JP2011001753A - Anti-slip structure of step bolt and method for preventing slip of the step bolt - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an anti-slip structure of a step bolt, which prevents a deterioration of an anti-slip function even in the application of anti-corrosive coating, and which can be applied to an existing steel tower or electric pole.SOLUTION: This anti-slip structure 10 of the step bolt 20 for being attached to the steel tower or electric pole includes a spiral 11 which is spirally wounded around the step bolt 20, and a fixing ring 12 for fixing both ends of the spiral 11 to the step bolt 20.

Description

  The present invention relates to a structure and method for preventing slipping of a step bolt attached to a steel tower or a utility pole for raising and lowering.

  Step bolts are attached to the steel towers and utility poles so that workers can move up and down during repair work. Conventionally, such step bolts have been formed with cuts of less than about 1 mm on the surface for the purpose of preventing slippage. However, when such a step bolt is coated to prevent corrosion, there is a problem that the notch is filled with paint and the anti-slip function is lowered.

  As a step bolt having such an anti-slip function, for example, Patent Document 1 describes a step bolt in which a number of bumps having a desired shape are formed. By using such a step bolt, it is possible to prevent the anti-slip function from being deteriorated even when coating for preventing corrosion is performed.

JP-A-10-243536

However, in order to apply the step bolt described in Patent Document 1 to existing steel towers and utility poles, it is necessary to replace all the step bolts, which takes time and cost.
The present invention has been made in view of the above problems, and the purpose of the present invention is to provide a step bolt that can be applied to existing steel towers and utility poles without reducing the anti-slip function even when coating is applied to prevent corrosion. It is to provide a non-slip structure.

  An anti-slip structure for a step bolt according to the present invention is an anti-slip structure for a step bolt attached to a steel tower or a utility pole, and includes a spiral member wound around the step bolt in a spiral manner, and both ends of the spiral member. And a fixing member for fixing to the step bolt.

  Further, the step bolt anti-slip method of the present invention is a step bolt anti-slip method attached to a steel tower or utility pole, wherein a spiral member is wound around the step bolt, and both ends of the spiral member are attached to the step. It is fixed to a bolt with a fixing member.

  According to the present invention, the spiral bolt wound around the step bolt is fixed by the fixing member, so that the grip of the step bolt can be secured. Can also have a non-slip function on the surface. Moreover, since it is the structure which winds a helical member around a step bolt and fixes it with a fixing member, it can apply also to the step bolt attached to the existing steel tower or the utility pole.

It is a figure which shows the anti-slip | skid structure of a step bolt. It is a figure which shows a fixing ring, (A) shows the open state, (B) shows the closed state.

Hereinafter, an embodiment of the anti-slip structure for a step bolt of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a diagram showing an anti-slip structure 10 for a step bolt 20 according to this embodiment. The step bolt 20 is made of a rod-shaped steel material having a head 21 at one end and a threaded portion 22 in the vicinity of the end at the other end. The step bolt 20 is composed of a pair of nuts 23 and 24 which are screwed into the threaded portion 22 in a state where the threaded portion 22 is inserted into a bolt hole 1A formed in the angled material 1 constituting the steel tower. It is fixed to the angle member 1 by being sandwiched.

  As shown in FIG. 1, the anti-slip structure 10 of the present embodiment includes a spiral 11 wound around the outer periphery of a step bolt 20 and a fixing ring 12 that fixes both ends of the spiral 11. The spiral 11 is made of, for example, a material having corrosion resistance such as aluminum or a metal containing aluminum, formed in a spiral shape with an interval of about 2 cm, and the surface is subjected to corrosion resistance processing.

  2A and 2B are diagrams showing the fixing ring 12, in which FIG. 2A shows an open state and FIG. 2B shows a closed state. As shown in the figure, the fixing ring 12 has a pair of arcuate members 13 and 14 connected to be rotatable. As these arc-shaped members 13 and 14, those made of plastic having durability and corrosion resistance can be used. Male and female claw portions 15 and 16 are formed on the ends of the pair of arcuate members 13 and 14 opposite to each other, and the male claw portion 16 is fitted into the female claw portion 15. Thus, the arc-shaped members 13 and 14 can be connected in an annular shape.

  Further, a cutout portion 14 </ b> A is formed on the side surface of one arcuate member 14. The fixing ring 12 is firmly inserted in the state where the end portion of the spiral 11 is sandwiched by fitting the male and female claw portions 15 and 16 in a state where the spiral 11 is accommodated in the notch portion 14A and applying pressure from the surroundings. It is fixed to the step bolt 20. The spiral 11 is held in a state of being wound around the step bolt 20 by fixing both ends thereof by the fixing ring 12. As described above, the spiral 11 is wound around the step bolt 20, whereby a grip on the surface can be secured, and the step bolt 20 can be provided with an anti-slip function.

Hereinafter, a method for applying the anti-corrosion coating to the step bolt 20 and attaching the anti-slip structure 10 will be described.
First, when attaching the anti-slip structure 10, the surface of the step bolt 20 is subjected to corrosion resistance processing.
Next, the spiral 11 is wound around the step bolt 20. Note that the winding work of the spiral 11 can be performed using pliers or the like.

Next, the end of the spiral 11 is accommodated in the notch 14A in a state where the fixing ring 12 is opened with the pair of arcuate members 13 and 14 at positions corresponding to both ends of the spiral 11 of the step bolt 20. The male claws 16 are fitted into the female claws 15 by rotating the pair of arcuate members 13, 14. Further, for example, pressure is applied to the fixing ring 12 from the outer peripheral side by caulking with pliers. As a result, the fixing ring 12 is firmly fixed to the step bolt 20 and the end portion of the spiral 11 is firmly held.
The anti-slip structure 10 can be fixed to the step bolt 20 by the above process.

  According to the present embodiment, the spiral 11 is wound around the step bolt 20, and the spiral 11 is fixed by the fixing ring 12, so that the grip of the surface is secured by the spiral 11. Even if it is the applied step bolt 20, the step bolt 20 can be provided with an anti-slip function.

  In addition, it can be attached to the step bolt 20 provided on the existing steel tower or utility pole, and the step bolt 20 has the corrosion resistance and anti-slip function without replacing the step bolt 20 with one having anti-corrosion and anti-slip function. The cost can be reduced. Moreover, since the installation work of the anti-slip structure 10 is simpler than replacing the step bolt 20, the workability can be improved.

  In the present embodiment, the end of the spiral 11 is fixed to the step bolt 20 by the fixing ring 12. However, the present invention is not limited to this, and the configuration is not limited thereto if the end of the spiral 11 can be firmly fixed to the step bolt 20. It doesn't matter.

DESCRIPTION OF SYMBOLS 1 Angle material 10 Anti-slip structure 11 Spiral 12 Fixing rings 13 and 14 Arc-shaped member 14A Notch 15 Female nail | claw part 16 Male nail | claw part 20 Step bolt 21 Head 22 Screw part 23, 24 Nut

Claims (2)

A step bolt anti-slip structure attached to a steel tower or utility pole,
A helical member spirally wound around the step bolt;
And a fixing member that fixes both ends of the spiral member to the step bolt. A method for preventing slipping of a step bolt attached to a steel tower or utility pole,
A helical member is wound around the step bolt,
A method for preventing slipping of a step bolt, wherein both ends of the spiral member are fixed to the step bolt by a fixing member.

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