KR20180013029A - Method for enlarging holes and bit therefore - Google Patents

Abstract

The present invention provides a bit for hole-enlarging work which enlarges an excavation hole formed in a prescribed depth while ascending from a lower end of the excavation hole. The bit for enlarging a hole comprises: a bit body (12) including a plurality of storage grooves (24) and a support groove (19) extended upwards from the storage grooves (24) and arranged on a lower surface thereof; and a plurality of wing bits (14) including a rotary support shaft (14B) inserted into the support groove to be rotatably supported by a pin (22), and a wing body (14A) integrally formed on a lower portion of the rotary support shaft (14B). The wing body can be stored into the storage grooves around the rotary support shaft or rotate to protrude out of the bit body. A plurality of button tips (BT) are installed on an upper portion of the wing body to come in contact with a ceiling surface (2A) of an enlarged portion of an excavation hole (2) to perform excavation work. An upper surface of the wing body is formed into an inclined surface (14S) inclined to allow slime produced on the button tips (BT) on the upper portion of the wing body to flow downwards. Hole-enlarging work using the bit for enlarging a hole is performed while ascending from a lower end of an excavation hole.

Description

Field of the Invention [0001] The present invention relates to a method for enlarging a civil engineering work,

The present invention relates to a method of drilling a drilling rig and a bit for the drilling rig, and more particularly, to a drilling method capable of maximizing the diameter of the lower end of the drilling rig more efficiently, will be.

In general engineering works, air drums and bits are used to form the excavation holes 2 as shown in FIG. The basic method of forming such excavation holes 2 is as follows. The excavation work is performed on the ground while the bit is vertically impacted (compressed air supplied from a plurality of compressors is generated through the air hammer) and rotated (rotational force by a drive motor (not shown)). As described above, rotating the bit while applying an impact (impact) in the up and down direction with respect to the paper surface is a widely used method, and a detailed description thereof will be omitted.

Here, the bit is reciprocated in the up-and-down direction with respect to the paper surface while the impact (striking) is applied to the paper surface downward as compressed air generated in a plurality of compressors passes through the air hammer. Therefore, the bit installed at the lower part of the air hammer repeatedly moves in the vertical direction, and provides an impact force for crushing against the excavated ground. At the same time, the bit is rotated, which is based on that the rotational force of the separate drive motor is transmitted to the bit through the casing. As described above, performing the excavation by moving the bit up and down and rotating it at the same time is practically widely used at present, and a detailed description thereof will be omitted.

In consideration of the stability of the structure provided inside the excavation hole 2 formed in this way, it is more preferable to form the expanded portion 4 having a constant height at the lower end of the excavation hole 2. That is, it is a matter of course that the structure supported by the inside of the excavation hole 2 with the concrete poured can be supported in a more stable and stable state by the presence of the expanded portion 4.

As shown in FIG. 2, a general method for forming the drilling hole having the enlarged diameter portion 4 at the lower end is as follows. After drilling holes are formed up to a certain depth, (6) to form a drill hole to a certain depth again. However, the following disadvantages can be brought about by such a conventional method.

If the dedicated bit 6 is used for the expansion, it is inevitable to carry out the excavation work in parallel with the up-down motion and the rotary motion by driving the air hammer as in the general construction method. Therefore, a large number of compressors are required, since the same amount of compressed air required in a typical drilling operation is required. Such a conventional excavation method relies on a conventional method of performing the excavation work while striking the ground substantially from the upper part to the lower part.

The main object of the present invention is to provide a drilling method capable of drilling the lower end portion of the drilling hole most efficiently.

Another object of the present invention is to provide a bit capable of achieving the most efficient drilling of the lower end of the drilling rig.

It is another object of the present invention to provide a method of drilling which can minimize the number of auxiliary equipment for drilling of drilling rigs.

The drilling method according to the present invention includes: a drilling hole forming step of drilling a ground surface while a bit moves in a vertical direction and forming a drilling hole at a predetermined depth while rotating a bit; Wherein the wiping bit for wiping the wiping bit is expanded by lowering the positioning bit to the lower end of the excavation hole at a predetermined depth and rotating the wiping bit in one direction so that a wiping operation is performed while the upper face of the wing bit contacts the ceiling face of the wiping bit . Such a spreading process is performed over a certain interval as the spreading bit rises.

The bit of the present invention is a positioning bit for positioning a drilling hole while rising at a lower end of a drilling hole formed at a predetermined depth, and is provided with a plurality of receiving grooves and a bit having a supporting groove extending upwardly from the receiving groove, And a plurality of wing bits having a main body, a rotation support shaft inserted into the support groove and rotatably supported by the pin, and a wingbody integrally formed on the lower portion of the rotation support shaft. Here, the wings are rotatable about the rotation support shaft so as to be housed in the receiving groove or protrude to the outside of the bead body. In addition, a plurality of button tips are provided at the upper part of the wingbody for performing a drilling operation in contact with the top surface of the widening portion of the drilling hole. Further, the upper surface of the wingbody is formed as an inclined surface inclined so that a slime generated from the button tip on the upper part of the wingbone can flow down.

It is preferable that a plurality of air passages for supplying compressed air to the wing bit are provided inside the bit body of the present invention.

As described above, according to the present invention, it can be seen that the spreading process is basically performed from the bottom to the top. According to such a spreading operation, the drilling operation can be carried out for a sufficient amount of time that the positioning bit is driven only by the rotational force in the separate driving motor. Therefore, it is expected that the compressor and the auxiliary facilities for supplying the compressed air can be minimized, and at the same time, the wastewater can be processed easily and easily.

1 is an exemplary sectional view showing the shape of an excavation hole having a lower end extended;
FIG. 2 is a view showing a process of enlarging the lower end of the excavation hole; FIG.
3 is an exemplary view showing a drilling method of the present invention.
Fig. 4 shows an explanatory bit of the present invention. Fig. 4 (a) is a sectional view, Fig. 4 (b) is a bottom view in a state in which wing bits are unfolded, and Fig. 4 (c) is a bottom view in a state in which wing bits are folded.
Figure 5 is a front view of a wing bit of the inventive spreading bit;

Hereinafter, the present invention will be described in more detail based on the embodiments shown in the drawings. First, a method of widening according to the present invention will be described with reference to FIG. The drilling method according to the present invention starts by drilling a drilling hole with a required depth L first. That is, the excavation hole 2 having a predetermined depth L is first drilled. The construction method of the excavation hole 2 itself is the same as the conventional method.

That is, the bit for carrying out the actual drilling operation in contact with the ground is parallel to the upward and downward impact (the compressed air supplied from the plurality of compressors is generated through the air hammer) and the rotation (rotational force by the drive motor The excavation hole 2 having a predetermined diameter is formed at a desired depth. The depth L of the excavation hole formed at this time includes the depth of the deeply-drawn portion M to be formed at the lower end portion.

The process of forming the excavation hole 2 at the desired depth L is substantially the same as that of the conventional excavation method. As described above, the excavated hole 2 thus formed includes the height of the reamer M. When the excavation hole having the predetermined depth L is formed in this way, an operation of extending the excavation hole 2 from below to below is performed.

The spreading process of the excavation hole 2 is performed by the positioning bit 10 described later. And for such a widening process, it first starts by exchanging the bit used for excavation with the bit for exploitation 10. That is, after the positioning bit 10 is installed at the lower end of the casing 20, the positioning bit 10 is lowered to the lowermost end of the preformed drilling hole 2, The waving operation is carried out while pulling the wrist strap 10 upward.

In the present invention, in the preformed excavation hole (2), the spreading operation proceeds while moving the positioning bit (10) from the lower side to the upper side. As described above, when the positioning bit 10 moves upward from the lower side and the positioning operation proceeds, the following advantages can be expected. It is not necessary to substantially move the positioning bit 10 in the up and down direction when the positioning bit 10 moves upward and the positioning operation proceeds. That is, as can be seen from the following description, since the button tip is provided on the top surface of the positioning bit 10, the digging operation can be easily performed when the positioning bit 10 comes into contact with the ground surface from the top by rotation. It is not necessary for the user 10 to move upward and striking the ground in the upper part thereof.

Since the upward and downward movement is not required in this way, the number of compressors for generating substantially compressed air and the number of additional apparatuses for moving (supplying) compressed air are remarkably reduced. In the description of the present invention, the configuration for discharging the slime at the time of excavation is not directly related to the present invention, and thus the constitution and description thereof are omitted.

As described above, according to the present invention, a drilling operation of the excavation hole 2 is performed downward at a desired depth L using a general bit, and then a drilling hole 2 is drilled using the drilling hole 10 It is seen that there is a feature that the wiping operation is performed while ascending upward from the lower end of the pipe. Since the positioning bit 10 capable of performing the widening operation in this way must be moved upward while performing the excavation work, the positioning bit 10 has the following configuration.

4 (a), the positioning bit 10 is composed of a bit body 12 and a wing bit 14 rotatably supported on the bit body 12. As shown in Fig. The bit body 12 has a connection portion 12a connected to a lower portion of the casing 10. [ The concave portion 12b is formed in the connecting portion 12a and is supported by the casing 20 through the connecting pin 22 inserted into the concave portion 12b.

Inside the bit body 12, air passages 15, 16, 18 for blowing air supplied through the interior of the casing 20 toward the wing bit 14 are formed. The air supplied through the air passage is also used for discharging the slime and has a function of preventing foreign matter from penetrating between the wing bit 14 and the bit body 12. [

The wing bit 14 will now be described in more detail with reference to FIG. The wing bit 14 is constituted by a wingbody 14A and a cylindrical rotary support shaft 14B extending upward from the wingbody 14A. Since the columnar rotary support shaft 14B is inserted into the support groove 19 of the bit body 12, it can rotate relative to the bit body 12 with respect to the rotary support shaft 14B. The bottom surface of the bit body 12 is provided with a receiving groove 24 in which the wing body 14A can be completely housed inward when the wingbody 14A is rotated in a state in which the rotation supporting shaft 14B is rotatably inserted, Respectively. The support groove 19 is formed so as to extend upward from the receiving groove 24.

And this rotation of the wing bit 14 allows the wing bit 14 to enter into the receiving groove 24 of the bit body 12 or to expand outward with respect to the bit body 12. [ Here, the rotation axis of the wing bit 14 is a rotation support shaft 14B having a cylindrical shape. The rotation support shaft 14B is inserted into a vertically formed support groove 19 upwardly from the upper surface of the bottom surface receiving groove 24 of the bit body 12 to be rotatable. In order to spread the wing bit 14 outward with respect to the bit body 12 about the rotation support shaft 14B, the rotation support shaft 14B is formed at a position eccentric to the wing body 14A .

The wing bit 14 is rotatably supported so that a pin insertion groove 14g having an arcuate cross section is formed along the entire circumference at the upper portion of the rotation support shaft 14B. An insertion groove 19a is also formed in the receiving groove 19 of the bit body 12 corresponding to the pin insertion groove 14g. The pin insertion groove 14g and the insertion groove 19a are formed in a circular shape as a whole. Therefore, when the cylindrical connecting pin 22 is inserted between the pin insertion groove 14g and the insertion groove 19a, the wing bit 14 can be supported on the bit body 12 without falling downward.

Since the connecting pin 22 is formed by a straight line of a cylindrical shape and the concave portion 12b has an arcuate cross section and is formed on the entire outer peripheral surface of the rotary support shaft 14B, And is rotatable around the axis 14B. 4 (b), when the bit body 12 rotates in the forward direction A (counterclockwise direction in the figure), the wing bit 14 is rotated clockwise around the rotation support shaft 14B And is held at one side of the receiving groove 24 to maintain the unfolded state as shown in FIG. 5 (b).

When the bit body 12 rotates in the opposite direction, that is, in the clockwise direction B, the wing bit 14 rotates counterclockwise about the rotation support shaft 14B as shown in (c) And is completely housed in the receiving groove 24 on the bottom surface of the bit body 12. [ This condition is such that the wing bit 14 does not protrude at all from the outside of the bit body 12.

As shown in Fig. 5, an inclined surface 14S is formed on the upper surface of the wing bod 14A of the wing bit 14 of the present invention. The inclined surface 14S is formed so that the slime generated by the contact with the top surface 2A of the reamer M of the excavation hole 2 can flow downward. Therefore, the inclined surface 14S is formed in a downward inclined state from the upper surface of the wingbody 14, and the inclined surface 14S is formed with the wing bit 14 in the unfolded state, In the present invention.

According to the wing bit 14 of the present invention, a plurality of button tips BT are provided on the upper surface of the wingbody 14A. Also, it can be seen that a plurality of button tips BT are attached to the lower surface of the wingbody 14A. The button tip BT on the upper surface of the wingbody 14A can be regarded as a portion that actually performs the wiping operation by directly contacting the top surface 2A of the reamer M of the excavator. The button tip BT on the lower surface of the wingbody 14A is moved downward in the folded state to contact the bottom surface of the excavation hole 2, The wing bit 14 is provided so as to be able to spread outward by contacting the bottom surface of the excavation hole 2 when the bit body 12 rotates in the counterclockwise direction.

Next, the overall excavation process will be described. First, the excavation hole 2 is formed to a predetermined depth L by a conventional method using a normal bit not shown. When this operation is completed, the positioning bit 10 of the present invention is attached to the lower end portion of the casing 10 and descends to the lowest portion in the inside of the excavation hole 2. The positioning bit 10 at this time is a state in which the wing bit 14 is folded into the receiving groove 24 of the bit body 12 as shown in Fig.

In this state, when the positioning bit 10 is rotated in the forward direction (A) after making contact with the bottom face of the excavation hole 2, the wing bit 14 in contact with the bottom face is moved to the position shown in And is spread outward as shown in the figure. At this time, the wing bit 14 is unfolded by reaction force by the button tip BT on the bottom surface of the wingbody 14A.

When the casing 20 is rotated by the driving force of a motor (not shown) in the unfolded state, the positioning bit 10 itself coupled to the casing 20 also rotates. The rotation of the positioning bit 10 is performed such that a drilling operation is performed in which the diameter of the drilling hole 2 is substantially enlarged while the button tip BT on the upper surface of the wingbody 14A contacts the ceiling face 2A it means. It can also be seen that such a widening work is practically carried out while ascending from the lower end inside the drilling hole 2.

The reason why the wiping operation is performed by contacting the top surface 2A of the excavation hole 2 on the upper surface of the wing bit 14 in this manner is that the drilling bit 10 is substantially lifted from the lower end of the excavation hole 2 But it can be said that the work of spreading is done. The slim generated when the button tip BT on the upper surface of the wing bit 14 contacts the ceiling surface 2A is caused to flow downward along the inclined surface 14S of the upper surface of the wing bit 14 do. As described above, the fact that the spreading operation is carried out while ascending from the lower side means that the slime generated when the upper surface of the wing bit 14 comes into contact with the ceiling surface 2A can flow very easily outward along the inclined surface, The efficiency of the excavation work is maximized.

As described above, it can be seen that the waving method according to the present invention can be performed while rising upward from the lower end of the excavation hole 2 by using the wing bit having the button tip formed thereon. It will also be understood that the present invention is designed in such a way that the drill bit can be in contact with the top face of the drill hole to perform the drilling operation.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the present invention as defined by the appended claims. In the light of the provisions of the Patent Act, it is reasonable.

2 ..... excavation ball
2A ..... ceiling front
10 ..... Binary bits
12 ..... bit body
14 ..... Wing beat
14A ..... Wingbodies
14B ..... rotation supporting shaft
14g ..... insert groove
15, 16, 18 ..... Air passage
19 ..... support groove
19a ..... insert groove
20 ..... casing
22 ..... Connection pin
24 ..... storage home
BT ..... button tip
L ..... depth of excavation
M .....

Claims (3)

A drilling hole forming step of drilling the ground surface while the bit moves in the vertical direction and simultaneously forming the drilling hole with a predetermined depth while rotating the bit;
By lowering the positioning bit to the lower end of the drilling hole with a predetermined depth and rotating it in one direction, the wing bit of the positioning bit is expanded so that the upper surface of the wing bit contacts the ceiling surface 2A of the ridge M And a spreading process in which a spreading operation is performed;
Wherein the spreading process is performed over a predetermined period while the spreading bits are being increased.
A drilling bit for drilling a drilling hole while rising at a lower end of a drilling hole formed at a predetermined depth;
A bit body (12) having a plurality of receiving grooves (24) and supporting grooves (19) extending upward from the receiving grooves (24) on the bottom surface;
A rotation support shaft 14B inserted into the support groove and rotatably supported by the pin 22 and a wingbody 14A integrally molded at the lower portion of the rotation support shaft 14B, (14);
Wherein the wingbody is rotatable so as to be housed inside the receiving groove around the rotation support shaft or protrude to the outside of the bead body;
A plurality of button tips (BT) are installed on the upper part of the wingbody to contact the top surface (2A) of the widening part of the drilling hole (2) to perform the drilling operation;
Wherein the upper surface of the wingbody is formed of a sloped surface (14S) sloped so that a slime generated in a button tip (BT) of the upper part of the wingbath can flow down.
3. The bidet according to claim 2, wherein the bit body is provided with an air passage

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