KR102335239B1 - Non-welding fence with rotating hook fastening device - Google Patents

Abstract

The present invention provides a non-welded fence with a rotatable hook fastening device, which applies a rotation method to respective ends of a pole and a crossbeam so as to simply and conveniently fasten and fix the pole and the crossbeam within a short time, and prevents the end of the crossbeam from being separated or detached from a pole boss even against an impact applied to the pole. The non-welded fence comprises: a hook locking protrusion formed on the inner circumferential surface by having a rectangular insertion groove formed at a predetermined depth at each end of the crossbeam; and a rotary hook member having a rotary hook flange formed on an end of the opposite side of a rotary hook to be supported by being hung at an end of the pole boss while the rectangular rotary hook is hung on the hook locking protrusion formed on a front end by rotation after being inserted into the insertion groove. Therefore, assembly efficiency can be maximized within a short time without being cumbersome or inconvenient, and a high degree of safety can be secured.

Description

Non-welding fence with rotating hook fastening device

The present invention relates to a non-welding fence having a rotating hook fastening device, and more particularly, by applying a rotation method to each end of a post and a crossbeam, fastening and fixing simply and conveniently within a short time, as well as the impact applied to the crossbar Also relates to a non-welded fence having a rotatable hook fastening device to prevent the end of the crossbar from being separated or separated from the holding boss of the pole.

In general, the fence is composed of a plurality of posts fixed to the ground at a predetermined interval by an anchor method using an anchor, and a cross bar coupled in multiple stages between the posts and the posts.

In the above, in the method of combining the post and the crossbar, most of the non-welding methods are applied in recent years due to various problems caused by welding. connect and fix

Conventional non-welding fences are generally fastened and fixed by bolts or the like with the ends of the cross bars inserted into the post bosses after each end of the cross bars are inserted into the post bosses formed on both sides of the posts.

However, in the event of a collision due to an external force applied to the crossbeam by a vehicle, etc., as the crosspiece is bent in the direction to which the external force is applied and both ends of the crosspiece are pushed to the side to which the external force is applied, the fastening parts between the holding boss and each end of the crosspiece are easily removed. There is a problem of breaking.

Moreover, it also provides a cause that causes secondary accidents such as pedestrian injury as well as vehicle departure due to the breakage of the fastening part.

As described above, in the prior art related to the non-welding fence for fastening the post and the cross bar, as disclosed in Korean Patent Publication No. 10-1781949 and Korean Patent Publication No. 10-0800595, a bracket or vertical connection between the post and the cross bar A technology for fastening and fixing by means has been proposed (hereinafter referred to as 'prior art document 1').

In addition, as disclosed in Korean Patent No. 10-1095059 (hereinafter referred to as 'Prior Art Document 2'), a high-strength rubber bar on the inner surface of the transverse bar is bound to the end of the rubber bar, and a coupling hole formed at the end of the fastening bolt A technology such as a trespassing prevention separator has also been proposed, which is bound to and has a first buffering spring accommodated in the first receiving groove of the clamp, so that the crossbar that has been pushed with a buffering force in the event of a vehicle collision returns to its horizontal original state.

In addition, as disclosed in Korean Patent Application Laid-Open No. 10-2011-0074837 (hereinafter referred to as 'Prior Art Document 3'), a cushioning material in contact with each end of the crossbar is provided inside the connection bracket fixed to the handrail post. A technology to set the rotation angle of the crossbar according to the installation conditions has also been proposed.

However, prior art document 1 has a disadvantage that fracture easily occurs at the fastening portion when a large impact is applied, such as a vehicle collision.

In addition, the prior art document 2 has a disadvantage in that the assembling property is significantly lowered due to the disadvantage that the technical configuration is quite complicated, as well as the manufacturing cost is increased.

In addition, prior art document 3 is for adjusting the angle of the crossbar, and has a disadvantage in that it cannot prevent breakage due to a vehicle collision and is easily separated even by a small external force.

Republic of Korea Patent Publication No. 10-1781949 Republic of Korea Patent Publication No. 10-0800595 Republic of Korea Patent Publication No. 10-1095059 Republic of Korea Patent Publication No. 10-2011-0074837

The specific technical solution of the present invention for solving the various problems of the present invention is to apply a rotation method to each end of the post and the crossbar to simply and conveniently fasten and fix the crossbar in a short time, as well as to prevent the impact applied to the crossbar. An object of the present invention is to provide a non-welded fence having a rotatable hook fastening device to prevent the end of the pole from being separated or separated from the holding boss.

Another specific technical solution of the present invention is to prevent arbitrarily rotating as well as high strength with respect to the part fastened and fixed by the rotation method.

Another specific technical solution of the present invention is to enable the insertion of the reinforcing means to be inserted to reinforce the strength more accurately and stably.

The specific technical solution of the present invention for solving the specific technical solution as described above is each post having at least one stage or more of each holding boss formed on both sides and a fixing flange fixed to the ground at the bottom, and the In the non-welding fence including each crossbar, each end of which is inserted into each holding boss and fastened and fixed by a rotary hook fastening device, the rotary hook fastening device has a rectangular insertion groove at each end of the crossbar a hook engaging projection formed to a predetermined depth and formed on an inner circumferential surface; And a rectangular rotating hook formed at the front end by rotation after being inserted into the insertion groove is caught on the hook engaging jaw, and at the opposite end of the rotating hook, a rotating hook flange is formed that is hung and supported by the end of the holding boss. It includes a rotatable hook member.

The rotary hook member includes a rotary hook corresponding to the insertion groove, a hook rotary shaft having a length corresponding to the hook engaging projection on one surface of the rotary hook, and a rotary hook flange contacting the end of the holding boss at the end of the hook rotary shaft do.

The rotational hook member includes a reinforcement member that is force-fitted while supporting one or both sides of the hook rotation shaft from the outside in order to reinforce strength and prevent self-rotation.

The reinforcing member includes a coupling groove formed to a predetermined depth in the flange of the rotary hook, each insertion hole formed on one or both sides with a hook rotation shaft interposed in the coupling groove, and one or a pair of reinforcing bars corresponding to each insertion hole and a reinforcing bracket in which a reinforcing flange corresponding to the coupling groove is formed.

Each of the guide grooves and guide projections are formed at positions corresponding to each other on the hook rotation shaft and each reinforcing bar.

The present invention applies the rotation method to each end of the pole and the pole to simply and conveniently fasten and fix the pole in a short time, as well as to prevent the end of the pole from being separated or separated from the pole boss against the impact applied to the pole. By doing so, it has the effect of maximizing assembly efficiency without cumbersome or inconvenient within a short time and ensuring high safety.

In addition, it has the effect of preventing the end of the crossbar from being separated or separated from the holding boss of the holding by providing high strength to the part fastened and fixed by the rotation method as well as preventing it from being rotated arbitrarily.

In addition, by allowing the insertion of the reinforcement means to be inserted for strength reinforcement to be made more accurately and stably, it has the effect of further increasing the assembly efficiency while maintaining a higher strength.

1 is a partially exploded perspective view for explaining a first embodiment of the present invention;
Figure 2 is a partially cut-away perspective view of the combined state according to Figure 1;
3 is a flowchart for explaining the assembly process of the present invention;
4 is a partially exploded cut-away perspective view for explaining a second embodiment of the present invention and a cut-away perspective view of a coupled state;
5 is a partially exploded cut-away perspective view for explaining a third embodiment of the present invention and a cut-away perspective view of a coupled state;
6 is a partially exploded and cut-away perspective view for explaining a fourth embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings, and the present invention is not limited or limited by the embodiments.

1 is a partially exploded perspective view for explaining a first embodiment of the present invention, FIG. 2 is a partially cutaway perspective view of the coupled state according to FIG. 1, and FIG. 3 is a flowchart for explaining the assembly process of the present invention.

As shown, the non-welded fence 100 is formed by at least one stage or more of each holding boss 112 on both sides, and a synthetic resin including a fixing flange (not shown) fixed to the ground at the lower part or the like. It has a technical configuration including each of the posts 110 to be manufactured, and each of the cross bars 120 that are fastened and fixed by inserting each end into each of the post bosses 112 .

However, as described in the background of the invention, in the case of a collision due to an external force applied to the crossbar by a vehicle, etc., the crossbar is bent in the direction in which the external force is applied, and both ends of the crossbar are pushed to the side to which the external force is applied. As a result, there is a problem that the fastening part where each end of the holding boss and the crossbar are fastened is easily damaged.

Moreover, it also provides a cause that causes secondary accidents such as pedestrian injury as well as vehicle departure due to damage to the fastening part.

In addition, due to the disadvantage that the technical configuration is quite complicated, assembling property is remarkably deteriorated, and the manufacturing cost is also increased.

The present invention applies the rotation method to each end of the pole and the pole to simply and conveniently fasten and fix the pole in a short time, as well as to prevent the end of the pole from being separated or separated from the pole boss against the impact applied to the pole. An object of the present invention is to provide a non-welded fence having a single rotary hook fastening device.

The rotatable hook fastening device applied to the non-welded fence 100 according to the present invention has a specific technical configuration including a hook engaging projection 10 and a rotatable hook member 20 .

The hook engaging projection 10 has a rectangular insertion groove 12 formed at a predetermined depth at each end of the crossbar 120 in the left and right or up and down directions, so that the rotatable hook member 20 is hooked by rotation on the inner circumferential surface. It has a technical configuration that is formed.

In the above, the hook engaging projection may be integrally formed during molding or manufacturing of the crossbar, and may be manufactured separately and press-fitted or combined.

These hook engaging projections are formed at each end of the crossbar, and as the rotary hook member is rotated, it has a technical configuration that can be fixed or released on the holding boss of the post by the rotary hook member.

The rotatable hook member 20 secures or releases the end of the crosspiece 120 by a rotation method within a short time on the branch boss 112 of the support post 110, as well as the end of the crosspiece 120 is separated or separated from the impact. It has a technical configuration that prevents it from happening.

The rotary hook member 20 is inserted into the insertion groove 12, and then a rectangular rotary hook 22 formed at the tip by rotation is caught on the hook engaging projection 10, and the rotary hook 22 ) has a technical configuration in which a rotating hook flange 24 supported by being caught on the end of the holding boss 122 is formed at the opposite end.

The specific technical configuration of the rotatable hook member 20 is a rotating hook 22 corresponding to the insertion groove 12 and a hook having a length corresponding to the hook engaging projection 10 on one surface of the rotating hook 22 . It is composed of a rotating shaft 23 and a rotating hook flange 24 in contact with the end of the holding boss 110 at the end of the hook rotating shaft 23 . The hook rotating shaft 23 connects the rotating hook 22 and the rotating hook flange 24, and has a smaller diameter than the rectangular rotating hook, and as the rotating hook is inserted into the insertion groove and rotates, the rotating hook is hooked Fixation or release with the jaw can be performed smoothly.

Accordingly, the rotary hook member is inserted by matching the first rotary hook in a direction corresponding to the insertion groove, and then rotates in a state where the rotary hook leaves the insertion groove and is located on the hook locking jaw. It is hung and fixed so that it cannot be pulled out.

In addition, as the rotating hook flange is supported by being hung on the end of the holding boss, the end of the crossbar can be tightly and firmly fixed.

As a result, the end of the crosspiece is not separated or separated due to the rotating hook flange against the impact applied to the crosspiece.

Furthermore, by fixing or releasing the end of the runway on the holding boss of the pole by a simple rotation method rather than a complicated method, as well as preventing the end of the traverse from being separated or separated from the pole boss for the impact applied to the pole, assembling Not only can the superiority of the product be improved, but also the convenience can be improved, and high reliability of the product can be secured.

Therefore, in the present invention, by fixing the end of the crossbar on the holding boss of the holding by a simple rotation method, the assembly can be performed quickly within a short time without cumbersome or inconvenience, thereby maximizing the assembly efficiency.

In addition, by preventing the end of the crossbar from being separated or separated from the supporting boss of the ground even for the impact applied to the crossbar, it has excellent conditions of safety as well as reliability.

4 is a partially exploded cut-away perspective view for explaining a second embodiment of the present invention and a cut-away perspective view of a coupled state.

As shown, in the above configuration, the rotatable hook member is supported and fixed to the post boss of the post after being inserted into the end of the crossbeam. A technical configuration to prevent this is also provided.

The rotating hook member 20 includes a reinforcing member 30 that is force-fitted while supporting both sides of the hook rotating shaft 23 from the outside in order to reinforce strength and prevent self-rotation.

In the above, the reinforcing member 30 includes a coupling groove 32 formed to a predetermined depth in the rotating hook flange 24, and each insert formed on both sides with the hook rotating shaft 23 interposed in the coupling groove 32 and a reinforcing bracket 35 in which a ball 34, a pair of reinforcing bars 35A corresponding to the respective insertion holes 34, and a reinforcing flange 35B corresponding to the coupling groove 32 are formed.

In other words, after inserting the rotary hook of the rotary hook member into the insertion groove and hook locking jaw formed at the end of the crossbeam, rotate and fix it, and then insert the reinforcing bar of the reinforcing bracket by the force fit method to fix it.

Accordingly, by fixing the end of the crossbar on the holding boss of the holding in a short time by the rotation method as described above, and then inserting the reinforcing bracket again and fixing it, not only the strength due to the reinforcing bracket but also the rotating hook member can be arbitrarily fixed. As it is fixed without rotation, the reliability of the product can be further increased.

As a result, it fundamentally prevents the end of the crossbar from being separated or separated due to the high strength of the rotary hook member against the impact applied to the crossbeam, as well as preventing the rotational hook member from arbitrarily rotating, so the separation of the rotary hook member Alternatively, it is possible to secure even higher reliability by preventing departure.

5 is a partially exploded cut-away perspective view for explaining a third embodiment of the present invention and a cut-away perspective view of a coupled state.

As shown, in the above configuration, the rotatable hook member is supported and fixed to the post boss of the post after being inserted into the end of the crossbeam. A technical configuration to prevent this is also provided.

The rotating hook member 20 includes a reinforcing member 30 that is press-fitted while supporting one surface of the hook rotating shaft 23 from the outside in order to reinforce strength and prevent self-rotation.

In the above, the reinforcing member 30 includes a coupling groove 32 formed to a predetermined depth in the rotating hook flange 24, and an insertion hole formed at one side with the hook rotating shaft 23 interposed in the coupling groove 32 ( 34), and a reinforcing bracket 35 in which one reinforcing bar 35A corresponding to the insertion hole 34 and a reinforcing flange 35B corresponding to the coupling groove 32 are formed.

The third embodiment of the present invention is another embodiment of the second embodiment of the present invention, and only some technical components are different from that of FIG. 3, but the operation and effect are the same, and thus detailed description of the operation and effect will be omitted.

6 is a partially exploded cross-sectional view for explaining a fourth embodiment of the present invention.

As shown, in the above configuration, with the technology applied to the second and third embodiments of the present invention, a technical configuration that can be accurately and stably inserted when the reinforcing bracket, which is a reinforcing member, is inserted into the rotatable hook member also provides

The hook rotation shaft 23 and each of the reinforcing bars 35A further include that guide grooves 40A and guide protrusions 40B are formed at positions corresponding to each other.

In other words, when the reinforcing bar of the reinforcing bracket, which is a reinforcing member, is inserted in a state in which the end of the crossbar is fixed by the rotating hook member, the correct position and more stably inserted by each guide groove and guide protrusion formed at positions corresponding to each other can be

Accordingly, it is possible to prevent the rotational hook member from being arbitrarily rotated together with strength reinforcement, which is a technical characteristic of the reinforcing bracket.

10: hook engaging jaw 12: insertion groove
20: rotary hook member 22: rotary hook
23: hook rotation shaft 24: rotation hook flange
30: reinforcing member 32: coupling groove
34: insertion hole 35: reinforcement bracket
35A: reinforcing bar 35B: reinforcing flange
40A: guide groove 40B: guide projection
100: non-welded fence
110: holding 112: holding boss
120: crossbar

Claims (5)

At least one stage of each holding boss is formed on both sides, and each holding having a fixing flange fixed to the ground is formed at the bottom, and each end is inserted into each of the holding bosses to be fastened and fixed by a rotary hook fastening device In the non-welding fence including each cross bar to be,
The rotary hook fastening device,
Rectangular-shaped insertion grooves are formed at each end of the crossbar to a predetermined depth, the hook engaging projection formed on the inner peripheral surface; and
After being inserted into the insertion groove, a rectangular rotating hook formed at the front end by rotation is caught on the hook engaging jaw, and at the opposite end of the rotating hook, a rotating hook flange that is hung and supported by the end of the holding boss is formed A non-welded fence having a rotary hook fastening device including a rotary hook member. According to claim 1,
The rotary hook member includes a rotary hook corresponding to the insertion groove, a hook rotary shaft having a length corresponding to the hook engaging projection on one surface of the rotary hook, and a rotary hook flange contacting the end of the holding boss at the end of the hook rotary shaft A non-welded fence equipped with a rotating hook fastening device. 3. The method of claim 2,
A non-welded fence having a rotary hook fastening device, comprising a reinforcement member that is force-fitted while supporting one or both sides of the hook rotation shaft from the outside in order to reinforce strength and prevent self-rotation to the rotary hook member. 4. The method of claim 3,
The reinforcing member includes a coupling groove formed to a predetermined depth in the rotating hook flange, each insertion hole formed on one or both sides with a hook rotation shaft interposed in the coupling groove, and one or a pair of reinforcing bars corresponding to each insertion hole and a non-welded fence having a rotating hook fastening device including a reinforcing bracket having a reinforcing flange corresponding to the coupling groove. 5. The method of claim 4,
Non-welding fence provided with a rotary hook fastening device further comprising the respective guide grooves and guide projections formed at positions corresponding to each other on the hook rotation shaft and each reinforcing bar.

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