JP6435077B1 - Drilling head - Google Patents

Abstract

An excavation head capable of easily crushing a columnar improved pile buried in the ground without misalignment.
An excavation head 1 for crushing a columnar improved pile mounted on an auger rod and embedded in the ground, the rotary shaft 10 attached to the auger rod, and at least 3 provided around the rotary shaft 10 The spiral excavation blade 20 of the strip, the small bit 30 attached to the end portion 20a of the excavation blade 20 in the excavation direction, and the distal end of the excavation blade 20 attached to the outer peripheral portion 20b of the excavation blade 20 in the excavation direction And a leading nail 40 that protrudes from the top.
[Selection] Figure 1

Description

  The present invention relates to an excavation head that is attached to an auger rod and crushes a columnar improved pile embedded in the ground.

  When a building such as a house is constructed, if it is found that the strength of the ground is insufficient, ground improvement work for stabilizing the ground may be performed. For example, ground improvement work called “columnar improvement method” is known. In the columnar improvement method, the ground is excavated and cement slurry is injected, and in that state, stirring is performed to mix the cement slurry and the soil contained in the ground, and the mixture is solidified to form columnar piles in the ground. It is a construction method. This pile is called a columnar improved pile and functions to stabilize buildings built on soft ground. The columnar improvement method is effective when a soft layer continues from the ground surface, and can be constructed using relatively small machines. It has increased.

  When the deep part of the ground is soft, ground improvement work called “slurry mechanical stirring type deep mixing method” is performed. The slurry-based mechanical agitation type deep mixing treatment method performs cement slurry injection and agitation with a stirrer while excavating the ground, and when excavation reaches a predetermined depth, the agitator is repeatedly moved up and down to This is a type of columnar improvement method that improves the mixability of cement slurry and soil. In the slurry-based mechanical agitation type deep mixing method, a high-quality columnar improved pile can be formed by managing the agitation speed of the agitator and the vertical movement speed (excavation speed and lifting speed).

  Thus, the columnar improvement pile formed in the ground by the columnar improvement method is basically a solid columnar body composed of a mixture of cement slurry and soil, such as steel frames and piano wires. It becomes a simple structure mainly composed of concrete that does not contain wire rods.

  By the way, when selling the land, it may be required to dismantle the building built on the land and level the land. However, in the land where the ground improvement work as described above has been performed, the columnar improvement pile remains in the ground, so it is not sufficient to leave the ground surface alone, and the columnar improvement pile must be removed. Land value may be low. Therefore, when piles or the like are buried in the ground, it is desired to restore the land to the original state by completely removing them.

  As a technique for removing the columnar improved piles, for example, focusing on the property that the columnar improved piles are brittle and easy to break compared to existing piles that are often used in relatively large buildings such as factories and buildings. There is a method of crushing and removing an improved pile with an excavation head mounted on an auger rod (see, for example, Patent Document 1). According to Patent Document 1, as a first stage, a cylindrical casing is inserted into the ground to surround a part of a columnar improved pile with a casing, and as a second stage, an auger rod equipped with an excavation head is provided. The drilling head can be guided to the columnar improved pile by being lowered so as to penetrate the inside of the casing while being rotated, and the columnar improved pile can be reliably crushed.

JP 2017-25534 A

  Since the columnar improved pile is used in the ground improvement work for ordinary houses, it is desired to remove the columnar improved pile with a simple apparatus configuration as much as possible. For example, in order to implement the technique described in Patent Document 1 with a simpler apparatus configuration, a method of crushing a columnar improved pile with an excavation head without using a casing is assumed.

  However, since the excavation head has a conical shape with a sharp tip as a whole, if the casing is not used, misalignment may occur. In particular, since the columnar improved pile is formed in a soft ground, the excavation direction tends to be shifted from the columnar improved pile to the surrounding soft soil. Therefore, in order to implement the technique described in Patent Document 1 without using a casing, an excavation head suitable for crushing the columnar improved pile is required.

  This invention is made | formed in view of the said problem, and it aims at providing the excavation head which can crush easily the columnar improvement pile embed | buried under the ground without centering.

The characteristic configuration of the excavation head according to the present invention for solving the above problems is as follows:
An excavation head that is mounted on an auger rod and crushes a columnar improved pile buried in the ground,
A rotating shaft attached to the auger rod;
At least three spiral excavation blades provided around the rotating shaft;
A small bit attached to the end of the excavating blade in the excavation direction;
And a leading claw attached to an outer peripheral portion of the excavating blade and having a tip protruding in a drilling direction from a tip of the small bit.

  The drilling head of this configuration has a leading claw protruding in the drilling direction rather than the small bit on the outer peripheral part of at least three drilling blades, and therefore precedes the small bit for cutting the columnar improved pile. Claws excavate the soil around the pillar-like improved pile, and fit so as to suppress the pillar-like improved pile from at least three directions. As a result, the excavation head according to the present invention can reliably capture the columnar improved piles and effectively crush them without misalignment. In addition, since the leading claws are separately attached to the excavating blades, the excavated material excavated by the leading claws is discharged from between the leading claws and is not easily accumulated in the ring-shaped groove formed by excavating the leading claws. . As a result, the excavation head of the present invention can prevent the excavated material excavated by the preceding claws from hindering the subsequent excavation, and can crush the columnar improved pile with high excavation efficiency.

In the drilling head of the present invention,
It is preferable that the tip of the leading nail protrudes 10 to 30 cm in the excavation direction from the tip of the small bit.

  According to the excavation head of this structure, since the tip of the leading claw protrudes 10 to 30 cm in the digging direction from the tip of the small bit, the leading claw is sufficiently fitted to the columnar improved pile before crushing to ensure misalignment. Can be prevented.

In the drilling head of the present invention,
It is preferable that the leading pawl has a turning radius at the tip that is larger than the radius of the columnar improved pile.

  According to the excavation head of this configuration, since the turning radius of the tip of the leading claw is larger than the radius of the columnar improved pile, when the tip of the leading claw reaches the upper end of the columnar improved pile by excavation, the leading claw becomes the columnar improved pile. It is easy to hang outside. Therefore, the excavation head can be easily aligned at the start of excavation.

In the drilling head of the present invention,
The rotation radius R on the inner surface closest to the rotation axis of the leading pawl and the radius r of the columnar improved pile are expressed by the following relational expression (1):
1 ≦ R / r ≦ 1.1 (1)
It is preferable to satisfy.

  According to the excavation head of this configuration, the rotation radius R on the inner surface closest to the rotation axis of the leading claw and the radius r of the columnar improved pile satisfy the above-described relational expression (1), so that misalignment is likely to occur. Even in this case, the displacement width is suppressed to less than 10% of the radius of the columnar improved pile by contacting the inner surface of any of the preceding claws attached to at least three excavating blades with the columnar improved pile. Thus, it is possible to maintain a positional relationship in which the entire columnar improved pile overlaps the excavating blade in a vertical view. As a result, the columnar improved pile can be reliably crushed.

In the drilling head of the present invention,
It is preferable that the leading pawl has an inclined surface that is inclined from the tip toward the excavation blade side.

  According to the excavation head of this configuration, since the leading claw has an inclined surface that inclines from the tip toward the excavation blade side, some misalignment occurred when the tip of the leading claw reached the upper end of the columnar improved pile. Even in this case, when the inclined surface comes into contact with the edge of the upper end of the columnar improved pile, the leading nail escapes to the soil side around the columnar improved pile and the misalignment is corrected.

In the drilling head of the present invention,
The small bit is preferably a conical bit having a bit body that is rotatably mounted.

  The small bit cuts the hard columnar improved pile, so it is easier to wear than the leading claw that excavates the soft soil around the columnar improved pile, but according to the excavation head of this configuration, the small bit is a conical bit. For this reason, even if the small bit is worn, the sharp shape can be maintained for a long time, thereby extending the life. As a result, the wear balance between the small bit and the leading claw is good.

FIG. 1 is an explanatory view of an excavation head according to the present invention. FIG. 2 is a front view of a small bit constituted by a conical bit. FIG. 3 is an explanatory diagram of a leading nail. FIG. 4 is a diagram illustrating a usage pattern of the excavation head of the present invention. FIG. 5 is an explanatory diagram of an excavation head according to another embodiment.

  Hereinafter, the excavation head according to the present invention will be described. However, the present invention is not intended to be limited to the configurations described in the embodiments and drawings described below.

(Columnar improved pile)
First, the columnar improved pile which is a construction target in the underground buried pile removing method and the underground buried pile removing apparatus of the present invention will be described. As described above, the columnar improved pile is a solid that does not include the streaks and wires formed in the ground when performing ground improvement work such as the columnar improvement method and slurry-based mechanical stirring type deep mixing treatment method. It is a columnar body. The component of the columnar improved pile is mainly a mixture of cement and soil. In performing ground improvement work, first, cement slurry is prepared. The blending of the cement slurry is adjusted to a water / cement ratio (weight ratio) of 50/50 to 90/10, preferably 60/40 to 80/20, and more preferably 70/30. The soil mixed with the cement slurry is usually soil (that is, excavated soil) existing on the ground where the ground improvement work is performed. The mixing ratio of cement slurry and soil is based on the condition of the ground to be constructed (excavated soil type, grain size, hardness, viscosity, moisture content, etc.). It is adjusted to satisfy the vertical bearing force.

  Since the columnar improved pile is formed inside the excavation hole of the ground, it is usually a columnar shape. The size of the columnar improved pile depends on the size of the excavation hole, that is, the excavation conditions. The size of the columnar improved pile is usually set to a diameter of 400 to 1000 mm, preferably 500 to 800 mm, more preferably 500 to 600 mm, and a height of 1 to 10 m. Moreover, in the case of ground improvement work in a general residential area, about 10 to 80 columnar improvement piles are formed in the ground below the foundation of the house in one work.

Columnar improved piles are required to meet certain standards from the viewpoint of safety and the like. For example, the allowable vertical bearing strength is defined as an index of improved ground on which columnar improved piles are constructed. The allowable vertical bearing capacity is a numerical value obtained by dividing the vertical ultimate bearing capacity when the ground undergoes shear failure by a predetermined safety factor. From the long-term viewpoint, it is considered that the allowable vertical bearing force of the improved ground is desirably 20 kN / m ² or more. In addition, the strength of the columnar improved pile itself is desirably 600 kN / m ² or more in a uniaxial compression test.

[Drilling head]
The excavation head of the present invention is attached to an auger rod and used for crushing a columnar improved pile buried in the ground. FIG. 1 is an explanatory diagram of an excavation head 1 according to the present invention. FIG. 1A is a perspective view of the excavation head 1, FIG. 1B is a front view of the excavation head 1, and FIG. 1C is a bottom view of the excavation head 1. The excavation head 1 includes a rotary shaft 10, an excavation blade 20, a small bit 30, and a leading claw 40.

  The rotating shaft 10 rotates with the rotation of the auger rod in a state where the rear end 10a is attached to the auger rod.

  A spiral excavation blade 20 is provided around the rotary shaft 10 so that the tip 10b side is in the excavation direction. In the example shown in FIG. 1, three excavating blades 20 are provided. However, if the excavation head 1 of the present invention has at least three excavating blades 20, each of the excavating blades 20 has a leading claw 40. Can be prevented effectively, and the number of excavating blades 20 may be four or more. Each of the excavating blades 20 is welded and fixed in parallel to the outer peripheral portion of the rotary shaft 10 at equal intervals, and the outer diameters thereof are substantially equal.

  A plurality of small bits 30 are attached to end portions 20a in the excavation direction of the respective excavating blades 20 so as to protrude from the end portions 20a. By arranging the small bit 30 in this way, the small bit 30 cuts the columnar improved pile when the outer diameter of the excavating blade 20 is equal to or larger than the diameter of the columnar improved pile to be crushed. The small bit 30 is preferably constituted by a conical bit. FIG. 2 is a front view of a small bit 30 constituted by conical bits. In the example shown in FIG. 2, the small bit 30 includes a holder 31 that is welded and fixed to the end portion 20 a, and a bit body 32 that has a tip 32 a formed in a conical shape and is rotatably attached to the holder 31. By comprising such a conical bit, the small bit 30 can maintain the pointed state of the tip 32a for a long period of time even if wear progresses by cutting a hard columnar improved pile.

  A leading claw 40 extending in the excavation direction is fixed to the outer peripheral portion 20b of each excavation blade 20 by welding. The leading end of the leading pawl 40 protrudes further in the excavation direction than the leading end of the small bit 30. Here, in the example shown in FIG. 1, since the lower end of the excavation head 1 has a generally conical shape that is pointed toward the excavation direction as a whole, the plurality of small bits 30 are arranged at various positions along the excavation direction. Has been. In such a configuration in which the position of the excavation direction differs among the plurality of small bits 30, the “tip of the small bit 30” protrudes most in the excavation direction in comparison of the amount of protrusion in the excavation direction with the tip of the leading claw 40 Means the tip of the small bit 30. Since the leading end of the leading pawl 40 protrudes in the excavation direction from the leading end of the small bit 30, the leading pawl 40 excavates the soil around the columnar improving pile prior to the small bit 30 cutting the columnar improving pile. The leading claws 40 attached to the respective excavating blades 20 are fitted so as to suppress the columnar improved pile from at least three directions. The protruding amount L from the tip of the small bit 30 to the tip of the leading claw 40 is preferably 10 to 30 cm. If the protrusion amount L is in the above range, when crushing the columnar improved pile by the excavation head 1, the leading pawl 40 can be sufficiently fitted to the columnar improved pile before crushing, and misalignment can be reliably suppressed. . If the protruding amount L is smaller than 10 cm, the leading pawl 40 may not be properly fitted to the columnar improved pile, and it may be difficult to suppress the columnar improved pile by the leading pawl 40. If the protruding amount L is larger than 30 cm, the load applied to the welded portion of the leading claw 40 during excavation becomes excessive, and the leading claw 40 may be damaged. Further, it is preferable that the leading pawl 40 is attached at a position closer to the tip 20a in the outer peripheral portion 20b. Accordingly, in the structure in which the leading end of the leading pawl 40 protrudes in the digging direction from the leading end of the small bit 30, the length of the leading pawl 40 along the digging direction can be shortened. It is possible to reduce the load applied to the welded part.

It is preferable that the leading pawl 40 is configured such that the turning radius of the tip is larger than the radius of the columnar improved pile. If the turning radius of the tip of the leading pawl 40 is larger than the radius of the columnar improved pile, the leading pawl 40 is easily caught on the outer peripheral surface of the columnar improving pile when the tip of the leading pawl 40 reaches the upper end of the columnar improving pile. Positioning of the excavation head 1 at the time becomes easy. Furthermore, when the leading nail 40 has a radius of rotation on the inner surface of the leading nail 40 as R and the radius of the columnar improved pile as r, the following relational expression (1):
1 ≦ R / r ≦ 1.1 (1)
It is preferable that it is comprised so that it may satisfy | fill. If R / r is in the above range, any inner surface of the leading claw 40 should be in contact with the columnar improved pile even when the misalignment occurs when the columnar improved pile is crushed by the excavation head 1. Thus, the displacement width can be suppressed to less than 10% of the radius of the columnar improved pile, and the positional relationship in which the entire columnar improved pile overlaps the excavating blade 20 in the vertical view from the rear end side of the excavation head 1 can be maintained. The columnar improved pile can be reliably cut with the small bit 30. When R / r is smaller than 1, the leading pawl 40 does not fit into the columnar improved pile, and there is a possibility that a part of the columnar improved pile cannot be cut with the small bit 30. When R / r is larger than 1.1, when the misalignment occurs when the columnar improved pile is crushed by the excavation head 1, there is a possibility that the deviation width cannot be sufficiently suppressed.

  FIG. 3 is an explanatory diagram of the leading claw 40. FIG. 3A is a perspective view of the leading claw 40, and FIG. 3B is a bottom view of the leading claw 40. The leading claw 40 has a rod-like claw body 41 and a reinforcing portion 42 that reinforces the strength of fixing to the outer peripheral portion 20b. It is preferable that the nail | claw main body 41 is formed so that it may have the inclined surface 41b which inclines toward the excavation blade 20 side from the front-end | tip 41a. Even when some misalignment occurs when the tip of the leading pawl 40 reaches the upper end of the columnar improved pile in the crushing of the columnar improved pile by the excavation head 1, an inclined surface 41b is formed on the edge of the upper end of the columnar improved pile. By contacting, the leading nail 40 escapes to the soil side around the columnar improved pile, so that the misalignment is corrected.

  Next, the usage pattern of the excavation head 1 of this invention is demonstrated. FIG. 4 is a diagram illustrating a usage pattern of the excavation head of the present invention. FIG. 4A is a diagram illustrating the overall configuration of the usage pattern of the excavation head 1, and FIG. 4B is a diagram illustrating a state in which the excavation head 1 has reached the upper end of the columnar improved pile P. 4 (c) is a cross-sectional view taken along line AA of FIG. 4 (b). When removing the columnar improvement pile P formed by the ground improvement work, the excavation head 1 is connected to the auger 3 via the auger rod 4 as shown in FIG. The position is aligned vertically above the pile P. In this state, excavation by the excavation head 1 proceeds by driving the auger 3 and rotating the auger rod 4.

  When the excavation progresses and the excavation head 1 reaches the upper end of the columnar improved pile P, first, as shown in FIG. Soil G is excavated, and excavation grooves X are formed around the columnar improved piles P. Here, in the example shown in FIG. 4, the excavation head 1 whose outer diameter of the excavation blade 20 matches the diameter of the columnar improved pile P is used, and the leading pawl 40 has a columnar shape as shown in FIG. Contact the side of the improved pile P. As a result, the excavation head 1 is in a state of being fitted to the columnar improved pile P by the three leading claws 40, and misalignment is prevented from occurring. As the excavation thereafter proceeds further, the small bit 30 in contact with the hard columnar improved pile P does not escape to the surrounding soft soil, and the columnar improved pile P is cut from the upper end. The excavation groove X formed by the leading claws 40 has a narrow ring shape as shown in FIG. 4C, but the excavated material (soil) by the leading claws 40 is between the leading claws 40. Since the material is discharged upward from the space, the excavated material does not accumulate in the excavation groove X. As a result, the excavation head 1 can crush the columnar improved pile P with high excavation efficiency by suppressing an increase in resistance due to the excavated material of the leading pawl 40.

  As described above, in the excavation head 1 of the present invention, the leading claw 40 excavates the soft soil around the columnar improvement pile P before the small bit 30 for crushing the columnar improvement pile P, thereby improving the columnar improvement pile. In order to catch P reliably, the columnar improved pile P can be effectively crushed without misalignment. Moreover, since the excavated material excavated by the leading pawl 40 is discharged upward between the leading claws 40 from the ring-shaped groove formed by excavating the leading pawl 40, the excavated material does not become a resistance. Therefore, the excavation head 1 of the present invention can crush the columnar improved pile P with high excavation efficiency.

[Another embodiment]
The excavation head 1 of the present invention is designed to prevent misalignment by engaging the leading pawl 40 so as to suppress the outer peripheral surface of the columnar improved pile P, prior to the small bit 30 for cutting the columnar improved pile P. The configuration described in the above embodiment can be changed as long as the effects of the invention are achieved. Some such modifications will be described as another embodiment.

<Another embodiment 1>
Drawing 5 is an explanatory view of excavation head 1A of another embodiment. FIG. 5A is a perspective view of the excavation head 1A, and FIG. 5B is a front view of the excavation head 1A. The excavation head 1 </ b> A is obtained by changing the preceding claws 40 of the excavation head 1 shown in FIG. 1 to the preceding claws 40 </ b> X to 40 </ b> Z, and the other configurations are the same as the excavation head 1. In the excavation head 1 of FIG. 1, as shown in FIG. 3, by providing the reinforcing portion 42, the welding area to the outer peripheral portion 20 b of the excavation blade 20 is increased to reinforce the fixing strength of the leading claw 40.

  On the other hand, in the excavation head 1A of FIG. 5, the leading pawl 40X is welded and fixed at a position from the tip 20a on the outer peripheral portion 20b of the excavation blade 20X, and the excavation head 1 further from the welding portion 40a with the excavation blade 20X. It is also welded and fixed to the outer peripheral portion 20b of the drilling blade 20Y extending in the rear end side and parallel to the drilling blade 20X. Thus, the welding strength 40a with the outer peripheral portion 20b of the excavating blade 20X and the welded portion 40b with the outer peripheral portion 20b of the excavating blade 20Y are welded at two locations, so that the fixing strength of the leading claw 40X is strong. It will be something. Therefore, the leading pawl 40X can have a simple bar-like structure without a reinforcing portion. Similar to the leading claw 40X, the leading claw 40Y is welded at two locations, the outer peripheral portion 20b of the excavating blade 20Y and the outer peripheral portion 20b of the excavating blade 20Z parallel to the excavating blade 20Y. Are welded at two locations, an outer peripheral portion 20b of the excavating blade 20X parallel to the excavating blade 20Z. For this reason, the preceding claws 40Y and 40Z can also have a simple bar-like structure without a reinforcing portion.

<Another embodiment 2>
In the example shown in FIG. 1, three excavating blades 20 are provided, and three leading claws 40 are provided as a whole of the excavating head 1 by attaching one leading claw 40 to each excavating blade 20. However, the excavation head 1 of the present invention only needs to prevent misalignment by fitting so as to suppress the outer peripheral surface of the columnar improved pile P with at least three leading claws 40. Two excavation blades 20 may be provided, and two excavation blades 20 may be attached to each excavation blade 20 so that four excavation heads 1 as a whole may be provided with four advance claws 40. Even in such a configuration, misalignment can be prevented by fitting so as to suppress the outer peripheral surface of the columnar improved pile P with four preceding claws.

<Another embodiment 3>
In the excavation head 1 shown in FIG. 1, when the radius of rotation at the inner surface of the leading pawl 40 is R and the radius of the columnar improved pile is r, the following relational expression (2):
1 ≦ R / r ≦ 2/3 ^1/2 (2)
You may comprise so that it may satisfy | fill. If R / r is in the above range, the distance between the leading claws 40 does not exceed the diameter of the columnar improved pile, so that a large misalignment is likely to occur from the state where the leading claws 40 are fitted to the columnar improved pile P. Even in such a case, the inner surface of any of the three preceding claws 40 always comes into contact with the columnar improved pile P, and misalignment can be suppressed. If R / r is smaller than 1, the leading pawl 40 may not fit into the columnar improved pile P, and a part of the columnar improved pile P may not be cut with the small bit 30. When R / r is larger than 2/3 ^1/2 , the distance between the leading claws 40 exceeds the diameter of the columnar improved piles P, and there is a large misalignment from the state in which the leading claws 40 are fitted to the columnar improved piles P. When it is likely to occur, any of the preceding claws 40 may not come into contact with the columnar improved pile P.

  The excavation head of the present invention can be used for crushing columnar piles constructed in ground improvement work, but can also be used for crushing other underground objects as long as it is a columnar underground object. .

DESCRIPTION OF SYMBOLS 1 Drilling head 4 Auger rod 10 Rotating shaft 20 Drilling blade 20a End part of drilling blade 20b Outer part of drilling blade 30 Small bit 32a Tip of small bit 40 Leading claw 41a Tip of leading claw 41b Inclined surface of leading claw P Columnar improvement pile

Claims (5)

An excavation head that is mounted on an auger rod and crushes a columnar improved pile buried in the ground,
A rotating shaft attached to the auger rod;
At least three spiral excavation blades provided around the rotating shaft;
A small bit attached to the end of the excavating blade in the excavation direction;
A leading claw attached to the outer peripheral portion of the excavation blade, the tip protruding in the excavation direction from the tip of the small bit ,
The leading pawl is an excavation head having a tip turning radius larger than that of the columnar improved pile .   An excavation head that is mounted on an auger rod and crushes a columnar improved pile buried in the ground,
  A rotating shaft attached to the auger rod;
  At least three spiral excavation blades provided around the rotating shaft;
  A small bit attached to the end of the excavating blade in the excavation direction;
  A leading claw attached to the outer periphery of the excavating blade and having a tip protruding in the excavating direction from the tip of the small bit;
With
  The rotation radius R on the inner surface closest to the rotation axis of the leading pawl and the radius r of the columnar improved pile are expressed by the following relational expression (1):
    1 ≦ R / r ≦ 1.1 (1)
Meet the drilling head.   An excavation head that is mounted on an auger rod and crushes a columnar improved pile buried in the ground,
  A rotating shaft attached to the auger rod;
  At least three spiral excavation blades provided around the rotating shaft;
  A small bit attached to the end of the excavating blade in the excavation direction;
  A leading claw attached to the outer periphery of the excavating blade and having a tip protruding in the excavating direction from the tip of the small bit;
With
  The leading claw is a drilling head having an inclined surface that has a tip turning radius larger than a radius of the columnar improved pile and is inclined from the tip toward the drilling blade side. The excavation head according to any one of claims 1 to 3 , wherein a tip of the leading claw protrudes 10 to 30 cm in a excavation direction from a tip of the small bit. The excavation head according to any one of claims 1 to 4, wherein the small bit is a conical bit having a bit body that is rotatably mounted.

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