JP4859417B2 - Rock bolt construction method and attachment - Google Patents

Description

  The present invention relates to a rock bolt construction method and an attachment, and more particularly to a rock bolt construction method and an attachment capable of treating spring water generated from a bore hole during the construction of the rock bolt.

When a hole is drilled in a tunnel or on a slope to try to place a rock bolt, underground water may spring out through the hole. Such spring water not only becomes an obstacle to rock bolting work, but also the work position is submerged, resulting in deterioration of the construction environment. In addition, when a fixing material is used for fixing the lock bolt, the fixing material flows and fixing becomes insufficient, or the underground water pressure becomes high and the ground becomes unstable.
In general, when there is a lot of spring water, a drainage work is carried out separately by placing a perforated pipe into the ground to drain the water. As another spring water treatment method, a technique (first conventional technique) has been proposed in which underground water is guided using an anchor having a water collecting joint and drained effectively from the ground surface (Patent Document 1). And Patent Document 2). In addition, a technique (second prior art) has been proposed in which a hole-cutting portion is closed with a mouth closing tool when grout is injected as a fixing material (see Patent Document 3).
Japanese Patent Publication No. 6-102891 Japanese Patent No. 2736295 JP-A-10-96400

In the drainage work where a perforated pipe is placed in the ground to drain water, if there is a water permeable layer, water will flow in from there and collapse, and the entire pipe will not be saturated. As a result, there is a problem that the perforated pipe existing in the upper part does not sufficiently perform the drainage function.
In addition, the first conventional technology requires anchors with a special structure, but when rock holes are drilled at a predetermined pitch on the ground for the construction of rock bolts, the same amount of spring water is generated in all the holes. Not that, there are holes that allow water and holes that do not. In the first prior art, all holes need to be anchored with a special structure, which is inefficient.
In addition, the second prior art closes the mouth of the drill hole and injects it, but for drilling holes where a large amount of spring water is coming out, this technique loses the mouth closing tool and grout material to the water pressure. So it is difficult to apply.
From the above, an object of the present invention is to enable selective and immediate treatment of spring water when spring water is generated while performing normal rock bolt construction or when it is necessary to perform spring water treatment.
Another object of the present invention is to be able to treat large amounts of spring water.

According to the present invention, there is provided a lock bolt construction method using a hollow lock bolt having a threaded portion at least on a base end side, and a bowl-shaped cap and the hollow lock bolt fixed to the inside of the bowl-shaped cap. A step of preparing an attachment having a hollow connecting portion provided with a screw portion connected to the screw portion and a non-threaded portion in which a through hole is formed, and a drain port attached to the bowl-shaped cap to drain spring water; A step of driving the hollow lock bolt into the ground, and after the driving, the connection portion of the attachment is screwed into a screw portion of the hollow lock bolt to pass through the internal space of the hollow lock bolt and the drainage port of the attachment. According to a lock bolt construction method comprising a step of communicating through a hole and covering the mouth of the hollow lock bolt with the bowl-shaped cap. It is achieved.
Further, according to the present invention, in the attachment for treating spring water generated during construction of a hollow lock bolt, the above-mentioned problem is a bowl-shaped cap and a screw fixed to the inside of the bowl-shaped cap and provided on the hollow lock bolt. A hollow connecting part having a threaded part connected to the part and a non-threaded part in which a through-hole is formed, and a drainage port attached to the bowl-shaped cap to drain the spring water, the connecting part of the attachment An attachment that connects the interior of the hollow lock bolt with the drainage port of the attachment through the through hole by screwing into the threaded portion of the hollow lock bolt, and covers the mouth of the hollow lock bolt with the bowl-shaped cap Is achieved.

According to the present invention, after preparing an attachment provided with a connection portion and a drain port connected to the thread portion of the hollow lock bolt, and after placing the hollow lock bolt in the ground, the attachment to the thread portion of the hollow lock bolt Since the connection part of the hollow lock bolt is screwed to connect the interior space of the hollow lock bolt and the drainage port of the attachment, there is no need to place an anchor with a special structure, and spring water is generated while performing normal lock bolt construction. When it is necessary, or when it becomes necessary to perform spring water treatment, it has become possible to perform spring water treatment immediately and selectively using an attachment. In addition, it was possible to improve the construction environment by treating the springs at the same time with the rock bolts, and to stabilize the ground. In addition, the groundwater can be used with clean water.
Further, according to the present invention, the main body includes a connection portion that can be connected to a screw portion provided on the lock bolt, and a drain port that drains the spring water, and the connection portion is screwed into the screw portion of the lock bolt. Thus, the attachment is configured to communicate the interior of the lock bolt with the drain through the main body, so that the lock bolt can be driven using the attachment and the water can be selectively applied to the hole from which the water has come out. Water treatment can be performed.
According to the attachment of the present invention, it is possible to attach / detach to / from the lock bolt using the threaded portion of the lock bolt, it can be used only at the time of the spring treatment, and is economical because it can be removed. This will not obstruct the injection work or nut tightening work required when installing the lock bolt.
Moreover, according to the attachment of this invention, since there is nothing which stops water forcibly, water pressure does not apply and it can process a lot of springs.

  The main body includes a threaded portion connected to a screw portion provided on the hollow lock bolt and a drain port for draining spring water, and the lock bolt is inserted into the threaded portion of the lock bolt by screwing the connection portion into the threaded portion of the lock bolt. Prepare an attachment that communicates the interior of the unit with the drain. In such a state, when a lock bolt is installed in the ground and spring water is generated from the borehole, the connection portion of the attachment is screwed into the screw portion of the hollow lock bolt to drain the internal space of the hollow lock bolt and the attachment. Connect the mouth and drain the spring water from the drain.

(A) General Description FIG. 1 is a schematic explanatory diagram of a rock bolt construction method and a drainage attachment according to the present invention. As shown in Fig. 1 (a), a tunnel is excavated in the natural ground 1 with an excavator, support and sprayed concrete are constructed on the inner wall 3 of the tunnel space 2, and then a number of locks are placed on the inner wall of the tunnel space. Bolt 4 will be installed, and the natural ground near the tunnel inner wall of natural ground 1 will be supported.
If the lock bolt 4 is a pipe type lock bolt that expands and expands by pressurizing and supplying a fluid to the inside of the lock bolt 4, a borehole having a predetermined depth from the tunnel space 2 toward the ground 1 (Not shown) is drilled, and a pipe-type lock bolt 4 is driven into the bore hole. After the driving, a fluid supply adapter (not shown) is attached to the mouth side sleeve 4b, and pressure is applied through the adapter. Fluid is supplied to the inside of the main body 4a of the pipe-type rock bolt, and the pipe-type rock bolt main body 4a is inflated and expanded to be brought into close contact with the hole wall of the bore hole. Thereafter, the fluid supply adapter is removed (see FIG. 1B). In addition, 4f is a washer for tightening the lock bolt to the ground, and 4g is a washer locking hook.
When spring water is generated from the rock bolt, the spring water drainage attachment 5 is connected to the mouth side sleeve 4b of the rock bolt. The attachment 5 for spring water drainage is provided with a bowl-shaped cap 5a as shown in FIG. 1 (c), and a threaded portion provided on a lock bolt and a connecting portion 5b connectable to the inside of the cap are fixed. In addition, a drain port 5c is attached for draining water that flows out through the lock bolt 4 from the cap inner space to the outer space. Connecting portion 5b has become cylindrical, provided with a threaded portion 5b ₁ and the non-threaded portion 5b _2, a plurality of through holes 5b ₃ are formed in the non-threaded portion.

When spring water is generated from the lock bolt, the screw portion of the connection portion 5b of the attachment 5 is screwed into the screw portion 4d formed inside the mouth-side sleeve 4b of the lock bolt, and the mouth-side sleeve 4a is covered with the cap 5a. As a result, spring water occurs through the inner space 4e and mouth side sleeve 4b of the lock bolt 4 is discharged to the outside from the drain port 5c through the through hole 5b ₃ attachments. In addition, the hose 6 can be attached to the drain port 5c to guide the spring water to an appropriate place for treatment.
The above is the outline of the lock bolt method and the drainage attachment, but the lock bolt 4 and the drainage attachment 5 that can be used in the present invention need to have at least the following configurations. That is, as the lock bolt 4, a hollow lock bolt having a screw portion 4d at least on the base end side is used. The threaded portion 4d connects the drainage attachment 5, and a lock bolt manufactured by rolling process uses a threaded portion originally formed on the inner and outer peripheries thereof. As the attachment 5, one having a hollow main body (for example, a cap) 5 a provided with a connecting portion 5 b that can be freely connected to the screw portion 4 d of the lock bolt 4 and a drain port 5 c is used.
The attachment 5 is effective when applied to pattern bolts (lock bolts radiating from the wall surface) in the tunnel shown in FIG. Further, the slope 7 shown in FIG. 2 is effective when applied when the lock bolt 4 is driven in the horizontal direction.
As described above, the attachment 5 is selectively attached only to the lock bolt at the location where the water comes out, and the spring water is treated. If the quality of this spring water is good, water is used effectively.

(B) 1st Example FIG. 3 is explanatory drawing of the lock bolt concerning 1st Example, FIG. 3 (a) is an external appearance top view of a pipe type lock bolt, FIG.3 (b) is a pipe type lock bolt. 3C is a cross-sectional view taken along line AA in FIG. 1B, and FIG. 3D is a cross-sectional view taken along line BB in FIG. 1B.
The pipe-type lock bolt 4 includes a pipe body (hereinafter referred to as “main body”) 4a having a predetermined length, a mouth-side sleeve 4b which is fitted on the mouth side of the main body 4a and restrains and reinforces the mouth side, and the tip of the body 4a. And a distal end sleeve 4c that restrains and reinforces the distal end portion. The main body 4a is formed by bending a pipe, and as shown in FIG. 3 (c), a section (concave portion) 4a ₁ , an internal space 4e, and an external space 4a ₂ having a concave cross section over the entire length in the axial direction are formed. The mouth side sleeve 4b is fixed to the mouth end surface of the main body 4a by a welded portion 4h (FIG. 3D), and a screw portion 4d for attaching a drainage attachment is formed inside the cylinder. The distal end sleeve 4c is fixed to the distal end surface of the main body 4a so as to close the inner space 4e by welding. Tip sleeve 4c is provided with a supporting portion 4c ₁ and plug 4c _2, the cylindrical inner surface of the support portion 4c ₁ are formed threaded portion for attaching the stopper 4c _2, plug 4c ₂ is added to the internal space 4a ₂ The pressure is released by the applied pressure.

FIG. 4 is an explanatory view in which a pipe-type lock bolt is placed in a bore hole, and then the main body is expanded and expanded by applying pressure to the internal space of the lock bolt. FIG. 4 (a) is an enlarged pipe-type lock. FIG. 4B is a sectional view taken along line CC in FIG. 4A.
After the pipe-type lock bolt 4 shown in FIG. 3 is placed in the bore hole, a fluid supply adapter (not shown) is attached to the mouth-side sleeve 4b, and pressure fluid is passed through the adapter to the inside of the pipe-type lock bolt main body. The pipe-type lock bolt main body 4a is expanded and expanded in diameter. Body 4a further applying pressure is in close contact with the borehole of the pore walls, thereafter disconnected stopper 4c ₂ of the tip sleeve 4c, open distal end of the inner space 4e. When spring water is generated, the spring water flows into the internal space 4e of the rock bolt from the tip. As shown in FIG. 4B, water also flows through the periphery of the lock bolt.

FIG. 5 is an explanatory view of the attachment for drainage according to the first embodiment, and is a view taken along the arrow M of the attachment in FIG.
The attachment 5 for spring water drainage is provided with a bowl-shaped cap 5 a, and a threaded portion provided on the lock bolt and a connection portion 5 b that can be connected to the inside of the cap are fixed, and springs out through the lock bolt 4. A drain port 5c is provided for guiding water from the space inside the cap to the external space for drainage. Connecting portion 5b has become cylindrical, provided with a threaded portion 5b ₁ and the non-threaded portion 5b _2, a plurality of through holes 5b ₃ are formed in the non-threaded portion.
When spring water is generated from the lock bolt, as shown in FIGS. 1B and 1C, the screw portion of the connection portion 5b of the attachment 5 is attached to the screw portion 4d formed inside the mouth side sleeve 4b of the lock bolt. 5b ₁ is screwed in, the mouth side sleeve 4a is covered with the cap 5a, and the spring water flowing into the internal space 4e of the lock bolt 4 is discharged outside through the drain hole 5c through the through hole 5b _{3 of the} attachment. In addition, the spring water which arises from the peripheral part of a rock bolt is also collected by an attachment, and is discharged | emitted outside from the drain port 5c. A hose 6 can be attached to the drain port 5c, and spring water can be guided to an appropriate place by the hose for processing.

  6A and 6B are explanatory diagrams in which the attachment is connected to the lock bolt. FIG. 6A is a cross-sectional view, and FIG. 6B is a cross-sectional view taken along the line DD in FIG. Since the cap 5a is bowl-shaped, the cap 5a can be turned around when the connection portion 5b is screwed into the lock bolt 4, and can be easily connected to the lock bolt. The spring water is drained along the route indicated by the dotted arrow in FIG.

FIG. 7 is an explanatory view of a construction method of a pipe type rock bolt.
In the construction method of each pipe-type rock bolt 4 on the inner wall of the tunnel, first, a bore hole 11 having a predetermined depth is drilled from the tunnel space 2 (see FIG. 1) toward the natural ground 1 (FIG. 7 (1)). When there is spring water in the natural ground 1, the spring water flows into the borehole 11 and flows from the hole 12 to the tunnel space 2.
Next, the pipe type lock bolt 4 is driven into the bore hole 11 (FIG. 7 (2)), and after the driving, the adapter 13 for supplying fluid is attached to the mouth side sleeve 4b, and the pressure fluid is supplied to the pipe type via the adapter. This is supplied to the internal space of the main body of the lock bolt, and the diameter of the pipe-type lock bolt main body 4a is expanded and expanded (FIG. 7 (3)). Further the addition of the pressure body 4a is in close contact with the borehole of the pore walls, disconnected stopper 4c ₂ of the tip sleeve 4c, open distal end of the inner space 4e. Thereafter, the adapter 13 is removed, and a fixing material is injected from the mouth side as required (FIG. 7 (4)). If there is no spring, this completes the construction of the rock bolt.
When spring water is generated, the spring water flows from the tip of the rock bolt into the internal space 4 e of the lock bolt and flows out into the tunnel space 2. Then, when spring water arises, the connection part 5b of the attachment 5 is screwed into the mouth side sleeve 4b of the lock bolt 4, and the mouth side sleeve 4a is covered with the cap 5a (FIG. 7 (5)). Thereby, the spring water which flowed into the internal space 4e of the lock bolt 4 is discharged to the outside from the drainage port 5c of the attachment. In addition, spring water generated from the periphery of the rock bolt is also collected by the attachment and discharged to the outside from the drain port 5c.

FIG. 8 is a modified example of the attachment for drainage, FIG. 8 (a) is a sectional view of the attachment attached to the placed lock bolt, and FIG. 8 (b) is an EE arrow in FIG. 8 (a). FIG. The lock bolt 4 has the same structure as the pipe-type lock bolt of the first embodiment.
The external appearance of the attachment 7 of the modified example is an elbow shape unlike the bowl shape of the first embodiment. A cylindrical connecting portion 7b is fixed to one end of the elbow 7a, and a drain hose port 7c is attached to the other end. It is fixed. A threaded portion that engages with a threaded portion formed on the inner peripheral portion of the mouth side sleeve 4b of the lock bolt 4 is formed on the outer periphery of the connecting portion 7b. When spring water is generated, the connecting portion 7b of the attachment 7 is screwed into the mouth side sleeve 4b of the lock bolt 4, and the spring water flowing into the internal space 4e of the lock bolt 4 is applied to the hose port 7c of the attachment 7 as indicated by a dotted arrow. Guide and discharge to the outside. Further, the hose 6 can guide the spring water to a proper place for treatment.

(C) Second Embodiment FIG. 9 is an explanatory view of a self-drilling lock bolt according to the second example, FIG. 9 (a) is an external plan view of the self-drilling lock bolt, and FIG. 9 (b) is a self-drilled lock bolt. It is a horizontal sectional view of a bolt.
The self-drilling lock bolt 8 is driven while drilling a bore hole with a lost bit 8b provided at the tip of the main body 8a of the lock bolt, and the lost bit 8b is discarded without being collected. The main body 8a has a hollow bolt shape in which rope-shaped screws are rolled over its entire length, and an outer peripheral screw 8c and an inner peripheral screw 8d are formed on the outer periphery and the inner periphery, respectively.
FIG. 10 is a sectional view showing a state in which the attachment 5 is attached to the self-drilling lock bolt 8 that has been driven. The attachment 5 has substantially the same configuration as the attachment of the first embodiment. The difference is that the threaded portion 5b ₁ of the connecting portion 5b has a shape corresponding to the inner peripheral screw 8d of the self-drilling lock bolt, and the through-hole 5b ₃ has a slit shape.
A self-drilling lock bolt 8 is driven on the inner wall of the tunnel, and is fixed to the ground by tightening with a nut 8g through a washer 8f. If there is no spring water, the fixing material is injected from the mouth side and the construction of the rock bolt is completed. However, when spring water is generated, the spring water flows into the internal space 8e of the rock bolt from the lost bit 8b and flows out into the tunnel space. Therefore, the connection portion 5b of the attachment 5 is screwed into the mouth side of the self-piercing lock bolt 8, and the mouth side of the self-piercing lock bolt is covered with the cap 5a. As a result, the spring water that has flowed into the internal space 8e of the lock bolt 8 is discharged to the outside through the drainage port 5c of the attachment as indicated by the dotted arrow. In addition, spring water generated from the periphery of the rock bolt is also collected by the attachment and discharged to the outside from the drain port 5c.

(D) Third Embodiment FIG. 11 is an explanatory view of a perforated pipe-shaped rock bolt according to a third embodiment, FIG. 11 (a) is an external plan view of the perforated pipe-shaped rock bolt, and FIG. 11 (b). FIG. 3 is a horizontal sectional view of a perforated pipe-shaped lock bolt.
The perforated pipe-shaped lock bolt 9 has a cone 9b for driving at the tip of a pipe-shaped main body 9a, and a plurality of holes 9c are formed in the circumference at predetermined intervals in the axial direction. A thread portion 9d for attaching the attachment is formed.
FIG. 12 is a cross-sectional view of the state in which the attachment 5 is attached to the perforated pipe-like lock bolt 9 that has been laid. The attachment 5 has the same configuration as the attachment of the first embodiment.
A perforated pipe-like lock bolt 9 is driven into the borehole and fixed to the ground by tightening with a nut 9g via a washer 9f. If there is no spring water, the fixing material is injected from the mouth side and the construction of the rock bolt is completed. However, when spring water is generated, the spring water flows into the inner space 9e of the rock bolt from the driving cone 9b and flows out into the tunnel space. Therefore, the connecting portion 5b of the attachment 5 is screwed into the mouth side of the perforated pipe-shaped lock bolt 9, and the mouth side of the self-drilling lock bolt is covered with the cap 5a. Thereby, the spring water which flowed into the internal space 9e of the lock bolt 9 is discharged to the outside from the drainage port 5c of the attachment as shown by the dotted arrow. In addition, spring water generated from the periphery of the rock bolt is also collected by the attachment and discharged to the outside from the drain port 5c.

In the above embodiment, an example of a female screw type in which a screw is provided on the inner peripheral side at least at the end of the lock bolt is illustrated, but a male screw type in which a screw is provided on the outer periphery may be used. The connection part of the attachment may be a female screw.
In addition, after the drainage is finished, it is possible to inject the fixing material 9 into the inner space and the outer peripheral portion of the lock bolt as shown in FIG. For example, after draining, the attachment 5 (see FIG. 10) is removed, the fixing material 9 is injected, and the nut 8g is applied. Moreover, after that, as shown in FIG. 14, the attachment 5 having the hook-shaped cap 5a can be fitted back, and the attachment can be used as a head protection cap for the lock bolt. If it does in this way, it can prevent that the edge part of a bolt protrudes from a construction wall surface, and damages the waterproof sheet 10. FIG.

As described above, according to the present invention, it is not necessary to place an anchor with a special structure, and when spring water is generated while performing normal rock bolt construction, or when it is necessary to perform spring water treatment, It has become possible to immediately and selectively treat spring water. In addition, it was possible to improve the construction environment by performing spring water treatment at the same time as rock bolting, to stabilize the ground, and to use groundwater in a clean state.
According to the present invention, it is possible to attach and detach the lock bolt using the threaded portion of the lock bolt, and it can be used only at the time of the spring treatment, and it is economical because it can be removed. Moreover, since there is nothing which stops water forcibly, water pressure is not applied and a large amount of spring water can be treated.

It is a schematic explanatory drawing of the rock bolt construction method and the attachment for drainage. It is explanatory drawing in the case of attaching an attachment to the lock bolt nailed on the slope. It is explanatory drawing of the lock bolt concerning 1st Example. It is explanatory drawing which expanded the diameter of the main body by applying a pressure to the internal space of the main body of this lock bolt, after driving a pipe-type lock bolt into a bore hole. It is explanatory drawing of the attachment for waste_water | drain concerning 1st Example. It is explanatory drawing which connected the attachment to the lock bolt. It is construction method explanatory drawing of a pipe type rock bolt. It is a modification of the attachment for drainage. It is explanatory drawing of the self-drilling lock bolt concerning 2nd Example. It is sectional drawing of the state which attached the attachment to the self-drilling lock bolt laid. It is explanatory drawing of the perforated pipe-shaped lock bolt concerning 3rd Example. It is sectional drawing of the state which attached the attachment to the perforated pipe-shaped lock bolt laid. It is explanatory drawing which removed the attachment after pouring the lock bolt of 2nd Example, inject | poured the fixing material, and tightened the nut. It is explanatory drawing at the time of attaching an attachment after fixing material injection | pouring and attaching a waterproof sheet.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Ground mountain 2 Tunnel space 3 Tunnel inner wall 4 Rock bolt 4a Body 4b Mouth side sleeve 5 Attachment for spring water drainage 5a Cap 5b Connection part 5c Drainage port 6 Hose

Claims (2)

In a lock bolt construction method using a hollow lock bolt having a threaded portion at least on the base end side,
A bowl-shaped cap, a hollow connecting part fixed to the inside of the bowl-shaped cap, and having a threaded part connected to a threaded part of the hollow lock bolt and a non-threaded part formed with a through hole, and the bowl-shaped cap Preparing an attachment with a drain outlet attached to the body to drain the spring water ,
Placing the hollow rock bolt into the ground;
After the placement, the attachment portion of the attachment is screwed into the threaded portion of the hollow lock bolt so that the internal space of the hollow lock bolt communicates with the drainage port of the attachment through the through hole. Covering the mouth of the hollow lock bolt ;
A rock bolt construction method characterized by comprising: In the attachment that handles the spring water generated during the construction of hollow rock bolts,
Bowl shaped cap ,
A hollow connecting portion fixed to the inside of the bowl-shaped cap and connected to a screw portion provided on the hollow lock bolt and a non-threaded portion formed with a through hole ;
A drain outlet attached to the bowl-shaped cap to drain the spring water;
The attachment portion is screwed into the threaded portion of the hollow lock bolt to communicate the interior of the hollow lock bolt with the drainage port of the attachment through the through hole , and the bowl-shaped cap Cover the mouth of the hollow lock bolt ,
An attachment characterized by that.

Images