JP6609732B2 - Spacer for lock bolt - Google Patents

Description

  The present invention relates to a lock bolt spacer for holding a lock bolt at the center of an excavation hole excavated in the ground when the lock bolt is installed on the ground such as a slope.

  In the civil engineering field, excavate the ground such as slopes into a cylindrical shape, insert a long lock bolt (anchor) into the drill hole, and then inject rock bolt grout material (non-shrink mortar material) A lock bolt method (earth anchor method) is known in which a rock bolt is fixed in the ground by hardening the grout material, and a rock wall or a frame is formed using the lock bolt. In such a lock bolt method, it is necessary to position the lock bolt at the center of the excavation hole and make the thickness of the grout material around the lock bolt (so-called cover thickness) constant.

  And the spacer for lock bolts like patent document 1 is used as a member for positioning a lock bolt in the center of an excavation hole. The spacer for a lock bolt of Patent Document 1 includes a fixing cylinder part for gripping the lock bolt, and a plurality of elastic arms protruding vertically and horizontally from the axis of the fixing cylinder part. By caulking outside the lock bolt and fixing it to the lock bolt, inserting the integrated lock bolt into the drilling hole and pressing the end of each elastic arm against the inner wall of the drilling hole, It can be positioned at the center.

JP-A-4-18917

  However, the lock bolt spacer according to Patent Document 1 requires that the fixing cylinder portion be caulked (crimped) from the outside when it is fixed to the lock bolt, so that the fixing work to the lock bolt requires a lot of labor. There is a problem that. Further, if the fixing cylinder portion is not sufficiently fixed to the lock bolt, there is a problem that the lock bolt is easily displaced in the longitudinal direction when the lock bolt is inserted into the excavation hole. In addition, if the lock bolt is inserted into the excavation hole so that the slit of the fixing cylinder portion is located on the lower side, the elastic arm located on the lower side will spread outward due to the load of the lock bolt. It becomes impossible to accurately position the center of the hole.

  The object of the present invention is that it can be securely attached (fixed) to the lock bolt without taking time and effort even when the lock bolt is inserted into the excavation hole. An object of the present invention is to provide a lock bolt spacer capable of accurately positioning the lock bolt at the center of the excavation hole without deviating from the predetermined position of the lock bolt even in the case of the action of.

In order to solve the above-mentioned problems, the invention described in claim 1 is a lock bolt spacer for holding a lock bolt at the center position of a cylindrical excavation hole excavated in the ground such as a slope. It is formed by bending a long cylindrical steel wire, and the middle of the steel wire is bent into a circular shape in which a part is overlapped in front and back, and both ends of the steel wire are bent circularly When a force in an opening direction acts on the bifurcated projecting portion from the center of the portion in the same plane as the circular bent portion in the radial direction , the force is applied to the circular bent portion. It is characterized by acting as a force to narrow the diameter .

  The invention described in claim 2 is characterized in that, in the invention described in claim 1, an angle formed by the bifurcated protruding portion is 65 ° to 75 °.

  The invention described in claim 3 is the invention described in claim 1 or 2, wherein an inner diameter of the circular bent portion is 18 mm to 28 mm, and a length of the bifurcated protruding portion is 22 mm to It is characterized by being 40 mm.

  The spacer for a lock bolt according to claim 1 is formed by bending a long cylindrical steel wire, and the middle of the steel wire is bent into a circular shape in which a part of the steel wire is overlapped on the front and back. In addition, both ends of the steel wire have a structure projecting in an acute-angled bifurcated shape radially from the center of the circular bent portion, and the circular bent portion can exhibit a function of gripping the lock bolt (the lock bolt The holding portion) and the bifurcated protruding portion can function to secure a space for positioning the lock bolt at the center of the excavation hole and injecting the grout material.

  Therefore, the lock bolt spacer according to claim 1 can be obtained by applying an inward force to the bifurcated protruding portion and expanding the diameter of the circular bent portion so that the lock bolt is inserted into the circular bent portion. It can be attached to the lock bolt very easily. In addition, deformed steel is often used for the lock bolt. In the lock bolt spacer according to claim 1, the circular bent portion is fitted into the circumferential groove of the deformed steel. Even when an unexpected force is applied during insertion, the position is not displaced along the longitudinal direction of the lock bolt.

  Furthermore, if the lock bolt is inserted into the excavation hole so that the bifurcated protrusion is on the lower side, the load of the lock bolt is applied after insertion, and even if a force in the direction of opening the bifurcated protrusion is applied, the force is Since the lock bolt absorbs the force by acting as a force for narrowing the diameter of the circular bent portion, the distance between the bifurcated protruding portions does not increase, so that the lock bolt can be reliably held at the center of the excavation hole.

  In the lock bolt spacer according to claim 2, since the angle formed by the forked protrusion is 65 ° to 75 °, the forked protrusion is grasped with the palm of one hand so that both ends of the steel wire are brought close to each other. The diameter of the circular bent portion can be expanded and the lock bolt can be inserted into the circular bent portion. Therefore, according to the lock bolt spacer of the second aspect, it is possible to attach the lock bolt to the lock bolt very easily with one hand.

  In the lock bolt spacer according to claim 3, the inner diameter of the circular bent portion and the length of the bifurcated protruding portion are adjusted within a specific range. Without tightening the part with strong force, the circular bent part can be expanded and the lock bolt can be inserted, and even if unexpected force is applied, the steel wire of the bifurcated protruding part will not be bent and damaged .

It is explanatory drawing which shows the spacer for lock bolts (a is a front view, b is a perspective view). It is explanatory drawing which shows the state which inserted the lock bolt which attached the spacer for lock bolts into the excavation hole (a is explanatory drawing which shows the state which looked at the excavation hole which inserted the lock bolt from the side, b is It is explanatory drawing (perspective view) which shows the attachment part to the lock bolt of the spacer for lock bolts, c is explanatory drawing which shows the state which looked at the excavation hole which inserted the lock bolt from the front.

<Structure of spacer for lock bolt>
Hereinafter, one embodiment of the spacer for lock bolts concerning the present invention is described in detail based on a drawing. FIG. 1 shows a lock bolt spacer (clip) according to the present invention, and the lock bolt spacer 1 is a cylindrical steel wire (having a heat treatment such as quenching) having a diameter of about 2 mm. It is formed by bending, and the surface is subjected to rust prevention treatment (zinc plating treatment).

  The intermediate portion of the steel wire constituting the lock bolt spacer 1 functions as a portion for holding the lock bolt (lock bolt holding portion 3), and is bent into a circle having a diameter (inner diameter) of about 18 mm. The lower part overlaps the front and rear (overlapping part 4). The central angle of the overlapping portion 4 (the central angle centered on the center of the lock bolt holding portion 3) is about 70 °.

  Further, both ends of the steel wire constituting the lock bolt spacer 1 are for positioning the lock bolt at the center of the excavation hole and injecting the ground material when the mounted lock bolt is inserted into the excavation hole. It functions as a portion for securing a space, and is bent so as to protrude radially from the center of the lock bolt holding portion 3 to form an acute angle bifurcated portion (bifurcated protruding portion 2). . The bifurcated protruding portion 2 has a length of each steel wire of about 40 mm, and is in an angled state of about 70 °.

<How to use the spacer for lock bolt>
The lock bolt spacer 1 configured as described above is mounted on a lock bolt and used in a lock bolt method (earth anchor method) such as a slope (slope). The rock bolt method is to drill a cylindrical hole on the slope (slope) using a drilling machine, and insert a long cylindrical rock bolt (such as deformed steel) into the drill hole. After that, it is a construction method in which the grout material is solidified together with the lock bolt by filling the inside of the excavation hole with the grud material.

  When attaching the lock bolt spacer 1 to the lock bolt, the diameter of the lock bolt holding portion 3 is expanded by holding the bifurcated protruding portion 2 with the palm of one hand and tightening both ends of the steel wire closer to each other. And insert a lock bolt through it. Since the lock bolt is usually made of deformed steel, in the lock bolt spacer 1 mounted as described above, the lock bolt holding portion 3 is fitted in the circumferential groove on the surface of the lock bolt. Become.

  When the lock bolt spacer 1 is attached to a deformed steel lock bolt, the diameter (inner diameter) of the lock bolt holding portion 3 of the lock bolt spacer 1 is made smaller by 1 to 2 mm than the diameter of the lock bolt. Is preferred. Therefore, the lock bolt spacer 1 having a diameter (inner diameter) of 22 mm of the lock bolt holding portion 3 described above can be suitably used for a lock bolt that is a deformed steel having a diameter of about 19 mm.

  Further, two lock bolt spacers 1 are preferably attached to one lock bolt, and three or more can be attached. And when attaching two spacers 1 and 1 for lock bolts to a lock bolt, when a lock bolt is inserted in a drilling hole, the part of 5-10 cm from the deepest part of a drilling hole, and opening of a drilling hole Each of the lock bolt spacers 1 and 1 is attached so as to be located in a portion that is 5 to 10 cm from the portion. Further, these lock bolt spacers 1 and 1 are attached to the lock bolt in the same direction (so as to have the same phase with respect to the axis of the lock bolt). On the other hand, when the three lock bolt spacers 1, 1, 1 are attached to the lock bolt, as described above, the lock bolt spacers 1, 1 are positioned so as to be positioned between the lock bolt spacers 1, 1. One lock bolt spacer 1 is attached to the lock bolt in the same direction (so as to have the same phase with respect to the axis of the lock bolt).

  Then, the lock bolt on which the lock bolt spacers 1 and 1 are mounted as described above is inserted into an excavation hole formed by excavating the ground. FIG. 2 shows a state in which the lock bolt on which the lock bolt spacers 1 and 1 are mounted is inserted into an excavation hole (diameter: about 65 mm) formed by excavating an inclined slope. The length of the lock bolt is adjusted to a length of 1,000 to 5,000 mm according to the situation at the site, the type of building constructed using the lock bolt, and the like. Further, as shown in FIG. 2, the excavation hole is excavated so that the base end of the inserted lock bolt protrudes from the ground surface by about 100 mm ± 50 mm.

  When the lock bolt R to which the lock bolt spacers 1 and 1 are attached is inserted into the excavation hole H, the lock bolt spacers 1 and 1 are inserted so that the bifurcated protruding portions 2 are on the lower side. When the lock bolt R is inserted into the excavation hole H as described above, the load of the lock bolt R is applied after the insertion, and a force in the opening direction acts on the bifurcated protruding portion 2 of each lock bolt spacer 1, 1. However, since the force acts as a force for narrowing the diameter of the lock bolt holding portion 3 and the lock bolt R absorbs the force, the distance between the forked protrusions 2 of the lock bolt spacers 1 and 1 is increased. The lock bolt R is held at the center of the excavation hole H (see FIG. 2C).

  Then, after inserting the lock bolt R into the insertion hole H as described above, it is checked whether the lock bolt R is located at the center of the excavation hole H using a dedicated measuring jig (not shown). For example, when the lock bolt R is installed in the excavation hole H having a diameter of about 90 mm, it is measured whether the length from the center of the lock bolt R to the peripheral wall of the excavation hole H is about 45 mm. Then, after confirming that the rock bolt R is located at the center of the excavation hole H, the inside of the excavation hole H is filled with a grud material (cement and water), and is cured for a sufficient amount of time. The lock bolt construction is completed by solidifying the ground material (and the lock bolt spacers 1, 1).

<Effect of spacer for lock bolt>
As described above, the spacer 1 for the lock bolt is formed by bending a long cylindrical steel wire, and the middle of the steel wire is bent into a circular shape in which a part of the steel wire is overlapped back and forth. (Lock bolt holding part 3) The steel wire has a structure in which both ends of the steel wire protrude from the center of the circular bent portion in a radial bifurcated shape, and the lock bolt holding part 3 holds the lock bolt R. The bifurcated protruding portion 2 can function to secure a space for positioning the lock bolt R at the center of the excavation hole H and injecting the grout material.

  Therefore, the lock bolt spacer 1 inserts the lock bolt R into the lock bolt holding portion 3 in a state where the inward force is applied to the bifurcated protruding portion 2 and the diameter of the lock bolt holding portion 3 is expanded. It is possible to attach the lock bolt R very easily by simply making it. Further, since the lock bolt holding portion 3 is fitted into the circumferential groove of the deformed steel, the lock bolt spacer 1 is inserted into the excavation hole H even when an unexpected force is applied. The position is not displaced along the longitudinal direction of the lock bolt R. Further, if the lock bolt R is inserted into the excavation hole H so that the bifurcated projecting portion 2 is on the lower side, the load of the lock bolt R is applied after the insertion, and a force in the direction of opening the bifurcated projecting portion 2 is applied. Even in this case, the force acts as a force for narrowing the diameter of the lock bolt holding portion 3, and the lock bolt R absorbs the force, so that the interval between the bifurcated protruding portions 2 does not widen. Can be securely held in the center of the.

  In addition, the lock bolt spacer 1 has an angle formed by the bifurcated projecting portion 2 of 70 °, and is locked by gripping the bifurcated projecting portion 2 with the palm of one hand and bringing both ends of the steel wire closer. Since the diameter of the bolt holding part 3 can be expanded and the lock bolt R can be inserted through the lock bolt holding part 3, it can be attached to the lock bolt R with one hand very easily.

  Furthermore, since the lock bolt spacer 1 has an inner diameter of 18 mm and the bifurcated protruding portion 2 has a length of 40 mm, when the lock bolt spacer 1 is mounted on the lock bolt R, the bifurcated protruding portion. The lock bolt holding portion 3 can be expanded and the lock bolt R can be inserted without tightening 2 with a strong force, and the steel wire of the bifurcated protruding portion 2 is bent even when an unexpected force is applied. It will not be damaged.

<Example of changing the lock bolt spacer>
The configuration of the spacer for the lock bolt according to the present invention is not limited to the aspect of the above embodiment, and the configuration of the bifurcated protruding portion, the shape of the lock bolt holding portion, the overlapping portion, the structure, the material, etc. The present invention can be changed as appropriate without departing from the spirit of the present invention.

  For example, the lock bolt spacer according to the present invention is not limited to the one formed by bending a steel wire as in the above embodiment, but can be changed to one formed by bending a prismatic steel material. It is. Further, the spacer for the lock bolt is not limited to a simple cylindrical shape with a bifurcated protruding portion as in the above-described embodiment, and may be one in which the tip of the bifurcated protruding portion is bent into an L shape or a circular shape. good. In addition, it is also possible to change to the one where a cap for increasing the ground contact area with the peripheral wall of the excavation hole is attached to the tip of the bifurcated protrusion.

  Since the spacer for a lock bolt according to the present invention has an excellent effect as described above, it can be suitably used as an auxiliary member or jig for slope work in the field of civil engineering construction.

1 ・ ・ Spacer for lock bolt 2 ・ ・ Forked protrusion 3 ・ ・ Lock bolt holding part 4 ・ ・ Overlapping part

Claims (3)

A lock bolt spacer for holding a lock bolt at the center position of a cylindrical excavation hole excavated in the ground such as a slope,
It is formed by bending a long cylindrical steel wire,
The middle of the steel wire is bent into a circular shape with parts overlapped in front and back, and both ends of the steel wire are acutely angled radially from the center of the circular bent portion in the same plane as the circular bent portion . Protrusively bifurcated ,
A lock bolt spacer, wherein when a force in an opening direction is applied to the bifurcated protruding portion, the force acts as a force to narrow the diameter of the circular bent portion .   The lock bolt spacer according to claim 1, wherein an angle formed by the bifurcated protruding portion is 65 ° to 75 °.   3. The lock bolt spacer according to claim 1, wherein an inner diameter of the circular bent portion is 18 mm to 28 mm, and a length of the bifurcated protruding portion is 22 mm to 40 mm.

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