 is a conceptual view of the unfastened state showing the spiral coil spring of Fig. 1,
Fig. 3 is a view showing a state in which the helical coil spring of Fig. 1 is not received in the nut, Fig.
Fig. 4 is a view showing a state in which the helical coil spring of Fig. 1 is housed in a nut;
Fig. 5 is a perspective view of Fig. 4 showing a state in which a spiral coil spring is expanded,
6 is a perspective view showing a state in which the helical coil spring is reduced in diameter,
Fig. 7 is a perspective view showing the spiral coil spring of the modified embodiment in a magnified state; Fig.
Fig. 8 is a perspective view showing a spiral coil spring of a modified embodiment in a state of being reduced in diameter, and Fig.
9 is a cross-sectional view showing that an arch portion and a cam surface are formed in the step portion at the downstream end in FIG.

Hereinafter, embodiments according to the present invention will be described in detail with reference to FIGS. 1 to 6. FIG.

3 and 4, the locknut of the present embodiment is indicated as 100. In Fig.

The lock nut 100 includes a helical coil spring 10 as shown in FIG.

As shown in FIG. 1, a downstream end bent portion 11 is formed at a downstream end of the helical coil spring 10 and is bent in the outward direction of the diameter of the helical coil spring 10. The helical coil spring 10 10 are located diametrically opposed to the downstream end bend 11.

The spiral coil spring 10 is configured such that the spiral portion 51 of the bolt 50 passes through the downstream end from the upstream end 12 of the spiral coil spring 10 and can be fastened to the spiral coil spring 10 It is wound in a spiral shape.

 5, the helical coil spring 10 is inserted into the recess 21 formed in the nut 20, which will be described later, and the bolt 50 is inserted into the recess 21 When the bolt 50 is brought into contact with the upstream end of the helical coil spring 10 and turned in the tightening direction (clockwise in FIG. 1), the bolt 50 is brought into frictional contact with the helical portion 51 of the bolt 50, To enter the downstream end of the helical coil spring 10.

2, the helical coil spring 10 is inserted into the concave portion 21 formed in the nut 20 and the bolt 50 is inserted into the concave portion 21 The bolt 50 is brought into frictional contact with the spiral portion 51 of the bolt 50 so that the bolt 50 can be easily moved in the direction of the spiral coil spring 10 to the upstream end thereof.

3, the nut 20 has a screw thread 22 which is fastened to the bolt 50 on the inner circumferential surface of the nut on the upstream side in the direction of engagement with the bolt 50, And a non-threaded portion 23 is provided on the downstream side in the fastening direction so that the helical coil spring 10 has an inner diameter larger than the inner diameter of the stud 22 and the helical coil spring 10 is received radially inwardly at a predetermined interval.

In order to prevent the helical coil spring 10, which is inscribed in the non-threaded portion 23, from being detached from the nut, the non-threaded portion 23 of the nut 20 has an upstream end stepped portion 23a and the downstream end stepped portion 23b are diametrically reduced.

As shown in Fig. 5, the nut 20 has a recess 21 and a recess 22 on the surface of the downstream end stepped portion 23b exposed in the center axis direction of the bolt 50, 5 and 6, the one recessed portion 21 and the other recessed portion 21 'are formed with the downstream end bending portion 21' of the helical coil spring 10, And the upstream end 12 of the spiral coil spring 10 is inserted into the non-threaded portion 23 so as to be resiliently contacted with the upstream end stepped portion 23a, And the non-spacer is also elastically contacted with the stopper S formed on the work 23.

The stopper S is a protrusion protruding from the upstream step portion 23a toward the downstream step portion 23b or protruding radially inward from the inner circumferential surface of the non-

The downstream end folded portion 11 of the spiral coil spring 10 is fixed to the one recess 21 and the downstream end of the spiral coil spring 10 is elastically pressed to the stopper S, The spiral coil spring 10 is kept in the enlarged state and the downstream end bent portion 11 of the spiral coil spring 10 is fixed to the other recessed portion 21 ' When the downstream end of the spiral coil spring 10 is resiliently pressed against the stopper S, the spiral coil spring 10 is maintained in a reduced diameter state.

The principle of this is that when the upstream end of the helical coil spring is pressed in the clockwise direction (fastening direction) and the downstream end is pressed in the counterclockwise direction (release direction), and the upstream end of the helical coil spring is rotated counterclockwise And when the downstream end is pressed in the clockwise direction (fastening direction), the shaft is reduced in diameter.

Therefore, the one recess 21 is formed by the spiral coil spring 10 having the spiral coil spring 10 as a position fixing point at which the upstream end 12 of the spiral coil spring 10 is fixed by the stopper S Is formed at the portion of the downstream step portion 23b where the downstream end of the helical coil spring 10 is located and the other recess 21 'is formed by the stopper S, The position where the upstream end 12 of the coil spring 10 is fixed is defined as a position fixing point and the helical coil spring 10 is circumscribed with respect to the helical portion 51 of the bolt 50, Is formed at the portion of the downstream step portion 23b where the downstream end of the spiral coil spring 10 is located when the spiral coil spring 10 is in a free state without receiving any external force.

That is, the other concave portion 21 'is spaced apart from the one concave portion 21 by a predetermined distance toward the downstream side in the fastening direction.

The lock nut 100 configured as described above can be operated as follows.

A first mode in which the upstream end 12 of the helical coil spring 10 is in contact with the stopper S and the downstream end bend 11 is inserted in the one recess 21, The spiral coil spring 10 is positioned with the spring in its expanded state (see Fig. 5).

Then, when the bolt 50 is rotated in the tightening direction while inserting the threaded portion 51 of the bolt 50 into the threaded portion 22 of the lock nut 100, the threaded portion 51 of the bolt 50 When the bolt 50 is further rotated in the tightening direction, the threaded portion 51 of the bolt 50 is engaged with the stopper 22 of the stopper 22, The spiral portion 51 of the bolt 50 can be easily inserted into the spiral coil spring 10 without being hindered by the pin 24 and the spiral coil spring 10 which is enlarged by the one recess 21, So that the lock nut 100 is completely fastened to the bolt 50.

In this state, the bolts 50 and the locknuts 50, which are fastened in the case where the object to be fastened is misaligned, the fastening order of the bolts 50 and the locknuts 100 is wrong, When the bolt 50 is loosened, the bolt 50 is rotated in the direction of unfastening such as a normal bolt and nut to release the fastening between the bolt 50 and the lot nut 100.

When the bolt 50 and the lock nut 100 are tightened again and the fastening state of the bolt 50 is not abnormal, the worker moves from the one recessed portion 21 to the downstream end bent portion of the helical coil spring 10 11, the spiral coil spring 10 is shrunk in its entirety and the downstream end bending portion 11 is moved to the downstream side in the fastening direction and positioned on the other recessed portion 21 ' , And a second mode (see FIG. 6 in which the helical coil spring is in a reduced diameter state) for inserting and fixing the downstream end bending portion 11 in which the worker has moved to the other recessed portion 21 '.

In the second mode, the spiral coil spring 10 is seated on the valley of the spiral portion 51 of the bolt 50 to resiliently press the spiral portion 51 radially inward so that any unintentional The locking between the lock nut 100 and the bolt 50 is prevented from being released.

In this state, when the lock nut 100 is to be released from the bolt 50 for maintenance, when the operator positions the helical coil spring 10 in the first mode, The fastening between the lock nut 100 and the bolt 50 can be released without damaging the lock nut 100. [

When the lock nut 100 is operated by the lock nut 100, the bolt and the lock nut are locked when the object to be fastened is misaligned, the fastening order of the bolt and the lock nut is wrong, It is possible to reduce the waste of resources by reducing the number of loosening of the locknut and the operation of reducing the diameter of the spiral coil spring by the operator and the operation of fastening the bolt and the locknut to each other can be performed by only one hand It is possible to make a worker feel comfortable and safe when handling the job.

9, in addition to the configuration of the above embodiment, a bolt (not shown) is provided at a portion of the downstream step portion 23b between the one recessed portion 21 and the other recessed portion 21 ' 50 and the other recessed portion 21 ', which are connected to both ends of the arch portion 61, are fastened to each other. The lower end bending portion 11 of the helical coil spring 10 is pulled out from the one recess 21 and the other recess 21 ' If the sliding cam surface 60 is formed so as to be positioned at the arch portion 61, the operator can easily remove the downstream end bent portion 11 from one recess 21 or the other recess 21 ' Tightening and loosening of bolts or nuts only without the use of hand or auger The spiral coil spring 10 can be enlarged and reduced in diameter by a tool alone, which is preferable.

As shown in Fig. 7, the present invention is a modification of the above embodiment in which the one recess 21 and the other recess 21 'of the other recess 21' are excluded A long through hole 30 is formed in the spiral direction on the non-sagging portion 23 provided with the stopper S and the lower end bent portion 11 of the helical coil spring 10, The upstream end 12 of the spring 10 is bent outward in the diameter direction to form a bent portion 12 'so that the bent portion 12' passes through the through hole 30, and the through hole 30 A stopper S 'protruding in the center axis direction of the nut 20 is formed on the upper wall 31 or the lower wall 32 in the center axial direction of the nut 20 among the wall portions defining the nut 20, In the side wall 33 positioned on the counterclockwise side of the wall portions defining the through hole 30, the stopper S ' And the spacing becomes a state of being enlarged when the bent portion 12 'of the upstream end 12 of the helical coil spring 10 is hooked on the stopper S' 12 'is positioned between the side wall 33 and the stopper S' beyond the stopper S 'so as to be in a reduced-diameter state.

The lock nut 100 of the modified embodiment configured as described above has the same structure as the first mode (the expanded state of the helical coil spring) shown in Fig. 7 and the second mode (the helical coil spring shown in Fig. 8) A reduced state) can be selectively implemented manually, so that it can be operated as in the above embodiment.

The bent portion 12 'of the upstream end 12 of the helical coil spring 10 is in contact with the stopper S' and the downstream end bent portion 11 of the helical coil spring 10 is in contact with the one recess 21 The helical coil spring 10 is positioned in the first mode (see FIG. 7 in which the helical coil spring is located) inserted.

Then, when the bolt 50 is rotated in the tightening direction while inserting the threaded portion 51 of the bolt 50 into the threaded portion 22 of the lock nut 100, the threaded portion 51 of the bolt 50 When the bolt 50 is further rotated in the tightening direction, the threaded portion 51 of the bolt 50 is engaged with the stopper 22 of the stopper 22, The spiral portion 51 of the bolt 50 can be easily inserted into the spiral coil spring 10 without being hindered by the pin 24 and the spiral coil spring 10 which is enlarged by the one recess 21, So that the lock nut 100 is completely fastened to the bolt 50.

In this state, the bolts 50 and the locknuts 50, which are fastened in the case where the object to be fastened is misaligned, the fastening order of the bolts 50 and the locknuts 100 is wrong, When the bolt 50 is loosened, the bolt 50 is rotated in the direction of unfastening such as a normal bolt and nut to release the fastening between the bolt 50 and the lot nut 100.

When the bolt 50 and the lock nut 100 are tightened again and the fastening state of the bolt 50 is not abnormal, the operator grips the bent portion 12 'to skip the stopper S' When the part 12 'is positioned between the side wall 33 and the stopper S', the spiral coil spring 10 is reduced in size to make the second mode.

In the second mode, the spiral coil spring 10 is seated on the valley of the spiral portion 51 of the bolt 50 to resiliently press the spiral portion 51 radially inward so that any unintentional The locking between the lock nut 100 and the bolt 50 is prevented from being released.

In this state, when the lock nut 100 is to be unscrewed by the bolt 50 for maintenance, the operator grips the bending portion 12 and compresses the lock nut 12 in the fastening direction to skip the stopper S ' When the spiral coil spring 10 is positioned in the first mode by being hooked on the stopper S 'so that the lock nut 100 is fastened to the bolt 50 without damaging the lock nut 100, Can be released.

10; Spiral coil spring, 20; Nut, 50; volt

Claims (5)

A lock nut (100) comprising a spiral coil spring (10) accommodated in a nut (20)
A downstream end bending portion 11 is formed at a downstream end of the helical coil spring 10 and is bent in a radially outward direction of the helical coil spring 10,
The spiral coil spring 10 is wound in a spiral shape so that the bolt 50 passes through the downstream end from the upstream end 12 of the spiral coil spring 10 and can be fastened to the spiral coil spring 10,
The nut 20 has a screw thread 22 that is fastened to the bolt 50 on the inner circumferential surface of the nut on the upstream side in the direction of engagement with the bolt 50 and is larger than the inner diameter of the screw 22 The spiral coil spring 10 having an inner diameter is accommodated radially inward at a predetermined interval so as to be inscribed in the radial direction, and the non-spiral coil spring 23 is included on the downstream side in the fastening direction,
The non-threaded portion 23 of the nut 20 includes the upstream end stepped portion 23a and the downstream end stepped portion 23b in the fastening direction in the diametrical direction,
One recessed portion is formed on the surface of the downstream step portion 23b exposed in the central axis direction of the bolt 50. The downstream recessed portion 11 of the helical coil spring 10 is formed in the one recessed portion Optionally detachably inserted,
The upstream end 12 of the spiral coil spring 10 is inscribed in the non-threaded portion 23 and resiliently contacts the upstream end stepped portion 23a,
The non-threaded portion 23 adjacent to the upstream step portion 23a or the upstream step portion 23a is provided with a stopper s elastically contacting the upstream end 12,
When the downstream end folded portion 11 of the helical coil spring 10 is inserted into the one recessed portion, the point where the upstream end 12 of the helical coil spring 10 is fixed by the stopper S The spiral coil spring 10 is reduced in diameter as a position fixing point,
An arch portion 61 recessed toward the head of the bolt 50 is formed at the portion of the downstream step portion 23b located upstream of the one recess 21 in the fastening direction,
In the one recessed portion adjoining the arch portion 61, And a sliding cam surface (60) is formed.
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