JP2009013695A - Pile hole excavating head - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To surely restrict the swing angle of excavating arms by eliminating the formation of a recessed part in the surfaces of a head body 1 and the excavating arms 40 on which they are rubbed to prevent the inclusion of foreign matters from occurring. <P>SOLUTION: To form an excavating head 50, the excavating arms 40 are connected to the head body 1 swingably around horizontal shaft 20 at the front of the head body 1 connectable to an excavation rod 52. (a) A stopper 22 for restricting the swing by coming into contact with the side edge 40b of the excavating arm 40 during small-diameter excavating and (b) stoppers 26, 28 for restricting the swing by coming into contact with the side edge 40b of the excavating arm 40 during large-diameter excavating are attached to the head body 1. The head body 1, the horizontal shaft 20, and the excavating arms 40 are installed to be deformed so that the end rear surfaces of both excavating arms 40 are separated from the front of the head body 1 (a) when the excavating arms 40 are temporarily reversely rotated at the swing angle during the small-diameter excavation, and the rear surfaces of the excavating arms 40 are deformable to extend over the stopper 22", and (b) then normally rotated to be brought into the large-diameter excavating state. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an excavation head used to excavate a pile hole when excavating the pile hole to construct a foundation pile.

  Conventionally, drilling heads have been proposed and implemented in which drilling arms are swingably mounted on both sides of the head body that can be connected to the lower end of the drilling rod, and the drilling diameter is freely changed by changing the swing angle. Yes. In this case, in order to hold the excavation arm at a predetermined excavation diameter, a member serving as a stopper is required between the excavation arm and the head body.

For example, a latching protrusion is provided on the outer surface of the excavating arm (the surface that slides with the surface of the head body), and a latching hole that can lock the latching protrusion on the surface of the head body (the surface that slides with the locking arm) is formed. (Patent Document 1).
JP-A-8-338020

  In the case of the conventional technique, when the excavation arm moves between the engagement holes, the tip of the engagement protrusion abuts the surface of the head body, and the outer surface of the excavation arm and the surface of the head body In some cases, foreign matter entered between the two, which hindered the swinging of the excavating arm. In addition, if the latching hole where the latching protrusion is not latched is not blocked by the excavation arm, the latching hole will be open and foreign matter will enter the latching hole, which may hinder the regulation of the excavation arm. There was also.

  Accordingly, the present invention solves the above-mentioned problems by eliminating the retaining holes on the surface of the head body and eliminating the retaining protrusions of the excavating arm.

That is, this invention is a pile hole excavation head characterized by having the following requirements (1) to (3).
(1) The upper end of an excavating arm having an excavating blade attached to the lower end is connected to both front faces of the head main body, which can be connected to the excavating rod, so as to be swingable around the horizontal axis of the head main body.
(2) The head main body is in contact with the side edge of the excavation arm during small-diameter excavation, and a small-diameter stopper that regulates swinging of the excavation arm, is in contact with the side edge of the excavation arm during large-diameter excavation, A large-diameter stopper for restricting the swing of the excavating arm is attached.
(3) The head main body, the horizontal axis, and the excavating arm are “the front and back surfaces of the two excavating arms are deformed so that they are separated from the front surface of the head main body, and the rear surface of the excavating arm is above the small diameter stopper. It can be deformed so that it can pass through.

Another invention is a pile hole excavation head characterized by having the following requirements (1) to (3).
(1) The upper end of an excavating arm having an excavating blade attached to the lower end is connected to both front faces of the head main body, which can be connected to the excavating rod, so as to be swingable around the horizontal axis of the head main body.
(2) A small-diameter stopper that regulates the swinging of the excavating arm by contacting the head main body with the side edge of the excavating arm when the head main body is rotated forward to excavate the small diameter, and the head main body is A large-diameter stopper that rotates and contacts the side edge of the excavating arm during large-diameter excavation and regulates the swinging of the excavating arm is attached.
(3) The head main body, the horizontal axis and the excavating arm are: “The head main body is lowered downward at the excavation angle of the excavating arm during the small-diameter excavation, and the tip of the excavating blade is pressed against the pile hole bottom. The front and back surfaces of the two excavation arms are deformed so that they are separated from the front surface of the head body, and the rear surfaces of the excavation arms can be deformed so that they can pass above the small diameter stopper. Yes.

Another invention is a pile hole excavation head characterized by having the following requirements (1) to (3).
(1) The upper end of an excavating arm having an excavating blade attached to the lower end is connected to both front faces of the head main body, which can be connected to the excavating rod, so as to be swingable around the horizontal axis of the head main body.
(2) The head main body is in contact with the side edge of the excavation arm during small-diameter excavation, and a small-diameter stopper that regulates swinging of the excavation arm, is in contact with the side edge of the excavation arm during large-diameter excavation, A large-diameter stopper for restricting the swing of the excavating arm is attached.
(3) The head main body, the horizontal axis, and the excavating arm are expressed as follows: “When the excavating arm rotates at a swing angle during small-diameter excavation, when the head main body is rotated in reverse, the front and back surfaces of both excavating arms are It is connected so that it can be deformed so as to be separated from the front surface of the main body so that the back surface of the excavating arm can pass above the small diameter stopper.

  According to the present invention, since the head body is provided with a stopper that contacts the side edge of the excavating arm, neither the head main body nor the excavating arm is formed with a recess into which foreign matter such as excavated soil enters. Pile holes can be constructed with an accurate excavation diameter by regulating the angle easily and reliably. In addition, since the stopper can be arranged so that it can rotate forward and perform both small-diameter excavation and large-diameter excavation, when applied to the medium excavation method, pile hole excavation can be performed without any trouble of soil removal to the ground.

(1) The horizontal shafts 20 and 20 are provided on the front surfaces 7 and 7 of the upper end portion (cuboid portion 6) of the head body 1 having the connecting portion 5 that can be connected to the lower end portion of the excavation rod 52. The upper end portion of the excavation arm 40 having the excavation blades 47, 47 at the lower end portion (the upper end portion of the main body portion 41) is connected. At this time, the front surfaces 7, 11, 16 of the head body 1 and the back surface 44 of the excavating arm 40 face each other.
The excavation arms 40 and 40 are swingably attached around the horizontal axis 20, and slide so that the front surfaces 7, 11 and 16 of the head body 1 and the rear surface 44 of the excavation arm 40 slide. Further, when a predetermined resistance is applied to the excavating arm 40 head body 1, the excavating arm 40 rotates in a direction perpendicular to the swinging direction with the upper end of the swinging arm 40 (near the mounting height of the horizontal shaft 20) as an axis. The lower end of the head main body 1 opens in the direction indicated by arrows 61 and 61 and can be deformed so that a gap 36 is formed between the front surface 16 of the lower end portion (enlarged portion 15) of the head body 1 and the rear surface 44 of the excavating arm 40. (FIG. 3B). The excavation arm 40 and the horizontal shaft 20 are attached, and the horizontal shaft 20 and the head main body 1 are attached so that the above operation can be performed (FIG. 1).

(2) A first stopper (small diameter stopper) 22 for maintaining the swing angle (inclination, small diameter excavation state) of the excavation arm 40 when the head main body 1 (excavation rod 52) is rotated forward. Is provided. Further, a second stopper (large diameter stopper) 26 for maintaining the large diameter excavation state in which the head main body 1 (excavation rod 52) is rotated forward and the excavation arm 40 further increases the swing angle (inclination). An upper stopper 28 is provided (FIG. 1).

(3) The excavation head 50 is configured as described above (FIGS. 1A and 1B). Fixed excavation blades 3, 3 are also projected downward at the lower end of the head body 1.

(4) This excavation head 50 connects the lower end portion of the excavation rod 52 to the connecting portion 4 and, like the conventional excavation head, the excavation blade 47 of the fixed excavation blades 3 and 3 of the head body 1 or the excavation arm 40. When the excavation rod 52 is rotated in the forward direction with the ground being put on the ground, the head main body 1 is also rotated in the forward direction, and excavation of the pile hole 57 can be started. At this time, the excavation arm 40 is caused by the resistance generated when the excavation blade 47 of the excavation arm 40 abuts against the pile hole bottom (ground) or the resistance received by the excavation arm 40 (the main body 51 or the excavation blade 47) itself by excavation soil or the like. Is opened, the outer edge 40b abuts against the first stopper 22 and the swing angle is restricted from further opening, and the shaft portion 58 of the pile hole 57 can be excavated with a predetermined diameter D1 (FIG. 2A). ).

(5) When excavation of the shaft portion 58 of the pile hole 57 is completed, the excavation arm 40 is opened in the directions of arrows 61 and 61, and the rear surface 44 of the excavation arm 40 and the front surface 16 of the lower end portion of the head body 1 are A gap 36 is formed between them (FIG. 3 (b)), and the back surface 44 side of the excavating arm 40 passes through (through) the tip (upper side) of the first stopper 22, and the excavating arm 40 is used for large-diameter excavation. It opens at the swing angle, the outer edge 40b is brought into contact with the second stopper 26, and further opening of the swing angle is restricted, so that the widened portion 59 of the pile hole 57 can be excavated with a predetermined diameter D2. 2 (b)).

(6) In (5), one method for opening the excavation arm 40 in the directions indicated by arrows 61 and 61 and generating the gap 36 is to once rotate the excavation rod 52 (head body 1) in a small-diameter excavation state. If it is lowered and slightly lowered, the excavation arm 40 receives the resistance of the excavation mud in the pile hole 36 and opens slightly in the direction of arrows 61 and 61 (FIG. 3 (b)). If the main body 1) is rotated forward, the excavating arm 40 can jump over the first stopper 22. At this time, the excavation arm 40 is pressed against the first stopper 22 with a very strong force during normal rotation for a long time, and when the excavation head 50 is pushed downward by releasing this state by reverse rotation. The excavating arm 40 can be easily moved.
When this method is adopted, it is necessary to make the excavating arm have a structure that receives the resistance of earth pressure. For example, although depending on the soil to be excavated, the lower end portions of the main body portions 41 of the excavating arms 40 and 40 and the excavating blades 47 are opened outward so that the excavating arms 40 can be easily opened (FIG. 1). Alternatively, the head main body 1 is shaped so that the tip of the excavation arm 40 is located below the lower end of the head main body 1 (FIGS. 1 and 2), or in a small diameter excavation state (and a large diameter excavation state), and the head main body in front view 1 and the excavation arm 40 do not overlap with each other, and the excavation arm 40 protrudes downward or laterally (FIGS. 2A and 2B), or a small inclined plate or the like is formed on the surface of the excavation arm 40. (It is desirable that the resistance generated during excavation be as low as possible) (not shown).
In another method, when the excavating rod 52 (head body 1) is pushed down and the excavating blades 47 and 47 are pressed against the bottom of the pile hole 57 in a small diameter excavation state, Due to the resistance to the bottom of 57, the excavating arms 40, 40 open in the direction of arrows 61, 61 (FIG. 3B) and can jump over the first stopper 22 immediately. At this time, similarly to the above-described one method, the excavating blades 47, 47 can be once reversely rotated while being pressed against the bottom of the pile hole 57, and immediately forward rotated. When this method is employed, it is desirable that the tip of the digging blade 47 is positioned below the tip of the fixed digging blades 3 and 3 in the small-diameter excavation state (FIG. 2A).
Further, the above one method and another method can be used in combination.

(7) When excavation of the expanded bottom portion 59 of the pile hole 57 is completed, cement milk is discharged into the expanded bottom portion 59 from the discharge port 32 of the head body 1 of the excavation head 50, and the excavation head 50 is rotated forward. Mix with excavated soil to form soil cement.

(8) When the formation of the soil cement is completed, the excavation arm 40 is opened again in the directions of arrows 61 and 61, and the excavation rod 52 (head body 1) is rotated in the reverse direction. A gap 36 is formed between the lower end portion of the head body 1 and the front surface 16 (FIG. 3B), and the front end of the first stopper 22 passes through the back surface 44 side of the excavating arm 40 (passes through). Subsequently, the rotation of the excavation rod 52 (head main body 1) is stopped, the swinging arm 40 is suspended, and the excavation head 50 is pulled up to the ground.

(9) In (8), one method for generating the gap 36 is to rotate the excavation rod 52 (head body 1) once in the large-diameter excavation state, and the excavation arm 40 can remove the excavation mud in the pile hole 36. If it opens in the direction of arrows 61 and 61 so as to receive resistance (FIG. 3B), the excavating arm 40 can jump over the first stopper 22. When this method is adopted, although depending on the state in the expanded bottom portion 59, if the lower end portions of the main body portions 41 of the excavating arms 40 and 40 and the excavating blades 47 are opened outward ( FIG. 1 (b)), by pushing down the excavating rod 52, a resistance force that opens in the directions of arrows 61 and 61 can be applied.
In another method, when the excavation blades 47 and 47 of the excavation rod 52 (head body 1) are pressed against the bottom of the pile hole 57 in a large diameter excavation state, the excavation blades 47 and 47 are connected to the bottom of the pile hole 57. Since the excavating arms 40 and 40 open in the directions indicated by arrows 61 and 61 due to the resistance (FIG. 3B), the first stopper 22 can be jumped over by reverse rotation. When this method is employed, it is desirable that the tip of the digging blade 47 is positioned below the tip of the fixed digging blades 3 and 3 in the large-diameter excavation state (FIG. 2B).

  Embodiments of the present invention will be described with reference to the drawings.

[1] Configuration of the excavation head 50

(1) The head body 1 has fixed digging blades 3 and 3 projecting downward at the lower end of the base 2 and has a connecting portion 4 with a digging rod 52 at the upper end of the base 2. The base 2 of the head main body 1 includes an upper rectangular parallelepiped portion 6, an intermediate reduced portion 10, and a lower enormous portion 15, and fixed excavating blades 3 and 3 project from the lower surface of the enormous portion 15.
The front surface 11 of the reduced portion 10 is formed flat with the same width from the front surface 7 of the rectangular parallelepiped portion 6 of the base portion 2, and the lower portion of the front surface 11 of the reduced portion 10 protrudes laterally with a larger width than the front surface 7 of the rectangular parallelepiped portion 6. The part 15 is formed, and the center of the lower edge 18 of the front part 16 of the enormous part is formed in a substantially arc shape that is the lowest. The enormous portion 15 has a substantially horizontal upper surface 19, and the side surface 12 of the reduced portion, the horizontal portion 19 and the side surface 17 of the enormous portion 15 are continuous.
Further, the side surface 12 of the reduced portion 10 of the base portion 2 is formed obliquely so that the width gradually decreases from the upper edge (the lower edge of the side surface 8 of the rectangular parallelepiped portion 6) toward the lower edge of the side surface 17 of the enlarged portion 15. Has been.

(2) Horizontal shafts 20, 20 project from the front surfaces 7, 7 of the rectangular parallelepiped portion 6 of the base 2 of the head body 1, and the upper end portions of the excavating arms 40 are attached to the horizontal shafts 20, respectively.

(3) The front surface 42 of the main body portion 41 of the excavating arm 40 is formed to be wide at the upper part to which the horizontal shaft 20 is attached, to be narrow at the middle part, and to be wide again at the lower end part. Has been.
Further, the side surface 43 of the main body portion 41 of the excavating arm 40 is formed with substantially the same width over the entire length, and is bent along the inclination of the front surfaces 7, 11, 16 of the head main body 1. That is, at the side surface 43, the upper portion of the main body portion 41 is vertical, the middle portion is inclined downward (towards the center and downward) so that the excavating arms 40 and 40 approach, and the lower portion is both excavating arms 40 and 40. Is formed so as to be inclined (outward and downward).
Excavation blades 47 and 47 are fixed to the lower end portion of the main body 41 downward. The excavation blades 47 and 47 are attached to be inclined outward and downward in accordance with the inclination of the lower portion of the main body 41 (attachment portion of the excavation blades 47 and 47).
Further, an upper bulging portion 45 is connected to the upper end of the main body portion 41.

(4) Stirring plates 34 and 34 for stirring and soil removal are provided obliquely on the side surface 8 of the rectangular parallelepiped portion 6 of the head main body 1 in a side view (FIGS. 1A and 1B). Further, discharge ports 32 and 32 for discharging cement milk or the like are provided in the side surfaces 12 and 12 of the reduced portion 10 of the head main body 1 in a horizontal columnar shape (FIG. 1B). The discharge port 32 is provided with an open / close valve, and is connected to a pipe (not shown) from the discharge port 32 to the head body 1 and from the connecting portion 4 through the excavating rod 52 to the ground. Etc. are used when discharging into the pile hole 57.

(5) Further, in order to maintain the inclination angle at which the excavating arm 40 swings and inclines and enters a small-diameter excavation state, the lower portion (intermediate portion) of the excavating arm 40 is placed on the front surfaces 16 and 16 of the enormous portion 15 of the head body 1 Alternatively, the first stopper 22 provided at the lower end portion is fixed. One surface (inner side) 22 a of the first stopper 22 abuts on the outer edge 40 b of the excavating arm 40.
Further, the front and rear stoppers 24 that contact the inner edge 40a of the excavating arm 40 are fixed to the front surfaces 16 and 16 of the enormous portion 15 of the head body 1 in this state. The in / out stopper 24 is a hemispherical convex outward, is exposed from the front surface 16 of the enormous portion 15 of the head body 1, and is normally urged by a spring or the like so as to be in a protruding state. As a result, the surface 16 is sunk as much as the front 16.
Further, the excavating arm 40 is regulated so as not to be opened any more by the first stopper 22, and is regulated so as not to be closed by the in / out stopper 24 so as to always maintain a constant inclination angle. .

(6) Further, in order to maintain the inclination in which the excavating arm 40 swings and inclines and becomes a large-diameter excavation state, on the upper surfaces 19 and 19 (or on the front surfaces 16 and 16) of the huge portion 15 of the head body 1, The second stopper 26 is fixed. Similarly, in this state, the excavation arm 40 swells upwardly on the front surface 7 of the rectangular parallelepiped portion 6 of the head body 1 in order to maintain the inclination in which the excavation arm 40 swings and inclines to a large diameter excavation state. The upper stopper 28 that restricts the maximum angle is fixed so that the excavation arm 40 does not open any more by coming into contact with the protruding portion 45.
Further, in this state, the other surface (outer side) 22b of the first stopper 22 abuts on the inner edge 40a of the excavating arm 40 so as to restrict the minimum angle so that the excavating arm 40 does not close below it. Works.

(7) Further, a third stopper 30 is fixed to the front surface 16 of the enormous portion 15 of the base portion 2 of the head main body 1 so as to maintain the drooping state when the excavation arm is rotated downward in the reverse direction. The third stopper 30 abuts against the inner rule edge 40a of the excavating arm 40 during reverse rotation.

(8) The excavation head 50 according to the present invention is configured as described above (FIGS. 1A and 1B). When the excavating arm 40 slides, the back surface 44 of the excavating arm 40 is formed in a shape that swings along each front surface 7, 11, 16 of the base portion 2 of the head body 1.
In the above description, the head main body 1 and the excavation arm 40 are in a state where the excavation arm 40 is inclined in a large-diameter excavation state, and the lower end of the excavation blade 47 of the excavation arm 40 is lower than the lower end of the fixed excavation blade 3 of the head main body 1. It is formed so as to be positioned below (FIG. 2B).
In addition, when the tip of the excavation blades 47, 47 is pressed against the ground (the bottom of the pile hole) in the small diameter excavation state or the large diameter excavation state, it is caused by the resistance with the ground or when it rotates in the pile hole without being pressed, Due to the resistance, the excavating arms 40, 40 rotate slightly around the horizontal axis 20 and the lower end opens in the direction of arrows 61, 61 (a direction perpendicular to the swinging direction). The head body 1, the horizontal shaft 20, and the excavation arm 40 are formed so that a gap 36 is opened between each of the front surfaces 7, 11, 16 and the rear surface 44 of the excavation arm 40 (FIG. 3B). The height of the first stopper 22 is lower than the gap 36, and the second stopper 26 is formed higher than the gap 36.
The excavating arm 40 and the stoppers 22, 24, 26, 28, 30 are identically formed on both sides of the head body 1.

[2] Use of drilling head (drilling method)

  Next, the example which used the excavation head 50 of this invention based on the said Example for the medium excavation method is demonstrated.

(1) In the medium excavation method, the excavation head 40 is attached to the tip of the excavation rod 52, and the excavation head 50 is inserted through the hollow portion 55 of the hollow ready-made pile 54 (FIGS. 1A and 1B). It protrudes from the lower end 56 of 54 (FIG. 2 (a)).

(2) When the excavating rod 52 is rotated forward, the excavating arms 40 and 40 of the excavating head 50 have the excavating blades 47 and 47 have their tips in contact with the ground (pile hole bottom), and the excavating arm 11 swings due to friction. (FIG. 2A. Small-diameter swing state) The excavating arms 40 and 40 are restricted by the first stopper 22 and the in / out stopper 24. Accordingly, the shaft portion 58 of the pile hole 57 having a predetermined diameter D1 can be excavated with the excavating blades 47 and 47 and the fixed excavating blades 3 and 3 (FIGS. 2A and 3A). At this time, the excavated soil is transferred upward through the hollow portion 55 of the ready-made pile 54 by a spiral blade (not shown) of the excavating rod 52.
After excavation of the shaft portion 58 of the pile hole 57 by the excavation head 50 is completed, or while excavating, the ready-made pile 54 is gradually lowered.

(3) Next, when the excavation of the shaft portion 58 of the pile hole 57 is completed, the rotational speed of the excavation rod 52 is once reduced and the excavation rod 52 is pushed down. In this state (the state in which the excavation arm 40 is inclined in the small-diameter excavation state), the lower end of the excavation blade 47 of the excavation arm 40 is located below the lower end of the fixed excavation blade 3 of the head body 1, so that the excavation rod 52 Is pushed down, the tips of the excavating blades 47, 47 are pressed against the ground (the bottom surface of the pile hole 57). As a result, the lower ends of the excavating arms 40, 40 are separated in the directions indicated by arrows 61, 61 (slightly rotated around the horizontal axis 20) and excavated from the front surfaces 7, 11, 16 of the head body 1. A gap 36 is opened between the back surface 44 of the arm 40 (FIG. 3B). Therefore, the back surface 44 of the excavating arm 40 gets over the first stopper 22 (FIG. 3B), and the swing inclination angle is greatly opened, the outer edge 40b of the excavating arm 40 abuts on the second stopper 26, and excavation is performed. The upper bulging portion 45 of the arm 40 comes into contact with the upper stopper 28, and the swing angle of the excavating arm 40 is restricted by both the stoppers 26, 28, so that it cannot be opened further.
At the same time, the inner edge 40a of the excavation arm 40 abuts against the other surface (outer side) 22b of the first stopper 22, so that the excavation arm 40 is also restricted from being closed below that, and the excavation arm 40 maintains its inclination angle. . Therefore, excavation of the bottom expanded part 59 of the pile hole 57 of the diameter D2 can be performed correctly.
At this time, if the excavation rod 52 is raised or the ready-made pile 54 is lowered, the excavation arm 40 of the excavation head 50 comes into contact with the lower end 56 of the ready-made pile 54 and the excavation rod 52 is further raised. Since the ready-made pile 54 cannot be lowered, it can be confirmed that the excavating arms 40 and 40 are restricted by the second stopper 26 and the upper stopper 28 and opened to the large-diameter excavation state.

(4) After excavation of the expanded bottom portion 59 with a diameter D2 by a predetermined depth, the excavating blades 47 and 47 are separated from the bottom of the pile hole, and the excavation head 50 continues to rotate to excavate soil in the expanded bottom portion 59. While stirring, cement milk is discharged from the discharge ports 32, 32 of the head body 1 to form a soil cement.

(5) When the predetermined cement milk is formed, the rotation of the excavation rod 52 (excavation head 50) is stopped, the excavation rod 52 is pushed down, and the excavation blades 47, 47 of the excavation head 52 are pressed against the pile hole bottom. Then, when each of the front surfaces 7, 11, 16 of the head main body 1 and the back surface 44 of the excavating arm 40 are opened so as to create a gap 36 (FIG. 3B), the excavation rod 52 is rotated in the reverse direction. The arms 40, 40 get over the first stoppers 22, 22 and close (FIG. 3 (a)), the swing inclination angle becomes small, and the arms 40 hang down (FIG. 1). At this time, since the inner edge 40a of the excavating arm 40 is locked to the third stopper 30, it is possible to prevent the excavating arm 40 from swinging to the opposite side to the first stopper 22 due to reverse rotation, and to hang downward. Can be maintained.
In this state, the excavation rod 52 and the excavation head 50 pass through the hollow portion 55 of the ready-made pile 54 (FIGS. 1A and 1B) and are pulled up to the ground, and the hollow ready-made pile 54 is pushed downward to prepare the ready-made pile. The lower end 56 of 54 is positioned within the widened portion 59 (not shown).

(6) When cement milk (soil cement) is solidified as described above, construction of the foundation pile is completed (not shown).

[3] Other embodiments

(1) In the above embodiment, the excavation head 50 is used for the medium excavation method, but a so-called pre-excavation method in which a pile hole is excavated in advance and an off-the-shelf pile is buried in the pile hole, or a concrete and reinforcing steel cage in the pile hole. It can also be used when excavating a pile hole in a field-built pile or the like to put (not shown).

(2) In the embodiment, the shapes of the head main body 1 and the excavating arm 40 are not limited to those in the embodiment, and the excavating arms 40, 40 with the excavating blades 47, 47 are swung around the horizontal axis 20 of the head main body 1. Other structures are possible as long as they are movably connected (not shown).

(3) In the above-described embodiment, the in / out stopper 24 is provided so that the opening does not shrink during the small-diameter excavation, but may be omitted (not shown).
Moreover, although the 2nd stopper 26 and the upper stopper 28 which restrict | limit the maximum opening at the time of large diameter excavation were provided, either one can also be abbreviate | omitted (not shown).

(4) In the above embodiment, the excavation blade 47 side of the excavation arm 40 rotates about the horizontal axis 20 so that the gap between the back surface 44 of the excavation arm 40 and the front surfaces 7, 11 and 16 of the head body 1 opens. This mechanism may be realized by either one or both of the mounting structure of the excavating arm 40 and the horizontal shaft 20 or the mounting structure of the horizontal shaft 20 and the head body 1 (not shown).

(5) In the above-described embodiment, when the excavation arm 40 is inclined in the large-diameter excavation state, the lower end of the excavation blade 47 of the excavation arm 40 is positioned at least below the lower end of the fixed excavation blade 3 of the head body 1. (FIG. 2B), but at least in a small-diameter excavation state, the lower end of the excavation blade 47 of the excavation arm 40 is formed below the lower end of the fixed excavation blade 3 of the head body 1. It is desirable. A structure in which the excavating arms 40 and 40 are opened in the directions indicated by arrows 61 and 61 by the resistance received by the entire excavating arm 40 by rotating the excavating rod 52 backward and vertically depending on the state of excavated soil and cement milk in the pile hole. In other words, the lower end position of the excavating blade 47 of the excavating arm 40 and the lower end position of the fixed excavating blade 3 of the head main body 1 are arbitrarily set to the same height or reversed (not shown).

(6) In the above-described embodiment, the discharge port 32 is provided on the side surfaces 12 and 12 of the reduced portion 10 of the head body 1. (Not shown). Moreover, it can also be installed in multiple places (not shown).

In the embodiment of the present invention, (a) is a front view and (b) is a side view. Similarly, in the embodiment of the present invention, (a) is a front view in a small diameter excavation state, and (b) is a front view in a large diameter excavation state. Similarly, in the embodiment of the present invention, (a) is a side view in a small-diameter excavation state, and (b) is a side view in transition to the small-diameter excavation state.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Head main body 2 Base part of head main body 3 Fixed excavation blade of head main body 4 Connection part of head main body 6 Rectangular body part of head (head main body)
7 Front of the rectangular parallelepiped portion of the base 8 Side surface of the rectangular parallelepiped portion of the base 10 Reduced portion of the base (head body)
11 Front of reduced portion of base 12 Side surface of reduced portion of base 15 Enlarged portion of base (head body)
16 Front side of base part 17 Side face 20 of base part Horizontal axis (head body)
22 First stopper (head body)
24 Intrusion stopper (head body)
26 Second stopper (head body)
28 Upper stopper (Head body)
30 Third stopper (head body)
32 Discharge port (head body)
34 Stirrer blade (head body)
40 Drilling arm 40a Drilling arm inner rule edge 40b Drilling arm outer rule edge 41 Drilling arm main body portion 42 Drilling arm main body portion front surface 43 Drilling arm main body side surface 44 Drilling arm main body portion rear surface 45 Drilling arm main body portion Upper bulging portion 47 Drilling arm drilling blade 50 Drilling head 52 Drilling rod 54 Ready-made pile 55 Ready-made pile hollow portion 56 Lower end of ready-made pile 57 Pile hole 58 Pile hole shaft portion 59 Pile hole widening portion

Claims (3)

A pile hole excavation head comprising the following requirements (1) to (3):
(1) The upper end of an excavating arm having an excavating blade attached to the lower end is connected to both front faces of the head main body, which can be connected to the excavating rod, so as to be swingable around the horizontal axis of the head main body.
(2) The head main body is in contact with the side edge of the excavation arm during small-diameter excavation, and a small-diameter stopper that regulates swinging of the excavation arm, is in contact with the side edge of the excavation arm during large-diameter excavation, A large-diameter stopper for restricting the swing of the excavating arm is attached.
(3) The head main body, the horizontal axis, and the excavating arm are “the front and back surfaces of the two excavating arms are deformed so that they are separated from the front surface of the head main body, and the rear surface of the excavating arm is above the small diameter stopper. It can be deformed so that it can pass through. A pile hole excavation head comprising the following requirements (1) to (3):
(1) The upper end of an excavating arm having an excavating blade attached to the lower end is connected to both front faces of the head main body, which can be connected to the excavating rod, so as to be swingable around the horizontal axis of the head main body.
(2) A small-diameter stopper that regulates the swinging of the excavating arm by contacting the head main body with the side edge of the excavating arm when the head main body is rotated forward to excavate the small diameter, and the head main body is A large-diameter stopper that rotates and contacts the side edge of the excavating arm during large-diameter excavation and regulates the swinging of the excavating arm is attached.
(3) The head main body, the horizontal axis and the excavating arm are: “The head main body is lowered downward at the excavation angle of the excavating arm during the small-diameter excavation, and the tip of the excavating blade is pressed against the pile hole bottom. The front and back surfaces of the two excavation arms are deformed so that they are separated from the front surface of the head body, and the rear surfaces of the excavation arms can be deformed so that they can pass above the small diameter stopper. Yes. A pile hole excavation head comprising the following requirements (1) to (3):
(1) The upper end of an excavating arm having an excavating blade attached to the lower end is connected to both front faces of the head main body, which can be connected to the excavating rod, so as to be swingable around the horizontal axis of the head main body.
(2) The head main body is in contact with the side edge of the excavation arm during small-diameter excavation, and a small-diameter stopper that regulates swinging of the excavation arm, is in contact with the side edge of the excavation arm during large-diameter excavation, A large-diameter stopper for restricting the swing of the excavating arm is attached.
(3) The head main body, the horizontal axis, and the excavating arm are expressed as follows: “When the excavating arm rotates at a swing angle during small-diameter excavation, when the head main body is rotated in reverse, the front and back surfaces of both excavating arms are It is connected so that it can be deformed so as to be separated from the front surface of the main body so that the back surface of the excavating arm can pass above the small diameter stopper.

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